diff options
31 files changed, 7653 insertions, 62 deletions
diff --git a/accel-pppd/CMakeLists.txt b/accel-pppd/CMakeLists.txt index a65f7fef..787dbd8c 100644 --- a/accel-pppd/CMakeLists.txt +++ b/accel-pppd/CMakeLists.txt @@ -66,6 +66,9 @@ ADD_EXECUTABLE(accel-pppd cli/telnet.c cli/tcp.c cli/cli.c + + libnetlink/libnetlink.c + libnetlink/iplink.c pwdb.c ipdb.c diff --git a/accel-pppd/ctrl/CMakeLists.txt b/accel-pppd/ctrl/CMakeLists.txt index 6b37bc4a..9b6a11d6 100644 --- a/accel-pppd/ctrl/CMakeLists.txt +++ b/accel-pppd/ctrl/CMakeLists.txt @@ -1,3 +1,4 @@ ADD_SUBDIRECTORY(pptp) ADD_SUBDIRECTORY(pppoe) ADD_SUBDIRECTORY(l2tp) +ADD_SUBDIRECTORY(ipoe) diff --git a/accel-pppd/ctrl/ipoe/CMakeLists.txt b/accel-pppd/ctrl/ipoe/CMakeLists.txt new file mode 100644 index 00000000..e2b71cbc --- /dev/null +++ b/accel-pppd/ctrl/ipoe/CMakeLists.txt @@ -0,0 +1,24 @@ +INCLUDE_DIRECTORIES(${CMAKE_CURRENT_SOURCE_DIR}) + +SET(sources + ipoe.c + dhcpv4.c + dhcpv4_options.c +) + +IF (LUA) + include(FindLua51) + IF (NOT LUA51_FOUND) + MESSAGE(FATAL_ERROR "lua not found") + ENDIF (NOT LUA51_FOUND) + INCLUDE_DIRECTORIES(${LUA_INCLUDE_DIR}) + ADD_DEFINITIONS(-DUSE_LUA) + SET(sources ${sources} lua.c lua_lpack.c) +ENDIF (LUA) + +ADD_LIBRARY(ipoe SHARED ${sources}) +IF (LUA) + TARGET_LINK_LIBRARIES(ipoe ${LUA_LIBRARIES}) +ENDIF(LUA) + +INSTALL(TARGETS ipoe LIBRARY DESTINATION lib/accel-ppp) diff --git a/accel-pppd/ctrl/ipoe/dhcpv4.c b/accel-pppd/ctrl/ipoe/dhcpv4.c new file mode 100644 index 00000000..2955d6cd --- /dev/null +++ b/accel-pppd/ctrl/ipoe/dhcpv4.c @@ -0,0 +1,538 @@ +#include <unistd.h> +#include <stdlib.h> +#include <stdio.h> +#include <errno.h> +#include <string.h> +#include <pthread.h> +#include <fcntl.h> +#include <sys/socket.h> +#include <sys/ioctl.h> +#include <net/ethernet.h> +#include <netinet/ip.h> +#include <netinet/udp.h> +#include <netpacket/packet.h> +#include <arpa/inet.h> +#include <linux/if.h> + +#include "events.h" +#include "list.h" +#include "triton.h" +#include "log.h" +#include "mempool.h" +#include "memdebug.h" +#include "ap_session.h" +#include "ipdb.h" + +#include "dhcpv4.h" + +#define DHCP_SERV_PORT 67 +#define DHCP_CLIENT_PORT 68 +#define DHCP_MAGIC "\x63\x82\x53\x63" + + +#define BUF_SIZE 4096 + + +static int conf_verbose; + +static mempool_t pack_pool; +static mempool_t opt_pool; + +static int dhcpv4_read(struct triton_md_handler_t *h); + +struct dhcpv4_serv *dhcpv4_create(struct triton_context_t *ctx, const char *ifname) +{ + struct dhcpv4_serv *serv; + int sock, raw_sock; + struct sockaddr_in addr; + struct sockaddr_ll ll_addr; + struct ifreq ifr; + int f = 1; + + memset(&ifr, 0, sizeof(ifr)); + + strncpy(ifr.ifr_name, ifname, sizeof(ifr.ifr_name)); + if (ioctl(sock_fd, SIOCGIFINDEX, &ifr)) { + log_error("dhcpv4(%s): ioctl(SIOCGIFINDEX): %s\n", ifname, strerror(errno)); + return NULL; + } + + raw_sock = socket(AF_PACKET, SOCK_RAW, ntohs(ETH_P_IP)); + if (raw_sock < 0) { + log_error("dhcpv4: packet socket is not supported by kernel\n"); + return NULL; + } + + memset(&ll_addr, 0, sizeof(ll_addr)); + ll_addr.sll_family = AF_PACKET; + ll_addr.sll_ifindex = ifr.ifr_ifindex; + ll_addr.sll_protocol = ntohs(ETH_P_IP); + + if (bind(raw_sock, (struct sockaddr *)&ll_addr, sizeof(ll_addr))) { + log_error("dhcpv4(%s): bind: %s\n", ifname, strerror(errno)); + close(raw_sock); + return NULL; + } + + memset(&addr, 0, sizeof(addr)); + + addr.sin_family = AF_INET; + addr.sin_port = htons(DHCP_SERV_PORT); + addr.sin_addr.s_addr = htonl(INADDR_ANY); + + sock = socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP); + + if (setsockopt(sock, SOL_SOCKET, SO_REUSEADDR, &f, sizeof(f))) + log_error("setsockopt(SO_REUSEADDR): %s\n", strerror(errno)); + + + if (setsockopt(sock, SOL_SOCKET, SO_BROADCAST, &f, sizeof(f))) { + log_error("setsockopt(SO_BROADCAST): %s\n", strerror(errno)); + goto out_err; + } + + if (bind(sock, &addr, sizeof(addr))) { + log_error("bind: %s\n", strerror(errno)); + goto out_err; + } + + if (setsockopt(sock, SOL_SOCKET, SO_BINDTODEVICE, ifname, strlen(ifname))) { + log_error("setsockopt(SO_BINDTODEVICE): %s\n", strerror(errno)); + goto out_err; + } + + if (ioctl(sock, SIOCGIFHWADDR, &ifr)) { + log_error("dhcpv4(%s): ioctl(SIOCGIFHWADDR): %s\n", ifname, strerror(errno)); + goto out_err; + } + + memcpy(serv->hwaddr, ifr.ifr_hwaddr.sa_data, ETH_ALEN); + + fcntl(raw_sock, F_SETFL, O_NONBLOCK); + fcntl(raw_sock, F_SETFD, fcntl(sock, F_GETFD) | FD_CLOEXEC); + + fcntl(sock, F_SETFL, O_NONBLOCK); + fcntl(sock, F_SETFD, fcntl(sock, F_GETFD) | FD_CLOEXEC); + + serv = _malloc(sizeof(*serv)); + memset(serv, 0, sizeof(*serv)); + + serv->ctx = ctx; + serv->hnd.fd = sock; + serv->hnd.read = dhcpv4_read; + serv->raw_sock = raw_sock; + + triton_md_register_handler(ctx, &serv->hnd); + triton_md_enable_handler(&serv->hnd, MD_MODE_READ); + + return serv; + +out_err: + close(raw_sock); + close(sock); + return NULL; +} + +void dhcpv4_free(struct dhcpv4_serv *serv) +{ + triton_md_unregister_handler(&serv->hnd); + close(serv->hnd.fd); + _free(serv); +} + +void dhcpv4_print_packet(struct dhcpv4_packet *pack, void (*print)(const char *fmt, ...)) +{ + const char *msg_name[] = {"Discover", "Offer", "Request", "Decline", "Ack", "Nak", "Release", "Inform"}; + + print("[DHCPv4 %s xid=%x ", msg_name[pack->msg_type - 1], pack->hdr->xid); + + if (pack->hdr->ciaddr) + print("ciaddr=%i.%i.%i.%i ", + pack->hdr->ciaddr & 0xff, + (pack->hdr->ciaddr >> 8) & 0xff, + (pack->hdr->ciaddr >> 16) & 0xff, + (pack->hdr->ciaddr >> 24) & 0xff); + + if (pack->hdr->yiaddr) + print("yiaddr=%i.%i.%i.%i ", + pack->hdr->yiaddr & 0xff, + (pack->hdr->yiaddr >> 8) & 0xff, + (pack->hdr->yiaddr >> 16) & 0xff, + (pack->hdr->yiaddr >> 24) & 0xff); + + if (pack->hdr->siaddr) + print("ciaddr=%i.%i.%i.%i ", + pack->hdr->siaddr & 0xff, + (pack->hdr->siaddr >> 8) & 0xff, + (pack->hdr->siaddr >> 16) & 0xff, + (pack->hdr->siaddr >> 24) & 0xff); + + if (pack->hdr->giaddr) + print("giaddr=%i.%i.%i.%i ", + pack->hdr->giaddr & 0xff, + (pack->hdr->giaddr >> 8) & 0xff, + (pack->hdr->giaddr >> 16) & 0xff, + (pack->hdr->giaddr >> 24) & 0xff); + + print("chaddr=%02x:%02x:%02x:%02x:%02x:%02x ", + pack->hdr->chaddr[0], + pack->hdr->chaddr[1], + pack->hdr->chaddr[2], + pack->hdr->chaddr[3], + pack->hdr->chaddr[4], + pack->hdr->chaddr[5], + pack->hdr->chaddr[6]); + + dhcpv4_print_options(pack, print); + + print("]\n"); +} + +static int parse_opt82(struct dhcpv4_packet *pack, struct dhcpv4_option *opt) +{ + uint8_t *ptr = opt->data; + uint8_t *endptr = ptr + opt->len; + int type, len; + struct dhcpv4_option *opt1; + + while (ptr < endptr) { + type = *ptr++; + len = *ptr++; + if (ptr + len > endptr) + return -1; + if (type == 1 || type == 2) { + opt1 = mempool_alloc(opt_pool); + if (!opt1) { + log_emerg("out of memory\n"); + return -1; + } + + opt1->type = type; + opt1->len = len; + opt1->data = ptr; + + if (type == 1) + pack->agent_circuit_id = opt1; + else + pack->agent_remote_id = opt1; + } + + ptr += len; + } + + return 0; +} + +static int dhcpv4_parse_packet(struct dhcpv4_packet *pack, int len) +{ + struct dhcpv4_option *opt; + uint8_t *ptr, *endptr = pack->data + len; + + if (len < sizeof(struct dhcpv4_hdr)) { + if (conf_verbose) + log_warn("dhcpv4: short packet received\n"); + return -1; + } + + if (pack->hdr->op != DHCP_OP_REQUEST) + return -1; + + if (pack->hdr->htype != 1) + return -1; + + if (pack->hdr->hlen != 6) + return -1; + + if (memcmp(pack->hdr->magic, DHCP_MAGIC, 4)) + return -1; + + ptr = pack->data + sizeof(struct dhcpv4_hdr); + + while (ptr < endptr) { + if (*ptr == 0) { + ptr++; + continue; + } + + if (*ptr == 0xff) + break; + + opt = mempool_alloc(opt_pool); + if (!opt) { + log_emerg("out of memory\n"); + return -1; + } + memset(opt, 0, sizeof(*opt)); + opt->type = *ptr++; + opt->len = *ptr++; + opt->data = ptr; + ptr += opt->len; + + if (ptr > endptr) + return -1; + + list_add_tail(&opt->entry, &pack->options); + + if (opt->type == 53) + pack->msg_type = opt->data[0]; + else if (opt->type == 82) + parse_opt82(pack, opt); + else if (opt->type == 50) + pack->request_ip = *(uint32_t *)opt->data; + else if (opt->type == 54) + pack->server_id = *(uint32_t *)opt->data; + } + + if (pack->msg_type == 0 || pack->msg_type > 8) + return -1; + + if (dhcpv4_check_options(pack)) + return -1; + + /*if (conf_verbose) { + log_info2("recv "); + print_packet(pack, log_info2); + }*/ + + return 0; +} + +static struct dhcpv4_packet *dhcpv4_packet_alloc() +{ + struct dhcpv4_packet *pack = mempool_alloc(pack_pool); + + if (!pack) + return NULL; + + memset(pack, 0, sizeof(*pack)); + + INIT_LIST_HEAD(&pack->options); + + pack->hdr = (struct dhcpv4_hdr *)pack->data; + pack->ptr = (uint8_t *)(pack->hdr + 1); + + memcpy(pack->hdr->magic, DHCP_MAGIC, 4); + + return pack; +} + +static int dhcpv4_read(struct triton_md_handler_t *h) +{ + struct dhcpv4_packet *pack; + struct dhcpv4_serv *serv = container_of(h, typeof(*serv), hnd); + struct sockaddr_in addr; + socklen_t len; + int n; + + while (1) { + pack = dhcpv4_packet_alloc(); + if (!pack) { + log_emerg("out of memory\n"); + return 1; + } + + len = sizeof(addr); + n = recvfrom(h->fd, pack->data, BUF_SIZE, 0, &addr, &len); + if (n == -1) { + mempool_free(pack); + if (errno == EAGAIN) + return 0; + log_error("dhcpv4: recv: %s\n", strerror(errno)); + continue; + } + + if (dhcpv4_parse_packet(pack, n)) { + dhcpv4_packet_free(pack); + continue; + } + + if (serv->recv) + serv->recv(serv, pack); + } +} + +uint16_t ip_csum(uint16_t *buf, int len) +{ + uint32_t sum=0; + int i; + + for (i=0; i < len; i += 2) + sum += *buf++; + + // take only 16 bits out of the 32 bit sum and add up the carries + while (sum >> 16) + sum = (sum & 0xffff) + (sum >> 16); + + // one's complement the result + sum = ~sum; + + return sum & 0xffff; +} + + +static int dhcpv4_send(struct dhcpv4_serv *serv, struct dhcpv4_packet *pack, in_addr_t saddr, in_addr_t daddr) +{ + uint8_t hdr[sizeof(struct ether_header) + sizeof(struct iphdr) + sizeof(struct udphdr)]; + struct ether_header *eth = (struct ether_header *)hdr; + struct iphdr *ip = (struct iphdr *)(eth + 1); + struct udphdr *udp = (struct udphdr *)(ip + 1); + int len = pack->ptr - pack->data; + struct iovec iov[2]; + + memcpy(eth->ether_dhost, pack->hdr->chaddr, ETH_ALEN); + memcpy(eth->ether_shost, serv->hwaddr, ETH_ALEN); + eth->ether_type = htons(ETH_P_IP); + + ip->ihl = 5; + ip->version = 4; + ip->tos = 0x10; + ip->tot_len = ntohs(sizeof(*ip) + sizeof(*udp) + len); + ip->id = 0; + ip->frag_off = 0; + ip->ttl = 128; + ip->protocol = IPPROTO_UDP; + ip->check = 0; + ip->saddr = saddr; + ip->daddr = daddr; + ip->check = ip_csum((uint16_t *)ip, 20); + + udp->source = ntohs(DHCP_SERV_PORT); + udp->dest = ntohs(DHCP_CLIENT_PORT); + udp->len = htons(sizeof(*udp) + len); + udp->check = 0; + + iov[0].iov_base = hdr; + iov[0].iov_len = sizeof(hdr); + iov[1].iov_base = pack->data; + iov[1].iov_len = len; + + len = writev(serv->raw_sock, iov, 2); + + if (len < 0) + return -1; + + return 0; +} + +void dhcpv4_packet_free(struct dhcpv4_packet *pack) +{ + struct dhcpv4_option *opt; + + while (!list_empty(&pack->options)) { + opt = list_entry(pack->options.next, typeof(*opt), entry); + list_del(&opt->entry); + mempool_free(opt); + } + + if (pack->agent_circuit_id) + mempool_free(pack->agent_circuit_id); + + if (pack->agent_remote_id) + mempool_free(pack->agent_remote_id); + + mempool_free(pack); +} + +int dhcpv4_packet_add_opt(struct dhcpv4_packet *pack, int type, const void *data, int len) +{ + struct dhcpv4_option *opt = mempool_alloc(opt_pool); + + if (!opt) { + log_emerg("out of memory\n"); + return -1; + } + + *pack->ptr++ = type; + *pack->ptr++ = len; + + opt->type = type; + opt->len = len; + opt->data = pack->ptr; + pack->ptr += len; + + memcpy(opt->data, data, len); + + list_add_tail(&opt->entry, &pack->options); + + return 0; +} + +int dhcpv4_send_reply(int msg_type, struct dhcpv4_serv *serv, struct dhcpv4_packet *req, struct ap_session *ses, int lease_time) +{ + struct dhcpv4_packet *pack; + int val, r; + + pack = dhcpv4_packet_alloc(); + if (!pack) { + log_emerg("out of memory\n"); + return -1; + } + + memcpy(pack->hdr, req->hdr, sizeof(*req->hdr)); + + pack->hdr->op = DHCP_OP_REPLY; + pack->hdr->yiaddr = ses->ipv4->peer_addr; + pack->hdr->siaddr = ses->ipv4->addr; + + if (dhcpv4_packet_add_opt(pack, 53, &msg_type, 1)) + goto out_err; + + if (dhcpv4_packet_add_opt(pack, 54, &ses->ipv4->addr, 4)) + goto out_err; + + val = ntohl(lease_time); + if (dhcpv4_packet_add_opt(pack, 51, &val, 4)) + goto out_err; + + if (dhcpv4_packet_add_opt(pack, 3, &ses->ipv4->addr, 4)) + goto out_err; + + val = htonl(~((1 << (32 - ses->ipv4->mask)) - 1)); + if (dhcpv4_packet_add_opt(pack, 1, &val, 4)) + goto out_err; + + *pack->ptr++ = 255; + + if (conf_verbose) { + pack->msg_type = msg_type; + log_ppp_info2("send "); + dhcpv4_print_packet(pack, log_ppp_info2); + } + + r = dhcpv4_send(serv, pack, ses->ipv4->addr, ses->ipv4->peer_addr); + + dhcpv4_packet_free(pack); + + return r; + +out_err: + dhcpv4_packet_free(pack); + return -1; +} + +int dhcpv4_send_nak(struct dhcpv4_serv *serv, struct dhcpv4_packet *req) +{ + + return 0; +} + +static void load_config() +{ + const char *opt; + + opt = conf_get_opt("ipoe", "verbose"); + if (opt) + conf_verbose = atoi(opt); +} + +static void init() +{ + pack_pool = mempool_create(BUF_SIZE + sizeof(struct dhcpv4_packet)); + opt_pool = mempool_create(sizeof(struct dhcpv4_option)); + + load_config(); + + triton_event_register_handler(EV_CONFIG_RELOAD, (triton_event_func)load_config); +} + +DEFINE_INIT(100, init); diff --git a/accel-pppd/ctrl/ipoe/dhcpv4.h b/accel-pppd/ctrl/ipoe/dhcpv4.h new file mode 100644 index 00000000..52e90a3e --- /dev/null +++ b/accel-pppd/ctrl/ipoe/dhcpv4.h @@ -0,0 +1,89 @@ +#ifndef __DHCPV4_H +#define __DHCPV4_H + +#include <stdint.h> +#include "list.h" + +#include "triton.h" + +#define __packed __attribute__((packed)) + +#define DHCP_OP_REQUEST 1 +#define DHCP_OP_REPLY 2 + +#define DHCPDISCOVER 1 +#define DHCPOFFER 2 +#define DHCPREQUEST 3 +#define DHCPDECLINE 4 +#define DHCPACK 5 +#define DHCPNAK 6 +#define DHCPRELEASE 7 +#define DHCPINFORM 8 + +struct dhcpv4_hdr +{ + uint8_t op; + uint8_t htype; + uint8_t hlen; + uint8_t hops; + uint32_t xid; + uint16_t sec; + uint16_t flags; + uint32_t ciaddr; + uint32_t yiaddr; + uint32_t siaddr; + uint32_t giaddr; + uint8_t chaddr[16]; + char sname[64]; + char file[128]; + uint8_t magic[4]; +} __packed; + +struct dhcpv4_option +{ + struct list_head entry; + uint8_t type; + uint8_t len; + uint8_t *data; +}; + +struct dhcpv4_packet +{ + struct dhcpv4_hdr *hdr; + struct list_head options; + struct dhcpv4_option *client_id; + struct dhcpv4_option *agent_circuit_id; + struct dhcpv4_option *agent_remote_id; + uint32_t request_ip; + uint32_t server_id; + int msg_type; + uint8_t *ptr; + uint8_t data[0]; +}; + +struct dhcpv4_serv +{ + struct triton_context_t *ctx; + struct triton_md_handler_t hnd; + int raw_sock; + uint8_t hwaddr[6]; + void (*recv)(struct dhcpv4_serv *serv, struct dhcpv4_packet *pack); +}; + +struct ap_session; + +struct dhcpv4_serv *dhcpv4_create(struct triton_context_t *ctx, const char *ifname); +void dhcpv4_free(struct dhcpv4_serv *); + + +int dhcpv4_send_reply(int msg_type, struct dhcpv4_serv *serv, struct dhcpv4_packet *req, struct ap_session *ses, int lease_time); +int dhcpv4_send_nak(struct dhcpv4_serv *serv, struct dhcpv4_packet *req); + +void dhcpv4_packet_free(struct dhcpv4_packet *pack); + +int dhcpv4_check_options(struct dhcpv4_packet *); +void dhcpv4_print_options(struct dhcpv4_packet *, void (*)(const char *, ...)); + +void dhcpv4_print_packet(struct dhcpv4_packet *pack, void (*print)(const char *fmt, ...)); + +#endif diff --git a/accel-pppd/ctrl/ipoe/dhcpv4_options.c b/accel-pppd/ctrl/ipoe/dhcpv4_options.c new file mode 100644 index 00000000..82e64902 --- /dev/null +++ b/accel-pppd/ctrl/ipoe/dhcpv4_options.c @@ -0,0 +1,290 @@ +#include <unistd.h> +#include <stdlib.h> +#include <stdio.h> +#include <string.h> +#include <ctype.h> +#include <arpa/inet.h> + +#include "dhcpv4.h" + +struct known_option +{ + int type; + int min_len; + int max_len; + int elem_size; + const char *name; + void (*print)(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +}; + +static void print_int(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +static void print_uint(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +static void print_ip(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +static void print_str(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +static void print_hex(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +static void print_route(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +static void print_classless_route(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +static void print_message_type(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +static void print_request_list(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); +static void print_relay_agent(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)); + +static struct known_option options[] = { + { 1, 4, 4, 4, "Subnet", print_ip }, + { 2, 4, 4, 4, "Time-Offset", print_int }, + { 3, 4, 255, 4, "Router", print_ip }, + { 4, 4, 255, 4, "Time-Server", print_ip }, + { 5, 4, 255, 4, "Name-Server", print_ip }, + { 6, 4, 255, 4, "DNS", print_ip }, + //{ 7, 4, 255, 4, "log-server", print_ip }, + //{ 8, 4, 255, 4, "cookie-server", print_ip }, + //{ 9, 4, 255, 4, "lpr-server", print_ip }, + //{ 10, 4, 255, 4, "impress-server", print_ip }, + //{ 11, 4, 255, 4, "resourse-location", print_ip }, + { 12, 1, 255, 1, "Host-Name", print_str }, + //{ 13, 4, 255, 4, "impress-server", print_ip }, + { 15, 1, 255, 1, "Domain-Name", print_str }, + { 26, 2, 2, 2, "MTU", print_int }, + { 28, 4, 4, 4, "Broadcast", print_ip }, + { 33, 8, 255, 8, "Route", print_route }, + { 42, 4, 4, 4, "NTP", print_ip }, + { 43, 1, 255, 1, "Vendor-Specific", print_hex }, + { 50, 4, 4, 4, "Request-IP", print_ip }, + { 51, 4, 4, 4, "Lease-Time", print_uint }, + { 53, 1, 1, 1, "Message-Type", print_message_type }, + { 54, 4, 4, 4, "Server-ID", print_ip }, + { 55, 1, 255, 1, "Request-List", print_request_list }, + { 56, 1, 255, 1, "Message", print_str }, + { 57, 2, 2, 2, "Max-Message-Size", print_uint }, + { 58, 4, 4, 4, "T1", print_uint }, + { 59, 4, 4, 4, "T2", print_uint }, + { 60, 1, 255, 1, "Vendor-Class", print_hex }, + { 61, 2, 255, 1, "Client-ID", print_hex }, + { 82, 3, 255, 1, "Relay-Agent", print_relay_agent }, + { 121, 5, 255, 1, "Classless-Route", print_classless_route }, + { 0 }, +}; + +int dhcpv4_check_options(struct dhcpv4_packet *pack) +{ + struct dhcpv4_option *opt; + struct known_option *kopt; + + list_for_each_entry(opt, &pack->options, entry) { + for (kopt = options; kopt->type; kopt++) { + if (kopt->type != opt->type) + continue; + if (opt->len < kopt->min_len) + return -1; + if (opt->len > kopt->max_len) + return -1; + if (opt->len % kopt->elem_size != 0) + return -1; + break; + } + } + + return 0; +} + +void dhcpv4_print_options(struct dhcpv4_packet *pack, void (*print)(const char *fmt, ...)) +{ + struct dhcpv4_option *opt; + struct known_option *kopt; + int n = 0; + + list_for_each_entry(opt, &pack->options, entry) { + if (n) + print(" <"); + else + print("<"); + n++; + for (kopt = options; kopt->type && kopt->type != opt->type; kopt++); + if (kopt->type) { + print("%s ", kopt->name); + kopt->print(opt, kopt->elem_size, print); + } else { + print("Option-%i "); + print_hex(opt, 1, print); + } + print(">"); + } +} + + +static void print_int(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + if (opt->len == 2) + print("%i", ntohs(*(int16_t *)(opt->data))); + else + print("%i", ntohl(*(int32_t *)(opt->data))); +} + +static void print_uint(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + if (opt->len == 2) + print("%u", ntohs(*(uint16_t *)(opt->data))); + else + print("%u", ntohl(*(uint32_t *)(opt->data))); +} + +static void print_ip(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + int i, n = opt->len / elem_size; + uint32_t ip; + + for (i = 0; i < n; i++) { + ip = ntohl(*(uint32_t *)(opt->data + i*elem_size)); + + if (i) + print(","); + + print("%i.%i.%i.%i", + (ip >> 24) & 0xff, + (ip >> 16) & 0xff, + (ip >> 8) & 0xff, + ip & 0xff); + } +} + +static void print_str(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + const char *ptr = (const char *)opt->data; + const char *endptr = ptr + opt->len; + + for(; ptr < endptr; ptr++) + print("%c", *ptr); +} + +static void print_hex(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + const uint8_t *ptr = opt->data; + const uint8_t *endptr = ptr + opt->len; + + for(; ptr < endptr; ptr++) + print("%02x", *ptr); +} + +static void print_route(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + int i, n = opt->len / 8; + uint32_t ip, gw; + + for (i = 0; i < n; i++) { + ip = ntohl(*(uint32_t *)(opt->data + i*8)); + gw = ntohl(*(uint32_t *)(opt->data + i*8 + 4)); + + if (i) + print(","); + + print("%i.%i.%i.%i via %i.%i.%i.%i", + (ip >> 24) & 0xff, + (ip >> 16) & 0xff, + (ip >> 8) & 0xff, + ip & 0xff, + (gw >> 24) & 0xff, + (gw >> 16) & 0xff, + (gw >> 8) & 0xff, + gw & 0xff); + } +} + +static void print_message_type(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + const char *msg_name[] = {"", "Discover", "Offer", "Request", "Decline", "Ack", "Nak", "Release", "Inform"}; + + print("%s", msg_name[opt->data[0]]); +} + +static void print_request_list(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + int i; + struct known_option *kopt; + + for (i = 0; i < opt->len; i++) { + if (i) + print(","); + for (kopt = options; kopt->type && kopt->type != opt->data[i]; kopt++); + if (kopt->type) + print("%s", kopt->name); + else + print("%i", opt->data[i]); + } +} + +static void print_relay_agent(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + const uint8_t *ptr = opt->data; + const uint8_t *endptr = ptr + opt->len; + const uint8_t *endptr1; + int type, len; + + while (ptr < endptr) { + if (ptr != opt->data) + print(" "); + type = *ptr++; + len = *ptr++; + /*if (ptr + len > endptr) { + print(" invalid"); + return; + }*/ + if (type == 1) + print("{Agent-Circuit-ID "); + else if (type == 2) + print("{Agent-Remote-ID "); + else + print("{Option-%i ", type); + + endptr1 = ptr + len; + for (;ptr < endptr1; ptr++) { + if (!isprint(*ptr)) { + print("_"); + break; + } + print("%c", *ptr); + } + for (;ptr < endptr1; ptr++) + print("%02x", *ptr); + print("}"); + } +} + +static void print_classless_route(const struct dhcpv4_option *opt, int elem_size, void (*print)(const char *fmt, ...)) +{ + const uint8_t *ptr = opt->data; + const uint8_t *endptr = ptr + opt->len; + int mask, i, mask1 = 0; + uint32_t ip; + uint32_t gw; + + while (ptr < endptr) { + if (ptr != opt->data) + print(","); + + mask = *ptr++; + ip = ntohl(*(uint32_t *)ptr); + for (i = 0; i < mask; i++) + mask1 |= (1 << (32 - i)); + ip &= mask1; + if (mask <= 8) + ptr++; + else if (mask <= 16) + ptr += 2; + else if (mask <= 24) + ptr += 3; + else + ptr += 4; + gw = ntohl(*(uint32_t *)ptr); + ptr += 4; + + print("%i.%i.%i.%i/%i via %i.%i.%i.%i", + (ip >> 24) & 0xff, + (ip >> 16) & 0xff, + (ip >> 8) & 0xff, + ip & 0xff, + mask, + (gw >> 24) & 0xff, + (gw >> 16) & 0xff, + (gw >> 8) & 0xff, + gw & 0xff); + } +} diff --git a/accel-pppd/ctrl/ipoe/ipoe.c b/accel-pppd/ctrl/ipoe/ipoe.c new file mode 100644 index 00000000..2258c622 --- /dev/null +++ b/accel-pppd/ctrl/ipoe/ipoe.c @@ -0,0 +1,688 @@ +#include <unistd.h> +#include <stdlib.h> +#include <stdio.h> +#include <stdarg.h> +#include <errno.h> +#include <string.h> +#include <fcntl.h> +#include <time.h> +#include <arpa/inet.h> +#include <netinet/in.h> +#include <sys/socket.h> +#include <sys/ioctl.h> +#include <linux/if.h> + +#include <pcre.h> + +#include "events.h" +#include "list.h" +#include "triton.h" +#include "log.h" +#include "mempool.h" +#include "utils.h" +#include "cli.h" +#include "ap_session.h" +#include "pwdb.h" +#include "ipdb.h" + +#include "iplink.h" +#include "connlimit.h" + +#include "ipoe.h" + +#include "memdebug.h" + +#define USERNAME_IFNAME 0 +#define USERNAME_LUA 1 + +static int conf_dhcpv4 = 1; +//static int conf_dhcpv6; +static int conf_username; + +#ifdef USE_LUA +static const char *conf_lua_username_func; +#endif + +static int conf_offer_timeout = 3; +static in_addr_t conf_gw_address; +static int conf_netmask = 24; +static int conf_lease_time = 600; +static int conf_lease_timeout = 660; +static int conf_verbose; + +static unsigned int stat_starting; +static unsigned int stat_active; + +static mempool_t ses_pool; + +static LIST_HEAD(serv_list); + +struct iplink_arg +{ + pcre *re; + const char *opt; +}; + +static void ipoe_session_finished(struct ap_session *s); + +static struct ipoe_session *ipoe_session_lookup(struct ipoe_serv *serv, struct dhcpv4_packet *pack) +{ + struct ipoe_session *ses; + + list_for_each_entry(ses, &serv->sessions, entry) { + if (pack->hdr->xid != ses->xid) + continue; + + if (pack->hdr->giaddr != ses->giaddr) + continue; + + if (pack->agent_circuit_id && !ses->agent_circuit_id) + continue; + + if (pack->agent_remote_id && !ses->agent_remote_id) + continue; + + if (pack->client_id && !ses->client_id) + continue; + + if (!pack->agent_circuit_id && ses->agent_circuit_id) + continue; + + if (!pack->agent_remote_id && ses->agent_remote_id) + continue; + + if (!pack->client_id && ses->client_id) + continue; + + if (pack->agent_circuit_id) { + if (pack->agent_circuit_id->len != ses->agent_circuit_id->len) + continue; + if (memcmp(pack->agent_circuit_id->data, ses->agent_circuit_id->data, pack->agent_circuit_id->len)) + continue; + } + + if (pack->agent_remote_id) { + if (pack->agent_remote_id->len != ses->agent_remote_id->len) + continue; + if (memcmp(pack->agent_remote_id->data, ses->agent_remote_id->data, pack->agent_remote_id->len)) + continue; + } + + if (pack->client_id) { + if (pack->client_id->len != ses->client_id->len) + continue; + if (memcmp(pack->client_id->data, ses->client_id->data, pack->client_id->len)) + continue; + } + + if (memcmp(pack->hdr->chaddr, ses->hwaddr, 6)) + continue; + + return ses; + } + + return NULL; +} + +static void ipoe_session_timeout(struct triton_timer_t *t) +{ + struct ipoe_session *ses = container_of(t, typeof(*ses), timer); + + triton_timer_del(t); + + log_ppp_info2("session timed out\n"); + + ap_session_terminate(&ses->ses, TERM_LOST_CARRIER, 0); +} + +static void ipoe_session_set_username(struct ipoe_session *ses) +{ +#ifdef USE_LUA + if (conf_username == USERNAME_LUA) { + ipoe_lua_set_username(ses, conf_lua_username_func); + } else +#endif + ses->ses.username = _strdup(ses->ses.ifname); +} + +static void ipoe_session_start(struct ipoe_session *ses) +{ + int r; + char *passwd; + + if (ses->serv->opt_single) + strncpy(ses->ses.ifname, ses->serv->ifname, AP_IFNAME_LEN); + + ipoe_session_set_username(ses); + if (!ses->ses.username) { + ipoe_session_finished(&ses->ses); + return; + } + + triton_event_fire(EV_CTRL_STARTING, &ses->ses); + triton_event_fire(EV_CTRL_STARTED, &ses->ses); + + ap_session_starting(&ses->ses); + + r = pwdb_check(&ses->ses, ses->ses.username, 0); + if (r == PWDB_NO_IMPL) { + passwd = pwdb_get_passwd(&ses->ses, ses->ses.username); + if (!passwd) + r = PWDB_DENIED; + else { + r = PWDB_SUCCESS; + _free(passwd); + } + } + + if (r == PWDB_DENIED) { + if (conf_ppp_verbose) + log_ppp_warn("authentication failed\n"); + ap_session_terminate(&ses->ses, TERM_AUTH_ERROR, 0); + return; + } + + if (ses->dhcpv4_request) { + ses->ses.ipv4 = ipdb_get_ipv4(&ses->ses); + if (!ses->ses.ipv4) { + log_ppp_warn("no free IPv4 address\n"); + ap_session_terminate(&ses->ses, TERM_AUTH_ERROR, 0); + return; + } + + if (conf_gw_address) + ses->ses.ipv4->addr = conf_gw_address; + + if (conf_netmask) + ses->ses.ipv4->mask = conf_netmask; + else if (!ses->ses.ipv4->mask) + ses->ses.ipv4->mask = 24; + + dhcpv4_send_reply(DHCPOFFER, ses->serv->dhcpv4, ses->dhcpv4_request, &ses->ses, conf_lease_time); + + dhcpv4_packet_free(ses->dhcpv4_request); + ses->dhcpv4_request = NULL; + } + + ses->timer.expire = ipoe_session_timeout; + ses->timer.period = conf_offer_timeout * 1000; + triton_timer_add(&ses->ctx, &ses->timer, 0); +} + +static void ipoe_session_activate(struct ipoe_session *ses) +{ + ap_session_activate(&ses->ses); + + if (ses->ses.state == AP_STATE_ACTIVE) + dhcpv4_send_reply(DHCPACK, ses->serv->dhcpv4, ses->dhcpv4_request, &ses->ses, conf_lease_time); + else + dhcpv4_send_nak(ses->serv->dhcpv4, ses->dhcpv4_request); + + dhcpv4_packet_free(ses->dhcpv4_request); + ses->dhcpv4_request = NULL; +} + +static void ipoe_session_started(struct ap_session *s) +{ + struct ipoe_session *ses = container_of(s, typeof(*ses), ses); + + log_ppp_debug("ipoe: session started\n"); + + triton_timer_del(&ses->timer); + + ses->timer.expire = ipoe_session_timeout; + ses->timer.period = conf_lease_timeout * 1000; + triton_timer_add(&ses->ctx, &ses->timer, 0); +} + +static void ipoe_session_free(struct ipoe_session *ses) +{ + if (ses->timer.tpd) + triton_timer_del(&ses->timer); + + triton_context_unregister(&ses->ctx); + + if (ses->data) + _free(ses->data); + + mempool_free(ses); +} + +static void ipoe_session_finished(struct ap_session *s) +{ + struct ipoe_session *ses = container_of(s, typeof(*ses), ses); + + log_ppp_debug("ipoe: session finished\n"); + + pthread_mutex_lock(&ses->serv->lock); + list_del(&ses->entry); + pthread_mutex_unlock(&ses->serv->lock); + + triton_context_call(&ses->ctx, (triton_event_func)ipoe_session_free, ses); +} + +static void ipoe_session_terminate(struct ap_session *s, int hard) +{ + ap_session_finished(s); +} + + +static void ipoe_session_close(struct triton_context_t *ctx) +{ + struct ipoe_session *ses = container_of(ctx, typeof(*ses), ctx); + + if (ses->ses.state) + ap_session_terminate(&ses->ses, TERM_ADMIN_RESET, 1); + else + ipoe_session_finished(&ses->ses); +} + +static struct ipoe_session *ipoe_session_create(struct ipoe_serv *serv, struct dhcpv4_packet *pack) +{ + struct ipoe_session *ses; + int dlen = 0; + uint8_t *ptr; + + ses = mempool_alloc(ses_pool); + if (!ses) { + log_emerg("out of memery\n"); + return NULL; + } + + memset(ses, 0, sizeof(*ses)); + + ap_session_init(&ses->ses); + + ses->serv = serv; + ses->dhcpv4_request = pack; + + ses->xid = pack->hdr->xid; + memcpy(ses->hwaddr, pack->hdr->chaddr, 6); + ses->giaddr = pack->hdr->giaddr; + + if (pack->agent_circuit_id) + dlen += sizeof(struct dhcp_opt) + pack->agent_circuit_id->len; + + if (pack->agent_remote_id) + dlen += sizeof(struct dhcp_opt) + pack->agent_remote_id->len; + + if (pack->client_id) + dlen += sizeof(struct dhcp_opt) + pack->client_id->len; + + if (dlen) { + ses->data = _malloc(dlen); + if (!ses->data) { + log_emerg("out of memery\n"); + mempool_free(ses); + return NULL; + } + ptr = ses->data; + } + + if (pack->agent_circuit_id) { + ses->agent_circuit_id = (struct dhcp_opt *)ptr; + ses->agent_circuit_id->len = pack->agent_circuit_id->len; + memcpy(ses->agent_circuit_id->data, pack->agent_circuit_id->data, pack->agent_circuit_id->len); + ptr += sizeof(struct dhcp_opt) + pack->agent_circuit_id->len; + } + + if (pack->agent_remote_id) { + ses->agent_remote_id = (struct dhcp_opt *)ptr; + ses->agent_remote_id->len = pack->agent_remote_id->len; + memcpy(ses->agent_remote_id->data, pack->agent_remote_id->data, pack->agent_remote_id->len); + ptr += sizeof(struct dhcp_opt) + pack->agent_remote_id->len; + } + + if (pack->client_id) { + ses->client_id = (struct dhcp_opt *)ptr; + ses->client_id->len = pack->client_id->len; + memcpy(ses->client_id->data, pack->client_id->data, pack->client_id->len); + ptr += sizeof(struct dhcp_opt) + pack->client_id->len; + } + + ses->ctx.before_switch = log_switch; + ses->ctx.close = ipoe_session_close; + ses->ctrl.ctx = &ses->ctx; + ses->ctrl.started = ipoe_session_started; + ses->ctrl.finished = ipoe_session_finished; + ses->ctrl.terminate = ipoe_session_terminate; + ses->ctrl.type = CTRL_TYPE_IPOE; + ses->ctrl.name = "ipoe"; + + ses->ctrl.calling_station_id = _malloc(19); + ses->ctrl.called_station_id = serv->ifname; + + ptr = ses->hwaddr; + sprintf(ses->ctrl.calling_station_id, "%02x:%02x:%02x:%02x:%02x:%02x", + ptr[0], ptr[1], ptr[2], ptr[3], ptr[4], ptr[5]); + + ses->ses.ctrl = &ses->ctrl; + ses->ses.chan_name = ses->ctrl.calling_station_id; + + triton_context_register(&ses->ctx, &ses->ses); + + triton_context_wakeup(&ses->ctx); + + //pthread_mutex_lock(&serv->lock); + list_add_tail(&ses->entry, &serv->sessions); + //pthread_mutex_unlock(&serv->lock); + + triton_context_call(&ses->ctx, (triton_event_func)ipoe_session_start, ses); + + return ses; +} + +static void ipoe_dhcpv4_recv(struct dhcpv4_serv *dhcpv4, struct dhcpv4_packet *pack) +{ + struct ipoe_serv *serv = container_of(dhcpv4->ctx, typeof(*serv), ctx); + struct ipoe_session *ses; + //struct dhcpv4_packet *reply; + + pthread_mutex_lock(&serv->lock); + if (pack->msg_type == DHCPDISCOVER) { + ses = ipoe_session_lookup(serv, pack); + if (!ses) { + ses = ipoe_session_create(serv, pack); + + if (conf_verbose && ses) { + log_switch(dhcpv4->ctx, &ses->ses); + log_ppp_info2("recv "); + dhcpv4_print_packet(pack, log_ppp_info2); + } + } else { + log_switch(dhcpv4->ctx, &ses->ses); + + if (conf_verbose) { + log_ppp_info2("recv "); + dhcpv4_print_packet(pack, log_ppp_info2); + } + + if (ses->ses.state == AP_STATE_ACTIVE) + dhcpv4_send_reply(DHCPOFFER, dhcpv4, pack, &ses->ses, conf_lease_time); + + dhcpv4_packet_free(pack); + } + } else if (pack->msg_type == DHCPREQUEST) { + ses = ipoe_session_lookup(serv, pack); + + if (!ses) { + if (conf_verbose) { + log_info2("recv "); + dhcpv4_print_packet(pack, log_info2); + } + + dhcpv4_send_nak(dhcpv4, pack); + } else { + if (!ses->ses.ipv4 || pack->server_id != ses->ses.ipv4->addr || pack->request_ip != ses->ses.ipv4->peer_addr) { + if (conf_verbose) { + log_info2("recv "); + dhcpv4_print_packet(pack, log_info2); + } + + if (ses->ses.ipv4 && pack->request_ip != ses->ses.ipv4->peer_addr) + dhcpv4_send_nak(dhcpv4, pack); + ap_session_terminate(&ses->ses, TERM_USER_REQUEST, 0); + } else { + if (conf_verbose) { + log_switch(dhcpv4->ctx, &ses->ses); + log_ppp_info2("recv "); + dhcpv4_print_packet(pack, log_ppp_info2); + } + + if (ses->ses.state == AP_STATE_STARTING && !ses->dhcpv4_request) { + ses->dhcpv4_request = pack; + pack = NULL; + triton_context_call(&ses->ctx, (triton_event_func)ipoe_session_activate, ses); + } + } + } + if (pack) + dhcpv4_packet_free(pack); + } else if (pack->msg_type == DHCPDECLINE || pack->msg_type == DHCPRELEASE) { + ses = ipoe_session_lookup(serv, pack); + if (ses) { + if (conf_verbose) { + log_switch(dhcpv4->ctx, &ses->ses); + log_ppp_info2("recv "); + dhcpv4_print_packet(pack, log_ppp_info2); + } + + ap_session_terminate(&ses->ses, TERM_USER_REQUEST, 0); + } + dhcpv4_packet_free(pack); + } + pthread_mutex_unlock(&serv->lock); +} + +static void ipoe_serv_close(struct triton_context_t *ctx) +{ + struct ipoe_serv *serv = container_of(ctx, typeof(*serv), ctx); + + if (serv->dhcpv4) + dhcpv4_free(serv->dhcpv4); + + triton_context_unregister(ctx); + + _free(serv->ifname); + _free(serv); +} + +static int show_stat_exec(const char *cmd, char * const *fields, int fields_cnt, void *client) +{ + cli_send(client, "ipoe:\r\n"); + cli_sendv(client," starting: %u\r\n", stat_starting); + cli_sendv(client," active: %u\r\n", stat_active); + + return CLI_CMD_OK; +} + +void __export ipoe_get_stat(unsigned int **starting, unsigned int **active) +{ + *starting = &stat_starting; + *active = &stat_active; +} + +static void ipoe_drop_sessions(struct ipoe_serv *serv) +{ + +} + +static void add_interface(const char *ifname, int ifindex, const char *opt) +{ + int opt_single; + const char *ptr; + struct ipoe_serv *serv; + + ptr = strstr(opt, ",single"); + if (ptr) { + if (ptr[7] && ptr[7] != ',') + goto out_err_parse; + opt_single = 1; + } else + opt_single = 0; + + + list_for_each_entry(serv, &serv_list, entry) { + if (strcmp(ifname, serv->ifname) == 0) { + serv->active = 1; + serv->ifindex = ifindex; + if (opt_single && !serv->opt_single) + ipoe_drop_sessions(serv); + serv->opt_single = opt_single; + return; + } + } + + serv = _malloc(sizeof(*serv)); + memset(serv, 0, sizeof(*serv)); + serv->ifname = _strdup(ifname); + serv->ifindex = ifindex; + serv->opt_single = opt_single; + serv->opt_dhcpv4 = conf_dhcpv4; + INIT_LIST_HEAD(&serv->sessions); + pthread_mutex_init(&serv->lock, NULL); + + triton_context_register(&serv->ctx, NULL); + + if (serv->opt_dhcpv4) { + serv->dhcpv4 = dhcpv4_create(&serv->ctx, serv->ifname); + if (serv->dhcpv4) + serv->dhcpv4->recv = ipoe_dhcpv4_recv; + } + + triton_context_wakeup(&serv->ctx); + + return; + +out_err_parse: + log_error("ipoe: failed to parse '%s'\n", opt); +} + +static void load_interface(const char *opt) +{ + const char *ptr; + struct ifreq ifr; + + for (ptr = opt; *ptr && *ptr != ','; ptr++); + + if (ptr - opt >= sizeof(ifr.ifr_name)) + return; + + memcpy(ifr.ifr_name, opt, ptr - opt); + ifr.ifr_name[ptr - opt] = 0; + + if (ioctl(sock_fd, SIOCGIFINDEX, &ifr)) { + log_error("ipoe: '%s': ioctl(SIOCGIFINDEX): %s\n", ifr.ifr_name, strerror(errno)); + return; + } + + add_interface(ifr.ifr_name, ifr.ifr_ifindex, opt); +} + +static int __load_interface_re(int index, int flags, const char *name, struct iplink_arg *arg) +{ + if (pcre_exec(arg->re, NULL, name, strlen(name), 0, 0, NULL, 0) < 0) + return 0; + + add_interface(name, index, arg->opt); + + return 0; +} + +static void load_interface_re(const char *opt) +{ + pcre *re = NULL; + const char *pcre_err; + char *pattern; + const char *ptr; + int pcre_offset; + struct iplink_arg arg; + + for (ptr = opt; *ptr && *ptr != ','; ptr++); + + pattern = _malloc(ptr - (opt + 3) + 1); + memcpy(pattern, opt + 3, ptr - (opt + 3)); + pattern[ptr - (opt + 3)] = 0; + + re = pcre_compile2(pattern, 0, NULL, &pcre_err, &pcre_offset, NULL); + + if (!re) { + log_error("ipoe: %s at %i\r\n", pcre_err, pcre_offset); + return; + } + + arg.re = re; + arg.opt = opt; + + iplink_list((iplink_list_func)__load_interface_re, &arg); + + pcre_free(re); + _free(pattern); +} + +static void load_interfaces(struct conf_sect_t *sect) +{ + struct ipoe_serv *serv; + struct conf_option_t *opt; + struct list_head *pos, *n; + + list_for_each_entry(serv, &serv_list, entry) + serv->active = 0; + + list_for_each_entry(opt, §->items, entry) { + if (strcmp(opt->name, "interface")) + continue; + if (!opt->val) + continue; + + if (strlen(opt->val) > 3 && memcmp(opt->val, "re:", 3) == 0) + load_interface_re(opt->val); + else + load_interface(opt->val); + } + + list_for_each_safe(pos, n, &serv_list) { + serv = list_entry(pos, typeof(*serv), entry); + if (!serv->active) { + list_del(&serv->entry); + triton_context_call(&serv->ctx, (triton_event_func)ipoe_serv_close, &serv->ctx); + } + } +} + +static void load_config(void) +{ + const char *opt; + struct conf_sect_t *s = conf_get_section("ipoe"); + + if (!s) + return; + + load_interfaces(s); + + opt = conf_get_opt("ipoe", "username"); + if (opt) { + if (strcmp(opt, "ifname") == 0) + conf_username = USERNAME_IFNAME; +#ifdef USE_LUA + else if (strlen(opt) > 4 && memcmp(opt, "lua:", 4) == 0) { + conf_username = USERNAME_LUA; + conf_lua_username_func = opt + 4; +#endif + } else + log_emerg("ipoe: unknown username value '%s'\n", opt); + } + + opt = conf_get_opt("ipoe", "gw-ip-address"); + if (opt) + conf_gw_address = inet_addr(opt); + else + conf_gw_address = 0; + + opt = conf_get_opt("ipoe", "netmask"); + if (opt) { + conf_netmask = atoi(opt); + if (conf_netmask <= 0 || conf_netmask > 32) { + log_error("ipoe: invalid netmask %s\n", opt); + conf_netmask = 0; + } + } else + conf_netmask = 0; + + opt = conf_get_opt("ipoe", "verbose"); + if (opt) + conf_verbose = atoi(opt); +} + +static void ipoe_init(void) +{ + ses_pool = mempool_create(sizeof(struct ipoe_session)); + + load_config(); + + cli_register_simple_cmd2(show_stat_exec, NULL, 2, "show", "stat"); + + triton_event_register_handler(EV_CONFIG_RELOAD, (triton_event_func)load_config); +} + +DEFINE_INIT(20, ipoe_init); diff --git a/accel-pppd/ctrl/ipoe/ipoe.h b/accel-pppd/ctrl/ipoe/ipoe.h new file mode 100644 index 00000000..adbc5cff --- /dev/null +++ b/accel-pppd/ctrl/ipoe/ipoe.h @@ -0,0 +1,54 @@ +#ifndef __IPOE_H +#define __IPOE_H + +#include <stdint.h> +#include <pthread.h> + +#include "triton.h" +#include "ap_session.h" +#include "dhcpv4.h" + +struct ipoe_serv +{ + struct list_head entry; + struct triton_context_t ctx; + char *ifname; + int ifindex; + int active; + int opt_single; + int opt_dhcpv4; + struct list_head sessions; + struct dhcpv4_serv *dhcpv4; + pthread_mutex_t lock; +}; + +struct dhcp_opt +{ + uint8_t len; + uint8_t data[0]; +}; + +struct ipoe_session +{ + struct list_head entry; + struct triton_context_t ctx; + struct triton_timer_t timer; + struct ipoe_serv *serv; + struct ap_ctrl ctrl; + struct ap_session ses; + uint8_t hwaddr[6]; + struct dhcp_opt *client_id; + struct dhcp_opt *agent_circuit_id; + struct dhcp_opt *agent_remote_id; + uint32_t xid; + uint32_t giaddr; + uint8_t *data; + struct dhcpv4_packet *dhcpv4_request; +}; + +#ifdef USE_LUA +int ipoe_lua_set_username(struct ipoe_session *, const char *func); +#endif + +#endif + diff --git a/accel-pppd/ctrl/ipoe/lua.c b/accel-pppd/ctrl/ipoe/lua.c new file mode 100644 index 00000000..77beca6e --- /dev/null +++ b/accel-pppd/ctrl/ipoe/lua.c @@ -0,0 +1,253 @@ +#include <stdlib.h> +#include <stdio.h> +#include <string.h> +#include <pthread.h> + +/* Include the Lua API header files. */ +#include <lua.h> +#include <lauxlib.h> +#include <lualib.h> + +#include "events.h" +#include "log.h" +#include "utils.h" + +#include "ipoe.h" + +#include "memdebug.h" + +#define IPOE_PACKET4 "ipoe.packet4" + +static const char *conf_filename; +static int serial; +static int file_error; + +static __thread lua_State *L; +static __thread int __serial; +static pthread_key_t __key; + +static int packet4_hdr(lua_State *L); +static int packet4_ifname(lua_State *L); +static int packet4_option(lua_State *L); +static int packet4_options(lua_State *L); +static int packet4_agent_circuit_id(lua_State *L); +static int packet4_agent_remote_id(lua_State *L); + +int luaopen_lpack(lua_State *L); + +static const struct luaL_reg packet4_lib [] = { + {"hdr", packet4_hdr}, + {"ifname", packet4_ifname}, + {"option", packet4_option}, + {"options", packet4_options}, + {"agent_circuit_id", packet4_agent_circuit_id}, + {"agent_remote_id", packet4_agent_remote_id}, + {NULL, NULL} +}; + +static int luaopen_packet4(lua_State *L) +{ + luaL_newmetatable(L, IPOE_PACKET4); + + lua_pushstring(L, "__index"); + lua_pushvalue(L, -2); /* pushes the metatable */ + lua_settable(L, -3); /* metatable.__index = metatable */ + + + luaI_openlib(L, NULL, packet4_lib, 0); + + luaI_openlib(L, "packet4", packet4_lib, 0); + + return 1; +} + +static int packet4_hdr(lua_State *L) +{ + struct ipoe_session *ses = luaL_checkudata(L, 1, IPOE_PACKET4); + const char *name = luaL_checkstring(L, 2); + char str[20]; + uint8_t *ptr; + + if (!ses) + return 0; + + if (!strcmp(name, "xid")) + lua_pushinteger(L, ses->dhcpv4_request->hdr->xid); + else if (!strcmp(name, "ciaddr")) { + u_inet_ntoa(ses->dhcpv4_request->hdr->ciaddr, str); + lua_pushstring(L, str); + } else if (!strcmp(name, "giaddr")) { + u_inet_ntoa(ses->dhcpv4_request->hdr->giaddr, str); + lua_pushstring(L, str); + } else if (!strcmp(name, "chaddr")) { + ptr = ses->dhcpv4_request->hdr->chaddr; + sprintf(str, "%02x:%02x:%02x:%02x:%02x:%02x", + ptr[0], ptr[1], ptr[2], ptr[3], ptr[4], ptr[5]); + lua_pushstring(L, str); + } + + return 1; +} + +static int packet4_ifname(lua_State *L) +{ + struct ipoe_session *ses = luaL_checkudata(L, 1, IPOE_PACKET4); + + if (!ses) + return 0; + + lua_pushstring(L, ses->serv->ifname); + + return 1; +} + +static int packet4_option(lua_State *L) +{ + struct ipoe_session *ses = luaL_checkudata(L, 1, IPOE_PACKET4); + int type = luaL_checkinteger(L, 2); + struct dhcpv4_option *opt; + + list_for_each_entry(opt, &ses->dhcpv4_request->options, entry) { + if (opt->type == type) { + lua_pushlstring(L, (char *)opt->data, opt->len); + return 1; + } + } + + lua_pushnil(L); + + return 1; +} + +static int packet4_options(lua_State *L) +{ + struct ipoe_session *ses = luaL_checkudata(L, 1, IPOE_PACKET4); + struct dhcpv4_option *opt; + int i = 1; + + if (!ses) + return 0; + + lua_newtable(L); + + list_for_each_entry(opt, &ses->dhcpv4_request->options, entry) { + lua_pushinteger(L, opt->type); + lua_rawseti(L, -2, i++); + } + + return 1; +} + +static int packet4_agent_circuit_id(lua_State *L) +{ + struct ipoe_session *ses = luaL_checkudata(L, 1, IPOE_PACKET4); + + if (!ses) + return 0; + + if (ses->agent_circuit_id) + lua_pushlstring(L, (char *)ses->agent_circuit_id->data, ses->agent_circuit_id->len); + else + lua_pushnil(L); + + return 1; +} + +static int packet4_agent_remote_id(lua_State *L) +{ + struct ipoe_session *ses = luaL_checkudata(L, 1, IPOE_PACKET4); + + if (!ses) + return 0; + + if (ses->agent_remote_id) + lua_pushlstring(L, (char *)ses->agent_remote_id->data, ses->agent_remote_id->len); + else + lua_pushnil(L); + + return 1; +} + +static void init_lua() +{ + __serial = serial; + + L = lua_open(); + + luaL_openlibs(L); + + luaopen_lpack(L); + luaopen_packet4(L); + + if (luaL_loadfile(L, conf_filename)) + goto out_err; + + if (lua_pcall(L, 0, 0, 0)) + goto out_err; + + file_error = 0; + + pthread_setspecific(__key, L); + + return; + +out_err: + file_error = 1; + log_ppp_error("ipoe: lua: %s\n", lua_tostring(L, -1)); + lua_close(L); + L = NULL; +} + +int ipoe_lua_set_username(struct ipoe_session *ses, const char *func) +{ + if (file_error && serial == __serial) + return -1; + + if (L && serial != __serial) { + lua_close(L); + init_lua(); + } else if (!L) + init_lua(); + + if (!L) + return -1; + + lua_getglobal(L, func); + lua_pushlightuserdata(L, ses); + luaL_getmetatable(L, IPOE_PACKET4); + lua_setmetatable(L, -2); + + if (lua_pcall(L, 1, 1, 0)) { + log_ppp_error("ipoe: lua: %s\n", lua_tostring(L, -1)); + return -1; + } + + if (!lua_isstring(L, -1)) { + log_ppp_error("ipoe: lua: function '%s' must return a string\n", func); + return -1; + } + + ses->ses.username = _strdup(lua_tostring(L, -1)); + + lua_pop(L, 1); + + return 0; +} + +static void load_config() +{ + conf_filename = conf_get_opt("ipoe", "lua-file"); + + serial++; +} + +static void init() +{ + load_config(); + + pthread_key_create(&__key, (void (*)(void *))lua_close); + + triton_event_register_handler(EV_CONFIG_RELOAD, (triton_event_func)load_config); +} + +DEFINE_INIT(100, init); diff --git a/accel-pppd/ctrl/ipoe/lua_lpack.c b/accel-pppd/ctrl/ipoe/lua_lpack.c new file mode 100644 index 00000000..22d34774 --- /dev/null +++ b/accel-pppd/ctrl/ipoe/lua_lpack.c @@ -0,0 +1,271 @@ +/* +* lpack.c +* a Lua library for packing and unpacking binary data +* Luiz Henrique de Figueiredo <lhf@tecgraf.puc-rio.br> +* 29 Jun 2007 19:27:20 +* This code is hereby placed in the public domain. +* with contributions from Ignacio Castaño <castanyo@yahoo.es> and +* Roberto Ierusalimschy <roberto@inf.puc-rio.br>. +*/ + +#define OP_ZSTRING 'z' /* zero-terminated string */ +#define OP_BSTRING 'p' /* string preceded by length byte */ +#define OP_WSTRING 'P' /* string preceded by length word */ +#define OP_SSTRING 'a' /* string preceded by length size_t */ +#define OP_STRING 'A' /* string */ +#define OP_FLOAT 'f' /* float */ +#define OP_DOUBLE 'd' /* double */ +#define OP_NUMBER 'n' /* Lua number */ +#define OP_CHAR 'c' /* char */ +#define OP_BYTE 'b' /* byte = unsigned char */ +#define OP_SHORT 'h' /* short */ +#define OP_USHORT 'H' /* unsigned short */ +#define OP_INT 'i' /* int */ +#define OP_UINT 'I' /* unsigned int */ +#define OP_LONG 'l' /* long */ +#define OP_ULONG 'L' /* unsigned long */ +#define OP_LITTLEENDIAN '<' /* little endian */ +#define OP_BIGENDIAN '>' /* big endian */ +#define OP_NATIVE '=' /* native endian */ + +#include <ctype.h> +#include <stdint.h> +#include <string.h> + +#include "lua.h" +#include "lualib.h" +#include "lauxlib.h" + +static void badcode(lua_State *L, int c) +{ + char s[]="bad code `?'"; + s[sizeof(s)-3]=c; + luaL_argerror(L,1,s); +} + +static int doendian(int c) +{ + int x=1; + int e=*(char*)&x; + if (c==OP_LITTLEENDIAN) return !e; + if (c==OP_BIGENDIAN) return e; + if (c==OP_NATIVE) return 0; + return 0; +} + +static void doswap(int swap, void *p, size_t n) +{ + if (swap) + { + char *a=p; + int i,j; + for (i=0, j=n-1, n=n/2; n--; i++, j--) + { + char t=a[i]; a[i]=a[j]; a[j]=t; + } + } +} + +#define UNPACKNUMBER(OP,T) \ + case OP: \ + { \ + T a; \ + int m=sizeof(a); \ + if (i+m>len) goto done; \ + memcpy(&a,s+i,m); \ + i+=m; \ + doswap(swap,&a,m); \ + lua_pushnumber(L,(lua_Number)a); \ + ++n; \ + break; \ + } + +#define UNPACKSTRING(OP,T) \ + case OP: \ + { \ + T l; \ + int m=sizeof(l); \ + if (i+m>len) goto done; \ + memcpy(&l,s+i,m); \ + doswap(swap,&l,m); \ + if (i+m+l>len) goto done; \ + i+=m; \ + lua_pushlstring(L,s+i,l); \ + i+=l; \ + ++n; \ + break; \ + } + +static int l_unpack(lua_State *L) /** unpack(s,f,[init]) */ +{ + size_t len; + const char *s=luaL_checklstring(L,1,&len); + const char *f=luaL_checkstring(L,2); + int i=luaL_optnumber(L,3,1)-1; + int n=0; + int swap=0; + lua_pushnil(L); + while (*f) + { + int c=*f++; + int N=1; + if (isdigit(*f)) + { + N=0; + while (isdigit(*f)) N=10*N+(*f++)-'0'; + if (N==0 && c==OP_STRING) { lua_pushliteral(L,""); ++n; } + } + while (N--) switch (c) + { + case OP_LITTLEENDIAN: + case OP_BIGENDIAN: + case OP_NATIVE: + { + swap=doendian(c); + N=0; + break; + } + case OP_STRING: + { + ++N; + if (i+N>len) goto done; + lua_pushlstring(L,s+i,N); + i+=N; + ++n; + N=0; + break; + } + case OP_ZSTRING: + { + size_t l; + if (i>=len) goto done; + l=strlen(s+i); + lua_pushlstring(L,s+i,l); + i+=l+1; + ++n; + break; + } + UNPACKSTRING(OP_BSTRING, unsigned char) + UNPACKSTRING(OP_WSTRING, unsigned short) + UNPACKSTRING(OP_SSTRING, size_t) + UNPACKNUMBER(OP_NUMBER, lua_Number) + UNPACKNUMBER(OP_DOUBLE, double) + UNPACKNUMBER(OP_FLOAT, float) + UNPACKNUMBER(OP_CHAR, int8_t) + UNPACKNUMBER(OP_BYTE, uint8_t) + UNPACKNUMBER(OP_SHORT, int16_t) + UNPACKNUMBER(OP_USHORT, uint16_t) + UNPACKNUMBER(OP_INT, int32_t) + UNPACKNUMBER(OP_UINT, uint32_t) + UNPACKNUMBER(OP_LONG, int64_t) + UNPACKNUMBER(OP_ULONG, uint64_t) + case ' ': case ',': + break; + default: + badcode(L,c); + break; + } + } +done: + lua_pushnumber(L,i+1); + lua_replace(L,-n-2); + return n+1; +} + +#define PACKNUMBER(OP,T) \ + case OP: \ + { \ + T a=(T)luaL_checknumber(L,i++); \ + doswap(swap,&a,sizeof(a)); \ + luaL_addlstring(&b,(void*)&a,sizeof(a)); \ + break; \ + } + +#define PACKSTRING(OP,T) \ + case OP: \ + { \ + size_t l; \ + const char *a=luaL_checklstring(L,i++,&l); \ + T ll=(T)l; \ + doswap(swap,&ll,sizeof(ll)); \ + luaL_addlstring(&b,(void*)&ll,sizeof(ll)); \ + luaL_addlstring(&b,a,l); \ + break; \ + } + +static int l_pack(lua_State *L) /** pack(f,...) */ +{ + int i=2; + const char *f=luaL_checkstring(L,1); + int swap=0; + luaL_Buffer b; + luaL_buffinit(L,&b); + while (*f) + { + int c=*f++; + int N=1; + if (isdigit(*f)) + { + N=0; + while (isdigit(*f)) N=10*N+(*f++)-'0'; + } + while (N--) switch (c) + { + case OP_LITTLEENDIAN: + case OP_BIGENDIAN: + case OP_NATIVE: + { + swap=doendian(c); + N=0; + break; + } + case OP_STRING: + case OP_ZSTRING: + { + size_t l; + const char *a=luaL_checklstring(L,i++,&l); + luaL_addlstring(&b,a,l+(c==OP_ZSTRING)); + break; + } + PACKSTRING(OP_BSTRING, unsigned char) + PACKSTRING(OP_WSTRING, unsigned short) + PACKSTRING(OP_SSTRING, size_t) + PACKNUMBER(OP_NUMBER, lua_Number) + PACKNUMBER(OP_DOUBLE, double) + PACKNUMBER(OP_FLOAT, float) + PACKNUMBER(OP_CHAR, int8_t) + PACKNUMBER(OP_BYTE, uint8_t) + PACKNUMBER(OP_SHORT, int16_t) + PACKNUMBER(OP_USHORT, uint16_t) + PACKNUMBER(OP_INT, int32_t) + PACKNUMBER(OP_UINT, uint32_t) + PACKNUMBER(OP_LONG, int64_t) + PACKNUMBER(OP_ULONG, uint64_t) + case ' ': case ',': + break; + default: + badcode(L,c); + break; + } + } + luaL_pushresult(&b); + return 1; +} + +static const luaL_reg R[] = +{ + {"pack", l_pack}, + {"unpack", l_unpack}, + {NULL, NULL} +}; + +int luaopen_lpack(lua_State *L) +{ +#ifdef USE_GLOBALS + lua_register(L,"bpack",l_pack); + lua_register(L,"bunpack",l_unpack); +#else + luaI_openlib(L, LUA_STRLIBNAME, R, 0); +#endif + return 0; +} diff --git a/accel-pppd/ctrl/l2tp/l2tp.c b/accel-pppd/ctrl/l2tp/l2tp.c index e3db614a..0ad8649c 100644 --- a/accel-pppd/ctrl/l2tp/l2tp.c +++ b/accel-pppd/ctrl/l2tp/l2tp.c @@ -144,7 +144,7 @@ static void l2tp_disconnect(struct l2tp_conn_t *conn) if (conn->tunnel_fd != -1) close(conn->tunnel_fd); - triton_event_fire(EV_CTRL_FINISHED, &conn->ppp); + triton_event_fire(EV_CTRL_FINISHED, &conn->ppp.ses); log_ppp_info1("disconnected\n"); @@ -423,7 +423,7 @@ static int l2tp_connect(struct l2tp_conn_t *conn) conn->ppp.ses.chan_name = _strdup(inet_ntoa(conn->addr.sin_addr)); - triton_event_fire(EV_CTRL_STARTED, &conn->ppp); + triton_event_fire(EV_CTRL_STARTED, &conn->ppp.ses); if (establish_ppp(&conn->ppp)) return -1; diff --git a/accel-pppd/ctrl/pppoe/pppoe.c b/accel-pppd/ctrl/pppoe/pppoe.c index 7981eba1..2659a6f5 100644 --- a/accel-pppd/ctrl/pppoe/pppoe.c +++ b/accel-pppd/ctrl/pppoe/pppoe.c @@ -120,7 +120,7 @@ static void disconnect(struct pppoe_conn_t *conn) close(conn->disc_sock); - triton_event_fire(EV_CTRL_FINISHED, &conn->ppp); + triton_event_fire(EV_CTRL_FINISHED, &conn->ppp.ses); log_ppp_info1("disconnected\n"); @@ -293,8 +293,8 @@ static struct pppoe_conn_t *allocate_channel(struct pppoe_serv_t *serv, const ui triton_context_register(&conn->ctx, &conn->ppp.ses); triton_context_wakeup(&conn->ctx); - triton_event_fire(EV_CTRL_STARTING, &conn->ppp); - triton_event_fire(EV_CTRL_STARTED, &conn->ppp); + triton_event_fire(EV_CTRL_STARTING, &conn->ppp.ses); + triton_event_fire(EV_CTRL_STARTED, &conn->ppp.ses); conn->disc_sock = dup(serv->hnd.fd); diff --git a/accel-pppd/ctrl/pptp/pptp.c b/accel-pppd/ctrl/pptp/pptp.c index 59d50984..dddf5edc 100644 --- a/accel-pppd/ctrl/pptp/pptp.c +++ b/accel-pppd/ctrl/pptp/pptp.c @@ -91,7 +91,7 @@ static void disconnect(struct pptp_conn_t *conn) } else if (conn->state != STATE_CLOSE) __sync_sub_and_fetch(&stat_starting, 1); - triton_event_fire(EV_CTRL_FINISHED, &conn->ppp); + triton_event_fire(EV_CTRL_FINISHED, &conn->ppp.ses); log_ppp_info1("disconnected\n"); @@ -327,7 +327,7 @@ static int pptp_out_call_rqst(struct pptp_conn_t *conn) conn->ppp.fd = pptp_sock; conn->ppp.ses.chan_name = _strdup(inet_ntoa(dst_addr.sa_addr.pptp.sin_addr)); - triton_event_fire(EV_CTRL_STARTED, &conn->ppp); + triton_event_fire(EV_CTRL_STARTED, &conn->ppp.ses); if (establish_ppp(&conn->ppp)) { close(pptp_sock); @@ -689,7 +689,7 @@ static int pptp_connect(struct triton_md_handler_t *h) triton_timer_add(&conn->ctx, &conn->timeout_timer, 0); triton_context_wakeup(&conn->ctx); - triton_event_fire(EV_CTRL_STARTING, &conn->ppp); + triton_event_fire(EV_CTRL_STARTING, &conn->ppp.ses); __sync_add_and_fetch(&stat_starting, 1); } diff --git a/accel-pppd/extra/pppd_compat.c b/accel-pppd/extra/pppd_compat.c index 4ed7824e..fcb83c25 100644 --- a/accel-pppd/extra/pppd_compat.c +++ b/accel-pppd/extra/pppd_compat.c @@ -107,8 +107,9 @@ static void ip_change_handler(struct sigchld_handler_t *h, int status) static void ev_ses_starting(struct ap_session *ses) { - struct pppd_compat_pd_t *pd = _malloc(sizeof(*pd)); - + struct pppd_compat_pd_t *pd; + + pd = _malloc(sizeof(*pd)); if (!pd) { log_emerg("pppd_compat: out of memory\n"); return; @@ -232,17 +233,21 @@ static void ev_ses_finishing(struct ap_session *ses) if (!pd) return; - memset(&ifreq, 0, sizeof(ifreq)); - ifreq.stats_ptr = (void *)&ifreq.stats; - strcpy(ifreq.ifr__name, ses->ifname); + if (ses->ctrl->type == CTRL_TYPE_IPOE) { - if (ioctl(sock_fd, SIOCGPPPSTATS, &ifreq)) { - log_ppp_error("pppd_compat: failed to get ppp statistics: %s\n", strerror(errno)); - return; - } + } else { + memset(&ifreq, 0, sizeof(ifreq)); + ifreq.stats_ptr = (void *)&ifreq.stats; + strcpy(ifreq.ifr__name, ses->ifname); - pd->bytes_sent = ifreq.stats.p.ppp_obytes; - pd->bytes_rcvd = ifreq.stats.p.ppp_ibytes; + if (ioctl(sock_fd, SIOCGPPPSTATS, &ifreq)) { + log_ppp_error("pppd_compat: failed to get ppp statistics: %s\n", strerror(errno)); + return; + } + + pd->bytes_sent = ifreq.stats.p.ppp_obytes; + pd->bytes_rcvd = ifreq.stats.p.ppp_ibytes; + } } static void ev_ses_finished(struct ap_session *ses) @@ -331,6 +336,9 @@ static void ev_radius_access_accept(struct ev_radius_t *ev) { struct pppd_compat_pd_t *pd = find_pd(ev->ses); + if (!pd) + return; + write_radattr(ev->ses, ev->reply, 0); pd->radattr_saved = 1; @@ -479,7 +487,7 @@ static struct pppd_compat_pd_t *find_pd(struct ap_session *ses) } } - log_ppp_warn("pppd_compat: pd not found\n"); + //log_ppp_warn("pppd_compat: pd not found\n"); return NULL; } diff --git a/accel-pppd/ifcfg.c b/accel-pppd/ifcfg.c index a1bb2e34..11251e1a 100644 --- a/accel-pppd/ifcfg.c +++ b/accel-pppd/ifcfg.c @@ -9,6 +9,7 @@ #include <arpa/inet.h> #include <sys/socket.h> #include <sys/ioctl.h> +#include <linux/route.h> #include "linux_ppp.h" #include "triton.h" @@ -55,6 +56,7 @@ void ap_session_ifup(struct ap_session *ses) { struct ipv6db_addr_t *a; struct ifreq ifr; + struct rtentry rt; struct in6_ifreq ifr6; struct npioctl np; struct sockaddr_in addr; @@ -75,16 +77,34 @@ void ap_session_ifup(struct ap_session *ses) memset(&addr, 0, sizeof(addr)); addr.sin_family = AF_INET; addr.sin_addr.s_addr = ses->ipv4->addr; - memcpy(&ifr.ifr_addr,&addr,sizeof(addr)); + memcpy(&ifr.ifr_addr, &addr, sizeof(addr)); if (ioctl(sock_fd, SIOCSIFADDR, &ifr)) log_ppp_error("failed to set IPv4 address: %s\n", strerror(errno)); + + if (ses->ctrl->type == CTRL_TYPE_IPOE) { + addr.sin_addr.s_addr = 0xffffffff; + memcpy(&ifr.ifr_netmask, &addr, sizeof(addr)); + if (ioctl(sock_fd, SIOCSIFNETMASK, &ifr)) + log_ppp_error("failed to set IPv4 nask: %s\n", strerror(errno)); + } addr.sin_addr.s_addr = ses->ipv4->peer_addr; - memcpy(&ifr.ifr_dstaddr,&addr,sizeof(addr)); - - if (ioctl(sock_fd, SIOCSIFDSTADDR, &ifr)) - log_ppp_error("failed to set peer IPv4 address: %s\n", strerror(errno)); + + if (ses->ctrl->type == CTRL_TYPE_IPOE) { + memset(&rt, 0, sizeof(rt)); + memcpy(&rt.rt_dst, &addr, sizeof(addr)); + rt.rt_flags = RTF_HOST | RTF_UP; + rt.rt_metric = 1; + rt.rt_dev = ifr.ifr_name; + if (ioctl(sock_fd, SIOCADDRT, &rt, sizeof(rt))) + log_ppp_error("failed to add route: %s\n", strerror(errno)); + } else { + memcpy(&ifr.ifr_dstaddr, &addr, sizeof(addr)); + + if (ioctl(sock_fd, SIOCSIFDSTADDR, &ifr)) + log_ppp_error("failed to set peer IPv4 address: %s\n", strerror(errno)); + } } if (ses->ipv6) { @@ -93,13 +113,16 @@ void ap_session_ifup(struct ap_session *ses) devconf(ses, "forwarding", "1"); memset(&ifr6, 0, sizeof(ifr6)); - ifr6.ifr6_addr.s6_addr32[0] = htons(0xfe80); - *(uint64_t *)(ifr6.ifr6_addr.s6_addr + 8) = ses->ipv6->intf_id; - ifr6.ifr6_prefixlen = 64; - ifr6.ifr6_ifindex = ses->ifindex; + + if (ses->ctrl->type != CTRL_TYPE_IPOE) { + ifr6.ifr6_addr.s6_addr32[0] = htons(0xfe80); + *(uint64_t *)(ifr6.ifr6_addr.s6_addr + 8) = ses->ipv6->intf_id; + ifr6.ifr6_prefixlen = 64; + ifr6.ifr6_ifindex = ses->ifindex; - if (ioctl(sock6_fd, SIOCSIFADDR, &ifr6)) - log_ppp_error("faild to set LL IPv6 address: %s\n", strerror(errno)); + if (ioctl(sock6_fd, SIOCSIFADDR, &ifr6)) + log_ppp_error("faild to set LL IPv6 address: %s\n", strerror(errno)); + } list_for_each_entry(a, &ses->ipv6->addr_list, entry) { if (a->prefix_len == 128) @@ -154,7 +177,9 @@ void __export ap_session_ifdown(struct ap_session *ses) memset(&ifr, 0, sizeof(ifr)); strcpy(ifr.ifr_name, ses->ifname); - ioctl(sock_fd, SIOCSIFFLAGS, &ifr); + + if (ses->ctrl->type != CTRL_TYPE_IPOE) + ioctl(sock_fd, SIOCSIFFLAGS, &ifr); if (ses->ipv4) { memset(&addr, 0, sizeof(addr)); diff --git a/accel-pppd/include/ap_session.h b/accel-pppd/include/ap_session.h index 681d05fb..b964c80d 100644 --- a/accel-pppd/include/ap_session.h +++ b/accel-pppd/include/ap_session.h @@ -2,7 +2,7 @@ #define __AP_SESSION_H__ #define AP_SESSIONID_LEN 16 -#define AP_IFNAME_LEN 10 +#define AP_IFNAME_LEN 16 #define AP_STATE_STARTING 1 #define AP_STATE_ACTIVE 2 diff --git a/accel-pppd/include/iplink.h b/accel-pppd/include/iplink.h new file mode 120000 index 00000000..7f0f09d4 --- /dev/null +++ b/accel-pppd/include/iplink.h @@ -0,0 +1 @@ +../libnetlink/iplink.h
\ No newline at end of file diff --git a/accel-pppd/include/libnetlink.h b/accel-pppd/include/libnetlink.h new file mode 120000 index 00000000..d494ddb4 --- /dev/null +++ b/accel-pppd/include/libnetlink.h @@ -0,0 +1 @@ +../libnetlink/libnetlink.h
