/* dhcp.c DHCP Protocol engine. */ /* * Copyright (c) 1995, 1996, 1997 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''. */ #ifndef lint static char copyright[] = "$Id: dhcp.c,v 1.1.1.2 1997/06/03 02:49:56 mellon Exp $ Copyright (c) 1995, 1996 The Internet Software Consortium. All rights reserved.\n"; #endif /* not lint */ #include "dhcpd.h" int outstanding_pings; static unsigned char dhcp_message [256]; void dhcp (packet) struct packet *packet; { if (!locate_network (packet) && packet -> packet_type != DHCPREQUEST) return; switch (packet -> packet_type) { case DHCPDISCOVER: dhcpdiscover (packet); break; case DHCPREQUEST: dhcprequest (packet); break; case DHCPRELEASE: dhcprelease (packet); break; case DHCPDECLINE: dhcpdecline (packet); break; case DHCPINFORM: dhcpinform (packet); break; default: break; } } void dhcpdiscover (packet) struct packet *packet; { struct lease *lease = find_lease (packet, packet -> shared_network); struct host_decl *hp; note ("DHCPDISCOVER from %s via %s", print_hw_addr (packet -> raw -> htype, packet -> raw -> hlen, packet -> raw -> chaddr), packet -> raw -> giaddr.s_addr ? inet_ntoa (packet -> raw -> giaddr) : packet -> interface -> name); /* Sourceless packets don't make sense here. */ if (!packet -> shared_network) { note ("Packet from unknown subnet: %s", inet_ntoa (packet -> raw -> giaddr)); return; } /* If we didn't find a lease, try to allocate one... */ if (!lease) { lease = packet -> shared_network -> last_lease; /* If there are no leases in that subnet that have expired, we have nothing to offer this client. */ if (!lease || lease -> ends > cur_time) { note ("no free leases on subnet %s", packet -> shared_network -> name); return; } /* Try to find a host_decl that matches the client identifier or hardware address on the packet, and has no fixed IP address. If there is one, hang it off the lease so that its option definitions can be used. */ if (((packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].len != 0) && ((hp = find_hosts_by_uid (packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].data, packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].len)) != (struct host_decl *)0)) || ((hp = find_hosts_by_haddr (packet -> raw -> htype, packet -> raw -> chaddr, packet -> raw -> hlen)) != (struct host_decl *)0)) { for (; hp; hp = hp -> n_ipaddr) { if (!hp -> fixed_addr) { lease -> host = hp; break; } } } else { lease -> host = (struct host_decl *)0; } } /* If this subnet won't boot unknown clients, ignore the request. */ if (!lease -> host && !lease -> subnet -> group -> boot_unknown_clients) { note ("Ignoring unknown client %s", print_hw_addr (packet -> raw -> htype, packet -> raw -> hlen, packet -> raw -> chaddr)); } else if (lease -> host && !lease -> host -> group -> allow_booting) { note ("Declining to boot client %s", lease -> host -> name); } else ack_lease (packet, lease, DHCPOFFER, cur_time + 120); } void dhcprequest (packet) struct packet *packet; { struct lease *lease; struct iaddr cip; struct subnet *subnet; if (packet -> options [DHO_DHCP_REQUESTED_ADDRESS].len) { cip.len = 4; memcpy (cip.iabuf, packet -> options [DHO_DHCP_REQUESTED_ADDRESS].data, 4); } else { cip.len = 4; memcpy (cip.iabuf, &packet -> raw -> ciaddr.s_addr, 4); } subnet = find_subnet (cip); /* Find the lease that matches the address requested by the client. */ if (subnet) lease = find_lease (packet, subnet -> shared_network); else lease = (struct lease *)0; note ("DHCPREQUEST for %s from %s via %s", piaddr (cip), print_hw_addr (packet -> raw -> htype, packet -> raw -> hlen, packet -> raw -> chaddr), packet -> raw -> giaddr.s_addr ? inet_ntoa (packet -> raw -> giaddr) : packet -> interface -> name); /* If a client on a given network REQUESTs a lease on an address on a different network, NAK it. If the Requested Address option was used, the protocol says that it must have been broadcast, so we can trust the source network information. If ciaddr was specified and Requested Address was not, then we really only know for sure what network a packet came from if it came through a BOOTP gateway - if it came through an IP router, we'll just have to assume that it's cool. If we don't think we know where the packet came from, it came through a gateway from an unknown network, so it's not from a RENEWING client. If we recognize the network it *thinks* it's on, we can NAK it even though we don't recognize the network it's *actually* on; otherwise we just have to ignore it. We don't currently try to take advantage of access to the raw packet, because it's not