/* $OpenBSD: memory.c,v 1.29 2020/04/06 17:05:40 krw Exp $ */ /* * Copyright (c) 1995, 1996, 1997, 1998 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''. */ #include #include #include #include #include #include #include #include #include "dhcp.h" #include "tree.h" #include "dhcpd.h" #include "log.h" #include "sync.h" struct subnet *subnets; static struct shared_network *shared_networks; static struct hash_table *host_hw_addr_hash; static struct hash_table *host_uid_hash; static struct hash_table *lease_uid_hash; static struct hash_table *lease_ip_addr_hash; static struct hash_table *lease_hw_addr_hash; static struct lease *dangling_leases; static struct hash_table *vendor_class_hash; static struct hash_table *user_class_hash; extern int syncsend; void enter_host(struct host_decl *hd) { struct host_decl *hp = NULL, *np = NULL; hd->n_ipaddr = NULL; if (hd->interface.hlen) { if (!host_hw_addr_hash) host_hw_addr_hash = new_hash(); else hp = (struct host_decl *)hash_lookup(host_hw_addr_hash, hd->interface.haddr, hd->interface.hlen); /* * If there isn't already a host decl matching this * address, add it to the hash table. */ if (!hp) add_hash(host_hw_addr_hash, hd->interface.haddr, hd->interface.hlen, (unsigned char *)hd); } /* * If there was already a host declaration for this hardware * address, add this one to the end of the list. */ if (hp) { for (np = hp; np->n_ipaddr; np = np->n_ipaddr) ; np->n_ipaddr = hd; } if (hd->group->options[DHO_DHCP_CLIENT_IDENTIFIER]) { if (!tree_evaluate( hd->group->options[DHO_DHCP_CLIENT_IDENTIFIER])) return; /* If there's no uid hash, make one; otherwise, see if there's already an entry in the hash for this host. */ if (!host_uid_hash) { host_uid_hash = new_hash(); hp = NULL; } else hp = (struct host_decl *)hash_lookup(host_uid_hash, hd->group->options[DHO_DHCP_CLIENT_IDENTIFIER]->value, hd->group->options[DHO_DHCP_CLIENT_IDENTIFIER]->len); /* * If there's already a host declaration for this * client identifier, add this one to the end of the * list. Otherwise, add it to the hash table. */ if (hp) { /* Don't link it in twice... */ if (!np) { for (np = hp; np->n_ipaddr; np = np->n_ipaddr) ; np->n_ipaddr = hd; } } else { add_hash(host_uid_hash, hd->group->options[DHO_DHCP_CLIENT_IDENTIFIER]->value, hd->group->options[DHO_DHCP_CLIENT_IDENTIFIER]->len, (unsigned char *)hd); } } } struct host_decl * find_hosts_by_haddr(int htype, unsigned char *haddr, int hlen) { return (struct host_decl *)hash_lookup(host_hw_addr_hash, haddr, hlen); } struct host_decl * find_hosts_by_uid(unsigned char *data, int len) { return (struct host_decl *)hash_lookup(host_uid_hash, data, len); } /* * More than one host_decl can be returned by find_hosts_by_haddr or * find_hosts_by_uid, and each host_decl can have multiple addresses. * Loop through the list of hosts, and then for each host, through the * list of addresses, looking for an address that's in the same shared * network as the one specified. Store the matching address through * the addr pointer, update the host pointer to point at the host_decl * that matched, and return the subnet that matched. */ struct subnet * find_host_for_network(struct host_decl **host, struct iaddr *addr, struct shared_network *share) { struct subnet *subnet; struct iaddr ip_address; struct host_decl *hp; int i; for (hp = *host; hp; hp = hp->n_ipaddr) { if (!hp->fixed_addr || !tree_evaluate(hp->fixed_addr)) continue; for (i = 0; i < hp->fixed_addr->len; i += 4) { ip_address.len = 4; memcpy(ip_address.iabuf, hp->fixed_addr->value + i, 4); subnet = find_grouped_subnet(share, ip_address); if (subnet) { *addr = ip_address; *host = hp; return subnet; } } } return NULL; } void new_address_range(struct iaddr low, struct iaddr high, struct subnet *subnet, int dynamic) { struct lease *address_range, *lp, *plp; struct iaddr net; int min, max, i; char lowbuf[16], highbuf[16], netbuf[16]; struct shared_network *share = subnet->shared_network; struct hostent *h; struct in_addr ia; /* All subnets should have attached shared network structures. */ if (!share) { strlcpy(netbuf, piaddr(subnet->net), sizeof(netbuf)); fatalx("No shared network for network %s (%s)", netbuf, piaddr(subnet->netmask)); } /* Initialize the hash table if it hasn't been done yet. */ if (!lease_uid_hash) lease_uid_hash = new_hash(); if (!lease_ip_addr_hash) lease_ip_addr_hash = new_hash(); if (!lease_hw_addr_hash) lease_hw_addr_hash = new_hash(); /* Make sure that high and low addresses are in same subnet. */ net = subnet_number(low, subnet->netmask); if (!addr_eq(net, subnet_number(high, subnet->netmask))) { strlcpy(lowbuf, piaddr(low), sizeof(lowbuf)); strlcpy(highbuf, piaddr(high), sizeof(highbuf)); strlcpy(netbuf, piaddr(subnet->netmask), sizeof(netbuf)); fatalx("Address range %s to %s, netmask %s spans %s!", lowbuf, highbuf, netbuf, "multiple subnets"); } /* Make sure that the addresses are on the correct subnet. */ if (!addr_eq(net, subnet->net)) { strlcpy(lowbuf, piaddr(low), sizeof(lowbuf)); strlcpy(highbuf, piaddr(high), sizeof(highbuf)); strlcpy(netbuf, piaddr(subnet->netmask), sizeof(netbuf)); fatalx("Address range %s to %s not on net %s/%s!", lowbuf, highbuf, piaddr(subnet->net), netbuf); } /* Get the high and low host addresses... */ max = host_addr(high, subnet->netmask); min = host_addr(low, subnet->netmask); /* Allow range to be specified high-to-low as well as low-to-high. */ if (min > max) { max = min; min = host_addr(high, subnet->netmask); } /* Get a lease structure for each address in the range. */ address_range = calloc(max - min + 1, sizeof(struct lease)); if (!address_range) { strlcpy(lowbuf, piaddr(low), sizeof(lowbuf)); strlcpy(highbuf, piaddr(high), sizeof(highbuf)); fatalx("No memory for address range %s-%s.", lowbuf, highbuf); } memset(address_range, 0, (sizeof *address_range) * (max - min + 1)); /* Fill in the last lease if it hasn't been already... */ if (!share->last_lease) share->last_lease = &address_range[0]; /* Fill out the lease structures with some minimal information. */ for (i = 0; i < max - min + 1; i++) { address_range[i].ip_addr = ip_addr(subnet->net, subnet->netmask, i + min); address_range[i].starts = address_range[i].timestamp = MIN_TIME; address_range[i].ends = MIN_TIME; address_range[i].subnet = subnet; address_range[i].shared_network = share; address_range[i].flags = dynamic ? DYNAMIC_BOOTP_OK : 0; memcpy(&ia, address_range[i].ip_addr.iabuf, 4); if (subnet->group->get_lease_hostnames) { h = gethostbyaddr((char *)&ia, sizeof ia, AF_INET); if (!h) log_warnx("No hostname for %s", inet_ntoa(ia)); else { address_range[i].hostname = strdup(h->h_name); if (address_range[i].hostname == NULL) fatalx("no memory for hostname %s.", h->h_name); } } /* Link this entry into the list. */ address_range[i].next = share->leases; address_range[i].prev = NULL; share->leases = &address_range[i]; if (address_range[i].next) address_range[i].next->prev = share->leases; add_hash(lease_ip_addr_hash, address_range[i].ip_addr.iabuf, address_range[i].ip_addr.len, (unsigned char *)&address_range[i]); } /* Find out if any dangling leases are in range... */ plp = NULL; for (lp = dangling_leases; lp; lp = lp->next) { struct iaddr