/* arp.c - arp ping checking * * Copyright (c) 2010-2014 Nicholas J. Kain * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * - Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * - 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. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT HOLDER 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. */ #include #include #include #include #include #include #include #include #include #include #include "nk/log.h" #include "nk/io.h" #include "arp.h" #include "state.h" #include "dhcp.h" #include "sys.h" #include "ifchange.h" #include "options.h" #include "leasefile.h" #include "sockd.h" #define ARP_MSG_SIZE 0x2a #define ARP_RETRANS_DELAY 5000 // ms // From RFC5227 int arp_probe_wait = 1000; // initial random delay (ms) int arp_probe_num = 3; // number of probe packets int arp_probe_min = 1000; // minimum delay until repeated probe (ms) int arp_probe_max = 2000; // maximum delay until repeated probe (ms) #define ANNOUNCE_WAIT 2000 // delay before announcing #define ANNOUNCE_NUM 2 // number of Announcement packets #define ANNOUNCE_INTERVAL 2000 // time between Announcement packets #define MAX_CONFLICTS 10 // max conflicts before rate-limiting #define RATE_LIMIT_INTERVAL 60000 // delay between successive attempts #define DEFEND_INTERVAL 10000 // minimum interval between defensive ARPs typedef enum { AS_NONE = 0, // Nothing to react to wrt ARP AS_COLLISION_CHECK, // Checking to see if another host has our IP before // accepting a new lease. AS_GW_CHECK, // Seeing if the default GW still exists on the local // segment after the hardware link was lost. AS_GW_QUERY, // Finding the default GW MAC address. AS_DEFENSE, // Defending our IP address (RFC5227) AS_MAX, } arp_state_t; typedef enum { ASEND_COLLISION_CHECK, ASEND_GW_PING, ASEND_ANNOUNCE, ASEND_MAX, } arp_send_t; struct arp_stats { long long ts; int count; }; struct arp_data { struct dhcpmsg dhcp_packet; // Used only for AS_COLLISION_CHECK struct arpMsg reply; struct arp_stats send_stats[ASEND_MAX]; long long wake_ts[AS_MAX]; long long last_conflict_ts; // TS of the last conflicting ARP seen. long long arp_check_start_ts; // TS of when we started the // AS_COLLISION_CHECK state. size_t reply_offset; arp_state_t state; unsigned int total_conflicts; // Total number of address conflicts on // the interface. Never decreases. int gw_check_initpings; // Initial count of ASEND_GW_PING when // AS_GW_CHECK was entered. uint16_t probe_wait_time; // Time to wait for a COLLISION_CHECK reply // (in ms?). bool using_bpf:1; // Is a BPF installed on the ARP socket? bool relentless_def:1; // Don't give up defense no matter what. bool router_replied:1; bool server_replied:1; }; static struct arp_data garp = { .state = AS_NONE, .wake_ts = { -1, -1, -1, -1, -1 }, .send_stats = {{0},{0},{0}}, .last_conflict_ts = 0, .gw_check_initpings = 0, .arp_check_start_ts = 0, .total_conflicts = 0, .probe_wait_time = 0, .reply_offset = 0, .using_bpf = false, .relentless_def = false, .router_replied = false, .server_replied = false, }; void set_arp_relentless_def(void) { garp.relentless_def = true; } static void arp_reply_clear(void) { memset(&garp.reply, 0, sizeof garp.reply); garp.reply_offset = 0; } void arp_reset_send_stats(void) { for (int i = 0; i < ASEND_MAX; ++i) { garp.send_stats[i].ts = 0; garp.send_stats[i].count = 0; } } static int get_arp_basic_socket(void) { char resp; int fd = request_sockd_fd("a", 1, &resp); switch (resp) { case 