available on all platforms. So a packet that was unicast to us through a router from a RENEWING client is going to look exactly like a packet that was broadcast to us from an INIT-REBOOT client. Since we can't tell the difference between these two kinds of packets, if the packet appears to have come in off the local wire, we have to treat it as if it's a RENEWING client. This means that we can't NAK a RENEWING client on the local wire that has a bogus address. The good news is that we won't ACK it either, so it should revert to INIT state and send us a DHCPDISCOVER, which we *can* work with. Because we can't detect that a RENEWING client is on the wrong wire, it's going to sit there trying to renew until it gets to the REBIND state, when we *can* NAK it because the packet will get to us through a BOOTP gateway. We shouldn't actually see DHCPREQUEST packets from RENEWING clients on the wrong wire anyway, since their idea of their local router will be wrong. In any case, the protocol doesn't really allow us to NAK a DHCPREQUEST from a RENEWING client, so we can punt on this issue. */ if (!packet -> shared_network || (packet -> raw -> ciaddr.s_addr && packet -> raw -> giaddr.s_addr) || packet -> options [DHO_DHCP_REQUESTED_ADDRESS].len) { /* If we don't know where it came from but we do know where it claims to have come from, it didn't come from there. Fry it. */ if (!packet -> shared_network) { if (subnet) { nak_lease (packet, &cip); return; } /* Otherwise, ignore it. */ return; } /* If we do know where it came from and it asked for an address that is not on that shared network, nak it. */ subnet = find_grouped_subnet (packet -> shared_network, cip); if (!subnet) { nak_lease (packet, &cip); return; } } /* If we found a lease for the client but it's not the one the client asked for, don't send it - some other server probably made the cut. */ if (lease && !addr_eq (lease -> ip_addr, cip)) { return; } /* If we own the lease that the client is asking for, and it's already been assigned to the client, ack it. */ if (lease && ((lease -> uid_len && lease -> uid_len == packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].len && !memcmp (packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].data, lease -> uid, lease -> uid_len)) || (lease -> hardware_addr.hlen == packet -> raw -> hlen && lease -> hardware_addr.htype == packet -> raw -> htype && !memcmp (lease -> hardware_addr.haddr, packet -> raw -> chaddr, packet -> raw -> hlen)))) { ack_lease (packet, lease, DHCPACK, 0); return; } } void dhcprelease (packet) struct packet *packet; { struct lease *lease = find_lease (packet, packet -> shared_network); note ("DHCPRELEASE of %s from %s via %s", inet_ntoa (packet -> raw -> ciaddr), print_hw_addr (packet -> raw -> htype, packet -> raw -> hlen, packet -> raw -> chaddr), packet -> raw -> giaddr.s_addr ? inet_ntoa (packet -> raw -> giaddr) : packet -> interface -> name); /* If we found a lease, release it. */ if (lease) { release_lease (lease); } } void dhcpdecline (packet) struct packet *packet; { struct lease *lease = find_lease (packet, packet -> shared_network); struct iaddr cip; if (packet -> options [DHO_DHCP_REQUESTED_ADDRESS].len) { cip.len = 4; memcpy (cip.iabuf, packet -> options [DHO_DHCP_REQUESTED_ADDRESS].data, 4); } else { cip.len = 0; } note ("DHCPDECLINE on %s from %s via %s", piaddr (cip), print_hw_addr (packet -> raw -> htype, packet -> raw -> hlen, packet -> raw -> chaddr), packet -> raw -> giaddr.s_addr ? inet_ntoa (packet -> raw -> giaddr) : packet -> interface -> name); /* If we found a lease, mark it as unusable and complain. */ if (lease) { abandon_lease (lease, "declined."); } } void dhcpinform (packet) struct packet *packet; { note ("DHCPINFORM from %s", inet_ntoa (packet -> raw -> ciaddr)); } void nak_lease (packet, cip) struct packet *packet; struct iaddr *cip; { struct sockaddr_in to; struct in_addr from; int result; struct dhcp_packet raw; unsigned char nak = DHCPNAK; struct packet outgoing; struct hardware hto; struct tree_cache *options [256]; struct tree_cache dhcpnak_tree; struct tree_cache dhcpmsg_tree; memset (options, 0, sizeof options); memset (&outgoing, 0, sizeof outgoing); memset (&raw, 0, sizeof raw); outgoing.raw = &raw; /* Set DHCP_MESSAGE_TYPE to DHCPNAK */ options [DHO_DHCP_MESSAGE_TYPE] = &dhcpnak_tree; options [DHO_DHCP_MESSAGE_TYPE] -> value = &nak; options [DHO_DHCP_MESSAGE_TYPE] -> len = sizeof nak; options [DHO_DHCP_MESSAGE_TYPE] -> buf_size = sizeof nak; options [DHO_DHCP_MESSAGE_TYPE] -> timeout = 0xFFFFFFFF; options [DHO_DHCP_MESSAGE_TYPE] -> tree = (struct tree *)0; /* Set DHCP_MESSAGE to whatever the message is */ options [DHO_DHCP_MESSAGE] = &dhcpmsg_tree; options [DHO_DHCP_MESSAGE] -> value = dhcp_message; options [DHO_DHCP_MESSAGE] -> len = strlen (dhcp_message); options [DHO_DHCP_MESSAGE] -> buf_size = strlen (dhcp_message); options [DHO_DHCP_MESSAGE] -> timeout = 0xFFFFFFFF; options [DHO_DHCP_MESSAGE] -> tree = (struct tree *)0; /* Do not use the client's requested parameter list. */ packet -> options [DHO_DHCP_PARAMETER_REQUEST_LIST].len = 0; packet -> options [DHO_DHCP_PARAMETER_REQUEST_LIST].data = (unsigned char *)0; /* Set up the option buffer... */ outgoing.packet_length = cons_options (packet, outgoing.raw, options, 0, 0); /* memset (&raw.ciaddr, 0, sizeof raw.ciaddr);*/ raw.siaddr = packet -> interface -> primary_address; raw.giaddr = packet -> raw -> giaddr; memcpy (raw.chaddr, packet -> raw -> chaddr, sizeof raw.chaddr); raw.hlen = packet -> raw -> hlen; raw.htype = packet -> raw -> htype; raw.xid = packet -> raw -> xid; raw.secs = packet -> raw -> secs; raw.flags = packet -> raw -> flags | htons (BOOTP_BROADCAST); raw.hops = packet -> raw -> hops; raw.op = BOOTREPLY; /* Report what we're sending... */ note ("DHCPNAK on %s to %s via %s", piaddr (*cip), print_hw_addr (packet -> raw -> htype, packet -> raw -> hlen, packet -> raw -> chaddr), packet -> raw -> giaddr.s_addr ? inet_ntoa (packet -> raw -> giaddr) : packet -> interface -> name); #ifdef DEBUG_PACKET dump_packet (packet); dump_raw ((unsigned char *)packet -> raw, packet -> packet_length); dump_packet (&outgoing); dump_raw ((unsigned char *)&raw, outgoing.packet_length); #endif hto.htype = packet -> raw -> htype; hto.hlen = packet -> raw -> hlen; memcpy (hto.haddr, packet -> raw -> chaddr, hto.hlen); /* Set up the common stuff... */ to.sin_family = AF_INET; #ifdef HAVE_SA_LEN to.sin_len = sizeof to; #endif memset (to.sin_zero, 0, sizeof to.sin_zero); from = packet -> interface -> primary_address; /* Make sure that the packet is at least as big as a BOOTP packet. */ if (outgoing.packet_length < BOOTP_MIN_LEN) outgoing.packet_length = BOOTP_MIN_LEN; /* If this was gatewayed, send it back to the gateway. Otherwise, broadcast it on the local network. */ if (raw.giaddr.s_addr) { to.sin_addr = raw.giaddr; to.sin_port = local_port; #ifdef USE_FALLBACK result = send_fallback (&fallback_interface, packet, &raw, outgoing.packet_length, from, &to, &hto); if (result < 0) warn ("send_fallback: %m"); return; #endif } else { to.sin_addr.s_addr = htonl (INADDR_BROADCAST); to.sin_port = remote_port; } errno = 0; result = send_packet (packet -> interface, packet, &raw, outgoing.packet_length, from, &to, (struct hardware *)0); if (result < 0) warn ("send_packet: %m"); } void ack_lease (packet, lease, offer, when) struct packet *packet; struct lease *lease; unsigned char offer; TIME when; { struct lease lt; struct lease_state *state; TIME lease_time; TIME offered_lease_time; struct class *vendor_class, *user_class; int i; /* If we're already acking this lease, don't do it again. */ if (lease -> state) { note ("already acking lease %s", piaddr (lease -> ip_addr)); return; } /* Allocate a lease state structure... */ state = new_lease_state ("ack_lease"); if (!state) error ("unable to allocate lease state!"); memset (state, 0, sizeof *state); if (packet -> options [DHO_DHCP_CLASS_IDENTIFIER].len) { vendor_class = find_class (0, packet -> options [DHO_DHCP_CLASS_IDENTIFIER].data, packet -> options [DHO_DHCP_CLASS_IDENTIFIER].len); } else { vendor_class = (struct class *)0; } if (packet -> options [DHO_DHCP_USER_CLASS_ID].len) { user_class = find_class (1, packet -> options [DHO_DHCP_USER_CLASS_ID].data, packet -> options [DHO_DHCP_USER_CLASS_ID].len); } else { user_class = (struct class *)0; } /* Replace the old lease hostname with the new one, if it's changed. */ if (packet -> options [DHO_HOST_NAME].len && lease -> client_hostname && (strlen (lease -> client_hostname) == packet -> options [DHO_HOST_NAME].len) && !memcmp (lease -> client_hostname, packet -> options [DHO_HOST_NAME].data, packet -> options [DHO_HOST_NAME].len)) { } else if (packet -> options [DHO_HOST_NAME].len) { if (lease -> client_hostname) free (lease -> client_hostname); lease -> client_hostname = malloc (packet -> options [DHO_HOST_NAME].len + 1); if (!lease -> client_hostname) error ("no memory for client hostname.