/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "states.h" #include "interface.h" #include "agent.h" #include "packet.h" #include "util.h" #include "dlpi_io.h" int v6_sock_fd = -1; int v4_sock_fd = -1; const in6_addr_t ipv6_all_dhcp_relay_and_servers = { 0xff, 0x02, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01, 0x00, 0x02 }; /* * We have our own version of this constant because dhcpagent is compiled with * -lxnet. */ const in6_addr_t my_in6addr_any = IN6ADDR_ANY_INIT; static void retransmit(iu_tq_t *, void *); static void next_retransmission(dhcp_smach_t *, boolean_t, boolean_t); static boolean_t send_pkt_internal(dhcp_smach_t *); /* * pkt_send_type(): returns an integer representing the packet's type; only * for use with outbound packets. * * input: dhcp_pkt_t *: the packet to examine * output: uchar_t: the packet type (0 if unknown) */ static uchar_t pkt_send_type(const dhcp_pkt_t *dpkt) { const uchar_t *option; if (dpkt->pkt_isv6) return (((const dhcpv6_message_t *)dpkt->pkt)->d6m_msg_type); /* * this is a little dirty but it should get the job done. * assumes that the type is in the statically allocated part * of the options field. */ option = dpkt->pkt->options; for (;;) { if (*option == CD_PAD) { option++; continue; } if (*option == CD_END || option + 2 - dpkt->pkt->options >= sizeof (dpkt->pkt->options)) return (0); if (*option == CD_DHCP_TYPE) break; option++; option += *option + 1; } return (option[2]); } /* * pkt_recv_type(): returns an integer representing the packet's type; only * for use with inbound packets. * * input: dhcp_pkt_t *: the packet to examine * output: uchar_t: the packet type (0 if unknown) */ uchar_t pkt_recv_type(const PKT_LIST *plp) { if (plp->isv6) return (((const dhcpv6_message_t *)plp->pkt)->d6m_msg_type); else if (plp->opts[CD_DHCP_TYPE] != NULL) return (plp->opts[CD_DHCP_TYPE]->value[0]); else return (0); } /* * pkt_get_xid(): returns transaction ID from a DHCP packet. * * input: const PKT *: the packet to examine * output: uint_t: the transaction ID (0 if unknown) */ uint_t pkt_get_xid(const PKT *pkt, boolean_t isv6) { if (pkt == NULL) return (0); if (isv6) return (DHCPV6_GET_TRANSID((const dhcpv6_message_t *)pkt)); else return (pkt->xid); } /* * init_pkt(): initializes and returns a packet of a given type * * input: dhcp_smach_t *: the state machine that will send the packet * uchar_t: the packet type (DHCP message type) * output: dhcp_pkt_t *: a pointer to the initialized packet; may be NULL */ dhcp_pkt_t * init_pkt(dhcp_smach_t *dsmp, uchar_t type) { uint_t mtu; dhcp_pkt_t *dpkt = &dsmp->dsm_send_pkt; dhcp_lif_t *lif = dsmp->dsm_lif; dhcp_pif_t *pif = lif->lif_pif; uint32_t xid; boolean_t isv6; mtu = dsmp->dsm_using_dlpi ? pif->pif_max : lif->lif_max; dpkt->pkt_isv6 = isv6 = pif->pif_isv6; /* * since multiple dhcp leases may be maintained over the same dlpi * device (e.g. "hme0" and "hme0:1"), make sure the xid is unique. * * Note that transaction ID zero is intentionally never assigned. * That's used to represent "no ID." Also note that transaction IDs * are only 24 bits long in DHCPv6. */ do { xid = mrand48(); if (isv6) xid &= 0xFFFFFF; } while (xid == 0 || lookup_smach_by_xid(xid, NULL, dpkt->pkt_isv6) != NULL); if (isv6) { dhcpv6_message_t *v6; if (mtu != dpkt->pkt_max_len && (v6 = realloc(dpkt->pkt, mtu)) != NULL) { /* LINTED: alignment known to be correct */ dpkt->pkt = (PKT *)v6; dpkt->pkt_max_len = mtu; } if (sizeof (*v6) > dpkt->pkt_max_len) { dhcpmsg(MSG_ERR, "init_pkt: cannot allocate v6 pkt: %u", mtu); return (NULL); } v6 = (dhcpv6_message_t *)dpkt->pkt; dpkt->pkt_cur_len = sizeof (*v6); (void) memset(v6, 0, dpkt->pkt_max_len); v6->d6m_msg_type = type; DHCPV6_SET_TRANSID(v6, xid); if (dsmp->dsm_cidlen > 0 && add_pkt_opt(dpkt, DHCPV6_OPT_CLIENTID, dsmp->dsm_cid, dsmp->dsm_cidlen) == NULL) { dhcpmsg(MSG_WARNING, "init_pkt: cannot insert client ID"); return (NULL); } /* For v6, time starts with the creation of a transaction */ dsmp->dsm_neg_hrtime = gethrtime(); dsmp->dsm_newstart_monosec = monosec(); } else { static uint8_t bootmagic[] = BOOTMAGIC; PKT *v4; if (mtu != dpkt->pkt_max_len && (v4 = realloc(dpkt->pkt, mtu)) != NULL) { dpkt->pkt = v4; dpkt->pkt_max_len = mtu; } if (offsetof(PKT, options) > dpkt->pkt_max_len) { dhcpmsg(MSG_ERR, "init_pkt: cannot allocate v4 pkt: %u", mtu); return (NULL); } v4 = dpkt->pkt; dpkt->pkt_cur_len = offsetof(PKT, options); (void) memset(v4, 0, dpkt->pkt_max_len); (void) memcpy(v4->cookie, bootmagic, sizeof (bootmagic)); if (pif->pif_hwlen <= sizeof (v4->chaddr)) { v4->hlen = pif->pif_hwlen; (void) memcpy(v4->chaddr, pif->pif_hwaddr, pif->pif_hwlen); } else { /* * The mac address does