/* dhclient.c DHCP Client. */ /* * Copyright (c) 1995, 1996, 1997, 1998, 1999 * The Internet Software Consortium. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of The Internet Software Consortium nor the names * of its contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE INTERNET SOFTWARE CONSORTIUM AND * CONTRIBUTORS ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, * INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE INTERNET SOFTWARE CONSORTIUM OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF * USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * This software has been written for the Internet Software Consortium * by Ted Lemon in cooperation with Vixie * Enterprises. To learn more about the Internet Software Consortium, * see ``http://www.vix.com/isc''. To learn more about Vixie * Enterprises, see ``http://www.vix.com''. * * This client was substantially modified and enhanced by Elliot Poger * for use on Linux while he was working on the MosquitoNet project at * Stanford. * * The current version owes much to Elliot's Linux enhancements, but * was substantially reorganized and partially rewritten by Ted Lemon * so as to use the same networking framework that the Internet Software * Consortium DHCP server uses. Much system-specific configuration code * was moved into a shell script so that as support for more operating * systems is added, it will not be necessary to port and maintain * system-specific configuration code to these operating systems - instead, * the shell script can invoke the native tools to accomplish the same * purpose. */ #ifndef lint static char ocopyright[] = "$Id: dhclient.c,v 1.44.2.39 1999/06/22 13:36:46 mellon Exp $ Copyright (c) 1995, 1996, 1997, 1998, 1999 The Internet Software Consortium. All rights reserved.\n"; #endif /* not lint */ #include "dhcpd.h" #include "version.h" TIME cur_time; TIME default_lease_time = 43200; /* 12 hours... */ TIME max_lease_time = 86400; /* 24 hours... */ struct tree_cache *global_options [256]; char *path_dhclient_conf = _PATH_DHCLIENT_CONF; char *path_dhclient_db = _PATH_DHCLIENT_DB; char *path_dhclient_pid = _PATH_DHCLIENT_PID; int interfaces_requested = 0; int log_perror = 1; struct iaddr iaddr_broadcast = { 4, { 255, 255, 255, 255 } }; struct iaddr iaddr_any = { 4, { 0, 0, 0, 0 } }; struct in_addr inaddr_any; struct sockaddr_in sockaddr_broadcast; /* ASSERT_STATE() does nothing now; it used to be assert (state_is == state_shouldbe). */ #define ASSERT_STATE(state_is, state_shouldbe) {} u_int16_t local_port; u_int16_t remote_port; int log_priority; int no_daemon; int save_scripts; int onetry; static char copyright[] = "Copyright 1995, 1996, 1997, 1998, 1999 The Internet Software Consortium."; static char arr [] = "All rights reserved."; static char message [] = "Internet Software Consortium DHCP Client"; static char contrib [] = "Please contribute if you find this software useful."; static char url [] = "For info, please visit http://www.isc.org/dhcp-contrib.html"; static void usage PROTO ((char *)); int main (argc, argv, envp) int argc; char **argv, **envp; { int i; struct servent *ent; struct interface_info *ip; int seed; int quiet = 1; char *s; s = strrchr (argv [0], '/'); if (!s) s = argv [0]; else s++; /* Initially, log errors to stderr as well as to syslogd. */ #ifdef SYSLOG_4_2 openlog (s, LOG_NDELAY); log_priority = DHCPD_LOG_FACILITY; #else openlog (s, LOG_NDELAY, DHCPD_LOG_FACILITY); #endif #if !(defined (DEBUG) || defined (SYSLOG_4_2) || defined (__CYGWIN32__)) setlogmask (LOG_UPTO (LOG_INFO)); #endif for (i = 1; i < argc; i++) { if (!strcmp (argv [i], "-p")) { if (++i == argc) usage (s); local_port = htons (atoi (argv [i])); debug ("binding to user-specified port %d", ntohs (local_port)); } else if (!strcmp (argv [i], "-d")) { no_daemon = 1; } else if (!strcmp (argv [i], "-D")) { save_scripts = 1; } else if (!strcmp (argv [i], "-pf")) { if (++i == argc) usage (s); path_dhclient_pid = argv [i]; } else if (!strcmp (argv [i], "-lf")) { if (++i == argc) usage (s); path_dhclient_db = argv [i]; } else if (!strcmp (argv [i], "-q")) { quiet = 1; quiet_interface_discovery = 1; } else if (!strcmp (argv [i], "-1")) { onetry = 1; } else if (argv [i][0] == '-') { usage (s); } else { struct interface_info *tmp = ((struct interface_info *) dmalloc (sizeof *tmp, "specified_interface")); if (!tmp) error ("Insufficient memory to %s %s", "record interface", argv [i]); memset (tmp, 0, sizeof *tmp); strcpy (tmp -> name, argv [i]); tmp -> next = interfaces; tmp -> flags = INTERFACE_REQUESTED; interfaces_requested = 1; interfaces = tmp; } } if (!quiet) { note ("%s %s", message, DHCP_VERSION); note (copyright); note (arr); note (""); note (contrib); note (url); note (""); } /* Default to the DHCP/BOOTP port. */ if (!local_port) { ent = getservbyname ("dhcpc", "udp"); if (!ent) local_port = htons (68); else local_port = ent -> s_port; #ifndef __CYGWIN32__ endservent (); #endif } remote_port = htons (ntohs (local_port) - 1); /* XXX */ /* Get the current time... */ GET_TIME (&cur_time); sockaddr_broadcast.sin_family = AF_INET; sockaddr_broadcast.sin_port = remote_port; sockaddr_broadcast.sin_addr.s_addr = INADDR_BROADCAST; #ifdef HAVE_SA_LEN sockaddr_broadcast.sin_len = sizeof sockaddr_broadcast; #endif inaddr_any.s_addr = INADDR_ANY; /* Discover all the network interfaces. */ discover_interfaces (DISCOVER_UNCONFIGURED); /* Parse the dhclient.conf file. */ read_client_conf (); /* Parse the lease database. */ read_client_leases (); /* Rewrite the lease database... */ rewrite_client_leases (); /* If no broadcast interfaces were discovered, call the script and tell it so. */ if (!interfaces) { script_init ((struct interface_info *)0, "NBI", (struct string_list *)0); script_go ((struct interface_info *)0); note ("No broadcast interfaces found - exiting."); /* Nothing more to do. */ exit (0); } else { /* Call the script with the list of interfaces. */ for (ip = interfaces; ip; ip = ip -> next) { /* If interfaces were specified, don't configure interfaces that weren't specified! */ if (interfaces_requested && ((ip -> flags & (INTERFACE_REQUESTED | INTERFACE_AUTOMATIC)) != INTERFACE_REQUESTED)) continue; script_init (ip, "PREINIT", (struct string_list *)0); if (ip -> client -> alias) script_write_params (ip, "alias_", ip -> client -> alias); script_go (ip); } } /* At this point, all the interfaces that the script thinks are relevant should be running, so now we once again call discover_interfaces(), and this time ask it to actually set up the interfaces. */ discover_interfaces (interfaces_requested ? DISCOVER_REQUESTED : DISCOVER_RUNNING); /* Make up a seed for the random number generator from current time plus the sum of the last four bytes of each interface's hardware address interpreted as an integer. Not much entropy, but we're booting, so we're not likely to find anything better. */ seed = 0; /* Unfortunately, what's on the stack isn't random. :') */ for (ip = interfaces; ip; ip = ip -> next) { int junk; memcpy (&junk, &ip -> hw_address.haddr [ip -> hw_address.hlen - sizeof seed], sizeof seed); seed += junk; } srandom (seed + cur_time); /* Start a configuration state machine for each interface. */ for (ip = interfaces; ip; ip = ip -> next) { ip -> client -> state = S_INIT; state_reboot (ip); } /* Set up the bootp packet handler... */ bootp_packet_handler = do_packet; /* Start dispatching