\n"); memcpy (lease -> client_hostname, packet -> options [DHO_HOST_NAME].data, packet -> options [DHO_HOST_NAME].len); lease -> client_hostname [packet -> options [DHO_HOST_NAME].len] = 0; } else if (lease -> client_hostname) { free (lease -> client_hostname); lease -> client_hostname = 0; } /* Choose a filename; first from the host_decl, if any, then from the user class, then from the vendor class. */ if (lease -> host && lease -> host -> group -> filename) state -> filename = lease -> host -> group -> filename; else if (user_class && user_class -> group -> filename) state -> filename = user_class -> group -> filename; else if (vendor_class && vendor_class -> group -> filename) state -> filename = vendor_class -> group -> filename; else state -> filename = (char *)0; /* Choose a server name as above. */ if (lease -> host && lease -> host -> group -> server_name) state -> server_name = lease -> host -> group -> server_name; else if (user_class && user_class -> group -> server_name) state -> server_name = user_class -> group -> server_name; else if (vendor_class && vendor_class -> group -> server_name) state -> server_name = vendor_class -> group -> server_name; else state -> server_name = (char *)0; /* At this point, we have a lease that we can offer the client. Now we construct a lease structure that contains what we want, and call supersede_lease to do the right thing with it. */ memset (<, 0, sizeof lt); /* Use the ip address of the lease that we finally found in the database. */ lt.ip_addr = lease -> ip_addr; /* Start now. */ lt.starts = cur_time; /* Figure out how long a lease to assign. If this is a dynamic BOOTP lease, its duration must be infinite. */ if (offer) { if (packet -> options [DHO_DHCP_LEASE_TIME].len == 4) { lease_time = getULong (packet -> options [DHO_DHCP_LEASE_TIME].data); /* Don't let the client ask for a longer lease than is supported for this subnet or host. */ if (lease -> host && lease -> host -> group -> max_lease_time) { if (lease_time > lease -> host -> group -> max_lease_time) lease_time = (lease -> host -> group -> max_lease_time); } else { if (lease_time > lease -> subnet -> group -> max_lease_time) lease_time = (lease -> subnet -> group -> max_lease_time); } } else { if (lease -> host && lease -> host -> group -> default_lease_time) lease_time = (lease -> host -> group -> default_lease_time); else lease_time = (lease -> subnet -> group -> default_lease_time); } state -> offered_expiry = cur_time + lease_time; if (when) lt.ends = when; else lt.ends = state -> offered_expiry; } else { if (lease -> host && lease -> host -> group -> bootp_lease_length) lt.ends = (cur_time + lease -> host -> group -> bootp_lease_length); else if (lease -> subnet -> group -> bootp_lease_length) lt.ends = (cur_time + lease -> subnet -> group -> bootp_lease_length); else if (lease -> host && lease -> host -> group -> bootp_lease_cutoff) lt.ends = lease -> host -> group -> bootp_lease_cutoff; else lt.ends = (lease -> subnet -> group -> bootp_lease_cutoff); state -> offered_expiry = lt.ends; lt.flags = BOOTP_LEASE; } lt.timestamp = cur_time; /* Record the uid, if given... */ i = DHO_DHCP_CLIENT_IDENTIFIER; if (packet -> options [i].len) { if (packet -> options [i].len <= sizeof lt.uid_buf) { memcpy (lt.uid_buf, packet -> options [i].data, packet -> options [i].len); lt.uid = lt.uid_buf; lt.uid_max = sizeof lt.uid_buf; lt.uid_len = packet -> options [i].len; } else { lt.uid_max = lt.uid_len = packet -> options [i].len; lt.uid = (unsigned char *)malloc (lt.uid_max); if (!lt.uid) error ("can't allocate memory for large uid."); memcpy (lt.uid, packet -> options [i].data, lt.uid_len); } } /* Record the hardware address, if given... */ lt.hardware_addr.hlen = packet -> raw -> hlen; lt.hardware_addr.htype = packet -> raw -> htype; memcpy (lt.hardware_addr.haddr, packet -> raw -> chaddr, packet -> raw -> hlen); lt.host = lease -> host; lt.subnet = lease -> subnet; lt.shared_network = lease -> shared_network; /* Don't call supersede_lease on a mocked-up lease. */ if (lease -> flags & STATIC_LEASE) ; else /* Install the new information about this lease in the database. If this is a DHCPACK or a dynamic BOOTREPLY and we can't write the lease, don't ACK it (or BOOTREPLY it) either. */ if (!