\ No newline at end of file diff --git a/accel-pppd/ipdb.h b/accel-pppd/ipdb.h index 0d13b76e..69cb12f3 100644 --- a/accel-pppd/ipdb.h +++ b/accel-pppd/ipdb.h @@ -11,6 +11,7 @@ struct ipv4db_item_t struct ipdb_t *owner; in_addr_t addr; in_addr_t peer_addr; + int mask; }; struct ipv6db_addr_t diff --git a/accel-pppd/libnetlink/iplink.c b/accel-pppd/libnetlink/iplink.c new file mode 100644 index 00000000..ba3ada06 --- /dev/null +++ b/accel-pppd/libnetlink/iplink.c @@ -0,0 +1,77 @@ +#include <stdio.h> +#include <stdlib.h> +#include <unistd.h> +#include <syslog.h> +#include <fcntl.h> +#include <net/if_arp.h> +#include <sys/socket.h> +#include <netinet/in.h> +#include <string.h> +#include <errno.h> +#include <time.h> +#include <sys/uio.h> + +#include "libnetlink.h" +#include "iplink.h" +#include "triton.h" +#include "log.h" + +struct arg +{ + iplink_list_func func; + void *arg; +}; + +static int store_nlmsg(const struct sockaddr_nl *who, struct nlmsghdr *n, void *arg) +{ + struct ifinfomsg *ifi = NLMSG_DATA(n); + struct rtattr *tb[IFLA_MAX + 1]; + struct arg *a = arg; + + if (n->nlmsg_type != RTM_NEWLINK) + return 0; + + if (n->nlmsg_len < NLMSG_LENGTH(sizeof(*ifi))) + return -1; + + memset(tb, 0, sizeof(tb)); + parse_rtattr(tb, IFLA_MAX, IFLA_RTA(ifi), IFLA_PAYLOAD(n)); + + if (tb[IFLA_IFNAME] == NULL) + return 0; + + //printf("%i %s\n", ifi->ifi_index, RTA_DATA(tb[IFLA_IFNAME])); + + return a->func(ifi->ifi_index, ifi->ifi_flags, RTA_DATA(tb[IFLA_IFNAME]), a->arg); +} + +int __export iplink_list(iplink_list_func func, void *arg) +{ + struct rtnl_handle rth; + struct arg a = { .func = func, .arg = arg }; + + if (rtnl_open(&rth, 0)) { + log_emerg("iplink: cannot open rtnetlink\n"); + return -1; + } + + if (rtnl_wilddump_request(&rth, AF_PACKET, RTM_GETLINK) < 0) { + log_emerg("iplink: cannot send dump request\n"); + goto out_err; + } + + if (rtnl_dump_filter(&rth, store_nlmsg, &a, NULL, NULL) < 0) { + log_emerg("iplink: dump terminated\n"); + goto out_err; + } + + rtnl_close(&rth); + + return 0; + +out_err: + rtnl_close(&rth); + + return -1; +} + diff --git a/accel-pppd/libnetlink/iplink.h b/accel-pppd/libnetlink/iplink.h new file mode 100644 index 00000000..70c7c600 --- /dev/null +++ b/accel-pppd/libnetlink/iplink.h @@ -0,0 +1,8 @@ +#ifndef __IPLINK_H +#define __IPLINK_H + +typedef int (*iplink_list_func)(int index, int flags, const char *name, void *arg); + +int iplink_list(iplink_list_func func, void *arg); + +#endif diff --git a/accel-pppd/shaper/libnetlink.c b/accel-pppd/libnetlink/libnetlink.c index 74cd5cb5..55a1a67a 100644 --- a/accel-pppd/shaper/libnetlink.c +++ b/accel-pppd/libnetlink/libnetlink.c @@ -26,9 +26,11 @@ #include "libnetlink.h" #include "log.h" +#define __export __attribute__((visibility("default"))) + int rcvbuf = 1024 * 1024; -void rtnl_close(struct rtnl_handle *rth) +void __export rtnl_close(struct rtnl_handle *rth) { if (rth->fd >= 0) { close(rth->fd); @@ -36,7 +38,7 @@ void rtnl_close(struct rtnl_handle *rth) } } -int rtnl_open_byproto(struct rtnl_handle *rth, unsigned subscriptions, +int __export rtnl_open_byproto(struct rtnl_handle *rth, unsigned subscriptions, int protocol) { socklen_t addr_len; @@ -85,12 +87,12 @@ int rtnl_open_byproto(struct rtnl_handle *rth, unsigned subscriptions, return 0; } -int rtnl_open(struct rtnl_handle *rth, unsigned subscriptions) +int __export rtnl_open(struct rtnl_handle *rth, unsigned subscriptions) { return rtnl_open_byproto(rth, subscriptions, NETLINK_ROUTE); } -int rtnl_wilddump_request(struct rtnl_handle *rth, int family, int type) +int __export rtnl_wilddump_request(struct rtnl_handle *rth, int family, int type) { struct { struct nlmsghdr nlh; @@ -108,12 +110,12 @@ int rtnl_wilddump_request(struct rtnl_handle *rth, int family, int type) return send(rth->fd, (void*)&req, sizeof(req), 0); } -int rtnl_send(struct rtnl_handle *rth, const char *buf, int len) +int __export rtnl_send(struct rtnl_handle *rth, const char *buf, int len) { return send(rth->fd, buf, len, 0); } -int rtnl_send_check(struct rtnl_handle *rth, const char *buf, int len) +int __export rtnl_send_check(struct rtnl_handle *rth, const char *buf, int len) { struct nlmsghdr *h; int status; @@ -146,7 +148,7 @@ int rtnl_send_check(struct rtnl_handle *rth, const char *buf, int len) return 0; } -int rtnl_dump_request(struct rtnl_handle *rth, int type, void *req, int len) +int __export rtnl_dump_request(struct rtnl_handle *rth, int type, void *req, int len) { struct nlmsghdr nlh; struct sockaddr_nl nladdr; @@ -173,7 +175,7 @@ int rtnl_dump_request(struct rtnl_handle *rth, int type, void *req, int len) return sendmsg(rth->fd, &msg, 0); } -int rtnl_dump_filter_l(struct rtnl_handle *rth, +int __export rtnl_dump_filter_l(struct rtnl_handle *rth, const struct rtnl_dump_filter_arg *arg) { struct sockaddr_nl nladdr; @@ -266,7 +268,7 @@ skip_it: } } -int rtnl_dump_filter(struct rtnl_handle *rth, +int __export rtnl_dump_filter(struct rtnl_handle *rth, rtnl_filter_t filter, void *arg1, rtnl_filter_t junk, @@ -280,7 +282,7 @@ int rtnl_dump_filter(struct rtnl_handle *rth, return rtnl_dump_filter_l(rth, a); } -int rtnl_talk(struct rtnl_handle *rtnl, struct nlmsghdr *n, pid_t peer, +int __export rtnl_talk(struct rtnl_handle *rtnl, struct nlmsghdr *n, pid_t peer, unsigned groups, struct nlmsghdr *answer, rtnl_filter_t junk, void *jarg, int ignore_einval) @@ -405,7 +407,7 @@ int rtnl_talk(struct rtnl_handle *rtnl, struct nlmsghdr *n, pid_t peer, } } -int rtnl_listen(struct rtnl_handle *rtnl, +int __export rtnl_listen(struct rtnl_handle *rtnl, rtnl_filter_t handler, void *jarg) { @@ -480,7 +482,7 @@ int rtnl_listen(struct rtnl_handle *rtnl, } } -int rtnl_from_file(FILE *rtnl, rtnl_filter_t handler, +int __export rtnl_from_file(FILE *rtnl, rtnl_filter_t handler, void *jarg) { int status; @@ -535,7 +537,7 @@ int rtnl_from_file(FILE *rtnl, rtnl_filter_t handler, } } -int addattr32(struct nlmsghdr *n, int maxlen, int type, __u32 data) +int __export addattr32(struct nlmsghdr *n, int maxlen, int type, __u32 data) { int len = RTA_LENGTH(4); struct rtattr *rta; @@ -551,7 +553,7 @@ int addattr32(struct nlmsghdr *n, int maxlen, int type, __u32 data) return 0; } -int addattr_l(struct nlmsghdr *n, int maxlen, int type, const void *data, +int __export addattr_l(struct nlmsghdr *n, int maxlen, int type, const void *data, int alen) { int len = RTA_LENGTH(alen); @@ -569,7 +571,7 @@ int addattr_l(struct nlmsghdr *n, int maxlen, int type, const void *data, return 0; } -int addraw_l(struct nlmsghdr *n, int maxlen, const void *data, int len) +int __export addraw_l(struct nlmsghdr *n, int maxlen, const void *data, int len) { if (NLMSG_ALIGN(n->nlmsg_len) + NLMSG_ALIGN(len) > maxlen) { log_error("libnetlink: ""addraw_l ERROR: message exceeded bound of %d\n",maxlen); @@ -582,7 +584,7 @@ int addraw_l(struct nlmsghdr *n, int maxlen, const void *data, int len) return 0; } -struct rtattr *addattr_nest(struct nlmsghdr *n, int maxlen, int type) +struct rtattr __export *addattr_nest(struct nlmsghdr *n, int maxlen, int type) { struct rtattr *nest = NLMSG_TAIL(n); @@ -590,13 +592,13 @@ struct rtattr *addattr_nest(struct nlmsghdr *n, int maxlen, int type) return nest; } -int addattr_nest_end(struct nlmsghdr *n, struct rtattr *nest) +int __export addattr_nest_end(struct nlmsghdr *n, struct rtattr *nest) { nest->rta_len = (void *)NLMSG_TAIL(n) - (void *)nest; return n->nlmsg_len; } -struct rtattr *addattr_nest_compat(struct nlmsghdr *n, int maxlen, int type, +struct rtattr __export *addattr_nest_compat(struct nlmsghdr *n, int maxlen, int type, const void *data, int len) { struct rtattr *start = NLMSG_TAIL(n); @@ -606,7 +608,7 @@ struct rtattr *addattr_nest_compat(struct nlmsghdr *n, int maxlen, int type, return start; } -int addattr_nest_compat_end(struct nlmsghdr *n, struct rtattr *start) +int __export addattr_nest_compat_end(struct nlmsghdr *n, struct rtattr *start) { struct rtattr *nest = (void *)start + NLMSG_ALIGN(start->rta_len); @@ -615,7 +617,7 @@ int addattr_nest_compat_end(struct nlmsghdr *n, struct rtattr *start) return n->nlmsg_len; } -int rta_addattr32(struct rtattr *rta, int maxlen, int type, __u32 data) +int __export rta_addattr32(struct rtattr *rta, int maxlen, int type, __u32 data) { int len = RTA_LENGTH(4); struct rtattr *subrta; @@ -632,7 +634,7 @@ int rta_addattr32(struct rtattr *rta, int maxlen, int type, __u32 data) return 0; } -int rta_addattr_l(struct rtattr *rta, int maxlen, int type, +int __export rta_addattr_l(struct rtattr *rta, int maxlen, int type, const void *data, int alen) { struct rtattr *subrta; diff --git a/accel-pppd/shaper/libnetlink.h b/accel-pppd/libnetlink/libnetlink.h index f68bf8a1..f68bf8a1 100644 --- a/accel-pppd/shaper/libnetlink.h +++ b/accel-pppd/libnetlink/libnetlink.h diff --git a/accel-pppd/radius/auth.c b/accel-pppd/radius/auth.c index 6a0b3a96..6cb4e803 100644 --- a/accel-pppd/radius/auth.c +++ b/accel-pppd/radius/auth.c @@ -552,3 +552,31 @@ out: } +int rad_auth_null(struct radius_pd_t *rpd, const char *username, va_list args) +{ + struct rad_req_t *req; + int r = PWDB_DENIED; + + req = rad_req_alloc(rpd, CODE_ACCESS_REQUEST, username); + if (!req) + return PWDB_DENIED; + + if (conf_sid_in_auth) + if (rad_packet_add_str(req->pack, NULL, "Acct-Session-Id", rpd->ses->sessionid)) + return -1; + + r = rad_auth_send(req); + if (r == PWDB_SUCCESS) { + struct ev_radius_t ev = { + .ses = rpd->ses, + .request = req->pack, + .reply = req->reply, + }; + triton_event_fire(EV_RADIUS_ACCESS_ACCEPT, &ev); + } + + rad_req_free(req); + + return r; +} + diff --git a/accel-pppd/radius/radius.c b/accel-pppd/radius/radius.c index b654f29c..d880ad01 100644 --- a/accel-pppd/radius/radius.c +++ b/accel-pppd/radius/radius.c @@ -164,7 +164,9 @@ static int check(struct pwdb_t *pwdb, struct ap_session *ses, const char *userna r = rad_auth_mschap_v2(rpd, username, args); break; } - break; + case 0: + r = rad_auth_null(rpd, username, args); + break; } va_end(args); diff --git a/accel-pppd/radius/radius_p.h b/accel-pppd/radius/radius_p.h index e2c48bf9..f8adb465 100644 --- a/accel-pppd/radius/radius_p.h +++ b/accel-pppd/radius/radius_p.h @@ -154,6 +154,7 @@ int rad_auth_pap(struct radius_pd_t *rpd, const char *username, va_list args); int rad_auth_chap_md5(struct radius_pd_t *rpd, const char *username, va_list args); int rad_auth_mschap_v1(struct radius_pd_t *rpd, const char *username, va_list args); int rad_auth_mschap_v2(struct radius_pd_t *rpd, const char *username, va_list args); +int rad_auth_null(struct radius_pd_t *rpd, const char *username, va_list args); int rad_acct_start(struct radius_pd_t *rpd); void rad_acct_stop(struct radius_pd_t *rpd); diff --git a/accel-pppd/radius/req.c b/accel-pppd/radius/req.c index 33273b43..f452c425 100644 --- a/accel-pppd/radius/req.c +++ b/accel-pppd/radius/req.c @@ -71,12 +71,21 @@ struct rad_req_t *rad_req_alloc(struct radius_pd_t *rpd, int code, const char *u if (rad_packet_add_int(req->pack, NULL, "NAS-Port", ppp->ses.unit_idx)) goto out_err; } - if (rad_packet_add_val(req->pack, NULL, "NAS-Port-Type", "Virtual")) - goto out_err; - if (rad_packet_add_val(req->pack, NULL, "Service-Type", "Framed-User")) - goto out_err; - if (rad_packet_add_val(req->pack, NULL, "Framed-Protocol", "PPP")) - goto out_err; + + if (req->rpd->ses->ctrl->type == CTRL_TYPE_IPOE) { + if (rad_packet_add_val(req->pack, NULL, "NAS-Port-Type", "Ethernet")) + goto out_err; + } else { + if (rad_packet_add_val(req->pack, NULL, "NAS-Port-Type", "Virtual")) + goto out_err; + + if (rad_packet_add_val(req->pack, NULL, "Service-Type", "Framed-User")) + goto out_err; + + if (rad_packet_add_val(req->pack, NULL, "Framed-Protocol", "PPP")) + goto out_err; + } + if (rpd->ses->ctrl->calling_station_id) if (rad_packet_add_str(req->pack, NULL, "Calling-Station-Id", rpd->ses->ctrl->calling_station_id)) goto out_err; diff --git a/accel-pppd/shaper/CMakeLists.txt b/accel-pppd/shaper/CMakeLists.txt index 515fd839..3c1ac951 100644 --- a/accel-pppd/shaper/CMakeLists.txt +++ b/accel-pppd/shaper/CMakeLists.txt @@ -1,4 +1,4 @@ -ADD_LIBRARY(shaper SHARED shaper.c limiter.c leaf_qdisc.c tc_core.c libnetlink.c) +ADD_LIBRARY(shaper SHARED shaper.c limiter.c leaf_qdisc.c tc_core.c) INSTALL(TARGETS shaper LIBRARY DESTINATION lib/accel-ppp diff --git a/rfc/rfc2131.txt b/rfc/rfc2131.txt new file mode 100644 index 00000000..f45d9b86 --- /dev/null +++ b/rfc/rfc2131.txt @@ -0,0 +1,2523 @@ + + + + + + +Network Working Group R. Droms +Request for Comments: 2131 Bucknell University +Obsoletes: 1541 March 1997 +Category: Standards Track + + Dynamic Host Configuration Protocol + +Status of this memo + + This document specifies an Internet standards track protocol for the + Internet community, and requests discussion and suggestions for + improvements. Please refer to the current edition of the "Internet + Official Protocol Standards" (STD 1) for the standardization state + and status of this protocol. Distribution of this memo is unlimited. + +Abstract + + The Dynamic Host Configuration Protocol (DHCP) provides a framework + for passing configuration information to hosts on a TCPIP network. + DHCP is based on the Bootstrap Protocol (BOOTP) [7], adding the + capability of automatic allocation of reusable network addresses and + additional configuration options [19]. DHCP captures the behavior of + BOOTP relay agents [7, 21], and DHCP participants can interoperate + with BOOTP participants [9]. + +Table of Contents + + 1. Introduction. . . . . . . . . . . . . . . . . . . . . . . . . 2 + 1.1 Changes to RFC1541. . . . . . . . . . . . . . . . . . . . . . 3 + 1.2 Related Work. . . . . . . . . . . . . . . . . . . . . . . . . 4 + 1.3 Problem definition and issues . . . . . . . . . . . . . . . . 4 + 1.4 Requirements. . . . . . . . . . . . . . . . . . . . . . . . . 5 + 1.5 Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 6 + 1.6 Design goals. . . . . . . . . . . . . . . . . . . . . . . . . 6 + 2. Protocol Summary. . . . . . . . . . . . . . . . . . . . . . . 8 + 2.1 Configuration parameters repository . . . . . . . . . . . . . 11 + 2.2 Dynamic allocation of network addresses . . . . . . . . . . . 12 + 3. The Client-Server Protocol. . . . . . . . . . . . . . . . . . 13 + 3.1 Client-server interaction - allocating a network address. . . 13 + 3.2 Client-server interaction - reusing a previously allocated + network address . . . . . . . . . . . . . . . . . . . . . . . 17 + 3.3 Interpretation and representation of time values. . . . . . . 20 + 3.4 Obtaining parameters with externally configured network + address . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 + 3.5 Client parameters in DHCP . . . . . . . . . . . . . . . . . . 21 + 3.6 Use of DHCP in clients with multiple interfaces . . . . . . . 22 + 3.7 When clients should use DHCP. . . . . . . . . . . . . . . . . 22 + 4. Specification of the DHCP client-server protocol. . . . . . . 22 + + + +Droms Standards Track [Page 1] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + 4.1 Constructing and sending DHCP messages. . . . . . . . . . . . 22 + 4.2 DHCP server administrative controls . . . . . . . . . . . . . 25 + 4.3 DHCP server behavior. . . . . . . . . . . . . . . . . . . . . 26 + 4.4 DHCP client behavior. . . . . . . . . . . . . . . . . . . . . 34 + 5. Acknowledgments. . . . . . . . . . . . . . . . . . . . . . . .42 + 6. References . . . . . . . . . . . . . . . . . . . . . . . . . .42 + 7. Security Considerations. . . . . . . . . . . . . . . . . . . .43 + 8. Author's Address . . . . . . . . . . . . . . . . . . . . . . .44 + A. Host Configuration Parameters . . . . . . . . . . . . . . . .45 +List of Figures + 1. Format of a DHCP message . . . . . . . . . . . . . . . . . . . 9 + 2. Format of the 'flags' field. . . . . . . . . . . . . . . . . . 11 + 3. Timeline diagram of messages exchanged between DHCP client and + servers when allocating a new network address. . . . . . . . . 15 + 4. Timeline diagram of messages exchanged between DHCP client and + servers when reusing a previously allocated network address. . 18 + 5. State-transition diagram for DHCP clients. . . . . . . . . . . 34 +List of Tables + 1. Description of fields in a DHCP message. . . . . . . . . . . . 10 + 2. DHCP messages. . . . . . . . . . . . . . . . . . . . . . . . . 14 + 3. Fields and options used by DHCP servers. . . . . . . . . . . . 28 + 4. Client messages from various states. . . . . . . . . . . . . . 33 + 5. Fields and options used by DHCP clients. . . . . . . . . . . . 37 + +1. Introduction + + The Dynamic Host Configuration Protocol (DHCP) provides configuration + parameters to Internet hosts. DHCP consists of two components: a + protocol for delivering host-specific configuration parameters from a + DHCP server to a host and a mechanism for allocation of network + addresses to hosts. + + DHCP is built on a client-server model, where designated DHCP server + hosts allocate network addresses and deliver configuration parameters + to dynamically configured hosts. Throughout the remainder of this + document, the term "server" refers to a host providing initialization + parameters through DHCP, and the term "client" refers to a host + requesting initialization parameters from a DHCP server. + + A host should not act as a DHCP server unless explicitly configured + to do so by a system administrator. The diversity of hardware and + protocol implementations in the Internet would preclude reliable + operation if random hosts were allowed to respond to DHCP requests. + For example, IP requires the setting of many parameters within the + protocol implementation software. Because IP can be used on many + dissimilar kinds of network hardware, values for those parameters + cannot be guessed or assumed to have correct defaults. Also, + distributed address allocation schemes depend on a polling/defense + + + +Droms Standards Track [Page 2] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + mechanism for discovery of addresses that are already in use. IP + hosts may not always be able to defend their network addresses, so + that such a distributed address allocation scheme cannot be + guaranteed to avoid allocation of duplicate network addresses. + + DHCP supports three mechanisms for IP address allocation. In + "automatic allocation", DHCP assigns a permanent IP address to a + client. In "dynamic allocation", DHCP assigns an IP address to a + client for a limited period of time (or until the client explicitly + relinquishes the address). In "manual allocation", a client's IP + address is assigned by the network administrator, and DHCP is used + simply to convey the assigned address to the client. A particular + network will use one or more of these mechanisms, depending on the + policies of the network administrator. + + Dynamic allocation is the only one of the three mechanisms that + allows automatic reuse of an address that is no longer needed by the + client to which it was assigned. Thus, dynamic allocation is + particularly useful for assigning an address to a client that will be + connected to the network only temporarily or for sharing a limited + pool of IP addresses among a group of clients that do not need + permanent IP addresses. Dynamic allocation may also be a good choice + for assigning an IP address to a new client being permanently + connected to a network where IP addresses are sufficiently scarce + that it is important to reclaim them when old clients are retired. + Manual allocation allows DHCP to be used to eliminate the error-prone + process of manually configuring hosts with IP addresses in + environments where (for whatever reasons) it is desirable to manage + IP address assignment outside of the DHCP mechanisms. + + The format of DHCP messages is based on the format of BOOTP messages, + to capture the BOOTP relay agent behavior described as part of the + BOOTP specification [7, 21] and to allow interoperability of existing + BOOTP clients with DHCP servers. Using BOOTP relay agents eliminates + the necessity of having a DHCP server on each physical network + segment. + +1.1 Changes to RFC 1541 + + This document updates the DHCP protocol specification that appears in + RFC1541. A new DHCP message type, DHCPINFORM, has been added; see + section 3.4, 4.3 and 4.4 for details. The classing mechanism for + identifying DHCP clients to DHCP servers has been extended to include + "vendor" classes as defined in sections 4.2 and 4.3. The minimum + lease time restriction has been removed. Finally, many editorial + changes have been made to clarify the text as a result of experience + gained in DHCP interoperability tests. + + + + +Droms Standards Track [Page 3] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +1.2 Related Work + + There are several Internet protocols and related mechanisms that + address some parts of the dynamic host configuration problem. The + Reverse Address Resolution Protocol (RARP) [10] (through the + extensions defined in the Dynamic RARP (DRARP) [5]) explicitly + addresses the problem of network address discovery, and includes an + automatic IP address assignment mechanism. The Trivial File Transfer + Protocol (TFTP) [20] provides for transport of a boot image from a + boot server. The Internet Control Message Protocol (ICMP) [16] + provides for informing hosts of additional routers via "ICMP + redirect" messages. ICMP also can provide subnet mask information + through the "ICMP mask request" message and other information through + the (obsolete) "ICMP information request" message. Hosts can locate + routers through the ICMP router discovery mechanism [8]. + + BOOTP is a transport mechanism for a collection of configuration + information. BOOTP is also extensible, and official extensions [17] + have been defined for several configuration parameters. Morgan has + proposed extensions to BOOTP for dynamic IP address assignment [15]. + The Network Information Protocol (NIP), used by the Athena project at + MIT, is a distributed mechanism for dynamic IP address assignment + [19]. The Resource Location Protocol RLP [1] provides for location + of higher level services. Sun Microsystems diskless workstations use + a boot procedure that employs RARP, TFTP and an RPC mechanism called + "bootparams" to deliver configuration information and operating + system code to diskless hosts. (Sun Microsystems, Sun Workstation + and SunOS are trademarks of Sun Microsystems, Inc.) Some Sun + networks also use DRARP and an auto-installation mechanism to + automate the configuration of new hosts in an existing network. + + In other related work, the path minimum transmission unit (MTU) + discovery algorithm can determine the MTU of an arbitrary internet + path [14]. The Address Resolution Protocol (ARP) has been proposed + as a transport protocol for resource location and selection [6]. + Finally, the Host Requirements RFCs [3, 4] mention specific + requirements for host reconfiguration and suggest a scenario for + initial configuration of diskless hosts. + +1.3 Problem definition and issues + + DHCP is designed to supply DHCP clients with the configuration + parameters defined in the Host Requirements RFCs. After obtaining + parameters via DHCP, a DHCP client should be able to exchange packets + with any other host in the Internet. The TCP/IP stack parameters + supplied by DHCP are listed in Appendix A. + + + + + +Droms Standards Track [Page 4] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + Not all of these parameters are required for a newly initialized + client. A client and server may negotiate for the transmission of + only those parameters required by the client or specific to a + particular subnet. + + DHCP allows but does not require the configuration of client + parameters not directly related to the IP protocol. DHCP also does + not address registration of newly configured clients with the Domain + Name System (DNS) [12, 13]. + + DHCP is not intended for use in configuring routers. + +1.4 Requirements + + Throughout this document, the words that are used to define the + significance of particular requirements are capitalized. These words + are: + + o "MUST" + + This word or the adjective "REQUIRED" means that the + item is an absolute requirement of this specification. + + o "MUST NOT" + + This phrase means that the item is an absolute prohibition + of this specification. + + o "SHOULD" + + This word or the adjective "RECOMMENDED" means that there + may exist valid reasons in particular circumstances to ignore + this item, but the full implications should be understood and + the case carefully weighed before choosing a different course. + + o "SHOULD NOT" + + This phrase means that there may exist valid reasons in + particular circumstances when the listed behavior is acceptable + or even useful, but the full implications should be understood + and the case carefully weighed before implementing any behavior + described with this label. + + + + + + + + + +Droms Standards Track [Page 5] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + o "MAY" + + This word or the adjective "OPTIONAL" means that this item is + truly optional. One vendor may choose to include the item + because a particular marketplace requires it or because it + enhances the product, for example; another vendor may omit the + same item. + +1.5 Terminology + + This document uses the following terms: + + o "DHCP client" + + A DHCP client is an Internet host using DHCP to obtain + configuration parameters such as a network address. + + o "DHCP server" + + A DHCP server is an Internet host that returns configuration + parameters to DHCP clients. + + o "BOOTP relay agent" + + A BOOTP relay agent or relay agent is an Internet host or router + that passes DHCP messages between DHCP clients and DHCP servers. + DHCP is designed to use the same relay agent behavior as specified + in the BOOTP protocol specification. + + o "binding" + + A binding is a collection of configuration parameters, including + at least an IP address, associated with or "bound to" a DHCP + client. Bindings are managed by DHCP servers. + +1.6 Design goals + + The following list gives general design goals for DHCP. + + o DHCP should be a mechanism rather than a policy. DHCP must + allow local system administrators control over configuration + parameters where desired; e.g., local system administrators + should be able to enforce local policies concerning allocation + and access to local resources where desired. + + + + + + + +Droms Standards Track [Page 6] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + o Clients should require no manual configuration. Each client + should be able to discover appropriate local configuration + parameters without user intervention and incorporate those + parameters into its own configuration. + + o Networks should require no manual configuration for individual + clients. Under normal circumstances, the network manager + should not have to enter any per-client configuration + parameters. + + o DHCP should not require a server on each subnet. To allow for + scale and economy, DHCP must work across routers or through the + intervention of BOOTP relay agents. + + o A DHCP client must be prepared to receive multiple responses + to a request for configuration parameters. Some installations + may include multiple, overlapping DHCP servers to enhance + reliability and increase performance. + + o DHCP must coexist with statically configured, non-participating + hosts and with existing network protocol implementations. + + o DHCP must interoperate with the BOOTP relay agent behavior as + described by RFC 951 and by RFC 1542 [21]. + + o DHCP must provide service to existing BOOTP clients. + + The following list gives design goals specific to the transmission of + the network layer parameters. DHCP must: + + o Guarantee that any specific network address will not be in + use by more than one DHCP client at a time, + + o Retain DHCP client configuration across DHCP client reboot. A + DHCP client should, whenever possible, be assigned the same + configuration parameters (e.g., network address) in response + to each request, + + o Retain DHCP client configuration across server reboots, and, + whenever possible, a DHCP client should be assigned the same + configuration parameters despite restarts of the DHCP mechanism, + + o Allow automated assignment of configuration parameters to new + clients to avoid hand configuration for new clients, + + o Support fixed or permanent allocation of configuration + parameters to specific clients. + + + + +Droms Standards Track [Page 7] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +2. Protocol Summary + + From the client's point of view, DHCP is an extension of the BOOTP + mechanism. This behavior allows existing BOOTP clients to + interoperate with DHCP servers without requiring any change to the + clients' initialization software. RFC 1542 [2] details the + interactions between BOOTP and DHCP clients and servers [9]. There + are some new, optional transactions that optimize the interaction + between DHCP clients and servers that are described in sections 3 and + 4. + + Figure 1 gives the format of a DHCP message and table 1 describes + each of the fields in the DHCP message. The numbers in parentheses + indicate the size of each field in octets. The names for the fields + given in the figure will be used throughout this document to refer to + the fields in DHCP messages. + + There are two primary differences between DHCP and BOOTP. First, + DHCP defines mechanisms through which clients can be assigned a + network address for a finite lease, allowing for serial reassignment + of network addresses to different clients. Second, DHCP provides the + mechanism for a client to acquire all of the IP configuration + parameters that it needs in order to operate. + + DHCP introduces a small change in terminology intended to clarify the + meaning of one of the fields. What was the "vendor extensions" field + in BOOTP has been re-named the "options" field in DHCP. Similarly, + the tagged data items that were used inside the BOOTP "vendor + extensions" field, which were formerly referred to as "vendor + extensions," are now termed simply "options." + + + + + + + + + + + + + + + + + + + + + +Droms Standards Track [Page 8] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | op (1) | htype (1) | hlen (1) | hops (1) | + +---------------+---------------+---------------+---------------+ + | xid (4) | + +-------------------------------+-------------------------------+ + | secs (2) | flags (2) | + +-------------------------------+-------------------------------+ + | ciaddr (4) | + +---------------------------------------------------------------+ + | yiaddr (4) | + +---------------------------------------------------------------+ + | siaddr (4) | + +---------------------------------------------------------------+ + | giaddr (4) | + +---------------------------------------------------------------+ + | | + | chaddr (16) | + | | + | | + +---------------------------------------------------------------+ + | | + | sname (64) | + +---------------------------------------------------------------+ + | | + | file (128) | + +---------------------------------------------------------------+ + | | + | options (variable) | + +---------------------------------------------------------------+ + + Figure 1: Format of a DHCP message + + DHCP defines a new 'client identifier' option that is used to pass an + explicit client identifier to a DHCP server. This change eliminates + the overloading of the 'chaddr' field in BOOTP messages, where + 'chaddr' is used both as a hardware address for transmission of BOOTP + reply messages and as a client identifier. The 'client identifier' + is an opaque key, not to be interpreted by the server; for example, + the 'client identifier' may contain a hardware address, identical to + the contents of the 'chaddr' field, or it may contain another type of + identifier, such as a DNS name. The 'client identifier' chosen by a + DHCP client MUST be unique to that client within the subnet to which + the client is attached. If the client uses a 'client identifier' in + one message, it MUST use that same identifier in all subsequent + messages, to ensure that all servers correctly identify the client. + + + + +Droms Standards Track [Page 9] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + DHCP clarifies the interpretation of the 'siaddr' field as the + address of the server to use in the next step of the client's + bootstrap process. A DHCP server may return its own address in the + 'siaddr' field, if the server is prepared to supply the next + bootstrap service (e.g., delivery of an operating system executable + image). A DHCP server always returns its own address in the 'server + identifier' option. + + FIELD OCTETS DESCRIPTION + ----- ------ ----------- + + op 1 Message op code / message type. + 1 = BOOTREQUEST, 2 = BOOTREPLY + htype 1 Hardware address type, see ARP section in "Assigned + Numbers" RFC; e.g., '1' = 10mb ethernet. + hlen 1 Hardware address length (e.g. '6' for 10mb + ethernet). + hops 1 Client sets to zero, optionally used by relay agents + when booting via a relay agent. + xid 4 Transaction ID, a random number chosen by the + client, used by the client and server to associate + messages and responses between a client and a + server. + secs 2 Filled in by client, seconds elapsed since client + began address acquisition or renewal process. + flags 2 Flags (see figure 2). + ciaddr 4 Client IP address; only filled in if client is in + BOUND, RENEW or REBINDING state and can respond + to ARP requests. + yiaddr 4 'your' (client) IP address. + siaddr 4 IP address of next server to use in bootstrap; + returned in DHCPOFFER, DHCPACK by server. + giaddr 4 Relay agent IP address, used in booting via a + relay agent. + chaddr 16 Client hardware address. + sname 64 Optional server host name, null terminated string. + file 128 Boot file name, null terminated string; "generic" + name or null in DHCPDISCOVER, fully qualified + directory-path name in DHCPOFFER. + options var Optional parameters field. See the options + documents for a list of defined options. + + Table 1: Description of fields in a DHCP message + + The 'options' field is now variable length. A DHCP client must be + prepared to receive DHCP messages with an 'options' field of at least + length 312 octets. This requirement implies that a DHCP client must + be prepared to receive a message of up to 576 octets, the minimum IP + + + +Droms Standards Track [Page 10] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + datagram size an IP host must be prepared to accept [3]. DHCP + clients may negotiate the use of larger DHCP messages through the + 'maximum DHCP message size' option. The options field may be further + extended into the 'file' and 'sname' fields. + + In the case of a client using DHCP for initial configuration (before + the client's TCP/IP software has been completely configured), DHCP + requires creative use of the client's TCP/IP software and liberal + interpretation of RFC 1122. The TCP/IP software SHOULD accept and + forward to the IP layer any IP packets delivered to the client's + hardware address before the IP address is configured; DHCP servers + and BOOTP relay agents may not be able to deliver DHCP messages to + clients that cannot accept hardware unicast datagrams before the + TCP/IP software is configured. + + To work around some clients that cannot accept IP unicast datagrams + before the TCP/IP software is configured as discussed in the previous + paragraph, DHCP uses the 'flags' field [21]. The leftmost bit is + defined as the BROADCAST (B) flag. The semantics of this flag are + discussed in section 4.1 of this document. The remaining bits of the + flags field are reserved for future use. They MUST be set to zero by + clients and ignored by servers and relay agents. Figure 2 gives the + format of the 'flags' field. + + 1 1 1 1 1 1 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |B| MBZ | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + B: BROADCAST flag + + MBZ: MUST BE ZERO (reserved for future use) + + Figure 2: Format of the 'flags' field + +2.1 Configuration parameters repository + + The first service provided by DHCP is to provide persistent storage + of network parameters for network clients. The model of DHCP + persistent storage is that the DHCP service stores a key-value entry + for each client, where the key is some unique identifier (for + example, an IP subnet number and a unique identifier within the + subnet) and the value contains the configuration parameters for the + client. + + For example, the key might be the pair (IP-subnet-number, hardware- + address) (note that the "hardware-address" should be typed by the + + + +Droms Standards Track [Page 11] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + type of hardware to accommodate possible duplication of hardware + addresses resulting from bit-ordering problems in a mixed-media, + bridged network) allowing for serial or concurrent reuse of a + hardware address on different subnets, and for hardware addresses + that may not be globally unique. Alternately, the key might be the + pair (IP-subnet-number, hostname), allowing the server to assign + parameters intelligently to a DHCP client that has been moved to a + different subnet or has changed hardware addresses (perhaps because + the network interface failed and was replaced). The protocol defines + that the key will be (IP-subnet-number, hardware-address) unless the + client explicitly supplies an identifier using the 'client + identifier' option. A client can query the DHCP service to + retrieve its configuration parameters. The client interface to the + configuration parameters repository consists of protocol messages to + request configuration parameters and responses from the server + carrying the configuration parameters. + +2.2 Dynamic allocation of network addresses + + The second service provided by DHCP is the allocation of temporary or + permanent network (IP) addresses to clients. The basic mechanism for + the dynamic allocation of network addresses is simple: a client + requests the use of an address for some period of time. The + allocation mechanism (the collection of DHCP servers) guarantees not + to reallocate that address within the requested time and attempts to + return the same network address each time the client requests an + address. In this document, the period over which a network address + is allocated to a client is referred to as a "lease" [11]. The + client may extend its lease with subsequent requests. The client may + issue a message to release the address back to the server when the + client no longer needs the address. The client may ask for a + permanent assignment by asking for an infinite lease. Even when + assigning "permanent" addresses, a server may choose to give out + lengthy but non-infinite leases to allow detection of the fact that + the client has been retired. + + In some environments it will be necessary to reassign network + addresses due to exhaustion of available addresses. In such + environments, the allocation mechanism will reuse addresses whose + lease has expired. The server should use whatever information is + available in the configuration information repository to choose an + address to reuse. For example, the server may choose the least + recently assigned address. As a consistency check, the allocating + server SHOULD probe the reused address before allocating the address, + e.g., with an ICMP echo request, and the client SHOULD probe the + newly received address, e.g., with ARP. + + + + + +Droms Standards Track [Page 12] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +3. The Client-Server Protocol + + DHCP uses the BOOTP message format defined in RFC 951 and given in + table 1 and figure 1. The 'op' field of each DHCP message sent from + a client to a server contains BOOTREQUEST. BOOTREPLY is used in the + 'op' field of each DHCP message sent from a server to a client. + + The first four octets of the 'options' field of the DHCP message + contain the (decimal) values 99, 130, 83 and 99, respectively (this + is the same magic cookie as is defined in RFC 1497 [17]). The + remainder of the 'options' field consists of a list of tagged + parameters that are called "options". All of the "vendor extensions" + listed in RFC 1497 are also DHCP options. RFC 1533 gives the + complete set of options defined for use with DHCP. + + Several options have been defined so far. One particular option - + the "DHCP message type" option - must be included in every DHCP + message. This option defines the "type" of the DHCP message. + Additional options may be allowed, required, or not allowed, + depending on the DHCP message type. + + Throughout this document, DHCP messages that include a 'DHCP message + type' option will be referred to by the type of the message; e.g., a + DHCP message with 'DHCP message type' option type 1 will be referred + to as a "DHCPDISCOVER" message. + +3.1 Client-server interaction - allocating a network address + + The following summary of the protocol exchanges between clients and + servers refers to the DHCP messages described in table 2. The + timeline diagram in figure 3 shows the timing relationships in a + typical client-server interaction. If the client already knows its + address, some steps may be omitted; this abbreviated interaction is + described in section 3.2. + + 1. The client broadcasts a DHCPDISCOVER message on its local physical + subnet. The DHCPDISCOVER message MAY include options that suggest + values for the network address and lease duration. BOOTP relay + agents may pass the message on to DHCP servers not on the same + physical subnet. + + 2. Each server may respond with a DHCPOFFER message that includes an + available network address in the 'yiaddr' field (and other + configuration parameters in DHCP options). Servers need not + reserve the offered network address, although the protocol will + work more efficiently if the server avoids allocating the offered + network address to another client. When allocating a new address, + servers SHOULD check that the offered network address is not + + + +Droms Standards Track [Page 13] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + already in use; e.g., the server may probe the offered address + with an ICMP Echo Request. Servers SHOULD be implemented so that + network administrators MAY choose to disable probes of newly + allocated addresses. The server transmits the DHCPOFFER message + to the client, using the BOOTP relay agent if necessary. + + Message Use + ------- --- + + DHCPDISCOVER - Client broadcast to locate available servers. + + DHCPOFFER - Server to client in response to DHCPDISCOVER with + offer of configuration parameters. + + DHCPREQUEST - Client message to servers either (a) requesting + offered parameters from one server and implicitly + declining offers from all others, (b) confirming + correctness of previously allocated address after, + e.g., system reboot, or (c) extending the lease on a + particular network address. + + DHCPACK - Server to client with configuration parameters, + including committed network address. + + DHCPNAK - Server to client indicating client's notion of network + address is incorrect (e.g., client has moved to new + subnet) or client's lease as expired + + DHCPDECLINE - Client to server indicating network address is already + in use. + + DHCPRELEASE - Client to server relinquishing network address and + cancelling remaining lease. + + DHCPINFORM - Client to server, asking only for local configuration + parameters; client already has externally configured + network address. + + Table 2: DHCP messages + + + + + + + + + + + + +Droms Standards Track [Page 14] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + Server Client Server + (not selected) (selected) + + v v v + | | | + | Begins initialization | + | | | + | _____________/|\____________ | + |/DHCPDISCOVER | DHCPDISCOVER \| + | | | + Determines | Determines + configuration | configuration + | | | + |\ | ____________/ | + | \________ | /DHCPOFFER | + | DHCPOFFER\ |/ | + | \ | | + | Collects replies | + | \| | + | Selects configuration | + | | | + | _____________/|\____________ | + |/ DHCPREQUEST | DHCPREQUEST\ | + | | | + | | Commits configuration + | | | + | | _____________/| + | |/ DHCPACK | + | | | + | Initialization complete | + | | | + . . . + . . . + | | | + | Graceful shutdown | + | | | + | |\ ____________ | + | | DHCPRELEASE \| + | | | + | | Discards lease + | | | + v v v + Figure 3: Timeline diagram of messages exchanged between DHCP + client and servers when allocating a new network address + + + + + + + +Droms Standards Track [Page 15] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + 3. The client receives one or more DHCPOFFER messages from one or more + servers. The client may choose to wait for multiple responses. + The client chooses one server from which to request configuration + parameters, based on the configuration parameters offered in the + DHCPOFFER messages. The client broadcasts a DHCPREQUEST message + that MUST include the 'server identifier' option to indicate which + server it has selected, and that MAY include other options + specifying desired configuration values. The 'requested IP + address' option MUST be set to the value of 'yiaddr' in the + DHCPOFFER message from the server. This DHCPREQUEST message is + broadcast and relayed through DHCP/BOOTP relay agents. To help + ensure that any BOOTP relay agents forward the DHCPREQUEST message + to the same set of DHCP servers that received the original + DHCPDISCOVER message, the DHCPREQUEST message MUST use the same + value in the DHCP message header's 'secs' field and be sent to the + same IP broadcast address as the original DHCPDISCOVER message. + The client times out and retransmits the DHCPDISCOVER message if + the client receives no DHCPOFFER messages. + + 4. The servers receive the DHCPREQUEST broadcast from the client. + Those servers not selected by the DHCPREQUEST message use the + message as notification that the client has declined that server's + offer. The server selected in the DHCPREQUEST message commits the + binding for the client to persistent storage and responds with a + DHCPACK message containing the configuration parameters for the + requesting client. The combination of 'client identifier' or + 'chaddr' and assigned network address constitute a unique + identifier for the client's lease and are used by both the client + and server to identify a lease referred to in any DHCP messages. + Any configuration parameters in the DHCPACK message SHOULD NOT + conflict with those in the earlier DHCPOFFER message to which the + client is responding. The server SHOULD NOT check the offered + network address at this point. The 'yiaddr' field in the DHCPACK + messages is filled in with the selected network address. + + If the selected server is unable to satisfy the DHCPREQUEST message + (e.g., the requested network address has been allocated), the + server SHOULD respond with a DHCPNAK message. + + A server MAY choose to mark addresses offered to clients in + DHCPOFFER messages as unavailable. The server SHOULD mark an + address offered to a client in a DHCPOFFER message as available if + the server receives no DHCPREQUEST message from that client. + + 5. The client receives the DHCPACK message with configuration + parameters. The client SHOULD perform a final check on the + parameters (e.g., ARP for allocated network address), and notes the + duration of the lease specified in the DHCPACK message. At this + + + +Droms Standards Track [Page 16] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + point, the client is configured. If the client detects that the + address is already in use (e.g., through the use of ARP), the + client MUST send a DHCPDECLINE message to the server and restarts + the configuration process. The client SHOULD wait a minimum of ten + seconds before restarting the configuration process to avoid + excessive network traffic in case of looping. + + If the client receives a DHCPNAK message, the client restarts the + configuration process. + + The client times out and retransmits the DHCPREQUEST message if the + client receives neither a DHCPACK or a DHCPNAK message. The client + retransmits the DHCPREQUEST according to the retransmission + algorithm in section 4.1. The client should choose to retransmit + the DHCPREQUEST enough times to give adequate probability of + contacting the server without causing the client (and the user of + that client) to wait overly long before giving up; e.g., a client + retransmitting as described in section 4.1 might retransmit the + DHCPREQUEST message four times, for a total delay of 60 seconds, + before restarting the initialization procedure. If the client + receives neither a DHCPACK or a DHCPNAK message after employing the + retransmission algorithm, the client reverts to INIT state and + restarts the initialization process. The client SHOULD notify the + user that the initialization process has failed and is restarting. + + 6. The client may choose to relinquish its lease on a network address + by sending a DHCPRELEASE message to the server. The client + identifies the lease to be released with its 'client identifier', + or 'chaddr' and network address in the DHCPRELEASE message. If the + client used a 'client identifier' when it obtained the lease, it + MUST use the same 'client identifier' in the DHCPRELEASE message. + +3.2 Client-server interaction - reusing a previously allocated network + address + + If a client remembers and wishes to reuse a previously allocated + network address, a client may choose to omit some of the steps + described in the previous section. The timeline diagram in figure 4 + shows the timing relationships in a typical client-server interaction + for a client reusing a previously allocated network address. + + + + + + + + + + + +Droms Standards Track [Page 17] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + 1. The client broadcasts a DHCPREQUEST message on its local subnet. + The message includes the client's network address in the + 'requested IP address' option. As the client has not received its + network address, it MUST NOT fill in the 'ciaddr' field. BOOTP + relay agents pass the message on to DHCP servers not on the same + subnet. If the client used a 'client identifier' to obtain its + address, the client MUST use the same 'client identifier' in the + DHCPREQUEST message. + + 2. Servers with knowledge of the client's configuration parameters + respond with a DHCPACK message to the client. Servers SHOULD NOT + check that the client's network address is already in use; the + client may respond to ICMP Echo Request messages at this point. + + Server Client Server + + v v v + | | | + | Begins | + | initialization | + | | | + | /|\ | + | _________ __/ | \__________ | + | /DHCPREQU EST | DHCPREQUEST\ | + |/ | \| + | | | + Locates | Locates + configuration | configuration + | | | + |\ | /| + | \ | ___________/ | + | \ | / DHCPACK | + | \ _______ |/ | + | DHCPACK\ | | + | Initialization | + | complete | + | \| | + | | | + | (Subsequent | + | DHCPACKS | + | ignored) | + | | | + | | | + v v v + + Figure 4: Timeline diagram of messages exchanged between DHCP + client and servers when reusing a previously allocated + network address + + + +Droms Standards Track [Page 18] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + If the client's request is invalid (e.g., the client has moved + to a new subnet), servers SHOULD respond with a DHCPNAK message to + the client. Servers SHOULD NOT respond if their information is not + guaranteed to be accurate. For example, a server that identifies a + request for an expired binding that is owned by another server SHOULD + NOT respond with a DHCPNAK unless the servers are using an explicit + mechanism to maintain coherency among the servers. + + If 'giaddr' is 0x0 in the DHCPREQUEST message, the client is on + the same subnet as the server. The server MUST + broadcast the DHCPNAK message to the 0xffffffff broadcast address + because the client may not have a correct network address or subnet + mask, and the client may not be answering ARP requests. + Otherwise, the server MUST send the DHCPNAK message to the IP + address of the BOOTP relay agent, as recorded in 'giaddr'. The + relay agent will, in turn, forward the message directly to the + client's hardware address, so that the DHCPNAK can be delivered even + if the client has moved to a new network. + + 3. The client receives the DHCPACK message with configuration + parameters. The client performs a final check on the parameters + (as in section 3.1), and notes the duration of the lease specified + in the DHCPACK message. The specific lease is implicitly identified + by the 'client identifier' or 'chaddr' and the network address. At + this point, the client is configured. + + If the client detects that the IP address in the DHCPACK message + is already in use, the client MUST send a DHCPDECLINE message to the + server and restarts the configuration process by requesting a + new network address. This action corresponds to the client + moving to the INIT state in the DHCP state diagram, which is + described in section 4.4. + + If the client receives a DHCPNAK message, it cannot reuse its + remembered network address. It must instead request a new + address by restarting the configuration process, this time + using the (non-abbreviated) procedure described in section + 3.1. This action also corresponds to the client moving to + the INIT state in the DHCP state diagram. + + The client times out and retransmits the DHCPREQUEST message if + the client receives neither a DHCPACK nor a DHCPNAK message. The + client retransmits the DHCPREQUEST according to the retransmission + algorithm in section 4.1. The client should choose to retransmit + the DHCPREQUEST enough times to give adequate probability of + contacting the server without causing the client (and the user of + that client) to wait overly long before giving up; e.g., a client + retransmitting as described in section 4.1 might retransmit the + + + +Droms Standards Track [Page 19] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + DHCPREQUEST message four times, for a total delay of 60 seconds, + before restarting the initialization procedure. If the client + receives neither a DHCPACK or a DHCPNAK message after employing + the retransmission algorithm, the client MAY choose to use the + previously allocated network address and configuration parameters + for the remainder of the unexpired lease. This corresponds to + moving to BOUND state in the client state transition diagram shown + in figure 5. + + 4. The client may choose to relinquish its lease on a network + address by sending a DHCPRELEASE message to the server. The + client identifies the lease to be released with its + 'client identifier', or 'chaddr' and network address in the + DHCPRELEASE message. + + Note that in this case, where the client retains its network + address locally, the client will not normally relinquish its + lease during a graceful shutdown. Only in the case where the + client explicitly needs to relinquish its lease, e.g., the client + is about to be moved to a different subnet, will the client send + a DHCPRELEASE message. + +3.3 Interpretation and representation of time values + + A client acquires a lease for a network address for a fixed period of + time (which may be infinite). Throughout the protocol, times are to + be represented in units of seconds. The time value of 0xffffffff is + reserved to represent "infinity". + + As clients and servers may not have synchronized clocks, times are + represented in DHCP messages as relative times, to be interpreted + with respect to the client's local clock. Representing relative + times in units of seconds in an unsigned 32 bit word gives a range of + relative times from 0 to approximately 100 years, which is sufficient + for the relative times to be measured using DHCP. + + The algorithm for lease duration interpretation given in the previous + paragraph assumes that client and server clocks are stable relative + to each other. If there is drift between the two clocks, the server + may consider the lease expired before the client does. To + compensate, the server may return a shorter lease duration to the + client than the server commits to its local database of client + information. + +3.4 Obtaining parameters with externally configured network address + + If a client has obtained a network address through some other means + (e.g., manual configuration), it may use a DHCPINFORM request message + + + +Droms Standards Track [Page 20] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + to obtain other local configuration parameters. Servers receiving a + DHCPINFORM message construct a DHCPACK message with any local + configuration parameters appropriate for the client without: + allocating a new address, checking for an existing binding, filling + in 'yiaddr' or including lease time parameters. The servers SHOULD + unicast the DHCPACK reply to the address given in the 'ciaddr' field + of the DHCPINFORM message. + + The server SHOULD check the network address in a DHCPINFORM message + for consistency, but MUST NOT check for an existing lease. The + server forms a DHCPACK message containing the configuration + parameters for the requesting client and sends the DHCPACK message + directly to the client. + +3.5 Client parameters in DHCP + + Not all clients require initialization of all parameters listed in + Appendix A. Two techniques are used to reduce the number of + parameters transmitted from the server to the client. First, most of + the parameters have defaults defined in the Host Requirements RFCs; + if the client receives no parameters from the server that override + the defaults, a client uses those default values. Second, in its + initial DHCPDISCOVER or DHCPREQUEST message, a client may provide the + server with a list of specific parameters the client is interested + in. If the client includes a list of parameters in a DHCPDISCOVER + message, it MUST include that list in any subsequent DHCPREQUEST + messages. + + The client SHOULD include the 'maximum DHCP message size' option to + let the server know how large the server may make its DHCP messages. + The parameters returned to a client may still exceed the space + allocated to options in a DHCP message. In this case, two additional + options flags (which must appear in the 'options' field of the + message) indicate that the 'file' and 'sname' fields are to be used + for options. + + The client can inform the server which configuration parameters the + client is interested in by including the 'parameter request list' + option. The data portion of this option explicitly lists the options + requested by tag number. + + In addition, the client may suggest values for the network address + and lease time in the DHCPDISCOVER message. The client may include + the 'requested IP address' option to suggest that a particular IP + address be assigned, and may include the 'IP address lease time' + option to suggest the lease time it would like. Other options + representing "hints" at configuration parameters are allowed in a + DHCPDISCOVER or DHCPREQUEST message. However, additional options may + + + +Droms Standards Track [Page 21] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + be ignored by servers, and multiple servers may, therefore, not + return identical values for some options. The 'requested IP address' + option is to be filled in only in a DHCPREQUEST message when the + client is verifying network parameters obtained previously. The + client fills in the 'ciaddr' field only when correctly configured + with an IP address in BOUND, RENEWING or REBINDING state. + + If a server receives a DHCPREQUEST message with an invalid 'requested + IP address', the server SHOULD respond to the client with a DHCPNAK + message and may choose to report the problem to the system + administrator. The server may include an error message in the + 'message' option. + +3.6 Use of DHCP in clients with multiple interfaces + + A client with multiple network interfaces must use DHCP through each + interface independently to obtain configuration information + parameters for those separate interfaces. + +3.7 When clients should use DHCP + + A client SHOULD use DHCP to reacquire or verify its IP address and + network parameters whenever the local network parameters may have + changed; e.g., at system boot time or after a disconnection from the + local network, as the local network configuration may change without + the client's or user's knowledge. + + If a client has knowledge of a previous network address and is unable + to contact a local DHCP server, the client may continue to use the + previous network address until the lease for that address expires. + If the lease expires before the client can contact a DHCP server, the + client must immediately discontinue use of the previous network + address and may inform local users of the problem. + +4. Specification of the DHCP client-server protocol + + In this section, we assume that a DHCP server has a block of network + addresses from which it can satisfy requests for new addresses. Each + server also maintains a database of allocated addresses and leases in + local permanent storage. + +4.1 Constructing and sending DHCP messages + + DHCP clients and servers both construct DHCP messages by filling in + fields in the fixed format section of the message and appending + tagged data items in the variable length option area. The options + area includes first a four-octet 'magic cookie' (which was described + in section 3), followed by the options. The last option must always + + + +Droms Standards Track [Page 22] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + be the 'end' option. + + DHCP uses UDP as its transport protocol. DHCP messages from a client + to a server are sent to the 'DHCP server' port (67), and DHCP + messages from a server to a client are sent to the 'DHCP client' port + (68). A server with multiple network address (e.g., a multi-homed + host) MAY use any of its network addresses in outgoing DHCP messages. + + The 'server identifier' field is used both to identify a DHCP server + in a DHCP message and as a destination address from clients to + servers. A server with multiple network addresses MUST be prepared + to to accept any of its network addresses as identifying that server + in a DHCP message. To accommodate potentially incomplete network + connectivity, a server MUST choose an address as a 'server + identifier' that, to the best of the server's knowledge, is reachable + from the client. For example, if the DHCP server and the DHCP client + are connected to the same subnet (i.e., the 'giaddr' field in the + message from the client is zero), the server SHOULD select the IP + address the server is using for communication on that subnet as the + 'server identifier'. If the server is using multiple IP addresses on + that subnet, any such address may be used. If the server has + received a message through a DHCP relay agent, the server SHOULD + choose an address from the interface on which the message was + recieved as the 'server identifier' (unless the server has other, + better information on which to make its choice). DHCP clients MUST + use the IP address provided in the 'server identifier' option for any + unicast requests to the DHCP server. + + DHCP messages broadcast by a client prior to that client obtaining + its IP address must have the source address field in the IP header + set to 0. + + 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. + + If the options in a DHCP message extend into the 'sname' and 'file' + fields, the 'option overload' option MUST appear in the 'options' + field, with value 1, 2 or 3, as specified in RFC 1533. If the + + + +Droms Standards Track [Page 23] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + 'option overload' option is present in the 'options' field, the + options in the 'options' field MUST be terminated by an 'end' option, + and MAY contain one or more 'pad' options to fill the options field. + The options in the 'sname' and 'file' fields (if in use as indicated + by the 'options overload' option) MUST begin with the first octet of + the field, MUST be terminated by an 'end' option, and MUST be + followed by 'pad' options to fill the remainder of the field. Any + individual option in the 'options', 'sname' and 'file' fields MUST be + entirely contained in that field. The options in the 'options' field + MUST be interpreted first, so that any 'option overload' options may + be interpreted. The 'file' field MUST be interpreted next (if the + 'option overload' option indicates that the 'file' field contains + DHCP options), followed by the 'sname' field. + + The values to be passed in an 'option' tag may be too long to fit in + the 255 octets available to a single option (e.g., a list of routers + in a 'router' option [21]). Options may appear only once, unless + otherwise specified in the options document. The client concatenates + the values of multiple instances of the same option into a single + parameter list for configuration. + + DHCP clients are responsible for all message retransmission. The + client MUST adopt a retransmission strategy that incorporates a + randomized exponential backoff algorithm to determine the delay + between retransmissions. The delay between retransmissions SHOULD be + chosen to allow sufficient time for replies from the server to be + delivered based on the characteristics of the internetwork between + the client and the server. For example, in a 10Mb/sec Ethernet + internetwork, the delay before the first retransmission SHOULD be 4 + seconds randomized by the value of a uniform random number chosen + from the range -1 to +1. Clients with clocks that provide resolution + granularity of less than one second may choose a non-integer + randomization value. The delay before the next retransmission SHOULD + be 8 seconds randomized by the value of a uniform number chosen from + the range -1 to +1. The retransmission delay SHOULD be doubled with + subsequent retransmissions up to a maximum of 64 seconds. The client + MAY provide an indication of retransmission attempts to the user as + an indication of the progress of the configuration process. + + The 'xid' field is used by the client to match incoming DHCP messages + with pending requests. A DHCP client MUST choose 'xid's in such a + way as to minimize the chance of using an 'xid' identical to one used + by another client. For example, a client may choose a different, + random initial 'xid' each time the client is rebooted, and + subsequently use sequential 'xid's until the next reboot. Selecting + a new 'xid' for each retransmission is an implementation decision. A + client may choose to reuse the same 'xid' or select a new 'xid' for + each retransmitted message. + + + +Droms Standards Track [Page 24] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + Normally, DHCP servers and BOOTP relay agents attempt to deliver + DHCPOFFER, DHCPACK and DHCPNAK messages directly to the client using + uicast delivery. The IP destination address (in the IP header) is + set to the DHCP 'yiaddr' address and the link-layer destination + address is set to the DHCP 'chaddr' address. Unfortunately, some + client implementations are unable to receive such unicast IP + datagrams until the implementation has been configured with a valid + IP address (leading to a deadlock in which the client's IP address + cannot be delivered until the client has been configured with an IP + address). + + A client that cannot receive unicast IP datagrams until its protocol + software has been configured with an IP address SHOULD set the + BROADCAST bit in the 'flags' field to 1 in any DHCPDISCOVER or + DHCPREQUEST messages that client sends. The BROADCAST bit will + provide a hint to the DHCP server and BOOTP relay agent to broadcast + any messages to the client on the client's subnet. A client that can + receive unicast IP datagrams before its protocol software has been + configured SHOULD clear the BROADCAST bit to 0. The BOOTP + clarifications document discusses the ramifications of the use of the + BROADCAST bit [21]. + + A server or relay agent sending or relaying a DHCP message directly + to a DHCP client (i.e., not to a relay agent specified in the + 'giaddr' field) SHOULD examine the BROADCAST bit in the 'flags' + field. If this bit is set to 1, the DHCP message SHOULD be sent as + an IP broadcast using an IP broadcast address (preferably 0xffffffff) + as the IP destination address and the link-layer broadcast address as + the link-layer destination address. If the BROADCAST bit is cleared + to 0, the message SHOULD be sent as an IP unicast to the IP address + specified in the 'yiaddr' field and the link-layer address specified + in the 'chaddr' field. If unicasting is not possible, the message + MAY be sent as an IP broadcast using an IP broadcast address + (preferably 0xffffffff) as the IP destination address and the link- + layer broadcast address as the link-layer destination address. + +4.2 DHCP server administrative controls + + DHCP servers are not required to respond to every DHCPDISCOVER and + DHCPREQUEST message they receive. For example, a network + administrator, to retain stringent control over the clients attached + to the network, may choose to configure DHCP servers to respond only + to clients that have been previously registered through some external + mechanism. The DHCP specification describes only the interactions + between clients and servers when the clients and servers choose to + interact; it is beyond the scope of the DHCP specification to + describe all of the administrative controls that system + administrators might want to use. Specific DHCP server + + + +Droms Standards Track [Page 25] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + implementations may incorporate any controls or policies desired by a + network administrator. + + In some environments, a DHCP server will have to consider the values + of the vendor class options included in DHCPDISCOVER or DHCPREQUEST + messages when determining the correct parameters for a particular + client. + + A DHCP server needs to use some unique identifier to associate a + client with its lease. The client MAY choose to explicitly provide + the identifier through the 'client identifier' option. If the client + supplies a 'client identifier', the client MUST use the same 'client + identifier' in all subsequent messages, and the server MUST use that + identifier to identify the client. If the client does not provide a + 'client identifier' option, the server MUST use the contents of the + 'chaddr' field to identify the client. It is crucial for a DHCP + client to use an identifier unique within the subnet to which the + client is attached in the 'client identifier' option. Use of + 'chaddr' as the client's unique identifier may cause unexpected + results, as that identifier may be associated with a hardware + interface that could be moved to a new client. Some sites may choose + to use a manufacturer's serial number as the 'client identifier', to + avoid unexpected changes in a clients network address due to transfer + of hardware interfaces among computers. Sites may also choose to use + a DNS name as the 'client identifier', causing address leases to be + associated with the DNS name rather than a specific hardware box. + + DHCP clients are free to use any strategy in selecting a DHCP server + among those from which the client receives a DHCPOFFER message. The + client implementation of DHCP SHOULD provide a mechanism for the user + to select directly the 'vendor class identifier' values. + +4.3 DHCP server behavior + + A DHCP server processes incoming DHCP messages from a client based on + the current state of the binding for that client. A DHCP server can + receive the following messages from a client: + + o DHCPDISCOVER + + o DHCPREQUEST + + o DHCPDECLINE + + o DHCPRELEASE + + o DHCPINFORM + + + + +Droms Standards Track [Page 26] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + Table 3 gives the use of the fields and options in a DHCP message by + a server. The remainder of this section describes the action of the + DHCP server for each possible incoming message. + +4.3.1 DHCPDISCOVER message + + When a server receives a DHCPDISCOVER message from a client, the + server chooses a network address for the requesting client. If no + address is available, the server may choose to report the problem to + the system administrator. If an address is available, the new address + SHOULD be chosen as follows: + + o The client's current address as recorded in the client's current + binding, ELSE + + o The client's previous address as recorded in the client's (now + expired or released) binding, if that address is in the server's + pool of available addresses and not already allocated, ELSE + + o The address requested in the 'Requested IP Address' option, if that + address is valid and not already allocated, ELSE + + o A new address allocated from the server's pool of available + addresses; the address is selected based on the subnet from which + the message was received (if 'giaddr' is 0) or on the address of + the relay agent that forwarded the message ('giaddr' when not 0). + + As described in section 4.2, a server MAY, for administrative + reasons, assign an address other than the one requested, or may + refuse to allocate an address to a particular client even though free + addresses are available. + + Note that, in some network architectures (e.g., internets with more + than one IP subnet assigned to a physical network segment), it may be + the case that the DHCP client should be assigned an address from a + different subnet than the address recorded in 'giaddr'. Thus, DHCP + does not require that the client be assigned as address from the + subnet in 'giaddr'. A server is free to choose some other subnet, + and it is beyond the scope of the DHCP specification to describe ways + in which the assigned IP address might be chosen. + + While not required for correct operation of DHCP, the server SHOULD + NOT reuse the selected network address before the client responds to + the server's DHCPOFFER message. The server may choose to record the + address as offered to the client. + + The server must also choose an expiration time for the lease, as + follows: + + + +Droms Standards Track [Page 27] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + o IF the client has not requested a specific lease in the + DHCPDISCOVER message and the client already has an assigned network + address, the server returns the lease expiration time previously + assigned to that address (note that the client must explicitly + request a specific lease to extend the expiration time on a + previously assigned address), ELSE + + o IF the client has not requested a specific lease in the + DHCPDISCOVER message and the client does not have an assigned + network address, the server assigns a locally configured default + lease time, ELSE + + o IF the client has requested a specific lease in the DHCPDISCOVER + message (regardless of whether the client has an assigned network + address), the server may choose either to return the requested + lease (if the lease is acceptable to local policy) or select + another lease. + +Field DHCPOFFER DHCPACK DHCPNAK +----- --------- ------- ------- +'op' BOOTREPLY BOOTREPLY BOOTREPLY +'htype' (From "Assigned Numbers" RFC) +'hlen' (Hardware address length in octets) +'hops' 0 0 0 +'xid' 'xid' from client 'xid' from client 'xid' from client + DHCPDISCOVER DHCPREQUEST DHCPREQUEST + message message message +'secs' 0 0 0 +'ciaddr' 0 'ciaddr' from 0 + DHCPREQUEST or 0 +'yiaddr' IP address offered IP address 0 + to client assigned to client +'siaddr' IP address of next IP address of next 0 + bootstrap server bootstrap server +'flags' 'flags' from 'flags' from 'flags' from + client DHCPDISCOVER client DHCPREQUEST client DHCPREQUEST + message message message +'giaddr' 'giaddr' from 'giaddr' from 'giaddr' from + client DHCPDISCOVER client DHCPREQUEST client DHCPREQUEST + message message message +'chaddr' 'chaddr' from 'chaddr' from 'chaddr' from + client DHCPDISCOVER client DHCPREQUEST client DHCPREQUEST + message message message +'sname' Server host name Server host name (unused) + or options or options +'file' Client boot file Client boot file (unused) + name or options name or options +'options' options options + + + +Droms Standards Track [Page 28] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +Option DHCPOFFER DHCPACK DHCPNAK +------ --------- ------- ------- +Requested IP address MUST NOT MUST NOT MUST NOT +IP address lease time MUST MUST (DHCPREQUEST) MUST NOT + MUST NOT (DHCPINFORM) +Use 'file'/'sname' fields MAY MAY MUST NOT +DHCP message type DHCPOFFER DHCPACK DHCPNAK +Parameter request list MUST NOT MUST NOT MUST NOT +Message SHOULD SHOULD SHOULD +Client identifier MUST NOT MUST NOT MAY +Vendor class identifier MAY MAY MAY +Server identifier MUST MUST MUST +Maximum message size MUST NOT MUST NOT MUST NOT +All others MAY MAY MUST NOT + + Table 3: Fields and options used by DHCP servers + + Once the network address and lease have been determined, the server + constructs a DHCPOFFER message with the offered configuration + parameters. It is important for all DHCP servers to return the same + parameters (with the possible exception of a newly allocated network + address) to ensure predictable client behavior regardless of which + server the client selects. The configuration parameters MUST be + selected by applying the following rules in the order given below. + The network administrator is responsible for configuring multiple + DHCP servers to ensure uniform responses from those servers. The + server MUST return to the client: + + o The client's network address, as determined by the rules given + earlier in this section, + + o The expiration time for the client's lease, as determined by the + rules given earlier in this section, + + o Parameters requested by the client, according to the following + rules: + + -- IF the server has been explicitly configured with a default + value for the parameter, the server MUST include that value + in an appropriate option in the 'option' field, ELSE + + -- IF the server recognizes the parameter as a parameter + defined in the Host Requirements Document, the server MUST + include the default value for that parameter as given in the + Host Requirements Document in an appropriate option in the + 'option' field, ELSE + + -- The server MUST NOT return a value for that parameter, + + + +Droms Standards Track [Page 29] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + The server MUST supply as many of the requested parameters as + possible and MUST omit any parameters it cannot provide. The + server MUST include each requested parameter only once unless + explicitly allowed in the DHCP Options and BOOTP Vendor + Extensions document. + + o Any parameters from the existing binding that differ from the Host + Requirements Document defaults, + + o Any parameters specific to this client (as identified by + the contents of 'chaddr' or 'client identifier' in the DHCPDISCOVER + or DHCPREQUEST message), e.g., as configured by the network + administrator, + + o Any parameters specific to this client's class (as identified + by the contents of the 'vendor class identifier' + option in the DHCPDISCOVER or DHCPREQUEST message), + e.g., as configured by the network administrator; the parameters + MUST be identified by an exact match between the client's vendor + class identifiers and the client's classes identified in the + server, + + o Parameters with non-default values on the client's subnet. + + The server MAY choose to return the 'vendor class identifier' used to + determine the parameters in the DHCPOFFER message to assist the + client in selecting which DHCPOFFER to accept. The server inserts + the 'xid' field from the DHCPDISCOVER message into the 'xid' field of + the DHCPOFFER message and sends the DHCPOFFER message to the + requesting client. + +4.3.2 DHCPREQUEST message + + A DHCPREQUEST message may come from a client responding to a + DHCPOFFER message from a server, from a client verifying a previously + allocated IP address or from a client extending the lease on a + network address. If the DHCPREQUEST message contains a 'server + identifier' option, the message is in response to a DHCPOFFER + message. Otherwise, the message is a request to verify or extend an + existing lease. If the client uses a 'client identifier' in a + DHCPREQUEST message, it MUST use that same 'client identifier' in all + subsequent messages. If the client included a list of requested + parameters in a DHCPDISCOVER message, it MUST include that list in + all subsequent messages. + + + + + + + +Droms Standards Track [Page 30] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + Any configuration parameters in the DHCPACK message SHOULD NOT + conflict with those in the earlier DHCPOFFER message to which the + client is responding. The client SHOULD use the parameters in the + DHCPACK message for configuration. + + Clients send DHCPREQUEST messages as follows: + + o DHCPREQUEST generated during SELECTING state: + + Client inserts the address of the selected server in 'server + identifier', 'ciaddr' MUST be zero, 'requested IP address' MUST be + filled in with the yiaddr value from the chosen DHCPOFFER. + + Note that the client may choose to collect several DHCPOFFER + messages and select the "best" offer. The client indicates its + selection by identifying the offering server in the DHCPREQUEST + message. If the client receives no acceptable offers, the client + may choose to try another DHCPDISCOVER message. Therefore, the + servers may not receive a specific DHCPREQUEST from which they can + decide whether or not the client has accepted the offer. Because + the servers have not committed any network address assignments on + the basis of a DHCPOFFER, servers are free to reuse offered + network addresses in response to subsequent requests. As an + implementation detail, servers SHOULD NOT reuse offered addresses + and may use an implementation-specific timeout mechanism to decide + when to reuse an offered address. + + o DHCPREQUEST generated during INIT-REBOOT state: + + 'server identifier' MUST NOT be filled in, 'requested IP address' + option MUST be filled in with client's notion of its previously + assigned address. 'ciaddr' MUST be zero. The client is seeking to + verify a previously allocated, cached configuration. Server SHOULD + send a DHCPNAK message to the client if the 'requested IP address' + is incorrect, or is on the wrong network. + + Determining whether a client in the INIT-REBOOT state is on the + correct network is done by examining the contents of 'giaddr', the + 'requested IP address' option, and a database lookup. If the DHCP + server detects that the client is on the wrong net (i.e., the + result of applying the local subnet mask or remote subnet mask (if + 'giaddr' is not zero) to 'requested IP address' option value + doesn't match reality), then the server SHOULD send a DHCPNAK + message to the client. + + + + + + + +Droms Standards Track [Page 31] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + If the network is correct, then the DHCP server should check if + the client's notion of its IP address is correct. If not, then the + server SHOULD send a DHCPNAK message to the client. If the DHCP + server has no record of this client, then it MUST remain silent, + and MAY output a warning to the network administrator. This + behavior is necessary for peaceful coexistence of non- + communicating DHCP servers on the same wire. + + If 'giaddr' is 0x0 in the DHCPREQUEST message, the client is on + the same subnet as the server. The server MUST broadcast the + DHCPNAK message to the 0xffffffff broadcast address because the + client may not have a correct network address or subnet mask, and + the client may not be answering ARP requests. + + 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. + + o DHCPREQUEST generated during RENEWING state: + + 'server identifier' MUST NOT be filled in, 'requested IP address' + option MUST NOT be filled in, 'ciaddr' MUST be filled in with + client's IP address. In this situation, the client is completely + configured, and is trying to extend its lease. This message will + be unicast, so no relay agents will be involved in its + transmission. Because 'giaddr' is therefore not filled in, the + DHCP server will trust the value in 'ciaddr', and use it when + replying to the client. + + A client MAY choose to renew or extend its lease prior to T1. The + server may choose not to extend the lease (as a policy decision by + the network administrator), but should return a DHCPACK message + regardless. + + o DHCPREQUEST generated during REBINDING state: + + 'server identifier' MUST NOT be filled in, 'requested IP address' + option MUST NOT be filled in, 'ciaddr' MUST be filled in with + client's IP address. In this situation, the client is completely + configured, and is trying to extend its lease. This message MUST + be broadcast to the 0xffffffff IP broadcast address. The DHCP + server SHOULD check 'ciaddr' for correctness before replying to + the DHCPREQUEST. + + + + + + +Droms Standards Track [Page 32] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + The DHCPREQUEST from a REBINDING client is intended to accommodate + sites that have multiple DHCP servers and a mechanism for + maintaining consistency among leases managed by multiple servers. + A DHCP server MAY extend a client's lease only if it has local + administrative authority to do so. + +4.3.3 DHCPDECLINE message + + If the server receives a DHCPDECLINE message, the client has + discovered through some other means that the suggested network + address is already in use. The server MUST mark the network address + as not available and SHOULD notify the local system administrator of + a possible configuration problem. + +4.3.4 DHCPRELEASE message + + Upon receipt of a DHCPRELEASE message, the server marks the network + address as not allocated. The server SHOULD retain a record of the + client's initialization parameters for possible reuse in response to + subsequent requests from the client. + +4.3.5 DHCPINFORM message + + The server responds to a DHCPINFORM message by sending a DHCPACK + message directly to the address given in the 'ciaddr' field of the + DHCPINFORM message. The server MUST NOT send a lease expiration time + to the client and SHOULD NOT fill in 'yiaddr'. The server includes + other parameters in the DHCPACK message as defined in section 4.3.1. + +4.3.6 Client messages + + Table 4 details the differences between messages from clients in + various states. + + --------------------------------------------------------------------- + | |INIT-REBOOT |SELECTING |RENEWING |REBINDING | + --------------------------------------------------------------------- + |broad/unicast |broadcast |broadcast |unicast |broadcast | + |server-ip |MUST NOT |MUST |MUST NOT |MUST NOT | + |requested-ip |MUST |MUST |MUST NOT |MUST NOT | + |ciaddr |zero |zero |IP address |IP address| + --------------------------------------------------------------------- + + Table 4: Client messages from different states + + + + + + + +Droms Standards Track [Page 33] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +4.4 DHCP client behavior + + Figure 5 gives a state-transition diagram for a DHCP client. A + client can receive the following messages from a server: + + o DHCPOFFER + + o DHCPACK + + o DHCPNAK + + The DHCPINFORM message is not shown in figure 5. A client simply + sends the DHCPINFORM and waits for DHCPACK messages. Once the client + has selected its parameters, it has completed the configuration + process. + + Table 5 gives the use of the fields and options in a DHCP message by + a client. The remainder of this section describes the action of the + DHCP client for each possible incoming message. The description in + the following section corresponds to the full configuration procedure + previously described in section 3.1, and the text in the subsequent + section corresponds to the abbreviated configuration procedure + described in section 3.2. + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Droms Standards Track [Page 34] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + -------- ------- +| | +-------------------------->| |<-------------------+ +| INIT- | | +-------------------->| INIT | | +| REBOOT |DHCPNAK/ +---------->| |<---+ | +| |Restart| | ------- | | + -------- | DHCPNAK/ | | | + | Discard offer | -/Send DHCPDISCOVER | +-/Send DHCPREQUEST | | | + | | | DHCPACK v | | + ----------- | (not accept.)/ ----------- | | +| | | Send DHCPDECLINE | | | +| REBOOTING | | | | SELECTING |<----+ | +| | | / | | |DHCPOFFER/ | + ----------- | / ----------- | |Collect | + | | / | | | replies | +DHCPACK/ | / +----------------+ +-------+ | +Record lease, set| | v Select offer/ | +timers T1, T2 ------------ send DHCPREQUEST | | + | +----->| | DHCPNAK, Lease expired/ | + | | | REQUESTING | Halt network | + DHCPOFFER/ | | | | + Discard ------------ | | + | | | | ----------- | + | +--------+ DHCPACK/ | | | + | Record lease, set -----| REBINDING | | + | timers T1, T2 / | | | + | | DHCPACK/ ----------- | + | v Record lease, set ^ | + +----------------> ------- /timers T1,T2 | | + +----->| |<---+ | | + | | BOUND |<---+ | | + DHCPOFFER, DHCPACK, | | | T2 expires/ DHCPNAK/ + DHCPNAK/Discard ------- | Broadcast Halt network + | | | | DHCPREQUEST | + +-------+ | DHCPACK/ | | + T1 expires/ Record lease, set | | + Send DHCPREQUEST timers T1, T2 | | + to leasing server | | | + | ---------- | | + | | |------------+ | + +->| RENEWING | | + | |----------------------------+ + ---------- + Figure 5: State-transition diagram for DHCP clients + + + + + + + +Droms Standards Track [Page 35] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +4.4.1 Initialization and allocation of network address + + The client begins in INIT state and forms a DHCPDISCOVER message. + The client SHOULD wait a random time between one and ten seconds to + desynchronize the use of DHCP at startup. The client sets 'ciaddr' + to 0x00000000. The client MAY request specific parameters by + including the 'parameter request list' option. The client MAY + suggest a network address and/or lease time by including the + 'requested IP address' and 'IP address lease time' options. The + client MUST include its hardware address in the 'chaddr' field, if + necessary for delivery of DHCP reply messages. The client MAY + include a different unique identifier in the 'client identifier' + option, as discussed in section 4.2. If the client included a list + of requested parameters in a DHCPDISCOVER message, it MUST include + that list in all subsequent messages. + + The client generates and records a random transaction identifier and + inserts that identifier into the 'xid' field. The client records its + own local time for later use in computing the lease expiration. The + client then broadcasts the DHCPDISCOVER on the local hardware + broadcast address to the 0xffffffff IP broadcast address and 'DHCP + server' UDP port. + + If the 'xid' of an arriving DHCPOFFER message does not match the + 'xid' of the most recent DHCPDISCOVER message, the DHCPOFFER message + must be silently discarded. Any arriving DHCPACK messages must be + silently discarded. + + The client collects DHCPOFFER messages over a period of time, selects + one DHCPOFFER message from the (possibly many) incoming DHCPOFFER + messages (e.g., the first DHCPOFFER message or the DHCPOFFER message + from the previously used server) and extracts the server address from + the 'server identifier' option in the DHCPOFFER message. The time + over which the client collects messages and the mechanism used to + select one DHCPOFFER are implementation dependent. + + + + + + + + + + + + + + + + +Droms Standards Track [Page 36] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +Field DHCPDISCOVER DHCPREQUEST DHCPDECLINE, + DHCPINFORM DHCPRELEASE +----- ------------ ----------- ----------- +'op' BOOTREQUEST BOOTREQUEST BOOTREQUEST +'htype' (From "Assigned Numbers" RFC) +'hlen' (Hardware address length in octets) +'hops' 0 0 0 +'xid' selected by client 'xid' from server selected by + DHCPOFFER message client +'secs' 0 or seconds since 0 or seconds since 0 + DHCP process started DHCP process started +'flags' Set 'BROADCAST' Set 'BROADCAST' 0 + flag if client flag if client + requires broadcast requires broadcast + reply reply +'ciaddr' 0 (DHCPDISCOVER) 0 or client's 0 (DHCPDECLINE) + client's network address client's network + network address (BOUND/RENEW/REBIND) address + (DHCPINFORM) (DHCPRELEASE) +'yiaddr' 0 0 0 +'siaddr' 0 0 0 +'giaddr' 0 0 0 +'chaddr' client's hardware client's hardware client's hardware + address address address +'sname' options, if options, if (unused) + indicated in indicated in + 'sname/file' 'sname/file' + option; otherwise option; otherwise + unused unused +'file' options, if options, if (unused) + indicated in indicated in + 'sname/file' 'sname/file' + option; otherwise option; otherwise + unused unused +'options' options options (unused) + + + + + + + + + + + + + + + + +Droms Standards Track [Page 37] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +Option DHCPDISCOVER DHCPREQUEST DHCPDECLINE, + DHCPINFORM DHCPRELEASE +------ ------------ ----------- ----------- +Requested IP address MAY MUST (in MUST + (DISCOVER) SELECTING or (DHCPDECLINE), + MUST NOT INIT-REBOOT) MUST NOT + (INFORM) MUST NOT (in (DHCPRELEASE) + BOUND or + RENEWING) +IP address lease time MAY MAY MUST NOT + (DISCOVER) + MUST NOT + (INFORM) +Use 'file'/'sname' fields MAY MAY MAY +DHCP message type DHCPDISCOVER/ DHCPREQUEST DHCPDECLINE/ + DHCPINFORM DHCPRELEASE +Client identifier MAY MAY MAY +Vendor class identifier MAY MAY MUST NOT +Server identifier MUST NOT MUST (after MUST + SELECTING) + MUST NOT (after + INIT-REBOOT, + BOUND, RENEWING + or REBINDING) +Parameter request list MAY MAY MUST NOT +Maximum message size MAY MAY MUST NOT +Message SHOULD NOT SHOULD NOT SHOULD +Site-specific MAY MAY MUST NOT +All others MAY MAY MUST NOT + + Table 5: Fields and options used by DHCP clients + + If the parameters are acceptable, the client records the address of + the server that supplied the parameters from the 'server identifier' + field and sends that address in the 'server identifier' field of a + DHCPREQUEST broadcast message. Once the DHCPACK message from the + server arrives, the client is initialized and moves to BOUND state. + The DHCPREQUEST message contains the same 'xid' as the DHCPOFFER + message. The client records the lease expiration time as the sum of + the time at which the original request was sent and the duration of + the lease from the DHCPACK message. The client SHOULD perform a + check on the suggested address to ensure that the address is not + already in use. For example, if the client is on a network that + supports ARP, the client may issue an ARP request for the suggested + request. When broadcasting an ARP request for the suggested address, + the client must fill in its own hardware address as the sender's + hardware address, and 0 as the sender's IP address, to avoid + confusing ARP caches in other hosts on the same subnet. If the + + + +Droms Standards Track [Page 38] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + network address appears to be in use, the client MUST send a + DHCPDECLINE message to the server. The client SHOULD broadcast an ARP + reply to announce the client's new IP address and clear any outdated + ARP cache entries in hosts on the client's subnet. + +4.4.2 Initialization with known network address + + The client begins in INIT-REBOOT state and sends a DHCPREQUEST + message. The client MUST insert its known network address as a + 'requested IP address' option in the DHCPREQUEST message. The client + may request specific configuration parameters by including the + 'parameter request list' option. The client generates and records a + random transaction identifier and inserts that identifier into the + 'xid' field. The client records its own local time for later use in + computing the lease expiration. The client MUST NOT include a + 'server identifier' in the DHCPREQUEST message. The client then + broadcasts the DHCPREQUEST on the local hardware broadcast address to + the 'DHCP server' UDP port. + + Once a DHCPACK message with an 'xid' field matching that in the + client's DHCPREQUEST message arrives from any server, the client is + initialized and moves to BOUND state. The client records the lease + expiration time as the sum of the time at which the DHCPREQUEST + message was sent and the duration of the lease from the DHCPACK + message. + +4.4.3 Initialization with an externally assigned network address + + The client sends a DHCPINFORM message. The client may request + specific configuration parameters by including the 'parameter request + list' option. The client generates and records a random transaction + identifier and inserts that identifier into the 'xid' field. The + client places its own network address in the 'ciaddr' field. The + client SHOULD NOT request lease time parameters. + + The client then unicasts the DHCPINFORM to the DHCP server if it + knows the server's address, otherwise it broadcasts the message to + the limited (all 1s) broadcast address. DHCPINFORM messages MUST be + directed to the 'DHCP server' UDP port. + + Once a DHCPACK message with an 'xid' field matching that in the + client's DHCPINFORM message arrives from any server, the client is + initialized. + + If the client does not receive a DHCPACK within a reasonable period + of time (60 seconds or 4 tries if using timeout suggested in section + 4.1), then it SHOULD display a message informing the user of the + problem, and then SHOULD begin network processing using suitable + + + +Droms Standards Track [Page 39] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + defaults as per Appendix A. + +4.4.4 Use of broadcast and unicast + + The DHCP client broadcasts DHCPDISCOVER, DHCPREQUEST and DHCPINFORM + messages, unless the client knows the address of a DHCP server. The + client unicasts DHCPRELEASE messages to the server. Because the + client is declining the use of the IP address supplied by the server, + the client broadcasts DHCPDECLINE messages. + + When the DHCP client knows the address of a DHCP server, in either + INIT or REBOOTING state, the client may use that address in the + DHCPDISCOVER or DHCPREQUEST rather than the IP broadcast address. + The client may also use unicast to send DHCPINFORM messages to a + known DHCP server. If the client receives no response to