'A': garp.using_bpf = true; break; case 'a': garp.using_bpf = false; break; default: suicide("%s: (%s) expected a or A sockd reply but got %c", client_config.interface, __func__, resp); } return fd; } static int get_arp_defense_socket(struct client_state_t *cs) { char buf[32]; size_t buflen = 0; buf[0] = 'd'; buflen += 1; memcpy(buf + buflen, &cs->clientAddr, sizeof cs->clientAddr); buflen += sizeof cs->clientAddr; memcpy(buf + buflen, client_config.arp, 6); buflen += 6; char resp; int fd = request_sockd_fd(buf, buflen, &resp); switch (resp) { case 'D': garp.using_bpf = true; break; case 'd': garp.using_bpf = false; break; default: suicide("%s: (%s) expected d or D sockd reply but got %c", client_config.interface, __func__, resp); } return fd; } static int arp_open_fd(struct client_state_t *cs, arp_state_t state) { if (cs->arpFd >= 0) { log_warning("%s: (%s) called but fd already exists", client_config.interface, __func__); return 0; } switch (state) { default: log_warning("%s: (%s) called for 'default' state", client_config.interface, __func__); return 0; case AS_COLLISION_CHECK: case AS_GW_QUERY: case AS_GW_CHECK: cs->arpFd = get_arp_basic_socket(); break; case AS_DEFENSE: cs->arpFd = get_arp_defense_socket(cs); break; } if (cs->arpFd < 0) { log_error("arp: Failed to create socket: %s", strerror(errno)); return -1; } epoll_add(cs->epollFd, cs->arpFd); arp_reply_clear(); return 0; } static void arp_min_close_fd(struct client_state_t *cs) { if (cs->arpFd < 0) return; epoll_del(cs->epollFd, cs->arpFd); close(cs->arpFd); cs->arpFd = -1; garp.state = AS_NONE; } static void arp_switch_state(struct client_state_t *cs, arp_state_t state) { if (garp.state == state || garp.state >= AS_MAX) return; if (state == AS_NONE) { arp_close_fd(cs); return; } bool force_reopen = state == AS_DEFENSE || garp.state == AS_DEFENSE; if (force_reopen) arp_min_close_fd(cs); if (cs->arpFd < 0 || force_reopen) { if (arp_open_fd(cs, state) < 0) suicide("arp: Failed to open arpFd when changing state %u -> %u", garp.state, state); } garp.state = state; } void arp_close_fd(struct client_state_t *cs) { arp_min_close_fd(cs); for (int i = 0; i < AS_MAX; ++i) garp.wake_ts[i] = -1; } static void arp_reopen_fd(struct client_state_t *cs) { arp_state_t prev_state = garp.state; arp_min_close_fd(cs); arp_switch_state(cs, prev_state); } static int arp_send(struct client_state_t *cs, struct arpMsg *arp) { struct sockaddr_ll addr = { .sll_family = AF_PACKET, .sll_ifindex = client_config.ifindex, .sll_halen = 6, }; memcpy(addr.sll_addr, client_config.arp, 6); if (cs->arpFd < 0) { log_warning("arp: Send attempted when no ARP fd is open."); return -1; } if (safe_sendto(cs->arpFd, (const char *)arp, sizeof *arp, 0, (struct sockaddr *)&addr, sizeof addr) < 0) { log_error("arp: sendto failed: %s", strerror(errno)); arp_reopen_fd(cs); return -1; } return 0; } #define BASE_ARPMSG() struct arpMsg arp = { \ .h_proto = htons(ETH_P_ARP), \ .htype = htons(ARPHRD_ETHER), \ .ptype = htons(ETH_P_IP), \ .hlen = 6, .plen = 4, \ .operation = htons(ARPOP_REQUEST), \ .smac = {0}, \ }; \ memcpy(arp.h_source, client_config.arp, 6); \ memset(arp.h_dest, 0xff, 6); \ memcpy(arp.smac, client_config.arp, 6) // Returns 0 on success, -1 on failure. static int arp_ping(struct client_state_t *cs, uint32_t test_ip) { BASE_ARPMSG(); memcpy(arp.sip4, &cs->clientAddr, sizeof cs->clientAddr); memcpy(arp.dip4, &test_ip, sizeof test_ip); if (arp_send(cs, &arp) < 0) return -1; garp.send_stats[ASEND_GW_PING].count++; garp.send_stats[ASEND_GW_PING].ts = curms(); return 0; } // Returns 0 on success, -1 on failure. static int arp_ip_anon_ping(struct client_state_t *cs, uint32_t test_ip) { BASE_ARPMSG(); memcpy(arp.dip4, &test_ip, sizeof test_ip); log_line("arp: Probing for hosts that may conflict with our lease..."); if (arp_send(cs, &arp) < 0) return -1; garp.send_stats[ASEND_COLLISION_CHECK].count++; garp.send_stats[ASEND_COLLISION_CHECK].ts = curms(); return 0; } static int arp_announcement(struct client_state_t *cs) { BASE_ARPMSG(); memcpy(arp.sip4, &cs->clientAddr, 4); memcpy(arp.dip4, &cs->clientAddr, 4); if (arp_send(cs, &arp) < 0) return -1; garp.send_stats[ASEND_ANNOUNCE].count++; garp.send_stats[ASEND_ANNOUNCE].ts = curms(); return 0; } #undef BASE_ARPMSG // Callable from DS_REQUESTING, DS_RENEWING, or DS_REBINDING via an_packet() int arp_check(struct client_state_t *cs, struct dhcpmsg *packet) { memcpy(&garp.dhcp_packet, packet, sizeof (struct dhcpmsg)); arp_switch_state(cs, AS_COLLISION_CHECK); if (arp_ip_anon_ping(cs, garp.dhcp_packet.yiaddr) < 0) return -1; cs->arpPrevState = cs->dhcpState; cs->dhcpState = DS_COLLISION_CHECK; garp.arp_check_start_ts = garp.send_stats[ASEND_COLLISION_CHECK].ts; garp.probe_wait_time = arp_probe_wait; garp.wake_ts[AS_COLLISION_CHECK] = garp.arp_check_start_ts + garp.probe_wait_time; return 0; } // Callable only from DS_BOUND via state.c:ifup_action(). int arp_gw_check(struct client_state_t *cs) { if (garp.state == AS_GW_CHECK) // Guard against state bounce. return 0; garp.gw_check_initpings = garp.send_stats[ASEND_GW_PING].count; garp.server_replied = false; if (arp_ping(cs, cs->serverAddr) < 0) return -1; if (cs->routerAddr) { garp.router_replied = false; if (arp_ping(cs, cs->routerAddr) < 0) return -1; } else garp.router_replied = true; arp_switch_state(cs, AS_GW_CHECK); cs->arpPrevState = cs->dhcpState; cs->dhcpState = DS_BOUND_GW_CHECK; garp.wake_ts[AS_GW_CHECK] = garp.send_stats[ASEND_GW_PING].ts + ARP_RETRANS_DELAY + 250; return 0; } // Should only be called from DS_BOUND state. static int arp_get_gw_hwaddr(struct client_state_t *cs) { if (cs->dhcpState != DS_BOUND) log_error("arp_get_gw_hwaddr: called when state != DS_BOUND"); arp_switch_state(cs, AS_GW_QUERY); if (cs->routerAddr) log_line("arp: Searching for dhcp server and gw addresses..."); else log_line("arp: Searching for dhcp server address..."); cs->got_server_arp = 0; if (arp_ping(cs, cs->serverAddr) < 0) return -1; if (cs->routerAddr) { cs->got_router_arp = 0; if (arp_ping(cs, cs->routerAddr) < 0) return -1; } else cs->got_router_arp = 1; garp.wake_ts[AS_GW_QUERY] = garp.send_stats[ASEND_GW_PING].ts + ARP_RETRANS_DELAY + 250; return 0; } static void arp_failed(struct client_state_t *cs) { log_line("arp: Offered address is in use. Declining."); send_decline(cs, garp.dhcp_packet.yiaddr); garp.wake_ts[AS_COLLISION_CHECK] = -1; reinit_selecting(cs, garp.total_conflicts < MAX_CONFLICTS ? 