packets and timeouts... */ dispatch (); /*NOTREACHED*/ return 0; } static void usage (appname) char *appname; { note (message); note (copyright); note (arr); note (""); note (contrib); note (url); note (""); warn ("Usage: %s [-D] [-d] [-p ] [-lf lease-file]", appname); error (" [-pf pidfile] [-q] [-1] [interface]"); } void cleanup () { } /* Individual States: * * Each routine is called from the dhclient_state_machine() in one of * these conditions: * -> entering INIT state * -> recvpacket_flag == 0: timeout in this state * -> otherwise: received a packet in this state * * Return conditions as handled by dhclient_state_machine(): * Returns 1, sendpacket_flag = 1: send packet, reset timer. * Returns 1, sendpacket_flag = 0: just reset the timer (wait for a milestone). * Returns 0: finish the nap which was interrupted for no good reason. * * Several per-interface variables are used to keep track of the process: * active_lease: the lease that is being used on the interface * (null pointer if not configured yet). * offered_leases: leases corresponding to DHCPOFFER messages that have * been sent to us by DHCP servers. * acked_leases: leases corresponding to DHCPACK messages that have been * sent to us by DHCP servers. * sendpacket: DHCP packet we're trying to send. * destination: IP address to send sendpacket to * In addition, there are several relevant per-lease variables. * T1_expiry, T2_expiry, lease_expiry: lease milestones * In the active lease, these control the process of renewing the lease; * In leases on the acked_leases list, this simply determines when we * can no longer legitimately use the lease. */ void state_reboot (ipp) void *ipp; { struct interface_info *ip = ipp; /* If we don't remember an active lease, go straight to INIT. */ if (!ip -> client -> active || ip -> client -> active -> is_bootp) { state_init (ip); return; } /* We are in the rebooting state. */ ip -> client -> state = S_REBOOTING; /* make_request doesn't initialize xid because it normally comes from the DHCPDISCOVER, but we haven't sent a DHCPDISCOVER, so pick an xid now. */ ip -> client -> xid = random (); /* Make a DHCPREQUEST packet, and set appropriate per-interface flags. */ make_request (ip, ip -> client -> active); ip -> client -> destination = iaddr_broadcast; ip -> client -> first_sending = cur_time; ip -> client -> interval = ip -> client -> config -> initial_interval; /* Zap the medium list... */ ip -> client -> medium = (struct string_list *)0; /* Send out the first DHCPREQUEST packet. */ send_request (ip); } /* Called when a lease has completely expired and we've been unable to renew it. */ void state_init (ipp) void *ipp; { struct interface_info *ip = ipp; ASSERT_STATE(state, S_INIT); /* Make a DHCPDISCOVER packet, and set appropriate per-interface flags. */ make_discover (ip, ip -> client -> active); ip -> client -> xid = ip -> client -> packet.xid; ip -> client -> destination = iaddr_broadcast; ip -> client -> state = S_SELECTING; ip -> client -> first_sending = cur_time; ip -> client -> interval = ip -> client -> config -> initial_interval; /* Add an immediate timeout to cause the first DHCPDISCOVER packet to go out. */ send_discover (ip); } /* state_selecting is called when one or more DHCPOFFER packets have been received and a configurable period of time has passed. */ void state_selecting (ipp) void *ipp; { struct interface_info *ip = ipp; struct client_lease *lp, *next, *picked; ASSERT_STATE(state, S_SELECTING); /* Cancel state_selecting and send_discover timeouts, since either one could have got us here. */ cancel_timeout (state_selecting, ip); cancel_timeout (send_discover, ip); /* We have received one or more DHCPOFFER packets. Currently, the only criterion by which we judge leases is whether or not we get a response when we arp for them. */ picked = (struct client_lease *)0; for (lp = ip -> client -> offered_leases; lp; lp = next) { next = lp -> next; /* Check to see if we got an ARPREPLY for the address in this particular lease. */ if (!picked) { script_init (ip, "ARPCHECK", lp -> medium); script_write_params (ip, "check_", lp); /* If the ARPCHECK code detects another machine using the offered address, it exits nonzero. We need to send a DHCPDECLINE and toss the lease. */ if (script_go (ip)) { make_decline (ip, lp); send_decline (ip); goto freeit; } picked = lp; picked -> next = (struct client_lease *)0; } else { freeit: free_client_lease (lp); } } ip -> client -> offered_leases = (struct client_lease *)0; /* If we just tossed all the leases we were offered, go back to square one. */ if (!picked) { ip -> client -> state = S_INIT; state_init (ip); return; } /* If it was a BOOTREPLY, we can just take the address right now. */ if (!picked -> options [DHO_DHCP_MESSAGE_TYPE].len) { ip -> client -> new = picked; /* Make up some lease expiry times XXX these should be configurable. */ ip -> client -> new -> expiry = cur_time + 12000; ip -> client -> new -> renewal += cur_time + 8000; ip -> client -> new -> rebind += cur_time + 10000; ip -> client -> state = S_REQUESTING; /* Bind to the address we received. */ bind_lease (ip); return; } /* Go to the REQUESTING state. */ ip -> client -> destination = iaddr_broadcast; ip -> client -> state = S_REQUESTING; ip -> client -> first_sending = cur_time; ip -> client -> interval = ip -> client -> config -> initial_interval; /* Make a DHCPREQUEST packet from the lease we picked. */ make_request (ip, picked); ip -> client -> xid = ip -> client -> packet.xid; /* Toss the lease we picked - we'll get it back in a DHCPACK. */ free_client_lease (picked); /* Add an immediate timeout to send the first DHCPREQUEST packet. */ send_request (ip); } /* state_requesting is called when we receive a DHCPACK message after having sent out one or more DHCPREQUEST packets. */ void dhcpack (packet) struct packet *packet; { struct interface_info *ip = packet -> interface; struct client_lease *lease; /* If we're not receptive to an offer right now, or if the offer has an unrecognizable transaction id, then just drop it. */ if (packet -> interface -> client -> xid != packet -> raw -> xid || (packet -> interface -> hw_address.hlen != packet -> raw -> hlen) || (memcmp (packet -> interface -> hw_address.haddr, packet -> raw -> chaddr, packet -> raw -> hlen))) { #if defined (DEBUG) debug ("DHCPACK in wrong transaction."); #endif return; } if (ip -> client -> state != S_REBOOTING && ip -> client -> state != S_REQUESTING && ip -> client -> state != S_RENEWING && ip -> client -> state != S_REBINDING) { #if defined (DEBUG) debug ("DHCPACK in wrong state."); #endif return; } note ("DHCPACK from %s", piaddr (packet -> client_addr)); lease = packet_to_lease (packet); if (!lease) { note ("packet_to_lease failed."); return; } ip -> client -> new = lease; /* Stop resending DHCPREQUEST. */ cancel_timeout (send_request, ip); /* Figure out the lease time. */ ip -> client -> new -> expiry = getULong (ip -> client -> new -> options [DHO_DHCP_LEASE_TIME].data); /* A number that looks negative here is really just very large, because the lease expiry offset is unsigned. */ if (ip -> client -> new -> expiry < 0) ip -> client -> new -> expiry = TIME_MAX; /* Take the server-provided renewal time if there is one; otherwise figure it out according to the spec. */ if (ip -> client -> new -> options [DHO_DHCP_RENEWAL_TIME].len) ip -> client -> new -> renewal = getULong (ip -> client -> new -> options [DHO_DHCP_RENEWAL_TIME].data); else ip -> client -> new -> renewal = ip -> client -> new -> expiry / 2; /* Same deal with the rebind time. */ if (ip -> client -> new -> options [DHO_DHCP_REBINDING_TIME].len) ip -> client -> new -> rebind = getULong (ip -> client -> new -> options [DHO_DHCP_REBINDING_TIME].data); else ip -> client -> new -> rebind = ip -> client -> new -> renewal + ip -> client -> new -> renewal / 2 + ip -> client -> new -> renewal / 4; ip -> client -> new -> expiry += cur_time; /* Lease lengths can never be negative. */ if (ip -> client -> new -> expiry < cur_time) ip -> client -> new -> expiry = TIME_MAX; ip -> client -> new -> renewal += cur_time; if (ip -> client -> new -> renewal < cur_time) ip -> client -> new -> renewal = TIME_MAX; ip -> client -> new -> rebind += cur_time; if (ip -> client -> new -> rebind < cur_time) ip -> client -> new -> rebind = TIME_MAX; bind_lease (ip); } void bind_lease (ip) struct interface_info *ip; { /* Remember the medium. */ ip -> client -> new -> medium = ip -> client -> medium; /* Write out the new lease. */ write_client_lease (ip, ip -> client -> new, 0); /* Run the client script with the new parameters. */ script_init (ip, (ip -> client -> state == S_REQUESTING ? "BOUND" : (ip -> client -> state == S_RENEWING ? "RENEW" : (ip -> client -> state == S_REBOOTING ? "REBOOT" : "REBIND"))), ip -> client -> new -> medium); if (ip -> client -> active && ip -> client -> state != S_REBOOTING) script_write_params (ip, "old_", ip -> client -> active); script_write_params (ip, "new_", ip -> client -> new); if (ip -> client -> alias) script_write_params (ip, "alias_", ip -> client -> alias); script_go (ip); /* Replace the old active lease with the new one. */ if (ip -> client -> active) free_client_lease (ip -> client -> active); ip -> client -> active = ip -> client -> new; ip -> client -> new = (struct client_lease *)0; /* Set up a timeout to start the renewal process. */ add_timeout (ip -> client -> active -> renewal, state_bound, ip); note ("bound to %s -- renewal in %d seconds.", piaddr (ip -> client -> active -> address), ip -> client -> active -> renewal - cur_time); ip -> client -> state = S_BOUND; reinitialize_interfaces (); go_daemon (); } /* state_bound is called when we've successfully bound to a particular lease, but the renewal time on that lease has expired. We are expected to unicast a DHCPREQUEST to the server that gave us our original lease. */ void state_bound (ipp) void *ipp; { struct interface_info *ip = ipp; ASSERT_STATE(state, S_BOUND); /* T1 has expired. */ make_request (ip, ip -> client -> active); ip -> client -> xid = ip -> client -> packet.xid; if (ip -> client -> active -> options [DHO_DHCP_SERVER_IDENTIFIER].len == 4) { memcpy (ip -> client -> destination.iabuf, ip -> client -> active -> options [DHO_DHCP_SERVER_IDENTIFIER].data, 4); ip -> client -> destination.len = 4; } else ip -> client -> destination = iaddr_broadcast; ip -> client -> first_sending = cur_time; ip -> client -> interval = ip -> client -> config -> initial_interval; ip -> client -> state = S_RENEWING; /* Send the first packet immediately. */ send_request (ip); } int commit_leases () { return 0; } int write_lease (lease) struct lease *lease; { return 0; } void db_startup () { } void bootp (packet) struct packet *packet; { struct iaddrlist *ap; if (packet -> raw -> op != BOOTREPLY) return; /* If there's a reject list, make sure this packet's sender isn't on it. */ for (ap = packet -> interface -> client -> config -> reject_list; ap; ap = ap -> next) { if (addr_eq (packet -> client_addr, ap -> addr)) { note ("BOOTREPLY from %s rejected.", piaddr (ap -> addr)); return; } } dhcpoffer (packet); } void dhcp (packet) struct packet *packet; { struct iaddrlist *ap; void (*handler) PROTO ((struct packet *)); char *type; switch (packet -> packet_type) { case DHCPOFFER: handler = dhcpoffer; type = "DHCPOFFER"; break; case DHCPNAK: handler = dhcpnak; type = "DHCPNACK"; break; case DHCPACK: handler = dhcpack; type = "DHCPACK"; break; default: return; } /* If there's a reject list, make sure this packet's sender isn't on it. */ for (ap = packet -> interface -> client -> config -> reject_list; ap; ap = ap -> next) { if (addr_eq (packet -> client_addr, ap -> addr)) { note ("%s from %s rejected.", type, piaddr (ap -> addr)); return; } } (*handler) (packet); } void dhcpoffer (packet) struct packet *packet; { struct interface_info *ip = packet -> interface; struct client_lease *lease, *lp; int i; int arp_timeout_needed, stop_selecting; char *name = (packet -> options [DHO_DHCP_MESSAGE_TYPE].len ? "DHCPOFFER" : "BOOTREPLY"); #ifdef DEBUG_PACKET dump_packet (packet); #endif /* If we're not receptive to an offer right now, or if the offer has an unrecognizable transaction id, then just drop it. */ if (ip -> client -> state != S_SELECTING || packet -> interface -> client -> xid != packet -> raw -> xid || (packet -> interface -> hw_address.hlen != packet -> raw -> hlen) || (memcmp (packet -> interface -> hw_address.haddr, packet -> raw -> chaddr, packet -> raw -> hlen))) { #if defined (DEBUG) debug ("%s in wrong transaction.", name); #endif return; } note ("%s from %s", name, piaddr (packet -> client_addr)); /* If this lease doesn't supply the minimum required parameters, blow it off. */ for (i = 0; ip -> client -> config -> required_options [i]; i++) { if (!packet -> options [ip -> client -> config -> required_options [i]].len) { note ("%s isn't satisfactory.", name); return; } } /* If we've already seen this lease, don't record it again. */ for (lease = ip -> client -> offered_leases; lease; lease = lease -> next) { if (lease -> address.len == sizeof packet -> raw -> yiaddr && !memcmp (lease -> address.iabuf, &packet -> raw -> yiaddr, lease -> address.len)) { debug ("%s already seen.", name); return; } } lease = packet_to_lease (packet); if (!lease) { note ("packet_to_lease failed."); return; } /* If this lease was acquired through a BOOTREPLY, record that fact. */ if (!packet -> options [DHO_DHCP_MESSAGE_TYPE].len) lease -> is_bootp = 1; /* Record the medium under which this lease was offered. */ lease -> medium = ip -> client -> medium; /* Send out an ARP Request for the offered IP address. */ script_init (ip, "ARPSEND", lease -> medium); script_write_params (ip, "check_", lease); /* If the script can't send an ARP request without waiting, we'll be waiting when we do the ARPCHECK, so don't wait now. */ if (script_go (ip)) arp_timeout_needed = 0; else arp_timeout_needed = 2; /* Figure out when we're supposed to stop selecting. */ stop_selecting = (ip -> client -> first_sending + ip -> client -> config -> select_interval); /* If this is the lease we asked for, put it at the head of the list, and don't mess with the arp request timeout. */ if (lease -> address.len == ip -> client -> requested_address.len && !memcmp (lease -> address.iabuf, ip -> client -> requested_address.iabuf, ip -> client -> requested_address.len)) { lease -> next = ip -> client -> offered_leases; ip -> client -> offered_leases = lease; } else { /* If we already have an offer, and arping for this offer would take us past the selection timeout, then don't extend the timeout - just hope for the best. */ if (ip -> client -> offered_leases && (cur_time + arp_timeout_needed) > stop_selecting) arp_timeout_needed = 0; /* Put the lease at the end of the list. */ lease -> next = (struct client_lease *)0; if (!ip -> client -> offered_leases) ip -> client -> offered_leases = lease; else { for (lp = ip -> client -> offered_leases; lp -> next; lp = lp -> next) ; lp -> next = lease; } } /* If we're supposed to stop selecting before we've had time to wait for the ARPREPLY, add some delay to wait for the ARPREPLY. */ if (stop_selecting - cur_time < arp_timeout_needed) stop_selecting = cur_time + arp_timeout_needed; /* If the selecting interval has expired, go immediately to state_selecting(). Otherwise, time out into state_selecting at the select interval. */ if (stop_selecting <= 0) state_selecting (ip); else { add_timeout (stop_selecting, state_selecting, ip); cancel_timeout (send_discover, ip); } } /* Allocate a client_lease structure and initialize it from the parameters in the specified packet. */ struct client_lease *packet_to_lease (packet) struct packet *packet; { struct client_lease *lease; int i; lease = (struct client_lease *)malloc (sizeof (struct client_lease)); if (!lease) { warn ("dhcpoffer: no memory to record lease.