DHCP + messages sent to the IP address of a known DHCP server, the DHCP + client reverts to using the IP broadcast address. + +4.4.5 Reacquisition and expiration + + The client maintains two times, T1 and T2, that specify the times at + which the client tries to extend its lease on its network address. + T1 is the time at which the client enters the RENEWING state and + attempts to contact the server that originally issued the client's + network address. T2 is the time at which the client enters the + REBINDING state and attempts to contact any server. T1 MUST be + earlier than T2, which, in turn, MUST be earlier than the time at + which the client's lease will expire. + + To avoid the need for synchronized clocks, T1 and T2 are expressed in + options as relative times [2]. + + At time T1 the client moves to RENEWING state and sends (via unicast) + a DHCPREQUEST message to the server to extend its lease. The client + sets the 'ciaddr' field in the DHCPREQUEST to its current network + address. The client records the local time at which the DHCPREQUEST + message is sent for computation of the lease expiration time. The + client MUST NOT include a 'server identifier' in the DHCPREQUEST + message. + + Any DHCPACK messages that arrive with an 'xid' that does not match + the 'xid' of the client's DHCPREQUEST message are silently discarded. + When the client receives a DHCPACK from the server, the client + computes the lease expiration time as the sum of the time at which + the client sent the DHCPREQUEST message and the duration of the lease + in the DHCPACK message. The client has successfully reacquired its + network address, returns to BOUND state and may continue network + processing. + + + +Droms Standards Track [Page 40] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + If no DHCPACK arrives before time T2, the client moves to REBINDING + state and sends (via broadcast) a DHCPREQUEST message to extend its + lease. The client sets the 'ciaddr' field in the DHCPREQUEST to its + current network address. The client MUST NOT include a 'server + identifier' in the DHCPREQUEST message. + + Times T1 and T2 are configurable by the server through options. T1 + defaults to (0.5 * duration_of_lease). T2 defaults to (0.875 * + duration_of_lease). Times T1 and T2 SHOULD be chosen with some + random "fuzz" around a fixed value, to avoid synchronization of + client reacquisition. + + A client MAY choose to renew or extend its lease prior to T1. The + server MAY choose to extend the client's lease according to policy + set by the network administrator. The server SHOULD return T1 and + T2, and their values SHOULD be adjusted from their original values to + take account of the time remaining on the lease. + + In both RENEWING and REBINDING states, if the client receives no + response to its DHCPREQUEST message, the client SHOULD wait one-half + of the remaining time until T2 (in RENEWING state) and one-half of + the remaining lease time (in REBINDING state), down to a minimum of + 60 seconds, before retransmitting the DHCPREQUEST message. + + If the lease expires before the client receives a DHCPACK, the client + moves to INIT state, MUST immediately stop any other network + processing and requests network initialization parameters as if the + client were uninitialized. If the client then receives a DHCPACK + allocating that client its previous network address, the client + SHOULD continue network processing. If the client is given a new + network address, it MUST NOT continue using the previous network + address and SHOULD notify the local users of the problem. + +4.4.6 DHCPRELEASE + + If the client no longer requires use of its assigned network address + (e.g., the client is gracefully shut down), the client sends a + DHCPRELEASE message to the server. Note that the correct operation + of DHCP does not depend on the transmission of DHCPRELEASE messages. + + + + + + + + + + + + +Droms Standards Track [Page 41] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +5. Acknowledgments + + The author thanks the many (and too numerous to mention!) members of + the DHC WG for their tireless and ongoing efforts in the development + of DHCP and this document. + + The efforts of J Allard, Mike Carney, Dave Lapp, Fred Lien and John + Mendonca in organizing DHCP interoperability testing sessions are + gratefully acknowledged. + + The development of this document was supported in part by grants from + the Corporation for National Research Initiatives (CNRI), Bucknell + University and Sun Microsystems. + +6. References + + [1] Acetta, M., "Resource Location Protocol", RFC 887, CMU, December + 1983. + + [2] Alexander, S., and R. Droms, "DHCP Options and BOOTP Vendor + Extensions", RFC 1533, Lachman Technology, Inc., Bucknell + University, October 1993. + + [3] Braden, R., Editor, "Requirements for Internet Hosts -- + Communication Layers", STD 3, RFC 1122, USC/Information Sciences + Institute, October 1989. + + [4] Braden, R., Editor, "Requirements for Internet Hosts -- + Application and Support, STD 3, RFC 1123, USC/Information + Sciences Institute, October 1989. + + [5] Brownell, D, "Dynamic Reverse Address Resolution Protocol + (DRARP)", Work in Progress. + + [6] Comer, D., and R. Droms, "Uniform Access to Internet Directory + Services", Proc. of ACM SIGCOMM '90 (Special issue of Computer + Communications Review), 20(4):50--59, 1990. + + [7] Croft, B., and J. Gilmore, "Bootstrap Protocol (BOOTP)", RFC 951, + Stanford and SUN Microsystems, September 1985. + + [8] Deering, S., "ICMP Router Discovery Messages", RFC 1256, Xerox + PARC, September 1991. + + [9] Droms, D., "Interoperation between DHCP and BOOTP", RFC 1534, + Bucknell University, October 1993. + + + + + +Droms Standards Track [Page 42] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + [10] Finlayson, R., Mann, T., Mogul, J., and M. Theimer, "A Reverse + Address Resolution Protocol", RFC 903, Stanford, June 1984. + + [11] Gray C., and D. Cheriton, "Leases: An Efficient Fault-Tolerant + Mechanism for Distributed File Cache Consistency", In Proc. of + the Twelfth ACM Symposium on Operating Systems Design, 1989. + + [12] Mockapetris, P., "Domain Names -- Concepts and Facilities", STD + 13, RFC 1034, USC/Information Sciences Institute, November 1987. + + [13] Mockapetris, P., "Domain Names -- Implementation and + Specification", STD 13, RFC 1035, USC/Information Sciences + Institute, November 1987. + + [14] Mogul J., and S. Deering, "Path MTU Discovery", RFC 1191, + November 1990. + + [15] Morgan, R., "Dynamic IP Address Assignment for Ethernet Attached + Hosts", Work in Progress. + + [16] Postel, J., "Internet Control Message Protocol", STD 5, RFC 792, + USC/Information Sciences Institute, September 1981. + + [17] Reynolds, J., "BOOTP Vendor Information Extensions", RFC 1497, + USC/Information Sciences Institute, August 1993. + + [18] Reynolds, J., and J. Postel, "Assigned Numbers", STD 2, RFC 1700, + USC/Information Sciences Institute, October 1994. + + [19] Jeffrey Schiller and Mark Rosenstein. A Protocol for the Dynamic + Assignment of IP Addresses for use on an Ethernet. (Available + from the Athena Project, MIT), 1989. + + [20] Sollins, K., "The TFTP Protocol (Revision 2)", RFC 783, NIC, + June 1981. + + [21] Wimer, W., "Clarifications and Extensions for the Bootstrap + Protocol", RFC 1542, Carnegie Mellon University, October 1993. + +7. Security Considerations + + DHCP is built directly on UDP and IP which are as yet inherently + insecure. Furthermore, DHCP is generally intended to make + maintenance of remote and/or diskless hosts easier. While perhaps + not impossible, configuring such hosts with passwords or keys may be + difficult and inconvenient. Therefore, DHCP in its current form is + quite insecure. + + + + +Droms Standards Track [Page 43] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + + Unauthorized DHCP servers may be easily set up. Such servers can + then send false and potentially disruptive information to clients + such as incorrect or duplicate IP addresses, incorrect routing + information (including spoof routers, etc.), incorrect domain + nameserver addresses (such as spoof nameservers), and so on. + Clearly, once this seed information is in place, an attacker can + further compromise affected systems. + + Malicious DHCP clients could masquerade as legitimate clients and + retrieve information intended for those legitimate clients. Where + dynamic allocation of resources is used, a malicious client could + claim all resources for itself, thereby denying resources to + legitimate clients. + +8. Author's Address + + Ralph Droms + Computer Science Department + 323 Dana Engineering + Bucknell University + Lewisburg, PA 17837 + + Phone: (717) 524-1145 + EMail: droms@bucknell.edu + + + + + + + + + + + + + + + + + + + + + + + + + + + +Droms Standards Track [Page 44] + +RFC 2131 Dynamic Host Configuration Protocol March 1997 + + +A. Host Configuration Parameters + + IP-layer_parameters,_per_host:_ + + Be a router on/off HRC 3.1 + Non-local source routing on/off HRC 3.3.5 + Policy filters for + non-local source routing (list) HRC 3.3.5 + Maximum reassembly size integer HRC 3.3.2 + Default TTL integer HRC 3.2.1.7 + PMTU aging timeout integer MTU 6.6 + MTU plateau table (list) MTU 7 + IP-layer_parameters,_per_interface:_ + IP address (address) HRC 3.3.1.6 + Subnet mask (address mask) HRC 3.3.1.6 + MTU integer HRC 3.3.3 + All-subnets-MTU on/off HRC 3.3.3 + Broadcast address flavor 0x00000000/0xffffffff HRC 3.3.6 + Perform mask discovery on/off HRC 3.2.2.9 + Be a mask supplier on/off HRC 3.2.2.9 + Perform router discovery on/off RD 5.1 + Router solicitation address (address) RD 5.1 + Default routers, list of: + router address (address) HRC 3.3.1.6 + preference level integer HRC 3.3.1.6 + Static routes, list of: + destination (host/subnet/net) HRC 3.3.1.2 + destination mask (address mask) HRC 3.3.1.2 + type-of-service integer HRC 3.3.1.2 + first-hop router (address) HRC 3.3.1.2 + ignore redirects on/off HRC 3.3.1.2 + PMTU integer MTU 6.6 + perform PMTU discovery on/off MTU 6.6 + + Link-layer_parameters,_per_interface:_ + Trailers on/off HRC 2.3.1 + ARP cache timeout integer HRC 2.3.2.1 + Ethernet encapsulation (RFC 894/RFC 1042) HRC 2.3.3 + + TCP_parameters,_per_host:_ + TTL integer HRC 4.2.2.19 + Keep-alive interval integer HRC 4.2.3.6 + Keep-alive data size 0/1 HRC 4.2.3.6 + +Key: + + MTU = Path MTU Discovery (RFC 1191, Proposed Standard) + RD = Router Discovery (RFC 1256, Proposed Standard) + + + +Droms Standards Track [Page 45] + diff --git a/rfc/rfc2132.txt b/rfc/rfc2132.txt new file mode 100644 index 00000000..e9c4f4b3 --- /dev/null +++ b/rfc/rfc2132.txt @@ -0,0 +1,1907 @@ + + + + + + +Network Working Group S. Alexander +Request for Comments: 2132 Silicon Graphics, Inc. +Obsoletes: 1533 R. Droms +Category: Standards Track Bucknell University + March 1997 + + DHCP Options and BOOTP Vendor Extensions + +Status of this memo + + This document specifies an Internet standards track protocol for the + Internet community, and requests discussion and suggestions for + improvements. Please refer to the current edition of the "Internet + Official Protocol Standards" (STD 1) for the standardization state + and status of this protocol. Distribution of this memo is unlimited. + +Abstract + + The Dynamic Host Configuration Protocol (DHCP) [1] provides a + framework for passing configuration information to hosts on a TCP/IP + network. Configuration parameters and other control information are + carried in tagged data items that are stored in the 'options' field + of the DHCP message. The data items themselves are also called + "options." + + This document specifies the current set of DHCP options. Future + options will be specified in separate RFCs. The current list of + valid options is also available in ftp://ftp.isi.edu/in- + notes/iana/assignments [22]. + + All of the vendor information extensions defined in RFC 1497 [2] may + be used as DHCP options. The definitions given in RFC 1497 are + included in this document, which supersedes RFC 1497. All of the + DHCP options defined in this document, except for those specific to + DHCP as defined in section 9, may be used as BOOTP vendor information + extensions. + +Table of Contents + + 1. Introduction .............................................. 2 + 2. BOOTP Extension/DHCP Option Field Format .................. 4 + 3. RFC 1497 Vendor Extensions ................................ 5 + 4. IP Layer Parameters per Host .............................. 11 + 5. IP Layer Parameters per Interface ........................ 13 + 6. Link Layer Parameters per Interface ....................... 16 + 7. TCP Parameters ............................................ 17 + 8. Application and Service Parameters ........................ 18 + 9. DHCP Extensions ........................................... 25 + + + +Alexander & Droms Standards Track [Page 1] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + 10. Defining new extensions ................................... 31 + 11. Acknowledgements .......................................... 31 + 12. References ................................................ 32 + 13. Security Considerations ................................... 33 + 14. Authors' Addresses ........................................ 34 + +1. Introduction + + This document specifies options for use with both the Dynamic Host + Configuration Protocol and the Bootstrap Protocol. + + The full description of DHCP packet formats may be found in the DHCP + specification document [1], and the full description of BOOTP packet + formats may be found in the BOOTP specification document [3]. This + document defines the format of information in the last field of DHCP + packets ('options') and of BOOTP packets ('vend'). The remainder of + this section defines a generalized use of this area for giving + information useful to a wide class of machines, operating systems and + configurations. Sites with a single DHCP or BOOTP server that is + shared among heterogeneous clients may choose to define other, site- + specific formats for the use of the 'options' field. + + Section 2 of this memo describes the formats of DHCP options and + BOOTP vendor extensions. Section 3 describes options defined in + previous documents for use with BOOTP (all may also be used with + DHCP). Sections 4-8 define new options intended for use with both + DHCP and BOOTP. Section 9 defines options used only in DHCP. + + References further describing most of the options defined in sections + 2-6 can be found in section 12. The use of the options defined in + section 9 is described in the DHCP specification [1]. + + Information on registering new options is contained in section 10. + + This document updates the definition of DHCP/BOOTP options that + appears in RFC1533. The classing mechanism has been extended to + include vendor classes as described in section 8.4 and 9.13. The new + procedure for defining new DHCP/BOOTP options in described in section + 10. Several new options, including NIS+ domain and servers, Mobile + IP home agent, SMTP server, TFTP server and Bootfile server, have + been added. Text giving definitions used throughout the document has + been added in section 1.1. Text emphasizing the need for uniqueness + of client-identifiers has been added to section 9.14. + + + + + + + + +Alexander & Droms Standards Track [Page 2] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + +1.1 Requirements + + Throughout this document, the words that are used to define the + significance of particular requirements are capitalized. These words + are: + + o "MUST" + + This word or the adjective "REQUIRED" means that the item is an + absolute requirement of this specification. + + o "MUST NOT" + + This phrase means that the item is an absolute prohibition of + this specification. + + o "SHOULD" + + This word or the adjective "RECOMMENDED" means that there may + exist valid reasons in particular circumstances to ignore this + item, but the full implications should be understood and the case + carefully weighed before choosing a different course. + + o "SHOULD NOT" + + This phrase means that there may exist valid reasons in + particular circumstances when the listed behavior is acceptable + or even useful, but the full implications should be understood + and the case carefully weighed before implementing any behavior + described with this label. + + o "MAY" + + This word or the adjective "OPTIONAL" means that this item is + truly optional. One vendor may choose to include the item + because a particular marketplace requires it or because it + enhances the product, for example; another vendor may omit the + same item. + +1.2 Terminology + + This document uses the following terms: + + o "DHCP client" + + A DHCP client or "client" is an Internet host using DHCP to + obtain configuration parameters such as a network address. + + + + +Alexander & Droms Standards Track [Page 3] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + o "DHCP server" + + A DHCP server of "server"is an Internet host that returns + configuration parameters to DHCP clients. + + o "binding" + + A binding is a collection of configuration parameters, including + at least an IP address, associated with or "bound to" a DHCP + client. Bindings are managed by DHCP servers. + +2. BOOTP Extension/DHCP Option Field Format + + + DHCP options have the same format as the BOOTP 'vendor extensions' + defined in RFC 1497 [2]. Options may be fixed length or variable + length. All options begin with a tag octet, which uniquely + identifies the option. Fixed-length options without data consist of + only a tag octet. Only options 0 and 255 are fixed length. All + other options are variable-length with a length octet following the + tag octet. The value of the length octet does not include the two + octets specifying the tag and length. The length octet is followed + by "length" octets of data. Options containing NVT ASCII data SHOULD + NOT include a trailing NULL; however, the receiver of such options + MUST be prepared to delete trailing nulls if they exist. The + receiver MUST NOT require that a trailing null be included in the + data. In the case of some variable-length options the length field + is a constant but must still be specified. + + Any options defined subsequent to this document MUST contain a length + octet even if the length is fixed or zero. + + All multi-octet quantities are in network byte-order. + + When used with BOOTP, the first four octets of the vendor information + field have been assigned to the "magic cookie" (as suggested in RFC + 951). This field identifies the mode in which the succeeding data is + to be interpreted. The value of the magic cookie is the 4 octet + dotted decimal 99.130.83.99 (or hexadecimal number 63.82.53.63) in + network byte order. + + All of the "vendor extensions" defined in RFC 1497 are also DHCP + options. + + Option codes 128 to 254 (decimal) are reserved for site-specific + options. + + + + + +Alexander & Droms Standards Track [Page 4] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + Except for the options in section 9, all options may be used with + either DHCP or BOOTP. + + Many of these options have their default values specified in other + documents. In particular, RFC 1122 [4] specifies default values for + most IP and TCP configuration parameters. + + Many options supply one or more 32-bit IP address. Use of IP + addresses rather than fully-qualified Domain Names (FQDNs) may make + future renumbering of IP hosts more difficult. Use of these + addresses is discouraged at sites that may require renumbering. + +3. RFC 1497 Vendor Extensions + + This section lists the vendor extensions as defined in RFC 1497. + They are defined here for completeness. + +3.1. Pad Option + + The pad option can be used to cause subsequent fields to align on + word boundaries. + + The code for the pad option is 0, and its length is 1 octet. + + Code + +-----+ + | 0 | + +-----+ + +3.2. End Option + + The end option marks the end of valid information in the vendor + field. Subsequent octets should be filled with pad options. + + The code for the end option is 255, and its length is 1 octet. + + Code + +-----+ + | 255 | + +-----+ + +3.3. Subnet Mask + + The subnet mask option specifies the client's subnet mask as per RFC + 950 [5]. + + If both the subnet mask and the router option are specified in a DHCP + reply, the subnet mask option MUST be first. + + + +Alexander & Droms Standards Track [Page 5] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The code for the subnet mask option is 1, and its length is 4 octets. + + Code Len Subnet Mask + +-----+-----+-----+-----+-----+-----+ + | 1 | 4 | m1 | m2 | m3 | m4 | + +-----+-----+-----+-----+-----+-----+ + +3.4. Time Offset + + The time offset field specifies the offset of the client's subnet in + seconds from Coordinated Universal Time (UTC). The offset is + expressed as a two's complement 32-bit integer. A positive offset + indicates a location east of the zero meridian and a negative offset + indicates a location west of the zero meridian. + + The code for the time offset option is 2, and its length is 4 octets. + + Code Len Time Offset + +-----+-----+-----+-----+-----+-----+ + | 2 | 4 | n1 | n2 | n3 | n4 | + +-----+-----+-----+-----+-----+-----+ + +3.5. Router Option + + The router option specifies a list of IP addresses for routers on the + client's subnet. Routers SHOULD be listed in order of preference. + + The code for the router option is 3. The minimum length for the + router option is 4 octets, and the length MUST always be a multiple + of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 3 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +3.6. Time Server Option + + The time server option specifies a list of RFC 868 [6] time servers + available to the client. Servers SHOULD be listed in order of + preference. + + The code for the time server option is 4. The minimum length for + this option is 4 octets, and the length MUST always be a multiple of + 4. + + + + + + +Alexander & Droms Standards Track [Page 6] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 4 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +3.7. Name Server Option + + The name server option specifies a list of IEN 116 [7] name servers + available to the client. Servers SHOULD be listed in order of + preference. + + The code for the name server option is 5. The minimum length for + this option is 4 octets, and the length MUST always be a multiple of + 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 5 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +3.8. Domain Name Server Option + + The domain name server option specifies a list of Domain Name System + (STD 13, RFC 1035 [8]) name servers available to the client. Servers + SHOULD be listed in order of preference. + + The code for the domain name server option is 6. The minimum length + for this option is 4 octets, and the length MUST always be a multiple + of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 6 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +3.9. Log Server Option + + The log server option specifies a list of MIT-LCS UDP log servers + available to the client. Servers SHOULD be listed in order of + preference. + + The code for the log server option is 7. The minimum length for this + option is 4 octets, and the length MUST always be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 7 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + + + +Alexander & Droms Standards Track [Page 7] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + +3.10. Cookie Server Option + + The cookie server option specifies a list of RFC 865 [9] cookie + servers available to the client. Servers SHOULD be listed in order + of preference. + + The code for the log server option is 8. The minimum length for this + option is 4 octets, and the length MUST always be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 8 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +3.11. LPR Server Option + + The LPR server option specifies a list of RFC 1179 [10] line printer + servers available to the client. Servers SHOULD be listed in order + of preference. + + The code for the LPR server option is 9. The minimum length for this + option is 4 octets, and the length MUST always be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 9 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +3.12. Impress Server Option + + The Impress server option specifies a list of Imagen Impress servers + available to the client. Servers SHOULD be listed in order of + preference. + + The code for the Impress server option is 10. The minimum length for + this option is 4 octets, and the length MUST always be a multiple of + 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 10 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +3.13. Resource Location Server Option + + This option specifies a list of RFC 887 [11] Resource Location + servers available to the client. Servers SHOULD be listed in order + of preference. + + + +Alexander & Droms Standards Track [Page 8] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The code for this option is 11. The minimum length for this option + is 4 octets, and the length MUST always be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 11 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +3.14. Host Name Option + + This option specifies the name of the client. The name may or may + not be qualified with the local domain name (see section 3.17 for the + preferred way to retrieve the domain name). See RFC 1035 for + character set restrictions. + + The code for this option is 12, and its minimum length is 1. + + Code Len Host Name + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 12 | n | h1 | h2 | h3 | h4 | h5 | h6 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +3.15. Boot File Size Option + + This option specifies the length in 512-octet blocks of the default + boot image for the client. The file length is specified as an + unsigned 16-bit integer. + + The code for this option is 13, and its length is 2. + + Code Len File Size + +-----+-----+-----+-----+ + | 13 | 2 | l1 | l2 | + +-----+-----+-----+-----+ + +3.16. Merit Dump File + + This option specifies the path-name of a file to which the client's + core image should be dumped in the event the client crashes. The + path is formatted as a character string consisting of characters from + the NVT ASCII character set. + + The code for this option is 14. Its minimum length is 1. + + Code Len Dump File Pathname + +-----+-----+-----+-----+-----+-----+--- + | 14 | n | n1 | n2 | n3 | n4 | ... + +-----+-----+-----+-----+-----+-----+--- + + + +Alexander & Droms Standards Track [Page 9] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + +3.17. Domain Name + + This option specifies the domain name that client should use when + resolving hostnames via the Domain Name System. + + The code for this option is 15. Its minimum length is 1. + + Code Len Domain Name + +-----+-----+-----+-----+-----+-----+-- + | 15 | n | d1 | d2 | d3 | d4 | ... + +-----+-----+-----+-----+-----+-----+-- + +3.18. Swap Server + + This specifies the IP address of the client's swap server. + + The code for this option is 16 and its length is 4. + + Code Len Swap Server Address + +-----+-----+-----+-----+-----+-----+ + | 16 | n | a1 | a2 | a3 | a4 | + +-----+-----+-----+-----+-----+-----+ + +3.19. Root Path + + This option specifies the path-name that contains the client's root + disk. The path is formatted as a character string consisting of + characters from the NVT ASCII character set. + + The code for this option is 17. Its minimum length is 1. + + Code Len Root Disk Pathname + +-----+-----+-----+-----+-----+-----+--- + | 17 | n | n1 | n2 | n3 | n4 | ... + +-----+-----+-----+-----+-----+-----+--- + +3.20. Extensions Path + + A string to specify a file, retrievable via TFTP, which contains + information which can be interpreted in the same way as the 64-octet + vendor-extension field within the BOOTP response, with the following + exceptions: + + - the length of the file is unconstrained; + - all references to Tag 18 (i.e., instances of the + BOOTP Extensions Path field) within the file are + ignored. + + + + +Alexander & Droms Standards Track [Page 10] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The code for this option is 18. Its minimum length is 1. + + Code Len Extensions Pathname + +-----+-----+-----+-----+-----+-----+--- + | 18 | n | n1 | n2 | n3 | n4 | ... + +-----+-----+-----+-----+-----+-----+--- + +4. IP Layer Parameters per Host + + This section details the options that affect the operation of the IP + layer on a per-host basis. + +4.1. IP Forwarding Enable/Disable Option + + This option specifies whether the client should configure its IP + layer for packet forwarding. A value of 0 means disable IP + forwarding, and a value of 1 means enable IP forwarding. + + The code for this option is 19, and its length is 1. + + Code Len Value + +-----+-----+-----+ + | 19 | 1 | 0/1 | + +-----+-----+-----+ + +4.2. Non-Local Source Routing Enable/Disable Option + + This option specifies whether the client should configure its IP + layer to allow forwarding of datagrams with non-local source routes + (see Section 3.3.5 of [4] for a discussion of this topic). A value + of 0 means disallow forwarding of such datagrams, and a value of 1 + means allow forwarding. + + The code for this option is 20, and its length is 1. + + Code Len Value + +-----+-----+-----+ + | 20 | 1 | 0/1 | + +-----+-----+-----+ + +4.3. Policy Filter Option + + This option specifies policy filters for non-local source routing. + The filters consist of a list of IP addresses and masks which specify + destination/mask pairs with which to filter incoming source routes. + + Any source routed datagram whose next-hop address does not match one + of the filters should be discarded by the client. + + + +Alexander & Droms Standards Track [Page 11] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + See [4] for further information. + + The code for this option is 21. The minimum length of this option is + 8, and the length MUST be a multiple of 8. + + Code Len Address 1 Mask 1 + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+ + | 21 | n | a1 | a2 | a3 | a4 | m1 | m2 | m3 | m4 | + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+ + Address 2 Mask 2 + +-----+-----+-----+-----+-----+-----+-----+-----+--- + | a1 | a2 | a3 | a4 | m1 | m2 | m3 | m4 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+--- + +4.4. Maximum Datagram Reassembly Size + + This option specifies the maximum size datagram that the client + should be prepared to reassemble. The size is specified as a 16-bit + unsigned integer. The minimum value legal value is 576. + + The code for this option is 22, and its length is 2. + + Code Len Size + +-----+-----+-----+-----+ + | 22 | 2 | s1 | s2 | + +-----+-----+-----+-----+ + +4.5. Default IP Time-to-live + + This option specifies the default time-to-live that the client should + use on outgoing datagrams. The TTL is specified as an octet with a + value between 1 and 255. + + The code for this option is 23, and its length is 1. + + Code Len TTL + +-----+-----+-----+ + | 23 | 1 | ttl | + +-----+-----+-----+ + +4.6. Path MTU Aging Timeout Option + + This option specifies the timeout (in seconds) to use when aging Path + MTU values discovered by the mechanism defined in RFC 1191 [12]. The + timeout is specified as a 32-bit unsigned integer. + + The code for this option is 24, and its length is 4. + + + + +Alexander & Droms Standards Track [Page 12] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + Code Len Timeout + +-----+-----+-----+-----+-----+-----+ + | 24 | 4 | t1 | t2 | t3 | t4 | + +-----+-----+-----+-----+-----+-----+ + +4.7. Path MTU Plateau