/* $NetBSD: if_spppsubr.c,v 1.268 2024/02/17 15:47:39 martin Exp $ */ /* * Synchronous PPP/Cisco link level subroutines. * Keepalive protocol implemented in both Cisco and PPP modes. * * Copyright (C) 1994-1996 Cronyx Engineering Ltd. * Author: Serge Vakulenko, * * Heavily revamped to conform to RFC 1661. * Copyright (C) 1997, Joerg Wunsch. * * RFC2472 IPv6CP support. * Copyright (C) 2000, Jun-ichiro itojun Hagino . * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE FREEBSD PROJECT ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE FREEBSD PROJECT OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * * From: Version 2.4, Thu Apr 30 17:17:21 MSD 1997 * * From: if_spppsubr.c,v 1.39 1998/04/04 13:26:03 phk Exp * * From: Id: if_spppsubr.c,v 1.23 1999/02/23 14:47:50 hm Exp */ #include __KERNEL_RCSID(0, "$NetBSD: if_spppsubr.c,v 1.268 2024/02/17 15:47:39 martin Exp $"); #if defined(_KERNEL_OPT) #include "opt_inet.h" #include "opt_modular.h" #include "opt_compat_netbsd.h" #include "opt_net_mpsafe.h" #include "opt_sppp.h" #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef INET #include #include #endif #include #ifdef INET6 #include #endif #include #include #ifdef NET_MPSAFE #define SPPPSUBR_MPSAFE 1 #endif #define DEFAULT_KEEPALIVE_INTERVAL 10 /* seconds between checks */ #define DEFAULT_ALIVE_INTERVAL 1 /* count of sppp_keepalive */ #define LOOPALIVECNT 3 /* loopback detection tries */ #define DEFAULT_MAXALIVECNT 3 /* max. missed alive packets */ #define DEFAULT_NORECV_TIME 15 /* before we get worried */ #define DEFAULT_MAX_AUTH_FAILURES 5 /* max. auth. failures */ #ifndef SPPP_KEEPALIVE_INTERVAL #define SPPP_KEEPALIVE_INTERVAL DEFAULT_KEEPALIVE_INTERVAL #endif #ifndef SPPP_NORECV_TIME #define SPPP_NORECV_TIME DEFAULT_NORECV_TIME #endif #ifndef SPPP_ALIVE_INTERVAL #define SPPP_ALIVE_INTERVAL DEFAULT_ALIVE_INTERVAL #endif #define SPPP_CPTYPE_NAMELEN 5 /* buf size of cp type name */ #define SPPP_AUTHTYPE_NAMELEN 32 /* buf size of auth type name */ #define SPPP_LCPOPT_NAMELEN 5 /* buf size of lcp option name */ #define SPPP_IPCPOPT_NAMELEN 5 /* buf size of ipcp option name */ #define SPPP_IPV6CPOPT_NAMELEN 5 /* buf size of ipv6cp option name */ #define SPPP_PROTO_NAMELEN 7 /* buf size of protocol name */ #define SPPP_DOTQUAD_BUFLEN 16 /* length of "aa.bb.cc.dd" */ /* * Interface flags that can be set in an ifconfig command. * * Setting link0 will make the link passive, i.e. it will be marked * as being administrative openable, but won't be opened to begin * with. Incoming calls will be answered, or subsequent calls with * -link1 will cause the administrative open of the LCP layer. * * Setting link1 will cause the link to auto-dial only as packets * arrive to be sent. * * Setting IFF_DEBUG will syslog the option negotiation and state * transitions at level kern.debug. Note: all logs consistently look * like * * : * * with being something like "bppp0", and * being one of "lcp", "ipcp", "cisco", "chap", "pap", etc. */ #define IFF_PASSIVE IFF_LINK0 /* wait passively for connection */ #define IFF_AUTO IFF_LINK1 /* auto-dial on output */ #define CONF_REQ 1 /* PPP configure request */ #define CONF_ACK 2 /* PPP configure acknowledge */ #define CONF_NAK 3 /* PPP configure negative ack */ #define CONF_REJ 4 /* PPP configure reject */ #define TERM_REQ 5 /* PPP terminate request */ #define TERM_ACK 6 /* PPP terminate acknowledge */ #define CODE_REJ 7 /* PPP code reject */ #define PROTO_REJ 8 /* PPP protocol reject */ #define ECHO_REQ 9 /* PPP echo request */ #define ECHO_REPLY 10 /* PPP echo reply */ #define DISC_REQ 11 /* PPP discard request */ #define LCP_OPT_MRU 1 /* maximum receive unit */ #define LCP_OPT_ASYNC_MAP 2 /* async control character map */ #define LCP_OPT_AUTH_PROTO 3 /* authentication protocol */ #define LCP_OPT_QUAL_PROTO 4 /* quality protocol */ #define LCP_OPT_MAGIC 5 /* magic number */ #define LCP_OPT_RESERVED 6 /* reserved */ #define LCP_OPT_PROTO_COMP 7 /* protocol field compression */ #define LCP_OPT_ADDR_COMP 8 /* address/control field compression */ #define LCP_OPT_FCS_ALTS 9 /* FCS alternatives */ #define LCP_OPT_SELF_DESC_PAD 10 /* self-describing padding */ #define LCP_OPT_CALL_BACK 13 /* callback */ #define LCP_OPT_COMPOUND_FRMS 15 /* compound frames */ #define LCP_OPT_MP_MRRU 17 /* multilink MRRU */ #define LCP_OPT_MP_SSNHF 18 /* multilink short seq. numbers */ #define LCP_OPT_MP_EID 19 /* multilink endpoint discriminator */ #define IPCP_OPT_ADDRESSES 1 /* both IP addresses; deprecated */ #define IPCP_OPT_COMPRESSION 2 /* IP compression protocol */ #define IPCP_OPT_ADDRESS 3 /* local IP address */ #define IPCP_OPT_PRIMDNS 129 /* primary remote dns address */ #define IPCP_OPT_SECDNS 131 /* secondary remote dns address */ #define IPCP_UPDATE_LIMIT 8 /* limit of pending IP updating job */ #define IPCP_SET_ADDRS 1 /* marker for IP address setting job */ #define IPCP_CLEAR_ADDRS 2 /* marker for IP address clearing job */ #define IPV6CP_OPT_IFID 1 /* interface identifier */ #define IPV6CP_OPT_COMPRESSION 2 /* IPv6 compression protocol */ #define PAP_REQ 1 /* PAP name/password request */ #define PAP_ACK 2 /* PAP acknowledge */ #define PAP_NAK 3 /* PAP fail */ #define CHAP_CHALLENGE 1 /* CHAP challenge request */ #define CHAP_RESPONSE 2 /* CHAP challenge response */ #define CHAP_SUCCESS 3 /* CHAP response ok */ #define CHAP_FAILURE 4 /* CHAP response failed */ #define CHAP_MD5 5 /* hash algorithm - MD5 */ #define CISCO_MULTICAST 0x8f /* Cisco multicast address */ #define CISCO_UNICAST 0x0f /* Cisco unicast address */ #define CISCO_KEEPALIVE 0x8035 /* Cisco keepalive protocol */ #define CISCO_ADDR_REQ 0 /* Cisco address request */ #define CISCO_ADDR_REPLY 1 /* Cisco address reply */ #define CISCO_KEEPALIVE_REQ 2 /* Cisco keepalive request */ #define PPP_NOPROTO 0 /* no authentication protocol */ enum { STATE_INITIAL = SPPP_STATE_INITIAL, STATE_STARTING = SPPP_STATE_STARTING, STATE_CLOSED = SPPP_STATE_CLOSED, STATE_STOPPED = SPPP_STATE_STOPPED, STATE_CLOSING = SPPP_STATE_CLOSING, STATE_STOPPING = SPPP_STATE_STOPPING, STATE_REQ_SENT = SPPP_STATE_REQ_SENT, STATE_ACK_RCVD = SPPP_STATE_ACK_RCVD, STATE_ACK_SENT = SPPP_STATE_ACK_SENT, STATE_OPENED = SPPP_STATE_OPENED, }; enum cp_rcr_type { CP_RCR_NONE = 0, /* initial value */ CP_RCR_ACK, /* RCR+ */ CP_RCR_NAK, /* RCR- */ CP_RCR_REJ, /* RCR- */ CP_RCR_DROP, /* DROP message */ CP_RCR_ERR, /* internal error */ }; struct ppp_header { uint8_t address; uint8_t control; uint16_t protocol; } __packed; #define PPP_HEADER_LEN sizeof (struct ppp_header) struct lcp_header { uint8_t type; uint8_t ident; uint16_t len; } __packed; #define LCP_HEADER_LEN sizeof (struct lcp_header) struct cisco_packet { uint32_t type; uint32_t par1; uint32_t par2; uint16_t rel; uint16_t time0; uint16_t time1; } __packed; #define CISCO_PACKET_LEN 18 /* * We follow the spelling and capitalization of RFC 1661 here, to make * it easier comparing with the standard. Please refer to this RFC in * case you can't make sense out of these abbreviation; it will also * explain the semantics related to the various events and actions. */ struct cp { u_short proto; /* PPP control protocol number */ u_char protoidx; /* index into state table in struct sppp */ u_char flags; #define CP_LCP 0x01 /* this is the LCP */ #define CP_AUTH 0x02 /* this is an authentication protocol */ #define CP_NCP 0x04 /* this is a NCP */ #define CP_QUAL 0x08 /* this is a quality reporting protocol */ const char *name; /* name of this control protocol */ /* event handlers */ void (*Up)(struct sppp *, void *); void (*Down)(struct sppp *, void *); void (*Open)(struct sppp *, void *); void (*Close)(struct sppp *, void *); void (*TO)(struct sppp *, void *); /* actions */ void (*tlu)(struct sppp *); void (*tld)(struct sppp *); void (*tls)(const struct cp *, struct sppp *); void (*tlf)(const struct cp *, struct sppp *); void (*scr)(struct sppp *); void (*screply)(const struct cp *, struct sppp *, u_char, uint8_t, size_t, void *); /* message parser */ enum cp_rcr_type (*parse_confreq)(struct sppp *, struct lcp_header *, int, uint8_t **, size_t *, size_t *); void (*parse_confrej)(struct sppp *, struct lcp_header *, int); void (*parse_confnak)(struct sppp *, struct lcp_header *, int); }; enum auth_role { SPPP_AUTH_NOROLE = 0, SPPP_AUTH_SERV = __BIT(0), SPPP_AUTH_PEER = __BIT(1), }; static struct sppp *spppq; static kmutex_t *spppq_lock = NULL; static callout_t keepalive_ch; static unsigned int sppp_keepalive_cnt = 0; pktq_rps_hash_func_t sppp_pktq_rps_hash_p; #define SPPPQ_LOCK() if (spppq_lock) \ mutex_enter(spppq_lock); #define SPPPQ_UNLOCK() if (spppq_lock) \ mutex_exit(spppq_lock); #define SPPP_LOCK(_sp, _op) rw_enter(&(_sp)->pp_lock, (_op)) #define SPPP_UNLOCK(_sp) rw_exit(&(_sp)->pp_lock) #define SPPP_WLOCKED(_sp) rw_write_held(&(_sp)->pp_lock) #define SPPP_UPGRADE(_sp) do{ \ SPPP_UNLOCK(_sp); \ SPPP_LOCK(_sp, RW_WRITER); \ }while (0) #define SPPP_DOWNGRADE(_sp) rw_downgrade(&(_sp)->pp_lock) #define SPPP_WQ_SET(_wk, _func, _arg) \ sppp_wq_set((_wk), (_func), __UNCONST((_arg))) #define SPPP_LOG(_sp, _lvl, _fmt, _args...) do { \ if (__predict_true((_sp) != NULL)) { \ log((_lvl), "%s: ", (_sp)->pp_if.if_xname); \ } \ addlog((_fmt), ##_args); \ } while (0) #define SPPP_DLOG(_sp, _fmt, _args...) do { \ if (!sppp_debug_enabled(_sp)) \ break; \ SPPP_LOG(_sp, LOG_DEBUG, _fmt, ##_args); \ } while (0) #ifdef INET #ifndef SPPPSUBR_MPSAFE /* * The following disgusting hack gets around the problem that IP TOS * can't be set yet. We want to put "interactive" traffic on a high * priority queue. To decide if traffic is interactive, we check that * a) it is TCP and b) one of its ports is telnet, rlogin or ftp control. * * XXX is this really still necessary? - joerg - */ static u_short interactive_ports[8] = { 0, 513, 0, 0, 0, 21, 0, 23, }; #define INTERACTIVE(p) (interactive_ports[(p) & 7] == (p)) #endif /* SPPPSUBR_MPSAFE */ #endif /* almost every function needs these */ static bool sppp_debug_enabled(struct sppp *sp); static int sppp_output(struct ifnet *, struct mbuf *, const struct sockaddr *, const struct rtentry *); static void sppp_cp_init(const struct cp *, struct sppp *); static void sppp_cp_fini(const struct cp *, struct sppp *); static void sppp_cp_input(const struct cp *, struct sppp *, struct mbuf *); static void sppp_cp_input(const struct cp *, struct sppp *, struct mbuf *); static void sppp_cp_send(struct sppp *, u_short, u_char, u_char, u_short, void *); /* static void sppp_cp_timeout(void *arg); */ static void sppp_cp_change_state(const struct cp *, struct sppp *, int); static struct workqueue * sppp_wq_create(struct sppp *, const char *, pri_t, int, int); static void sppp_wq_destroy(struct sppp *, struct workqueue *); static void sppp_wq_set(struct sppp_work *, void (*)(struct sppp *, void *), void *); static void sppp_wq_add(struct workqueue *, struct sppp_work *); static void sppp_wq_wait(struct workqueue *, struct sppp_work *); static void sppp_cp_to_lcp(void *); static void sppp_cp_to_ipcp(void *); static void sppp_cp_to_ipv6cp(void *); static void sppp_auth_send(const struct cp *, struct sppp *, unsigned int, unsigned int, ...); static int sppp_auth_role(const struct cp *, struct sppp *); static void sppp_auth_to_event(struct sppp *, void *); static void sppp_auth_screply(const struct cp *, struct sppp *, u_char, uint8_t, size_t, void *); static void sppp_up_event(struct sppp *, void *); static void sppp_down_event(struct sppp *, void *); static void sppp_open_event(struct sppp *, void *); static void sppp_close_event(struct sppp *, void *); static void sppp_to_event(struct sppp *, void *); static void sppp_rcr_event(struct sppp *, void *); static void sppp_rca_event(struct sppp *, void *); static void sppp_rcn_event(struct sppp *, void *); static void sppp_rtr_event(struct sppp *, void *); static void sppp_rta_event(struct sppp *, void *); static void sppp_rxj_event(struct sppp *, void *); static void sppp_null(struct sppp *); static void sppp_tls(const struct cp *, struct sppp *); static void sppp_tlf(const struct cp *, struct sppp *); static void sppp_screply(const struct cp *, struct sppp *, u_char, uint8_t, size_t, void *); static void sppp_ifdown(struct sppp *, void *); static void sppp_lcp_init(struct sppp *); static void sppp_lcp_up(struct sppp *, void *); static void sppp_lcp_down(struct sppp *, void *); static void sppp_lcp_open(struct sppp *, void *); static enum cp_rcr_type sppp_lcp_confreq(struct sppp *, struct lcp_header *, int, uint8_t **, size_t *, size_t *); static void sppp_lcp_confrej(struct sppp *, struct lcp_header *, int); static void sppp_lcp_confnak(struct sppp *, struct lcp_header *, int); static void sppp_lcp_tlu(struct sppp *); static void sppp_lcp_tld(struct sppp *); static void sppp_lcp_tls(const struct cp *, struct sppp *); static void sppp_lcp_tlf(const struct cp *, struct sppp *); static void sppp_lcp_scr(struct sppp *); static void sppp_lcp_check_and_close(struct sppp *); static int sppp_cp_check(struct sppp *, u_char); static void sppp_ipcp_init(struct sppp *); static void sppp_ipcp_open(struct sppp *, void *); static void sppp_ipcp_close(struct sppp *, void *); static enum cp_rcr_type sppp_ipcp_confreq(struct sppp *, struct lcp_header *, int, uint8_t **, size_t *, size_t *); static void sppp_ipcp_confrej(struct sppp *, struct lcp_header *, int); static void sppp_ipcp_confnak(struct sppp *, struct lcp_header *, int); static void sppp_ipcp_tlu(struct sppp *); static void sppp_ipcp_tld(struct sppp *); static void sppp_ipcp_scr(struct sppp *); static void sppp_ipv6cp_init(struct sppp *); static void sppp_ipv6cp_open(struct sppp *, void *); static enum cp_rcr_type sppp_ipv6cp_confreq(struct sppp *, struct lcp_header *, int, uint8_t **, size_t *, size_t *); static void sppp_ipv6cp_confrej(struct sppp *, struct lcp_header *, int); static void sppp_ipv6cp_confnak(struct sppp *, struct lcp_header *, int); static void sppp_ipv6cp_tlu(struct sppp *); static void sppp_ipv6cp_tld(struct sppp *); static void sppp_ipv6cp_scr(struct sppp *); static void sppp_pap_input(struct sppp *, struct mbuf *); static void sppp_pap_init(struct sppp *); static void sppp_pap_tlu(struct sppp *); static void sppp_pap_scr(struct sppp *); static void sppp_chap_input(struct sppp *, struct mbuf *); static void sppp_chap_init(struct sppp *); static void sppp_chap_open(struct sppp *, void *); static void sppp_chap_tlu(struct sppp *); static void sppp_chap_scr(struct sppp *); static void sppp_chap_rcv_challenge_event(struct sppp *, void *); static const char *sppp_auth_type_name(char *, size_t, u_short, u_char); static const char *sppp_cp_type_name(char *, size_t, u_char); static const char *sppp_dotted_quad(char *, size_t, uint32_t); static const char *sppp_ipcp_opt_name(char *, size_t, u_char); #ifdef INET6 static const char *sppp_ipv6cp_opt_name(char *, size_t, u_char); #endif static const char *sppp_lcp_opt_name(char *, size_t, u_char); static const char *sppp_phase_name(int); static const char *sppp_proto_name(char *, size_t, u_short); static const char *sppp_state_name(int); static int sppp_params(struct sppp *, u_long, void *); #ifdef INET static void sppp_get_ip_addrs(struct sppp *, uint32_t *, uint32_t *, uint32_t *); static void sppp_set_ip_addrs(struct sppp *); static void sppp_clear_ip_addrs(struct sppp *); #endif static void sppp_keepalive(void *); static void sppp_phase_network(struct sppp *); static void sppp_print_bytes(const u_char *, u_short); static void sppp_print_string(const char *, u_short); #ifdef INET6 static void sppp_get_ip6_addrs(struct sppp *, struct in6_addr *, struct in6_addr *, struct in6_addr *); #ifdef IPV6CP_MYIFID_DYN static void sppp_set_ip6_addr(struct sppp *, const struct in6_addr *); static void sppp_gen_ip6_addr(struct sppp *, const struct in6_addr *); #endif static void sppp_suggest_ip6_addr(struct sppp *, struct in6_addr *); #endif static void sppp_notify_up(struct sppp *); static void sppp_notify_down(struct sppp *); static void sppp_notify_tls_wlocked(struct sppp *); static void sppp_notify_tlf_wlocked(struct sppp *); #ifdef INET6 static void sppp_notify_con_wlocked(struct sppp *); #endif static void sppp_notify_con(struct sppp *); static void sppp_notify_chg_wlocked(struct sppp *); /* our control protocol descriptors */ static const struct cp lcp = { PPP_LCP, IDX_LCP, CP_LCP, "lcp", sppp_lcp_up, sppp_lcp_down, sppp_lcp_open, sppp_close_event, sppp_to_event, sppp_lcp_tlu, sppp_lcp_tld, sppp_lcp_tls, sppp_lcp_tlf, sppp_lcp_scr, sppp_screply, sppp_lcp_confreq, sppp_lcp_confrej, sppp_lcp_confnak }; static const struct cp ipcp = { PPP_IPCP, IDX_IPCP, #ifdef INET CP_NCP, /*don't run IPCP if there's no IPv4 support*/ #else 0, #endif "ipcp", sppp_up_event, sppp_down_event, sppp_ipcp_open, sppp_ipcp_close, sppp_to_event, sppp_ipcp_tlu, sppp_ipcp_tld, sppp_tls, sppp_tlf, sppp_ipcp_scr, sppp_screply, sppp_ipcp_confreq, sppp_ipcp_confrej, sppp_ipcp_confnak, }; static const struct cp ipv6cp = { PPP_IPV6CP, IDX_IPV6CP, #ifdef INET6 /*don't run IPv6CP if there's no IPv6 support*/ CP_NCP, #else 0, #endif "ipv6cp", sppp_up_event, sppp_down_event, sppp_ipv6cp_open, sppp_close_event, sppp_to_event, sppp_ipv6cp_tlu, sppp_ipv6cp_tld, sppp_tls, sppp_tlf, sppp_ipv6cp_scr, sppp_screply, sppp_ipv6cp_confreq, sppp_ipv6cp_confrej, sppp_ipv6cp_confnak, }; static