/** * Copyright (C) 2017 Hans Dedecker * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License v2 as published by * the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include "odhcpd.h" struct event_socket { struct odhcpd_event ev; struct nl_sock *sock; int sock_bufsize; }; static void handle_rtnl_event(struct odhcpd_event *ev); static int cb_rtnl_valid(struct nl_msg *msg, void *arg); static void catch_rtnl_err(struct odhcpd_event *e, int error); static struct nl_sock *create_socket(int protocol); static struct nl_sock *rtnl_socket = NULL; struct list_head netevent_handler_list = LIST_HEAD_INIT(netevent_handler_list); static struct event_socket rtnl_event = { .ev = { .uloop = {.fd = - 1, }, .handle_dgram = NULL, .handle_error = catch_rtnl_err, .recv_msgs = handle_rtnl_event, }, .sock = NULL, .sock_bufsize = 133120, }; int netlink_init(void) { rtnl_socket = create_socket(NETLINK_ROUTE); if (!rtnl_socket) { syslog(LOG_ERR, "Unable to open nl socket: %m"); goto err; } rtnl_event.sock = create_socket(NETLINK_ROUTE); if (!rtnl_event.sock) { syslog(LOG_ERR, "Unable to open nl event socket: %m"); goto err; } rtnl_event.ev.uloop.fd = nl_socket_get_fd(rtnl_event.sock); if (nl_socket_set_buffer_size(rtnl_event.sock, rtnl_event.sock_bufsize, 0)) goto err; nl_socket_disable_seq_check(rtnl_event.sock); nl_socket_modify_cb(rtnl_event.sock, NL_CB_VALID, NL_CB_CUSTOM, cb_rtnl_valid, NULL); /* Receive IPv4 address, IPv6 address, IPv6 routes and neighbor events */ if (nl_socket_add_memberships(rtnl_event.sock, RTNLGRP_IPV4_IFADDR, RTNLGRP_IPV6_IFADDR, RTNLGRP_IPV6_ROUTE, RTNLGRP_NEIGH, RTNLGRP_LINK, 0)) goto err; odhcpd_register(&rtnl_event.ev); return 0; err: if (rtnl_socket) { nl_socket_free(rtnl_socket); rtnl_socket = NULL; } if (rtnl_event.sock) { nl_socket_free(rtnl_event.sock); rtnl_event.sock = NULL; rtnl_event.ev.uloop.fd = -1; } return -1; } int netlink_add_netevent_handler(struct netevent_handler *handler) { if (!handler->cb) return -1; list_add(&handler->head, &netevent_handler_list); return 0; } static void call_netevent_handler_list(unsigned long event, struct netevent_handler_info *info) { struct netevent_handler *handler; list_for_each_entry(handler, &netevent_handler_list, head) handler->cb(event, info); } static void handle_rtnl_event(struct odhcpd_event *e) { struct event_socket *ev_sock = container_of(e, struct event_socket, ev); nl_recvmsgs_default(ev_sock->sock); } static void refresh_iface_addr4(int ifindex) { struct odhcpd_ipaddr *addr = NULL; struct interface *iface; ssize_t len = netlink_get_interface_addrs(ifindex, false, &addr); bool change = false; if (len < 0) return; avl_for_each_element(&interfaces, iface, avl) { struct netevent_handler_info event_info; if (iface->ifindex != ifindex) continue; memset(&event_info, 0, sizeof(event_info)); event_info.iface = iface; event_info.addrs_old.addrs = iface->addr4; event_info.addrs_old.len = iface->addr4_len; if (!change) { change = len != (ssize_t)iface->addr4_len; for (ssize_t i = 0; !change && i < len; ++i) { if (addr[i].addr.in.s_addr != iface->addr4[i].addr.in.s_addr) change = true; } } iface->addr4 = addr; iface->addr4_len = len; if (change) call_netevent_handler_list(NETEV_ADDRLIST_CHANGE, &event_info); free(event_info.addrs_old.addrs); if (!len) continue; addr = malloc(len * sizeof(*addr)); if (!addr) break; memcpy(addr, iface->addr4, len * sizeof(*addr)); } free(addr); } static void refresh_iface_addr6(int ifindex) { struct odhcpd_ipaddr *addr = NULL; struct interface *iface; ssize_t len = netlink_get_interface_addrs(ifindex, true, &addr); time_t now = odhcpd_time(); bool change = false; if (len < 0) return; avl_for_each_element(&interfaces, iface, avl) { struct netevent_handler_info event_info; if (iface->ifindex != ifindex) continue; memset(&event_info, 0, sizeof(event_info)); event_info.iface = iface; event_info.addrs_old.addrs = iface->addr6; event_info.addrs_old.len = iface->addr6_len; if (!change) { change = len != (ssize_t)iface->addr6_len; for (ssize_t i = 0; !change && i < len; ++i) { if (!IN6_ARE_ADDR_EQUAL(&addr[i].addr.in6, &iface->addr6[i].addr.in6) || (addr[i].preferred > (uint32_t)now) != (iface->addr6[i].preferred > (uint32_t)now) || addr[i].valid < iface->addr6[i].valid || addr[i].preferred < iface->addr6[i].preferred) change = true; } } iface->addr6 = addr; iface->addr6_len = len; if (change) call_netevent_handler_list(NETEV_ADDR6LIST_CHANGE, &event_info); free(event_info.addrs_old.addrs); if (!len) continue; addr = malloc(len * sizeof(*addr)); if (!addr) break; memcpy(addr, iface->addr6, len * sizeof(*addr)); } free(addr); } static int handle_rtm_link(struct nlmsghdr *hdr) { struct ifinfomsg *ifi = nlmsg_data(hdr); struct nlattr *nla[__IFLA_MAX]; struct interface *iface; struct netevent_handler_info event_info; const char *ifname; memset(&event_info, 0, sizeof(event_info)); if (!nlmsg_valid_hdr(hdr, sizeof(*ifi)) || ifi->ifi_family != AF_UNSPEC) return NL_SKIP; nlmsg_parse(hdr, sizeof(*ifi), nla, __IFLA_MAX - 1, NULL); if (!nla[IFLA_IFNAME]) return NL_SKIP; ifname = nla_get_string(nla[IFLA_IFNAME]); avl_for_each_element(&interfaces, iface, avl) { if (strcmp(iface->ifname, ifname) || iface->ifindex == ifi->ifi_index) continue; iface->ifindex = ifi->ifi_index; event_info.iface = iface; call_netevent_handler_list(NETEV_IFINDEX_CHANGE, &event_info); } return NL_OK; } static int handle_rtm_route(struct nlmsghdr *hdr, bool add) { struct rtmsg *rtm = nlmsg_data(hdr); struct nlattr *nla[__RTA_MAX]; struct interface *iface; struct netevent_handler_info event_info; int ifindex = 0; if (!nlmsg_valid_hdr(hdr, sizeof(*rtm)) || rtm->rtm_family != AF_INET6) return NL_SKIP; nlmsg_parse(hdr, sizeof(*rtm), nla, __RTA_MAX - 1, NULL); memset(&event_info, 