not fit in the chaddr * field, thus it can not be sent to the server, * thus server can not unicast the reply. Per * RFC 2131 4.4.1, client can set this bit in * DISCOVER/REQUEST. If the client is already * in BOUND/REBINDING/RENEWING state, do not set * this bit, as it can respond to unicast responses * from server using the 'ciaddr' address. */ if (type == DISCOVER || (type == REQUEST && dsmp->dsm_state != RENEWING && dsmp->dsm_state != REBINDING && dsmp->dsm_state != BOUND)) v4->flags = htons(BCAST_MASK); } v4->xid = xid; v4->op = BOOTREQUEST; v4->htype = pif->pif_hwtype; if (add_pkt_opt(dpkt, CD_DHCP_TYPE, &type, 1) == NULL) { dhcpmsg(MSG_WARNING, "init_pkt: cannot set DHCP packet type"); return (NULL); } if (dsmp->dsm_cidlen > 0 && add_pkt_opt(dpkt, CD_CLIENT_ID, dsmp->dsm_cid, dsmp->dsm_cidlen) == NULL) { dhcpmsg(MSG_WARNING, "init_pkt: cannot insert client ID"); return (NULL); } } return (dpkt); } /* * remove_pkt_opt(): removes the first instance of an option from a dhcp_pkt_t * * input: dhcp_pkt_t *: the packet to remove the option from * uint_t: the type of option being added * output: boolean_t: B_TRUE on success, B_FALSE on failure * note: currently does not work with DHCPv6 suboptions, or to remove * arbitrary option instances. */ boolean_t remove_pkt_opt(dhcp_pkt_t *dpkt, uint_t opt_type) { uchar_t *raw_pkt, *raw_end, *next; uint_t len; raw_pkt = (uchar_t *)dpkt->pkt; raw_end = raw_pkt + dpkt->pkt_cur_len; if (dpkt->pkt_isv6) { dhcpv6_option_t d6o; raw_pkt += sizeof (dhcpv6_message_t); opt_type = htons(opt_type); while (raw_pkt + sizeof (d6o) <= raw_end) { (void) memcpy(&d6o, raw_pkt, sizeof (d6o)); len = ntohs(d6o.d6o_len) + sizeof (d6o); if (len > raw_end - raw_pkt) break; next = raw_pkt + len; if (d6o.d6o_code == opt_type) { if (next < raw_end) { (void) memmove(raw_pkt, next, raw_end - next); } dpkt->pkt_cur_len -= len; return (B_TRUE); } raw_pkt = next; } } else { uchar_t *pstart, *padrun; raw_pkt += offsetof(PKT, options); pstart = raw_pkt; if (opt_type == CD_END || opt_type == CD_PAD) return (B_FALSE); padrun = NULL; while (raw_pkt + 1 <= raw_end) { if (*raw_pkt == CD_END) break; if (*raw_pkt == CD_PAD) { if (padrun == NULL) padrun = raw_pkt; raw_pkt++; continue; } if (raw_pkt + 2 > raw_end) break; len = raw_pkt[1]; if (len > raw_end - raw_pkt || len < 2) break; next = raw_pkt + len; if (*raw_pkt == opt_type) { if (next < raw_end) { int toadd = (4 + ((next-pstart)&3) - ((raw_pkt-pstart)&3)) & 3; int torem = 4 - toadd; if (torem != 4 && padrun != NULL && (raw_pkt - padrun) >= torem) { raw_pkt -= torem; dpkt->pkt_cur_len -= torem; } else if (toadd > 0) { (void) memset(raw_pkt, CD_PAD, toadd); raw_pkt += toadd; /* max is not an issue here */ dpkt->pkt_cur_len += toadd; } if (raw_pkt != next) { (void) memmove(raw_pkt, next, raw_end - next); } } dpkt->pkt_cur_len -= len; return (B_TRUE); } padrun = NULL; raw_pkt = next; } } return (B_FALSE); } /* * update_v6opt_len(): updates the length field of a DHCPv6 option. * * input: dhcpv6_option_t *: option to be updated * int: number of octets to add or subtract * output: boolean_t: B_TRUE on success, B_FALSE on failure */ boolean_t update_v6opt_len(dhcpv6_option_t *opt, int adjust) { dhcpv6_option_t optval; (void) memcpy(&optval, opt, sizeof (optval)); adjust += ntohs(optval.d6o_len); if (adjust < 0 || adjust > UINT16_MAX) { return (B_FALSE); } else { optval.d6o_len = htons(adjust); (void) memcpy(opt, &optval, sizeof (optval)); return (B_TRUE); } } /* * add_pkt_opt(): adds an option to a dhcp_pkt_t * * input: dhcp_pkt_t *: the packet to add the option to * uint_t: the type of option being added * const void *: the value of that option * uint_t: the length of the value of the option * output: void *: pointer to the option that was added, or NULL on failure. */ void * add_pkt_opt(dhcp_pkt_t *dpkt, uint_t opt_type, const void *opt_val, uint_t opt_len) { uchar_t *raw_pkt; int req_len; void *optr; raw_pkt = (uchar_t *)dpkt->pkt; optr = raw_pkt + dpkt->pkt_cur_len; if (dpkt->pkt_isv6) { dhcpv6_option_t d6o; req_len = opt_len + sizeof (d6o); if (dpkt->pkt_cur_len + req_len > dpkt->pkt_max_len) { dhcpmsg(MSG_WARNING, "add_pkt_opt: not enough room for v6 option %u in " "packet (%u + %u > %u)", opt_type, dpkt->pkt_cur_len, req_len, dpkt->pkt_max_len); return (NULL); } d6o.d6o_code = htons(opt_type); d6o.d6o_len = htons(opt_len); (void) memcpy(&raw_pkt[dpkt->pkt_cur_len], &d6o, sizeof (d6o)); dpkt->pkt_cur_len += sizeof (d6o); if (opt_len > 0) { (void) memcpy(&raw_pkt[dpkt->pkt_cur_len], opt_val, opt_len); dpkt->pkt_cur_len += opt_len; } } else { req_len = opt_len + 2; /* + 2 for code & length bytes */ /* CD_END and CD_PAD options don't