const struct cp pap = { PPP_PAP, IDX_PAP, CP_AUTH, "pap", sppp_up_event, sppp_down_event, sppp_open_event, sppp_close_event, sppp_auth_to_event, sppp_pap_tlu, sppp_null, sppp_tls, sppp_tlf, sppp_pap_scr, sppp_auth_screply, NULL, NULL, NULL }; static const struct cp chap = { PPP_CHAP, IDX_CHAP, CP_AUTH, "chap", sppp_up_event, sppp_down_event, sppp_chap_open, sppp_close_event, sppp_auth_to_event, sppp_chap_tlu, sppp_null, sppp_tls, sppp_tlf, sppp_chap_scr, sppp_auth_screply, NULL, NULL, NULL }; static const struct cp *cps[IDX_COUNT] = { &lcp, /* IDX_LCP */ &ipcp, /* IDX_IPCP */ &ipv6cp, /* IDX_IPV6CP */ &pap, /* IDX_PAP */ &chap, /* IDX_CHAP */ }; static inline u_int sppp_proto2authproto(u_short proto) { switch (proto) { case PPP_PAP: return SPPP_AUTHPROTO_PAP; case PPP_CHAP: return SPPP_AUTHPROTO_CHAP; } return SPPP_AUTHPROTO_NONE; } static inline u_short sppp_authproto2proto(u_int authproto) { switch (authproto) { case SPPP_AUTHPROTO_PAP: return PPP_PAP; case SPPP_AUTHPROTO_CHAP: return PPP_CHAP; } return PPP_NOPROTO; } static inline bool sppp_debug_enabled(struct sppp *sp) { if (__predict_false(sp == NULL)) return false; if ((sp->pp_if.if_flags & IFF_DEBUG) == 0) return false; return true; } static void sppp_change_phase(struct sppp *sp, int phase) { struct ifnet *ifp; KASSERT(SPPP_WLOCKED(sp)); ifp = &sp->pp_if; if (sp->pp_phase == phase) return; sp->pp_phase = phase; if (phase == SPPP_PHASE_NETWORK) if_link_state_change(ifp, LINK_STATE_UP); else if_link_state_change(ifp, LINK_STATE_DOWN); SPPP_DLOG(sp, "phase %s\n", sppp_phase_name(sp->pp_phase)); } /* * Exported functions, comprising our interface to the lower layer. */ /* * Process the received packet. */ void sppp_input(struct ifnet *ifp, struct mbuf *m) { struct ppp_header *h = NULL; pktqueue_t *pktq = NULL; uint16_t protocol; struct sppp *sp = (struct sppp *)ifp; /* No RPS for not-IP. */ pktq_rps_hash_func_t rps_hash = NULL; SPPP_LOCK(sp, RW_READER); if (ifp->if_flags & IFF_UP) { /* Count received bytes, add hardware framing */ if_statadd(ifp, if_ibytes, m->m_pkthdr.len + sp->pp_framebytes); /* Note time of last receive */ sp->pp_last_receive = time_uptime; } if (m->m_pkthdr.len <= PPP_HEADER_LEN) { /* Too small packet, drop it. */ SPPP_DLOG(sp, "input packet is too small, " "%d bytes\n", m->m_pkthdr.len); goto drop; } if (sp->pp_flags & PP_NOFRAMING) { memcpy(&protocol, mtod(m, void *), 2); protocol = ntohs(protocol); m_adj(m, 2); } else { /* Get PPP header. */ h = mtod(m, struct ppp_header *); m_adj(m, PPP_HEADER_LEN); switch (h->address) { case PPP_ALLSTATIONS: if (h->control != PPP_UI) goto invalid; break; case CISCO_MULTICAST: case CISCO_UNICAST: /* Don't check the control field here (RFC 1547). */ SPPP_DLOG(sp, "Cisco packet in PPP mode " "\n", h->address, h->control, ntohs(h->protocol)); goto drop; default: /* Invalid PPP packet. */ invalid: SPPP_DLOG(sp, "invalid input packet " "\n", h->address, h->control, ntohs(h->protocol)); goto drop; } protocol = ntohs(h->protocol); } switch (protocol) { reject_protocol: if (sp->scp[IDX_LCP].state == STATE_OPENED) { uint16_t prot = htons(protocol); SPPP_UPGRADE(sp); sppp_cp_send(sp, PPP_LCP, PROTO_REJ, ++sp->scp[IDX_LCP].seq, m->m_pkthdr.len + 2, &prot); SPPP_DOWNGRADE(sp); } if_statinc(ifp, if_noproto); goto drop; default: SPPP_DLOG(sp, "invalid input protocol " "\n", protocol); goto reject_protocol; case PPP_LCP: SPPP_UNLOCK(sp); sppp_cp_input(&lcp, sp, m); /* already m_freem(m) */ return; case PPP_PAP: SPPP_UNLOCK(sp); if (sp->pp_phase >= SPPP_PHASE_AUTHENTICATE) { sppp_pap_input(sp, m); } m_freem(m); return; case PPP_CHAP: SPPP_UNLOCK(sp); if (sp->pp_phase >= SPPP_PHASE_AUTHENTICATE) { sppp_chap_input(sp, m); } m_freem(m); return; #ifdef INET case PPP_IPCP: if (!ISSET(sp->pp_ncpflags, SPPP_NCP_IPCP)) { SPPP_LOG(sp, LOG_INFO, "reject IPCP packet " "because IPCP is disabled\n"); goto reject_protocol; } SPPP_UNLOCK(sp); if (sp->pp_phase == SPPP_PHASE_NETWORK) { sppp_cp_input(&ipcp, sp, m); /* already m_freem(m) */ } else { m_freem(m); } return; case PPP_IP: if (sp->scp[IDX_IPCP].state == STATE_OPENED) { sp->pp_last_activity = time_uptime; pktq = ip_pktq; rps_hash = atomic_load_relaxed(&sppp_pktq_rps_hash_p); } break; #endif #ifdef INET6 case PPP_IPV6CP: if (!ISSET(sp->pp_ncpflags, SPPP_NCP_IPV6CP)) { SPPP_LOG(sp, LOG_INFO, "reject IPv6CP packet " "because IPv6CP is disabled\n"); goto reject_protocol; } SPPP_UNLOCK(sp); if (sp->pp_phase == SPPP_PHASE_NETWORK) { sppp_cp_input(&ipv6cp, sp, m); /* already m_freem(m) */ } else { m_freem(m); } return; case PPP_IPV6: if (sp->scp[IDX_IPV6CP].state == STATE_OPENED) { sp->pp_last_activity = time_uptime; pktq = ip6_pktq; rps_hash = atomic_load_relaxed(&sppp_pktq_rps_hash_p); } break; #endif } if ((ifp->if_flags & IFF_UP) == 0 || pktq == NULL) { goto drop; } /* Check queue. */ const uint32_t hash = rps_hash ? pktq_rps_hash(&rps_hash, m) : 0; if (__predict_false(!pktq_enqueue(pktq, m, hash))) { goto drop; } SPPP_UNLOCK(sp); return; drop: if_statadd2(ifp, if_ierrors, 1, if_iqdrops, 1); m_freem(m); SPPP_UNLOCK(sp); return; } /* * Enqueue transmit packet. */ static int sppp_output(struct ifnet *ifp, struct mbuf *m, const struct sockaddr *dst, const struct rtentry *rt) { struct sppp *sp = (struct sppp *) ifp; struct ppp_header *h = NULL; #ifndef SPPPSUBR_MPSAFE struct ifqueue *ifq = NULL; /* XXX */ #endif int s, error = 0; uint16_t protocol; size_t pktlen; s = splnet(); SPPP_LOCK(sp, RW_READER); sp->pp_last_activity = time_uptime; if ((ifp->if_flags & IFF_UP) == 0 || (ifp->if_flags & (IFF_RUNNING | IFF_AUTO)) == 0) { SPPP_UNLOCK(sp); splx(s); m_freem(m); if_statinc(ifp, if_oerrors); return (ENETDOWN); } if ((ifp->if_flags & (IFF_RUNNING | IFF_AUTO)) == IFF_AUTO) { /* ignore packets that have no enabled NCP */ if ((dst->sa_family == AF_INET && !ISSET(sp->pp_ncpflags, SPPP_NCP_IPCP)) || (dst->sa_family == AF_INET6 && !ISSET(sp->pp_ncpflags, SPPP_NCP_IPV6CP))) { SPPP_UNLOCK(sp); splx(s); m_freem(m); if_statinc(ifp, if_oerrors); return (ENETDOWN); } /* * Interface is not yet running, but auto-dial. Need * to start LCP for it. */ ifp->if_flags |= IFF_RUNNING; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_open); } /* * If the queueing discipline needs packet classification, * do it before prepending link headers. */ IFQ_CLASSIFY(&ifp->if_snd, m, dst->sa_family); #ifdef INET if (dst->sa_family == AF_INET) { struct ip *ip = NULL; #ifndef SPPPSUBR_MPSAFE struct tcphdr *th = NULL; #endif if (m->m_len >= sizeof(struct ip)) { ip = mtod(m, struct ip *); #ifndef SPPPSUBR_MPSAFE if (ip->ip_p == IPPROTO_TCP && m->m_len >= sizeof(struct ip) + (ip->ip_hl << 2) + sizeof(struct tcphdr)) { th = (struct tcphdr *) ((char *)ip + (ip->ip_hl << 2)); } #endif } else ip = NULL; /* * When using dynamic local IP address assignment by using * 0.0.0.0 as a local address, the first TCP session will * not connect because the local TCP checksum is computed * using 0.0.0.0 which will later become our real IP address * so the TCP checksum computed at the remote end will * become invalid. So we * - don't let packets with src ip addr 0 thru * - we flag TCP packets with src ip 0 as an error */ if (ip && ip->ip_src.s_addr == INADDR_ANY) { uint8_t proto = ip->ip_p; SPPP_UNLOCK(sp); splx(s); m_freem(m); if (proto == IPPROTO_TCP) return (EADDRNOTAVAIL); else return (0); } #ifndef SPPPSUBR_MPSAFE /* * Put low delay, telnet, rlogin and ftp control packets * in front of the queue. */ if (!IF_QFULL(&sp->pp_fastq) && ((ip && (ip->ip_tos & IPTOS_LOWDELAY)) || (th && (INTERACTIVE(ntohs(th->th_sport)) || INTERACTIVE(ntohs(th->th_dport)))))) ifq = &sp->pp_fastq; #endif /* !SPPPSUBR_MPSAFE */ } #endif #ifdef INET6 if (dst->sa_family == AF_INET6) { /* XXX do something tricky here? */ } #endif if ((sp->pp_flags & PP_NOFRAMING) == 0) { /* * Prepend general data packet PPP header. For now, IP only. */ M_PREPEND(m, PPP_HEADER_LEN, M_DONTWAIT); if (! m) { SPPP_DLOG(sp, "no memory for transmit header\n"); if_statinc(ifp, if_oerrors); SPPP_UNLOCK(sp); splx(s); return (ENOBUFS); } /* * May want to check size of packet * (albeit due to the implementation it's always enough) */ h = mtod(m, struct ppp_header *); h->address = PPP_ALLSTATIONS; /* broadcast address */ h->control = PPP_UI; /* Unnumbered Info */ } switch (dst->sa_family) { #ifdef INET case AF_INET: /* Internet Protocol */ /* * Don't choke with an ENETDOWN early. It's * possible that we just started dialing out, * so don't drop the packet immediately. If * we notice that we run out of buffer space * below, we will however remember that we are * not ready to carry IP packets, and return * ENETDOWN, as opposed to ENOBUFS. */ protocol = htons(PPP_IP); if (sp->scp[IDX_IPCP].state != STATE_OPENED) { if (ifp->if_flags & IFF_AUTO) { error = ENETDOWN; } else { IF_DROP(&ifp->if_snd); SPPP_UNLOCK(sp); splx(s); m_freem(m); if_statinc(ifp, if_oerrors); return (ENETDOWN); } } break; #endif #ifdef INET6 case AF_INET6: /* Internet Protocol version 6 */ /* * Don't choke with an ENETDOWN early. It's * possible that we just started dialing out, * so don't drop the packet immediately. If * we notice that we run out of buffer space * below, we will however remember that we are * not ready to carry IP packets, and return * ENETDOWN, as opposed to ENOBUFS. */ protocol = htons(PPP_IPV6); if (sp->scp[IDX_IPV6CP].state != STATE_OPENED) { if (ifp->if_flags & IFF_AUTO) { error = ENETDOWN; } else { IF_DROP(&ifp->if_snd); SPPP_UNLOCK(sp); splx(s); m_freem(m); if_statinc(ifp, if_oerrors); return (ENETDOWN); } } break; #endif default: m_freem(m); if_statinc(ifp, if_oerrors); SPPP_UNLOCK(sp); splx(s); return (EAFNOSUPPORT); } if (sp->pp_flags & PP_NOFRAMING) { M_PREPEND(m, 2, M_DONTWAIT); if (m == NULL) { SPPP_DLOG(sp, "no memory for transmit header\n"); if_statinc(ifp, if_oerrors); SPPP_UNLOCK(sp); splx(s); return (ENOBUFS); } *mtod(m, uint16_t *) = protocol; } else { h->protocol = protocol; } pktlen = m->m_pkthdr.len; #ifdef SPPPSUBR_MPSAFE SPPP_UNLOCK(sp); error = if_transmit_lock(ifp, m); SPPP_LOCK(sp, RW_READER); if (error == 0) if_statadd(ifp, if_obytes, pktlen + sp->pp_framebytes); #else /* !SPPPSUBR_MPSAFE */ error = ifq_enqueue2(ifp, ifq, m); if (error == 0) { /* * Count output packets and bytes. * The packet length includes header + additional hardware * framing according to RFC 1333. */ if (!(ifp->if_flags & IFF_OACTIVE)) { SPPP_UNLOCK(sp); if_start_lock(ifp); SPPP_LOCK(sp, RW_READER); } if_statadd(ifp, if_obytes, pktlen + sp->pp_framebytes); } #endif /* !SPPPSUBR_MPSAFE */ SPPP_UNLOCK(sp); splx(s); return error; } void sppp_attach(struct ifnet *ifp) { struct sppp *sp = (struct sppp *) ifp; char xnamebuf[MAXCOMLEN]; /* Initialize keepalive handler. */ if (! spppq) { callout_init(&keepalive_ch, CALLOUT_MPSAFE); callout_reset(&keepalive_ch, hz * SPPP_KEEPALIVE_INTERVAL, sppp_keepalive, NULL); } if (! spppq_lock) spppq_lock = mutex_obj_alloc(MUTEX_DEFAULT, IPL_SOFTNET); sp->pp_if.if_type = IFT_PPP; sp->pp_if.if_output = sppp_output; IFQ_SET_MAXLEN(&sp->pp_fastq, 32); IFQ_LOCK_INIT(&sp->pp_fastq); IFQ_SET_MAXLEN(&sp->pp_cpq, 20); sp->pp_loopcnt = 0; sp->pp_alivecnt = 0; sp->pp_alive_interval = SPPP_ALIVE_INTERVAL; sp->pp_last_activity = 0; sp->pp_last_receive = 0; sp->pp_maxalive = DEFAULT_MAXALIVECNT; sp->pp_max_noreceive = SPPP_NORECV_TIME; sp->pp_idle_timeout = 0; sp->pp_max_auth_fail = DEFAULT_MAX_AUTH_FAILURES; sp->pp_phase = SPPP_PHASE_DEAD; sp->pp_up = sppp_notify_up; sp->pp_down = sppp_notify_down; sp->pp_ncpflags = SPPP_NCP_IPCP | SPPP_NCP_IPV6CP; #ifdef SPPP_IFDOWN_RECONNECT sp->pp_flags |= PP_LOOPBACK_IFDOWN | PP_KEEPALIVE_IFDOWN; #endif sppp_wq_set(&sp->work_ifdown, sppp_ifdown, NULL); memset(sp->scp, 0, sizeof(sp->scp)); rw_init(&sp->pp_lock); if_alloc_sadl(ifp); /* Lets not beat about the bush, we know we're down. */ if_link_state_change(ifp, LINK_STATE_DOWN); snprintf(xnamebuf, sizeof(xnamebuf), "%s.wq_cp", ifp->if_xname); sp->wq_cp = sppp_wq_create(sp, xnamebuf, PRI_SOFTNET, IPL_SOFTNET, WQ_MPSAFE); memset(&sp->myauth, 0, sizeof sp->myauth); memset(&sp->hisauth, 0, sizeof sp->hisauth); SPPP_LOCK(sp, RW_WRITER); sppp_lcp_init(sp); sppp_ipcp_init(sp); sppp_ipv6cp_init(sp); sppp_pap_init(sp); sppp_chap_init(sp); SPPP_UNLOCK(sp); SPPPQ_LOCK(); /* Insert new entry into the keepalive list. */ sp->pp_next = spppq; spppq = sp; SPPPQ_UNLOCK(); } void sppp_detach(struct ifnet *ifp) { struct sppp **q, *p, *sp = (struct sppp *) ifp; /* Remove the entry from the keepalive list. */ SPPPQ_LOCK(); for (q = &spppq; (p = *q); q = &p->pp_next) if (p == sp) { *q = p->pp_next; break; } SPPPQ_UNLOCK(); if (! spppq) { /* Stop keepalive handler. */ callout_stop(&keepalive_ch); mutex_obj_free(spppq_lock); spppq_lock = NULL; } sppp_cp_fini(&lcp, sp); sppp_cp_fini(&ipcp, sp); sppp_cp_fini(&pap, sp); sppp_cp_fini(&chap, sp); #ifdef INET6 sppp_cp_fini(&ipv6cp, sp); #endif sppp_wq_destroy(sp, sp->wq_cp); /* free authentication info */ if (sp->myauth.name) free(sp->myauth.name, M_DEVBUF); if (sp->myauth.secret) free(sp->myauth.secret, M_DEVBUF); if (sp->hisauth.name) free(sp->hisauth.name, M_DEVBUF); if (sp->hisauth.secret) free(sp->hisauth.secret, M_DEVBUF); IFQ_LOCK_DESTROY(&sp->pp_fastq); rw_destroy(&sp->pp_lock); } /* * Flush the interface output queue. */ void sppp_flush(struct ifnet *ifp) { struct sppp *sp = (struct sppp *) ifp; SPPP_LOCK(sp, RW_WRITER); IFQ_PURGE(&sp->pp_if.if_snd); IF_PURGE(&sp->pp_fastq); IF_PURGE(&sp->pp_cpq); SPPP_UNLOCK(sp); } /* * Check if the output queue is empty. */ int sppp_isempty(struct ifnet *ifp) { struct sppp *sp = (struct sppp *) ifp; int empty, s; s = splnet(); SPPP_LOCK(sp, RW_READER); empty = IF_IS_EMPTY(&sp->pp_fastq) && IF_IS_EMPTY(&sp->pp_cpq) && IFQ_IS_EMPTY(&sp->pp_if.if_snd); SPPP_UNLOCK(sp); splx(s); return (empty); } /* * Get next packet to send. */ struct mbuf * sppp_dequeue(struct ifnet *ifp) { struct sppp *sp = (struct sppp *) ifp; struct mbuf *m; int s; s = splnet(); SPPP_LOCK(sp, RW_WRITER); /* * Process only the control protocol queue until we have at * least one NCP open. * * Do always serve all three queues in Cisco mode. */ IF_DEQUEUE(&sp->pp_cpq, m); if (m == NULL && sppp_cp_check(sp, CP_NCP)) { IF_DEQUEUE(&sp->pp_fastq, m); if (m == NULL) IFQ_DEQUEUE(&sp->pp_if.if_snd, m); } SPPP_UNLOCK(sp); splx(s); return m; } /* * Process an ioctl request. Called on low priority level. */ int sppp_ioctl(struct ifnet *ifp, u_long cmd, void *data) { struct lwp *l = curlwp; /* XXX */ struct ifreq *ifr = (struct ifreq *) data; struct ifaddr *ifa = (struct ifaddr *) data; struct sppp *sp = (struct sppp *) ifp; int s, error=0, going_up, going_down; u_short newmode; u_long lcp_mru; s = splnet(); switch (cmd) { case SIOCINITIFADDR: ifa->ifa_rtrequest = p2p_rtrequest; break; case SIOCSIFFLAGS: if ((error = ifioctl_common(ifp, cmd, data)) != 0) break; SPPP_LOCK(sp, RW_WRITER); going_up = ifp->if_flags & IFF_UP && (ifp->if_flags & IFF_RUNNING) == 0; going_down = (ifp->if_flags & IFF_UP) == 0 && ifp->if_flags & IFF_RUNNING; newmode = ifp->if_flags & (IFF_AUTO | IFF_PASSIVE); if (newmode == (IFF_AUTO | IFF_PASSIVE)) { /* sanity */ newmode = IFF_PASSIVE; ifp->if_flags &= ~IFF_AUTO; } if (ifp->if_flags & IFF_UP) { sp->pp_flags |= PP_ADMIN_UP; } else { sp->pp_flags &= ~PP_ADMIN_UP; } if (going_up || going_down) { sp->lcp.reestablish = false; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); } if (going_up && newmode == 0) { /* neither auto-dial nor passive */ ifp->if_flags |= IFF_RUNNING; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_open); } else if (going_down) { SPPP_UNLOCK(sp); sppp_flush(ifp); SPPP_LOCK(sp, RW_WRITER); ifp->if_flags &= ~IFF_RUNNING; } SPPP_UNLOCK(sp); break; case SIOCSIFMTU: if (ifr->ifr_mtu < PPP_MINMRU || ifr->ifr_mtu > PP_MTU) { error = EINVAL; break; } error = ifioctl_common(ifp, cmd, data); if (error == ENETRESET) error = 0; SPPP_LOCK(sp, RW_WRITER); lcp_mru = sp->lcp.mru; if (ifp->if_mtu < PP_MTU) { sp->lcp.mru = ifp->if_mtu; } else { sp->lcp.mru = PP_MTU; } if (lcp_mru != sp->lcp.mru) SET(sp->lcp.opts, SPPP_LCP_OPT_MRU); if (sp->scp[IDX_LCP].state == STATE_OPENED && ifp->if_mtu > sp->lcp.their_mru) { sp->pp_saved_mtu = ifp->if_mtu; ifp->if_mtu = sp->lcp.their_mru; SPPP_DLOG(sp, "setting MTU " "from %"PRIu64" bytes to %"PRIu64" bytes\n", sp->pp_saved_mtu, ifp->if_mtu); } SPPP_UNLOCK(sp); break; case SIOCGIFMTU: if ((error = ifioctl_common(ifp, cmd, data)) == ENETRESET) error = 0; break; case SIOCADDMULTI: case SIOCDELMULTI: break; case SPPPSETAUTHCFG: case SPPPSETLCPCFG: case SPPPSETNCPCFG: case SPPPSETIDLETO: case SPPPSETAUTHFAILURE: case SPPPSETDNSOPTS: case SPPPSETKEEPALIVE: #if defined(COMPAT_50) || defined(MODULAR) case __SPPPSETIDLETO50: case __SPPPSETKEEPALIVE50: #endif /* COMPAT_50 || MODULAR */ error = kauth_authorize_network(l->l_cred, KAUTH_NETWORK_INTERFACE, KAUTH_REQ_NETWORK_INTERFACE_SETPRIV, ifp, (void *)cmd, NULL); if (error) break; error = sppp_params(sp, cmd, data); break; case SPPPGETAUTHCFG: case SPPPGETLCPCFG: case SPPPGETNCPCFG: case SPPPGETAUTHFAILURES: error = kauth_authorize_network(l->l_cred, KAUTH_NETWORK_INTERFACE, KAUTH_REQ_NETWORK_INTERFACE_GETPRIV, ifp, (void *)cmd, NULL); if (error) break; error = sppp_params(sp, cmd, data); break; case SPPPGETSTATUS: case SPPPGETSTATUSNCP: case SPPPGETIDLETO: case SPPPGETDNSOPTS: case SPPPGETDNSADDRS: case SPPPGETKEEPALIVE: #if defined(COMPAT_50) || defined(MODULAR) case __SPPPGETIDLETO50: case __SPPPGETKEEPALIVE50: #endif /* COMPAT_50 || MODULAR */ case SPPPGETLCPSTATUS: case SPPPGETIPCPSTATUS: case SPPPGETIPV6CPSTATUS: error = sppp_params(sp, cmd, data); break; default: error = ifioctl_common(ifp, cmd, data); break; } splx(s); return (error); } /* * PPP protocol implementation. */ /* * Send PPP control protocol packet. */ static void sppp_cp_send(struct sppp *sp, u_short proto, u_char type, u_char ident, u_short len, void *data) { struct ifnet *ifp; struct lcp_header *lh; struct mbuf *m; size_t pkthdrlen; KASSERT(SPPP_WLOCKED(sp)); ifp = &sp->pp_if; pkthdrlen = (sp->pp_flags & PP_NOFRAMING) ? 