(supersede_lease (lease, <, !offer || offer == DHCPACK) || (offer && offer != DHCPACK))) return; /* Remember the interface on which the packet arrived. */ state -> ip = packet -> interface; /* Set a flag if this client is a lame Microsoft client that NUL terminates string options and expects us to do likewise. */ if (packet -> options [DHO_HOST_NAME].data && packet -> options [DHO_HOST_NAME].data [packet -> options [DHO_HOST_NAME].len - 1] == '\0') lease -> flags |= MS_NULL_TERMINATION; else lease -> flags &= ~MS_NULL_TERMINATION; /* Remember the giaddr, xid, secs, flags and hops. */ state -> giaddr = packet -> raw -> giaddr; state -> ciaddr = packet -> raw -> ciaddr; state -> xid = packet -> raw -> xid; state -> secs = packet -> raw -> secs; state -> bootp_flags = packet -> raw -> flags; state -> hops = packet -> raw -> hops; state -> offer = offer; /* Figure out what options to send to the client: */ /* Start out with the subnet options... */ memcpy (state -> options, lease -> subnet -> group -> options, sizeof state -> options); /* Vendor and user classes are only supported for DHCP clients. */ if (state -> offer) { /* If we have a vendor class, install those options, superseding any subnet options. */ if (vendor_class) { for (i = 0; i < 256; i++) if (vendor_class -> group -> options [i]) state -> options [i] = (vendor_class -> group -> options [i]); } /* If we have a user class, install those options, superseding any subnet and vendor class options. */ if (user_class) { for (i = 0; i < 256; i++) if (user_class -> group -> options [i]) state -> options [i] = (user_class -> group -> options [i]); } } /* If we have a host_decl structure, install the associated options, superseding anything that's in the way. */ if (lease -> host) { for (i = 0; i < 256; i++) if (lease -> host -> group -> options [i]) state -> options [i] = (lease -> host -> group -> options [i]); } /* If we didn't get a hostname from an option somewhere, see if we can get one from the lease. */ i = DHO_HOST_NAME; if (!state -> options [i] && lease -> hostname) { state -> options [i] = new_tree_cache ("hostname"); state -> options [i] -> flags = TC_TEMPORARY; state -> options [i] -> value = (unsigned char *)lease -> hostname; state -> options [i] -> len = strlen (lease -> hostname); state -> options [i] -> buf_size = state -> options [i] -> len; state -> options [i] -> timeout = 0xFFFFFFFF; state -> options [i] -> tree = (struct tree *)0; } /* Now, if appropriate, put in DHCP-specific options that override those. */ if (state -> offer) { i = DHO_DHCP_MESSAGE_TYPE; state -> options [i] = new_tree_cache ("message-type"); state -> options [i] -> flags = TC_TEMPORARY; state -> options [i] -> value = &state -> offer; state -> options [i] -> len = sizeof state -> offer; state -> options [i] -> buf_size = sizeof state -> offer; state -> options [i] -> timeout = 0xFFFFFFFF; state -> options [i] -> tree = (struct tree *)0; i = DHO_DHCP_SERVER_IDENTIFIER; state -> options [i] = new_tree_cache ("server-id"); state -> options [i] -> value = (unsigned char *)&state -> ip -> primary_address; state -> options [i] -> len = sizeof state -> ip -> primary_address; state -> options [i] -> buf_size = state -> options [i] -> len; state -> options [i] -> timeout = 0xFFFFFFFF; state -> options [i] -> tree = (struct tree *)0; /* Sanity check the lease time. */ if ((state -> offered_expiry - cur_time) < 15) offered_lease_time = (lease -> subnet -> group -> default_lease_time); else if (state -> offered_expiry - cur_time > lease -> subnet -> group -> max_lease_time) offered_lease_time = (lease -> subnet -> group -> max_lease_time); else offered_lease_time = state -> offered_expiry - cur_time; putULong ((unsigned char *)&state -> expiry, offered_lease_time); i = DHO_DHCP_LEASE_TIME; state -> options [i] = new_tree_cache ("lease-expiry"); state -> options [i] -> flags = TC_TEMPORARY; state -> options [i] -> value = (unsigned char *)&state -> expiry; state -> options [i] -> len = sizeof state -> expiry; state -> options [i] -> buf_size = sizeof state -> expiry; state -> options [i] -> timeout = 0xFFFFFFFF; state -> options [i] -> tree = (struct tree *)0; /* Renewal time is lease time * 0.5. */ offered_lease_time /= 2; putULong ((unsigned char *)&state -> renewal, offered_lease_time); i = DHO_DHCP_RENEWAL_TIME; state -> options [i] = new_tree_cache ("renewal-time"); state -> options [i] -> flags = TC_TEMPORARY; state -> options [i] -> value = (unsigned char *)&state -> renewal; state -> options [i] -> len = sizeof state -> renewal; state -> options [i] -> buf_size = sizeof state -> renewal; state -> options [i] -> timeout = 0xFFFFFFFF; state -> options [i] -> tree = (struct tree *)0; /* Rebinding time is lease time * 0.875. */ offered_lease_time += (offered_lease_time / 2 + offered_lease_time / 4); putULong ((unsigned char *)&state -> rebind, offered_lease_time); i = DHO_DHCP_REBINDING_TIME; state -> options [i] = new_tree_cache ("rebind-time"); state -> options [i] -> flags = TC_TEMPORARY; state -> options [i] -> value = (unsigned