0 : RATE_LIMIT_INTERVAL); } static void arp_gw_failed(struct client_state_t *cs) { garp.wake_ts[AS_GW_CHECK] = -1; reinit_selecting(cs, 0); } static int act_if_arp_gw_failed(struct client_state_t *cs) { if (garp.send_stats[ASEND_GW_PING].count >= garp.gw_check_initpings + 6) { if (garp.router_replied && !garp.server_replied) log_line("arp: DHCP server didn't reply. Getting new lease."); else if (!garp.router_replied && garp.server_replied) log_line("arp: Gateway didn't reply. Getting new lease."); else log_line("arp: DHCP server and gateway didn't reply. Getting new lease."); arp_gw_failed(cs); return 1; } return 0; } void arp_set_defense_mode(struct client_state_t *cs) { arp_switch_state(cs, AS_DEFENSE); } void arp_success(struct client_state_t *cs) { char clibuf[INET_ADDRSTRLEN]; struct in_addr temp_addr = {.s_addr = garp.dhcp_packet.yiaddr}; inet_ntop(AF_INET, &temp_addr, clibuf, sizeof clibuf); log_line("Lease of %s obtained. Lease time is %ld seconds.", clibuf, cs->lease); cs->clientAddr = garp.dhcp_packet.yiaddr; cs->dhcpState = DS_BOUND; cs->init = 0; garp.last_conflict_ts = 0; garp.wake_ts[AS_COLLISION_CHECK] = -1; ifchange_bind(cs, &garp.dhcp_packet); if (cs->arpPrevState == DS_RENEWING || cs->arpPrevState == DS_REBINDING) { arp_switch_state(cs, AS_DEFENSE); } else { cs->routerAddr = get_option_router(&garp.dhcp_packet); arp_get_gw_hwaddr(cs); } set_listen_none(cs); write_leasefile(temp_addr); arp_announcement(cs); if (client_config.quit_after_lease) exit(EXIT_SUCCESS); if (!client_config.foreground) background(); } static void arp_gw_success(struct client_state_t *cs) { log_line("arp: Network seems unchanged. Resuming normal operation."); arp_switch_state(cs, AS_DEFENSE); arp_announcement(cs); garp.wake_ts[AS_GW_CHECK] = -1; cs->dhcpState = cs->arpPrevState; } // ARP validation functions that will be performed by the BPF if it is // installed. static int arp_validate_bpf(struct arpMsg *am) { if (am->h_proto != htons(ETH_P_ARP)) { log_warning("arp: IP header does not indicate ARP protocol"); return 0; } if (am->htype != htons(ARPHRD_ETHER)) { log_warning("arp: ARP hardware type field invalid"); return 0; } if (am->ptype != htons(ETH_P_IP)) { log_warning("arp: ARP protocol type field invalid"); return 0; } if (am->hlen != 6) { log_warning("arp: ARP hardware address length invalid"); return 0; } if (am->plen != 4) { log_warning("arp: ARP protocol address length invalid"); return 0; } return 1; } // ARP validation functions that will be performed by the BPF if it is // installed. static int arp_validate_bpf_defense(struct client_state_t *cs, struct arpMsg *am) { if (memcmp(am->sip4, &cs->clientAddr, 4)) return 0; if (!memcmp(am->smac, client_config.arp, 6)) return 0; return 1; } static int arp_is_query_reply(struct arpMsg *am) { if (am->operation != htons(ARPOP_REPLY)) return 0; if (memcmp(am->h_dest, client_config.arp, 6)) return 0; if (memcmp(am->dmac, client_config.arp, 6)) return 0; return 1; } static int arp_gen_probe_wait(struct client_state_t *cs) { // This is not a uniform distribution but it doesn't matter here. return arp_probe_min + (nk_random_u32(&cs->rnd32_state) & 0x7fffffffu) % (arp_probe_max - arp_probe_min); } static void arp_defense_timeout(struct client_state_t *cs, long long nowts) { (void)nowts; // Suppress warning; parameter necessary but unused. if (garp.wake_ts[AS_DEFENSE] != -1) { log_line("arp: Defending our lease IP."); arp_announcement(cs); garp.wake_ts[AS_DEFENSE] = -1; } } static void arp_gw_check_timeout(struct client_state_t *cs, long long nowts) { arp_defense_timeout(cs, nowts); if (act_if_arp_gw_failed(cs)) return; long long rtts = garp.send_stats[ASEND_GW_PING].ts + ARP_RETRANS_DELAY; if (nowts < rtts) { garp.wake_ts[AS_GW_CHECK] = rtts; return; } if (!garp.router_replied) { log_line("arp: Still waiting for gateway to reply to arp ping..."); if (arp_ping(cs, cs->routerAddr) < 0) log_warning("arp: Failed to send ARP ping in retransmission."); } if (!garp.server_replied) { log_line("arp: Still waiting for DHCP server to reply to arp ping..."); if (arp_ping(cs, cs->serverAddr) < 0) log_warning("arp: Failed to send ARP ping in retransmission."); } garp.wake_ts[AS_GW_CHECK] = garp.send_stats[ASEND_GW_PING].ts + ARP_RETRANS_DELAY; } static void arp_gw_query_timeout(struct client_state_t *cs, long long nowts) { arp_defense_timeout(cs, nowts); long long rtts = garp.send_stats[ASEND_GW_PING].ts + ARP_RETRANS_DELAY; if (nowts < rtts) { garp.wake_ts[AS_GW_QUERY] = rtts; return; } if (!cs->got_router_arp) { log_line("arp: Still looking for gateway hardware address..."); if (arp_ping(cs, cs->routerAddr) < 0) log_warning("arp: Failed to send ARP ping in retransmission."); } if (!cs->got_server_arp) { log_line("arp: Still looking for DHCP server hardware address..."); if (arp_ping(cs, cs->serverAddr) < 0) log_warning("arp: Failed to send ARP ping in retransmission."); } garp.wake_ts[AS_GW_QUERY] = garp.send_stats[ASEND_GW_PING].ts + ARP_RETRANS_DELAY; } static void arp_collision_timeout(struct client_state_t *cs, long long nowts) { arp_defense_timeout(cs, nowts); if (nowts >= garp.arp_check_start_ts + ANNOUNCE_WAIT || garp.send_stats[ASEND_COLLISION_CHECK].count >= arp_probe_num) { arp_success(cs); return; } long long rtts = garp.send_stats[ASEND_COLLISION_CHECK].ts + garp.probe_wait_time; if (nowts < rtts) { garp.wake_ts[AS_COLLISION_CHECK] = rtts; return; } if (arp_ip_anon_ping(cs, garp.dhcp_packet.yiaddr) < 0) log_warning("arp: Failed to send ARP ping in retransmission."); garp.probe_wait_time = arp_gen_probe_wait(cs); garp.wake_ts[AS_COLLISION_CHECK] = garp.send_stats[ASEND_COLLISION_CHECK].ts + garp.probe_wait_time; } static void arp_do_defense(struct client_state_t *cs) { // Even though the BPF will usually catch this case, sometimes there are // packets still in the socket buffer that arrived before the defense // BPF was installed, so it's necessary to check here. if (!arp_validate_bpf_defense(cs, &garp.reply)) return; log_line("arp: Detected a peer attempting to use our IP!"); long long nowts = curms(); garp.wake_ts[AS_DEFENSE] = -1; if (!garp.last_conflict_ts || nowts - garp.last_conflict_ts < DEFEND_INTERVAL) { log_line("arp: Defending our lease IP."); arp_announcement(cs); } else if (!garp.relentless_def) { log_line("arp: Conflicting peer is persistent. Requesting new lease."); send_release(cs); reinit_selecting(cs, 0); } else { garp.wake_ts[AS_DEFENSE] = garp.send_stats[ASEND_ANNOUNCE].ts + DEFEND_INTERVAL; } garp.total_conflicts++; garp.last_conflict_ts = nowts; } static void arp_do_gw_query_done(struct client_state_t *cs) { garp.wake_ts[AS_GW_QUERY] = -1; arp_switch_state(cs, AS_DEFENSE); arp_announcement(cs); // Do a second announcement. } static void arp_do_gw_query(struct client_state_t *cs) { if (!arp_is_query_reply(&garp.reply)) { arp_do_defense(cs); return; } if (!memcmp(garp.reply.sip4, &cs->routerAddr, 4)) { memcpy(cs->routerArp, garp.reply.smac, 6); log_line("arp: Gateway hardware address %02x:%02x:%02x:%02x:%02x:%02x", cs->routerArp[0], cs->routerArp[1], cs->routerArp[2], cs->routerArp[3], cs->routerArp[4], cs->routerArp[5]); cs->got_router_arp = 1; if (cs->routerAddr == cs->serverAddr) goto server_is_router; if (cs->got_server_arp) arp_do_gw_query_done(cs); return; } if (!memcmp(garp.reply.sip4, &cs->serverAddr, 4)) { server_is_router: memcpy(cs->serverArp, garp.reply.smac, 6); log_line("arp: DHCP Server hardware address %02x:%02x:%02x:%02x:%02x:%02x", cs->serverArp[0], cs->serverArp[1], cs->serverArp[2], cs->serverArp[3], cs->serverArp[4], cs->serverArp[5]); cs->got_server_arp = 1; if (cs->got_router_arp) arp_do_gw_query_done(cs); return; } arp_do_defense(cs); } static void arp_do_collision_check(struct client_state_t *cs) { if (!arp_is_query_reply(&garp.reply)) return; // If this packet was sent from our lease IP, and does not have a // MAC address matching our own (the latter check guards against stupid // hubs or repeaters), then it's a conflict and thus a failure. if (!memcmp(garp.reply.sip4, &garp.dhcp_packet.yiaddr, 4) && !memcmp(client_config.arp, garp.reply.smac, 6)) { garp.total_conflicts++; arp_failed(cs); } } static void arp_do_gw_check(struct client_state_t *cs) { if (!arp_is_query_reply(&garp.reply)) return; if (!memcmp(garp.reply.sip4, &cs->routerAddr, 4)) { // Success only if the router/gw MAC matches stored value if (!memcmp(cs->routerArp, garp.reply.smac, 6)) { garp.router_replied = true; if (cs->routerAddr == cs->serverAddr) goto server_is_router; if (garp.server_replied) arp_gw_success(cs); } else { log_line("arp: Gateway is different. Getting a new lease."); arp_gw_failed(cs); } return; } if (!memcmp(garp.reply.sip4, &cs->serverAddr, 4)) { server_is_router: // Success only if the server MAC matches stored value if (!memcmp(cs->serverArp, garp.reply.smac, 6)) { garp.server_replied = true; if (garp.router_replied) arp_gw_success(cs); } else { log_line("arp: DHCP server is different. Getting a new lease."); arp_gw_failed(cs); } } } static void arp_do_invalid(struct client_state_t *cs) { log_error("handle_arp_response: called in invalid state %u", garp.state); arp_close_fd(cs); } typedef struct { void (*packet_fn)(struct client_state_t *cs); void (*timeout_fn)(struct client_state_t *cs, long long nowts); } arp_state_fn_t; static const arp_state_fn_t arp_states[] = { { arp_do_invalid, 0 }, // AS_NONE { arp_do_collision_check, arp_collision_timeout }, // AS_COLLISION_CHECK { arp_do_gw_check, arp_gw_check_timeout }, // AS_GW_CHECK { arp_do_gw_query, arp_gw_query_timeout }, // AS_GW_QUERY { arp_do_defense, arp_defense_timeout }, // AS_DEFENSE { arp_do_invalid, 0 }, // AS_MAX }; void handle_arp_response(struct client_state_t *cs) { ssize_t r = 0; if (garp.reply_offset < sizeof garp.reply) { r = safe_read(cs->arpFd, (char *)&garp.reply + garp.reply_offset, sizeof garp.reply - garp.reply_offset); if (r < 0) { log_error("arp: ARP response read failed: %s", strerror(errno)); switch (garp.state) { case AS_COLLISION_CHECK: arp_failed(cs); break; case AS_GW_CHECK: arp_gw_failed(cs); break; default: arp_reopen_fd(cs); break; } } else garp.reply_offset += (size_t)r; } if (r <= 0) { handle_arp_timeout(cs, curms()); return; } if (garp.reply_offset < ARP_MSG_SIZE) return; // Emulate the BPF filters if they are not in use. if (!garp.using_bpf && (!arp_validate_bpf(&garp.reply) || (garp.state == AS_DEFENSE && !arp_validate_bpf_defense(cs, &garp.reply)))) { arp_reply_clear(); return; } if (arp_states[garp.state].packet_fn) arp_states[garp.state].packet_fn(cs); arp_reply_clear(); } // Perform retransmission if necessary. void handle_arp_timeout(struct client_state_t *cs, long long nowts) { if (arp_states[garp.state].timeout_fn) arp_states[garp.state].timeout_fn(cs, nowts); } long long arp_get_wake_ts(void) { long long mt = -1; for (int i = 0; i < AS_MAX; ++i) { if (garp.wake_ts[i] < 0) continue; if (mt < 0 || mt > garp.wake_ts[i]) mt = garp.wake_ts[i]; } return mt; }