/* dispatch.c Network input dispatcher... */ /* * Copyright (c) 1995, 1996 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: dispatch.c,v 1.1 1998/08/18 03:43:25 deraadt Exp $ Copyright (c) 1995, 1996 The Internet Software Consortium. All rights reserved.\n"; #endif /* not lint */ #include "dhcpd.h" #include struct interface_info *interfaces, *dummy_interfaces; struct protocol *protocols; struct timeout *timeouts; static struct timeout *free_timeouts; static int interfaces_invalidated; void (*bootp_packet_handler) PROTO ((struct interface_info *, unsigned char *, int, unsigned short, struct iaddr, struct hardware *)); static void got_one PROTO ((struct protocol *)); int quiet_interface_discovery; /* Use the SIOCGIFCONF ioctl to get a list of all the attached interfaces. For each interface that's of type INET and not the loopback interface, register that interface with the network I/O software, figure out what subnet it's on, and add it to the list of interfaces. */ void discover_interfaces (state) int state; { struct interface_info *tmp; struct interface_info *last, *next; char buf [8192]; struct ifconf ic; struct ifreq ifr; int i; int sock; int address_count = 0; struct subnet *subnet; struct shared_network *share; struct sockaddr_in foo; int ir; #ifdef ALIAS_NAMES_PERMUTED char *s; #endif #ifdef USE_FALLBACK static struct shared_network fallback_network; #endif /* Create an unbound datagram socket to do the SIOCGIFADDR ioctl on. */ if ((sock = socket (AF_INET, SOCK_DGRAM, IPPROTO_UDP)) < 0) error ("Can't create addrlist socket"); /* Get the interface configuration information... */ ic.ifc_len = sizeof buf; ic.ifc_ifcu.ifcu_buf = (caddr_t)buf; i = ioctl(sock, SIOCGIFCONF, &ic); if (i < 0) error ("ioctl: SIOCGIFCONF: %m"); /* If we already have a list of interfaces, and we're running as a DHCP server, the interfaces were requested. */ if (interfaces && (state == DISCOVER_SERVER || state == DISCOVER_RELAY || state == DISCOVER_REQUESTED)) ir = 0; else if (state == DISCOVER_UNCONFIGURED) ir = INTERFACE_REQUESTED | INTERFACE_AUTOMATIC; else ir = INTERFACE_REQUESTED; /* Cycle through the list of interfaces looking for IP addresses. Go through twice; once to count the number of addresses, and a second time to copy them into an array of addresses. */ for (i = 0; i < ic.ifc_len;) { struct ifreq *ifp = (struct ifreq *)((caddr_t)ic.ifc_req + i); #ifdef HAVE_SA_LEN if (ifp -> ifr_addr.sa_len) i += (sizeof ifp -> ifr_name) + ifp -> ifr_addr.sa_len; else #endif i += sizeof *ifp; #ifdef ALIAS_NAMES_PERMUTED if ((s = strrchr (ifp -> ifr_name, ':'))) { *s = 0; } #endif #ifdef SKIP_DUMMY_INTERFACES if (!strncmp (ifp -> ifr_name, "dummy", 5)) continue; #endif /* See if this is the sort of interface we want to deal with. */ strcpy (ifr.ifr_name, ifp -> ifr_name); if (ioctl (sock, SIOCGIFFLAGS, &ifr) < 0) error ("Can't get interface flags for %s: %m", ifr.ifr_name); /* Skip loopback, point-to-point and down interfaces, except don't skip down interfaces if we're trying to get a list of configurable interfaces. */ if ((ifr.ifr_flags & IFF_LOOPBACK) || #ifdef IFF_POINTOPOINT (ifr.ifr_flags & IFF_POINTOPOINT) || #endif (!(ifr.ifr_flags & IFF_UP) && state != DISCOVER_UNCONFIGURED)) continue; /* See if we've seen an interface that matches this one. */ for (tmp = interfaces; tmp; tmp = tmp -> next) if (!strcmp (tmp -> name, ifp -> ifr_name)) break; /* If there isn't already an interface by this name, allocate one. */ if (!tmp) { tmp = ((struct interface_info *) dmalloc (sizeof *tmp, "discover_interfaces")); if (!tmp) error ("Insufficient memory to %s %s", "record interface", ifp -> ifr_name); strcpy (tmp -> name, ifp -> ifr_name); tmp -> next = interfaces; tmp -> flags = ir; interfaces = tmp; } /* If we have the capability, extract link information and record it in a linked list. */ #ifdef AF_LINK if (ifp -> ifr_addr.sa_family == AF_LINK) { struct sockaddr_dl *foo = ((struct sockaddr_dl *) (&ifp -> ifr_addr)); tmp -> hw_address.hlen = foo -> sdl_alen; tmp -> hw_address.htype = HTYPE_ETHER; /* XXX */ memcpy (tmp -> hw_address.haddr, LLADDR (foo), foo -> sdl_alen); } else #endif /* AF_LINK */ if (ifp -> ifr_addr.sa_family == AF_INET) { struct iaddr addr; #if defined (SIOCGIFHWADDR) && !defined (AF_LINK) struct ifreq ifr; struct sockaddr sa; int b, sk; /* Read the hardware address from this interface. */ ifr = *ifp; if (ioctl (sock, SIOCGIFHWADDR, &ifr) < 0) error ("Can't get hardware address for %s: %m", ifr.ifr_name); sa = *(struct sockaddr *)&ifr.ifr_hwaddr; switch (sa.sa_family) { #ifdef ARPHRD_LOOPBACK case ARPHRD_LOOPBACK: /* ignore loopback interface */ break; #endif case ARPHRD_ETHER: tmp -> hw_address.hlen = 6; tmp -> hw_address.htype = ARPHRD_ETHER; memcpy (tmp -> hw_address.haddr, sa.sa_data, 6); break; #ifndef ARPHRD_IEEE802 # define ARPHRD_IEEE802 HTYPE_IEEE802 #endif case ARPHRD_IEEE802: tmp -> hw_address.hlen = 6; tmp -> hw_address.htype = ARPHRD_IEEE802; memcpy (tmp -> hw_address.haddr, sa.sa_data, 6); break; #ifdef ARPHRD_METRICOM case ARPHRD_METRICOM: tmp -> hw_address.hlen = 6; tmp -> hw_address.htype = ARPHRD_METRICOM; memcpy (tmp -> hw_address.haddr, sa.sa_data, 6); break; #endif default: error ("%s: unknown hardware address type %d", ifr.ifr_name, sa.sa_family); } #endif /* defined (SIOCGIFHWADDR) && !defined (AF_LINK) */ /* Get a pointer to the address... */ memcpy (&foo, &ifp -> ifr_addr, sizeof ifp -> ifr_addr); /* We don't want the loopback interface. */ if (foo.sin_addr.s_addr == htonl (INADDR_LOOPBACK)) continue; /* If this is the first real IP address we've found, keep a pointer to ifreq structure in which we found it. */ if (!tmp -> ifp) { struct ifreq *tif; #ifdef HAVE_SA_LEN int len = ((sizeof ifp -> ifr_name) + ifp -> ifr_addr.sa_len); #else int len = sizeof *ifp; #endif tif = (struct ifreq *)malloc (len); if (!tif) error ("no space to remember ifp."); memcpy (tif, ifp, len); tmp -> ifp = tif; tmp -> primary_address = foo.sin_addr; } /* Grab the address... */ addr.len = 4; memcpy (addr.iabuf, &foo.sin_addr.s_addr, addr.len); /* If there's a registered subnet for this address, connect it together... */ if ((subnet = find_subnet (addr))) { /* If this interface has multiple aliases on the same subnet, ignore all but the first we encounter. */ if (!subnet -> interface) { subnet -> interface = tmp; subnet -> interface_address = addr; } else if (subnet -> interface != tmp) { warn ("Multiple %s %s: %s %s", "interfaces match the", "same subnet", subnet -> interface -> name, tmp -> name); } share = subnet -> shared_network; if (tmp -> shared_network && tmp -> shared_network != share) { warn ("Interface %s matches %s", tmp -> name, "multiple shared networks"); } else { tmp -> shared_network = share; } if (!share -> interface) { share -> interface = tmp; } else if (share -> interface != tmp) { warn ("Multiple %s %s: %s %s", "interfaces match the", "same shared network", share -> interface -> name, tmp -> name); } } } } /* If we're just trying to get a list of interfaces that we might be able to configure, we can quit now. */ if (state == DISCOVER_UNCONFIGURED) return; /* Weed out the interfaces that did not have IP addresses. */ last = (struct interface_info *)0; for (tmp = interfaces; tmp; tmp = next) { next = tmp -> next; if ((tmp -> flags & INTERFACE_AUTOMATIC) && state == DISCOVER_REQUESTED) tmp -> flags &= ~(INTERFACE_AUTOMATIC | INTERFACE_REQUESTED); if (!tmp -> ifp || !(tmp -> flags & INTERFACE_REQUESTED)) { if ((tmp -> flags & INTERFACE_REQUESTED) != ir) error ("%s: not found", tmp -> name); if (!last) interfaces = interfaces -> next; else last -> next = tmp -> next; /* Remember the interface in case we need to know about it later. */ tmp -> next = dummy_interfaces; dummy_interfaces = tmp; continue; } last = tmp; memcpy (&foo, &tmp -> ifp -> ifr_addr, sizeof tmp -> ifp -> ifr_addr); /* We must have a subnet declaration for each interface. */ if (!tmp -> shared_network && (state == DISCOVER_SERVER)) error ("No subnet declaration for %s (%s).", tmp -> name, inet_ntoa (foo.sin_addr)); /* Find subnets that don't have valid interface addresses... */ for (subnet = (tmp -> shared_network ? tmp -> shared_network -> subnets : (struct subnet *)0); subnet; subnet = subnet -> next_sibling) { if (!subnet -> interface_address.len) { /* Set the interface address for this subnet to the first address we found. */ subnet -> interface_address.len = 4; memcpy (subnet -> interface_address.iabuf, &foo.sin_addr.s_addr, 4); } } /* Register the interface... */ if_register_receive (tmp); if_register_send (tmp); } /* Now register all the remaining interfaces as protocols. */ for (tmp = interfaces; tmp; tmp = tmp -> next) add_protocol (tmp -> name, tmp -> rfdesc, got_one, tmp); close (sock); #ifdef USE_FALLBACK strcpy (fallback_interface.name, "fallback"); fallback_interface.shared_network = &fallback_network; fallback_network.name = "fallback-net"; if_register_fallback (&fallback_interface); add_protocol ("fallback", fallback_interface.wfdesc, fallback_discard, &fallback_interface); #endif } void reinitialize_interfaces () { struct interface_info *ip; for (ip = interfaces; ip; ip = ip -> next) { if_reinitialize_receive (ip); if_reinitialize_send (ip); } #ifdef USE_FALLBACK if_reinitialize_fallback (&fallback_interface); #endif interfaces_invalidated = 1; } #ifdef USE_POLL /* Wait for packets to come in using poll(). Anyway, when a packet comes in, call receive_packet to receive the packet and possibly strip hardware addressing information from it, and then call do_packet to try to do something with it. As you can see by comparing this with the code that uses select(), below, this is gratuitously complex. Quelle surprise, eh? This is SysV we're talking about, after all, and even in the 90's, it wouldn't do for SysV to make networking *easy*, would it? Rant, rant... */ void dispatch () { struct protocol *l; int nfds = 0; struct pollfd *fds; int count; int i; int to_msec; nfds = 0; for (l = protocols; l; l = l -> next) { ++nfds; } fds = (struct pollfd *)malloc ((nfds) * sizeof (struct pollfd)); if (!fds) error ("Can't allocate poll structures."); do { /* Call any expired timeouts, and then if there's still a timeout registered, time out the select call then. */ another: if (timeouts) { struct timeout *t; if (timeouts -> when <= cur_time) { t = timeouts; timeouts = timeouts -> next; (*(t -> func)) (t -> what); t -> next = free_timeouts; free_timeouts = t; goto another; } /* Figure timeout in milliseconds, and check for potential overflow. We assume that integers are 32 bits, which is harmless if they're 64 bits - we'll just get extra timeouts in that case. Lease times would have to be quite long in order for a 32-bit integer to overflow, anyway. */ to_msec = timeouts -> when - cur_time; if (to_msec > 2147483) to_msec = 2147483; to_msec *= 1000; } else to_msec = -1; /* Set up the descriptors to be polled. */ i = 0; for (l = protocols; l; l = l -> next) { fds [i].fd = l -> fd; fds [i].events = POLLIN; fds [i].revents = 0; ++i; } /* Wait for a packet or a timeout... XXX */ count = poll (fds, nfds, to_msec); /* Get the current time... */ GET_TIME (&cur_time); /* Not likely to be transitory... */ if (count < 0) { if (errno == EAGAIN || errno == EINTR) continue; else error ("poll: %m"); } i = 0; for (l = protocols; l; l = l -> next) { if ((fds [i].revents & POLLIN)) { fds [i].revents = 0; if (l -> handler) (*(l -> handler)) (l); if (interfaces_invalidated) break; } ++i; } interfaces_invalidated = 0; } while (1); } #else /* Wait for packets to come in using select(). When one does, call receive_packet to receive the packet and possibly strip hardware addressing information from it, and then call do_packet to try to do something with it. */ void dispatch () { fd_set r, w, x; struct protocol *l; int max = 0; int count; struct timeval tv, *tvp; FD_ZERO (&w); FD_ZERO (&x); do { /* Call any expired timeouts, and then if there's still a timeout registered, time out the select call then. */ another: if (timeouts) { struct timeout *t; if (timeouts -> when <= cur_time) { t = timeouts; timeouts = timeouts -> next; (*(t -> func)) (t -> what); t -> next = free_timeouts; free_timeouts = t; goto another; } tv.tv_sec = timeouts -> when - cur_time; tv.tv_usec = 0; tvp = &tv; } else tvp = (struct timeval *)0; /* Set up the read mask. */ FD_ZERO (&r); for (l = protocols; l; l = l -> next) { FD_SET (l -> fd, &r); if (l -> fd > max) max = l -> fd; } /* Wait for a packet or a timeout... XXX */ count = select (max + 1, &r, &w, &x, tvp); /* Get the current time... */ GET_TIME (&cur_time); /* Not likely to be transitory... */ if (count < 0) error ("select: %m"); for (l = protocols; l; l = l -> next) { if (!FD_ISSET (l -> fd, &r)) continue; if (l -> handler) (*(l -> handler)) (l); if (interfaces_invalidated) break; } interfaces_invalidated = 0; } while (1); } #endif /* USE_POLL */ static void got_one (l) struct protocol *l; { struct sockaddr_in from; struct hardware hfrom; struct iaddr ifrom; int result; static unsigned char packbuf [4095]; /* Packet input buffer. Must be as large as largest possible MTU. */ struct interface_info *ip = l -> local; if ((result = receive_packet (ip, packbuf, sizeof packbuf, &from, &hfrom)) < 0) { warn ("receive_packet failed on %s: %m", ip -> name); return; } if (result == 0) return; if (bootp_packet_handler) { ifrom.len = 4; memcpy (ifrom.iabuf, &from.sin_addr, ifrom.len); (*bootp_packet_handler) (ip, packbuf, result, from.sin_port, ifrom, &hfrom); } } int locate_network (packet) struct packet *packet; { struct iaddr ia; /* If this came through a gateway, find the corresponding subnet... */ if (packet -> raw -> giaddr.s_addr) { struct subnet *subnet; ia.len = 4; memcpy (ia.iabuf, &packet -> raw -> giaddr, 4); subnet = find_subnet (ia); if (subnet) packet -> shared_network = subnet -> shared_network; else packet -> shared_network = (struct shared_network *)0; } else { packet -> shared_network = packet -> interface -> shared_network; } if (packet -> shared_network) return 1; return 0; } void add_timeout (when, where, what) TIME when; void (*where) PROTO ((void *)); void *what; { struct timeout *t, *q; /* See if this timeout supersedes an existing timeout. */ t = (struct timeout *)0; for (q = timeouts; q; q = q -> next) { if (q -> func == where && q -> what == what) { if (t) t -> next = q -> next; else timeouts = q -> next; break; } t = q; } /* If we didn't supersede a timeout, allocate a timeout structure now. */ if (!q) { if (free_timeouts) { q = free_timeouts; free_timeouts = q -> next; q -> func = where; q -> what = what; } else { q = (struct timeout *)malloc (sizeof (struct timeout)); if (!q) error ("Can't allocate timeout structure!"); q -> func = where; q -> what = what; } } q -> when = when; /* Now sort this timeout into the timeout list. */ /* Beginning of list? */ if (!timeouts || timeouts -> when > q -> when) { q -> next = timeouts; timeouts = q; return; } /* Middle of list? */ for (t = timeouts; t -> next; t = t -> next) { if (t -> next -> when > q -> when) { q -> next = t -> next; t -> next = q; return; } } /* End of list. */ t -> next = q; q -> next = (struct timeout *)0; } void cancel_timeout (where, what) void (*where) PROTO ((void *)); void *what; { struct timeout *t, *q; /* Look for this timeout on the list, and unlink it if we find it. */ t = (struct timeout *)0; for (q = timeouts; q; q = q -> next) { if (q -> func == where && q -> what == what) { if (t) t -> next = q -> next; else timeouts = q -> next; break; } t = q; } /* If we found the timeout, put it on the free list. */ if (q) { q -> next = free_timeouts; free_timeouts = q; } } /* Add a protocol to the list of protocols... */ void add_protocol (name, fd, handler, local) char *name; int fd; void (*handler) PROTO ((struct protocol *)); void *local; { struct protocol *p; p = (struct protocol *)malloc (sizeof *p); if (!p) error ("can't allocate protocol struct for %s", name); p -> fd = fd; p -> handler = handler; p -> local = local; p -> next = protocols; protocols = p; } void remove_protocol (proto) struct protocol *proto; { struct protocol *p, *next, *prev; prev = (struct protocol *)0; for (p = protocols; p; p = next) { next = p -> next; if (p == proto) { if (prev) prev -> next = p -> next; else protocols = p -> next; free (p); } } }