2 : PPP_HEADER_LEN; if (len > MHLEN - pkthdrlen - LCP_HEADER_LEN) len = MHLEN - pkthdrlen - LCP_HEADER_LEN; MGETHDR(m, M_DONTWAIT, MT_DATA); if (! m) { return; } m->m_pkthdr.len = m->m_len = pkthdrlen + LCP_HEADER_LEN + len; m_reset_rcvif(m); if (sp->pp_flags & PP_NOFRAMING) { *mtod(m, uint16_t *) = htons(proto); lh = (struct lcp_header *)(mtod(m, uint8_t *) + 2); } else { struct ppp_header *h; h = mtod(m, struct ppp_header *); h->address = PPP_ALLSTATIONS; /* broadcast address */ h->control = PPP_UI; /* Unnumbered Info */ h->protocol = htons(proto); /* Link Control Protocol */ lh = (struct lcp_header *)(h + 1); } lh->type = type; lh->ident = ident; lh->len = htons(LCP_HEADER_LEN + len); if (len) memcpy(lh + 1, data, len); if (sppp_debug_enabled(sp)) { char pbuf[SPPP_PROTO_NAMELEN]; char tbuf[SPPP_CPTYPE_NAMELEN]; const char *pname, *cpname; pname = sppp_proto_name(pbuf, sizeof(pbuf), proto); cpname = sppp_cp_type_name(tbuf, sizeof(tbuf), lh->type); SPPP_LOG(sp, LOG_DEBUG, "%s output <%s id=0x%x len=%d", pname, cpname, lh->ident, ntohs(lh->len)); if (len) sppp_print_bytes((u_char *)(lh + 1), len); addlog(">\n"); } if (IF_QFULL(&sp->pp_cpq)) { IF_DROP(&sp->pp_fastq); IF_DROP(&ifp->if_snd); m_freem(m); if_statinc(ifp, if_oerrors); return; } if_statadd(ifp, if_obytes, m->m_pkthdr.len + sp->pp_framebytes); IF_ENQUEUE(&sp->pp_cpq, m); if (! (ifp->if_flags & IFF_OACTIVE)) { SPPP_UNLOCK(sp); if_start_lock(ifp); SPPP_LOCK(sp, RW_WRITER); } } static void sppp_cp_to_lcp(void *xsp) { struct sppp *sp = xsp; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_to); } static void sppp_cp_to_ipcp(void *xsp) { struct sppp *sp = xsp; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_IPCP].work_to); } static void sppp_cp_to_ipv6cp(void *xsp) { struct sppp *sp = xsp; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_IPV6CP].work_to); } static void sppp_cp_to_pap(void *xsp) { struct sppp *sp = xsp; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_PAP].work_to); } static void sppp_cp_to_chap(void *xsp) { struct sppp *sp = xsp; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_CHAP].work_to); } static void sppp_cp_init(const struct cp *cp, struct sppp *sp) { struct sppp_cp *scp; typedef void (*sppp_co_cb_t)(void *); static const sppp_co_cb_t to_cb[IDX_COUNT] = { [IDX_LCP] = sppp_cp_to_lcp, [IDX_IPCP] = sppp_cp_to_ipcp, [IDX_IPV6CP] = sppp_cp_to_ipv6cp, [IDX_PAP] = sppp_cp_to_pap, [IDX_CHAP] = sppp_cp_to_chap, }; scp = &sp->scp[cp->protoidx]; scp->state = STATE_INITIAL; scp->fail_counter = 0; scp->seq = 0; scp->rseq = 0; SPPP_WQ_SET(&scp->work_up, cp->Up, cp); SPPP_WQ_SET(&scp->work_down, cp->Down, cp); SPPP_WQ_SET(&scp->work_open, cp->Open, cp); SPPP_WQ_SET(&scp->work_close, cp->Close, cp); SPPP_WQ_SET(&scp->work_to, cp->TO, cp); SPPP_WQ_SET(&scp->work_rcr, sppp_rcr_event, cp); SPPP_WQ_SET(&scp->work_rca, sppp_rca_event, cp); SPPP_WQ_SET(&scp->work_rcn, sppp_rcn_event, cp); SPPP_WQ_SET(&scp->work_rtr, sppp_rtr_event, cp); SPPP_WQ_SET(&scp->work_rta, sppp_rta_event, cp); SPPP_WQ_SET(&scp->work_rxj, sppp_rxj_event, cp); callout_init(&scp->ch, CALLOUT_MPSAFE); callout_setfunc(&scp->ch, to_cb[cp->protoidx], sp); } static void sppp_cp_fini(const struct cp *cp, struct sppp *sp) { struct sppp_cp *scp; scp = &sp->scp[cp->protoidx]; sppp_wq_wait(sp->wq_cp, &scp->work_up); sppp_wq_wait(sp->wq_cp, &scp->work_down); sppp_wq_wait(sp->wq_cp, &scp->work_open); sppp_wq_wait(sp->wq_cp, &scp->work_close); sppp_wq_wait(sp->wq_cp, &scp->work_to); sppp_wq_wait(sp->wq_cp, &scp->work_rcr); sppp_wq_wait(sp->wq_cp, &scp->work_rca); sppp_wq_wait(sp->wq_cp, &scp->work_rcn); sppp_wq_wait(sp->wq_cp, &scp->work_rtr); sppp_wq_wait(sp->wq_cp, &scp->work_rta); sppp_wq_wait(sp->wq_cp, &scp->work_rxj); callout_halt(&scp->ch, NULL); callout_destroy(&scp->ch); if (scp->mbuf_confreq != NULL) { m_freem(scp->mbuf_confreq); scp->mbuf_confreq = NULL; } if (scp->mbuf_confnak != NULL) { m_freem(scp->mbuf_confnak); scp->mbuf_confnak = NULL; } } /* * Handle incoming PPP control protocol packets. */ static void sppp_cp_input(const struct cp *cp, struct sppp *sp, struct mbuf *m) { struct ifnet *ifp; struct lcp_header *h; struct sppp_cp *scp; int printlen, len = m->m_pkthdr.len; u_char *p; uint32_t u32; char tbuf[SPPP_CPTYPE_NAMELEN]; const char *cpname; bool debug; SPPP_LOCK(sp, RW_WRITER); ifp = &sp->pp_if; debug = sppp_debug_enabled(sp); scp = &sp->scp[cp->protoidx]; if (len < 4) { SPPP_DLOG(sp, "%s invalid packet length: %d bytes\n", cp->name, len); goto out; } h = mtod(m, struct lcp_header *); if (debug) { printlen = ntohs(h->len); cpname = sppp_cp_type_name(tbuf, sizeof(tbuf), h->type); SPPP_LOG(sp, LOG_DEBUG, "%s input(%s): <%s id=0x%x len=%d", cp->name, sppp_state_name(scp->state), cpname, h->ident, printlen); if (len < printlen) printlen = len; if (printlen > 4) sppp_print_bytes((u_char *)(h + 1), printlen - 4); addlog(">\n"); } if (len > ntohs(h->len)) len = ntohs(h->len); p = (u_char *)(h + 1); switch (h->type) { case CONF_REQ: if (len < 4) { SPPP_DLOG(sp,"%s invalid conf-req length %d\n", cp->name, len); if_statinc(ifp, if_ierrors); break; } scp->rcr_type = CP_RCR_NONE; scp->rconfid = h->ident; if (scp->mbuf_confreq != NULL) { m_freem(scp->mbuf_confreq); } scp->mbuf_confreq = m; m = NULL; sppp_wq_add(sp->wq_cp, &scp->work_rcr); break; case CONF_ACK: if (h->ident != scp->confid) { SPPP_DLOG(sp, "%s id mismatch 0x%x != 0x%x\n", cp->name, h->ident, scp->confid); if_statinc(ifp, if_ierrors); break; } sppp_wq_add(sp->wq_cp, &scp->work_rca); break; case CONF_NAK: case CONF_REJ: if (h->ident != scp->confid) { SPPP_DLOG(sp, "%s id mismatch 0x%x != 0x%x\n", cp->name, h->ident, scp->confid); if_statinc(ifp, if_ierrors); break; } if (scp->mbuf_confnak) { m_freem(scp->mbuf_confnak); } scp->mbuf_confnak = m; m = NULL; sppp_wq_add(sp->wq_cp, &scp->work_rcn); break; case TERM_REQ: scp->rseq = h->ident; sppp_wq_add(sp->wq_cp, &scp->work_rtr); break; case TERM_ACK: if (h->ident != scp->confid && h->ident != scp->seq) { SPPP_DLOG(sp, "%s id mismatch " "0x%x != 0x%x and 0x%x != %0lx\n", cp->name, h->ident, scp->confid, h->ident, scp->seq); if_statinc(ifp, if_ierrors); break; } sppp_wq_add(sp->wq_cp, &scp->work_rta); break; case CODE_REJ: /* XXX catastrophic rejects (RXJ-) aren't handled yet. */ cpname = sppp_cp_type_name(tbuf, sizeof(tbuf), h->type); SPPP_LOG(sp, LOG_INFO, "%s: ignoring RXJ (%s) for code ?, " "danger will robinson\n", cp->name, cpname); sppp_wq_add(sp->wq_cp, &scp->work_rxj); break; case PROTO_REJ: { int catastrophic; const struct cp *upper; int i; uint16_t proto; catastrophic = 0; upper = NULL; proto = p[0] << 8 | p[1]; for (i = 0; i < IDX_COUNT; i++) { if (cps[i]->proto == proto) { upper = cps[i]; break; } } if (upper == NULL) catastrophic++; if (debug) { cpname = sppp_cp_type_name(tbuf, sizeof(tbuf), h->type); SPPP_LOG(sp, LOG_INFO, "%s: RXJ%c (%s) for proto 0x%x (%s/%s)\n", cp->name, catastrophic ? '-' : '+', cpname, proto, upper ? upper->name : "unknown", upper ? sppp_state_name(sp->scp[upper->protoidx].state) : "?"); } /* * if we got RXJ+ against conf-req, the peer does not implement * this particular protocol type. terminate the protocol. */ if (upper && !catastrophic) { if (sp->scp[upper->protoidx].state == STATE_REQ_SENT) { sppp_wq_add(sp->wq_cp, &sp->scp[upper->protoidx].work_close); break; } } sppp_wq_add(sp->wq_cp, &scp->work_rxj); break; } case DISC_REQ: if (cp->proto != PPP_LCP) goto illegal; /* Discard the packet. */ break; case ECHO_REQ: if (cp->proto != PPP_LCP) goto illegal; if (scp->state != STATE_OPENED) { SPPP_DLOG(sp, "lcp echo req but lcp closed\n"); if_statinc(ifp, if_ierrors); break; } if (len < 8) { SPPP_DLOG(sp, "invalid lcp echo request " "packet length: %d bytes\n", len); break; } memcpy(&u32, h + 1, sizeof u32); if (ntohl(u32) == sp->lcp.magic) { /* Line loopback mode detected. */ SPPP_DLOG(sp, "loopback\n"); if (sp->pp_flags & PP_LOOPBACK_IFDOWN) { sp->pp_flags |= PP_LOOPBACK; sppp_wq_add(sp->wq_cp, &sp->work_ifdown); } /* Shut down the PPP link. */ sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_open); break; } u32 = htonl(sp->lcp.magic); memcpy(h + 1, &u32, sizeof u32); SPPP_DLOG(sp, "got lcp echo req, sending echo rep\n"); sppp_cp_send(sp, PPP_LCP, ECHO_REPLY, h->ident, len - 4, h + 1); break; case ECHO_REPLY: if (cp->proto != PPP_LCP) goto illegal; if (h->ident != sp->lcp.echoid) { if_statinc(ifp, if_ierrors); break; } if (len < 8) { SPPP_DLOG(sp, "lcp invalid echo reply " "packet length: %d bytes\n", len); break; } SPPP_DLOG(sp, "lcp got echo rep\n"); memcpy(&u32, h + 1, sizeof u32); if (ntohl(u32) != sp->lcp.magic) sp->pp_alivecnt = 0; break; default: /* Unknown packet type -- send Code-Reject packet. */ illegal: SPPP_DLOG(sp, "%s send code-rej for 0x%x\n", cp->name, h->type); sppp_cp_send(sp, cp->proto, CODE_REJ, ++scp->seq, m->m_pkthdr.len, h); if_statinc(ifp, if_ierrors); } out: SPPP_UNLOCK(sp); if (m != NULL) m_freem(m); } /* * The generic part of all Up/Down/Open/Close/TO event handlers. * Basically, the state transition handling in the automaton. */ static void sppp_up_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); if ((cp->flags & CP_AUTH) != 0 && sppp_auth_role(cp, sp) == SPPP_AUTH_NOROLE) return; SPPP_DLOG(sp, "%s up(%s)\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); switch (sp->scp[cp->protoidx].state) { case STATE_INITIAL: sppp_cp_change_state(cp, sp, STATE_CLOSED); break; case STATE_STARTING: sp->scp[cp->protoidx].rst_counter = sp->lcp.max_configure; (cp->scr)(sp); sppp_cp_change_state(cp, sp, STATE_REQ_SENT); break; default: SPPP_LOG(sp, LOG_DEBUG, "%s illegal up in state %s\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); } } static void sppp_down_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); if ((cp->flags & CP_AUTH) != 0 && sppp_auth_role(cp, sp) == SPPP_AUTH_NOROLE) return; SPPP_DLOG(sp, "%s down(%s)\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); switch (sp->scp[cp->protoidx].state) { case STATE_CLOSED: case STATE_CLOSING: sppp_cp_change_state(cp, sp, STATE_INITIAL); break; case STATE_STOPPED: (cp->tls)(cp, sp); /* fall through */ case STATE_STOPPING: case STATE_REQ_SENT: case STATE_ACK_RCVD: case STATE_ACK_SENT: sppp_cp_change_state(cp, sp, STATE_STARTING); break; case STATE_OPENED: (cp->tld)(sp); sppp_cp_change_state(cp, sp, STATE_STARTING); break; default: /* * a down event may be caused regardless * of state just in LCP case. */ if (cp->proto == PPP_LCP) break; SPPP_LOG(sp, LOG_DEBUG, "%s illegal down in state %s\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); } } static void sppp_open_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); if ((cp->flags & CP_AUTH) != 0 && sppp_auth_role(cp, sp) == SPPP_AUTH_NOROLE) return; SPPP_DLOG(sp, "%s open(%s)\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); switch (sp->scp[cp->protoidx].state) { case STATE_INITIAL: sppp_cp_change_state(cp, sp, STATE_STARTING); (cp->tls)(cp, sp); break; case STATE_STARTING: break; case STATE_CLOSED: sp->scp[cp->protoidx].rst_counter = sp->lcp.max_configure; sp->lcp.protos |= (1 << cp->protoidx); (cp->scr)(sp); sppp_cp_change_state(cp, sp, STATE_REQ_SENT); break; case STATE_STOPPED: case STATE_STOPPING: case STATE_REQ_SENT: case STATE_ACK_RCVD: case STATE_ACK_SENT: case STATE_OPENED: break; case STATE_CLOSING: sppp_cp_change_state(cp, sp, STATE_STOPPING); break; } } static void sppp_close_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); if ((cp->flags & CP_AUTH) != 0 && sppp_auth_role(cp, sp) == SPPP_AUTH_NOROLE) return; SPPP_DLOG(sp, "%s close(%s)\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); switch (sp->scp[cp->protoidx].state) { case STATE_INITIAL: case STATE_CLOSED: case STATE_CLOSING: break; case STATE_STARTING: sppp_cp_change_state(cp, sp, STATE_INITIAL); (cp->tlf)(cp, sp); break; case STATE_STOPPED: sppp_cp_change_state(cp, sp, STATE_CLOSED); break; case STATE_STOPPING: sppp_cp_change_state(cp, sp, STATE_CLOSING); break; case STATE_OPENED: (cp->tld)(sp); /* fall through */ case STATE_REQ_SENT: case STATE_ACK_RCVD: case STATE_ACK_SENT: sp->scp[cp->protoidx].rst_counter = sp->lcp.max_terminate; if ((cp->flags & CP_AUTH) == 0) { sppp_cp_send(sp, cp->proto, TERM_REQ, ++sp->scp[cp->protoidx].seq, 0, 0); } sppp_cp_change_state(cp, sp, STATE_CLOSING); break; } } static void sppp_to_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; int s; KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); s = splnet(); SPPP_DLOG(sp, "%s TO(%s) rst_counter = %d\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state), sp->scp[cp->protoidx].rst_counter); if (--sp->scp[cp->protoidx].rst_counter < 0) /* TO- event */ switch (sp->scp[cp->protoidx].state) { case STATE_CLOSING: sppp_cp_change_state(cp, sp, STATE_CLOSED); (cp->tlf)(cp, sp); break; case STATE_STOPPING: sppp_cp_change_state(cp, sp, STATE_STOPPED); (cp->tlf)(cp, sp); break; case STATE_REQ_SENT: case STATE_ACK_RCVD: case STATE_ACK_SENT: sppp_cp_change_state(cp, sp, STATE_STOPPED); (cp->tlf)(cp, sp); break; } else /* TO+ event */ switch (sp->scp[cp->protoidx].state) { case STATE_CLOSING: case STATE_STOPPING: if ((cp->flags & CP_AUTH) == 0) { sppp_cp_send(sp, cp->proto, TERM_REQ, ++sp->scp[cp->protoidx].seq, 0, 0); } callout_schedule(&sp->scp[cp->protoidx].ch, sp->lcp.timeout); break; case STATE_REQ_SENT: case STATE_ACK_RCVD: (cp->scr)(sp); /* sppp_cp_change_state() will restart the timer */ sppp_cp_change_state(cp, sp, STATE_REQ_SENT); break; case STATE_ACK_SENT: (cp->scr)(sp); callout_schedule(&sp->scp[cp->protoidx].ch, sp->lcp.timeout); break; } splx(s); } static void sppp_rcr_update_state(const struct cp *cp, struct sppp *sp, enum cp_rcr_type type, uint8_t ident, size_t msglen, void *msg) { struct ifnet *ifp; u_char ctype; ifp = &sp->pp_if; if (type == CP_RCR_ERR) { /* parse error, shut down */ sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_open); } else if (type == CP_RCR_ACK) { /* RCR+ event */ ctype = CONF_ACK; switch (sp->scp[cp->protoidx].state) { case STATE_OPENED: sppp_cp_change_state(cp, sp, STATE_ACK_SENT); cp->tld(sp); cp->scr(sp); cp->screply(cp, sp, ctype, ident, msglen, msg); break; case STATE_REQ_SENT: sppp_cp_change_state(cp, sp, STATE_ACK_SENT); /* fall through */ case STATE_ACK_SENT: cp->screply(cp, sp, ctype, ident, msglen, msg); break; case STATE_STOPPED: sppp_cp_change_state(cp, sp, STATE_ACK_SENT); cp->scr(sp); cp->screply(cp, sp, ctype, ident, msglen, msg); break; case STATE_ACK_RCVD: sppp_cp_change_state(cp, sp, STATE_OPENED); SPPP_DLOG(sp, "%s tlu\n", cp->name); cp->tlu(sp); cp->screply(cp, sp, ctype, ident, msglen, msg); break; case STATE_CLOSING: case STATE_STOPPING: break; case STATE_CLOSED: if ((cp->flags & CP_AUTH) == 0) { sppp_cp_send(sp, cp->proto, TERM_ACK, ident, 0, 0); } break; default: SPPP_LOG(sp, LOG_DEBUG, "%s illegal RCR+ in state %s\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); if_statinc(ifp, if_ierrors); } } else if (type == CP_RCR_NAK || type == CP_RCR_REJ) { ctype = type == CP_RCR_NAK ? CONF_NAK : CONF_REJ; /* RCR- event */ switch (sp->scp[cp->protoidx].state) { case STATE_OPENED: sppp_cp_change_state(cp, sp, STATE_REQ_SENT); cp->tld(sp); cp->scr(sp); cp->screply(cp, sp, ctype, ident, msglen, msg); break; case STATE_ACK_SENT: sppp_cp_change_state(cp, sp, STATE_REQ_SENT); /* fall through */ case STATE_REQ_SENT: cp->screply(cp, sp, ctype, ident, msglen, msg); break; case STATE_STOPPED: sppp_cp_change_state(cp, sp, STATE_REQ_SENT); cp->scr(sp); cp->screply(cp, sp, ctype, ident, msglen, msg); break; case STATE_ACK_RCVD: sppp_cp_change_state(cp, sp, STATE_ACK_RCVD); cp->screply(cp, sp, ctype, ident, msglen, msg); break; case STATE_CLOSING: case STATE_STOPPING: break; case STATE_CLOSED: sppp_cp_change_state(cp, sp, STATE_CLOSED); if ((cp->flags & CP_AUTH) == 0) { sppp_cp_send(sp, cp->proto, TERM_ACK, ident, 0, 0); } break; default: SPPP_LOG(sp, LOG_DEBUG, "%s illegal RCR- in state %s\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); if_statinc(ifp, if_ierrors); } } } static void sppp_rcr_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; struct sppp_cp *scp; struct lcp_header *h; struct mbuf *m; enum cp_rcr_type type; size_t len; uint8_t *buf; size_t blen, rlen; uint8_t ident; KASSERT(!cpu_softintr_p()); scp = &sp->scp[cp->protoidx]; if (cp->parse_confreq != NULL) { m = scp->mbuf_confreq; if (m == NULL) return; scp->mbuf_confreq = NULL; h = mtod(m, struct lcp_header *); if (h->type != CONF_REQ) { m_freem(m); return; } ident = h->ident; len = MIN(m->m_pkthdr.len, ntohs(h->len)); type = (cp->parse_confreq)(sp, h, len, &buf, &blen, &rlen); m_freem(m); } else { /* mbuf_cofreq is already parsed and freed */ type = scp->rcr_type; ident = scp->rconfid; buf = NULL; blen = rlen = 0; } sppp_rcr_update_state(cp, sp, type, ident, rlen, (void *)buf); if (buf != NULL) kmem_free(buf, blen); } static void sppp_rca_event(struct sppp *sp, void *xcp) { struct ifnet *ifp; const struct cp *cp = xcp; KASSERT(!cpu_softintr_p()); ifp = &sp->pp_if; switch (sp->scp[cp->protoidx].state) { case STATE_CLOSED: case STATE_STOPPED: if ((cp->flags & CP_AUTH) == 0) { sppp_cp_send(sp, cp->proto, TERM_ACK, sp->scp[cp->protoidx].rconfid, 0, 0); } break; case STATE_CLOSING: case STATE_STOPPING: break; case STATE_REQ_SENT: sp->scp[cp->protoidx].rst_counter = sp->lcp.max_configure; sppp_cp_change_state(cp, sp, STATE_ACK_RCVD); break; case STATE_OPENED: (cp->tld)(sp); /* fall through */ case STATE_ACK_RCVD: (cp->scr)(sp); sppp_cp_change_state(cp, sp, STATE_REQ_SENT); break; case STATE_ACK_SENT: sppp_cp_change_state(cp, sp, STATE_OPENED); sp->scp[cp->protoidx].rst_counter = sp->lcp.max_configure; SPPP_DLOG(sp, "%s tlu\n", cp->name); (cp->tlu)(sp); break; default: SPPP_LOG(sp, LOG_DEBUG, "%s illegal RCA in state %s\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); if_statinc(ifp, if_ierrors); } } static void sppp_rcn_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; struct sppp_cp *scp; struct lcp_header *h; struct mbuf *m; struct ifnet *ifp = &sp->pp_if; size_t len; KASSERT(!cpu_softintr_p()); scp = &sp->scp[cp->protoidx]; m = scp->mbuf_confnak; if (m == NULL) return; scp->mbuf_confnak = NULL; h = mtod(m, struct lcp_header *); len = MIN(m->m_pkthdr.len, ntohs(h->len)); switch (h->type) { case CONF_NAK: (cp->parse_confnak)(sp, h, len); break; case CONF_REJ: (cp->parse_confrej)(sp, h, len); break; default: m_freem(m); return; } m_freem(m); switch (scp->state) { case STATE_CLOSED: case STATE_STOPPED: if ((cp->flags & CP_AUTH) == 0) { sppp_cp_send(sp, cp->proto, TERM_ACK, scp->rconfid, 0, 0); } break; case STATE_REQ_SENT: case STATE_ACK_SENT: scp->rst_counter = sp->lcp.max_configure; (cp->scr)(sp); break; case STATE_OPENED: (cp->tld)(sp); /* fall through */ case STATE_ACK_RCVD: sppp_cp_change_state(cp, sp, STATE_ACK_SENT); (cp->scr)(sp); break; case STATE_CLOSING: case STATE_STOPPING: break; default: SPPP_LOG(sp, LOG_DEBUG, "%s illegal RCN in state %s\n", cp->name, sppp_state_name(scp->state)); if_statinc(ifp, if_ierrors); } } static void sppp_rtr_event(struct sppp *sp, void *xcp) { struct ifnet *ifp; const struct cp *cp = xcp; KASSERT(!cpu_softintr_p()); ifp = &sp->pp_if; switch (sp->scp[cp->protoidx].state) { case STATE_ACK_RCVD: case STATE_ACK_SENT: sppp_cp_change_state(cp, sp, STATE_REQ_SENT); break; case STATE_CLOSED: case STATE_STOPPED: case STATE_CLOSING: case STATE_STOPPING: case STATE_REQ_SENT: break; case STATE_OPENED: (cp->tld)(sp); sp->scp[cp->protoidx].rst_counter = 0; sppp_cp_change_state(cp, sp, STATE_STOPPING); break; default: SPPP_LOG(sp, LOG_DEBUG, "%s illegal RTR in state %s\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); if_statinc(ifp, if_ierrors); return; } /* Send Terminate-Ack packet. */ SPPP_DLOG(sp, "%s send terminate-ack\n", cp->name); if ((cp->flags & CP_AUTH) == 0) { sppp_cp_send(sp, cp->proto, TERM_ACK, sp->scp[cp->protoidx].rseq, 0, 0); } } static void sppp_rta_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; struct ifnet *ifp = &sp->pp_if; KASSERT(!cpu_softintr_p()); switch (sp->scp[cp->protoidx].state) { case STATE_CLOSED: case STATE_STOPPED: case STATE_REQ_SENT: case STATE_ACK_SENT: break; case STATE_CLOSING: sppp_cp_change_state(cp, sp, STATE_CLOSED); (cp->tlf)(cp, sp); break; case STATE_STOPPING: sppp_cp_change_state(cp, sp, STATE_STOPPED); (cp->tlf)(cp, sp); break; case STATE_ACK_RCVD: sppp_cp_change_state(cp, sp, STATE_REQ_SENT); break; case STATE_OPENED: (cp->tld)(sp); (cp->scr)(sp); sppp_cp_change_state(cp, sp, STATE_ACK_RCVD); break; default: SPPP_LOG(sp, LOG_DEBUG, "%s illegal RTA in state %s\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); if_statinc(ifp, if_ierrors); } } static void sppp_rxj_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; struct ifnet *ifp = &sp->pp_if; KASSERT(!cpu_softintr_p()); /* XXX catastrophic rejects (RXJ-) aren't handled yet. */ switch (sp->scp[cp->protoidx].state) { case STATE_CLOSED: case STATE_STOPPED: case STATE_REQ_SENT: case STATE_ACK_SENT: case STATE_CLOSING: case STATE_STOPPING: case STATE_OPENED: break; case STATE_ACK_RCVD: sppp_cp_change_state(cp, sp, STATE_REQ_SENT); break; default: SPPP_LOG(sp, LOG_DEBUG, "%s illegal RXJ- in state %s\n", cp->name, sppp_state_name(sp->scp[cp->protoidx].state)); if_statinc(ifp, if_ierrors); } } /* * Change the state of a control protocol in the state automaton. * Takes care of starting/stopping the restart timer. */ void sppp_cp_change_state(const struct cp *cp, struct sppp *sp, int newstate) { KASSERT(SPPP_WLOCKED(sp)); sp->scp[cp->protoidx].state = newstate; callout_stop(&sp->scp[cp->protoidx].ch); switch (newstate) { case STATE_INITIAL: case STATE_STARTING: case STATE_CLOSED: case STATE_STOPPED: case STATE_OPENED: break; case STATE_CLOSING: case STATE_STOPPING: case STATE_REQ_SENT: case STATE_ACK_RCVD: case STATE_ACK_SENT: callout_schedule(&sp->scp[cp->protoidx].ch, sp->lcp.timeout); break; } } /* *--------------------------------------------------------------------------* * * * The LCP implementation. * * * *--------------------------------------------------------------------------* */ static void sppp_lcp_init(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); sppp_cp_init(&lcp, sp); SET(sp->lcp.opts, SPPP_LCP_OPT_MAGIC); sp->lcp.magic = 0; sp->lcp.protos = 0; sp->lcp.max_terminate = 2; sp->lcp.max_configure = 10; sp->lcp.max_failure = 10; sp->lcp.tlf_sent = false; /* * Initialize counters and timeout values. Note that we don't * use the 3 seconds suggested in RFC 1661 since we are likely * running on a fast link. XXX We should probably implement * the exponential backoff option. Note that these values are * relevant for all control protocols, not just LCP only. */ sp->lcp.timeout = 1 * hz; } static void sppp_lcp_up(struct sppp *sp, void *xcp) { struct ifnet *ifp; const struct cp *cp = xcp; int pidx; KASSERT(SPPP_WLOCKED(sp)); ifp = &sp->pp_if; pidx = cp->protoidx; /* Initialize activity timestamp: opening a connection is an activity */ sp->pp_last_receive = sp->pp_last_activity = time_uptime; /* * If this interface is passive or dial-on-demand, and we are * still in Initial state, it means we've got an incoming * call. Activate the interface. */ if ((ifp->if_flags & (IFF_AUTO | IFF_PASSIVE)) != 0) { ifp->if_flags |= IFF_RUNNING; if (sp->scp[pidx].state == STATE_INITIAL) { SPPP_DLOG(sp, "Up event (incoming call)\n"); sp->pp_flags |= PP_CALLIN; sppp_wq_add(sp->wq_cp, &sp->scp[pidx].work_open); } else { SPPP_DLOG(sp, "Up event\n"); } } sppp_up_event(sp, xcp); } static void sppp_lcp_down(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; struct ifnet *ifp; int pidx; KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); ifp = &sp->pp_if; pidx = cp->protoidx; sppp_down_event(sp, xcp); /* * We need to do tls to restart when a down event is caused * by the last tlf. */ if (sp->scp[pidx].state == STATE_STARTING && sp->lcp.tlf_sent) { cp->tls(cp, sp); sp->lcp.tlf_sent = false; } SPPP_DLOG(sp, "Down event (carrier loss)\n"); if ((ifp->if_flags & (IFF_AUTO | IFF_PASSIVE)) == 0) { if (sp->lcp.reestablish) sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_open); } else { sp->pp_flags &= ~PP_CALLIN; if (sp->scp[pidx].state != STATE_INITIAL) sppp_wq_add(sp->wq_cp, &sp->scp[pidx].work_close); ifp->if_flags &= ~IFF_RUNNING; } sp->scp[pidx].fail_counter = 0; } static void sppp_lcp_open(struct sppp *sp, void *xcp) { KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); sp->lcp.reestablish = false; sp->scp[IDX_LCP].fail_counter = 0; /* the interface was down while waiting for reconnection */ if ((sp->pp_flags & PP_ADMIN_UP) == 0) return; if (sp->pp_if.if_mtu < PP_MTU) { sp->lcp.mru = sp->pp_if.if_mtu; SET(sp->lcp.opts, SPPP_LCP_OPT_MRU); } else { sp->lcp.mru = PP_MTU; } sp->lcp.their_mru = PP_MTU; /* * If we are authenticator, negotiate LCP_AUTH */ if (sp->hisauth.proto != PPP_NOPROTO) SET(sp->lcp.opts, SPPP_LCP_OPT_AUTH_PROTO); else CLR(sp->lcp.opts, SPPP_LCP_OPT_AUTH_PROTO); sp->pp_flags &= ~PP_NEEDAUTH; sppp_open_event(sp, xcp); } /* * Analyze a configure request. Return true if it was agreeable, and * caused action sca, false if it has been rejected or nak'ed, and * caused action scn. (The return value is used to make the state * transition decision in the state automaton.) */ static enum cp_rcr_type sppp_lcp_confreq(struct sppp *sp, struct lcp_header *h, int origlen, uint8_t **msgbuf, size_t *buflen, size_t *msglen) { u_char *buf, *r, *p, l, blen; enum cp_rcr_type type; int len, rlen; uint32_t nmagic; u_short authproto; char lbuf[SPPP_LCPOPT_NAMELEN]; bool debug; KASSERT(SPPP_WLOCKED(sp)); debug = sppp_debug_enabled(sp); if (origlen < sizeof(*h)) return CP_RCR_DROP; origlen -= sizeof(*h); type = CP_RCR_NONE; type = 0; if (origlen <= 0) return CP_RCR_DROP; else blen = origlen; buf = kmem_intr_alloc(blen, KM_NOSLEEP); if (buf == NULL) return CP_RCR_DROP; if (debug) SPPP_LOG(sp, LOG_DEBUG, "lcp parse opts:"); /* pass 1: check for things that need to be rejected */ p = (void *)(h + 1); r = buf; rlen = 0; for (len = origlen; len > 1; len-= l, p += l) { l = p[1]; if (l == 0) break; /* Sanity check option length */ if (l > len) { /* * Malicious option - drop immediately. * XXX Maybe we should just RXJ it? */ if (debug) addlog("\n"); SPPP_LOG(sp, LOG_DEBUG, "received malicious LCP option 0x%02x, " "length 0x%02x, (len: 0x%02x) dropping.\n", p[0], l, len); type = CP_RCR_ERR; goto end; } if (debug) addlog(" %s", sppp_lcp_opt_name(lbuf, sizeof(lbuf), *p)); switch (p[0]) { case LCP_OPT_MAGIC: /* Magic number. */ /* fall through, both are same length */ case LCP_OPT_ASYNC_MAP: /* Async control character map. */ if (len >= 6 || l == 6) continue; if (debug) addlog(" [invalid]"); break; case LCP_OPT_MP_EID: if (len >= l && l >= 3) { switch (p[2]) { case 0: if (l==3+ 0) continue;break; case 2: if (l==3+ 4) continue;break; case 3: if (l==3+ 6) continue;break; case 6: if (l==3+16) continue;break; case 1: /* FALLTHROUGH */ case 4: if (l<=3+20) continue;break; case 5: if (l<=3+15) continue;break; /* XXX should it be default: continue;? */ } } if (debug) addlog(" [invalid class %d len %d]", p[2], l); break; case LCP_OPT_MP_SSNHF: if (len >= 2 && l == 2) { if (debug) addlog(" [rej]"); break; } if (debug) addlog(" [invalid]"); break; case LCP_OPT_MP_MRRU: /* Multilink maximum received reconstructed unit */ /* should be fall through, both are same length */ /* FALLTHROUGH */ case LCP_OPT_MRU: /* Maximum receive unit. */ if (len >= 4 && l == 4) continue; if (debug) addlog(" [invalid]"); break; case LCP_OPT_AUTH_PROTO: if (len < 4) { if (debug) addlog(" [invalid]"); break; } authproto = (p[2] << 8) + p[3]; if (authproto == PPP_CHAP && l != 5) { if (debug) addlog(" [invalid chap len]"); break; } if (ISSET(sp->myauth.flags, SPPP_AUTHFLAG_PASSIVEAUTHPROTO)) { if (authproto == PPP_PAP || authproto == PPP_CHAP) sp->myauth.proto = authproto; } if (sp->myauth.proto == PPP_NOPROTO) { /* we are not configured to do auth */ if (debug) addlog(" [not configured]"); break; } /* * Remote want us to authenticate, remember this, * so we stay in SPPP_PHASE_AUTHENTICATE after LCP got * up. */ sp->pp_flags |= PP_NEEDAUTH; continue; default: /* Others not supported. */ if (debug) addlog(" [rej]"); break; } if (rlen + l > blen) { if (debug) addlog(" [overflow]"); continue; } /* Add the option to rejected list. */ memcpy(r, p, l); r += l; rlen += l; } if (rlen > 0) { type = CP_RCR_REJ; goto end; } if (debug) addlog("\n"); /* * pass 2: check for option values that are unacceptable and * thus require to be nak'ed. */ if (debug) SPPP_LOG(sp, LOG_DEBUG, "lcp parse opt values:"); p = (void *)(h + 1); r = buf; rlen = 0; for (len = origlen; len > 0; len -= l, p += l) { l = p[1]; if (l == 0) break; if (debug) addlog(" %s", sppp_lcp_opt_name(lbuf, sizeof(lbuf), *p)); switch (p[0]) { case LCP_OPT_MAGIC: /* Magic number -- extract. */ nmagic = (uint32_t)p[2] << 24 | (uint32_t)p[3] << 16 | p[4] << 8 | p[5]; if (nmagic != sp->lcp.magic) { if (debug) addlog(" 0x%x", nmagic); continue; } /* * Local and remote magics equal -- loopback? */ if (sp->pp_loopcnt >= LOOPALIVECNT*5) { SPPP_DLOG(sp, "loopback\n"); sp->pp_loopcnt = 0; if (sp->pp_flags & PP_LOOPBACK_IFDOWN) { sp->pp_flags |= PP_LOOPBACK; sppp_wq_add(sp->wq_cp, &sp->work_ifdown); } sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_open); } else { if (debug) addlog(" [glitch]"); ++sp->pp_loopcnt; } /* * We negate our magic here, and NAK it. If * we see it later in an NAK packet, we * suggest a new one. */ nmagic = ~sp->lcp.magic; /* Gonna NAK it. */ p[2] = nmagic >> 24; p[3] = nmagic >> 16; p[4] = nmagic >> 8; p[5] = nmagic; break; case LCP_OPT_ASYNC_MAP: /* * Async control character map -- just ignore it. * * Quote from RFC 1662, chapter 6: * To enable this functionality, synchronous PPP * implementations MUST always respond to the * Async-Control-Character-Map Configuration * Option with the LCP Configure-Ack. However, * acceptance of the Configuration Option does * not imply that the synchronous implementation * will do any ACCM mapping. Instead, all such * octet mapping will be performed by the * asynchronous-to-synchronous converter. */ continue; case LCP_OPT_MRU: /* * Maximum receive unit. Always agreeable, * but ignored by now. */ sp->lcp.their_mru = p[2] * 256 + p[3]; if (debug) addlog(" %ld", sp->lcp.their_mru); continue; case LCP_OPT_AUTH_PROTO: authproto = (p[2] << 8) + p[3]; if (ISSET(sp->myauth.flags, SPPP_AUTHFLAG_PASSIVEAUTHPROTO)) { if (authproto == PPP_PAP || authproto == PPP_CHAP) sp->myauth.proto = authproto; } if (sp->myauth.proto == authproto) { if (authproto != PPP_CHAP || p[4] == CHAP_MD5) { continue; } if (debug) addlog(" [chap without MD5]"); } else { if (debug) { char pbuf1[SPPP_PROTO_NAMELEN]; char pbuf2[SPPP_PROTO_NAMELEN]; const char *pname1, *pname2; pname1 = sppp_proto_name(pbuf1, sizeof(pbuf1), sp->myauth.proto); pname2 = sppp_proto_name(pbuf2, sizeof(pbuf2), authproto); addlog(" [mine %s != his %s]", pname1, pname2); } } /* not agreed, nak */ if (sp->myauth.proto == PPP_CHAP) { l = 5; } else { l = 4; } if (rlen + l > blen) { if (debug) addlog(" [overflow]"); continue; } r[0] = LCP_OPT_AUTH_PROTO; r[1] = l; r[2] = sp->myauth.proto >> 8; r[3] = sp->myauth.proto & 0xff; if (sp->myauth.proto == PPP_CHAP) r[4] = CHAP_MD5; rlen += l; r += l; continue; case LCP_OPT_MP_EID: /* * Endpoint identification. * Always agreeable, * but ignored by now. */ if (debug) { addlog(" type %d", p[2]); sppp_print_bytes(p+3, p[1]-3); } continue; case LCP_OPT_MP_MRRU: /* * Maximum received reconstructed unit. * Always agreeable, * but ignored by now. */ sp->lcp.their_mrru = p[2] * 256 + p[3]; if (debug) addlog(" %ld", sp->lcp.their_mrru); continue; } if (rlen + l > blen) { if (debug) addlog(" [overflow]"); continue; } /* Add the option to nak'ed list. */ memcpy(r, p, l); r += l; rlen += l; } if (rlen > 0) { if (++sp->scp[IDX_LCP].fail_counter >= sp->lcp.max_failure) { if (debug) addlog(" max_failure (%d) exceeded, ", sp->lcp.max_failure); type = CP_RCR_REJ; } else { type = CP_RCR_NAK; } } else { type = CP_RCR_ACK; rlen = origlen; memcpy(r, h + 1, rlen); sp->scp[IDX_LCP].fail_counter = 0; sp->pp_loopcnt = 0; } end: if (debug) addlog("\n"); if (type == CP_RCR_ERR || type == CP_RCR_DROP) { if (buf != NULL) kmem_intr_free(buf, blen); } else { *msgbuf = buf; *buflen = blen; *msglen = rlen; } return type; } /* * Analyze the LCP Configure-Reject option list, and adjust our * negotiation. */ static void sppp_lcp_confrej(struct sppp *sp, struct lcp_header *h, int len) { u_char *p, l; bool debug; KASSERT(SPPP_WLOCKED(sp)); debug = sppp_debug_enabled(sp); if (len <= sizeof(*h)) return; len -= sizeof(*h); if (debug) SPPP_LOG(sp, LOG_DEBUG, "lcp rej opts:"); p = (void *)(h + 1); for (; len > 1 && (l = p[1]) != 0; len -= l, p += l) { /* Sanity check option length */ if (l > len) { /* * Malicious option - drop immediately. * XXX Maybe we should just RXJ it? */ if (debug) addlog("\n"); SPPP_LOG(sp, LOG_DEBUG, "received malicious LCP option, dropping.