/*-*- Mode: C; c-basic-offset: 8; indent-tabs-mode: nil -*-*/ /*** This file is part of systemd. Copyright (C) 2013 Intel Corporation. All rights reserved. Copyright (C) 2014 Tom Gundersen systemd is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. systemd 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with systemd; If not, see . ***/ #include #include "in-addr-util.h" #include "siphash24.h" #include "sd-dhcp-server.h" #include "dhcp-server-internal.h" #include "dhcp-internal.h" #define DHCP_DEFAULT_LEASE_TIME_USEC USEC_PER_HOUR #define DHCP_MAX_LEASE_TIME_USEC (USEC_PER_HOUR*12) /* configures the server's address and subnet, and optionally the pool's size and offset into the subnet * the whole pool must fit into the subnet, and may not contain the first (any) nor last (broadcast) address * moreover, the server's own address may be in the pool, and is in that case reserved in order not to * accidentally hand it out */ int sd_dhcp_server_configure_pool(sd_dhcp_server *server, struct in_addr *address, unsigned char prefixlen, uint32_t offset, uint32_t size) { struct in_addr netmask_addr; be32_t netmask; uint32_t server_off, broadcast_off, size_max; assert_return(server, -EINVAL); assert_return(address, -EINVAL); assert_return(address->s_addr != INADDR_ANY, -EINVAL); assert_return(prefixlen <= 32, -ERANGE); assert_return(server->address == INADDR_ANY, -EBUSY); assert_se(in_addr_prefixlen_to_netmask(&netmask_addr, prefixlen)); netmask = netmask_addr.s_addr; server_off = be32toh(address->s_addr & ~netmask); broadcast_off = be32toh(~netmask); /* the server address cannot be the subnet address */ assert_return(server_off != 0, -ERANGE); /* nor the broadcast address */ assert_return(server_off != broadcast_off, -ERANGE); /* 0 offset means we should set a default, we skip the first (subnet) address and take the next one */ if (offset == 0) offset = 1; size_max = (broadcast_off + 1) /* the number of addresses in the subnet */ - offset /* exclude the addresses before the offset */ - 1; /* exclude the last (broadcast) address */ /* The pool must contain at least one address */ assert_return(size_max >= 1, -ERANGE); if (size != 0) assert_return(size <= size_max, -ERANGE); else size = size_max; server->bound_leases = new0(DHCPLease*, size); if (!server->bound_leases) return -ENOMEM; server->pool_offset = offset; server->pool_size = size; server->address = address->s_addr; server->netmask = netmask; server->subnet = address->s_addr & netmask; if (server_off >= offset && server_off - offset < size) server->bound_leases[server_off - offset] = &server->invalid_lease; return 0; } bool sd_dhcp_server_is_running(sd_dhcp_server *server) { assert_return(server, false); return !!server->receive_message; } sd_dhcp_server *sd_dhcp_server_ref(sd_dhcp_server *server) { if (!server) return NULL; assert(server->n_ref >= 1); server->n_ref++; return server; } unsigned long client_id_hash_func(const void *p, const uint8_t hash_key[HASH_KEY_SIZE]) { uint64_t u; const DHCPClientId *id = p; assert(id); assert(id->length); assert(id->data); siphash24((uint8_t*) &u, id->data, id->length, hash_key); return (unsigned long) u; } int client_id_compare_func(const void *_a, const void *_b) { const DHCPClientId *a, *b; a = _a; b = _b; assert(!a->length || a->data); assert(!b->length || b->data); if (a->length != b->length) return a->length < b->length ? -1 : 1; return memcmp(a->data, b->data, a->length); } static const struct hash_ops client_id_hash_ops = { .hash = client_id_hash_func, .compare = client_id_compare_func }; static void dhcp_lease_free(DHCPLease *lease) { if (!lease) return; free(lease->client_id.data); free(lease); } sd_dhcp_server *sd_dhcp_server_unref(sd_dhcp_server *server) { DHCPLease *lease; if (!server) return NULL; assert(server->n_ref >= 1); server->n_ref--; if (server->n_ref > 0) return NULL; log_dhcp_server(server, "UNREF"); sd_dhcp_server_stop(server); sd_event_unref(server->event); free(server->timezone); free(server->dns); free(server->ntp); while ((lease = hashmap_steal_first(server->leases_by_client_id))) dhcp_lease_free(lease); hashmap_free(server->leases_by_client_id); free(server->bound_leases); free(server); return NULL; } int sd_dhcp_server_new(sd_dhcp_server **ret, int ifindex) { _cleanup_dhcp_server_unref_ sd_dhcp_server *server = NULL; assert_return(ret, -EINVAL); assert_return(ifindex > 0, -EINVAL); server = new0(sd_dhcp_server, 1); if (!server) return -ENOMEM; server->n_ref = 1; server->fd_raw = -1; server->fd = -1; server->address = htobe32(INADDR_ANY); server->netmask = htobe32(INADDR_ANY); server->ifindex = ifindex; server->leases_by_client_id = hashmap_new(&client_id_hash_ops); server->default_lease_time = DIV_ROUND_UP(DHCP_DEFAULT_LEASE_TIME_USEC, USEC_PER_SEC); server->max_lease_time = DIV_ROUND_UP(DHCP_MAX_LEASE_TIME_USEC, USEC_PER_SEC); *ret = server; server = NULL; return 0; } int sd_dhcp_server_attach_event(sd_dhcp_server *server, sd_event *event, int priority) { int r; assert_return(server, -EINVAL); assert_return(!server->event, -EBUSY); if (event) server->event = sd_event_ref(event); else { r = sd_event_default(&server->event); if (r < 0) return r; } server->event_priority = priority; return 0; } int sd_dhcp_server_detach_event(sd_dhcp_server *server) { assert_return(server, -EINVAL); server->event = sd_event_unref(server->event); return 0; } sd_event *sd_dhcp_server_get_event(sd_dhcp_server *server) { assert_return(server, NULL); return server->event; } int sd_dhcp_server_stop(sd_dhcp_server *server) { assert_return(server, -EINVAL); server->receive_message = sd_event_source_unref(server->receive_message); server->fd_raw = safe_close(server->fd_raw); server->fd = safe_close(server->fd); log_dhcp_server(server, "STOPPED"); return 0; } static int dhcp_server_send_unicast_raw(sd_dhcp_server *server, DHCPPacket *packet, size_t len) { union sockaddr_union link = { .ll.sll_family = AF_PACKET, .ll.sll_protocol = htons(ETH_P_IP), .ll.sll_ifindex = server->ifindex, .ll.sll_halen = ETH_ALEN, }; assert(server); assert(server->ifindex > 0); assert(server->address); assert(packet); assert(len > sizeof(DHCPPacket)); memcpy(&link.ll.sll_addr, &packet->dhcp.chaddr, ETH_ALEN); dhcp_packet_append_ip_headers(packet, server->address, DHCP_PORT_SERVER, packet->dhcp.yiaddr, DHCP_PORT_CLIENT, len); return dhcp_network_send_raw_socket(server->fd_raw, &link, packet, len); } static int dhcp_server_send_udp(sd_dhcp_server *server, be32_t destination, DHCPMessage *message, size_t len) { union sockaddr_union dest = { .in.sin_family = AF_INET, .in.sin_port = htobe16(DHCP_PORT_CLIENT), .in.sin_addr.s_addr = destination, }; struct iovec iov = { .iov_base = message, .iov_len = len, }; uint8_t cmsgbuf[CMSG_LEN(sizeof(struct in_pktinfo))] = {}; struct msghdr msg = { .msg_name = &dest, .msg_namelen = sizeof(dest.in), .msg_iov = &iov, .msg_iovlen = 1, .msg_control = cmsgbuf, .msg_controllen = sizeof(cmsgbuf), }; struct cmsghdr *cmsg; struct in_pktinfo *pktinfo; int r; assert(server); assert(server->fd > 0); assert(message); assert(len > sizeof(DHCPMessage)); cmsg = CMSG_FIRSTHDR(&msg); assert(cmsg); cmsg->cmsg_level = IPPROTO_IP; cmsg->cmsg_type = IP_PKTINFO; cmsg->cmsg_len = CMSG_LEN(sizeof(struct in_pktinfo)); /* we attach source interface and address info to the message rather than binding the socket. This will be mostly useful when we gain support for arbitrary number of server