char *)&state -> rebind; state -> options [i] -> len = sizeof state -> rebind; state -> options [i] -> buf_size = sizeof state -> rebind; state -> options [i] -> timeout = 0xFFFFFFFF; state -> options [i] -> tree = (struct tree *)0; /* If we used the vendor class the client specified, we have to return it. */ if (vendor_class) { i = DHO_DHCP_CLASS_IDENTIFIER; state -> options [i] = new_tree_cache ("class-identifier"); state -> options [i] -> flags = TC_TEMPORARY; state -> options [i] -> value = (unsigned char *)vendor_class -> name; state -> options [i] -> len = strlen (vendor_class -> name); state -> options [i] -> buf_size = state -> options [i] -> len; state -> options [i] -> timeout = 0xFFFFFFFF; state -> options [i] -> tree = (struct tree *)0; } /* If we used the user class the client specified, we have to return it. */ if (user_class) { i = DHO_DHCP_USER_CLASS_ID; state -> options [i] = new_tree_cache ("user-class"); state -> options [i] -> flags = TC_TEMPORARY; state -> options [i] -> value = (unsigned char *)user_class -> name; state -> options [i] -> len = strlen (user_class -> name); state -> options [i] -> buf_size = state -> options [i] -> len; state -> options [i] -> timeout = 0xFFFFFFFF; state -> options [i] -> tree = (struct tree *)0; } } /* Use the subnet mask from the subnet declaration if no other mask has been provided. */ i = DHO_SUBNET_MASK; if (!state -> options [i]) { state -> options [i] = new_tree_cache ("subnet-mask"); state -> options [i] -> flags = TC_TEMPORARY; state -> options [i] -> value = lease -> subnet -> netmask.iabuf; state -> options [i] -> len = lease -> subnet -> netmask.len; state -> options [i] -> buf_size = lease -> subnet -> netmask.len; state -> options [i] -> timeout = 0xFFFFFFFF; state -> options [i] -> tree = (struct tree *)0; } #ifdef DEBUG_PACKET dump_packet (packet); dump_raw ((unsigned char *)packet -> raw, packet -> packet_length); #endif lease -> state = state; /* If this is a DHCPOFFER, ping the lease address before actually sending the offer. */ if (offer == DHCPOFFER) { icmp_echorequest (&lease -> ip_addr); add_timeout (cur_time + 1, lease_ping_timeout, lease); ++outstanding_pings; } else { dhcp_reply (lease); } } void dhcp_reply (lease) struct lease *lease; { int bufs = 0; int packet_length; struct dhcp_packet raw; struct sockaddr_in to; struct in_addr from; struct hardware hto; int result; int i; struct lease_state *state = lease -> state; if (!state) error ("dhcp_reply was supplied lease with no state!"); /* Compose a response for the client... */ memset (&raw, 0, sizeof raw); /* Copy in the filename if given; otherwise, flag the filename buffer as available for options. */ if (state -> filename) strncpy (raw.file, state -> filename, sizeof raw.file); else bufs |= 1; /* Copy in the server name if given; otherwise, flag the server_name buffer as available for options. */ if (state -> server_name) strncpy (raw.sname, state -> server_name, sizeof raw.sname); else bufs |= 2; /* XXX */ memcpy (raw.chaddr, lease -> hardware_addr.haddr, lease -> hardware_addr.hlen); raw.hlen = lease -> hardware_addr.hlen; raw.htype = lease -> hardware_addr.htype; /* See if this is a Microsoft client that NUL-terminates its strings and expects us to do likewise... */ if (lease -> flags & MS_NULL_TERMINATION) packet_length = cons_options ((struct packet *)0, &raw, state -> options, bufs, 1); else packet_length = cons_options ((struct packet *)0, &raw, state -> options, bufs, 0); /* Having done the cons_options(), we can release the tree_cache entries. */ for (i = 0; i < 256; i++) { if (state -> options [i] && state -> options [i] -> flags & TC_TEMPORARY) free_tree_cache (state -> options [i], "dhcp_reply"); } memcpy (&raw.ciaddr, &state -> ciaddr, sizeof raw.ciaddr); memcpy (&raw.yiaddr, lease -> ip_addr.iabuf, 4); /* Figure out the address of the next server. */ if (lease -> host && lease -> host -> group -> next_server.len) memcpy (&raw.siaddr, lease -> host -> group -> next_server.iabuf, 4); else if (lease -> subnet -> group -> next_server.len) memcpy (&raw.siaddr, lease -> subnet -> group -> next_server.iabuf, 4); else if (lease -> subnet -> interface_address.len) memcpy (&raw.siaddr, lease -> subnet -> interface_address.iabuf, 4); else raw.siaddr = state -> ip -> primary_address; raw.giaddr = state -> giaddr; raw.xid = state -> xid; raw.secs = state -> secs; raw.flags = state -> bootp_flags; raw.hops = state -> hops; raw.op = BOOTREPLY; /* Say what we're doing... */ note ("%s on %s to %s via %s", (state -> offer ? (state -> offer == DHCPACK ? "DHCPACK" : "DHCPOFFER") : "BOOTREPLY"), piaddr (lease -> ip_addr), print_hw_addr (lease -> hardware_addr.htype, lease -> hardware_addr.hlen, lease -> hardware_addr.haddr), state -> giaddr.s_addr ? inet_ntoa (state -> giaddr) : state -> ip -> name); /* Set up the hardware address... */ hto.htype = lease -> hardware_addr.htype; hto.hlen = lease -> hardware_addr.hlen; memcpy (hto.haddr, lease -> hardware_addr.haddr, hto.hlen); to.sin_family = AF_INET; #ifdef HAVE_SA_LEN to.sin_len = sizeof to; #endif memset (to.sin_zero, 0, sizeof to.sin_zero); from = state -> ip -> primary_address; #ifdef DEBUG_PACKET dump_raw ((unsigned char *)&raw, packet_length); #endif /* Make sure outgoing packets are at least as big as a BOOTP packet. */ if (packet_length < BOOTP_MIN_LEN) packet_length = BOOTP_MIN_LEN; /* If this was gatewayed, send it back to the gateway... */ if (raw.giaddr.s_addr) { to.sin_addr = raw.giaddr; to.sin_port = local_port; #ifdef USE_FALLBACK result = send_fallback (&fallback_interface, (struct packet *)0, &raw, packet_length, raw.siaddr, &to, &hto); if (result < 0) warn ("send_fallback: %m"); free_lease_state (state, "dhcp_reply fallback 1"); lease -> state = (struct lease_state *)0; return; #endif /* If it comes from a client who already knows its address and is not requesting a broadcast response, sent it directly to that client. */ } else if (raw.ciaddr.s_addr && state -> offer == DHCPACK && !(raw.flags & htons (BOOTP_BROADCAST))) { to.sin_addr = state -> ciaddr; to.sin_port = remote_port; /* XXX */ #ifdef USE_FALLBACK result = send_fallback (&fallback_interface, (struct packet *)0, &raw, packet_length, raw.siaddr, &to, &hto); if (result < 0) warn ("send_fallback: %m"); free_lease_state (state, "dhcp_reply fallback 1"); lease -> state = (struct lease_state *)0; return; #endif /* Otherwise, broadcast it on the local network. */ } else { to.sin_addr.s_addr = htonl (INADDR_BROADCAST); to.sin_port = remote_port; /* XXX */ } result = send_packet (state -> ip, (struct packet *)0, &raw, packet_length, raw.siaddr, &to, &hto); if (result < 0) warn ("sendpkt: %m"); free_lease_state (state, "dhcp_reply"); lease -> state = (struct lease_state *)0; } struct lease *find_lease (packet, share) struct packet *packet; struct shared_network *share; { struct lease *uid_lease, *ip_lease, *hw_lease; struct lease *lease = (struct lease *)0; struct iaddr cip; struct host_decl *hp, *host = (struct host_decl *)0; struct lease *fixed_lease; /* Try to find a host or lease that's been assigned to the specified unique client identifier. */ if (packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].len) { /* First, try to find a fixed host entry for the specified client identifier... */ hp = find_hosts_by_uid (packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].data, packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].len); if (hp) { host = hp; fixed_lease = mockup_lease (packet, share, hp); uid_lease = (struct lease *)0; } else { uid_lease = find_lease_by_uid (packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].data, packet -> options [DHO_DHCP_CLIENT_IDENTIFIER].len); /* Find the lease matching this uid that's on the network the packet came from (if any). */ for (; uid_lease; uid_lease = uid_lease -> n_uid) if (uid_lease -> shared_network == share) break; fixed_lease = (struct lease *)0; if (uid_lease && (uid_lease -> flags & ABANDONED_LEASE)) uid_lease = (struct lease *)0; } } else { uid_lease = (struct lease *)0; fixed_lease = (struct lease *)0; } /* If we didn't find a fixed lease using the uid, try doing it with the hardware address... */ if (!fixed_lease) { hp = find_hosts_by_haddr (packet -> raw -> htype, packet -> raw -> chaddr, packet -> raw -> hlen); if (hp) { host = hp; /* Save it for later. */ fixed_lease = mockup_lease (packet, share, hp); } } /* Try to find a lease that's been attached to the client's hardware address... */ hw_lease = find_lease_by_hw_addr (packet -> raw -> chaddr, packet -> raw -> hlen); /* Find the lease that's on the network the packet came from (if any). */ for (; hw_lease; hw_lease = hw_lease -> n_hw) if (hw_lease -> shared_network == share) break; if (hw_lease && (hw_lease -> flags & ABANDONED_LEASE)) hw_lease = (struct lease *)0; /* Try to find a lease that's been allocated to the client's IP address. */ if (packet -> options [DHO_DHCP_REQUESTED_ADDRESS].len && packet -> options [DHO_DHCP_REQUESTED_ADDRESS].len == 4) { cip.len = 4; memcpy (cip.iabuf, packet -> options [DHO_DHCP_REQUESTED_ADDRESS].data, cip.len); ip_lease = find_lease_by_ip_addr (cip); } else