\n"); return (struct client_lease *)0; } memset (lease, 0, sizeof *lease); /* Copy the lease options. */ for (i = 0; i < 256; i++) { if (packet -> options [i].len) { lease -> options [i].data = (unsigned char *) malloc (packet -> options [i].len + 1); if (!lease -> options [i].data) { warn ("dhcpoffer: no memory for option %d\n", i); free_client_lease (lease); return (struct client_lease *)0; } else { memcpy (lease -> options [i].data, packet -> options [i].data, packet -> options [i].len); lease -> options [i].len = packet -> options [i].len; lease -> options [i].data [lease -> options [i].len] = 0; } } } lease -> address.len = sizeof (packet -> raw -> yiaddr); memcpy (lease -> address.iabuf, &packet -> raw -> yiaddr, lease -> address.len); /* If the server name was filled out, copy it. */ if ((!packet -> options [DHO_DHCP_OPTION_OVERLOAD].len || !(packet -> options [DHO_DHCP_OPTION_OVERLOAD].data [0] & 2)) && packet -> raw -> sname [0]) { int len; /* Don't count on the NUL terminator. */ for (len = 0; len < 64; len++) if (!packet -> raw -> sname [len]) break; lease -> server_name = malloc (len + 1); if (!lease -> server_name) { warn ("dhcpoffer: no memory for filename.\n"); free_client_lease (lease); return (struct client_lease *)0; } else { memcpy (lease -> server_name, packet -> raw -> sname, len); lease -> server_name [len] = 0; } } /* Ditto for the filename. */ if ((!packet -> options [DHO_DHCP_OPTION_OVERLOAD].len || !(packet -> options [DHO_DHCP_OPTION_OVERLOAD].data [0] & 1)) && packet -> raw -> file [0]) { int len; /* Don't count on the NUL terminator. */ for (len = 0; len < 64; len++) if (!packet -> raw -> file [len]) break; lease -> filename = malloc (len + 1); if (!lease -> filename) { warn ("dhcpoffer: no memory for filename.\n"); free_client_lease (lease); return (struct client_lease *)0; } else { memcpy (lease -> filename, packet -> raw -> file, len); lease -> filename [len] = 0; } } return lease; } void dhcpnak (packet) struct packet *packet; { struct interface_info *ip = packet -> interface; /* If we're not receptive to an offer right now, or if the offer has an unrecognizable transaction id, then just drop it. */ if (packet -> interface -> client -> xid != packet -> raw -> xid || (packet -> interface -> hw_address.hlen != packet -> raw -> hlen) || (memcmp (packet -> interface -> hw_address.haddr, packet -> raw -> chaddr, packet -> raw -> hlen))) { #if defined (DEBUG) debug ("DHCPNAK in wrong transaction."); #endif return; } if (ip -> client -> state != S_REBOOTING && ip -> client -> state != S_REQUESTING && ip -> client -> state != S_RENEWING && ip -> client -> state != S_REBINDING) { #if defined (DEBUG) debug ("DHCPNAK in wrong state."); #endif return; } note ("DHCPNAK from %s", piaddr (packet -> client_addr)); if (!ip -> client -> active) { note ("DHCPNAK with no active lease.\n"); return; } free_client_lease (ip -> client -> active); ip -> client -> active = (struct client_lease *)0; /* Stop sending DHCPREQUEST packets... */ cancel_timeout (send_request, ip); ip -> client -> state = S_INIT; state_init (ip); } /* Send out a DHCPDISCOVER packet, and set a timeout to send out another one after the right interval has expired. If we don't get an offer by the time we reach the panic interval, call the panic function. */ void send_discover (ipp) void *ipp; { struct interface_info *ip = ipp; int result; int interval; int increase = 1; /* Figure out how long it's been since we started transmitting. */ interval = cur_time - ip -> client -> first_sending; /* If we're past the panic timeout, call the script and tell it we haven't found anything for this interface yet. */ if (interval > ip -> client -> config -> timeout) { state_panic (ip); return; } /* If we're selecting media, try the whole list before doing the exponential backoff, but if we've already received an offer, stop looping, because we obviously have it right. */ if (!ip -> client -> offered_leases && ip -> client -> config -> media) { int fail = 0; again: if (ip -> client -> medium) { ip -> client -> medium = ip -> client -> medium -> next; increase = 0; } if (!ip -> client -> medium) { if (fail) error ("No valid media types for %s!", ip -> name); ip -> client -> medium = ip -> client -> config -> media; increase = 1; } note ("Trying medium \"%s\" %d", ip -> client -> medium -> string, increase); script_init (ip, "MEDIUM", ip -> client -> medium); if (script_go (ip)) { goto again; } } /* If we're supposed to increase the interval, do so. If it's currently zero (i.e., we haven't sent any packets yet), set it to one; otherwise, add to it a random number between zero and two times itself. On average, this means that it will double with every transmission. */ if (increase) { if (!ip -> client -> interval) ip -> client -> interval = ip -> client -> config -> initial_interval; else { ip -> client -> interval += ((random () >> 2) % (2 * ip -> client -> interval)); } /* Don't backoff past cutoff. */ if (ip -> client -> interval > ip -> client -> config -> backoff_cutoff) ip -> client -> interval = ((ip -> client -> config -> backoff_cutoff / 2) + ((random () >> 2) % ip -> client -> config -> backoff_cutoff)); } else if (!ip -> client -> interval) ip -> client -> interval = ip -> client -> config -> initial_interval; /* If the backoff would take us to the panic timeout, just use that as the interval. */ if (cur_time + ip -> client -> interval > ip -> client -> first_sending + ip -> client -> config -> timeout) ip -> client -> interval = (ip -> client -> first_sending + ip -> client -> config -> timeout) - cur_time + 1; /* Record the number of seconds since we started sending. */ if (interval < 65536) ip -> client -> packet.secs = htons (interval); else ip -> client -> packet.secs = htons (65535); ip -> client -> secs = ip -> client -> packet.secs; note ("DHCPDISCOVER on %s to %s port %d interval %ld", ip -> name, inet_ntoa (sockaddr_broadcast.sin_addr), ntohs (sockaddr_broadcast.sin_port), ip -> client -> interval); /* Send out a packet. */ result = send_packet (ip, (struct packet *)0, &ip -> client -> packet, ip -> client -> packet_length, inaddr_any, &sockaddr_broadcast, (struct hardware *)0); add_timeout (cur_time + ip -> client -> interval, send_discover, ip); } /* state_panic gets called if we haven't received any offers in a preset amount of time. When this