0, sizeof(event_info)); event_info.rt.dst_len = rtm->rtm_dst_len; if (nla[RTA_DST]) nla_memcpy(&event_info.rt.dst, nla[RTA_DST], sizeof(event_info.rt.dst)); if (nla[RTA_OIF]) ifindex = nla_get_u32(nla[RTA_OIF]); if (nla[RTA_GATEWAY]) nla_memcpy(&event_info.rt.gateway, nla[RTA_GATEWAY], sizeof(event_info.rt.gateway)); avl_for_each_element(&interfaces, iface, avl) { if (ifindex && iface->ifindex != ifindex) continue; event_info.iface = ifindex ? iface : NULL; call_netevent_handler_list(add ? NETEV_ROUTE6_ADD : NETEV_ROUTE6_DEL, &event_info); } return NL_OK; } static int handle_rtm_addr(struct nlmsghdr *hdr, bool add) { struct ifaddrmsg *ifa = nlmsg_data(hdr); struct nlattr *nla[__IFA_MAX]; struct interface *iface; struct netevent_handler_info event_info; char buf[INET6_ADDRSTRLEN]; if (!nlmsg_valid_hdr(hdr, sizeof(*ifa)) || (ifa->ifa_family != AF_INET6 && ifa->ifa_family != AF_INET)) return NL_SKIP; memset(&event_info, 0, sizeof(event_info)); nlmsg_parse(hdr, sizeof(*ifa), nla, __IFA_MAX - 1, NULL); if (ifa->ifa_family == AF_INET6) { if (!nla[IFA_ADDRESS]) return NL_SKIP; nla_memcpy(&event_info.addr, nla[IFA_ADDRESS], sizeof(event_info.addr)); if (IN6_IS_ADDR_LINKLOCAL(&event_info.addr) || IN6_IS_ADDR_MULTICAST(&event_info.addr)) return NL_SKIP; inet_ntop(AF_INET6, &event_info.addr, buf, sizeof(buf)); avl_for_each_element(&interfaces, iface, avl) { if (iface->ifindex != (int)ifa->ifa_index) continue; syslog(LOG_DEBUG, "Netlink %s %s on %s", add ? "newaddr" : "deladdr", buf, iface->name); event_info.iface = iface; call_netevent_handler_list(add ? NETEV_ADDR6_ADD : NETEV_ADDR6_DEL, &event_info); } refresh_iface_addr6(ifa->ifa_index); } else { if (!nla[IFA_LOCAL]) return NL_SKIP; nla_memcpy(&event_info.addr, nla[IFA_LOCAL], sizeof(event_info.addr)); inet_ntop(AF_INET, &event_info.addr, buf, sizeof(buf)); avl_for_each_element(&interfaces, iface, avl) { if (iface->ifindex != (int)ifa->ifa_index) continue; syslog(LOG_DEBUG, "Netlink %s %s on %s", add ? "newaddr" : "deladdr", buf, iface->name); event_info.iface = iface; call_netevent_handler_list(add ? NETEV_ADDR_ADD : NETEV_ADDR_DEL, &event_info); } refresh_iface_addr4(ifa->ifa_index); } return NL_OK; } static int handle_rtm_neigh(struct nlmsghdr *hdr, bool add) { struct ndmsg *ndm = nlmsg_data(hdr); struct nlattr *nla[__NDA_MAX]; struct interface *iface; struct netevent_handler_info event_info; char buf[INET6_ADDRSTRLEN]; if (!nlmsg_valid_hdr(hdr, sizeof(*ndm)) || ndm->ndm_family != AF_INET6) return NL_SKIP; nlmsg_parse(hdr, sizeof(*ndm), nla, __NDA_MAX - 1, NULL); if (!nla[NDA_DST]) return NL_SKIP; memset(&event_info, 0, sizeof(event_info)); nla_memcpy(&event_info.neigh.dst, nla[NDA_DST], sizeof(event_info.neigh.dst)); if (IN6_IS_ADDR_LINKLOCAL(&event_info.neigh.dst) || IN6_IS_ADDR_MULTICAST(&event_info.neigh.dst)) return