addresses */ pktinfo = (struct in_pktinfo*) CMSG_DATA(cmsg); assert(pktinfo); pktinfo->ipi_ifindex = server->ifindex; pktinfo->ipi_spec_dst.s_addr = server->address; r = sendmsg(server->fd, &msg, 0); if (r < 0) return -errno; return 0; } static bool requested_broadcast(DHCPRequest *req) { assert(req); return req->message->flags & htobe16(0x8000); } int dhcp_server_send_packet(sd_dhcp_server *server, DHCPRequest *req, DHCPPacket *packet, int type, size_t optoffset) { be32_t destination = INADDR_ANY; int r; assert(server); assert(req); assert(req->max_optlen); assert(optoffset <= req->max_optlen); assert(packet); r = dhcp_option_append(&packet->dhcp, req->max_optlen, &optoffset, 0, DHCP_OPTION_SERVER_IDENTIFIER, 4, &server->address); if (r < 0) return r; r = dhcp_option_append(&packet->dhcp, req->max_optlen, &optoffset, 0, DHCP_OPTION_END, 0, NULL); if (r < 0) return r; /* RFC 2131 Section 4.1 If the ’giaddr’ field in a DHCP message from a client is non-zero, the server sends any return messages to the ’DHCP server’ port on the BOOTP relay agent whose address appears in ’giaddr’. If the ’giaddr’ field is zero and the ’ciaddr’ field is nonzero, then the server unicasts DHCPOFFER and DHCPACK messages to the address in ’ciaddr’. If ’giaddr’ is zero and ’ciaddr’ is zero, and the broadcast bit is set, then the server broadcasts DHCPOFFER and DHCPACK messages to 0xffffffff. If the broadcast bit is not set and ’giaddr’ is zero and ’ciaddr’ is zero, then the server unicasts DHCPOFFER and DHCPACK messages to the client’s hardware address and ’yiaddr’ address. In all cases, when ’giaddr’ is zero, the server broadcasts any DHCPNAK messages to 0xffffffff. Section 4.3.2 If ’giaddr’ is set in the DHCPREQUEST message, the client is on a different subnet. The server MUST set the broadcast bit in the DHCPNAK, so that the relay agent will broadcast the DHCPNAK to the client, because the client may not have a correct network address or subnet mask, and the client may not be answering ARP requests. */ if (req->message->giaddr) { destination = req->message->giaddr; if (type == DHCP_NAK) packet->dhcp.flags = htobe16(0x8000); } else if (req->message->ciaddr && type != DHCP_NAK) destination = req->message->ciaddr; if (destination != INADDR_ANY) return dhcp_server_send_udp(server, destination, &packet->dhcp, sizeof(DHCPMessage) + optoffset); else if (requested_broadcast(req) || type == DHCP_NAK) return dhcp_server_send_udp(server, INADDR_BROADCAST, &packet->dhcp, sizeof(DHCPMessage) + optoffset); else /* we cannot send UDP packet to specific MAC address when the address is not yet configured, so must fall back to raw packets */ return dhcp_server_send_unicast_raw(server, packet, sizeof(DHCPPacket) + optoffset); } static int server_message_init(sd_dhcp_server *server, DHCPPacket **ret, uint8_t type, size_t *_optoffset, DHCPRequest *req) { _cleanup_free_ DHCPPacket *packet = NULL; size_t optoffset = 0; int r; assert(server); assert(ret); assert(_optoffset); assert(IN_SET(type, DHCP_OFFER, DHCP_ACK, DHCP_NAK)); packet = malloc0(sizeof(DHCPPacket) + req->max_optlen); if (!packet) return -ENOMEM; r = dhcp_message_init(&packet->dhcp, BOOTREPLY, be32toh(req->message->xid), type, ARPHRD_ETHER, req->max_optlen, &optoffset); if (r < 0) return r; packet->dhcp.flags = req->message->flags; packet->dhcp.giaddr = req->message->giaddr; memcpy(&packet->dhcp.chaddr, &req->message->chaddr, ETH_ALEN); *_optoffset = optoffset; *ret = packet; packet = NULL; return 0; } static int server_send_offer(sd_dhcp_server *server, DHCPRequest *req, be32_t address) { _cleanup_free_ DHCPPacket *packet = NULL; size_t offset; be32_t lease_time; int r; r = server_message_init(server, &packet, DHCP_OFFER, &offset, req); if (r < 0) return r; packet->dhcp.yiaddr = address; lease_time = htobe32(req->lifetime); r = dhcp_option_append(&packet->dhcp, req->max_optlen, &offset, 0, DHCP_OPTION_IP_ADDRESS_LEASE_TIME, 4, &lease_time); if (r < 0) return r; r = dhcp_option_append(&packet->dhcp, req->max_optlen, &offset, 0, DHCP_OPTION_SUBNET_MASK, 4, &server->netmask); if (r < 0) return r; r = dhcp_option_append(&packet->dhcp, req->max_optlen, &offset, 0, DHCP_OPTION_ROUTER, 4, &server->address); if (r < 0) return r; r = dhcp_server_send_packet(server, req, packet, DHCP_OFFER, offset); if (r < 0) return r; return 0; } static int server_send_ack(sd_dhcp_server *server, DHCPRequest *req, be32_t address) { _cleanup_free_ DHCPPacket *packet = NULL; size_t offset; be32_t lease_time; int r; r = server_message_init(server, &packet, DHCP_ACK, &offset, req); if (r < 0) return r; packet->dhcp.yiaddr = address; lease_time = htobe32(req->lifetime); r = dhcp_option_append(&packet->dhcp, req->max_optlen, &offset, 0, DHCP_OPTION_IP_ADDRESS_LEASE_TIME, 4, &lease_time); if (r < 0) return r; r = dhcp_option_append(&packet->dhcp, req->max_optlen, &offset, 0, DHCP_OPTION_SUBNET_MASK, 4, &server->netmask); if (r < 0) return r; r = dhcp_option_append(&packet->dhcp, req->max_optlen, &offset, 0, DHCP_OPTION_ROUTER, 4, &server->address); if (r < 0) return r; if (server->n_dns > 0) { r = dhcp_option_append( &packet->dhcp, req->max_optlen, &offset, 0, DHCP_OPTION_DOMAIN_NAME_SERVER, sizeof(struct in_addr) * server->n_dns, server->dns); if (r < 0) return r; } if (server->n_ntp > 0) { r = dhcp_option_append( &packet->dhcp, req->max_optlen, &offset, 0, DHCP_OPTION_NTP_SERVER, sizeof(struct in_addr) * server->n_ntp, server->ntp); if (r < 0) return r; } if (server->timezone) { r = dhcp_option_append( &packet->dhcp, req->max_optlen, &offset, 0, DHCP_OPTION_NEW_TZDB_TIMEZONE, strlen(server->timezone), server->timezone); if (r < 0) return r; } r = dhcp_server_send_packet(server, req, packet, DHCP_ACK, offset); if (r < 0) return r; return 0; } static int server_send_nak(sd_dhcp_server *server, DHCPRequest *req) { _cleanup_free_ DHCPPacket *packet = NULL; size_t offset; int r; r = server_message_init(server, &packet, DHCP_NAK, &offset, req); if (r < 0) return r; return dhcp_server_send_packet(server, req, packet, DHCP_NAK, offset); } static int server_send_forcerenew(sd_dhcp_server *server, be32_t address, be32_t gateway, uint8_t chaddr[]) { _cleanup_free_ DHCPPacket *packet = NULL; size_t optoffset = 0; int r; assert(server); assert(address != INADDR_ANY); assert(chaddr); packet = malloc0(sizeof(DHCPPacket) + DHCP_MIN_OPTIONS_SIZE); if (!packet) return -ENOMEM; r = dhcp_message_init(&packet->dhcp, BOOTREPLY, 0, DHCP_FORCERENEW, ARPHRD_ETHER, DHCP_MIN_OPTIONS_SIZE, &optoffset); if (r < 0) return r; r = dhcp_option_append(&packet->dhcp, DHCP_MIN_OPTIONS_SIZE, &optoffset, 0, DHCP_OPTION_END, 0, NULL); if (r < 0) return r; memcpy(&packet->dhcp.chaddr, chaddr, ETH_ALEN); r = dhcp_server_send_udp(server, address, &packet->dhcp, sizeof(DHCPMessage) + optoffset); if (r < 0) return r; return 0; } static int parse_request(uint8_t code, uint8_t len, const void *option, void *userdata) { DHCPRequest *req = userdata; assert(req); switch(code) { case DHCP_OPTION_IP_ADDRESS_LEASE_TIME: if (len == 4) req->lifetime = be32toh(*(be32_t*)option); break; case DHCP_OPTION_REQUESTED_IP_ADDRESS: if (len == 4) req->requested_ip = *(be32_t*)option; break; case DHCP_OPTION_SERVER_IDENTIFIER: if (len == 4) req->server_id = *(be32_t*)option; break; case DHCP_OPTION_CLIENT_IDENTIFIER: if (len >= 2) { uint8_t *data; data = memdup(option, len); if (!data) return -ENOMEM; free(req->client_id.data); req->client_id.data = data; req->client_id.length = len; } break; case DHCP_OPTION_MAXIMUM_MESSAGE_SIZE: if (len == 2) req->max_optlen = be16toh(*(be16_t*)option) - - sizeof(DHCPPacket); break; } return 0; } static void dhcp_request_free(DHCPRequest *req) { if (!req) return; free(req->client_id.data); free(req); } DEFINE_TRIVIAL_CLEANUP_FUNC(DHCPRequest*, dhcp_request_free); #define _cleanup_dhcp_request_free_ _cleanup_(dhcp_request_freep) static int ensure_sane_request(sd_dhcp_server *server, DHCPRequest *req, DHCPMessage *message) { assert(req); assert(message); req->message = message; /* set client id based on MAC address if client did not send an explicit one */ if (!req->client_id.data) { void *data; data = malloc0(ETH_ALEN + 1); if (!data) return -ENOMEM; ((uint8_t*) data)[0] = 0x01; memcpy((uint8_t*) data + 1, &message->chaddr, ETH_ALEN); req->client_id.length = ETH_ALEN + 1; req->client_id.data = data; } if (req->max_optlen < DHCP_MIN_OPTIONS_SIZE) req->max_optlen = DHCP_MIN_OPTIONS_SIZE; if (req->lifetime <= 0) req->lifetime = MAX(1ULL, server->default_lease_time); if (server->max_lease_time > 0 && req->lifetime > server->max_lease_time) req->lifetime = server->max_lease_time; return 0; } static int get_pool_offset(sd_dhcp_server *server, be32_t requested_ip) { assert(server); if (!server->pool_size) return -EINVAL; if (be32toh(requested_ip) < (be32toh(server->subnet) | server->pool_offset) || be32toh(requested_ip) >= (be32toh(server->subnet) | (server->pool_offset + server->pool_size))) return -ERANGE; return be32toh(requested_ip & ~server->netmask) - server->pool_offset; } #define HASH_KEY SD_ID128_MAKE(0d,1d,fe,bd,f1,24,bd,b3,47,f1,dd,6e,73,21,93,30) int dhcp_server_handle_message(sd_dhcp_server *server, DHCPMessage *message, size_t length) { _cleanup_dhcp_request_free_ DHCPRequest *req = NULL; DHCPLease *existing_lease; int type, r; assert(server); assert(message); if (message->op != BOOTREQUEST || message->htype != ARPHRD_ETHER || message->hlen != ETHER_ADDR_LEN) return 0; req = new0(DHCPRequest, 1); if (!req) return -ENOMEM; type = dhcp_option_parse(message, length, parse_request, req); if (type < 0) return 0; r = ensure_sane_request(server, req, message); if (r < 0) /* this only fails on critical errors */ return r; existing_lease = hashmap_get(server->leases_by_client_id, &req->client_id); switch(type) { case DHCP_DISCOVER: { be32_t address = INADDR_ANY; unsigned i; log_dhcp_server(server, "DISCOVER (0x%x)", be32toh(req->message->xid)); if (!server->pool_size) /* no pool allocated */ return 0; /* for now pick a random free address from the pool */ if (existing_lease) address = existing_lease->address; else { uint32_t next_offer; /* even with no persistence of leases, we try to offer the same client the same IP address. we do this by using the hash of the client id as the offset into the pool of leases when finding the next free one */ next_offer = client_id_hash_func(&req->client_id, HASH_KEY.bytes) % server->pool_size; for (i = 0; i < server->pool_size; i++) { if (!server->bound_leases[next_offer]) { address = server->subnet | htobe32(server->pool_offset + next_offer); break; } else next_offer = (next_offer + 1) % server->pool_size; } } if (address == INADDR_ANY) /* no free addresses left */ return 0; r = server_send_offer(server, req, address); if (r < 0) { /* this only fails on critical errors */ log_dhcp_server(server, "could not send offer: %s", strerror(-r)); return r; } else { log_dhcp_server(server, "OFFER (0x%x)", be32toh(req->message->xid)); return DHCP_OFFER; } break; } case DHCP_DECLINE: log_dhcp_server(server, "DECLINE (0x%x)", be32toh(req->message->xid)); /* TODO: make sure we don't offer this address again */ return 