lnet; int lhost; lnet = subnet_number(lp->ip_addr, subnet->netmask); lhost = host_addr(lp->ip_addr, subnet->netmask); /* If it's in range, fill in the real lease structure with the dangling lease's values, and remove the lease from the list of dangling leases. */ if (addr_eq(lnet, subnet->net) && lhost >= i && lhost <= max) { if (plp) { plp->next = lp->next; } else { dangling_leases = lp->next; } lp->next = NULL; address_range[lhost - i].hostname = lp->hostname; address_range[lhost - i].client_hostname = lp->client_hostname; supersede_lease(&address_range[lhost - i], lp, 0); free(lp); return; } else plp = lp; } } struct subnet * find_subnet(struct iaddr addr) { struct subnet *rv; for (rv = subnets; rv; rv = rv->next_subnet) { if (addr_eq(subnet_number(addr, rv->netmask), rv->net)) return rv; } return NULL; } struct subnet * find_grouped_subnet(struct shared_network *share, struct iaddr addr) { struct subnet *rv; for (rv = share->subnets; rv; rv = rv->next_sibling) { if (addr_eq(subnet_number(addr, rv->netmask), rv->net)) return rv; } return NULL; } int subnet_inner_than(struct subnet *subnet, struct subnet *scan, int warnp) { if (addr_eq(subnet_number(subnet->net, scan->netmask), scan->net) || addr_eq(subnet_number(scan->net, subnet->netmask), subnet->net)) { char n1buf[16]; int i, j; for (i = 0; i < 32; i++) if (subnet->netmask.iabuf[3 - (i >> 3)] & (1 << (i & 7))) break; for (j = 0; j < 32; j++) if (scan->netmask.iabuf[3 - (j >> 3)] & (1 << (j & 7))) break; strlcpy(n1buf, piaddr(subnet->net), sizeof(n1buf)); if (warnp) log_warnx("%ssubnet %s/%d conflicts with subnet %s/%d", "Warning: ", n1buf, 32 - i, piaddr(scan->net), 32 - j); if (i < j) return 1; } return 0; } /* Enter a new subnet into the subnet list. */ void enter_subnet(struct subnet *subnet) { struct subnet *scan, *prev = NULL; /* Check for duplicates... */ for (scan = subnets; scan; scan = scan->next_subnet) { /* * When we find a conflict, make sure that the * subnet with the narrowest subnet mask comes * first. */ if (subnet_inner_than(subnet, scan, 1)) { if (prev) { prev->next_subnet = subnet; } else subnets = subnet; subnet->next_subnet = scan; return; } prev = scan; } /* XXX use the BSD radix tree code instead of a linked list. */ subnet->next_subnet = subnets; subnets = subnet; } /* Enter a new shared network into the shared network list. */ void enter_shared_network(struct shared_network *share) { /* XXX Sort the nets into a balanced tree to make searching quicker. */ share->next = shared_networks; shared_networks = share; } /* * Enter a lease into the system. This is called by the parser each * time it reads in a new lease. If the subnet for that lease has * already been read in (usually the case), just update that lease; * otherwise, allocate temporary storage for the lease and keep it around * until we're done reading in the config file. */ void enter_lease(struct lease *lease) { struct lease *comp = find_lease_by_ip_addr(lease->ip_addr); /* If we don't have a place for this lease yet, save it for later. */ if (!comp) { comp = calloc(1, sizeof(struct lease)); if (!comp) fatalx("No memory for lease %s\n", piaddr(lease->ip_addr)); *comp = *lease; comp->next = dangling_leases; comp->prev = NULL; dangling_leases = comp; } else { /* Record the hostname information in the lease. */ comp->hostname = lease->hostname; comp->client_hostname = lease->client_hostname; supersede_lease(comp, lease, 0); } } static inline int hwaddrcmp(struct hardware *a, struct hardware *b) { return ((a->htype != b->htype) || (a->hlen != b->hlen) || memcmp(a->haddr, b->haddr, b->hlen)); } static