\n"); goto end; } if (debug) { char lbuf[SPPP_LCPOPT_NAMELEN]; addlog(" %s", sppp_lcp_opt_name(lbuf, sizeof(lbuf), *p)); } switch (p[0]) { case LCP_OPT_MAGIC: /* Magic number -- can't use it, use 0 */ CLR(sp->lcp.opts, SPPP_LCP_OPT_MAGIC); sp->lcp.magic = 0; break; case LCP_OPT_MRU: /* * We try to negotiate a lower MRU if the underlying * link's MTU is less than PP_MTU (e.g. PPPoE). If the * peer rejects this lower rate, fallback to the * default. */ if (!debug) { SPPP_LOG(sp, LOG_INFO, "peer rejected our MRU of " "%ld bytes. Defaulting to %d bytes\n", sp->lcp.mru, PP_MTU); } CLR(sp->lcp.opts, SPPP_LCP_OPT_MRU); sp->lcp.mru = PP_MTU; break; case LCP_OPT_AUTH_PROTO: /* * Peer doesn't want to authenticate himself, * deny unless this is a dialout call, and * SPPP_AUTHFLAG_NOCALLOUT is set. */ if ((sp->pp_flags & PP_CALLIN) == 0 && (sp->hisauth.flags & SPPP_AUTHFLAG_NOCALLOUT) != 0) { if (debug) { addlog(" [don't insist on auth " "for callout]"); } CLR(sp->lcp.opts, SPPP_LCP_OPT_AUTH_PROTO); break; } if (debug) addlog("[access denied]\n"); sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); break; } } if (debug) addlog("\n"); end: return; } /* * Analyze the LCP Configure-NAK option list, and adjust our * negotiation. */ static void sppp_lcp_confnak(struct sppp *sp, struct lcp_header *h, int len) { u_char *p, l; uint32_t magic; bool debug; KASSERT(SPPP_WLOCKED(sp)); if (len <= sizeof(*h)) return; debug = sppp_debug_enabled(sp); len -= sizeof(*h); if (debug) SPPP_LOG(sp, LOG_DEBUG, "lcp nak opts:"); p = (void *)(h + 1); for (; len > 1 && (l = p[1]) != 0; len -= l, p += l) { /* Sanity check option length */ if (l > len) { /* * Malicious option - drop immediately. * XXX Maybe we should just RXJ it? */ if (debug) addlog("\n"); SPPP_LOG(sp, LOG_DEBUG, "received malicious LCP option, dropping.\n"); goto end; } if (debug) { char lbuf[SPPP_LCPOPT_NAMELEN]; addlog(" %s", sppp_lcp_opt_name(lbuf, sizeof(lbuf),*p)); } switch (p[0]) { case LCP_OPT_MAGIC: /* Magic number -- renegotiate */ if (ISSET(sp->lcp.opts, SPPP_LCP_OPT_MAGIC) && len >= 6 && l == 6) { magic = (uint32_t)p[2] << 24 | (uint32_t)p[3] << 16 | p[4] << 8 | p[5]; /* * If the remote magic is our negated one, * this looks like a loopback problem. * Suggest a new magic to make sure. */ if (magic == ~sp->lcp.magic) { if (debug) addlog(" magic glitch"); sp->lcp.magic = cprng_fast32(); } else { sp->lcp.magic = magic; if (debug) addlog(" %d", magic); } } break; case LCP_OPT_MRU: /* * Peer wants to advise us to negotiate an MRU. * Agree on it if it's reasonable, or use * default otherwise. */ if (len >= 4 && l == 4) { u_int mru = p[2] * 256 + p[3]; if (debug) addlog(" %d", mru); if (mru < PPP_MINMRU || mru > sp->pp_if.if_mtu) mru = sp->pp_if.if_mtu; sp->lcp.mru = mru; SET(sp->lcp.opts, SPPP_LCP_OPT_MRU); } break; case LCP_OPT_AUTH_PROTO: /* * Peer doesn't like our authentication method, * deny. */ if (debug) addlog("[access denied]\n"); sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); break; } } if (debug) addlog("\n"); end: return; } static void sppp_lcp_tlu(struct sppp *sp) { struct ifnet *ifp; struct sppp_cp *scp; int i; bool going_up; KASSERT(SPPP_WLOCKED(sp)); ifp = &sp->pp_if; /* unlock for IFNET_LOCK and if_up() */ SPPP_UNLOCK(sp); if (! (ifp->if_flags & IFF_UP) && (ifp->if_flags & IFF_RUNNING)) { /* Coming out of loopback mode. */ going_up = true; if_up(ifp); } else { going_up = false; } IFNET_LOCK(ifp); SPPP_LOCK(sp, RW_WRITER); if (going_up) { if ((sp->pp_flags & PP_LOOPBACK) == 0) { SPPP_LOG(sp, LOG_DEBUG, "interface is going up, " "but no loopback packet is detected\n"); } sp->pp_flags &= ~PP_LOOPBACK; } if (ifp->if_mtu > sp->lcp.their_mru) { sp->pp_saved_mtu = ifp->if_mtu; ifp->if_mtu = sp->lcp.their_mru; SPPP_DLOG(sp, "setting MTU " "from %"PRIu64" bytes to %"PRIu64" bytes\n", sp->pp_saved_mtu, ifp->if_mtu); } IFNET_UNLOCK(ifp); if (ISSET(sp->lcp.opts, SPPP_LCP_OPT_AUTH_PROTO) || (sp->pp_flags & PP_NEEDAUTH) != 0) sppp_change_phase(sp, SPPP_PHASE_AUTHENTICATE); else sppp_change_phase(sp, SPPP_PHASE_NETWORK); for (i = 0; i < IDX_COUNT; i++) { scp = &sp->scp[(cps[i])->protoidx]; if (((cps[i])->flags & CP_LCP) == 0) sppp_wq_add(sp->wq_cp, &scp->work_up); /* * Open all authentication protocols. This is even required * if we already proceeded to network phase, since it might be * that remote wants us to authenticate, so we might have to * send a PAP request. Undesired authentication protocols * don't do anything when they get an Open event. */ if ((cps[i])->flags & CP_AUTH) sppp_wq_add(sp->wq_cp, &scp->work_open); /* Open all NCPs. */ if (sp->pp_phase == SPPP_PHASE_NETWORK && ((cps[i])->flags & CP_NCP) != 0) { sppp_wq_add(sp->wq_cp, &scp->work_open); } } /* notify low-level driver of state change */ sppp_notify_chg_wlocked(sp); } static void sppp_lcp_tld(struct sppp *sp) { struct ifnet *ifp; struct sppp_cp *scp; int i, phase; KASSERT(SPPP_WLOCKED(sp)); phase = sp->pp_phase; sppp_change_phase(sp, SPPP_PHASE_TERMINATE); if (sp->pp_saved_mtu > 0) { ifp = &sp->pp_if; SPPP_UNLOCK(sp); IFNET_LOCK(ifp); SPPP_LOCK(sp, RW_WRITER); SPPP_DLOG(sp, "setting MTU " "from %"PRIu64" bytes to %"PRIu64" bytes\n", ifp->if_mtu, sp->pp_saved_mtu); ifp->if_mtu = sp->pp_saved_mtu; sp->pp_saved_mtu = 0; IFNET_UNLOCK(ifp); } /* * Take upper layers down. We send the Down event first and * the Close second to prevent the upper layers from sending * ``a flurry of terminate-request packets'', as the RFC * describes it. */ for (i = 0; i < IDX_COUNT; i++) { scp = &sp->scp[(cps[i])->protoidx]; if (((cps[i])->flags & CP_LCP) == 0) sppp_wq_add(sp->wq_cp, &scp->work_down); if ((cps[i])->flags & CP_AUTH) { sppp_wq_add(sp->wq_cp, &scp->work_close); } /* Close all NCPs. */ if (phase == SPPP_PHASE_NETWORK && ((cps[i])->flags & CP_NCP) != 0) { sppp_wq_add(sp->wq_cp, &scp->work_close); } } } static void sppp_lcp_tls(const struct cp *cp __unused, struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); sppp_change_phase(sp, SPPP_PHASE_ESTABLISH); /* Notify lower layer if desired. */ sppp_notify_tls_wlocked(sp); sp->lcp.tlf_sent = false; } static void sppp_lcp_tlf(const struct cp *cp __unused, struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); sppp_change_phase(sp, SPPP_PHASE_DEAD); /* Notify lower layer if desired. */ sppp_notify_tlf_wlocked(sp); switch (sp->scp[IDX_LCP].state) { case STATE_CLOSED: case STATE_STOPPED: sp->lcp.tlf_sent = true; break; case STATE_INITIAL: default: /* just in case */ sp->lcp.tlf_sent = false; } } static void sppp_lcp_scr(struct sppp *sp) { char opt[6 /* magicnum */ + 4 /* mru */ + 5 /* chap */]; int i = 0; u_short authproto; KASSERT(SPPP_WLOCKED(sp)); if (ISSET(sp->lcp.opts, SPPP_LCP_OPT_MAGIC)) { if (! sp->lcp.magic) sp->lcp.magic = cprng_fast32(); opt[i++] = LCP_OPT_MAGIC; opt[i++] = 6; opt[i++] = sp->lcp.magic >> 24; opt[i++] = sp->lcp.magic >> 16; opt[i++] = sp->lcp.magic >> 8; opt[i++] = sp->lcp.magic; } if (ISSET(sp->lcp.opts,SPPP_LCP_OPT_MRU)) { opt[i++] = LCP_OPT_MRU; opt[i++] = 4; opt[i++] = sp->lcp.mru >> 8; opt[i++] = sp->lcp.mru; } if (ISSET(sp->lcp.opts, SPPP_LCP_OPT_AUTH_PROTO)) { authproto = sp->hisauth.proto; opt[i++] = LCP_OPT_AUTH_PROTO; opt[i++] = authproto == PPP_CHAP? 5: 4; opt[i++] = authproto >> 8; opt[i++] = authproto; if (authproto == PPP_CHAP) opt[i++] = CHAP_MD5; } sp->scp[IDX_LCP].confid = ++sp->scp[IDX_LCP].seq; sppp_cp_send(sp, PPP_LCP, CONF_REQ, sp->scp[IDX_LCP].confid, i, &opt); } /* * Check the open NCPs, return true if at least one NCP is open. */ static int sppp_cp_check(struct sppp *sp, u_char cp_flags) { int i, mask; for (i = 0, mask = 1; i < IDX_COUNT; i++, mask <<= 1) if ((sp->lcp.protos & mask) && (cps[i])->flags & cp_flags) return 1; return 0; } /* * Re-check the open NCPs and see if we should terminate the link. * Called by the NCPs during their tlf action handling. */ static void sppp_lcp_check_and_close(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); if (sp->pp_phase < SPPP_PHASE_AUTHENTICATE) { /* don't bother, we are already going down */ return; } if (sp->pp_phase == SPPP_PHASE_AUTHENTICATE && sppp_cp_check(sp, CP_AUTH)) return; if (sp->pp_phase >= SPPP_PHASE_NETWORK && sppp_cp_check(sp, CP_NCP)) return; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); if (sp->pp_max_auth_fail != 0 && sp->pp_auth_failures >= sp->pp_max_auth_fail) { SPPP_LOG(sp, LOG_INFO, "authentication failed %d times, " "not retrying again\n", sp->pp_auth_failures); sppp_wq_add(sp->wq_cp, &sp->work_ifdown); sp->pp_if.if_flags &= ~IFF_RUNNING; } else { sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_open); } } /* *--------------------------------------------------------------------------* * * * The IPCP implementation. * * * *--------------------------------------------------------------------------* */ static void sppp_ipcp_init(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); sppp_cp_init(&ipcp, sp); sp->ipcp.opts = 0; sp->ipcp.flags = 0; } static void sppp_ipcp_open(struct sppp *sp, void *xcp) { uint32_t myaddr, hisaddr; KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); if (!ISSET(sp->pp_ncpflags, SPPP_NCP_IPCP)) return; sp->ipcp.flags &= ~(IPCP_HISADDR_SEEN|IPCP_MYADDR_SEEN|IPCP_MYADDR_DYN|IPCP_HISADDR_DYN); sp->ipcp.req_myaddr = 0; sp->ipcp.req_hisaddr = 0; memset(&sp->dns_addrs, 0, sizeof sp->dns_addrs); #ifdef INET sppp_get_ip_addrs(sp, &myaddr, &hisaddr, 0); #else myaddr = hisaddr = 0; #endif /* * If we don't have his address, this probably means our * interface doesn't want to talk IP at all. (This could * be the case if somebody wants to speak only IPX, for * example.) Don't open IPCP in this case. */ if (hisaddr == 0) { /* XXX this message should go away */ SPPP_DLOG(sp, "ipcp_open(): no IP interface\n"); return; } if (myaddr == 0) { /* * I don't have an assigned address, so i need to * negotiate my address. */ sp->ipcp.flags |= IPCP_MYADDR_DYN; SET(sp->ipcp.opts, SPPP_IPCP_OPT_ADDRESS); } if (hisaddr == 1) { /* * XXX - remove this hack! * remote has no valid address, we need to get one assigned. */ sp->ipcp.flags |= IPCP_HISADDR_DYN; sp->ipcp.saved_hisaddr = htonl(hisaddr); } if (sp->query_dns & 1) { SET(sp->ipcp.opts, SPPP_IPCP_OPT_PRIMDNS); } else { CLR(sp->ipcp.opts, SPPP_IPCP_OPT_PRIMDNS); } if (sp->query_dns & 2) { SET(sp->ipcp.opts, SPPP_IPCP_OPT_SECDNS); } else { CLR(sp->ipcp.opts, SPPP_IPCP_OPT_SECDNS); } sppp_open_event(sp, xcp); } static void sppp_ipcp_close(struct sppp *sp, void *xcp) { KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); sppp_close_event(sp, xcp); #ifdef INET if (sp->ipcp.flags & (IPCP_MYADDR_DYN|IPCP_HISADDR_DYN)) { /* * Some address was dynamic, clear it again. */ sppp_clear_ip_addrs(sp); } #endif memset(&sp->dns_addrs, 0, sizeof sp->dns_addrs); } /* * Analyze a configure request. Return true if it was agreeable, and * caused action sca, false if it has been rejected or nak'ed, and * caused action scn. (The return value is used to make the state * transition decision in the state automaton.) */ static enum cp_rcr_type sppp_ipcp_confreq(struct sppp *sp, struct lcp_header *h, int origlen, uint8_t **msgbuf, size_t *buflen, size_t *msglen) { u_char *buf, *r, *p, l, blen; enum cp_rcr_type type; int rlen, len; uint32_t hisaddr, desiredaddr; char ipbuf[SPPP_IPCPOPT_NAMELEN]; char dqbuf[SPPP_DOTQUAD_BUFLEN]; const char *dq; bool debug; KASSERT(SPPP_WLOCKED(sp)); type = CP_RCR_NONE; origlen -= sizeof(*h); if (origlen < 0) return CP_RCR_DROP; debug = sppp_debug_enabled(sp); /* * Make sure to allocate a buf that can at least hold a * conf-nak with an `address' option. We might need it below. */ blen = MAX(6, origlen); buf = kmem_intr_alloc(blen, KM_NOSLEEP); if (buf == NULL) return CP_RCR_DROP; /* pass 1: see if we can recognize them */ if (debug) SPPP_LOG(sp, LOG_DEBUG, "ipcp parse opts:"); p = (void *)(h + 1); r = buf; rlen = 0; for (len = origlen; len > 1; len -= l, p += l) { l = p[1]; if (l == 0) break; /* Sanity check option length */ if (l > len) { /* XXX should we just RXJ? */ if (debug) addlog("\n"); SPPP_LOG(sp, LOG_DEBUG, " malicious IPCP option received, dropping\n"); type = CP_RCR_ERR; goto end; } if (debug) { addlog(" %s", sppp_ipcp_opt_name(ipbuf, sizeof(ipbuf), *p)); } switch (p[0]) { #ifdef notyet case IPCP_OPT_COMPRESSION: if (len >= 6 && l >= 6) { /* correctly formed compress option */ continue; } if (debug) addlog(" [invalid]"); break; #endif case IPCP_OPT_ADDRESS: if (len >= 6 && l == 6) { /* correctly formed address option */ continue; } if (debug) addlog(" [invalid]"); break; default: /* Others not supported. */ if (debug) addlog(" [rej]"); break; } /* Add the option to rejected list. */ if (rlen + l > blen) { if (debug) addlog(" [overflow]"); continue; } memcpy(r, p, l); r += l; rlen += l; } if (rlen > 0) { type = CP_RCR_REJ; goto end; } if (debug) addlog("\n"); /* pass 2: parse option values */ if (sp->ipcp.flags & IPCP_HISADDR_SEEN) hisaddr = sp->ipcp.req_hisaddr; /* we already aggreed on that */ else #ifdef INET sppp_get_ip_addrs(sp, 0, &hisaddr, 0); /* user configuration */ #else hisaddr = 0; #endif if (debug) SPPP_LOG(sp, LOG_DEBUG, "ipcp parse opt values:"); p = (void *)(h + 1); r = buf; rlen = 0; for (len = origlen; len > 1; len -= l, p += l) { l = p[1]; if (l == 0) break; if (debug) { addlog(" %s", sppp_ipcp_opt_name(ipbuf, sizeof(ipbuf), *p)); } switch (p[0]) { #ifdef notyet case IPCP_OPT_COMPRESSION: continue; #endif case IPCP_OPT_ADDRESS: desiredaddr = p[2] << 24 | p[3] << 16 | p[4] << 8 | p[5]; if (desiredaddr == hisaddr || ((sp->ipcp.flags & IPCP_HISADDR_DYN) && desiredaddr != 0)) { /* * Peer's address is same as our value, * this is agreeable. Gonna conf-ack * it. */ if (debug) { dq = sppp_dotted_quad(dqbuf, sizeof(dqbuf), hisaddr); addlog(" %s [ack]", dq); } /* record that we've seen it already */ sp->ipcp.flags |= IPCP_HISADDR_SEEN; sp->ipcp.req_hisaddr = desiredaddr; hisaddr = desiredaddr; continue; } /* * The address wasn't agreeable. This is either * he sent us 0.0.0.0, asking to assign him an * address, or he send us another address not * matching our value. Either case, we gonna * conf-nak it with our value. */ if (debug) { if (desiredaddr == 0) { addlog(" [addr requested]"); } else { dq = sppp_dotted_quad(dqbuf, sizeof(dqbuf), desiredaddr); addlog(" %s [not agreed]", dq); } } p[2] = hisaddr >> 24; p[3] = hisaddr >> 16; p[4] = hisaddr >> 8; p[5] = hisaddr; break; } if (rlen + l > blen) { if (debug) addlog(" [overflow]"); continue; } /* Add the option to nak'ed list. */ memcpy(r, p, l); r += l; rlen += l; } if (rlen > 0) { type = CP_RCR_NAK; } else { if ((sp->ipcp.flags & IPCP_HISADDR_SEEN) == 0) { /* * If we are about to conf-ack the request, but haven't seen * his address so far, gonna conf-nak it instead, with the * `address' option present and our idea of his address being * filled in there, to request negotiation of both addresses. * * XXX This can result in an endless req - nak loop if peer * doesn't want to send us his address. Q: What should we do * about it? XXX A: implement the max-failure counter. */ buf[0] = IPCP_OPT_ADDRESS; buf[1] = 6; buf[2] = hisaddr >> 24; buf[3] = hisaddr >> 16; buf[4] = hisaddr >> 8; buf[5] = hisaddr; rlen = 6; if (debug) addlog(" still need hisaddr"); type = CP_RCR_NAK; } else { type = CP_RCR_ACK; rlen = origlen; memcpy(r, h + 1, rlen); } } end: if (debug) addlog("\n"); if (type == CP_RCR_ERR || type == CP_RCR_DROP) { if (buf != NULL) kmem_intr_free(buf, blen); } else { *msgbuf = buf; *buflen = blen; *msglen = rlen; } return type; } /* * Analyze the IPCP Configure-Reject option list, and adjust our * negotiation. */ static void sppp_ipcp_confrej(struct sppp *sp, struct lcp_header *h, int len) { u_char *p, l; bool debug; KASSERT(SPPP_WLOCKED(sp)); if (len <= sizeof(*h)) return; len -= sizeof(*h); debug = sppp_debug_enabled(sp); if (debug) SPPP_LOG(sp, LOG_DEBUG, "ipcp rej opts:"); p = (void *)(h + 1); for (; len > 1; len -= l, p += l) { l = p[1]; if (l == 0) break; /* Sanity check option length */ if (l > len) { /* XXX should we just RXJ? */ if (debug) addlog("\n"); SPPP_LOG(sp, LOG_DEBUG, "malicious IPCP option received, dropping\n"); goto end; } if (debug) { char ipbuf[SPPP_IPCPOPT_NAMELEN]; addlog(" %s", sppp_ipcp_opt_name(ipbuf, sizeof(ipbuf), *p)); } switch (p[0]) { case IPCP_OPT_ADDRESS: /* * Peer doesn't grok address option. This is * bad. XXX Should we better give up here? */ if (!debug) { SPPP_LOG(sp, LOG_ERR, "IPCP address option rejected\n"); } CLR(sp->ipcp.opts, SPPP_IPCP_OPT_ADDRESS); break; #ifdef notyet case IPCP_OPT_COMPRESS: CLR(sp->ipcp.opts, SPPP_IPCP_OPT_COMPRESS); break; #endif case IPCP_OPT_PRIMDNS: CLR(sp->ipcp.opts, SPPP_IPCP_OPT_PRIMDNS); break; case IPCP_OPT_SECDNS: CLR(sp->ipcp.opts, SPPP_IPCP_OPT_SECDNS); break; } } if (debug) addlog("\n"); end: return; } /* * Analyze the IPCP Configure-NAK option list, and adjust our * negotiation. */ static void sppp_ipcp_confnak(struct sppp *sp, struct lcp_header *h, int len) { u_char *p, l; struct ifnet *ifp = &sp->pp_if; int debug = ifp->if_flags & IFF_DEBUG; uint32_t wantaddr; KASSERT(SPPP_WLOCKED(sp)); len -= sizeof(*h); debug = sppp_debug_enabled(sp); if (debug) SPPP_LOG(sp, LOG_DEBUG, "ipcp nak opts:"); p = (void *)(h + 1); for (; len > 1; len -= l, p += l) { l = p[1]; if (l == 0) break; /* Sanity check option length */ if (l > len) { /* XXX should we just RXJ? */ if (debug) addlog("\n"); SPPP_LOG(sp, LOG_DEBUG, "malicious IPCP option received, dropping\n"); return; } if (debug) { char ipbuf[SPPP_IPCPOPT_NAMELEN]; addlog(" %s", sppp_ipcp_opt_name(ipbuf, sizeof(ipbuf), *p)); } switch (*p) { case IPCP_OPT_ADDRESS: /* * Peer doesn't like our local IP address. See * if we can do something for him. We'll drop * him our address then. */ if (len >= 6 && l == 6) { wantaddr = p[2] << 24 | p[3] << 16 | p[4] << 8 | p[5]; SET(sp->ipcp.opts, SPPP_IPCP_OPT_ADDRESS); if (debug) { char dqbuf[SPPP_DOTQUAD_BUFLEN]; const char *dq; dq = sppp_dotted_quad(dqbuf, sizeof(dqbuf), wantaddr); addlog(" [wantaddr %s]", dq); } /* * When doing dynamic address assignment, * we accept his offer. Otherwise, we * ignore it and thus continue to negotiate * our already existing value. */ if (sp->ipcp.flags & IPCP_MYADDR_DYN) { if (ntohl(wantaddr) != INADDR_ANY) { if (debug) addlog(" [agree]"); sp->ipcp.flags |= IPCP_MYADDR_SEEN; sp->ipcp.req_myaddr = wantaddr; } else { if (debug) addlog(" [not agreed]"); } } } break; case IPCP_OPT_PRIMDNS: if (ISSET(sp->ipcp.opts, SPPP_IPCP_OPT_PRIMDNS) && len >= 6 && l == 6) { sp->dns_addrs[0] = p[2] << 24 | p[3] << 16 | p[4] << 8 | p[5]; } break; case IPCP_OPT_SECDNS: if (ISSET(sp->ipcp.opts, SPPP_IPCP_OPT_SECDNS) && len >= 6 && l == 6) { sp->dns_addrs[1] = p[2] << 24 | p[3] << 16 | p[4] << 8 | p[5]; } break; #ifdef notyet case IPCP_OPT_COMPRESS: /* * Peer wants different compression parameters. */ break; #endif } } if (debug) addlog("\n"); } static void sppp_ipcp_tlu(struct sppp *sp) { #ifdef INET struct ifnet *ifp; KASSERT(SPPP_WLOCKED(sp)); SPPP_LOG(sp, LOG_INFO, "IPCP layer up\n"); ifp = &sp->pp_if; if ((sp->ipcp.flags & IPCP_MYADDR_DYN) && ((sp->ipcp.flags & IPCP_MYADDR_SEEN) == 0)) { SPPP_LOG(sp, LOG_WARNING, "no IP address, closing IPCP\n"); sppp_wq_add(sp->wq_cp, &sp->scp[IDX_IPCP].work_close); } else { /* we are up. Set addresses and notify anyone interested */ sppp_set_ip_addrs(sp); rt_ifmsg(ifp); } #endif } static void sppp_ipcp_tld(struct sppp *sp) { #ifdef INET struct ifnet *ifp; KASSERT(SPPP_WLOCKED(sp)); SPPP_LOG(sp, LOG_INFO, "IPCP layer down\n"); ifp = &sp->pp_if; rt_ifmsg(ifp); #endif } static void sppp_ipcp_scr(struct sppp *sp) { uint8_t opt[6 /* compression */ + 6 /* address */ + 12 /* dns addresses */]; #ifdef INET uint32_t ouraddr; #endif int i = 0; KASSERT(SPPP_WLOCKED(sp)); #ifdef notyet if (ISSET(sp->ipcp.opts,SPPP_IPCP_OPT_COMPRESSION)) { opt[i++] = IPCP_OPT_COMPRESSION; opt[i++] = 6; opt[i++] = 0; /* VJ header compression */ opt[i++] = 0x2d; /* VJ header compression */ opt[i++] = max_slot_id; opt[i++] = comp_slot_id; } #endif #ifdef INET if (ISSET(sp->ipcp.opts, SPPP_IPCP_OPT_ADDRESS)) { if (sp->ipcp.flags & IPCP_MYADDR_SEEN) { ouraddr = sp->ipcp.req_myaddr; /* not sure if this can ever happen */ } else { sppp_get_ip_addrs(sp, &ouraddr, 0, 0); } opt[i++] = IPCP_OPT_ADDRESS; opt[i++] = 6; opt[i++] = ouraddr >> 24; opt[i++] = ouraddr >> 16; opt[i++] = ouraddr >> 8; opt[i++] = ouraddr; } #endif if (ISSET(sp->ipcp.opts, SPPP_IPCP_OPT_PRIMDNS)) { opt[i++] = IPCP_OPT_PRIMDNS; opt[i++] = 6; opt[i++] = sp->dns_addrs[0] >> 24; opt[i++] = sp->dns_addrs[0] >> 16; opt[i++] = sp->dns_addrs[0] >> 8; opt[i++] = sp->dns_addrs[0]; } if (ISSET(sp->ipcp.opts, SPPP_IPCP_OPT_SECDNS)) { opt[i++] = IPCP_OPT_SECDNS; opt[i++] = 6; opt[i++] = sp->dns_addrs[1] >> 24; opt[i++] = sp->dns_addrs[1] >> 16; opt[i++] = sp->dns_addrs[1] >> 8; opt[i++] = sp->dns_addrs[1]; } sp->scp[IDX_IPCP].confid = ++sp->scp[IDX_IPCP].seq; sppp_cp_send(sp, PPP_IPCP, CONF_REQ, sp->scp[IDX_IPCP].confid, i, &opt); } /* *--------------------------------------------------------------------------* * * * The IPv6CP implementation. * * * *--------------------------------------------------------------------------* */ #ifdef INET6 static void sppp_ipv6cp_init(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); sppp_cp_init(&ipv6cp, sp); sp->ipv6cp.opts = 0; sp->ipv6cp.flags = 0; } static void sppp_ipv6cp_open(struct sppp *sp, void *xcp) { struct in6_addr myaddr, hisaddr; KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); if (!ISSET(sp->pp_ncpflags, SPPP_NCP_IPV6CP)) return; #ifdef IPV6CP_MYIFID_DYN sp->ipv6cp.flags &= ~(IPV6CP_MYIFID_SEEN|IPV6CP_MYIFID_DYN); #else sp->ipv6cp.flags &= ~IPV6CP_MYIFID_SEEN; #endif sppp_get_ip6_addrs(sp, &myaddr, &hisaddr, 0); /* * If we don't have our address, this probably means our * interface doesn't want to talk IPv6 at all. (This could * be the case if somebody wants to speak only IPX, for * example.) Don't open IPv6CP in this case. */ if (IN6_IS_ADDR_UNSPECIFIED(&myaddr)) { /* XXX this message should go away */ SPPP_DLOG(sp, "ipv6cp_open(): no IPv6 interface\n"); return; } sp->ipv6cp.flags |= IPV6CP_MYIFID_SEEN; SET(sp->ipv6cp.opts, SPPP_IPV6CP_OPT_IFID); sppp_open_event(sp, xcp); } /* * Analyze a configure request. Return true if it was agreeable, and * caused action sca, false if it has been rejected or nak'ed, and * caused action scn. (The return value is used to make the state * transition decision in the state automaton.) */ static enum cp_rcr_type sppp_ipv6cp_confreq(struct sppp *sp, struct lcp_header *h, int origlen, uint8_t **msgbuf, size_t *buflen, size_t *msglen) { u_char *buf, *r, *p, l, blen; int rlen, len; struct in6_addr myaddr, desiredaddr, suggestaddr; enum cp_rcr_type type; int ifidcount; int collision, nohisaddr; char ip6buf[INET6_ADDRSTRLEN]; char tbuf[SPPP_CPTYPE_NAMELEN]; char ipv6buf[SPPP_IPV6CPOPT_NAMELEN]; const char *cpname; bool debug; KASSERT(SPPP_WLOCKED(sp)); debug = sppp_debug_enabled(sp); type = CP_RCR_NONE; origlen -= sizeof(*h); if (origlen < 0) return CP_RCR_DROP; /* * Make sure to allocate a buf that can at least hold a * conf-nak with an `address' option. We might need it below. */ blen = MAX(6, origlen); buf = kmem_intr_alloc(blen, KM_NOSLEEP); if (buf == NULL) return CP_RCR_DROP; /* pass 1: see if we can recognize them */ if (debug) SPPP_LOG(sp, LOG_DEBUG, "ipv6cp parse opts:"); p = (void *)(h + 1); r = buf; rlen = 0; ifidcount = 0; for (len = origlen; len > 1; len -= l, p += l) { l = p[1]; if (l == 0) break; /* Sanity check option length */ if (l > len) { /* XXX just RXJ? */ if (debug) addlog("\n"); SPPP_LOG(sp, LOG_DEBUG, "received malicious IPCPv6 option, " "dropping\n"); type = CP_RCR_ERR; goto end; } if (debug) { addlog(" %s", sppp_ipv6cp_opt_name(ipv6buf, sizeof(ipv6buf),*p)); } switch (p[0]) { case IPV6CP_OPT_IFID: if (len >= 10 && l == 10 && ifidcount == 0) { /* correctly formed address option */ ifidcount++; continue; } if (debug) addlog(" [invalid]"); break; #ifdef notyet case IPV6CP_OPT_COMPRESSION: if (len >= 4 && l >= 4) { /* correctly formed compress option */ continue; } if (debug) addlog(" [invalid]"); break; #endif default: /* Others not supported. */ if (debug) addlog(" [rej]"); break; } if (rlen + l > blen) { if (debug) addlog(" [overflow]"); continue; } /* Add the option to rejected list. */ memcpy(r, p, l); r += l; rlen += l; } if (rlen > 0) { type = CP_RCR_REJ; goto end; } if (debug) addlog("\n"); /* pass 2: parse option values */ sppp_get_ip6_addrs(sp, &myaddr, 0, 0); if (debug) SPPP_LOG(sp, LOG_DEBUG, "ipv6cp parse opt values:"); p = (void *)(h + 1); r = buf; rlen = 0; type = CP_RCR_ACK; for (len = origlen; len > 1; len -= l, p += l) { l = p[1]; if (l == 0) break; if (debug) { addlog(" %s", sppp_ipv6cp_opt_name(ipv6buf, sizeof(ipv6buf), *p)); } switch (p[0]) { #ifdef notyet case IPV6CP_OPT_COMPRESSION: continue; #endif case IPV6CP_OPT_IFID: memset(&desiredaddr, 0, sizeof(desiredaddr)); memcpy(&desiredaddr.s6_addr[8], &p[2], 8); collision = (memcmp(&desiredaddr.s6_addr[8], &myaddr.s6_addr[8], 8) == 0); nohisaddr = IN6_IS_ADDR_UNSPECIFIED(&desiredaddr); desiredaddr.s6_addr16[0] = htons(0xfe80); (void)in6_setscope(&desiredaddr, &sp->pp_if, NULL); if (!collision && !nohisaddr) { /* no collision, hisaddr known - Conf-Ack */ type = CP_RCR_ACK; memcpy(sp->ipv6cp.my_ifid, &myaddr.s6_addr[8], sizeof(sp->ipv6cp.my_ifid)); memcpy(sp->ipv6cp.his_ifid, &desiredaddr.s6_addr[8], sizeof(sp->ipv6cp.my_ifid)); if (debug) { cpname = sppp_cp_type_name(tbuf, sizeof(tbuf), CONF_ACK); addlog(" %s [%s]", IN6_PRINT(ip6buf, &desiredaddr), cpname); } continue; } memset(&suggestaddr, 0, sizeof(suggestaddr)); if (collision && nohisaddr) { /* collision, hisaddr unknown - Conf-Rej */ type = CP_RCR_REJ; memset(&p[2], 0, 8); } else { /* * - no collision, hisaddr unknown, or * - collision, hisaddr known * Conf-Nak, suggest hisaddr */ type = CP_RCR_NAK; sppp_suggest_ip6_addr(sp, &suggestaddr); memcpy(&p[2], &suggestaddr.s6_addr[8], 8); } if (debug) { int ctype = type == CP_RCR_REJ ? CONF_REJ : CONF_NAK; cpname = sppp_cp_type_name(tbuf, sizeof(tbuf), ctype); addlog(" %s [%s]", IN6_PRINT(ip6buf, &desiredaddr), cpname); } break; } if (rlen + l > blen) { if (debug) addlog(" [overflow]"); continue; } /* Add the option to nak'ed list. */ memcpy(r, p, l); r += l; rlen += l; } if (rlen > 0) { if (type != CP_RCR_ACK) { if (debug) { int ctype ; ctype = type == CP_RCR_REJ ? CONF_REJ : CONF_NAK; cpname = sppp_cp_type_name(tbuf, sizeof(tbuf), ctype); addlog(" send %s suggest %s\n", cpname, IN6_PRINT(ip6buf, &suggestaddr)); } } #ifdef notdef if (type == CP_RCR_ACK) panic("IPv6CP RCR: CONF_ACK with non-zero rlen"); #endif } else { if (type == CP_RCR_ACK) { rlen = origlen; memcpy(r, h + 1, rlen); } } end: if (debug) addlog("\n"); if (type == CP_RCR_ERR || type == CP_RCR_DROP) { if (buf != NULL) kmem_intr_free(buf, blen); } else { *msgbuf = buf; *buflen = blen; *msglen = rlen; } return type; } /* * Analyze the IPv6CP Configure-Reject option list, and adjust our * negotiation. */ static void sppp_ipv6cp_confrej(struct sppp *sp, struct lcp_header *h, int len) { u_char *p, l; bool debug; KASSERT(SPPP_WLOCKED(sp)); if (len <= sizeof(*h)) return; len -= sizeof(*h); debug = sppp_debug_enabled(sp); if (debug) SPPP_LOG(sp, LOG_DEBUG, "ipv6cp rej opts:"); p = (void *)(h + 1); for (; len > 1; len -= l, p += l) { l = p[1]; if (l == 0) break; if (l > len) { /* XXX just RXJ? */ if (debug) addlog("\n"); SPPP_LOG(sp, LOG_DEBUG, "received malicious IPCPv6 option, " "dropping\n"); goto end; } if (debug) { char ipv6buf[SPPP_IPV6CPOPT_NAMELEN]; addlog(" %s", sppp_ipv6cp_opt_name(ipv6buf, sizeof(ipv6buf), *p)); } switch (p[0]) { case IPV6CP_OPT_IFID: /* * Peer doesn't grok address option. This is * bad. XXX Should we better give up here? */ CLR(sp->ipv6cp.opts, SPPP_IPV6CP_OPT_IFID); break; #ifdef notyet case IPV6CP_OPT_COMPRESS: CLR(sp->ipv6cp.opts, SPPP_IPV6CP_OPT_COMPRESS); break; #endif } } if (debug) addlog("\n"); end: return; } /* * Analyze the IPv6CP Configure-NAK option list, and adjust our * negotiation. */ static void sppp_ipv6cp_confnak(struct sppp *sp, struct lcp_header *h, int len) { u_char *p, l; struct in6_addr suggestaddr; char ip6buf[INET6_ADDRSTRLEN]; bool debug; KASSERT(SPPP_WLOCKED(sp)); if (len <= sizeof(*h)) return; len -= sizeof(*h); debug = sppp_debug_enabled(sp); if (debug) SPPP_LOG(sp, LOG_DEBUG, "ipv6cp nak opts:"); p = (void *)(h + 1); for (; len > 1; len -= l, p += l) { l = p[1]; if (l == 0) break; if (l > len) { /* XXX just RXJ? */ if (debug) addlog("\n"); SPPP_LOG(sp, LOG_DEBUG, "received malicious IPCPv6 option, " "dropping\n"); goto end; } if (debug) { char ipv6buf[SPPP_IPV6CPOPT_NAMELEN]; addlog(" %s", sppp_ipv6cp_opt_name(ipv6buf, sizeof(ipv6buf), *p)); } switch (p[0]) { case IPV6CP_OPT_IFID: /* * Peer doesn't like our local ifid. See * if we can do something for him. We'll drop * him our address then. */ if (len < 10 || l != 10) break; memset(&suggestaddr, 0, sizeof(suggestaddr)); suggestaddr.s6_addr16[0] = htons(0xfe80); (void)in6_setscope(&suggestaddr, &sp->pp_if, NULL); memcpy(&suggestaddr.s6_addr[8], &p[2], 8); SET(sp->ipv6cp.opts, SPPP_IPV6CP_OPT_IFID); if (debug) addlog(" [suggestaddr %s]", IN6_PRINT(ip6buf, &suggestaddr)); #ifdef IPV6CP_MYIFID_DYN /* * When doing dynamic address assignment, * we accept his offer. */ if (sp->ipv6cp.flags & IPV6CP_MYIFID_DYN) { struct in6_addr lastsuggest; /* * If equals to * , * we have a collision. generate new random * ifid. */ sppp_suggest_ip6_addr(&lastsuggest); if (IN6_ARE_ADDR_EQUAL(&suggestaddr, lastsuggest)) { if (debug) addlog(" [random]"); sppp_gen_ip6_addr(sp, &suggestaddr); } sppp_set_ip6_addr(sp, &suggestaddr, 0); if (debug) addlog(" [agree]"); sp->ipv6cp.flags |= IPV6CP_MYIFID_SEEN; } #else /* * Since we do not do dynamic address assignment, * we ignore it and thus continue to negotiate * our already existing value. This can possibly * go into infinite request-reject loop. * * This is not likely because we normally use * ifid based on MAC-address. * If you have no ethernet card on the node, too bad. * XXX should we use fail_counter? */ #endif break; #ifdef notyet case IPV6CP_OPT_COMPRESS: /* * Peer wants different compression parameters. */ break; #endif } } if (debug) addlog("\n"); end: return; } static void sppp_ipv6cp_tlu(struct sppp *sp) { struct ifnet *ifp; KASSERT(SPPP_WLOCKED(sp)); SPPP_LOG(sp, LOG_INFO, "IPv6CP layer up\n"); ifp = &sp->pp_if; /* we are up - notify isdn daemon */ sppp_notify_con_wlocked(sp); rt_ifmsg(ifp); } static void sppp_ipv6cp_tld(struct sppp *sp) { struct ifnet *ifp; KASSERT(SPPP_WLOCKED(sp)); SPPP_LOG(sp, LOG_INFO, "IPv6CP layer down\n"); ifp = &sp->pp_if; rt_ifmsg(ifp); } static void sppp_ipv6cp_scr(struct sppp *sp) { char opt[10 /* ifid */ + 4 /* compression, minimum */]; struct in6_addr ouraddr; int i = 0; KASSERT(SPPP_WLOCKED(sp)); if (ISSET(sp->ipv6cp.opts, SPPP_IPV6CP_OPT_IFID)) { sppp_get_ip6_addrs(sp, &ouraddr, 0, 0); opt[i++] = IPV6CP_OPT_IFID; opt[i++] = 10; memcpy(&opt[i], &ouraddr.s6_addr[8], 8); i += 8; } #ifdef notyet if (ISSET(sp->ipv6cp.opts, SPPP_IPV6CP_OPT_COMPRESSION)) { opt[i++] = IPV6CP_OPT_COMPRESSION; opt[i++] = 4; opt[i++] = 0; /* TBD */ opt[i++] = 0; /* TBD */ /* variable length data may follow */ } #endif sp->scp[IDX_IPV6CP].confid = ++sp->scp[IDX_IPV6CP].seq; sppp_cp_send(sp, PPP_IPV6CP, CONF_REQ, sp->scp[IDX_IPV6CP].confid, i, &opt); } #else /*INET6*/ static void sppp_ipv6cp_init(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); } static void sppp_ipv6cp_open(struct sppp *sp, void *xcp) { KASSERT(SPPP_WLOCKED(sp)); } static enum cp_rcr_type sppp_ipv6cp_confreq(struct sppp *sp, struct lcp_header *h, int len, uint8_t **msgbuf, size_t *buflen, size_t *msglen) { KASSERT(SPPP_WLOCKED(sp)); return 0; } static void sppp_ipv6cp_confrej(struct sppp *sp, struct lcp_header *h, int len) { KASSERT(SPPP_WLOCKED(sp)); } static void sppp_ipv6cp_confnak(struct sppp *sp, struct lcp_header *h, int len) { KASSERT(SPPP_WLOCKED(sp)); } static void sppp_ipv6cp_tlu(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); } static void sppp_ipv6cp_tld(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); } static void sppp_ipv6cp_scr(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); } #endif /*INET6*/ /* *--------------------------------------------------------------------------* * * * The CHAP implementation. * * * *--------------------------------------------------------------------------* */ /* * The authentication protocols is implemented on the state machine for * control protocols. And it uses following actions and events. * * Actions: * - scr: send CHAP_CHALLENGE and CHAP_RESPONSE * - sca: send CHAP_SUCCESS * - scn: send CHAP_FAILURE and shutdown lcp * Events: * - RCR+: receive CHAP_RESPONSE containing correct digest * - RCR-: receive CHAP_RESPONSE containing wrong digest * - RCA: receive CHAP_SUCCESS * - RCN: (this event is unused) * - TO+: re-send CHAP_CHALLENGE and CHAP_RESPONSE * - TO-: this layer finish */ /* * Handle incoming CHAP packets. */ void sppp_chap_input(struct sppp *sp, struct mbuf *m) { struct ifnet *ifp; struct lcp_header *h; int len, x; u_char *value, *name, digest[sizeof(sp->chap.challenge)]; int value_len, name_len; MD5_CTX ctx; char abuf[SPPP_AUTHTYPE_NAMELEN]; const char *authname; bool debug; ifp = &sp->pp_if; debug = sppp_debug_enabled(sp); len = m->m_pkthdr.len; if (len < 4) { SPPP_DLOG(sp, "chap invalid packet length: " "%d bytes\n", len); return; } h = mtod(m, struct lcp_header *); if (len > ntohs(h->len)) len = ntohs(h->len); SPPP_LOCK(sp, RW_WRITER); switch (h->type) { /* challenge, failure and success are his authproto */ case CHAP_CHALLENGE: if (sp->myauth.secret == NULL || sp->myauth.name == NULL) { /* can't do anything useful */ sp->pp_auth_failures++; SPPP_DLOG(sp, "chap input " "without my name and my secret being set\n"); break; } value = 1 + (u_char *)(h + 1); value_len = value[-1]; name = value + value_len; name_len = len - value_len - 5; if (name_len < 0) { if (debug) { authname = sppp_auth_type_name(abuf, sizeof(abuf), PPP_CHAP, h->type); SPPP_LOG(sp, LOG_DEBUG, "chap corrupted challenge " "<%s id=0x%x len=%d", authname, h->ident, ntohs(h->len)); if (len > 4) sppp_print_bytes((u_char *)(h + 1), len - 4); addlog(">\n"); } break; } if (debug) { authname = sppp_auth_type_name(abuf, sizeof(abuf), PPP_CHAP, h->type); SPPP_LOG(sp, LOG_DEBUG, "chap input <%s id=0x%x len=%d name=", authname, h->ident, ntohs(h->len)); sppp_print_string((char *) name, name_len); addlog(" value-size=%d value=", value_len); sppp_print_bytes(value, value_len); addlog(">\n"); } /* Compute reply value. */ MD5Init(&ctx); MD5Update(&ctx, &h->ident, 1); MD5Update(&ctx, sp->myauth.secret, sp->myauth.secret_len); MD5Update(&ctx, value, value_len); MD5Final(sp->chap.digest, &ctx); sp->chap.digest_len = sizeof(sp->chap.digest); sp->scp[IDX_CHAP].rconfid = h->ident; sppp_wq_add(sp->wq_cp, &sp->chap.work_challenge_rcvd); break; case CHAP_SUCCESS: if (debug) { SPPP_LOG(sp, LOG_DEBUG, "chap success"); if (len > 4) { addlog(": "); sppp_print_string((char *)(h + 1), len - 4); } addlog("\n"); } if (h->ident != sp->scp[IDX_CHAP].rconfid) { SPPP_DLOG(sp, "%s id mismatch 0x%x != 0x%x\n", chap.name, h->ident, sp->scp[IDX_CHAP].rconfid); if_statinc(ifp, if_ierrors); break; } if (sp->chap.digest_len == 0) { SPPP_DLOG(sp, "receive CHAP success" " without challenge\n"); if_statinc(ifp, if_ierrors); break; } x = splnet(); sp->pp_auth_failures = 