have a length field */ if (opt_type == CD_END || opt_type == CD_PAD) { req_len = 1; } else if (opt_val == NULL) { dhcpmsg(MSG_ERROR, "add_pkt_opt: option type %d is " "missing required value", opt_type); return (NULL); } if ((dpkt->pkt_cur_len + req_len) > dpkt->pkt_max_len) { dhcpmsg(MSG_WARNING, "add_pkt_opt: not enough room for v4 option %u in " "packet", opt_type); return (NULL); } raw_pkt[dpkt->pkt_cur_len++] = opt_type; if (req_len > 1) { raw_pkt[dpkt->pkt_cur_len++] = opt_len; if (opt_len > 0) { (void) memcpy(&raw_pkt[dpkt->pkt_cur_len], opt_val, opt_len); dpkt->pkt_cur_len += opt_len; } } } return (optr); } /* * add_pkt_subopt(): adds an option to a dhcp_pkt_t option. DHCPv6-specific, * but could be extended to IPv4 DHCP if necessary. Assumes * that if the parent isn't a top-level option, the caller * will adjust any upper-level options recursively using * update_v6opt_len. * * input: dhcp_pkt_t *: the packet to add the suboption to * dhcpv6_option_t *: the start of the option to that should contain * it (parent) * uint_t: the type of suboption being added * const void *: the value of that option * uint_t: the length of the value of the option * output: void *: pointer to the suboption that was added, or NULL on * failure. */ void * add_pkt_subopt(dhcp_pkt_t *dpkt, dhcpv6_option_t *parentopt, uint_t opt_type, const void *opt_val, uint_t opt_len) { uchar_t *raw_pkt; int req_len; void *optr; dhcpv6_option_t d6o; uchar_t *optend; int olen; if (!dpkt->pkt_isv6) return (NULL); raw_pkt = (uchar_t *)dpkt->pkt; req_len = opt_len + sizeof (d6o); if (dpkt->pkt_cur_len + req_len > dpkt->pkt_max_len) { dhcpmsg(MSG_WARNING, "add_pkt_subopt: not enough room for v6 suboption %u in " "packet (%u + %u > %u)", opt_type, dpkt->pkt_cur_len, req_len, dpkt->pkt_max_len); return (NULL); } /* * Update the parent option to include room for this option, * and compute the insertion point. */ (void) memcpy(&d6o, parentopt, sizeof (d6o)); olen = ntohs(d6o.d6o_len); optend = (uchar_t *)(parentopt + 1) + olen; olen += req_len; d6o.d6o_len = htons(olen); (void) memcpy(parentopt, &d6o, sizeof (d6o)); /* * If there's anything at the end to move, then move it. Also bump up * the packet size. */ if (optend < raw_pkt + dpkt->pkt_cur_len) { (void) memmove(optend + req_len, optend, (raw_pkt + dpkt->pkt_cur_len) - optend); } dpkt->pkt_cur_len += req_len; /* * Now format the suboption and add it in. */ optr = optend; d6o.d6o_code = htons(opt_type); d6o.d6o_len = htons(opt_len); (void) memcpy(optend, &d6o, sizeof (d6o)); if (opt_len > 0) (void) memcpy(optend + sizeof (d6o), opt_val, opt_len); return (optr); } /* * add_pkt_opt16(): adds an option with a 16-bit value to a dhcp_pkt_t * * input: dhcp_pkt_t *: the packet to add the option to * uint_t: the type of option being added * uint16_t: the value of that option * output: void *: pointer to the option that was added, or NULL on failure. */ void * add_pkt_opt16(dhcp_pkt_t *dpkt, uint_t opt_type, uint16_t opt_value) { return (add_pkt_opt(dpkt, opt_type, &opt_value, 2)); } /* * add_pkt_opt32(): adds an option with a 32-bit value to a dhcp_pkt_t * * input: dhcp_pkt_t *: the packet to add the option to * uint_t: the type of option being added * uint32_t: the value of that option * output: void *: pointer to the option that was added, or NULL on failure. */ void * add_pkt_opt32(dhcp_pkt_t *dpkt, uint_t opt_type, uint32_t opt_value) { return (add_pkt_opt(dpkt, opt_type, &opt_value, 4)); } /* * add_pkt_prl(): adds the parameter request option to the packet * * input: dhcp_pkt_t *: the packet to add the option to * dhcp_smach_t *: state machine with request option * output: void *: pointer to the option that was added, or NULL on failure. */ void * add_pkt_prl(dhcp_pkt_t *dpkt, dhcp_smach_t *dsmp) { uint_t len; if (dsmp->dsm_prllen == 0) return (0); if (dpkt->pkt_isv6) { uint16_t *prl; /* * RFC 3315 requires that we include the option, even if we * have nothing to request. */ if (dsmp->dsm_prllen == 0) prl = NULL; else prl = alloca(dsmp->dsm_prllen * sizeof (uint16_t)); for (len = 0; len < dsmp->dsm_prllen; len++) prl[len] = htons(dsmp->dsm_prl[len]); return (add_pkt_opt(dpkt, DHCPV6_OPT_ORO, prl, len * sizeof (uint16_t))); } else { uint8_t *prl = alloca(dsmp->dsm_prllen); for (len = 0; len < dsmp->dsm_prllen; len++) prl[len] = dsmp->dsm_prl[len]; return (add_pkt_opt(dpkt, CD_REQUEST_LIST, prl, len)); } } /* * add_pkt_lif(): Adds CD_REQUESTED_IP_ADDR (IPv4 DHCP) or IA_NA and IAADDR * (DHCPv6) options to the packet to represent the given LIF. * * input: dhcp_pkt_t *: the packet to add the options to * dhcp_lif_t *: the logical interface to represent * int: status code (unused