inline int uidcmp(struct lease *a, struct lease *b) { return (a->uid_len != b->uid_len || memcmp(a->uid, b->uid, b->uid_len)); } static inline int uid_or_hwaddr_cmp(struct lease *a, struct lease *b) { if (a->uid && b->uid) return uidcmp(a, b); return hwaddrcmp(&a->hardware_addr, &b->hardware_addr); } /* * Replace the data in an existing lease with the data in a new lease; * adjust hash tables to suit, and insertion sort the lease into the * list of leases by expiry time so that we can always find the oldest * lease. */ int supersede_lease(struct lease *comp, struct lease *lease, int commit) { int enter_uid = 0; int enter_hwaddr = 0; int do_pftable = 0; struct lease *lp; /* Static leases are not currently kept in the database... */ if (lease->flags & STATIC_LEASE) return 1; /* * If the existing lease hasn't expired and has a different * unique identifier or, if it doesn't have a unique * identifier, a different hardware address, then the two * leases are in conflict. If the existing lease has a uid * and the new one doesn't, but they both have the same * hardware address, and dynamic bootp is allowed on this * lease, then we allow that, in case a dynamic BOOTP lease is * requested *after* a DHCP lease has been assigned. */ if (!(lease->flags & ABANDONED_LEASE) && comp->ends > cur_time && uid_or_hwaddr_cmp(comp, lease)) { log_warnx("Lease conflict at %s", piaddr(comp->ip_addr)); return 0; } else { /* If there's a Unique ID, dissociate it from the hash table and free it if necessary. */ if (comp->uid) { uid_hash_delete(comp); enter_uid = 1; if (comp->uid != &comp->uid_buf[0]) { if (comp->uid != lease->uid) free(comp->uid); comp->uid_max = 0; comp->uid_len = 0; } comp->uid = NULL; } else enter_uid = 1; if (comp->hardware_addr.htype && hwaddrcmp(&comp->hardware_addr, &lease->hardware_addr)) { hw_hash_delete(comp); enter_hwaddr = 1; do_pftable = 1; } else if (!comp->hardware_addr.htype) { enter_hwaddr = 1; do_pftable = 1; } /* Copy the data files, but not the linkages. */ comp->starts = lease->starts; if (lease->uid) { if (lease->uid_len <= sizeof (lease->uid_buf)) { memcpy(comp->uid_buf, lease->uid, lease->uid_len); comp->uid = &comp->uid_buf[0]; comp->uid_max = sizeof comp->uid_buf; } else if (lease->uid != &lease->uid_buf[0]) { comp->uid = lease->uid; comp->uid_max = lease->uid_max; lease->uid = NULL; lease->uid_max = 0; } else { fatalx("corrupt lease uid."); /* XXX */ } } else { comp->uid = NULL; comp->uid_max = 0; } comp->uid_len = lease->uid_len; comp->host = lease->host; comp->hardware_addr = lease->hardware_addr; comp->flags = ((lease->flags & ~PERSISTENT_FLAGS) | (comp->flags & ~EPHEMERAL_FLAGS)); /* Record the lease in the uid hash if necessary. */ if (enter_uid && lease->uid) uid_hash_add(comp); /* Record it in the hardware address hash if necessary. */ if (enter_hwaddr && lease->hardware_addr.htype) hw_hash_add(comp); /* Remove the lease from its current place in the timeout sequence. */ if (comp->prev) comp->prev->next = comp->next; else comp->shared_network->leases = comp->next; if (comp->next) comp->next->prev = comp->prev; if (comp->shared_network->last_lease == comp) comp->shared_network->last_lease = comp->prev; /* Find the last insertion point... */ if (comp == comp->shared_network->insertion_point || !comp->shared_network->insertion_point) lp = comp->shared_network->leases; else lp = comp->shared_network->insertion_point; if (!lp) { /* Nothing on the list yet? Just make comp the head of the list. */ comp->shared_network->leases = comp; comp->shared_network->last_lease = comp; } else if (lp->ends > lease->ends) { /* Skip down the list until we run out of list or find a place for comp. */ while (lp->next && lp->ends > lease->ends) { lp = lp->next; } if (lp->ends > lease->ends) { /* If we ran out of list, put comp at the end. */ lp->next = comp; comp->prev = lp; comp->next = NULL; comp->shared_network->last_lease = comp; } else { /* If we didn't, put it between lp and the previous item on the list. */ if ((comp->prev = lp->prev)) comp->prev->next = comp; comp->next = lp; lp->prev = comp; } } else { /* Skip up the list until we run out of list or find a place for comp. */ while (lp->prev && lp->ends < lease->ends) { lp = lp->prev; } if (lp->ends < lease->ends) { /* If we ran out of list, put comp at the beginning. */ lp->prev = comp; comp->next = lp; comp->prev = NULL; comp->shared_network->leases = comp; } else { /* If we didn't, put it between lp and the next item on the list. */ if ((comp->next = lp->next)) comp->next->prev = comp; comp->prev = lp; lp->next = comp; } } comp->shared_network->insertion_point = comp; comp->ends = lease->ends; } pfmsg('L', lease); /* address is leased. remove from purgatory */ if (do_pftable) /* address changed hwaddr. remove from overload */ pfmsg('C', lease); /* Return zero if we didn't commit the lease to permanent storage; nonzero if we did. */ return commit && write_lease(comp) && commit_leases(); } /* Release the specified lease and re-hash it as appropriate. */ void release_lease(struct lease *lease) { struct lease lt; lt = *lease; if (lt.ends > cur_time) { lt.ends = cur_time; supersede_lease(lease, <, 1); log_info("Released lease for IP address %s", piaddr(lease->ip_addr)); pfmsg('R', lease); } } /* * Abandon the specified lease for the specified time. sets it's * particulars to zero, the end time appropriately and re-hash it as * appropriate. abandons permanently if abtime is 0 */ void abandon_lease(struct lease *lease, char *message) { struct lease lt; time_t abtime; abtime = lease->subnet->group->default_lease_time; lease->flags |= ABANDONED_LEASE; lt = *lease; lt.ends = cur_time + abtime; log_warnx("Abandoning IP address %s for %lld seconds: %s", piaddr(lease->ip_addr), (long long)abtime, message); lt.hardware_addr.htype = 0; lt.hardware_addr.hlen = 0; lt.uid = NULL; lt.uid_len = 0; supersede_lease(lease, <, 1); pfmsg('A', lease); /* address is abandoned. send to purgatory */ return; } /* Locate the lease associated with a given IP address... */ struct lease * find_lease_by_ip_addr(struct iaddr addr) { return (struct lease *)hash_lookup(lease_ip_addr_hash, addr.iabuf, addr.len); } struct lease *find_lease_by_uid(unsigned char *uid, int len) { return (struct lease *)hash_lookup(lease_uid_hash, uid, len); } struct lease * find_lease_by_hw_addr(unsigned char *hwaddr, int hwlen) { return (struct lease *)hash_lookup(lease_hw_addr_hash, hwaddr, hwlen); } /* Add the specified lease to the uid hash. */ void uid_hash_add(struct lease *lease) { struct lease *head = find_lease_by_uid(lease->uid, lease->uid_len); struct lease *scan; /* If it's not in the hash, just add it. */ if (!head) add_hash(lease_uid_hash, lease->uid, lease->uid_len, (unsigned char *)lease); else { /* Otherwise, attach it to the end of the list. */ for (scan = head; scan->n_uid; scan = scan->n_uid) ; scan->n_uid = lease; } } /* Delete the specified lease from the uid hash. */ void uid_hash_delete(struct lease *lease) { struct lease *head = find_lease_by_uid(lease->uid, lease->uid_len); struct lease *scan; /* If it's not in the hash, we have no work to do. */ if (!head) { lease->n_uid = NULL; return; } /* If the lease we're