0; sp->pp_flags &= ~PP_NEEDAUTH; splx(x); memset(sp->chap.digest, 0, sizeof(sp->chap.digest)); sp->chap.digest_len = 0; if (!ISSET(sppp_auth_role(&chap, sp), SPPP_AUTH_SERV)) { /* * we are not authenticator for CHAP, * generate a dummy RCR+ event without CHAP_RESPONSE */ sp->scp[IDX_CHAP].rcr_type = CP_RCR_ACK; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_CHAP].work_rcr); } sppp_wq_add(sp->wq_cp, &sp->scp[IDX_CHAP].work_rca); break; case CHAP_FAILURE: if (h->ident != sp->scp[IDX_CHAP].rconfid) { SPPP_DLOG(sp, "%s id mismatch 0x%x != 0x%x\n", chap.name, h->ident, sp->scp[IDX_CHAP].rconfid); if_statinc(ifp, if_ierrors); break; } if (sp->chap.digest_len == 0) { SPPP_DLOG(sp, "receive CHAP failure " "without challenge\n"); if_statinc(ifp, if_ierrors); break; } x = splnet(); sp->pp_auth_failures++; splx(x); SPPP_LOG(sp, LOG_INFO, "chap failure"); if (debug) { if (len > 4) { addlog(": "); sppp_print_string((char *)(h + 1), len - 4); } } addlog("\n"); memset(sp->chap.digest, 0, sizeof(sp->chap.digest)); sp->chap.digest_len = 0; /* * await LCP shutdown by authenticator, * so we don't have to enqueue sc->scp[IDX_CHAP].work_rcn */ break; /* response is my authproto */ case CHAP_RESPONSE: if (sp->hisauth.name == NULL || sp->hisauth.secret == NULL) { /* can't do anything useful */ SPPP_DLOG(sp, "chap response " "without his name and his secret being set\n"); break; } value = 1 + (u_char *)(h + 1); value_len = value[-1]; name = value + value_len; name_len = len - value_len - 5; if (name_len < 0) { if (debug) { authname = sppp_auth_type_name(abuf, sizeof(abuf), PPP_CHAP, h->type); SPPP_LOG(sp, LOG_DEBUG, "chap corrupted response " "<%s id=0x%x len=%d", authname, h->ident, ntohs(h->len)); if (len > 4) sppp_print_bytes((u_char *)(h + 1), len - 4); addlog(">\n"); } break; } if (h->ident != sp->scp[IDX_CHAP].confid) { SPPP_DLOG(sp, "chap dropping response for old ID " "(got %d, expected %d)\n", h->ident, sp->scp[IDX_CHAP].confid); break; } else { sp->scp[IDX_CHAP].rconfid = h->ident; } if (sp->hisauth.name != NULL && (name_len != sp->hisauth.name_len || memcmp(name, sp->hisauth.name, name_len) != 0)) { SPPP_LOG(sp, LOG_INFO, "chap response, his name "); sppp_print_string(name, name_len); addlog(" != expected "); sppp_print_string(sp->hisauth.name, sp->hisauth.name_len); addlog("\n"); /* generate RCR- event */ sp->scp[IDX_CHAP].rcr_type = CP_RCR_NAK; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_CHAP].work_rcr); break; } if (debug) { authname = sppp_auth_type_name(abuf, sizeof(abuf), PPP_CHAP, h->type); SPPP_LOG(sp, LOG_DEBUG, "chap input(%s) " "<%s id=0x%x len=%d name=", sppp_state_name(sp->scp[IDX_CHAP].state), authname, h->ident, ntohs(h->len)); sppp_print_string((char *)name, name_len); addlog(" value-size=%d value=", value_len); sppp_print_bytes(value, value_len); addlog(">\n"); } if (value_len == sizeof(sp->chap.challenge) && value_len == sizeof(sp->chap.digest)) { MD5Init(&ctx); MD5Update(&ctx, &h->ident, 1); MD5Update(&ctx, sp->hisauth.secret, sp->hisauth.secret_len); MD5Update(&ctx, sp->chap.challenge, sizeof(sp->chap.challenge)); MD5Final(digest, &ctx); if (memcmp(digest, value, value_len) == 0) { sp->scp[IDX_CHAP].rcr_type = CP_RCR_ACK; } else { sp->scp[IDX_CHAP].rcr_type = CP_RCR_NAK; } } else { if (debug) { SPPP_LOG(sp, LOG_DEBUG, "chap bad hash value length: " "%d bytes, should be %zu\n", value_len, sizeof(sp->chap.challenge)); } sp->scp[IDX_CHAP].rcr_type = CP_RCR_NAK; } sppp_wq_add(sp->wq_cp, &sp->scp[IDX_CHAP].work_rcr); /* generate a dummy RCA event */ if (sp->scp[IDX_CHAP].rcr_type == CP_RCR_ACK && (!ISSET(sppp_auth_role(&chap, sp), SPPP_AUTH_PEER) || sp->chap.rechallenging)) { sppp_wq_add(sp->wq_cp, &sp->scp[IDX_CHAP].work_rca); } break; default: /* Unknown CHAP packet type -- ignore. */ if (debug) { SPPP_LOG(sp, LOG_DEBUG, "chap unknown input(%s) " "<0x%x id=0x%xh len=%d", sppp_state_name(sp->scp[IDX_CHAP].state), h->type, h->ident, ntohs(h->len)); if (len > 4) sppp_print_bytes((u_char *)(h + 1), len - 4); addlog(">\n"); } break; } SPPP_UNLOCK(sp); } static void sppp_chap_init(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); sppp_cp_init(&chap, sp); SPPP_WQ_SET(&sp->chap.work_challenge_rcvd, sppp_chap_rcv_challenge_event, &chap); } static void sppp_chap_open(struct sppp *sp, void *xcp) { KASSERT(SPPP_WLOCKED(sp)); memset(sp->chap.digest, 0, sizeof(sp->chap.digest)); sp->chap.digest_len = 0; sp->chap.rechallenging = false; sp->chap.response_rcvd = false; sppp_open_event(sp, xcp); } static void sppp_chap_tlu(struct sppp *sp) { int i, x; KASSERT(SPPP_WLOCKED(sp)); i = 0; sp->scp[IDX_CHAP].rst_counter = sp->lcp.max_configure; x = splnet(); sp->pp_auth_failures = 0; splx(x); SPPP_LOG(sp, LOG_DEBUG, "chap %s", sp->pp_phase == SPPP_PHASE_NETWORK ? "reconfirmed" : "tlu"); /* * Some broken CHAP implementations (Conware CoNet, firmware * 4.0.?) don't want to re-authenticate their CHAP once the * initial challenge-response exchange has taken place. * Provide for an option to avoid rechallenges. */ if (ISSET(sppp_auth_role(&chap, sp), SPPP_AUTH_SERV) && (sp->hisauth.flags & SPPP_AUTHFLAG_NORECHALLENGE) == 0) { /* * Compute the re-challenge timeout. This will yield * a number between 300 and 810 seconds. */ i = 300 + ((unsigned)(cprng_fast32() & 0xff00) >> 7); callout_schedule(&sp->scp[IDX_CHAP].ch, i * hz); if (sppp_debug_enabled(sp)) { addlog(", next rechallenge in %d seconds", i); } } addlog("\n"); /* * If we are already in phase network, we are done here. This * is the case if this is a dummy tlu event after a re-challenge. */ if (sp->pp_phase != SPPP_PHASE_NETWORK) sppp_phase_network(sp); } static void sppp_chap_scr(struct sppp *sp) { uint32_t *ch; u_char clen, dsize; int role; KASSERT(SPPP_WLOCKED(sp)); role = sppp_auth_role(&chap, sp); if (ISSET(role, SPPP_AUTH_SERV) && !sp->chap.response_rcvd) { /* we are authenticator for CHAP, send challenge */ ch = (uint32_t *)sp->chap.challenge; clen = sizeof(sp->chap.challenge); /* Compute random challenge. */ cprng_strong(kern_cprng, ch, clen, 0); sp->scp[IDX_CHAP].confid = ++sp->scp[IDX_CHAP].seq; sppp_auth_send(&chap, sp, CHAP_CHALLENGE, sp->scp[IDX_CHAP].confid, sizeof(clen), (const char *)&clen, sizeof(sp->chap.challenge), sp->chap.challenge, 0); } if (ISSET(role, SPPP_AUTH_PEER) && sp->chap.digest_len > 0) { /* we are peer for CHAP, send response */ dsize = sp->chap.digest_len; sppp_auth_send(&chap, sp, CHAP_RESPONSE, sp->scp[IDX_CHAP].rconfid, sizeof(dsize), (const char *)&dsize, sp->chap.digest_len, sp->chap.digest, sp->myauth.name_len, sp->myauth.name, 0); } } static void sppp_chap_rcv_challenge_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; KASSERT(!cpu_softintr_p()); sp->chap.rechallenging = false; switch (sp->scp[IDX_CHAP].state) { case STATE_REQ_SENT: sppp_cp_change_state(cp, sp, STATE_REQ_SENT); cp->scr(sp); break; case STATE_OPENED: sppp_cp_change_state(cp, sp, STATE_ACK_SENT); cp->scr(sp); break; } } /* *--------------------------------------------------------------------------* * * * The PAP implementation. * * * *--------------------------------------------------------------------------* */ /* * PAP uses following actions and events. * Actions: * - scr: send PAP_REQ * - sca: send PAP_ACK * - scn: send PAP_NAK * Events: * - RCR+: receive PAP_REQ containing correct username and password * - RCR-: receive PAP_REQ containing wrong username and password * - RCA: receive PAP_ACK * - RCN: (this event is unused) * - TO+: re-send PAP_REQ * - TO-: this layer finish */ /* * Handle incoming PAP packets. */ static void sppp_pap_input(struct sppp *sp, struct mbuf *m) { struct ifnet *ifp; struct lcp_header *h; int len, x; char *name, *secret; int name_len, secret_len; char abuf[SPPP_AUTHTYPE_NAMELEN]; const char *authname; bool debug; ifp = &sp->pp_if; debug = sppp_debug_enabled(sp); /* * Malicious input might leave this uninitialized, so * init to an impossible value. */ secret_len = -1; len = m->m_pkthdr.len; if (len < 5) { SPPP_DLOG(sp, "pap invalid packet length: " "%d bytes\n", len); return; } h = mtod(m, struct lcp_header *); if (len > ntohs(h->len)) len = ntohs(h->len); SPPP_LOCK(sp, RW_WRITER); switch (h->type) { /* PAP request is my authproto */ case PAP_REQ: if (sp->hisauth.name == NULL || sp->hisauth.secret == NULL) { /* can't do anything useful */ SPPP_DLOG(sp, "pap request" " without his name and his secret being set\n"); break; } name = 1 + (u_char *)(h + 1); name_len = name[-1]; secret = name + name_len + 1; if (name_len > len - 6 || (secret_len = secret[-1]) > len - 6 - name_len) { if (debug) { authname = sppp_auth_type_name(abuf, sizeof(abuf), PPP_PAP, h->type); SPPP_LOG(sp, LOG_DEBUG, "pap corrupted input " "<%s id=0x%x len=%d", authname, h->ident, ntohs(h->len)); if (len > 4) sppp_print_bytes((u_char *)(h + 1), len - 4); addlog(">\n"); } break; } if (debug) { authname = sppp_auth_type_name(abuf, sizeof(abuf), PPP_PAP, h->type); SPPP_LOG(sp, LOG_DEBUG, "pap input(%s) " "<%s id=0x%x len=%d name=", sppp_state_name(sp->scp[IDX_PAP].state), authname, h->ident, ntohs(h->len)); sppp_print_string((char *)name, name_len); addlog(" secret="); sppp_print_string((char *)secret, secret_len); addlog(">\n"); } sp->scp[IDX_PAP].rconfid = h->ident; if (name_len == sp->hisauth.name_len && memcmp(name, sp->hisauth.name, name_len) == 0 && secret_len == sp->hisauth.secret_len && memcmp(secret, sp->hisauth.secret, secret_len) == 0) { sp->scp[IDX_PAP].rcr_type = CP_RCR_ACK; } else { sp->scp[IDX_PAP].rcr_type = CP_RCR_NAK; } sppp_wq_add(sp->wq_cp, &sp->scp[IDX_PAP].work_rcr); /* generate a dummy RCA event */ if (sp->scp[IDX_PAP].rcr_type == CP_RCR_ACK && !ISSET(sppp_auth_role(&pap, sp), SPPP_AUTH_PEER)) { sppp_wq_add(sp->wq_cp, &sp->scp[IDX_PAP].work_rca); } break; /* ack and nak are his authproto */ case PAP_ACK: if (debug) { SPPP_LOG(sp, LOG_DEBUG, "pap success"); name = 1 + (u_char *)(h + 1); name_len = name[-1]; if (len > 5 && name_len < len+4) { addlog(": "); sppp_print_string(name, name_len); } addlog("\n"); } if (h->ident != sp->scp[IDX_PAP].confid) { SPPP_DLOG(sp, "%s id mismatch 0x%x != 0x%x\n", pap.name, h->ident, sp->scp[IDX_PAP].rconfid); if_statinc(ifp, if_ierrors); break; } x = splnet(); sp->pp_auth_failures = 0; sp->pp_flags &= ~PP_NEEDAUTH; splx(x); /* we are not authenticator, generate a dummy RCR+ event */ if (!ISSET(sppp_auth_role(&pap, sp), SPPP_AUTH_SERV)) { sp->scp[IDX_PAP].rcr_type = CP_RCR_ACK; sppp_wq_add(sp->wq_cp, &sp->scp[IDX_PAP].work_rcr); } sppp_wq_add(sp->wq_cp, &sp->scp[IDX_PAP].work_rca); break; case PAP_NAK: if (debug) { SPPP_LOG(sp, LOG_INFO, "pap failure"); name = 1 + (u_char *)(h + 1); name_len = name[-1]; if (len > 5 && name_len < len+4) { addlog(": "); sppp_print_string(name, name_len); } addlog("\n"); } else { SPPP_LOG(sp, LOG_INFO, "pap failure\n"); } if (h->ident != sp->scp[IDX_PAP].confid) { SPPP_DLOG(sp, "%s id mismatch 0x%x != 0x%x\n", pap.name, h->ident, sp->scp[IDX_PAP].rconfid); if_statinc(ifp, if_ierrors); break; } sp->pp_auth_failures++; /* * await LCP shutdown by authenticator, * so we don't have to enqueue sc->scp[IDX_PAP].work_rcn */ break; default: /* Unknown PAP packet type -- ignore. */ if (debug) { SPPP_LOG(sp, LOG_DEBUG, "pap corrupted input " "<0x%x id=0x%x len=%d", h->type, h->ident, ntohs(h->len)); if (len > 4) sppp_print_bytes((u_char *)(h + 1), len - 4); addlog(">\n"); } break; } SPPP_UNLOCK(sp); } static void sppp_pap_init(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); sppp_cp_init(&pap, sp); } static void sppp_pap_tlu(struct sppp *sp) { int x; SPPP_DLOG(sp, "%s tlu\n", pap.name); sp->scp[IDX_PAP].rst_counter = sp->lcp.max_configure; x = splnet(); sp->pp_auth_failures = 0; splx(x); if (sp->pp_phase < SPPP_PHASE_NETWORK) sppp_phase_network(sp); } static void sppp_pap_scr(struct sppp *sp) { u_char idlen, pwdlen; KASSERT(SPPP_WLOCKED(sp)); if (ISSET(sppp_auth_role(&pap, sp), SPPP_AUTH_PEER) && sp->scp[IDX_PAP].state != STATE_ACK_RCVD) { if (sp->myauth.secret == NULL || sp->myauth.name == NULL) { SPPP_LOG(sp, LOG_DEBUG, "couldn't send PAP_REQ " "because of no name or no secret\n"); } else { sp->scp[IDX_PAP].confid = ++sp->scp[IDX_PAP].seq; pwdlen = sp->myauth.secret_len; idlen = sp->myauth.name_len; sppp_auth_send(&pap, sp, PAP_REQ, sp->scp[IDX_PAP].confid, sizeof idlen, (const char *)&idlen, idlen, sp->myauth.name, sizeof pwdlen, (const char *)&pwdlen, pwdlen, sp->myauth.secret, 0); } } } /* * Random miscellaneous functions. */ /* * Send a PAP or CHAP proto packet. * * Varadic function, each of the elements for the ellipsis is of type * ``size_t mlen, const u_char *msg''. Processing will stop iff * mlen == 0. * NOTE: never declare variadic functions with types subject to type * promotion (i.e. u_char). This is asking for big trouble depending * on the architecture you are on... */ static void sppp_auth_send(const struct cp *cp, struct sppp *sp, unsigned int type, unsigned int id, ...) { struct ifnet *ifp; struct lcp_header *lh; struct mbuf *m; u_char *p; int len; size_t pkthdrlen; unsigned int mlen; const char *msg; va_list ap; KASSERT(SPPP_WLOCKED(sp)); ifp = &sp->pp_if; MGETHDR(m, M_DONTWAIT, MT_DATA); if (! m) return; m_reset_rcvif(m); if (sp->pp_flags & PP_NOFRAMING) { *mtod(m, uint16_t *) = htons(cp->proto); pkthdrlen = 2; lh = (struct lcp_header *)(mtod(m, uint8_t *)+2); } else { struct ppp_header *h; h = mtod(m, struct ppp_header *); h->address = PPP_ALLSTATIONS; /* broadcast address */ h->control = PPP_UI; /* Unnumbered Info */ h->protocol = htons(cp->proto); pkthdrlen = PPP_HEADER_LEN; lh = (struct lcp_header *)(h + 1); } lh->type = type; lh->ident = id; p = (u_char *)(lh + 1); va_start(ap, id); len = 0; while ((mlen = (unsigned int)va_arg(ap, size_t)) != 0) { msg = va_arg(ap, const char *); len += mlen; if (len > MHLEN - pkthdrlen - LCP_HEADER_LEN) { va_end(ap); m_freem(m); return; } memcpy(p, msg, mlen); p += mlen; } va_end(ap); m->m_pkthdr.len = m->m_len = pkthdrlen + LCP_HEADER_LEN + len; lh->len = htons(LCP_HEADER_LEN + len); if (sppp_debug_enabled(sp)) { char abuf[SPPP_AUTHTYPE_NAMELEN]; const char *authname; authname = sppp_auth_type_name(abuf, sizeof(abuf), cp->proto, lh->type); SPPP_LOG(sp, LOG_DEBUG, "%s output <%s id=0x%x len=%d", cp->name, authname, lh->ident, ntohs(lh->len)); if (len) sppp_print_bytes((u_char *)(lh + 1), len); addlog(">\n"); } if (IF_QFULL(&sp->pp_cpq)) { IF_DROP(&sp->pp_fastq); IF_DROP(&ifp->if_snd); m_freem(m); if_statinc(ifp, if_oerrors); return; } if_statadd(ifp, if_obytes, m->m_pkthdr.len + sp->pp_framebytes); IF_ENQUEUE(&sp->pp_cpq, m); if (! (ifp->if_flags & IFF_OACTIVE)) { SPPP_UNLOCK(sp); if_start_lock(ifp); SPPP_LOCK(sp, RW_WRITER); } } static int sppp_auth_role(const struct cp *cp, struct sppp *sp) { int role; role = SPPP_AUTH_NOROLE; if (sp->hisauth.proto == cp->proto && ISSET(sp->lcp.opts, SPPP_LCP_OPT_AUTH_PROTO)) SET(role, SPPP_AUTH_SERV); if (sp->myauth.proto == cp->proto) SET(role, SPPP_AUTH_PEER); return role; } static void sppp_auth_to_event(struct sppp *sp, void *xcp) { const struct cp *cp = xcp; bool override; int state; KASSERT(SPPP_WLOCKED(sp)); KASSERT(!cpu_softintr_p()); override = false; state = sp->scp[cp->protoidx].state; if (sp->scp[cp->protoidx].rst_counter > 0) { /* override TO+ event */ switch (state) { case STATE_OPENED: if ((sp->hisauth.flags & SPPP_AUTHFLAG_NORECHALLENGE) == 0) { override = true; sp->chap.rechallenging = true; sp->chap.response_rcvd = false; sppp_cp_change_state(cp, sp, STATE_REQ_SENT); cp->scr(sp); } break; case STATE_ACK_RCVD: override = true; cp->scr(sp); callout_schedule(&sp->scp[cp->protoidx].ch, sp->lcp.timeout); break; } } if (override) { SPPP_DLOG(sp, "%s TO(%s) rst_counter = %d\n", cp->name, sppp_state_name(state), sp->scp[cp->protoidx].rst_counter); sp->scp[cp->protoidx].rst_counter--; } else { sppp_to_event(sp, xcp); } } static void sppp_auth_screply(const struct cp *cp, struct sppp *sp, u_char ctype, uint8_t ident, size_t _mlen __unused, void *_msg __unused) { static const char *succmsg = "Welcome!"; static const char *failmsg = "Failed..."; const char *msg; u_char type, mlen; KASSERT(SPPP_WLOCKED(sp)); if (!ISSET(sppp_auth_role(cp, sp), SPPP_AUTH_SERV)) return; if (ctype == CONF_ACK) { type = cp->proto == PPP_CHAP ? CHAP_SUCCESS : PAP_ACK; msg = succmsg; mlen = sizeof(succmsg) - 1; sp->pp_auth_failures = 0; } else { type = cp->proto == PPP_CHAP ? CHAP_FAILURE : PAP_NAK; msg = failmsg; mlen = sizeof(failmsg) - 1; /* shutdown LCP if auth failed */ sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); sp->pp_auth_failures++; } sppp_auth_send(cp, sp, type, ident, mlen, (const u_char *)msg, 0); } /* * Send keepalive packets, every 10 seconds. */ static void sppp_keepalive(void *dummy) { struct sppp *sp; int s; time_t now; SPPPQ_LOCK(); s = splnet(); now = time_uptime; for (sp=spppq; sp; sp=sp->pp_next) { struct ifnet *ifp = NULL; SPPP_LOCK(sp, RW_WRITER); ifp = &sp->pp_if; /* check idle timeout */ if ((sp->pp_idle_timeout != 0) && (ifp->if_flags & IFF_RUNNING) && (sp->pp_phase == SPPP_PHASE_NETWORK)) { /* idle timeout is enabled for this interface */ if ((now-sp->pp_last_activity) >= sp->pp_idle_timeout) { SPPP_DLOG(sp, "no activity for %lu seconds\n", (unsigned long)(now-sp->pp_last_activity)); sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); SPPP_UNLOCK(sp); continue; } } /* Keepalive