for IPv4 DHCP) * const char *: message to include with status option, or NULL * output: boolean_t: B_TRUE on success, B_FALSE on failure */ boolean_t add_pkt_lif(dhcp_pkt_t *dpkt, dhcp_lif_t *lif, int status, const char *msg) { if (lif->lif_pif->pif_isv6) { dhcp_smach_t *dsmp; dhcpv6_message_t *d6m; dhcpv6_ia_na_t d6in; dhcpv6_iaaddr_t d6ia; uint32_t iaid; uint16_t *statusopt; dhcpv6_option_t *d6o, *d6so; uint_t olen; /* * Currently, we support just one IAID related to the primary * LIF on the state machine. */ dsmp = lif->lif_lease->dl_smach; iaid = dsmp->dsm_lif->lif_iaid; iaid = htonl(iaid); d6m = (dhcpv6_message_t *)dpkt->pkt; /* * Find or create the IA_NA needed for this LIF. If we * supported IA_TA, we'd check the IFF_TEMPORARY bit here. */ d6o = NULL; while ((d6o = dhcpv6_find_option(d6m + 1, dpkt->pkt_cur_len - sizeof (*d6m), d6o, DHCPV6_OPT_IA_NA, &olen)) != NULL) { if (olen < sizeof (d6in)) continue; (void) memcpy(&d6in, d6o, sizeof (d6in)); if (d6in.d6in_iaid == iaid) break; } if (d6o == NULL) { d6in.d6in_iaid = iaid; d6in.d6in_t1 = 0; d6in.d6in_t2 = 0; d6o = add_pkt_opt(dpkt, DHCPV6_OPT_IA_NA, (dhcpv6_option_t *)&d6in + 1, sizeof (d6in) - sizeof (*d6o)); if (d6o == NULL) return (B_FALSE); } /* * Now add the IAADDR suboption for this LIF. No need to * search here, as we know that this is unique. */ d6ia.d6ia_addr = lif->lif_v6addr; /* * For Release and Decline, we zero out the lifetime. For * Renew and Rebind, we report the original time as the * preferred and valid lifetimes. */ if (d6m->d6m_msg_type == DHCPV6_MSG_RELEASE || d6m->d6m_msg_type == DHCPV6_MSG_DECLINE) { d6ia.d6ia_preflife = 0; d6ia.d6ia_vallife = 0; } else { d6ia.d6ia_preflife = htonl(lif->lif_preferred.dt_start); d6ia.d6ia_vallife = htonl(lif->lif_expire.dt_start); } d6so = add_pkt_subopt(dpkt, d6o, DHCPV6_OPT_IAADDR, (dhcpv6_option_t *)&d6ia + 1, sizeof (d6ia) - sizeof (*d6o)); if (d6so == NULL) return (B_FALSE); /* * Add a status code suboption to the IAADDR to tell the server * why we're declining the address. Note that we must manually * update the enclosing IA_NA, as add_pkt_subopt doesn't know * how to do that. */ if (status != DHCPV6_STAT_SUCCESS || msg != NULL) { olen = sizeof (*statusopt) + (msg == NULL ? 0 : strlen(msg)); statusopt = alloca(olen); *statusopt = htons(status); if (msg != NULL) { (void) memcpy((char *)(statusopt + 1), msg, olen - sizeof (*statusopt)); } d6so = add_pkt_subopt(dpkt, d6so, DHCPV6_OPT_STATUS_CODE, statusopt, olen); if (d6so != NULL) { /* * Update for length of suboption header and * suboption contents. */ (void) update_v6opt_len(d6o, sizeof (*d6so) + olen); } } } else { /* * For DECLINE, we need to add the CD_REQUESTED_IP_ADDR option. * In all other cases (RELEASE and REQUEST), we need to set * ciadr. */ if (pkt_send_type(dpkt) == DECLINE) { if (!add_pkt_opt32(dpkt, CD_REQUESTED_IP_ADDR, lif->lif_addr)) return (B_FALSE); } else { dpkt->pkt->ciaddr.s_addr = lif->lif_addr; } /* * It's not too worrisome if the message fails to fit in the * packet. The result will still be valid. */ if (msg != NULL) (void) add_pkt_opt(dpkt, CD_MESSAGE, msg, strlen(msg) + 1); } return (B_TRUE); } /* * free_pkt_entry(): frees a packet list list entry * * input: PKT_LIST *: the packet list entry to free * output: void */ void free_pkt_entry(PKT_LIST *plp) { if (plp != NULL) { free(plp->pkt); free(plp); } } /* * free_pkt_list(): frees an entire packet list * * input: PKT_LIST **: the packet list to free * output: void */ void free_pkt_list(PKT_LIST **head) { PKT_LIST *plp; while ((plp = *head) != NULL) { remque(plp); free_pkt_entry(plp); } } /* * send_pkt_internal(): sends a packet out on an interface * * input: dhcp_smach_t *: the state machine with a packet to send * output: boolean_t: B_TRUE if the packet is sent, B_FALSE otherwise */ static boolean_t send_pkt_internal(dhcp_smach_t *dsmp) { ssize_t n_bytes; dhcp_lif_t *lif = dsmp->dsm_lif; dhcp_pif_t *pif = lif->lif_pif; dhcp_pkt_t *dpkt = &dsmp->dsm_send_pkt; uchar_t ptype = pkt_send_type(dpkt); const char *pkt_name; struct iovec iov; struct msghdr msg; struct cmsghdr *cmsg; struct in6_pktinfo *ipi6; boolean_t ismcast; /* * Timer should not be running at the point we go to send a packet. */ if (dsmp->dsm_retrans_timer != -1) { dhcpmsg(MSG_CRIT, "send_pkt_internal: unexpected retransmit " "timer on %s", dsmp->dsm_name); stop_pkt_retransmission(dsmp); } pkt_name = pkt_type_to_string(ptype, dpkt->pkt_isv6); /* * if needed, schedule a retransmission timer, then attempt to * send the packet. if we fail, then log the error. our * return value should indicate whether or not we were * successful in sending the request, independent of whether * we