happens, we try to use existing leases that haven't yet expired, and failing that, we call the client script and hope it can do something. */ void state_panic (ipp) void *ipp; { struct interface_info *ip = ipp; struct client_lease *loop = ip -> client -> active; struct client_lease *lp; note ("No DHCPOFFERS received."); /* We may not have an active lease, but we may have some predefined leases that we can try. */ if (!ip -> client -> active && ip -> client -> leases) goto activate_next; /* Run through the list of leases and see if one can be used. */ while (ip -> client -> active) { if (ip -> client -> active -> expiry > cur_time) { note ("Trying recorded lease %s", piaddr (ip -> client -> active -> address)); /* Run the client script with the existing parameters. */ script_init (ip, "TIMEOUT", ip -> client -> active -> medium); script_write_params (ip, "new_", ip -> client -> active); if (ip -> client -> alias) script_write_params (ip, "alias_", ip -> client -> alias); /* If the old lease is still good and doesn't yet need renewal, go into BOUND state and timeout at the renewal time. */ if (!script_go (ip)) { if (cur_time < ip -> client -> active -> renewal) { ip -> client -> state = S_BOUND; note ("bound: renewal in %d seconds.", ip -> client -> active -> renewal - cur_time); add_timeout ((ip -> client -> active -> renewal), state_bound, ip); } else { ip -> client -> state = S_BOUND; note ("bound: immediate renewal."); state_bound (ip); } reinitialize_interfaces (); go_daemon (); return; } } /* If there are no other leases, give up. */ if (!ip -> client -> leases) { ip -> client -> leases = ip -> client -> active; ip -> client -> active = (struct client_lease *)0; break; } activate_next: /* Otherwise, put the active lease at the end of the lease list, and try another lease.. */ for (lp = ip -> client -> leases; lp -> next; lp = lp -> next) ; lp -> next = ip -> client -> active; if (lp -> next) { lp -> next -> next = (struct client_lease *)0; } ip -> client -> active = ip -> client -> leases; ip -> client -> leases = ip -> client -> leases -> next; /* If we already tried this lease, we've exhausted the set of leases, so we might as well give up for now. */ if (ip -> client -> active == loop) break; else if (!loop) loop = ip -> client -> active; } /* No leases were available, or what was available didn't work, so tell the shell script that we failed to allocate an address, and try again later. */ if (onetry) { exit(2); note ("Unable to obtain a lease on first try - exiting.\n"); } note ("No working leases in persistent database - sleeping.\n"); script_init (ip, "FAIL", (struct string_list *)0); if (ip -> client -> alias) script_write_params (ip, "alias_", ip -> client -> alias); script_go (ip); ip -> client -> state = S_INIT; add_timeout (cur_time + ip -> client -> config -> retry_interval, state_init, ip); go_daemon (); } void send_request (ipp) void *ipp; { struct interface_info *ip = ipp; int result; int interval; struct sockaddr_in destination; struct in_addr from; /* Figure out how long it's been since we started transmitting. */ interval = cur_time - ip -> client -> first_sending; /* If we're in the INIT-REBOOT or REQUESTING state and we're past the reboot timeout, go to INIT and see if we can DISCOVER an address... */ /* XXX In the INIT-REBOOT state, if we don't get an ACK, it means either that we're on a network with no DHCP server, or that our server is down. In the latter case, assuming that there is a backup DHCP server, DHCPDISCOVER will get us a new address, but we could also have successfully reused our old address. In the former case, we're hosed anyway. This is not a win-prone situation. */ if ((ip -> client -> state == S_REBOOTING || ip -> client -> state == S_REQUESTING) && interval > ip -> client -> config -> reboot_timeout) { cancel: ip -> client -> state = S_INIT; cancel_timeout (send_request, ip); state_init (ip); return; } /* If we're in the reboot state, make sure the media is set up correctly. */ if (ip -> client -> state == S_REBOOTING && !ip -> client -> medium && ip -> client -> active -> medium ) { script_init (ip, "MEDIUM", ip -> client -> active -> medium); /* If the medium we chose won't fly, go to INIT state. */ if (script_go (ip)) goto cancel; /* Record the medium. */ ip -> client -> medium = ip -> client -> active -> medium; } /* If the lease has expired, relinquish the address and go back to the INIT state. */ if (ip -> client -> state != S_REQUESTING && cur_time > ip -> client -> active -> expiry) { /* Run the client script with the new parameters. */ script_init (ip, "EXPIRE", (struct string_list *)0); script_write_params (ip, "old_", ip -> client -> active); if (ip -> client -> alias) script_write_params (ip, "alias_", ip -> client -> alias); script_go (ip); /* Now do a preinit on the interface so that we can discover a new address. */ script_init (ip, "PREINIT", (struct string_list *)0); if (ip -> client -> alias) script_write_params (ip, "alias_", ip -> client -> alias); script_go (ip); ip -> client -> state = S_INIT; state_init (ip); return; } /* Do the exponential backoff... */ if (!ip -> client -> interval) ip -> client -> interval = ip -> client -> config -> initial_interval; else { ip -> client -> interval += ((random () >> 2) % (2 * ip -> client -> interval)); } /* Don't backoff past cutoff. */ if (ip -> client -> interval > ip -> client -> config -> backoff_cutoff) ip -> client -> interval = ((ip -> client -> config -> backoff_cutoff / 2) + ((random () >> 2) % ip -> client -> interval)); /* If the backoff would take us to the expiry time, just set the timeout to the expiry time. */ if (ip -> client -> state != S_REQUESTING && cur_time + ip -> client -> interval > ip -> client -> active -> expiry) ip -> client -> interval = ip -> client -> active -> expiry - cur_time + 1; /* If the lease T2 time has elapsed, or if we're not yet bound, broadcast the DHCPREQUEST rather than unicasting. */ if (ip -> client -> state == S_REQUESTING || ip -> client -> state == S_REBOOTING || cur_time > ip -> client -> active -> rebind) destination.sin_addr.s_addr = INADDR_BROADCAST; else memcpy (&destination.sin_addr.s_addr, ip -> client -> destination.iabuf, sizeof destination.sin_addr.s_addr); destination.sin_port = remote_port; destination.sin_family = AF_INET; #ifdef HAVE_SA_LEN destination.sin_len = sizeof destination; #endif if (ip -> client -> state != S_REQUESTING) memcpy (&from, ip -> client -> active -> address.iabuf, sizeof from); else from.s_addr = INADDR_ANY; /* Record the number of seconds since we started sending. */ if (ip -> client -> state == S_REQUESTING) ip -> client -> packet.secs = ip -> client -> secs; else { if (interval < 65536) ip -> client -> packet.secs = htons (interval); else ip -> client -> packet.secs = htons (65535); } note ("DHCPREQUEST on %s to %s port %d", ip -> name, inet_ntoa (destination.sin_addr), ntohs (destination.sin_port)); if (destination.sin_addr.s_addr != INADDR_BROADCAST && fallback_interface) result = send_packet (fallback_interface, (struct packet *)0, &ip -> client -> packet, ip -> client -> packet_length, from, &destination, (struct hardware *)0); else /* Send out a packet. */ result = send_packet (ip, (struct packet *)0, &ip -> client -> packet, ip -> client -> packet_length, from, &destination, (struct hardware *)0); add_timeout (cur_time + ip -> client -> interval, send_request, ip); } void