Table Option + + This option specifies a table of MTU sizes to use when performing + Path MTU Discovery as defined in RFC 1191. The table is formatted as + a list of 16-bit unsigned integers, ordered from smallest to largest. + The minimum MTU value cannot be smaller than 68. + + The code for this option is 25. Its minimum length is 2, and the + length MUST be a multiple of 2. + + Code Len Size 1 Size 2 + +-----+-----+-----+-----+-----+-----+--- + | 25 | n | s1 | s2 | s1 | s2 | ... + +-----+-----+-----+-----+-----+-----+--- + +5. IP Layer Parameters per Interface + + This section details the options that affect the operation of the IP + layer on a per-interface basis. It is expected that a client can + issue multiple requests, one per interface, in order to configure + interfaces with their specific parameters. + +5.1. Interface MTU Option + + This option specifies the MTU to use on this interface. The MTU is + specified as a 16-bit unsigned integer. The minimum legal value for + the MTU is 68. + + The code for this option is 26, and its length is 2. + + Code Len MTU + +-----+-----+-----+-----+ + | 26 | 2 | m1 | m2 | + +-----+-----+-----+-----+ + +5.2. All Subnets are Local Option + + This option specifies whether or not the client may assume that all + subnets of the IP network to which the client is connected use the + same MTU as the subnet of that network to which the client is + directly connected. A value of 1 indicates that all subnets share + the same MTU. A value of 0 means that the client should assume that + some subnets of the directly connected network may have smaller MTUs. + + + +Alexander & Droms Standards Track [Page 13] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The code for this option is 27, and its length is 1. + + Code Len Value + +-----+-----+-----+ + | 27 | 1 | 0/1 | + +-----+-----+-----+ + +5.3. Broadcast Address Option + + This option specifies the broadcast address in use on the client's + subnet. Legal values for broadcast addresses are specified in + section 3.2.1.3 of [4]. + + The code for this option is 28, and its length is 4. + + Code Len Broadcast Address + +-----+-----+-----+-----+-----+-----+ + | 28 | 4 | b1 | b2 | b3 | b4 | + +-----+-----+-----+-----+-----+-----+ + +5.4. Perform Mask Discovery Option + + This option specifies whether or not the client should perform subnet + mask discovery using ICMP. A value of 0 indicates that the client + should not perform mask discovery. A value of 1 means that the + client should perform mask discovery. + + The code for this option is 29, and its length is 1. + + Code Len Value + +-----+-----+-----+ + | 29 | 1 | 0/1 | + +-----+-----+-----+ + +5.5. Mask Supplier Option + + This option specifies whether or not the client should respond to + subnet mask requests using ICMP. A value of 0 indicates that the + client should not respond. A value of 1 means that the client should + respond. + + The code for this option is 30, and its length is 1. + + Code Len Value + +-----+-----+-----+ + | 30 | 1 | 0/1 | + +-----+-----+-----+ + + + + +Alexander & Droms Standards Track [Page 14] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + +5.6. Perform Router Discovery Option + + This option specifies whether or not the client should solicit + routers using the Router Discovery mechanism defined in RFC 1256 + [13]. A value of 0 indicates that the client should not perform + router discovery. A value of 1 means that the client should perform + router discovery. + + The code for this option is 31, and its length is 1. + + Code Len Value + +-----+-----+-----+ + | 31 | 1 | 0/1 | + +-----+-----+-----+ + +5.7. Router Solicitation Address Option + + This option specifies the address to which the client should transmit + router solicitation requests. + + The code for this option is 32, and its length is 4. + + Code Len Address + +-----+-----+-----+-----+-----+-----+ + | 32 | 4 | a1 | a2 | a3 | a4 | + +-----+-----+-----+-----+-----+-----+ + +5.8. Static Route Option + + This option specifies a list of static routes that the client should + install in its routing cache. If multiple routes to the same + destination are specified, they are listed in descending order of + priority. + + The routes consist of a list of IP address pairs. The first address + is the destination address, and the second address is the router for + the destination. + + The default route (0.0.0.0) is an illegal destination for a static + route. See section 3.5 for information about the router option. + + The code for this option is 33. The minimum length of this option is + 8, and the length MUST be a multiple of 8. + + + + + + + + +Alexander & Droms Standards Track [Page 15] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + Code Len Destination 1 Router 1 + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+ + | 33 | n | d1 | d2 | d3 | d4 | r1 | r2 | r3 | r4 | + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+ + Destination 2 Router 2 + +-----+-----+-----+-----+-----+-----+-----+-----+--- + | d1 | d2 | d3 | d4 | r1 | r2 | r3 | r4 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+--- + +6. Link Layer Parameters per Interface + + This section lists the options that affect the operation of the data + link layer on a per-interface basis. + +6.1. Trailer Encapsulation Option + + This option specifies whether or not the client should negotiate the + use of trailers (RFC 893 [14]) when using the ARP protocol. A value + of 0 indicates that the client should not attempt to use trailers. A + value of 1 means that the client should attempt to use trailers. + + The code for this option is 34, and its length is 1. + + Code Len Value + +-----+-----+-----+ + | 34 | 1 | 0/1 | + +-----+-----+-----+ + +6.2. ARP Cache Timeout Option + + This option specifies the timeout in seconds for ARP cache entries. + The time is specified as a 32-bit unsigned integer. + + The code for this option is 35, and its length is 4. + + Code Len Time + +-----+-----+-----+-----+-----+-----+ + | 35 | 4 | t1 | t2 | t3 | t4 | + +-----+-----+-----+-----+-----+-----+ + +6.3. Ethernet Encapsulation Option + + This option specifies whether or not the client should use Ethernet + Version 2 (RFC 894 [15]) or IEEE 802.3 (RFC 1042 [16]) encapsulation + if the interface is an Ethernet. A value of 0 indicates that the + client should use RFC 894 encapsulation. A value of 1 means that the + client should use RFC 1042 encapsulation. + + + + +Alexander & Droms Standards Track [Page 16] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The code for this option is 36, and its length is 1. + + Code Len Value + +-----+-----+-----+ + | 36 | 1 | 0/1 | + +-----+-----+-----+ + +7. TCP Parameters + + This section lists the options that affect the operation of the TCP + layer on a per-interface basis. + +7.1. TCP Default TTL Option + + This option specifies the default TTL that the client should use when + sending TCP segments. The value is represented as an 8-bit unsigned + integer. The minimum value is 1. + + The code for this option is 37, and its length is 1. + + Code Len TTL + +-----+-----+-----+ + | 37 | 1 | n | + +-----+-----+-----+ + +7.2. TCP Keepalive Interval Option + + This option specifies the interval (in seconds) that the client TCP + should wait before sending a keepalive message on a TCP connection. + The time is specified as a 32-bit unsigned integer. A value of zero + indicates that the client should not generate keepalive messages on + connections unless specifically requested by an application. + + The code for this option is 38, and its length is 4. + + Code Len Time + +-----+-----+-----+-----+-----+-----+ + | 38 | 4 | t1 | t2 | t3 | t4 | + +-----+-----+-----+-----+-----+-----+ + +7.3. TCP Keepalive Garbage Option + + This option specifies the whether or not the client should send TCP + keepalive messages with a octet of garbage for compatibility with + older implementations. A value of 0 indicates that a garbage octet + should not be sent. A value of 1 indicates that a garbage octet + should be sent. + + + + +Alexander & Droms Standards Track [Page 17] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The code for this option is 39, and its length is 1. + + Code Len Value + +-----+-----+-----+ + | 39 | 1 | 0/1 | + +-----+-----+-----+ + +8. Application and Service Parameters + + This section details some miscellaneous options used to configure + miscellaneous applications and services. + +8.1. Network Information Service Domain Option + + This option specifies the name of the client's NIS [17] domain. The + domain is formatted as a character string consisting of characters + from the NVT ASCII character set. + + The code for this option is 40. Its minimum length is 1. + + Code Len NIS Domain Name + +-----+-----+-----+-----+-----+-----+--- + | 40 | n | n1 | n2 | n3 | n4 | ... + +-----+-----+-----+-----+-----+-----+--- + +8.2. Network Information Servers Option + + This option specifies a list of IP addresses indicating NIS servers + available to the client. Servers SHOULD be listed in order of + preference. + + The code for this option is 41. Its minimum length is 4, and the + length MUST be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 41 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +8.3. Network Time Protocol Servers Option + + This option specifies a list of IP addresses indicating NTP [18] + servers available to the client. Servers SHOULD be listed in order + of preference. + + The code for this option is 42. Its minimum length is 4, and the + length MUST be a multiple of 4. + + + + +Alexander & Droms Standards Track [Page 18] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 42 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +8.4. Vendor Specific Information + + This option is used by clients and servers to exchange vendor- + specific information. The information is an opaque object of n + octets, presumably interpreted by vendor-specific code on the clients + and servers. The definition of this information is vendor specific. + The vendor is indicated in the vendor class identifier option. + Servers not equipped to interpret the vendor-specific information + sent by a client MUST ignore it (although it may be reported). + Clients which do not receive desired vendor-specific information + SHOULD make an attempt to operate without it, although they may do so + (and announce they are doing so) in a degraded mode. + + If a vendor potentially encodes more than one item of information in + this option, then the vendor SHOULD encode the option using + "Encapsulated vendor-specific options" as described below: + + The Encapsulated vendor-specific options field SHOULD be encoded as a + sequence of code/length/value fields of identical syntax to the DHCP + options field with the following exceptions: + + 1) There SHOULD NOT be a "magic cookie" field in the encapsulated + vendor-specific extensions field. + + 2) Codes other than 0 or 255 MAY be redefined by the vendor within + the encapsulated vendor-specific extensions field, but SHOULD + conform to the tag-length-value syntax defined in section 2. + + 3) Code 255 (END), if present, signifies the end of the + encapsulated vendor extensions, not the end of the vendor + extensions field. If no code 255 is present, then the end of + the enclosing vendor-specific information field is taken as the + end of the encapsulated vendor-specific extensions field. + + The code for this option is 43 and its minimum length is 1. + + Code Len Vendor-specific information + +-----+-----+-----+-----+--- + | 43 | n | i1 | i2 | ... + +-----+-----+-----+-----+--- + + + + + + +Alexander & Droms Standards Track [Page 19] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + When encapsulated vendor-specific extensions are used, the + information bytes 1-n have the following format: + + Code Len Data item Code Len Data item Code + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+ + | T1 | n | d1 | d2 | ... | T2 | n | D1 | D2 | ... | ... | + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+ + +8.5. NetBIOS over TCP/IP Name Server Option + + The NetBIOS name server (NBNS) option specifies a list of RFC + 1001/1002 [19] [20] NBNS name servers listed in order of preference. + + The code for this option is 44. The minimum length of the option is + 4 octets, and the length must always be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+---- + | 44 | n | a1 | a2 | a3 | a4 | b1 | b2 | b3 | b4 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+---- + +8.6. NetBIOS over TCP/IP Datagram Distribution Server Option + + The NetBIOS datagram distribution server (NBDD) option specifies a + list of RFC 1001/1002 NBDD servers listed in order of preference. The + code for this option is 45. The minimum length of the option is 4 + octets, and the length must always be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+---- + | 45 | n | a1 | a2 | a3 | a4 | b1 | b2 | b3 | b4 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-----+-----+---- + +8.7. NetBIOS over TCP/IP Node Type Option + + The NetBIOS node type option allows NetBIOS over TCP/IP clients which + are configurable to be configured as described in RFC 1001/1002. The + value is specified as a single octet which identifies the client type + as follows: + + Value Node Type + ----- --------- + 0x1 B-node + 0x2 P-node + 0x4 M-node + 0x8 H-node + + + + + +Alexander & Droms Standards Track [Page 20] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + In the above chart, the notation '0x' indicates a number in base-16 + (hexadecimal). + + The code for this option is 46. The length of this option is always + 1. + + Code Len Node Type + +-----+-----+-----------+ + | 46 | 1 | see above | + +-----+-----+-----------+ + +8.8. NetBIOS over TCP/IP Scope Option + + The NetBIOS scope option specifies the NetBIOS over TCP/IP scope + parameter for the client as specified in RFC 1001/1002. See [19], + [20], and [8] for character-set restrictions. + + The code for this option is 47. The minimum length of this option is + 1. + + Code Len NetBIOS Scope + +-----+-----+-----+-----+-----+-----+---- + | 47 | n | s1 | s2 | s3 | s4 | ... + +-----+-----+-----+-----+-----+-----+---- + +8.9. X Window System Font Server Option + + This option specifies a list of X Window System [21] Font servers + available to the client. Servers SHOULD be listed in order of + preference. + + The code for this option is 48. The minimum length of this option is + 4 octets, and the length MUST be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+--- + | 48 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+--- + +8.10. X Window System Display Manager Option + + This option specifies a list of IP addresses of systems that are + running the X Window System Display Manager and are available to the + client. + + Addresses SHOULD be listed in order of preference. + + + + + +Alexander & Droms Standards Track [Page 21] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The code for the this option is 49. The minimum length of this option + is 4, and the length MUST be a multiple of 4. + + Code Len Address 1 Address 2 + + +-----+-----+-----+-----+-----+-----+-----+-----+--- + | 49 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+--- + +8.11. Network Information Service+ Domain Option + + This option specifies the name of the client's NIS+ [17] domain. The + domain is formatted as a character string consisting of characters + from the NVT ASCII character set. + + The code for this option is 64. Its minimum length is 1. + + Code Len NIS Client Domain Name + +-----+-----+-----+-----+-----+-----+--- + | 64 | n | n1 | n2 | n3 | n4 | ... + +-----+-----+-----+-----+-----+-----+--- + +8.12. Network Information Service+ Servers Option + + This option specifies a list of IP addresses indicating NIS+ servers + available to the client. Servers SHOULD be listed in order of + preference. + + The code for this option is 65. Its minimum length is 4, and the + length MUST be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 65 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +8.13. Mobile IP Home Agent option + + This option specifies a list of IP addresses indicating mobile IP + home agents available to the client. Agents SHOULD be listed in + order of preference. + + The code for this option is 68. Its minimum length is 0 (indicating + no home agents are available) and the length MUST be a multiple of 4. + It is expected that the usual length will be four octets, containing + a single home agent's address. + + + + + +Alexander & Droms Standards Track [Page 22] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + Code Len Home Agent Addresses (zero or more) + +-----+-----+-----+-----+-----+-----+-- + | 68 | n | a1 | a2 | a3 | a4 | ... + +-----+-----+-----+-----+-----+-----+-- + +8.14. Simple Mail Transport Protocol (SMTP) Server Option + + The SMTP server option specifies a list of SMTP servers available to + the client. Servers SHOULD be listed in order of preference. + + The code for the SMTP server option is 69. The minimum length for + this option is 4 octets, and the length MUST always be a multiple of + 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 69 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +8.15. Post Office Protocol (POP3) Server Option + + The POP3 server option specifies a list of POP3 available to the + client. Servers SHOULD be listed in order of preference. + + The code for the POP3 server option is 70. The minimum length for + this option is 4 octets, and the length MUST always be a multiple of + 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 70 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +8.16. Network News Transport Protocol (NNTP) Server Option + + The NNTP server option specifies a list of NNTP available to the + client. Servers SHOULD be listed in order of preference. + + The code for the NNTP server option is 71. The minimum length for + this option is 4 octets, and the length MUST always be a multiple of + 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 71 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + + + + + +Alexander & Droms Standards Track [Page 23] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + +8.17. Default World Wide Web (WWW) Server Option + + The WWW server option specifies a list of WWW available to the + client. Servers SHOULD be listed in order of preference. + + The code for the WWW server option is 72. The minimum length for + this option is 4 octets, and the length MUST always be a multiple of + 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 72 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +8.18. Default Finger Server Option + + The Finger server option specifies a list of Finger available to the + client. Servers SHOULD be listed in order of preference. + + The code for the Finger server option is 73. The minimum length for + this option is 4 octets, and the length MUST always be a multiple of + 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 73 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +8.19. Default Internet Relay Chat (IRC) Server Option + + The IRC server option specifies a list of IRC available to the + client. Servers SHOULD be listed in order of preference. + + The code for the IRC server option is 74. The minimum length for + this option is 4 octets, and the length MUST always be a multiple of + 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 74 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +8.20. StreetTalk Server Option + + The StreetTalk server option specifies a list of StreetTalk servers + available to the client. Servers SHOULD be listed in order of + preference. + + + + +Alexander & Droms Standards Track [Page 24] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The code for the StreetTalk server option is 75. The minimum length + for this option is 4 octets, and the length MUST always be a multiple + of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 75 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +8.21. StreetTalk Directory Assistance (STDA) Server Option + + The StreetTalk Directory Assistance (STDA) server option specifies a + list of STDA servers available to the client. Servers SHOULD be + listed in order of preference. + + The code for the StreetTalk Directory Assistance server option is 76. + The minimum length for this option is 4 octets, and the length MUST + always be a multiple of 4. + + Code Len Address 1 Address 2 + +-----+-----+-----+-----+-----+-----+-----+-----+-- + | 76 | n | a1 | a2 | a3 | a4 | a1 | a2 | ... + +-----+-----+-----+-----+-----+-----+-----+-----+-- + +9. DHCP Extensions + + This section details the options that are specific to DHCP. + +9.1. Requested IP Address + + This option is used in a client request (DHCPDISCOVER) to allow the + client to request that a particular IP address be assigned. + + The code for this option is 50, and its length is 4. + + Code Len Address + +-----+-----+-----+-----+-----+-----+ + | 50 | 4 | a1 | a2 | a3 | a4 | + +-----+-----+-----+-----+-----+-----+ + +9.2. IP Address Lease Time + + This option is used in a client request (DHCPDISCOVER or DHCPREQUEST) + to allow the client to request a lease time for the IP address. In a + server reply (DHCPOFFER), a DHCP server uses this option to specify + the lease time it is willing to offer. + + + + + +Alexander & Droms Standards Track [Page 25] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The time is in units of seconds, and is specified as a 32-bit + unsigned integer. + + The code for this option is 51, and its length is 4. + + Code Len Lease Time + +-----+-----+-----+-----+-----+-----+ + | 51 | 4 | t1 | t2 | t3 | t4 | + +-----+-----+-----+-----+-----+-----+ + +9.3. Option Overload + + This option is used to indicate that the DHCP 'sname' or 'file' + fields are being overloaded by using them to carry DHCP options. A + DHCP server inserts this option if the returned parameters will + exceed the usual space allotted for options. + + If this option is present, the client interprets the specified + additional fields after it concludes interpretation of the standard + option fields. + + The code for this option is 52, and its length is 1. Legal values + for this option are: + + Value Meaning + ----- -------- + 1 the 'file' field is used to hold options + 2 the 'sname' field is used to hold options + 3 both fields are used to hold options + + Code Len Value + +-----+-----+-----+ + | 52 | 1 |1/2/3| + +-----+-----+-----+ + +9.4 TFTP server name + + This option is used to identify a TFTP server when the 'sname' field + in the DHCP header has been used for DHCP options. + + The code for this option is 66, and its minimum length is 1. + + Code Len TFTP server + +-----+-----+-----+-----+-----+--- + | 66 | n | c1 | c2 | c3 | ... + +-----+-----+-----+-----+-----+--- + + + + + +Alexander & Droms Standards Track [Page 26] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + +9.5 Bootfile name + + This option is used to identify a bootfile when the 'file' field in + the DHCP header has been used for DHCP options. + + The code for this option is 67, and its minimum length is 1. + + Code Len Bootfile name + +-----+-----+-----+-----+-----+--- + | 67 | n | c1 | c2 | c3 | ... + +-----+-----+-----+-----+-----+--- + +9.6. DHCP Message Type + + This option is used to convey the type of the DHCP message. The code + for this option is 53, and its length is 1. Legal values for this + option are: + + Value Message Type + ----- ------------ + 1 DHCPDISCOVER + 2 DHCPOFFER + 3 DHCPREQUEST + 4 DHCPDECLINE + 5 DHCPACK + 6 DHCPNAK + 7 DHCPRELEASE + 8 DHCPINFORM + + Code Len Type + +-----+-----+-----+ + | 53 | 1 | 1-9 | + +-----+-----+-----+ + +9.7. Server Identifier + + This option is used in DHCPOFFER and DHCPREQUEST messages, and may + optionally be included in the DHCPACK and DHCPNAK messages. DHCP + servers include this option in the DHCPOFFER in order to allow the + client to distinguish between lease offers. DHCP clients use the + contents of the 'server identifier' field as the destination address + for any DHCP messages unicast to the DHCP server. DHCP clients also + indicate which of several lease offers is being accepted by including + this option in a DHCPREQUEST message. + + The identifier is the IP address of the selected server. + + The code for this option is 54, and its length is 4. + + + +Alexander & Droms Standards Track [Page 27] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + Code Len Address + +-----+-----+-----+-----+-----+-----+ + | 54 | 4 | a1 | a2 | a3 | a4 | + +-----+-----+-----+-----+-----+-----+ + +9.8. Parameter Request List + + This option is used by a DHCP client to request values for specified + configuration parameters. The list of requested parameters is + specified as n octets, where each octet is a valid DHCP option code + as defined in this document. + + The client MAY list the options in order of preference. The DHCP + server is not required to return the options in the requested order, + but MUST try to insert the requested options in the order requested + by the client. + + The code for this option is 55. Its minimum length is 1. + + Code Len Option Codes + +-----+-----+-----+-----+--- + | 55 | n | c1 | c2 | ... + +-----+-----+-----+-----+--- + +9.9. Message + + This option is used by a DHCP server to provide an error message to a + DHCP client in a DHCPNAK message in the event of a failure. A client + may use this option in a DHCPDECLINE message to indicate the why the + client declined the offered parameters. The message consists of n + octets of NVT ASCII text, which the client may display on an + available output device. + + The code for this option is 56 and its minimum length is 1. + + Code Len Text + +-----+-----+-----+-----+--- + | 56 | n | c1 | c2 | ... + +-----+-----+-----+-----+--- + +9.10. Maximum DHCP Message Size + + This option specifies the maximum length DHCP message that it is + willing to accept. The length is specified as an unsigned 16-bit + integer. A client may use the maximum DHCP message size option in + DHCPDISCOVER or DHCPREQUEST messages, but should not use the option + in DHCPDECLINE messages. + + + + +Alexander & Droms Standards Track [Page 28] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The code for this option is 57, and its length is 2. The minimum + legal value is 576 octets. + + Code Len Length + +-----+-----+-----+-----+ + | 57 | 2 | l1 | l2 | + +-----+-----+-----+-----+ + +9.11. Renewal (T1) Time Value + + This option specifies the time interval from address assignment until + the client transitions to the RENEWING state. + + The value is in units of seconds, and is specified as a 32-bit + unsigned integer. + + The code for this option is 58, and its length is 4. + + Code Len T1 Interval + +-----+-----+-----+-----+-----+-----+ + | 58 | 4 | t1 | t2 | t3 | t4 | + +-----+-----+-----+-----+-----+-----+ + +9.12. Rebinding (T2) Time Value + + This option specifies the time interval from address assignment until + the client transitions to the REBINDING state. + + The value is in units of seconds, and is specified as a 32-bit + unsigned integer. + + The code for this option is 59, and its length is 4. + + Code Len T2 Interval + +-----+-----+-----+-----+-----+-----+ + | 59 | 4 | t1 | t2 | t3 | t4 | + +-----+-----+-----+-----+-----+-----+ + +9.13. Vendor class identifier + + This option is used by DHCP clients to optionally identify the vendor + type and configuration of a DHCP client. The information is a string + of n octets, interpreted by servers. Vendors may choose to define + specific vendor class identifiers to convey particular configuration + or other identification information about a client. For example, the + identifier may encode the client's hardware configuration. Servers + not equipped to interpret the class-specific information sent by a + client MUST ignore it (although it may be reported). Servers that + + + +Alexander & Droms Standards Track [Page 29] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + respond SHOULD only use option 43 to return the vendor-specific + information to the client. + + The code for this option is 60, and its minimum length is 1. + + Code Len Vendor class Identifier + +-----+-----+-----+-----+--- + | 60 | n | i1 | i2 | ... + +-----+-----+-----+-----+--- + +9.14. Client-identifier + + This option is used by DHCP clients to specify their unique + identifier. DHCP servers use this value to index their database of + address bindings. This value is expected to be unique for all + clients in an administrative domain. + + Identifiers SHOULD be treated as opaque objects by DHCP servers. + + The client identifier MAY consist of type-value pairs similar to the + 'htype'/'chaddr' fields defined in [3]. For instance, it MAY consist + of a hardware type and hardware address. In this case the type field + SHOULD be one of the ARP hardware types defined in STD2 [22]. A + hardware type of 0 (zero) should be used when the value field + contains an identifier other than a hardware address (e.g. a fully + qualified domain name). + + For correct identification of clients, each client's client- + identifier MUST be unique among the client-identifiers used on the + subnet to which the client is attached. Vendors and system + administrators are responsible for choosing client-identifiers that + meet this requirement for uniqueness. + + The code for this option is 61, and its minimum length is 2. + + Code Len Type Client-Identifier + +-----+-----+-----+-----+-----+--- + | 61 | n | t1 | i1 | i2 | ... + +-----+-----+-----+-----+-----+--- + + + + + + + + + + + + +Alexander & Droms Standards Track [Page 30] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + +10. Defining new extensions + + The author of a new DHCP option will follow these steps to obtain + acceptance of the option as a part of the DHCP Internet Standard: + + 1. The author devises the new option. + 2. The author requests a number for the new option from IANA by + contacting: + Internet Assigned Numbers Authority (IANA) + USC/Information Sciences Institute + 4676 Admiralty Way + Marina del Rey, California 90292-6695 + + or by email as: iana@iana.org + + 3. The author documents the new option, using the newly obtained + option number, as an Internet Draft. + 4. The author submits the Internet Draft for review through the IETF + standards process as defined in "Internet Official Protocol + Standards" (STD 1). The new option will be submitted for eventual + acceptance as an Internet Standard. + 5. The new option progresses through the IETF standards process; the + new option will be reviewed by the Dynamic Host Configuration + Working Group (if that group still exists), or as an Internet + Draft not submitted by an IETF working group. + 6. If the new option fails to gain acceptance as an Internet + Standard, the assigned option number will be returned to IANA for + reassignment. + + This procedure for defining new extensions will ensure that: + + * allocation of new option numbers is coordinated from a single + authority, + * new options are reviewed for technical correctness and + appropriateness, and + * documentation for new options is complete and published. + +11. Acknowledgements + + The author thanks the many (and too numerous to mention!) members of + the DHC WG for their tireless and ongoing efforts in the development + of DHCP and this document. + + The efforts of J Allard, Mike Carney, Dave Lapp, Fred Lien and John + Mendonca in organizing DHCP interoperability testing sessions are + gratefully acknowledged. + + + + + +Alexander & Droms Standards Track [Page 31] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + The development of this document was supported in part by grants from + the Corporation for National Research Initiatives (CNRI), Bucknell + University and Sun Microsystems. + +12. References + + [1] Droms, R., "Dynamic Host Configuration Protocol", RFC 2131, + Bucknell University, March 1997. + + [2] Reynolds, J., "BOOTP Vendor Information Extensions", RFC 1497, + USC/Information Sciences Institute, August 1993. + + [3] Croft, W., and J. Gilmore, "Bootstrap Protocol", RFC 951, + Stanford University and Sun Microsystems, September 1985. + + [4] Braden, R., Editor, "Requirements for Internet Hosts - + Communication Layers", STD 3, RFC 1122, USC/Information Sciences + Institute, October 1989. + + [5] Mogul, J., and J. Postel, "Internet Standard Subnetting + Procedure", STD 5, RFC 950, USC/Information Sciences Institute, + August 1985. + + [6] Postel, J., and K. Harrenstien, "Time Protocol", STD 26, RFC + 868, USC/Information Sciences Institute, SRI, May 1983. + + [7] Postel, J., "Name Server", IEN 116, USC/Information Sciences + Institute, August 1979. + + [8] Mockapetris, P., "Domain Names - Implementation and + Specification", STD 13, RFC 1035, USC/Information Sciences + Institute, November 1987. + + [9] Postel, J., "Quote of the Day Protocol", STD 23, RFC 865, + USC/Information Sciences Institute, May 1983. + + [10] McLaughlin, L., "Line Printer Daemon Protocol", RFC 1179, The + Wollongong Group, August 1990. + + [11] Accetta, M., "Resource Location Protocol", RFC 887, CMU, + December 1983. + + [12] Mogul, J. and S. Deering, "Path MTU Discovery", RFC 1191, + DECWRL, Stanford University, November 1990. + + [13] Deering, S., "ICMP Router Discovery Messages", RFC 1256, + Xerox PARC, September 1991. + + + + +Alexander & Droms Standards Track [Page 32] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + + [14] Leffler, S. and M. Karels, "Trailer Encapsulations", RFC 893, + U. C. Berkeley, April 1984. + + [15] Hornig, C., "Standard for the Transmission of IP Datagrams over + Ethernet Networks", RFC 894, Symbolics, April 1984. + + [16] Postel, J. and J. Reynolds, "Standard for the Transmission of + IP Datagrams Over IEEE 802 Networks", RFC 1042, USC/Information + Sciences Institute, February 1988. + + [17] Sun Microsystems, "System and Network Administration", March + 1990. + + [18] Mills, D., "Internet Time Synchronization: The Network Time + Protocol", RFC 1305, UDEL, March 1992. + + [19] NetBIOS Working Group, "Protocol Standard for a NetBIOS Service + on a TCP/UDP transport: Concepts and Methods", STD 19, RFC 1001, + March 1987. + + [20] NetBIOS Working Group, "Protocol Standard for a NetBIOS Service + on a TCP/UDP transport: Detailed Specifications", STD 19, RFC + 1002, March 1987. + + [21] Scheifler, R., "FYI On the X Window System", FYI 6, RFC 1198, + MIT Laboratory for Computer Science, January 1991. + + [22] Reynolds, J., and J. Postel, "Assigned Numbers", STD 2, RFC 1700, + USC/Information Sciences Institute, July 1992. + +13. Security Considerations + + Security issues are not discussed in this memo. + + + + + + + + + + + + + + + + + + +Alexander & Droms Standards Track [Page 33] + +RFC 2132 DHCP Options and BOOTP Vendor Extensions March 1997 + + +14. Authors' Addresses + + Steve Alexander + Silicon Graphics, Inc. + 2011 N. Shoreline Boulevard + Mailstop 510 + Mountain View, CA 94043-1389 + + Phone: (415) 933-6172 + EMail: sca@engr.sgi.com + + + Ralph Droms + Bucknell University + Lewisburg, PA 17837 + + Phone: (717) 524-1145 + EMail: droms@bucknell.edu + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Alexander & Droms Standards Track [Page 34] + diff --git a/rfc/rfc3046.txt b/rfc/rfc3046.txt new file mode 100644 index 00000000..18d70144 --- /dev/null +++ b/rfc/rfc3046.txt @@ -0,0 +1,787 @@ + + + + + + +Network Working Group M. Patrick +Request for Comments: 3046 Motorola BCS +Category: Standards Track January 2001 + + + DHCP Relay Agent Information Option + +Status of this Memo + + This document specifies an Internet standards track protocol for the + Internet community, and requests discussion and suggestions for + improvements. Please refer to the current edition of the "Internet + Official Protocol Standards" (STD 1) for the standardization state + and status of this protocol. Distribution of this memo is unlimited. + +Copyright Notice + + Copyright (C) The Internet Society (2001). All Rights Reserved. + +Abstract + + Newer high-speed public Internet access technologies call for a + high-speed modem to have a local area network (LAN) attachment to one + or more customer premise hosts. It is advantageous to use the + Dynamic Host Configuration Protocol (DHCP) as defined in RFC 2131 to + assign customer premise host IP addresses in this environment. + However, a number of security and scaling problems arise with such + "public" DHCP use. This document describes a new DHCP option to + address these issues. This option extends the set of DHCP options as + defined in RFC 2132. + + The new option is called the Relay Agent Information option and is + inserted by the DHCP relay agent when forwarding client-originated + DHCP packets to a DHCP server. Servers recognizing the Relay Agent + Information option may use the information to implement IP address or + other parameter assignment policies. The DHCP Server echoes the + option back verbatim to the relay agent in server-to-client replies, + and the relay agent strips the option before forwarding the reply to + the client. + + The "Relay Agent Information" option is organized as a single DHCP + option that contains one or more "sub-options" that convey + information known by the relay agent. The initial sub-options are + defined for a relay agent that is co-located in a public circuit + access unit. These include a "circuit ID" for the incoming circuit, + and a "remote ID" which provides a trusted identifier for the remote + high-speed modem. + + + + +Patrick Standards Track [Page 1] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + +Table of Contents + + 1 Introduction........................................... 2 + 1.1 High-Speed Circuit Switched Data Networks.............. 2 + 1.2 DHCP Relay Agent in the Circuit Access Equipment....... 4 + 2.0 Relay Agent Information Option......................... 5 + 2.1 Agent Operation........................................ 6 + 2.1.1 Reforwarded DHCP requests............................ 7 + 2.2 Server Operation....................................... 7 + 3.0 Relay Agent Information Suboptions..................... 8 + 3.1 Agent Circuit ID....................................... 8 + 3.2 Agent Remote ID........................................ 9 + 4.0 Issues Resolved........................................ 9 + 5.0 Security Considerations................................ 10 + 6.0 IANA Considerations.................................... 11 + 7.0 Intellectual Property Notice........................... 12 + 8.0 References............................................. 12 + 9.0 Glossary............................................... 13 + 10.0 Author's Address...................................... 13 + 11.0 Full Copyright Statement ............................. 14 + +1 Introduction + +1.1 High-Speed Circuit Switched Data Networks + + Public Access to the Internet is usually via a circuit switched data + network. Today, this is primarily implemented with dial-up modems + connecting to a Remote Access Server. But higher speed circuit + access networks also include ISDN, ATM, Frame Relay, and Cable Data + Networks. All of these networks can be characterized as a "star" + topology where multiple users connect to a "circuit access unit" via + switched or permanent circuits. + + With dial-up modems, only a single host PC attempts to connect to the + central point. The PPP protocol is widely used to assign IP + addresses to be used by the single host PC. + + The newer high-speed circuit technologies, however, frequently + provide a LAN interface (especially Ethernet) to one or more host + PCs. It is desirable to support centralized assignment of the IP + addresses of host computers connecting on such circuits via DHCP. + The DHCP server can be, but usually is not, co-implemented with the + centralized circuit concentration access device. The DHCP server is + often connected as a separate server on the "Central LAN" to which + the central access device (or devices) attach. + + + + + + +Patrick Standards Track [Page 2] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + + A common physical model for high-speed Internet circuit access is + shown in Figure 1, below. + + +---------------+ | + Central | Circuit |-- ckt 1--- Modem1-- Host-|- Host A + LAN | | Access | Lan |- Host B + | | Unit 1 | |- Host C + |-----| |-- | + | |(relay agent) |... ++---------+ | +---------------+ +| DHCP |--| +| Server | | ++---------+ | + | + | +---------------+ ++---------+ | | Circuit |-- ckt 1--- Modem2-- Host--- Host D +| Other | | | Access | Lan +| Servers |--|-----| Unit 2 | +| (Web, | | | |-- ckt 2--- Modem3-- Host--- Host E +| DNS) | | |(relay agent) |... Lan +| | +---------------+ ++---------+ + + Figure 1: DHCP High Speed Circuit Access Model + + Note that in this model, the "modem" connects to a LAN at the user + site, rather than to a single host. Multiple hosts are implemented + at this site. Although it is certainly possible to implement a full + IP router at the user site, this requires a relatively expensive + piece of equipment (compared to typical modem costs). Furthermore, a + router requires an IP address not only for every host, but for the + router itself. Finally, a user-side router requires a dedicated + Logical IP Subnet (LIS) for each user. While this model is + appropriate for relatively small corporate networking environments, + it is not appropriate for large, public accessed networks. In this + scenario, it is advantageous to implement an IP networking model that + does not allocate an IP address for the modem (or other networking + equipment device at the user site), and especially not an entire LIS + for the user side LAN. + + Note that using this method to obtain IP addresses means that IP + addresses can only be obtained while communication to the central + site is available. Some host lan installations may use a local DHCP + server or other methods to obtain IP addresses for in-house use. + + + + + + + +Patrick Standards Track [Page 3] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + +1.2 DHCP Relay Agent in the Circuit Access Unit + + It is desirable to use DHCP to assign the IP addresses for public + high-speed circuit access. A number of circuit access units (e.g., + RAS's, cable modem termination systems, ADSL access units, etc) + connect to a LAN (or local internet) to which is attached a DHCP + server. + + For scaling and security reasons, it is advantageous to implement a + "router hop" at the circuit access unit, much like high-capacity + RAS's do today. The circuit access equipment acts as both a router + to the circuits and as the DHCP relay agent. + + The advantages of co-locating the DHCP relay agent with the circuit + access equipment are: + + DHCP broadcast replies can be routed to only the proper circuit, + avoiding, say, the replication of the DCHP reply broadcast onto + thousands of access circuits; + + The same mechanism used to identify the remote connection of the + circuit (e.g., a user ID requested by a Remote Access Server acting + as the circuit access equipment) may be used as a host identifier by + DHCP, and used for parameter assignment. This includes centralized + assignment of IP addresses to hosts. This provides a secure remote + ID from a trusted source -- the relay agent. + + A number of issues arise when forwarding DHCP requests from hosts + connecting publicly accessed high-speed circuits with LAN connections + at the host. Many of these are security issues arising from DHCP + client requests from untrusted sources. How does the relay agent + know to which circuit to forward replies? How does the system + prevent DHCP IP exhaustion attacks? This is when an attacker + requests all available IP addresses from a DHCP server by sending + requests with fabricated client MAC addresses. How can an IP address + or LIS be permanently assigned to a particular user or modem? How + does one prevent "spoofing" of client identifier fields used to + assign IP addresses? How does one prevent denial of service by + "spoofing" other client's MAC addresses? + + All of these issues may be addressed by having the circuit access + equipment, which is a trusted component, add information to DHCP + client requests that it forwards to the DHCP server. + + + + + + + + +Patrick Standards Track [Page 4] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + +2.0 Relay Agent Information Option + + This document defines a new DHCP Option called the Relay Agent + Information Option. It is a "container" option for specific agent- + supplied sub-options. The format of the Relay Agent Information + option is: + + Code Len Agent Information Field + +------+------+------+------+------+------+--...-+------+ + | 82 | N | i1 | i2 | i3 | i4 | | iN | + +------+------+------+------+------+------+--...-+------+ + + The length N gives the total number of octets in the Agent + Information Field. The Agent Information field consists of a + sequence of SubOpt/Length/Value tuples for each sub-option, encoded + in the following manner: + + SubOpt Len Sub-option Value + +------+------+------+------+------+------+--...-+------+ + | 1 | N | s1 | s2 | s3 | s4 | | sN | + +------+------+------+------+------+------+--...-+------+ + SubOpt Len Sub-option Value + +------+------+------+------+------+------+--...-+------+ + | 2 | N | i1 | i2 | i3 | i4 | | iN | + +------+------+------+------+------+------+--...-+------+ + + No "pad" sub-option is defined, and the Information field shall NOT + be terminated with a 255 sub-option. The length N of the DHCP Agent + Information Option shall include all bytes of the sub-option + code/length/value tuples. Since at least one sub-option must be + defined, the minimum Relay Agent Information length is two (2). The + length N of the sub-options shall be the number of octets in only + that sub-option's value field. A sub-option length may be zero. The + sub-options need not appear in sub-option code order. + + The initial assignment of DHCP Relay Agent Sub-options is as follows: + + DHCP Agent Sub-Option Description + Sub-option Code + --------------- ---------------------- + 1 Agent Circuit ID Sub-option + 2 Agent Remote ID Sub-option + + + + + + + + + +Patrick Standards Track [Page 5] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + +2.1 Agent Operation + + Overall adding of the DHCP relay agent option SHOULD be configurable, + and SHOULD be disabled by default. Relay agents SHOULD have separate + configurables for each sub-option to control whether it is added to + client-to-server packets. + + A DHCP relay agent adding a Relay Agent Information field SHALL add + it as the last option (but before 'End Option' 255, if present) in + the DHCP options field of any recognized BOOTP or DHCP packet + forwarded from a client to a server. + + Relay agents receiving a DHCP packet from an untrusted circuit with + giaddr set to zero (indicating that they are the first-hop router) + but with a Relay Agent Information option already present in the + packet SHALL discard the packet and increment an error count. A + trusted circuit may contain a trusted downstream (closer to client) + network element (bridge) between the relay agent and the client that + MAY add a relay agent option but not set the giaddr field. In this + case, the relay agent does NOT add a "second" relay agent option, but + forwards the DHCP packet per normal DHCP relay agent operations, + setting the giaddr field as it deems appropriate. + + The mechanisms for distinguishing between "trusted" and "untrusted" + circuits are specific to the type of circuit termination equipment, + and may involve local administration. For example, a Cable Modem + Termination System may consider upstream packets from most cable + modems as "untrusted", but an ATM switch terminating VCs switched + through a DSLAM may consider such VCs as "trusted" and accept a relay + agent option added by the DSLAM. + + Relay agents MAY have a configurable for the maximum size of the DHCP + packet to be created after appending the Agent Information option. + Packets which, after appending the Relay Agent Information option, + would exceed this configured maximum size shall be forwarded WITHOUT + adding the Agent Information option. An error counter SHOULD be + incremented in this case. In the absence of this configurable, the + agent SHALL NOT increase a forwarded DHCP packet size to exceed the + MTU of the interface on which it is forwarded. + + The Relay Agent Information option echoed by a server MUST be removed + by either the relay agent or the trusted downstream network element + which added it when forwarding a server-to-client response back to + the client. + + + + + + + +Patrick Standards Track [Page 6] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + + The agent SHALL NOT add an "Option Overload" option to the packet or + use the "file" or "sname" fields for adding Relay Agent Information + option. It SHALL NOT parse or remove Relay Agent Information options + that may appear in the sname or file fields of a server-to-client + packet forwarded through the agent. + + The operation of relay agents for specific sub-options is specified + with that sub-option. + + Relay agents are NOT required to monitor or modify client-originated + DHCP packets addressed to a server unicast address. This includes + the DHCP-REQUEST sent when entering the RENEWING state. + + Relay agents MUST NOT modify DHCP packets that use the IPSEC + Authentication Header or IPSEC Encapsulating Security Payload [6]. + +2.1.1 Reforwarded DHCP requests + + A DHCP relay agent may receive a client DHCP packet forwarded from a + BOOTP/DHCP relay agent closer to the client. Such a packet will have + giaddr as non-zero, and may or may not already have a DHCP Relay + Agent option in it. + + Relay agents configured to add a Relay Agent option which receive a + client DHCP packet with a nonzero giaddr SHALL discard the packet if + the giaddr spoofs a giaddr address implemented by the local agent + itself. + + Otherwise, the relay agent SHALL forward any received DHCP packet + with a valid non-zero giaddr WITHOUT adding any relay agent options. + Per RFC 2131, it shall also NOT modify the giaddr value. + +2.2 Server Operation + + DHCP servers unaware of the Relay Agent Information option will + ignore the option upon receive and will not echo it back on + responses. This is the specified server behavior for unknown + options. + + DHCP servers claiming to support the Relay Agent Information option + SHALL echo the entire contents of the Relay Agent Information option + in all replies. Servers SHOULD copy the Relay Agent Information + option as the last DHCP option in the response. Servers SHALL NOT + place the echoed Relay Agent Information option in the overloaded + sname or file fields. If a server is unable to copy a full Relay + Agent Information field into a response, it SHALL send the response + without the Relay Information Field, and SHOULD increment an error + counter for the situation. + + + +Patrick Standards Track [Page 7] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + + The operation of DHCP servers for specific sub-options is specified + with that sub-option. + + Note that DHCP relay agents are not required to monitor unicast DHCP + messages sent directly between the client and server (i.e., those + that aren't sent via a relay agent). However, some relay agents MAY + chose to do such monitoring and add relay agent options. + Consequently, servers SHOULD be prepared to handle relay agent + options in unicast messages, but MUST NOT expect them to always be + there. + +3.0 Relay Agent Information Sub-options + +3.1 Agent Circuit ID Sub-option + + This sub-option MAY be added by DHCP relay agents which terminate + switched or permanent circuits. It encodes an agent-local identifier + of the circuit from which a DHCP client-to-server packet was + received. It is intended for use by agents in relaying DHCP + responses back to the proper circuit. Possible uses of this field + include: + + - Router interface number + - Switching Hub port number + - Remote Access Server port number + - Frame Relay DLCI + - ATM virtual circuit number + - Cable Data virtual circuit number + + Servers MAY use the Circuit ID for IP and other parameter assignment + policies. The Circuit ID SHOULD be considered an opaque value, with + policies based on exact string match only; that is, the Circuit ID + SHOULD NOT be internally parsed by the server. + + The DHCP server SHOULD report the Agent Circuit ID value of current + leases in statistical reports (including its MIB) and in logs. Since + the Circuit ID is local only to a particular relay agent, a circuit + ID should be qualified with the giaddr value that identifies the + relay agent. + + SubOpt Len Circuit ID + +------+------+------+------+------+------+------+------+-- + | 1 | n | c1 | c2 | c3 | c4 | c5 | c6 | ... + +------+------+------+------+------+------+------+------+-- + + + + + + + +Patrick Standards Track [Page 8] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + +3.2 Agent Remote ID Sub-option + + This sub-option MAY be added by DHCP relay agents which terminate + switched or permanent circuits and have mechanisms to identify the + remote host end of the circuit. The Remote ID field may be used to + encode, for instance: + + -- a "caller ID" telephone number for dial-up connection + -- a "user name" prompted for by a Remote Access Server + -- a remote caller ATM address + -- a "modem ID" of a cable data modem + -- the remote IP address of a point-to-point link + -- a remote X.25 address for X.25 connections + + The remote ID MUST be globally unique. + + DHCP servers MAY use this option to select parameters specific to + particular users, hosts, or subscriber modems. The option SHOULD be + considered an opaque value, with policies based on exact string match + only; that is, the option SHOULD NOT be internally parsed by the + server. + + The relay agent MAY use this field in addition to or instead of the + Agent Circuit ID field to select the circuit on which to forward the + DHCP reply (e.g., Offer, Ack, or Nak). DHCP servers SHOULD report + this value in any reports or MIBs associated with a particular + client. + + SubOpt Len Agent Remote ID + +------+------+------+------+------+------+------+------+-- + | 2 | n | r1 | r2 | r3 | r4 | r5 | r6 | ... + +------+------+------+------+------+------+------+------+-- + +4.0 Issues Resolved + + The DHCP relay agent option resolves several issues in an environment + in which untrusted hosts access the internet via a circuit based + public network. This resolution assumes that all DHCP protocol + traffic by the public hosts traverse the DHCP relay agent and that + the IP network between the DHCP relay agent and the DHCP server is + uncompromised. + + Broadcast Forwarding + + The circuit access equipment forwards the normally broadcasted + DHCP response only on the circuit indicated in the Agent Circuit + ID. + + + + +Patrick Standards Track [Page 9] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + + DHCP Address Exhaustion + + In general, the DHCP server may be extended to maintain a database + with the "triplet" of + + (client IP address, client MAC address, client remote ID) + + The DHCP server SHOULD implement policies that restrict the number + of IP addresses to be assigned to a single remote ID. + + Static Assignment + + The DHCP server may use the remote ID to select the IP address to + be assigned. It may permit static assignment of IP addresses to + particular remote IDs, and disallow an address request from an + unauthorized remote ID. + + IP Spoofing + + The circuit access device may associate the IP address assigned by + a DHCP server in a forwarded DHCP Ack packet with the circuit to + which it was forwarded. The circuit access device MAY prevent + forwarding of IP packets with source IP addresses -other than- + those it has associated with the receiving circuit. This prevents + simple IP spoofing attacks on the Central LAN, and IP spoofing of + other hosts. + + Client Identifier Spoofing + + By using the agent-supplied Agent Remote ID option, the untrusted + and as-yet unstandardized client identifier field need not be used + by the DHCP server. + + MAC Address Spoofing + + By associating a MAC address with an Agent Remote ID, the DHCP + server can prevent offering an IP address to an attacker spoofing + the same MAC address on a different remote ID. + +5.0 Security Considerations + + DHCP as currently defined provides no authentication or security + mechanisms. Potential exposures to attack are discussed in section 7 + of the DHCP protocol specification in RFC 2131 [1]. + + This document introduces mechanisms to address several security + attacks on the operation of IP address assignment, including IP + spoofing, Client ID spoofing, MAC address spoofing, and DHCP server + + + +Patrick Standards Track [Page 10] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + + address exhaustion. It relies on an implied trusted relationship + between the DHCP Relay Agent and the DHCP server, with an assumed + untrusted DHCP client. It introduces a new identifer, the "Remote + ID", that is also assumed to be trusted. The Remote ID is provided + by the access network or modem and not by client premise equipment. + Cryptographic or other techniques to authenticate the remote ID are + certainly possible and encouraged, but are beyond the scope of this + document. + + This option is targeted towards environments in which the network + infrastructure -- the relay agent, the DHCP server, and the entire + network in which those two devices reside -- is trusted and secure. + As used in this document, the word "trusted" implies that + unauthorized DHCP traffic cannot enter the trusted network except + through secured and trusted relay agents and that all devices + internal to the network are secure and trusted. Potential deployers + of this option should give careful consideration to the potential + security vulnerabilities that are present in this model before + deploying this option in actual networks. + + Note that any future mechanisms for authenticating DHCP client to + server communications must take care to omit the DHCP Relay Agent + option from server authentication calculations. This was the + principal reason for organizing the DHCP Relay Agent Option as a + single option with sub-options, and for requiring the relay agent to + remove the option before forwarding to the client. + + While it is beyond the scope of this document to specify the general + forwarding algorithm of public data circuit access units, note that + automatic reforwarding of IP or ARP broadcast packets back downstream + exposes serious IP security risks. For example, if an upstream + broadcast DHCP-DISCOVER or DHCP-REQUEST were re-broadcast back + downstream, any public host may easily spoof the desired DHCP server. + +6.0 IANA Considerations + + IANA is required to maintain a new number space of "DHCP Relay Agent + Sub-options", located in the BOOTP-DHCP Parameters Registry. The + initial sub-options are described in section 2.0 of this document. + + IANA assigns future DHCP Relay Agent Sub-options with a "IETF + Consensus" policy as described in RFC 2434 [3]. Future proposed + sub-options are to be referenced symbolically in the Internet-Drafts + that describe them, and shall be assigned numeric codes by IANA when + approved for publication as an RFC. + + + + + + +Patrick Standards Track [Page 11] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + +7.0 Intellectual Property Notices + + This section contains two notices as required by [5] for standards + track documents. + + The IETF takes no position regarding the validity or scope of any + intellectual property or other rights that might be claimed to + pertain to the implementation or use of the technology described in + this document or the extent to which any license under such rights + might or might not be available; neither does it represent that it + has made any effort to identify any such rights. Information on the + IETF's procedures with respect to rights in standards-track and + standards-related documentation can be found in BCP-11. Copies of + claims of rights made available for publication and any assurances of + licenses to be made available, or the result of an attempt made to + obtain a general license or permission for the use of such + proprietary rights by implementors or users of this specification can + be obtained from the IETF Secretariat. + + The IETF has been notified of intellectual property rights claimed in + regard to some or all of the specification contained in this + document. For more information consult the online list of claimed + rights. + +8.0 References + + [1] Droms, R., "Dynamic Host Configuration Protocol", RFC 2131, + March 1997. + + [2] Alexander, S. and R. Droms, "DHCP Options and BOOTP Vendor + Extension", RFC 2132, March 1997. + + [3] Narten, T. and H. Alvestrand, "Guidelines for Writing an IANA + Considerations Section in RFCs", BCP 26, RFC 2434, October 1998. + + [4] Bradner, S., "Key words for use in RFCs to Indicate Requirement + Levels", BCP 14, RFC 2119, March 1997. + + [5] Bradner, S., "The Internet Standards Process -- Revision 3", BCP + 9, RFC 2026, October 1996. + + [6] Kent, S. and R. Atkinson, "Security Architecture for the + Internet Protocol", RFC 2401, November 1998. + + + + + + + + +Patrick Standards Track [Page 12] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + +9.0 Glossary + + DSLAM Digital Subscriber Link Access Multiplexer + IANA Internet Assigned Numbers Authority + LIS Logical IP Subnet + MAC Message Authentication Code + RAS Remote Access Server + +10.0 Author's Address + + Michael Patrick + Motorola Broadband Communications Sector + 20 Cabot Blvd., MS M4-30 + Mansfield, MA 02048 + + Phone: (508) 261-5707 + EMail: michael.patrick@motorola.com + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Patrick Standards Track [Page 13] + +RFC 3046 DHCP Relay Agent Information Option January 2001 + + +11.0 Full Copyright Statement + + Copyright (C) The Internet Society (2001). All Rights Reserved. + + This document and translations of it may be copied and furnished to + others, and derivative works that comment on or otherwise explain it + or assist in its implementation may be prepared, copied, published + and distributed, in whole or in part, without restriction of any + kind, provided that the above copyright notice and this paragraph are + included on all such copies and derivative works. However, this + document itself may not be modified in any way, such as by removing + the copyright notice or references to the Internet Society or other + Internet organizations, except as needed for the purpose of + developing Internet standards in which case the procedures for + copyrights defined in the Internet Standards process must be + followed, or as required to translate it into languages other than + English. + + The limited permissions granted above are perpetual and will not be + revoked by the Internet Society or its successors or assigns. + + This document and the information contained herein is provided on an + "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING + TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING + BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION + HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF + MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. + +Acknowledgement + + Funding for the RFC Editor function is currently provided by the + Internet Society. + + + + + + + + + + + + + + + + + + + +Patrick Standards Track [Page 14] + |