freeing is at the head of the list, remove the hash table entry and add a new one with the next lease on the list (if there is one). */ if (head == lease) { delete_hash_entry(lease_uid_hash, lease->uid, lease->uid_len); if (lease->n_uid) add_hash(lease_uid_hash, lease->n_uid->uid, lease->n_uid->uid_len, (unsigned char *)(lease->n_uid)); } else { /* Otherwise, look for the lease in the list of leases attached to the hash table entry, and remove it if we find it. */ for (scan = head; scan->n_uid; scan = scan->n_uid) { if (scan->n_uid == lease) { scan->n_uid = scan->n_uid->n_uid; break; } } } lease->n_uid = NULL; } /* Add the specified lease to the hardware address hash. */ void hw_hash_add(struct lease *lease) { struct lease *head = find_lease_by_hw_addr(lease->hardware_addr.haddr, lease->hardware_addr.hlen); struct lease *scan; /* If it's not in the hash, just add it. */ if (!head) add_hash(lease_hw_addr_hash, lease->hardware_addr.haddr, lease->hardware_addr.hlen, (unsigned char *)lease); else { /* Otherwise, attach it to the end of the list. */ for (scan = head; scan->n_hw; scan = scan->n_hw) ; scan->n_hw = lease; } } /* Delete the specified lease from the hardware address hash. */ void hw_hash_delete(struct lease *lease) { struct lease *head = find_lease_by_hw_addr(lease->hardware_addr.haddr, lease->hardware_addr.hlen); struct lease *scan; /* If it's not in the hash, we have no work to do. */ if (!head) { lease->n_hw = NULL; return; } /* If the lease we're freeing is at the head of the list, remove the hash table entry and add a new one with the next lease on the list (if there is one). */ if (head == lease) { delete_hash_entry(lease_hw_addr_hash, lease->hardware_addr.haddr, lease->hardware_addr.hlen); if (lease->n_hw) add_hash(lease_hw_addr_hash, lease->n_hw->hardware_addr.haddr, lease->n_hw->hardware_addr.hlen, (unsigned char *)(lease->n_hw)); } else { /* * Otherwise, look for the lease in the list of leases * attached to the hash table entry, and remove it if * we find it. */ for (scan = head; scan->n_hw; scan = scan->n_hw) { if (scan->n_hw == lease) { scan->n_hw = scan->n_hw->n_hw; break; } } } lease->n_hw = NULL; } struct class * add_class(int type, char *name) { struct class *class; char *tname; class = calloc(1, sizeof(*class)); tname = strdup(name); if (!vendor_class_hash) vendor_class_hash = new_hash(); if (!user_class_hash) user_class_hash = new_hash(); if (!tname || !class || !vendor_class_hash || !user_class_hash) { log_warnx("No memory for %s.", name); free(class); free(tname); return NULL; } class->name = tname; if (type) add_hash(user_class_hash, (unsigned char *)tname, strlen(tname), (unsigned char *)class); else add_hash(vendor_class_hash, (unsigned char *)tname, strlen(tname), (unsigned char *)class); return class; } struct class * find_class(int type, unsigned char *name, int len) { return (struct class *)hash_lookup(type ? user_class_hash : vendor_class_hash, name, len); } struct group * clone_group(struct group *group, char *caller) { struct group *g; g = calloc(1, sizeof(struct group)); if (!g) fatalx("%s: can't allocate new group", caller); *g = *group; return g; } /* Write all interesting leases to permanent storage. */ void write_leases(void) { struct lease *l; struct shared_network *s; for (s = shared_networks; s; s = s->next) { for (l = s->leases; l; l = l->next) { if (l->hardware_addr.hlen || l->uid_len || (l->flags & ABANDONED_LEASE)) { if (!write_lease(l)) fatalx("Can't rewrite lease database"); if (syncsend) sync_lease(l); } } } if (!commit_leases()) fatal("Can't commit leases to new database"); }