send_decline (ipp) void *ipp; { struct interface_info *ip = ipp; int result; note ("DHCPDECLINE on %s to %s port %d", ip -> name, inet_ntoa (sockaddr_broadcast.sin_addr), ntohs (sockaddr_broadcast.sin_port)); /* Send out a packet. */ result = send_packet (ip, (struct packet *)0, &ip -> client -> packet, ip -> client -> packet_length, inaddr_any, &sockaddr_broadcast, (struct hardware *)0); } void send_release (ipp) void *ipp; { struct interface_info *ip = ipp; int result; note ("DHCPRELEASE on %s to %s port %d", ip -> name, inet_ntoa (sockaddr_broadcast.sin_addr), ntohs (sockaddr_broadcast.sin_port)); /* Send out a packet. */ result = send_packet (ip, (struct packet *)0, &ip -> client -> packet, ip -> client -> packet_length, inaddr_any, &sockaddr_broadcast, (struct hardware *)0); } void make_discover (ip, lease) struct interface_info *ip; struct client_lease *lease; { unsigned char discover = DHCPDISCOVER; int i; struct tree_cache *options [256]; struct tree_cache option_elements [256]; memset (option_elements, 0, sizeof option_elements); memset (options, 0, sizeof options); memset (&ip -> client -> packet, 0, sizeof (ip -> client -> packet)); /* Set DHCP_MESSAGE_TYPE to DHCPDISCOVER */ i = DHO_DHCP_MESSAGE_TYPE; options [i] = &option_elements [i]; options [i] -> value = &discover; options [i] -> len = sizeof discover; options [i] -> buf_size = sizeof discover; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; /* Request the options we want */ i = DHO_DHCP_PARAMETER_REQUEST_LIST; options [i] = &option_elements [i]; options [i] -> value = ip -> client -> config -> requested_options; options [i] -> len = ip -> client -> config -> requested_option_count; options [i] -> buf_size = ip -> client -> config -> requested_option_count; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; /* If we had an address, try to get it again. */ if (lease) { ip -> client -> requested_address = lease -> address; i = DHO_DHCP_REQUESTED_ADDRESS; options [i] = &option_elements [i]; options [i] -> value = lease -> address.iabuf; options [i] -> len = lease -> address.len; options [i] -> buf_size = lease -> address.len; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; } else { ip -> client -> requested_address.len = 0; } /* Send any options requested in the config file. */ for (i = 0; i < 256; i++) { if (!options [i] && ip -> client -> config -> send_options [i].data) { options [i] = &option_elements [i]; options [i] -> value = ip -> client -> config -> send_options [i].data; options [i] -> len = ip -> client -> config -> send_options [i].len; options [i] -> buf_size = ip -> client -> config -> send_options [i].len; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; } } /* Set up the option buffer... */ ip -> client -> packet_length = cons_options ((struct packet *)0, &ip -> client -> packet, 0, options, 0, 0, 0, (u_int8_t *)0, 0); if (ip -> client -> packet_length < BOOTP_MIN_LEN) ip -> client -> packet_length = BOOTP_MIN_LEN; ip -> client -> packet.op = BOOTREQUEST; ip -> client -> packet.htype = ip -> hw_address.htype; ip -> client -> packet.hlen = ip -> hw_address.hlen; ip -> client -> packet.hops = 0; ip -> client -> packet.xid = random (); ip -> client -> packet.secs = 0; /* filled in by send_discover. */ if (can_receive_unicast_unconfigured (ip)) ip -> client -> packet.flags = 0; else ip -> client -> packet.flags = htons (BOOTP_BROADCAST); memset (&(ip -> client -> packet.ciaddr), 0, sizeof ip -> client -> packet.ciaddr); memset (&(ip -> client -> packet.yiaddr), 0, sizeof ip -> client -> packet.yiaddr); memset (&(ip -> client -> packet.siaddr), 0, sizeof ip -> client -> packet.siaddr); memset (&(ip -> client -> packet.giaddr), 0, sizeof ip -> client -> packet.giaddr); memcpy (ip -> client -> packet.chaddr, ip -> hw_address.haddr, ip -> hw_address.hlen); #ifdef DEBUG_PACKET dump_packet (sendpkt); dump_raw ((unsigned char *)ip -> client -> packet, sendpkt->packet_length); #endif } void make_request (ip, lease) struct interface_info *ip; struct client_lease *lease; { unsigned char request = DHCPREQUEST; int i; struct tree_cache *options [256]; struct tree_cache option_elements [256]; memset (options, 0, sizeof options); memset (&ip -> client -> packet, 0, sizeof (ip -> client -> packet)); /* Set DHCP_MESSAGE_TYPE to DHCPREQUEST */ i = DHO_DHCP_MESSAGE_TYPE; options [i] = &option_elements [i]; options [i] -> value = &request; options [i] -> len = sizeof request; options [i] -> buf_size = sizeof request; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; /* Request the options we want */ i = DHO_DHCP_PARAMETER_REQUEST_LIST; options [i] = &option_elements [i]; options [i] -> value = ip -> client -> config -> requested_options; options [i] -> len = ip -> client -> config -> requested_option_count; options [i] -> buf_size = ip -> client -> config -> requested_option_count; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; /* If we are requesting an address that hasn't yet been assigned to us, use the DHCP Requested Address option. */ if (ip -> client -> state == S_REQUESTING) { /* Send back the server identifier... */ i = DHO_DHCP_SERVER_IDENTIFIER; options [i] = &option_elements [i]; options [i] -> value = lease -> options [i].data; options [i] -> len = lease -> options [i].len; options [i] -> buf_size = lease -> options [i].len; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; } if (ip -> client -> state == S_REQUESTING || ip -> client -> state == S_REBOOTING) { ip -> client -> requested_address = lease -> address; i = DHO_DHCP_REQUESTED_ADDRESS; options [i] = &option_elements [i]; options [i] -> value = lease -> address.iabuf; options [i] -> len = lease -> address.len; options [i] -> buf_size = lease -> address.len; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; } else { ip -> client -> requested_address.len = 0; } /* Send any options requested in the config file. */ for (i = 0; i < 256; i++) { if (!options [i] && ip -> client -> config -> send_options [i].data) { options [i] = &option_elements [i]; options [i] -> value = ip -> client -> config -> send_options [i].data; options [i] -> len = ip -> client -> config -> send_options [i].len; options [i] -> buf_size = ip -> client -> config -> send_options [i].len; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; } } /* Set up the option buffer... */ ip -> client -> packet_length = cons_options ((struct packet *)0, &ip -> client -> packet, 0, options, 0, 0, 0, (u_int8_t *)0, 0); if (ip -> client -> packet_length < BOOTP_MIN_LEN) ip -> client -> packet_length = BOOTP_MIN_LEN; ip -> client -> packet.op = BOOTREQUEST; ip -> client -> packet.htype = ip -> hw_address.htype; ip -> client -> packet.hlen = ip -> hw_address.hlen; ip -> client -> packet.hops = 0; ip -> client -> packet.xid = ip -> client -> xid; ip -> client -> packet.secs = 0; /* Filled in by send_request. */ /* If we own the address we're requesting, put it in ciaddr; otherwise set ciaddr to zero. */ if (ip -> client -> state == S_BOUND || ip -> client -> state == S_RENEWING || ip -> client -> state == S_REBINDING) { memcpy (&ip -> client -> packet.ciaddr, lease -> address.iabuf, lease -> address.len); ip -> client -> packet.flags = 0; } else { memset (&ip -> client -> packet.ciaddr, 0, sizeof ip -> client -> packet.ciaddr); if (can_receive_unicast_unconfigured (ip)) ip -> client -> packet.flags = 0; else ip -> client -> packet.flags = htons (BOOTP_BROADCAST); } memset (&ip -> client -> packet.yiaddr, 0, sizeof ip -> client -> packet.yiaddr); memset (&ip -> client -> packet.siaddr, 0, sizeof ip -> client -> packet.siaddr); memset (&ip -> client -> packet.giaddr, 0, sizeof ip -> client -> packet.giaddr); memcpy (ip -> client -> packet.chaddr, ip -> hw_address.haddr, ip -> hw_address.hlen); #ifdef DEBUG_PACKET dump_packet (sendpkt); dump_raw ((unsigned char *)ip -> client -> packet, sendpkt->packet_length); #endif } void make_decline (ip, lease) struct interface_info *ip; struct client_lease *lease; { unsigned char decline = DHCPDECLINE; int i; struct tree_cache *options [256]; struct tree_cache message_type_tree; struct tree_cache requested_address_tree; struct tree_cache server_id_tree; struct tree_cache client_id_tree; memset (options, 0, sizeof options); memset (&ip -> client -> packet, 0, sizeof (ip -> client -> packet)); /* Set DHCP_MESSAGE_TYPE to DHCPDECLINE */ i = DHO_DHCP_MESSAGE_TYPE; options [i] = &message_type_tree; options [i] -> value = &decline; options [i] -> len = sizeof decline; options [i] -> buf_size = sizeof decline; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; /* Send back the server identifier... */ i = DHO_DHCP_SERVER_IDENTIFIER; options [i] = &server_id_tree; options [i] -> value = lease -> options [i].data; options [i] -> len = lease -> options [i].len; options [i] -> buf_size = lease -> options [i].len; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; /* Send back the address we're declining. */ i = DHO_DHCP_REQUESTED_ADDRESS; options [i] = &requested_address_tree; options [i] -> value = lease -> address.iabuf; options [i] -> len = lease -> address.len; options [i] -> buf_size = lease -> address.len; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; /* Send the uid if the user supplied one. */ i = DHO_DHCP_CLIENT_IDENTIFIER; if (ip -> client -> config -> send_options [i].len) { options [i] = &client_id_tree; options [i] -> value = ip -> client -> config -> send_options [i].data; options [i] -> len = ip -> client -> config -> send_options [i].len; options [i] -> buf_size = ip -> client -> config -> send_options [i].len; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; } /* Set up the option buffer... */ ip -> client -> packet_length = cons_options ((struct packet *)0, &ip -> client -> packet, 0, options, 0, 0, 0, (u_int8_t *)0, 0); if (ip -> client -> packet_length < BOOTP_MIN_LEN) ip -> client -> packet_length = BOOTP_MIN_LEN; ip -> client -> packet.op = BOOTREQUEST; ip -> client -> packet.htype = ip -> hw_address.htype; ip -> client -> packet.hlen = ip -> hw_address.hlen; ip -> client -> packet.hops = 0; ip -> client -> packet.xid = ip -> client -> xid; ip -> client -> packet.secs = 0; /* Filled in by send_request. */ ip -> client -> packet.flags = 0; /* ciaddr must always be zero. */ memset (&ip -> client -> packet.ciaddr, 0, sizeof ip -> client -> packet.ciaddr); memset (&ip -> client -> packet.yiaddr, 0, sizeof ip -> client -> packet.yiaddr); memset (&ip -> client -> packet.siaddr, 0, sizeof ip -> client -> packet.siaddr); memset (&ip -> client -> packet.giaddr, 0, sizeof ip -> client -> packet.giaddr); memcpy (ip -> client -> packet.chaddr, ip -> hw_address.haddr, ip -> hw_address.hlen); #ifdef DEBUG_PACKET dump_packet (sendpkt); dump_raw ((unsigned char *)ip -> client -> packet, sendpkt->packet_length); #endif } void make_release (ip, lease) struct interface_info *ip; struct client_lease *lease; { unsigned char request = DHCPRELEASE; int i; struct tree_cache *options [256]; struct tree_cache message_type_tree; struct tree_cache server_id_tree; memset (options, 0, sizeof options); memset (&ip -> client -> packet, 0, sizeof (ip -> client -> packet)); /* Set DHCP_MESSAGE_TYPE to DHCPRELEASE */ i = DHO_DHCP_MESSAGE_TYPE; options [i] = &message_type_tree; options [i] -> value = &request; options [i] -> len = sizeof request; options [i] -> buf_size = sizeof request; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; /* Send back the server identifier... */ i = DHO_DHCP_SERVER_IDENTIFIER; options [i] = &server_id_tree; options [i] -> value = lease -> options [i].data; options [i] -> len = lease -> options [i].len; options [i] -> buf_size = lease -> options [i].len; options [i] -> timeout = 0xFFFFFFFF; options [i] -> tree = (struct tree *)0; /* Set up the option buffer... */ ip -> client -> packet_length = cons_options ((struct packet *)0, &ip -> client -> packet, 0, options, 0, 0, 0, (u_int8_t *)0, 0); if (ip -> client -> packet_length < BOOTP_MIN_LEN) ip -> client -> packet_length = BOOTP_MIN_LEN; ip -> client -> packet.op = BOOTREQUEST; ip -> client -> packet.htype = ip -> hw_address.htype; ip -> client -> packet.hlen = ip -> hw_address.hlen; ip -> client -> packet.hops = 0; ip -> client -> packet.xid = random (); ip -> client -> packet.secs = 0; ip -> client -> packet.flags = 0; memset (&ip -> client -> packet.ciaddr, 0, sizeof ip -> client -> packet.ciaddr); memset (&ip -> client -> packet.yiaddr, 0, sizeof ip -> client -> packet.yiaddr); memset (&ip -> client -> packet.siaddr, 0, sizeof ip -> client -> packet.siaddr); memset (&ip -> client -> packet.giaddr, 0, sizeof ip -> client -> packet.giaddr); memcpy (ip -> client -> packet.chaddr, ip -> hw_address.haddr, ip -> hw_address.hlen); #ifdef DEBUG_PACKET dump_packet (sendpkt); dump_raw ((unsigned char *)ip -> client -> packet, ip -> client -> packet_length); #endif } void free_client_lease (lease) struct client_lease *lease; { int i; if (lease -> server_name) free (lease -> server_name); if (lease -> filename) free (lease -> filename); for (i = 0; i < 256; i++) { if (lease -> options [i].len) free (lease -> options [i].data); } free (lease); } FILE *leaseFile; void rewrite_client_leases () { struct interface_info *ip; struct client_lease *lp; if (leaseFile) fclose (leaseFile); leaseFile = fopen (path_dhclient_db, "w"); if (!leaseFile) error ("can't create %s: %m", path_dhclient_db); /* Write out all the leases attached to configured interfaces that we know about. */ for (ip = interfaces; ip; ip = ip -> next) { for (lp = ip -> client -> leases; lp; lp = lp -> next) { write_client_lease (ip, lp, 1); } if (ip -> client -> active) write_client_lease (ip, ip -> client -> active, 1); } /* Write out any leases that are attached to interfaces that aren't currently configured. */ for (ip = dummy_interfaces; ip; ip = ip -> next) { for (lp = ip -> client -> leases; lp; lp = lp -> next) { write_client_lease (ip, lp, 1); } if (ip -> client -> active) write_client_lease (ip, ip -> client -> active, 1); } fflush (leaseFile); } void write_client_lease (ip, lease, rewrite) struct interface_info *ip; struct client_lease *lease; int rewrite; { int i; struct tm *t; static int leases_written; if (!rewrite) { if (leases_written++ > 20) { rewrite_client_leases (); leases_written = 0; } } /* If the lease came from the config file, we don't need to stash a copy in the lease database. */ if (lease -> is_static) return; if (!leaseFile) { /* XXX */ leaseFile = fopen (path_dhclient_db, "w"); if (!leaseFile) error ("can't create %s: %m", path_dhclient_db); } fprintf (leaseFile, "lease {\n"); if (lease -> is_bootp) fprintf (leaseFile, " bootp;\n"); fprintf (leaseFile, " interface \"%s\";\n", ip -> name); fprintf (leaseFile, " fixed-address %s;\n", piaddr (lease -> address)); if (lease -> filename) fprintf (leaseFile, " filename \"%s\";\n", lease -> filename); if (lease -> server_name) fprintf (leaseFile, " server-name \"%s\";\n", lease -> filename); if (lease -> medium) fprintf (leaseFile, " medium \"%s\";\n", lease -> medium -> string); for (i = 0; i < 256; i++) { if (lease -> options [i].len) { fprintf (leaseFile, " option %s %s;\n", dhcp_options [i].name, pretty_print_option (i, lease -> options [i].data, lease -> options [i].len, 1, 1)); } } /* Note: the following is not a Y2K bug - it's a Y1.9K bug. Until somebody invents a time machine, I think we can safely disregard it. */ t = gmtime (&lease -> renewal); fprintf (leaseFile, " renew %d %d/%d/%d %02d:%02d:%02d;\n", t -> tm_wday, t -> tm_year + 1900, t -> tm_mon + 1, t -> tm_mday, t -> tm_hour, t -> tm_min, t -> tm_sec); t = gmtime (&lease -> rebind); fprintf (leaseFile, " rebind %d %d/%d/%d %02d:%02d:%02d;\n", t -> tm_wday, t -> tm_year + 1900, t -> tm_mon + 1, t -> tm_mday, t -> tm_hour, t -> tm_min, t -> tm_sec); t = gmtime (&lease -> expiry); fprintf (leaseFile, " expire %d %d/%d/%d %02d:%02d:%02d;\n", t -> tm_wday, t -> tm_year + 1900, t -> tm_mon + 1, t -> tm_mday, t -> tm_hour, t -> tm_min, t -> tm_sec); fprintf (leaseFile, "}\n"); fflush (leaseFile); } /* Variables holding name of script and file pointer for writing to script. Needless to say, this is not reentrant - only one script can be invoked at a time. */ char scriptName [256]; FILE *scriptFile; void script_init (ip, reason, medium) struct interface_info *ip; char *reason; struct string_list *medium; { int fd; #ifndef HAVE_MKSTEMP do { #endif strcpy (scriptName, "/tmp/dcsXXXXXX"); #ifdef HAVE_MKSTEMP fd = mkstemp (scriptName); #else if (!mktemp (scriptName)) error ("can't create temporary client script %s: %m", scriptName); fd = creat (scriptName, 0600); } while (fd < 0); #endif scriptFile = fdopen (fd, "w"); if (!scriptFile) error ("can't write script file: %m"); fprintf (scriptFile, "#!/bin/sh\n\n"); if (ip) { fprintf (scriptFile, "interface=\"%s\"\n", ip -> name); fprintf (scriptFile, "export interface\n"); } if (medium) { fprintf (scriptFile, "medium=\"%s\"\n", medium -> string); fprintf (scriptFile, "export medium\n"); } fprintf (scriptFile, "reason=\"%s\"\n", reason); fprintf (scriptFile, "export reason\n"); } void script_write_params (ip, prefix, lease) struct interface_info *ip; char *prefix; struct client_lease *lease; { int i; u_int8_t dbuf [1500]; int len; fprintf (scriptFile, "%sip_address=\"%s\"\n", prefix, piaddr (lease -> address)); fprintf (scriptFile, "export %sip_address\n", prefix); /* For the benefit of Linux (and operating systems which may have similar needs), compute the network address based on the supplied ip address and netmask, if provided. Also compute the broadcast address (the host address all ones broadcast address, not the host address all zeroes broadcast address). */ if (lease -> options [DHO_SUBNET_MASK].len && (lease -> options [DHO_SUBNET_MASK].len < sizeof lease -> address.iabuf)) { struct iaddr netmask, subnet, broadcast; memcpy (netmask.iabuf, lease -> options [DHO_SUBNET_MASK].data, lease -> options [DHO_SUBNET_MASK].len); netmask.len = lease -> options [DHO_SUBNET_MASK].len; subnet = subnet_number (lease -> address, netmask); if (subnet.len) { fprintf (scriptFile, "%snetwork_number=\"%s\";\n", prefix, piaddr (subnet)); fprintf (scriptFile, "export %snetwork_number\n", prefix); if (!lease -> options [DHO_BROADCAST_ADDRESS].len) { broadcast = broadcast_addr (subnet, netmask); if (broadcast.len) { fprintf (scriptFile, "%s%s=\"%s\";\n", prefix, "broadcast_address", piaddr (broadcast)); fprintf (scriptFile, "export %s%s\n", prefix, "broadcast_address"); } } } } if (lease -> filename) { fprintf (scriptFile, "%sfilename=\"%s\";\n", prefix, lease -> filename); fprintf (scriptFile, "export %sfilename\n", prefix); } if (lease -> server_name) { fprintf (scriptFile, "%sserver_name=\"%s\";\n", prefix, lease -> server_name); fprintf (scriptFile, "export %sserver_name\n", prefix); } for (i = 0; i < 256; i++) { u_int8_t *dp; if (ip -> client -> config -> defaults [i].len) { if (lease -> options [i].len) { switch (ip -> client -> config -> default_actions [i]) { case ACTION_DEFAULT: dp = lease -> options [i].data; len = lease -> options [i].len; break; case ACTION_SUPERSEDE: supersede: dp = ip -> client -> config -> defaults [i].data; len = ip -> client -> config -> defaults [i].len; break; case ACTION_PREPEND: len = (ip -> client -> config -> defaults [i].len + lease -> options [i].len); if (len > sizeof dbuf) { warn ("no space to %s %s", "prepend option", dhcp_options [i].name); goto supersede; } dp = dbuf; memcpy (dp, ip -> client -> config -> defaults [i].data, ip -> client -> config -> defaults [i].len); memcpy (dp + ip -> client -> config -> defaults [i].len, lease -> options [i].data, lease -> options [i].len); break; case ACTION_APPEND: len = (ip -> client -> config -> defaults [i].len + lease -> options [i].len); if (len > sizeof dbuf) { warn ("no space to %s %s", "append option", dhcp_options [i].name); goto supersede; } dp = dbuf; memcpy (dp, lease -> options [i].data, lease -> options [i].len); memcpy (dp + lease -> options [i].len, ip -> client -> config -> defaults [i].data, ip -> client -> config -> defaults [i].len); } } else { dp = ip -> client -> config -> defaults [i].data; len = ip -> client -> config -> defaults [i].len; } } else if (lease -> options [i].len) { len = lease -> options [i].len; dp = lease -> options [i].data; } else { len = 0; } if (len) { char *s = dhcp_option_ev_name (&dhcp_options [i]); fprintf (scriptFile, "%s%s=\"%s\"\n", prefix, s, pretty_print_option (i, dp, len, 0, 0)); fprintf (scriptFile, "export %s%s\n", prefix, s); } } fprintf (scriptFile, "%sexpiry=\"%d\"\n", prefix, (int)lease -> expiry); /* XXX */ fprintf (scriptFile, "export %sexpiry\n", prefix); } int script_go (ip) struct interface_info *ip; { int rval; if (ip) fprintf (scriptFile, "%s\n", ip -> client -> config -> script_name); else fprintf (scriptFile, "%s\n", top_level_config.script_name); fprintf (scriptFile, "exit $?\n"); fclose (scriptFile); chmod (scriptName, 0700); rval = system (scriptName); if (!save_scripts) unlink (scriptName); return rval; } char *dhcp_option_ev_name (option) struct option *option; { static char evbuf [256]; int i; if (strlen (option -> name) + 1 > sizeof evbuf) error ("option %s name is larger than static buffer."); for (i = 0; option -> name [i]; i++) { if (option -> name [i] == '-') evbuf [i] = '_'; else evbuf [i] = option -> name [i]; } evbuf [i] = 0; return evbuf; } void go_daemon () { static int state = 0; int pid; /* Don't become a daemon if the user requested otherwise. */ if (no_daemon) { write_client_pid_file (); return; } /* Only do it once. */ if (state) return; state = 1; /* Stop logging to stderr... */ log_perror = 0; /* Become a daemon... */ if ((pid = fork ()) < 0) error ("Can't fork daemon: %m"); else if (pid) exit (0); /* Become session leader and get pid... */ pid = setsid (); /* Close standard I/O descriptors. */ close(0); close(1); close(2); write_client_pid_file (); } void write_client_pid_file () { FILE *pf; int pfdesc; pfdesc = open (path_dhclient_pid, O_CREAT | O_TRUNC | O_WRONLY, 0644); if (pfdesc < 0) { warn ("Can't create %s: %m", path_dhclient_pid); return; } pf = fdopen (pfdesc, "w"); if (!pf) warn ("Can't fdopen %s: %m", path_dhclient_pid); else { fprintf (pf, "%ld\n", (long)getpid ()); fclose (pf); } }