1; case DHCP_REQUEST: { be32_t address; bool init_reboot = false; int pool_offset; /* see RFC 2131, section 4.3.2 */ if (req->server_id) { log_dhcp_server(server, "REQUEST (selecting) (0x%x)", be32toh(req->message->xid)); /* SELECTING */ if (req->server_id != server->address) /* client did not pick us */ return 0; if (req->message->ciaddr) /* this MUST be zero */ return 0; if (!req->requested_ip) /* this must be filled in with the yiaddr from the chosen OFFER */ return 0; address = req->requested_ip; } else if (req->requested_ip) { log_dhcp_server(server, "REQUEST (init-reboot) (0x%x)", be32toh(req->message->xid)); /* INIT-REBOOT */ if (req->message->ciaddr) /* this MUST be zero */ return 0; /* TODO: check more carefully if IP is correct */ address = req->requested_ip; init_reboot = true; } else { log_dhcp_server(server, "REQUEST (rebinding/renewing) (0x%x)", be32toh(req->message->xid)); /* REBINDING / RENEWING */ if (!req->message->ciaddr) /* this MUST be filled in with clients IP address */ return 0; address = req->message->ciaddr; } pool_offset = get_pool_offset(server, address); /* verify that the requested address is from the pool, and either owned by the current client or free */ if (pool_offset >= 0 && server->bound_leases[pool_offset] == existing_lease) { DHCPLease *lease; usec_t time_now = 0; if (!existing_lease) { lease = new0(DHCPLease, 1); lease->address = req->requested_ip; lease->client_id.data = memdup(req->client_id.data, req->client_id.length); if (!lease->client_id.data) { free(lease); return -ENOMEM; } lease->client_id.length = req->client_id.length; memcpy(&lease->chaddr, &req->message->chaddr, ETH_ALEN); lease->gateway = req->message->giaddr; } else lease = existing_lease; r = sd_event_now(server->event, clock_boottime_or_monotonic(), &time_now); if (r < 0) { if (!existing_lease) dhcp_lease_free(lease); return r; } lease->expiration = req->lifetime * USEC_PER_SEC + time_now; r = server_send_ack(server, req, address); if (r < 0) { /* this only fails on critical errors */ log_dhcp_server(server, "could not send ack: %s", strerror(-r)); if (!existing_lease) dhcp_lease_free(lease); return r; } else { log_dhcp_server(server, "ACK (0x%x)", be32toh(req->message->xid)); server->bound_leases[pool_offset] = lease; hashmap_put(server->leases_by_client_id, &lease->client_id, lease); return DHCP_ACK; } } else if (init_reboot) { r = server_send_nak(server, req); if (r < 0) { /* this only fails on critical errors */ log_dhcp_server(server, "could not send nak: %s", strerror(-r)); return r; } else { log_dhcp_server(server, "NAK (0x%x)", be32toh(req->message->xid)); return DHCP_NAK; } } break; } case DHCP_RELEASE: { int pool_offset; log_dhcp_server(server, "RELEASE (0x%x)", be32toh(req->message->xid)); if (!existing_lease) return 0; if (existing_lease->address != req->message->ciaddr) return 0; pool_offset = get_pool_offset(server, req->message->ciaddr); if (pool_offset < 0) return 0; if (server->bound_leases[pool_offset] == existing_lease) { server->bound_leases[pool_offset] = NULL; hashmap_remove(server->leases_by_client_id, existing_lease); dhcp_lease_free(existing_lease); return 1; } else return 0; } } return 0; } static int server_receive_message(sd_event_source *s, int fd, uint32_t revents, void *userdata) { _cleanup_free_ DHCPMessage *message = NULL; uint8_t cmsgbuf[CMSG_LEN(sizeof(struct in_pktinfo))]; sd_dhcp_server *server = userdata; struct iovec iov = {}; struct msghdr msg = { .msg_iov = &iov, .msg_iovlen = 1, .msg_control = cmsgbuf, .msg_controllen = sizeof(cmsgbuf), }; struct cmsghdr *cmsg; int buflen = 0, len; assert(server); if (ioctl(fd, FIONREAD, &buflen) < 0) return -errno; if (buflen < 0) return -EIO; message = malloc0(buflen); if (!message) return -ENOMEM; iov.iov_base = message; iov.iov_len = buflen; len = recvmsg(fd, &msg, 0); if (len < buflen) return 0; else if ((size_t)len < sizeof(DHCPMessage)) return 0; CMSG_FOREACH(cmsg, &msg) { if (cmsg->cmsg_level == IPPROTO_IP && cmsg->cmsg_type == IP_PKTINFO && cmsg->cmsg_len == CMSG_LEN(sizeof(struct in_pktinfo))) { struct in_pktinfo *info = (struct in_pktinfo*)CMSG_DATA(cmsg); /* TODO figure out if this can be done as a filter on * the socket, like for IPv6 */ if (server->ifindex != info->ipi_ifindex) return 0; break; } } return dhcp_server_handle_message(server, message, (size_t)len); } int sd_dhcp_server_start(sd_dhcp_server *server) { int r; assert_return(server, -EINVAL); assert_return(server->event, -EINVAL); assert_return(!server->receive_message, -EBUSY); assert_return(server->fd_raw == -1, -EBUSY); assert_return(server->fd == -1, -EBUSY); assert_return(server->address != htobe32(INADDR_ANY), -EUNATCH); r = socket(AF_PACKET, SOCK_DGRAM | SOCK_NONBLOCK, 0); if (r < 0) { r = -errno; sd_dhcp_server_stop(server); return r; } server->fd_raw = r; r = dhcp_network_bind_udp_socket(INADDR_ANY, DHCP_PORT_SERVER); if (r < 0) { sd_dhcp_server_stop(server); return r; } server->fd = r; r = sd_event_add_io(server->event, &server->receive_message, server->fd, EPOLLIN, server_receive_message, server); if (r < 0) { sd_dhcp_server_stop(server); return r; } r = sd_event_source_set_priority(server->receive_message, server->event_priority); if (r < 0) { sd_dhcp_server_stop(server); return r; } log_dhcp_server(server, "STARTED"); return 0; } int sd_dhcp_server_forcerenew(sd_dhcp_server *server) { unsigned i; int r = 0; assert_return(server, -EINVAL); assert(server->bound_leases); for (i = 0; i < server->pool_size; i++) { DHCPLease *lease = server->bound_leases[i]; if (!lease || lease == &server->invalid_lease) continue; r = server_send_forcerenew(server, lease->address, lease->gateway, lease->chaddr); if (r < 0) return r; else log_dhcp_server(server, "FORCERENEW"); } return r; } int sd_dhcp_server_set_timezone(sd_dhcp_server *server, const char *timezone) { int r; assert_return(server, -EINVAL); assert_return(timezone_is_valid(timezone), -EINVAL); if (streq_ptr(timezone, server->timezone)) return 0; r = free_and_strdup(&server->timezone, timezone); if (r < 0) return r; return 1; } int sd_dhcp_server_set_max_lease_time(sd_dhcp_server *server, uint32_t t) { assert_return(server, -EINVAL); if (t == server->max_lease_time) return 0; server->max_lease_time = t; return 1; } int sd_dhcp_server_set_default_lease_time(sd_dhcp_server *server, uint32_t t) { assert_return(server, -EINVAL); if (t == server->default_lease_time) return 0; server->default_lease_time = t; return 1; } int sd_dhcp_server_set_dns(sd_dhcp_server *server, const struct in_addr dns[], unsigned n) { assert_return(server, -EINVAL); assert_return(dns || n <= 0, -EINVAL); if (server->n_dns == n && memcmp(server->dns, dns, sizeof(struct in_addr) * n) == 0) return 0; if (n <= 0) { server->dns = mfree(server->dns); server->n_dns = 0; } else { struct in_addr *c; c = newdup(struct in_addr, dns, n); if (!c) return -ENOMEM; free(server->dns); server->dns = c; server->n_dns = n; } return 1; } int sd_dhcp_server_set_ntp(sd_dhcp_server *server, const struct in_addr ntp[], unsigned n) { assert_return(server, -EINVAL); assert_return(ntp || n <= 0, -EINVAL); if (server->n_ntp == n && memcmp(server->ntp, ntp, sizeof(struct in_addr) * n) == 0) return 0; if (n <= 0) { server->ntp = mfree(server->ntp); server->n_ntp = 0; } else { struct in_addr *c; c = newdup(struct in_addr, ntp, n); if (!c) return -ENOMEM; free(server->ntp); server->ntp = c; server->n_ntp = n; } return 1; }