could schedule a timer. */ if (dsmp->dsm_send_timeout != 0) { if ((dsmp->dsm_retrans_timer = iu_schedule_timer_ms(tq, dsmp->dsm_send_timeout, retransmit, dsmp)) == -1) dhcpmsg(MSG_WARNING, "send_pkt_internal: cannot " "schedule retransmit timer for %s packet", pkt_name); else hold_smach(dsmp); } if (dpkt->pkt_isv6) { hrtime_t delta; /* * Convert current time into centiseconds since transaction * started. This is what DHCPv6 expects to see in the Elapsed * Time option. */ delta = (gethrtime() - dsmp->dsm_neg_hrtime) / (NANOSEC / 100); if (delta > DHCPV6_FOREVER) delta = DHCPV6_FOREVER; (void) remove_pkt_opt(dpkt, DHCPV6_OPT_ELAPSED_TIME); (void) add_pkt_opt16(dpkt, DHCPV6_OPT_ELAPSED_TIME, htons(delta)); } else { /* * set the `pkt->secs' field depending on the type of packet. * it should be zero, except in the following cases: * * DISCOVER: set to the number of seconds since we started * trying to obtain a lease. * * INFORM: set to the number of seconds since we started * trying to get configuration parameters. * * REQUEST: if in the REQUESTING state, then same value as * DISCOVER, otherwise the number of seconds * since we started trying to obtain a lease. * * we also set `dsm_newstart_monosec', to the time we sent a * REQUEST or DISCOVER packet, so we know the lease start * time (the DISCOVER case is for handling BOOTP servers). */ switch (ptype) { case DISCOVER: dsmp->dsm_newstart_monosec = monosec(); dsmp->dsm_disc_secs = dsmp->dsm_newstart_monosec - hrtime_to_monosec(dsmp->dsm_neg_hrtime); dpkt->pkt->secs = htons(dsmp->dsm_disc_secs); break; case INFORM: dpkt->pkt->secs = htons(monosec() - hrtime_to_monosec(dsmp->dsm_neg_hrtime)); break; case REQUEST: dsmp->dsm_newstart_monosec = monosec(); if (dsmp->dsm_state == REQUESTING) { dpkt->pkt->secs = htons(dsmp->dsm_disc_secs); break; } dpkt->pkt->secs = htons(monosec() - hrtime_to_monosec(dsmp->dsm_neg_hrtime)); break; default: dpkt->pkt->secs = htons(0); break; } } if (dpkt->pkt_isv6) { struct sockaddr_in6 sin6; (void) memset(&iov, 0, sizeof (iov)); iov.iov_base = dpkt->pkt; iov.iov_len = dpkt->pkt_cur_len; (void) memset(&msg, 0, sizeof (msg)); msg.msg_name = &dsmp->dsm_send_dest.v6; msg.msg_namelen = sizeof (struct sockaddr_in6); msg.msg_iov = &iov; msg.msg_iovlen = 1; /* * If the address that's requested cannot be reached, then fall * back to the multcast address. */ if (IN6_IS_ADDR_MULTICAST(&dsmp->dsm_send_dest.v6.sin6_addr)) { ismcast = B_TRUE; } else { struct dstinforeq dinfo; struct strioctl str; ismcast = B_FALSE; (void) memset(&dinfo, 0, sizeof (dinfo)); dinfo.dir_daddr = dsmp->dsm_send_dest.v6.sin6_addr; str.ic_cmd = SIOCGDSTINFO; str.ic_timout = 0; str.ic_len = sizeof (dinfo); str.ic_dp = (char *)&dinfo; if (ioctl(v6_sock_fd, I_STR, &str) == -1) { dhcpmsg(MSG_ERR, "send_pkt_internal: ioctl SIOCGDSTINFO"); } else if (!dinfo.dir_dreachable) { char abuf[INET6_ADDRSTRLEN]; dhcpmsg(MSG_DEBUG, "send_pkt_internal: %s is " "not reachable; using multicast instead", inet_ntop(AF_INET6, &dinfo.dir_daddr, abuf, sizeof (abuf))); sin6 = dsmp->dsm_send_dest.v6; sin6.sin6_addr = ipv6_all_dhcp_relay_and_servers; msg.msg_name = &sin6; ismcast = B_TRUE; } } /* * Make room for our ancillary data option as well as a dummy * option used by CMSG_NXTHDR. */ msg.msg_controllen = sizeof (*cmsg) + _MAX_ALIGNMENT + sizeof (*ipi6) + _MAX_ALIGNMENT + sizeof (*cmsg); msg.msg_control = alloca(msg.msg_controllen); cmsg = CMSG_FIRSTHDR(&msg); cmsg->cmsg_level = IPPROTO_IPV6; cmsg->cmsg_type = IPV6_PKTINFO; /* LINTED: alignment */ ipi6 = (struct in6_pktinfo *)CMSG_DATA(cmsg); if (ismcast) ipi6->ipi6_addr = lif->lif_v6addr; else ipi6->ipi6_addr = my_in6addr_any; ipi6->ipi6_ifindex = lif->lif_pif->pif_index; cmsg->cmsg_len = (char *)(ipi6 + 1) - (char *)cmsg; /* * Now correct the control message length. */ cmsg = CMSG_NXTHDR(&msg, cmsg); msg.msg_controllen = (char *)cmsg - (char *)msg.msg_control; n_bytes = sendmsg(v6_sock_fd, &msg, 0); } else { if (dsmp->dsm_using_dlpi) { n_bytes = dlpi_sendto(pif->pif_dlpi_hd, dpkt->pkt, dpkt->pkt_cur_len, &dsmp->dsm_send_dest.v4, pif->pif_daddr, pif->pif_dlen); /* dlpi_sendto calls putmsg */ if (n_bytes == 0) n_bytes = dpkt->pkt_cur_len; } else { n_bytes = sendto(lif->lif_sock_ip_fd, dpkt->pkt, dpkt->pkt_cur_len, 0, (struct sockaddr *)&dsmp->dsm_send_dest.v4, sizeof (struct sockaddr_in)); } } if (n_bytes != dpkt->pkt_cur_len) { if (dsmp->dsm_retrans_timer == -1) dhcpmsg(MSG_WARNING, "send_pkt_internal: cannot send " "%s packet to server", pkt_name); else dhcpmsg(MSG_WARNING, "send_pkt_internal: cannot send " "%s packet to server (will retry in %u seconds)", pkt_name, dsmp->dsm_send_timeout / MILLISEC); return (B_FALSE); } dhcpmsg(MSG_VERBOSE, "sent %s xid %x packet out %s", pkt_name, pkt_get_xid(dpkt->pkt, dpkt->pkt_isv6), dsmp->dsm_name); dsmp->dsm_packet_sent++; dsmp->dsm_sent++; return (B_TRUE); } /* * send_pkt(): sends a packet out * * input: dhcp_smach_t *: the state machine sending the packet * dhcp_pkt_t *: the packet to send out * in_addr_t: the destination IP address for the packet * stop_func_t *: a pointer to function to indicate when to stop * retransmitting the packet (if NULL, packet is * not retransmitted) * output: boolean_t: B_TRUE if the packet was sent, B_FALSE otherwise */ boolean_t send_pkt(dhcp_smach_t *dsmp, dhcp_pkt_t *dpkt, in_addr_t dest, stop_func_t *stop) { /* * packets must be at least sizeof (PKT) or they may be dropped * by routers. pad out the packet in this case. */ dpkt->pkt_cur_len = MAX(dpkt->pkt_cur_len, sizeof (PKT)); dsmp->dsm_packet_sent = 0; (void) memset(&dsmp->dsm_send_dest.v4, 0, sizeof (dsmp->dsm_send_dest.v4)); dsmp->dsm_send_dest.v4.sin_addr.s_addr = dest; dsmp->dsm_send_dest.v4.sin_family = AF_INET; dsmp->dsm_send_dest.v4.sin_port = htons(IPPORT_BOOTPS); dsmp->dsm_send_stop_func = stop; /* * TODO: dispose of this gruesome assumption (there's no real * technical gain from doing so, but it would be cleaner) */ assert(dpkt == &dsmp->dsm_send_pkt); /* * clear out any packets which had been previously received * but not pulled off of the recv_packet queue. */ free_pkt_list(&dsmp->dsm_recv_pkt_list); if (stop == NULL) dsmp->dsm_send_timeout = 0; /* prevents retransmissions */ else next_retransmission(dsmp, B_TRUE, B_FALSE); return (send_pkt_internal(dsmp)); } /* * send_pkt_v6(): sends a DHCPv6 packet out * * input: dhcp_smach_t *: the state machine sending the packet * dhcp_pkt_t *: the packet to send out * in6_addr_t: the destination IPv6 address for the packet * stop_func_t *: a pointer to function to indicate when to stop * retransmitting the packet (if NULL, packet is * not retransmitted) * uint_t: Initial Retransmit Timer value * uint_t: Maximum Retransmit Timer value, zero if none * output: boolean_t: B_TRUE if the packet was sent, B_FALSE otherwise */ boolean_t send_pkt_v6(dhcp_smach_t *dsmp, dhcp_pkt_t *dpkt, in6_addr_t dest, stop_func_t *stop, uint_t irt, uint_t mrt) { dsmp->dsm_packet_sent = 0; (void) memset(&dsmp->dsm_send_dest.v6, 0, sizeof (dsmp->dsm_send_dest.v6)); dsmp->dsm_send_dest.v6.sin6_addr = dest; dsmp->dsm_send_dest.v6.sin6_family = AF_INET6; dsmp->dsm_send_dest.v6.sin6_port = htons(IPPORT_DHCPV6S); dsmp->dsm_send_stop_func = stop; /* * TODO: dispose of this gruesome assumption (there's no real * technical gain from doing so, but it would be cleaner) */ assert(dpkt == &dsmp->dsm_send_pkt); /* * clear out any packets which had been previously received * but not pulled off of the recv_packet queue. */ free_pkt_list(&dsmp->dsm_recv_pkt_list); if (stop == NULL) { dsmp->dsm_send_timeout = 0; /* prevents retransmissions */ } else { dsmp->dsm_send_timeout = irt; dsmp->dsm_send_tcenter = mrt; /* * This is quite ugly, but RFC 3315 section 17.1.2 requires * that the RAND value for the very first retransmission of a * Solicit message is strictly greater than zero. */ next_retransmission(dsmp, B_TRUE, pkt_send_type(dpkt) == DHCPV6_MSG_SOLICIT); } return (send_pkt_internal(dsmp)); } /* * retransmit(): retransmits the current packet on an interface * * input: iu_tq_t *: unused * void *: the dhcp_smach_t * (state machine) sending a packet * output: void */ /* ARGSUSED */ static void retransmit(iu_tq_t *tqp, void *arg) { dhcp_smach_t *dsmp = arg; dsmp->dsm_retrans_timer = -1; if (!verify_smach(dsmp)) return; /* * Check the callback to see if we should keep sending retransmissions. * Compute the next retransmission time first, so that the callback can * cap the value if need be. (Required for DHCPv6 Confirm messages.) * * Hold the state machine across the callback so that the called * function can remove the state machine from the system without * disturbing the string used subsequently for verbose logging. The * Release function destroys the state machine when the retry count * expires. */ next_retransmission(dsmp, B_FALSE, B_FALSE); hold_smach(dsmp); if (dsmp->dsm_send_stop_func(dsmp, dsmp->dsm_packet_sent)) { dhcpmsg(MSG_VERBOSE, "retransmit: time to stop on %s", dsmp->dsm_name); } else { dhcpmsg(MSG_VERBOSE, "retransmit: sending another on %s", dsmp->dsm_name); (void) send_pkt_internal(dsmp); } release_smach(dsmp); } /* * stop_pkt_retransmission(): stops retransmission of last sent packet * * input: dhcp_smach_t *: the state machine to stop retransmission on * output: void */ void stop_pkt_retransmission(dhcp_smach_t *dsmp) { if (dsmp->dsm_retrans_timer != -1 && iu_cancel_timer(tq, dsmp->dsm_retrans_timer, NULL) == 1) { dhcpmsg(MSG_VERBOSE, "stop_pkt_retransmission: stopped on %s", dsmp->dsm_name); dsmp->dsm_retrans_timer = -1; release_smach(dsmp); } } /* * retransmit_now(): force a packet retransmission right now. Used only with * the DHCPv6 UseMulticast status code. Use with caution; * triggered retransmissions can cause packet storms. * * input: dhcp_smach_t *: the state machine to force retransmission on * output: void */ void retransmit_now(dhcp_smach_t *dsmp) { stop_pkt_retransmission(dsmp); (void) send_pkt_internal(dsmp); } /* * alloc_pkt_entry(): Allocates a packet list entry with a given data area * size. * * input: size_t: size of data area for packet * boolean_t: B_TRUE for IPv6 * output: PKT_LIST *: allocated packet list entry */ PKT_LIST * alloc_pkt_entry(size_t psize, boolean_t isv6) { PKT_LIST *plp; if ((plp = calloc(1, sizeof (*plp))) == NULL || (plp->pkt = malloc(psize)) == NULL) { free(plp); plp = NULL; } else { plp->len = psize; plp->isv6 = isv6; } return (plp); } /* * sock_recvpkt(): read from the given socket into an allocated buffer and * handles any ancillary data options. * * input: int: file descriptor to read * PKT_LIST *: allocated buffer * output: ssize_t: number of bytes read, or -1 on error */ static ssize_t sock_recvpkt(int fd, PKT_LIST *plp) { struct iovec iov; struct msghdr msg; int64_t ctrl[8192 / sizeof (int64_t)]; ssize_t msglen; (void) memset(&iov, 0, sizeof (iov)); iov.iov_base = (caddr_t)plp->pkt; iov.iov_len = plp->len; (void) memset(&msg, 0, sizeof (msg)); msg.msg_name = &plp->pktfrom; msg.msg_namelen = sizeof (plp->pktfrom); msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_control = ctrl; msg.msg_controllen = sizeof (ctrl); if ((msglen = recvmsg(fd, &msg, 0)) != -1) { struct cmsghdr *cmsg; for (cmsg = CMSG_FIRSTHDR(&msg); cmsg != NULL; cmsg = CMSG_NXTHDR(&msg, cmsg)) { struct sockaddr_in *sinp; struct sockaddr_in6 *sin6; struct in6_pktinfo *ipi6; switch (cmsg->cmsg_level) { case IPPROTO_IP: switch (cmsg->cmsg_type) { case IP_RECVDSTADDR: sinp = (struct sockaddr_in *) &plp->pktto; sinp->sin_family = AF_INET; (void) memcpy(&sinp->sin_addr.s_addr, CMSG_DATA(cmsg), sizeof (ipaddr_t)); break; case IP_RECVIF: (void) memcpy(&plp->ifindex, CMSG_DATA(cmsg), sizeof (uint_t)); break; } break; case IPPROTO_IPV6: switch (cmsg->cmsg_type) { case IPV6_PKTINFO: /* LINTED: alignment */ ipi6 = (struct in6_pktinfo *) CMSG_DATA(cmsg); sin6 = (struct sockaddr_in6 *) &plp->pktto; sin6->sin6_family = AF_INET6; (void) memcpy(&sin6->sin6_addr, &ipi6->ipi6_addr, sizeof (ipi6->ipi6_addr)); (void) memcpy(&plp->ifindex, &ipi6->ipi6_ifindex, sizeof (uint_t)); break; } } } } return (msglen); } /* * recv_pkt(): receives a single DHCP packet on a given file descriptor. * * input: int: if not using dlpi, the file descriptor to receive the packet * int: the maximum packet size to allow * boolean_t: B_TRUE for IPv6 * boolean_t: B_TRUE if using DLPI * void *: if using DLPI, structure that has DLPI handle * output: PKT_LIST *: the received packet */ PKT_LIST * recv_pkt(int fd, int mtu, boolean_t isv6, boolean_t isdlpi, dhcp_pif_t *arg) { PKT_LIST *plp; ssize_t retval; if ((plp = alloc_pkt_entry(mtu, isv6)) == NULL) { dhcpmsg(MSG_ERROR, "recv_pkt: allocation failure; dropped packet"); return (NULL); } if (isv6) { retval = sock_recvpkt(fd, plp); if (retval == -1) { dhcpmsg(MSG_ERR, "recv_pkt: recvfrom v6 failed, dropped"); goto failure; } plp->len = retval; if (retval < sizeof (dhcpv6_message_t)) { dhcpmsg(MSG_WARNING, "recv_pkt: runt message"); goto failure; } } else { if (isdlpi) { dhcp_pif_t *pif = arg; retval = dlpi_recvfrom(pif->pif_dlpi_hd, plp->pkt, mtu, (struct sockaddr_in *)&plp->pktfrom, (struct sockaddr_in *)&plp->pktto); } else { retval = sock_recvpkt(fd, plp); } if (retval == -1) { dhcpmsg(MSG_ERR, "recv_pkt: %srecvfrom v4 failed, dropped", isdlpi ? "dlpi_" : ""); goto failure; } plp->len = retval; switch (dhcp_options_scan(plp, B_TRUE)) { case DHCP_WRONG_MSG_TYPE: dhcpmsg(MSG_WARNING, "recv_pkt: unexpected DHCP message"); goto failure; case DHCP_GARBLED_MSG_TYPE: dhcpmsg(MSG_WARNING, "recv_pkt: garbled DHCP message type"); goto failure; case DHCP_BAD_OPT_OVLD: dhcpmsg(MSG_WARNING, "recv_pkt: bad option overload"); goto failure; case 0: break; default: dhcpmsg(MSG_WARNING, "recv_pkt: packet corrupted, dropped"); goto failure; } } return (plp); failure: free_pkt_entry(plp); return (NULL); } /* * pkt_v4_match(): check if a given DHCPv4 message type is in a given set * * input: uchar_t: packet type * dhcp_message_type_t: bit-wise OR of DHCP_P* values. * output: boolean_t: B_TRUE if packet type is in the set */ boolean_t pkt_v4_match(uchar_t type, dhcp_message_type_t match_type) { /* * note: the ordering here allows direct indexing of the table * based on the RFC2131 packet type value passed in. */ static dhcp_message_type_t type_map[] = { DHCP_PUNTYPED, DHCP_PDISCOVER, DHCP_POFFER, DHCP_PREQUEST, DHCP_PDECLINE, DHCP_PACK, DHCP_PNAK, DHCP_PRELEASE, DHCP_PINFORM }; if (type < (sizeof (type_map) / sizeof (*type_map))) return ((type_map[type] & match_type) ? B_TRUE : B_FALSE); else return (B_FALSE); } /* * pkt_smach_enqueue(): enqueue a packet on a given state machine * * input: dhcp_smach_t: state machine * PKT_LIST *: packet to enqueue * output: none */ void pkt_smach_enqueue(dhcp_smach_t *dsmp, PKT_LIST *plp) { dhcpmsg(MSG_VERBOSE, "pkt_smach_enqueue: received %s %s packet on %s", pkt_type_to_string(pkt_recv_type(plp), dsmp->dsm_isv6), dsmp->dsm_isv6 ? "v6" : "v4", dsmp->dsm_name); /* add to front of list */ insque(plp, &dsmp->dsm_recv_pkt_list); } /* * next_retransmission(): computes the number of seconds until the next * retransmission, based on the algorithms in RFCs 2131 * 3315. * * input: dhcp_smach_t *: state machine that needs a new timer * boolean_t: B_TRUE if this is the first time sending the message * boolean_t: B_TRUE for positive RAND values only (RFC 3315 17.1.2) * output: none */ static void next_retransmission(dhcp_smach_t *dsmp, boolean_t first_send, boolean_t positive_only) { uint32_t timeout_ms; if (dsmp->dsm_isv6) { double randval; /* * The RFC specifies 0 to 10% jitter for the initial * solicitation, and plus or minus 10% jitter for all others. * This works out to 100 milliseconds on the shortest timer we * use. */ if (positive_only) randval = drand48() / 10.0; else randval = (drand48() - 0.5) / 5.0; /* The RFC specifies doubling *after* the first transmission */ timeout_ms = dsmp->dsm_send_timeout; if (!first_send) timeout_ms *= 2; timeout_ms += (int)(randval * dsmp->dsm_send_timeout); /* This checks the MRT (maximum retransmission time) */ if (dsmp->dsm_send_tcenter != 0 && timeout_ms > dsmp->dsm_send_tcenter) { timeout_ms = dsmp->dsm_send_tcenter + (uint_t)(randval * dsmp->dsm_send_tcenter); } dsmp->dsm_send_timeout = timeout_ms; } else { if (dsmp->dsm_state == RENEWING || dsmp->dsm_state == REBINDING) { monosec_t mono; timeout_ms = dsmp->dsm_state == RENEWING ? dsmp->dsm_leases->dl_t2.dt_start : dsmp->dsm_leases->dl_lifs->lif_expire.dt_start; timeout_ms += dsmp->dsm_curstart_monosec; mono = monosec(); if (mono > timeout_ms) timeout_ms = 0; else timeout_ms -= mono; timeout_ms *= MILLISEC / 2; } else { /* * Start at 4, and increase by a factor of 2 up to 64. */ if (first_send) { timeout_ms = 4 * MILLISEC; } else { timeout_ms = MIN(dsmp->dsm_send_tcenter << 1, 64 * MILLISEC); } } dsmp->dsm_send_tcenter = timeout_ms; /* * At each iteration, jitter the timeout by some fraction of a * second. */ dsmp->dsm_send_timeout = timeout_ms + ((lrand48() % (2 * MILLISEC)) - MILLISEC); } } /* * dhcp_ip_default(): open and bind the default IP sockets used for I/O and * interface control. * * input: none * output: B_TRUE on success */ boolean_t dhcp_ip_default(void) { int on = 1; if ((v4_sock_fd = socket(AF_INET, SOCK_DGRAM, 0)) == -1) { dhcpmsg(MSG_ERR, "dhcp_ip_default: unable to create IPv4 socket"); return (B_FALSE); } if (setsockopt(v4_sock_fd, IPPROTO_IP, IP_RECVDSTADDR, &on, sizeof (on)) == -1) { dhcpmsg(MSG_ERR, "dhcp_ip_default: unable to enable IP_RECVDSTADDR"); return (B_FALSE); } if (setsockopt(v4_sock_fd, IPPROTO_IP, IP_RECVIF, &on, sizeof (on)) == -1) { dhcpmsg(MSG_ERR, "dhcp_ip_default: unable to enable IP_RECVIF"); return (B_FALSE); } if (!bind_sock(v4_sock_fd, IPPORT_BOOTPC, INADDR_ANY)) { dhcpmsg(MSG_ERROR, "dhcp_ip_default: unable to bind IPv4 socket to port %d", IPPORT_BOOTPC); return (B_FALSE); } if (iu_register_event(eh, v4_sock_fd, POLLIN, dhcp_acknak_common, NULL) == -1) { dhcpmsg(MSG_WARNING, "dhcp_ip_default: cannot register to " "receive IPv4 broadcasts"); return (B_FALSE); } if ((v6_sock_fd = socket(AF_INET6, SOCK_DGRAM, 0)) == -1) { dhcpmsg(MSG_ERR, "dhcp_ip_default: unable to create IPv6 socket"); return (B_FALSE); } if (setsockopt(v6_sock_fd, IPPROTO_IPV6, IPV6_RECVPKTINFO, &on, sizeof (on)) == -1) { dhcpmsg(MSG_ERR, "dhcp_ip_default: unable to enable IPV6_RECVPKTINFO"); return (B_FALSE); } if (!bind_sock_v6(v6_sock_fd, IPPORT_DHCPV6C, NULL)) { dhcpmsg(MSG_ERROR, "dhcp_ip_default: unable to bind IPv6 socket to port %d", IPPORT_DHCPV6C); return (B_FALSE); } if (iu_register_event(eh, v6_sock_fd, POLLIN, dhcp_acknak_common, NULL) == -1) { dhcpmsg(MSG_WARNING, "dhcp_ip_default: cannot register to " "receive IPv6 packets"); return (B_FALSE); } return (B_TRUE); }