NL_SKIP; inet_ntop(AF_INET6, &event_info.neigh.dst, buf, sizeof(buf)); avl_for_each_element(&interfaces, iface, avl) { if (iface->ifindex != ndm->ndm_ifindex) continue; syslog(LOG_DEBUG, "Netlink %s %s on %s", true ? "newneigh" : "delneigh", buf, iface->name); event_info.iface = iface; event_info.neigh.state = ndm->ndm_state; event_info.neigh.flags = ndm->ndm_flags; call_netevent_handler_list(add ? NETEV_NEIGH6_ADD : NETEV_NEIGH6_DEL, &event_info); } return NL_OK; } /* Handler for neighbor cache entries from the kernel. This is our source * to learn and unlearn hosts on interfaces. */ static int cb_rtnl_valid(struct nl_msg *msg, _unused void *arg) { struct nlmsghdr *hdr = nlmsg_hdr(msg); int ret = NL_SKIP; bool add = false; switch (hdr->nlmsg_type) { case RTM_NEWLINK: ret = handle_rtm_link(hdr); break; case RTM_NEWROUTE: add = true; /* fall through */ case RTM_DELROUTE: ret = handle_rtm_route(hdr, add); break; case RTM_NEWADDR: add = true; /* fall through */ case RTM_DELADDR: ret = handle_rtm_addr(hdr, add); break; case RTM_NEWNEIGH: add = true; /* fall through */ case RTM_DELNEIGH: ret = handle_rtm_neigh(hdr, add); break; default: break; } return ret; } static void catch_rtnl_err(struct odhcpd_event *e, int error) { struct event_socket *ev_sock = container_of(e, struct event_socket, ev); if (error != ENOBUFS) goto err; /* Double netlink event buffer size */ ev_sock->sock_bufsize *= 2; if (nl_socket_set_buffer_size(ev_sock->sock, ev_sock->sock_bufsize, 0)) goto err; netlink_dump_addr_table(true); return; err: odhcpd_deregister(e); } static struct nl_sock *create_socket(int protocol) { struct nl_sock *nl_sock; nl_sock = nl_socket_alloc(); if (!nl_sock) goto err; if (nl_connect(nl_sock, protocol) < 0) goto err; return nl_sock; err: if (nl_sock) nl_socket_free(nl_sock); return NULL; } struct addr_info { int ifindex; int af; struct odhcpd_ipaddr **addrs; int pending; ssize_t ret; }; static int cb_addr_valid(struct nl_msg *msg, void *arg) { struct addr_info *ctxt = (struct addr_info *)arg; struct odhcpd_ipaddr *addrs = *(ctxt->addrs); struct nlmsghdr *hdr = nlmsg_hdr(msg); struct ifaddrmsg *ifa; struct nlattr *nla[__IFA_MAX], *nla_addr = NULL; if (hdr->nlmsg_type != RTM_NEWADDR) return NL_SKIP; ifa = NLMSG_DATA(hdr); if (ifa->ifa_scope != RT_SCOPE_UNIVERSE || (ctxt->af != ifa->ifa_family) || (ctxt->ifindex && ifa->ifa_index != (unsigned)ctxt->ifindex)) return NL_SKIP; nlmsg_parse(hdr, sizeof(*ifa), nla, __IFA_MAX - 1, NULL); switch (ifa->ifa_family) { case AF_INET6: if (nla[IFA_ADDRESS]) nla_addr = nla[IFA_ADDRESS]; break; case AF_INET: if (nla[IFA_LOCAL]) nla_addr = nla[IFA_LOCAL]; break; default: break; } if (!nla_addr) return NL_SKIP; addrs = realloc(addrs, sizeof(*addrs)*(ctxt->ret + 1)); if (!addrs) return NL_SKIP; memset(&addrs[ctxt->ret], 0, sizeof(addrs[ctxt->ret])); addrs[ctxt->ret].prefix = ifa->ifa_prefixlen; nla_memcpy(&addrs[ctxt->ret].addr, nla_addr, sizeof(addrs[ctxt->ret].addr)); if (nla[IFA_BROADCAST]) nla_memcpy(&addrs[ctxt->ret].broadcast, nla[IFA_BROADCAST], sizeof(addrs[ctxt->ret].broadcast)); if (nla[IFA_CACHEINFO]) { struct ifa_cacheinfo *ifc = nla_data(nla[IFA_CACHEINFO]); addrs[ctxt->ret].preferred = ifc->ifa_prefered; addrs[ctxt->ret].valid = ifc->ifa_valid; } if (ifa->ifa_flags & IFA_F_DEPRECATED) addrs[ctxt->ret].preferred = 0; ctxt->ret++; *(ctxt->addrs) = addrs; return NL_OK; } static int cb_addr_finish(_unused struct nl_msg *msg, void *arg) { struct addr_info *ctxt = (struct addr_info *)arg; ctxt->pending = 0; return NL_STOP; } static int cb_addr_error(_unused struct sockaddr_nl *nla, struct nlmsgerr *err, void *arg) { struct addr_info *ctxt = (struct addr_info *)arg; ctxt->pending = 0; ctxt->ret = err->error; return NL_STOP; } static int prefix_cmp(const void *va, const void *vb) { const struct odhcpd_ipaddr *a = va, *b = vb; int ret = 0; if (a->prefix == b->prefix) { ret = (ntohl(a->addr.in.s_addr) < ntohl(b->addr.in.s_addr)) ? 1 : (ntohl(a->addr.in.s_addr) > ntohl(b->addr.in.s_addr)) ? -1 : 0; } else ret = a->prefix < b->prefix ? 1 : -1; return ret; } /* compare IPv6 prefixes */ static int prefix6_cmp(const void *va, const void *vb) { const struct odhcpd_ipaddr *a = va, *b = vb; uint32_t a_pref = IN6_IS_ADDR_ULA(&a->addr.in6) ? 1 : a->preferred; uint32_t b_pref = IN6_IS_ADDR_ULA(&b->addr.in6) ? 1 : b->preferred; return (a_pref < b_pref) ? 1 : (a_pref > b_pref) ? -1 : 0; } /* Detect an IPV6-address currently assigned to the given interface */ ssize_t netlink_get_interface_addrs(int ifindex, bool v6, struct odhcpd_ipaddr **addrs) { struct nl_msg *msg; struct ifaddrmsg ifa = { .ifa_family = v6? AF_INET6: AF_INET, .ifa_prefixlen = 0, .ifa_flags = 0, .ifa_scope = 0, .ifa_index = ifindex, }; struct nl_cb *cb = nl_cb_alloc(NL_CB_DEFAULT); struct addr_info ctxt = { .ifindex = ifindex, .af = v6? AF_INET6: AF_INET, .addrs = addrs, .ret = 0, .pending = 1, }; if (!cb) { ctxt.ret = -1; goto out; } msg = nlmsg_alloc_simple(RTM_GETADDR, NLM_F_REQUEST | NLM_F_DUMP); if (!msg) { ctxt.ret = - 1; goto out; } nlmsg_append(msg, &ifa, sizeof(ifa), 0); nl_cb_set(cb, NL_CB_VALID, NL_CB_CUSTOM, cb_addr_valid, &ctxt); nl_cb_set(cb, NL_CB_FINISH, NL_CB_CUSTOM, cb_addr_finish, &ctxt); nl_cb_err(cb, NL_CB_CUSTOM, cb_addr_error, &ctxt); ctxt.ret = nl_send_auto_complete(rtnl_socket, msg); if (ctxt.ret < 0) goto free; ctxt.ret = 0; while (ctxt.pending > 0) nl_recvmsgs(rtnl_socket, cb); if (ctxt.ret <= 0) goto free; time_t now = odhcpd_time(); struct odhcpd_ipaddr *addr = *addrs; qsort(addr, ctxt.ret, sizeof(*addr), v6 ? prefix6_cmp : prefix_cmp); for (ssize_t i = 0; i < ctxt.ret; ++i) { if (addr[i].preferred < UINT32_MAX - now) addr[i].preferred += now; if (addr[i].valid < UINT32_MAX - now) addr[i].valid += now; } free: nlmsg_free(msg); out: nl_cb_put(cb); return ctxt.ret; } struct neigh_info { int ifindex; int pending; const struct in6_addr *addr; int ret; }; static int cb_proxy_neigh_valid(struct nl_msg *msg, void *arg) { struct neigh_info *ctxt = (struct neigh_info *)arg; struct nlmsghdr *hdr = nlmsg_hdr(msg); struct ndmsg *ndm; struct nlattr *nla_dst; if (hdr->nlmsg_type != RTM_NEWNEIGH) return NL_SKIP; ndm = NLMSG_DATA(hdr); if (ndm->ndm_family != AF_INET6 || (ctxt->ifindex && ndm->ndm_ifindex != ctxt->ifindex)) return NL_SKIP; if (!(ndm->ndm_flags & NTF_PROXY)) return NL_SKIP; nla_dst = nlmsg_find_attr(hdr, sizeof(*ndm), NDA_DST); if (!nla_dst) return NL_SKIP; if (nla_memcmp(nla_dst,ctxt->addr, 16) == 0) ctxt->ret = 1; return NL_OK; } static int cb_proxy_neigh_finish(_unused struct nl_msg *msg, void *arg) { struct neigh_info *ctxt = (struct neigh_info *)arg; ctxt->pending = 0; return NL_STOP; } static int cb_proxy_neigh_error(_unused struct sockaddr_nl *nla, struct nlmsgerr *err, void *arg) { struct neigh_info *ctxt = (struct neigh_info *)arg; ctxt->pending = 0; ctxt->ret = err->error; return NL_STOP; } /* Detect an IPV6-address proxy neighbor for the given interface */ int netlink_get_interface_proxy_neigh(int ifindex, const struct in6_addr *addr) { struct nl_msg *msg; struct ndmsg ndm = { .ndm_family = AF_INET6, .ndm_flags = NTF_PROXY, .ndm_ifindex = ifindex, }; struct nl_cb *cb = nl_cb_alloc(NL_CB_DEFAULT); struct neigh_info ctxt = { .ifindex = ifindex, .addr = addr, .ret = 0, .pending = 1, }; if (!cb) { ctxt.ret = -1; goto out; } msg = nlmsg_alloc_simple(RTM_GETNEIGH, NLM_F_REQUEST | NLM_F_MATCH); if (!msg) { ctxt.ret = -1; goto out; } nlmsg_append(msg, &ndm, sizeof(ndm), 0); nla_put(msg, NDA_DST, sizeof(*addr), addr); nl_cb_set(cb, NL_CB_VALID, NL_CB_CUSTOM, cb_proxy_neigh_valid, &ctxt); nl_cb_set(cb, NL_CB_FINISH, NL_CB_CUSTOM, cb_proxy_neigh_finish, &ctxt); nl_cb_err(cb, NL_CB_CUSTOM, cb_proxy_neigh_error, &ctxt); ctxt.ret = nl_send_auto_complete(rtnl_socket, msg); if (ctxt.ret < 0) goto free; while (ctxt.pending > 0) nl_recvmsgs(rtnl_socket, cb); free: nlmsg_free(msg); out: nl_cb_put(cb); return ctxt.ret; } int netlink_setup_route(const struct in6_addr *addr, const int prefixlen, const int ifindex, const struct in6_addr *gw, const uint32_t metric, const bool add) { struct nl_msg *msg; struct rtmsg rtm = { .rtm_family = AF_INET6, .rtm_dst_len = prefixlen, .rtm_src_len = 0, .rtm_table = RT_TABLE_MAIN, .rtm_protocol = (add ? RTPROT_STATIC : RTPROT_UNSPEC), .rtm_scope = (add ? (gw ? RT_SCOPE_UNIVERSE : RT_SCOPE_LINK) : RT_SCOPE_NOWHERE), .rtm_type = (add ? RTN_UNICAST : RTN_UNSPEC), }; int ret = 0; msg = nlmsg_alloc_simple(add ? RTM_NEWROUTE : RTM_DELROUTE, add ? NLM_F_CREATE | NLM_F_REPLACE : 0); if (!msg) return -1; nlmsg_append(msg, &rtm, sizeof(rtm), 0); nla_put(msg, RTA_DST, sizeof(*addr), addr); nla_put_u32(msg, RTA_OIF, ifindex); nla_put_u32(msg, RTA_PRIORITY, metric); if (gw) nla_put(msg, RTA_GATEWAY, sizeof(*gw), gw); ret = nl_send_auto_complete(rtnl_socket, msg); nlmsg_free(msg); if (ret < 0) return ret; return nl_wait_for_ack(rtnl_socket); } int netlink_setup_proxy_neigh(const struct in6_addr *addr, const int ifindex, const bool add) { struct nl_msg *msg; struct ndmsg ndm = { .ndm_family = AF_INET6, .ndm_flags = NTF_PROXY, .ndm_ifindex = ifindex, }; int ret = 0, flags = NLM_F_REQUEST; if (add) flags |= NLM_F_REPLACE | NLM_F_CREATE; msg = nlmsg_alloc_simple(add ? RTM_NEWNEIGH : RTM_DELNEIGH, flags); if (!msg) return -1; nlmsg_append(msg, &ndm, sizeof(ndm), 0); nla_put(msg, NDA_DST, sizeof(*addr), addr); ret = nl_send_auto_complete(rtnl_socket, msg); nlmsg_free(msg); if (ret < 0) return ret; return nl_wait_for_ack(rtnl_socket); } int netlink_setup_addr(struct odhcpd_ipaddr *addr, const int ifindex, const bool v6, const bool add) { struct nl_msg *msg; struct ifaddrmsg ifa = { .ifa_family = v6 ? AF_INET6 : AF_INET, .ifa_prefixlen = addr->prefix, .ifa_flags = 0, .ifa_scope = 0, .ifa_index = ifindex, }; int ret = 0, flags = NLM_F_REQUEST; if (add) flags |= NLM_F_REPLACE | NLM_F_CREATE; msg = nlmsg_alloc_simple(add ? RTM_NEWADDR : RTM_DELADDR, 0); if (!msg) return -1; nlmsg_append(msg, &ifa, sizeof(ifa), flags); nla_put(msg, IFA_LOCAL, v6 ? 16 : 4, &addr->addr); if (v6) { struct ifa_cacheinfo cinfo = { .ifa_prefered = 0xffffffffU, .ifa_valid = 0xffffffffU, .cstamp = 0, .tstamp = 0 }; time_t now = odhcpd_time(); if (addr->preferred) { int64_t preferred = addr->preferred - now; if (preferred < 0) preferred = 0; else if (preferred > UINT32_MAX) preferred = UINT32_MAX; cinfo.ifa_prefered = preferred; } if (addr->valid) { int64_t valid = addr->valid - now; if (valid <= 0) { nlmsg_free(msg); return -1; } else if (valid > UINT32_MAX) valid = UINT32_MAX; cinfo.ifa_valid = valid; } nla_put(msg, IFA_CACHEINFO, sizeof(cinfo), &cinfo); nla_put_u32(msg, IFA_FLAGS, IFA_F_NOPREFIXROUTE); } else { if (addr->broadcast.s_addr) nla_put_u32(msg, IFA_BROADCAST, addr->broadcast.s_addr); } ret = nl_send_auto_complete(rtnl_socket, msg); nlmsg_free(msg); if (ret < 0) return ret; return nl_wait_for_ack(rtnl_socket); } void netlink_dump_neigh_table(const bool proxy) { struct nl_msg *msg; struct ndmsg ndm = { .ndm_family = AF_INET6, .ndm_flags = proxy ? NTF_PROXY : 0, }; msg = nlmsg_alloc_simple(RTM_GETNEIGH, NLM_F_REQUEST | NLM_F_DUMP); if (!msg) return; nlmsg_append(msg, &ndm, sizeof(ndm), 0); nl_send_auto_complete(rtnl_event.sock, msg); nlmsg_free(msg); } void netlink_dump_addr_table(const bool v6) { struct nl_msg *msg; struct ifaddrmsg ifa = { .ifa_family = v6 ? AF_INET6 : AF_INET, }; msg = nlmsg_alloc_simple(RTM_GETADDR, NLM_F_REQUEST | NLM_F_DUMP); if (!msg) return; nlmsg_append(msg, &ifa, sizeof(ifa), 0); nl_send_auto_complete(rtnl_event.sock, msg); nlmsg_free(msg); }