if (packet -> raw -> ciaddr.s_addr) { cip.len = 4; memcpy (cip.iabuf, &packet -> raw -> ciaddr, 4); ip_lease = find_lease_by_ip_addr (cip); } else ip_lease = (struct lease *)0; /* If the requested IP address isn't on the network the packet came from, or if it's been abandoned, don't use it. */ if (ip_lease && (ip_lease -> shared_network != share || (ip_lease -> flags & ABANDONED_LEASE))) ip_lease = (struct lease *)0; /* Toss ip_lease if it hasn't yet expired and the uid doesn't match */ if (ip_lease && ip_lease -> ends >= cur_time && ip_lease -> uid && ip_lease != uid_lease) ip_lease = (struct lease *)0; /* Toss hw_lease if it hasn't yet expired and the uid doesn't match, except that if the hardware address matches and the client is now doing dynamic BOOTP (and thus hasn't provided a uid) we let the client get away with it. */ if (hw_lease && hw_lease -> ends >= cur_time && hw_lease -> uid && hw_lease != uid_lease && (packet -> packet_type != 0 || !(hw_lease -> flags & DYNAMIC_BOOTP_OK))) hw_lease = (struct lease *)0; /* Toss extra pointers to the same lease... */ if (ip_lease == hw_lease) ip_lease = (struct lease *)0; if (hw_lease == uid_lease) hw_lease = (struct lease *)0; if (ip_lease == uid_lease) ip_lease = (struct lease *)0; /* If we got an ip address lease, make sure it isn't assigned to some *other* client! If it was assigned to this client, we'd have zeroed it out above, so the only way we can take it at this point is if some other client had it but it's timed out, or if no other client has ever had it. */ if (ip_lease && ip_lease -> ends >= cur_time) ip_lease = (struct lease *)0; /* If we've already eliminated the lease, it wasn't there to begin with. If we have come up with a matching lease, set the message to bad network in case we have to throw it out. */ if (!ip_lease && !hw_lease && !uid_lease) { strcpy (dhcp_message, "requested address not available"); } else { strcpy (dhcp_message, "requested address on bad subnet"); } /* Now eliminate leases that are on the wrong network... */ if (ip_lease && (share != ip_lease -> shared_network)) { release_lease (ip_lease); ip_lease = (struct lease *)0; } if (uid_lease && (share != uid_lease -> shared_network)) { release_lease (uid_lease); uid_lease = (struct lease *)0; } if (hw_lease && (share != hw_lease -> shared_network)) { release_lease (hw_lease); hw_lease = (struct lease *)0; } /* At this point, if fixed_lease is nonzero, we can assign it to this client. */ if (fixed_lease) { lease = fixed_lease; } /* If we got a lease that matched the ip address and don't have a better offer, use that; otherwise, release it. */ if (ip_lease) { if (lease) { release_lease (ip_lease); } else { lease = ip_lease; lease -> host = (struct host_decl *)0; } } /* If we got a lease that matched the client identifier, we may want to use it, but if we already have a lease we like, we must free the lease that matched the client identifier. */ if (uid_lease) { if (lease) { release_lease (uid_lease); } else { lease = uid_lease; lease -> host = (struct host_decl *)0; } } /* The lease that matched the hardware address is treated likewise. */ if (hw_lease) { if (lease) { release_lease (hw_lease); } else { lease = hw_lease; lease -> host = (struct host_decl *)0; } } /* If we found a host_decl but no matching address, try to find a host_decl that has no address, and if there is one, hang it off the lease so that we can use the supplied options. */ if (lease && host && !lease -> host) { for (; host; host = host -> n_ipaddr) { if (!host -> fixed_addr) { lease -> host = host; break; } } } return lease; } /* Search the provided host_decl structure list for an address that's on the specified shared network. If one is found, mock up and return a lease structure for it; otherwise return the null pointer. */ struct lease *mockup_lease (packet, share, hp) struct packet *packet; struct shared_network *share; struct host_decl *hp; { static struct lease mock; mock.subnet = find_host_for_network (&hp, &mock.ip_addr, share); if (!mock.subnet) return (struct lease *)0; mock.next = mock.prev = (struct lease *)0; mock.shared_network = mock.subnet -> shared_network; mock.host = hp; if (hp -> group -> options [DHO_DHCP_CLIENT_IDENTIFIER]) { mock.uid = hp -> group -> options [DHO_DHCP_CLIENT_IDENTIFIER] -> value; mock.uid_len = hp -> group -> options [DHO_DHCP_CLIENT_IDENTIFIER] -> len; } else { mock.uid = (unsigned char *)0; mock.uid_len = 0; } mock.hardware_addr = hp -> interface; mock.starts = mock.timestamp = mock.ends = MIN_TIME; mock.flags = STATIC_LEASE; return &mock; }