mode disabled or channel down? */ if (! (sp->pp_flags & PP_KEEPALIVE) || ! (ifp->if_flags & IFF_RUNNING)) { SPPP_UNLOCK(sp); continue; } /* No keepalive in PPP mode if LCP not opened yet. */ if (sp->pp_phase < SPPP_PHASE_AUTHENTICATE) { SPPP_UNLOCK(sp); continue; } /* No echo reply, but maybe user data passed through? */ if (sp->pp_max_noreceive != 0 && (now - sp->pp_last_receive) < sp->pp_max_noreceive) { sp->pp_alivecnt = 0; SPPP_UNLOCK(sp); continue; } /* No echo request */ if (sp->pp_alive_interval == 0) { SPPP_UNLOCK(sp); continue; } /* send a ECHO_REQ once in sp->pp_alive_interval times */ if ((sppp_keepalive_cnt % sp->pp_alive_interval) != 0) { SPPP_UNLOCK(sp); continue; } if (sp->pp_alivecnt >= sp->pp_maxalive) { /* No keepalive packets got. Stop the interface. */ if (sp->pp_flags & PP_KEEPALIVE_IFDOWN) sppp_wq_add(sp->wq_cp, &sp->work_ifdown); SPPP_LOG(sp, LOG_INFO,"LCP keepalive timed out, " "going to restart the connection\n"); sp->pp_alivecnt = 0; /* we are down, close all open protocols */ sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_close); /* And now prepare LCP to reestablish the link, if configured to do so. */ sp->lcp.reestablish = true; SPPP_UNLOCK(sp); continue; } if (sp->pp_alivecnt < sp->pp_maxalive) ++sp->pp_alivecnt; if (sp->pp_phase >= SPPP_PHASE_AUTHENTICATE) { int32_t nmagic = htonl(sp->lcp.magic); sp->lcp.echoid = ++sp->scp[IDX_LCP].seq; sppp_cp_send(sp, PPP_LCP, ECHO_REQ, sp->lcp.echoid, 4, &nmagic); } SPPP_UNLOCK(sp); } splx(s); sppp_keepalive_cnt++; callout_reset(&keepalive_ch, hz * SPPP_KEEPALIVE_INTERVAL, sppp_keepalive, NULL); SPPPQ_UNLOCK(); } #ifdef INET /* * Get both IP addresses. */ static void sppp_get_ip_addrs(struct sppp *sp, uint32_t *src, uint32_t *dst, uint32_t *srcmask) { struct ifnet *ifp = &sp->pp_if; struct ifaddr *ifa; struct sockaddr_in *si, *sm; uint32_t ssrc, ddst; int bound, s; struct psref psref; sm = NULL; ssrc = ddst = 0; /* * Pick the first AF_INET address from the list, * aliases don't make any sense on a p2p link anyway. */ si = 0; bound = curlwp_bind(); s = pserialize_read_enter(); IFADDR_READER_FOREACH(ifa, ifp) { if (ifa->ifa_addr->sa_family == AF_INET) { si = (struct sockaddr_in *)ifa->ifa_addr; sm = (struct sockaddr_in *)ifa->ifa_netmask; if (si) { ifa_acquire(ifa, &psref); break; } } } pserialize_read_exit(s); if (ifa) { if (si && si->sin_addr.s_addr) { ssrc = si->sin_addr.s_addr; if (srcmask) *srcmask = ntohl(sm->sin_addr.s_addr); } si = (struct sockaddr_in *)ifa->ifa_dstaddr; if (si && si->sin_addr.s_addr) ddst = si->sin_addr.s_addr; ifa_release(ifa, &psref); } curlwp_bindx(bound); if (dst) *dst = ntohl(ddst); if (src) *src = ntohl(ssrc); } /* * Set IP addresses. Must be called at splnet. * If an address is 0, leave it the way it is. */ static void sppp_set_ip_addrs(struct sppp *sp) { struct ifnet *ifp; struct ifaddr *ifa; struct sockaddr_in *si, *dest; uint32_t myaddr = 0, hisaddr = 0; int s; KASSERT(SPPP_WLOCKED(sp)); ifp = &sp->pp_if; SPPP_UNLOCK(sp); IFNET_LOCK(ifp); SPPP_LOCK(sp, RW_WRITER); /* * Pick the first AF_INET address from the list, * aliases don't make any sense on a p2p link anyway. */ si = dest = NULL; s = pserialize_read_enter(); IFADDR_READER_FOREACH(ifa, ifp) { if (ifa->ifa_addr->sa_family == AF_INET) { si = (struct sockaddr_in *)ifa->ifa_addr; dest = (struct sockaddr_in *)ifa->ifa_dstaddr; break; } } pserialize_read_exit(s); if ((sp->ipcp.flags & IPCP_MYADDR_DYN) && (sp->ipcp.flags & IPCP_MYADDR_SEEN)) myaddr = sp->ipcp.req_myaddr; else if (si != NULL) myaddr = ntohl(si->sin_addr.s_addr); if ((sp->ipcp.flags & IPCP_HISADDR_DYN) && (sp->ipcp.flags & IPCP_HISADDR_SEEN)) hisaddr = sp->ipcp.req_hisaddr; else if (dest != NULL) hisaddr = ntohl(dest->sin_addr.s_addr); if (si != NULL && dest != NULL) { int error; struct sockaddr_in new_sin = *si; struct sockaddr_in new_dst = *dest; if (myaddr != 0) new_sin.sin_addr.s_addr = htonl(myaddr); if (hisaddr != 0) { new_dst.sin_addr.s_addr = htonl(hisaddr); if (new_dst.sin_addr.s_addr != dest->sin_addr.s_addr) sp->ipcp.saved_hisaddr = dest->sin_addr.s_addr; } in_addrhash_remove(ifatoia(ifa)); error = in_ifinit(ifp, ifatoia(ifa), &new_sin, &new_dst, 0); in_addrhash_insert(ifatoia(ifa)); if (error) { SPPP_DLOG(sp, "%s: in_ifinit failed, error=%d\n", __func__, error); } else { pfil_run_addrhooks(if_pfil, SIOCAIFADDR, ifa); } } IFNET_UNLOCK(ifp); sppp_notify_con(sp); } /* * Clear IP addresses. Must be called at splnet. */ static void sppp_clear_ip_addrs(struct sppp *sp) { struct ifnet *ifp; struct ifaddr *ifa; struct sockaddr_in *si, *dest; int s; KASSERT(SPPP_WLOCKED(sp)); ifp = &sp->pp_if; SPPP_UNLOCK(sp); IFNET_LOCK(ifp); SPPP_LOCK(sp, RW_WRITER); /* * Pick the first AF_INET address from the list, * aliases don't make any sense on a p2p link anyway. */ si = dest = NULL; s = pserialize_read_enter(); IFADDR_READER_FOREACH(ifa, ifp) { if (ifa->ifa_addr->sa_family == AF_INET) { si = (struct sockaddr_in *)ifa->ifa_addr; dest = (struct sockaddr_in *)ifa->ifa_dstaddr; break; } } pserialize_read_exit(s); if (si != NULL) { struct sockaddr_in new_sin = *si; struct sockaddr_in new_dst = *dest; int error; if (sp->ipcp.flags & IPCP_MYADDR_DYN) new_sin.sin_addr.s_addr = 0; if (sp->ipcp.flags & IPCP_HISADDR_DYN && ntohl(sp->ipcp.saved_hisaddr) != 0) new_dst.sin_addr.s_addr = sp->ipcp.saved_hisaddr; in_addrhash_remove(ifatoia(ifa)); error = in_ifinit(ifp, ifatoia(ifa), &new_sin, &new_dst, 0); in_addrhash_insert(ifatoia(ifa)); if (error) { SPPP_DLOG(sp, "%s: in_ifinit failed, error=%d\n", __func__, error); } else { pfil_run_addrhooks(if_pfil, SIOCAIFADDR, ifa); } } IFNET_UNLOCK(ifp); } #endif #ifdef INET6 /* * Get both IPv6 addresses. */ static void sppp_get_ip6_addrs(struct sppp *sp, struct in6_addr *src, struct in6_addr *dst, struct in6_addr *srcmask) { struct ifnet *ifp = &sp->pp_if; struct ifaddr *ifa; struct sockaddr_in6 *si, *sm; struct in6_addr ssrc, ddst; int bound, s; struct psref psref; sm = NULL; memset(&ssrc, 0, sizeof(ssrc)); memset(&ddst, 0, sizeof(ddst)); /* * Pick the first link-local AF_INET6 address from the list, * aliases don't make any sense on a p2p link anyway. */ si = 0; bound = curlwp_bind(); s = pserialize_read_enter(); IFADDR_READER_FOREACH(ifa, ifp) { if (ifa->ifa_addr->sa_family == AF_INET6) { si = (struct sockaddr_in6 *)ifa->ifa_addr; sm = (struct sockaddr_in6 *)ifa->ifa_netmask; if (si && IN6_IS_ADDR_LINKLOCAL(&si->sin6_addr)) { ifa_acquire(ifa, &psref); break; } } } pserialize_read_exit(s); if (ifa) { if (si && !IN6_IS_ADDR_UNSPECIFIED(&si->sin6_addr)) { memcpy(&ssrc, &si->sin6_addr, sizeof(ssrc)); if (srcmask) { memcpy(srcmask, &sm->sin6_addr, sizeof(*srcmask)); } } si = (struct sockaddr_in6 *)ifa->ifa_dstaddr; if (si && !IN6_IS_ADDR_UNSPECIFIED(&si->sin6_addr)) memcpy(&ddst, &si->sin6_addr, sizeof(ddst)); ifa_release(ifa, &psref); } curlwp_bindx(bound); if (dst) memcpy(dst, &ddst, sizeof(*dst)); if (src) memcpy(src, &ssrc, sizeof(*src)); } #ifdef IPV6CP_MYIFID_DYN /* * Generate random ifid. */ static void sppp_gen_ip6_addr(struct sppp *sp, struct in6_addr *addr) { /* TBD */ } /* * Set my IPv6 address. Must be called at splnet. */ static void sppp_set_ip6_addr(struct sppp *sp, const struct in6_addr *src) { struct ifnet *ifp; struct ifaddr *ifa; struct sockaddr_in6 *sin6; int s; struct psref psref; KASSERT(SPPP_WLOCKED(sp)); ifp = &sp->pp_if; SPPP_UNLOCK(sp); IFNET_LOCK(ifp); SPPP_LOCK(sp, RW_WRITER); /* * Pick the first link-local AF_INET6 address from the list, * aliases don't make any sense on a p2p link anyway. */ sin6 = NULL; s = pserialize_read_enter(); IFADDR_READER_FOREACH(ifa, ifp) { if (ifa->ifa_addr->sa_family == AF_INET6) { sin6 = (struct sockaddr_in6 *)ifa->ifa_addr; if (sin6 && IN6_IS_ADDR_LINKLOCAL(&sin6->sin6_addr)) { ifa_acquire(ifa, &psref); break; } } } pserialize_read_exit(s); if (ifa && sin6) { int error; struct sockaddr_in6 new_sin6 = *sin6; memcpy(&new_sin6.sin6_addr, src, sizeof(new_sin6.sin6_addr)); error = in6_ifinit(ifp, ifatoia6(ifa), &new_sin6, 1); if (error) { SPPP_DLOG(sp, "%s: in6_ifinit failed, error=%d\n", __func__, error); } else { pfil_run_addrhooks(if_pfil, SIOCAIFADDR_IN6, ifa); } ifa_release(ifa, &psref); } IFNET_UNLOCK(ifp); } #endif /* * Suggest a candidate address to be used by peer. */ static void sppp_suggest_ip6_addr(struct sppp *sp, struct in6_addr *suggest) { struct in6_addr myaddr; struct timeval tv; sppp_get_ip6_addrs(sp, &myaddr, 0, 0); myaddr.s6_addr[8] &= ~0x02; /* u bit to "local" */ microtime(&tv); if ((tv.tv_usec & 0xff) == 0 && (tv.tv_sec & 0xff) == 0) { myaddr.s6_addr[14] ^= 0xff; myaddr.s6_addr[15] ^= 0xff; } else { myaddr.s6_addr[14] ^= (tv.tv_usec & 0xff); myaddr.s6_addr[15] ^= (tv.tv_sec & 0xff); } if (suggest) memcpy(suggest, &myaddr, sizeof(myaddr)); } #endif /*INET6*/ /* * Process ioctl requests specific to the PPP interface. * Permissions have already been checked. */ static int sppp_params(struct sppp *sp, u_long cmd, void *data) { switch (cmd) { case SPPPGETAUTHCFG: { struct spppauthcfg *cfg = (struct spppauthcfg *)data; int error; size_t len; SPPP_LOCK(sp, RW_READER); cfg->myauthflags = sp->myauth.flags; cfg->hisauthflags = sp->hisauth.flags; strlcpy(cfg->ifname, sp->pp_if.if_xname, sizeof(cfg->ifname)); cfg->hisauth = sppp_proto2authproto(sp->hisauth.proto); cfg->myauth = sppp_proto2authproto(sp->myauth.proto); if (cfg->myname_length == 0) { if (sp->myauth.name != NULL) cfg->myname_length = sp->myauth.name_len + 1; } else { if (sp->myauth.name == NULL) { cfg->myname_length = 0; } else { len = sp->myauth.name_len + 1; if (cfg->myname_length < len) { SPPP_UNLOCK(sp); return (ENAMETOOLONG); } error = copyout(sp->myauth.name, cfg->myname, len); if (error) { SPPP_UNLOCK(sp); return error; } } } if (cfg->hisname_length == 0) { if (sp->hisauth.name != NULL) cfg->hisname_length = sp->hisauth.name_len + 1; } else { if (sp->hisauth.name == NULL) { cfg->hisname_length = 0; } else { len = sp->hisauth.name_len + 1; if (cfg->hisname_length < len) { SPPP_UNLOCK(sp); return (ENAMETOOLONG); } error = copyout(sp->hisauth.name, cfg->hisname, len); if (error) { SPPP_UNLOCK(sp); return error; } } } SPPP_UNLOCK(sp); } break; case SPPPSETAUTHCFG: { struct spppauthcfg *cfg = (struct spppauthcfg *)data; int error; SPPP_LOCK(sp, RW_WRITER); if (sp->myauth.name) { free(sp->myauth.name, M_DEVBUF); sp->myauth.name = NULL; } if (sp->myauth.secret) { free(sp->myauth.secret, M_DEVBUF); sp->myauth.secret = NULL; } if (sp->hisauth.name) { free(sp->hisauth.name, M_DEVBUF); sp->hisauth.name = NULL; } if (sp->hisauth.secret) { free(sp->hisauth.secret, M_DEVBUF); sp->hisauth.secret = NULL; } if (cfg->hisname != NULL && cfg->hisname_length > 0) { if (cfg->hisname_length >= MCLBYTES) { SPPP_UNLOCK(sp); return (ENAMETOOLONG); } sp->hisauth.name = malloc(cfg->hisname_length, M_DEVBUF, M_WAITOK); error = copyin(cfg->hisname, sp->hisauth.name, cfg->hisname_length); if (error) { free(sp->hisauth.name, M_DEVBUF); sp->hisauth.name = NULL; SPPP_UNLOCK(sp); return error; } sp->hisauth.name_len = cfg->hisname_length - 1; sp->hisauth.name[sp->hisauth.name_len] = 0; } if (cfg->hissecret != NULL && cfg->hissecret_length > 0) { if (cfg->hissecret_length >= MCLBYTES) { SPPP_UNLOCK(sp); return (ENAMETOOLONG); } sp->hisauth.secret = malloc(cfg->hissecret_length, M_DEVBUF, M_WAITOK); error = copyin(cfg->hissecret, sp->hisauth.secret, cfg->hissecret_length); if (error) { free(sp->hisauth.secret, M_DEVBUF); sp->hisauth.secret = NULL; SPPP_UNLOCK(sp); return error; } sp->hisauth.secret_len = cfg->hissecret_length - 1; sp->hisauth.secret[sp->hisauth.secret_len] = 0; } if (cfg->myname != NULL && cfg->myname_length > 0) { if (cfg->myname_length >= MCLBYTES) { SPPP_UNLOCK(sp); return (ENAMETOOLONG); } sp->myauth.name = malloc(cfg->myname_length, M_DEVBUF, M_WAITOK); error = copyin(cfg->myname, sp->myauth.name, cfg->myname_length); if (error) { free(sp->myauth.name, M_DEVBUF); sp->myauth.name = NULL; SPPP_UNLOCK(sp); return error; } sp->myauth.name_len = cfg->myname_length - 1; sp->myauth.name[sp->myauth.name_len] = 0; } if (cfg->mysecret != NULL && cfg->mysecret_length > 0) { if (cfg->mysecret_length >= MCLBYTES) { SPPP_UNLOCK(sp); return (ENAMETOOLONG); } sp->myauth.secret = malloc(cfg->mysecret_length, M_DEVBUF, M_WAITOK); error = copyin(cfg->mysecret, sp->myauth.secret, cfg->mysecret_length); if (error) { free(sp->myauth.secret, M_DEVBUF); sp->myauth.secret = NULL; SPPP_UNLOCK(sp); return error; } sp->myauth.secret_len = cfg->mysecret_length - 1; sp->myauth.secret[sp->myauth.secret_len] = 0; } sp->myauth.flags = cfg->myauthflags; if (cfg->myauth != SPPP_AUTHPROTO_NOCHG) { sp->myauth.proto = sppp_authproto2proto(cfg->myauth); } sp->hisauth.flags = cfg->hisauthflags; if (cfg->hisauth != SPPP_AUTHPROTO_NOCHG) { sp->hisauth.proto = sppp_authproto2proto(cfg->hisauth); } sp->pp_auth_failures = 0; if (sp->hisauth.proto != PPP_NOPROTO) SET(sp->lcp.opts, SPPP_LCP_OPT_AUTH_PROTO); else CLR(sp->lcp.opts, SPPP_LCP_OPT_AUTH_PROTO); SPPP_UNLOCK(sp); } break; case SPPPGETLCPCFG: { struct sppplcpcfg *lcpp = (struct sppplcpcfg *)data; SPPP_LOCK(sp, RW_READER); lcpp->lcp_timeout = sp->lcp.timeout; SPPP_UNLOCK(sp); } break; case SPPPSETLCPCFG: { struct sppplcpcfg *lcpp = (struct sppplcpcfg *)data; SPPP_LOCK(sp, RW_WRITER); sp->lcp.timeout = lcpp->lcp_timeout; SPPP_UNLOCK(sp); } break; case SPPPGETNCPCFG: { struct spppncpcfg *ncpp = (struct spppncpcfg *) data; SPPP_LOCK(sp, RW_READER); ncpp->ncp_flags = sp->pp_ncpflags; SPPP_UNLOCK(sp); } break; case SPPPSETNCPCFG: { struct spppncpcfg *ncpp = (struct spppncpcfg *) data; SPPP_LOCK(sp, RW_WRITER); sp->pp_ncpflags = ncpp->ncp_flags; SPPP_UNLOCK(sp); } break; case SPPPGETSTATUS: { struct spppstatus *status = (struct spppstatus *)data; SPPP_LOCK(sp, RW_READER); status->phase = sp->pp_phase; SPPP_UNLOCK(sp); } break; case SPPPGETSTATUSNCP: { struct spppstatusncp *status = (struct spppstatusncp *)data; SPPP_LOCK(sp, RW_READER); status->phase = sp->pp_phase; status->ncpup = sppp_cp_check(sp, CP_NCP); SPPP_UNLOCK(sp); } break; case SPPPGETIDLETO: { struct spppidletimeout *to = (struct spppidletimeout *)data; SPPP_LOCK(sp, RW_READER); to->idle_seconds = sp->pp_idle_timeout; SPPP_UNLOCK(sp); } break; case SPPPSETIDLETO: { struct spppidletimeout *to = (struct spppidletimeout *)data; SPPP_LOCK(sp, RW_WRITER); sp->pp_idle_timeout = to->idle_seconds; SPPP_UNLOCK(sp); } break; case SPPPSETAUTHFAILURE: { struct spppauthfailuresettings *afsettings = (struct spppauthfailuresettings *)data; SPPP_LOCK(sp, RW_WRITER); sp->pp_max_auth_fail = afsettings->max_failures; sp->pp_auth_failures = 0; SPPP_UNLOCK(sp); } break; case SPPPGETAUTHFAILURES: { struct spppauthfailurestats *stats = (struct spppauthfailurestats *)data; SPPP_LOCK(sp, RW_READER); stats->auth_failures = sp->pp_auth_failures; stats->max_failures = sp->pp_max_auth_fail; SPPP_UNLOCK(sp); } break; case SPPPSETDNSOPTS: { struct spppdnssettings *req = (struct spppdnssettings *)data; SPPP_LOCK(sp, RW_WRITER); sp->query_dns = req->query_dns & 3; SPPP_UNLOCK(sp); } break; case SPPPGETDNSOPTS: { struct spppdnssettings *req = (struct spppdnssettings *)data; SPPP_LOCK(sp, RW_READER); req->query_dns = sp->query_dns; SPPP_UNLOCK(sp); } break; case SPPPGETDNSADDRS: { struct spppdnsaddrs *addrs = (struct spppdnsaddrs *)data; SPPP_LOCK(sp, RW_READER); memcpy(&addrs->dns, &sp->dns_addrs, sizeof addrs->dns); SPPP_UNLOCK(sp); } break; case SPPPGETKEEPALIVE: { struct spppkeepalivesettings *settings = (struct spppkeepalivesettings*)data; SPPP_LOCK(sp, RW_READER); settings->maxalive = sp->pp_maxalive; settings->max_noreceive = sp->pp_max_noreceive; settings->alive_interval = sp->pp_alive_interval; SPPP_UNLOCK(sp); } break; case SPPPSETKEEPALIVE: { struct spppkeepalivesettings *settings = (struct spppkeepalivesettings*)data; SPPP_LOCK(sp, RW_WRITER); sp->pp_maxalive = settings->maxalive; sp->pp_max_noreceive = settings->max_noreceive; sp->pp_alive_interval = settings->alive_interval; SPPP_UNLOCK(sp); } break; case SPPPGETLCPSTATUS: { struct sppplcpstatus *status = (struct sppplcpstatus *)data; SPPP_LOCK(sp, RW_READER); status->state = sp->scp[IDX_LCP].state; status->opts = sp->lcp.opts; status->magic = sp->lcp.magic; status->mru = sp->lcp.mru; SPPP_UNLOCK(sp); } break; case SPPPGETIPCPSTATUS: { struct spppipcpstatus *status = (struct spppipcpstatus *)data; u_int32_t myaddr; SPPP_LOCK(sp, RW_READER); status->state = sp->scp[IDX_IPCP].state; status->opts = sp->ipcp.opts; #ifdef INET sppp_get_ip_addrs(sp, &myaddr, 0, 0); #else myaddr = 0; #endif status->myaddr = ntohl(myaddr); SPPP_UNLOCK(sp); } break; case SPPPGETIPV6CPSTATUS: { struct spppipv6cpstatus *status = (struct spppipv6cpstatus *)data; SPPP_LOCK(sp, RW_READER); status->state = sp->scp[IDX_IPV6CP].state; memcpy(status->my_ifid, sp->ipv6cp.my_ifid, sizeof(status->my_ifid)); memcpy(status->his_ifid, sp->ipv6cp.his_ifid, sizeof(status->his_ifid)); SPPP_UNLOCK(sp); } break; default: { int ret; MODULE_HOOK_CALL(sppp_params_50_hook, (sp, cmd, data), enosys(), ret); if (ret != ENOSYS) return ret; return (EINVAL); } } return (0); } static void sppp_phase_network(struct sppp *sp) { int i; KASSERT(SPPP_WLOCKED(sp)); sppp_change_phase(sp, SPPP_PHASE_NETWORK); /* Notify NCPs now. */ for (i = 0; i < IDX_COUNT; i++) if ((cps[i])->flags & CP_NCP) sppp_wq_add(sp->wq_cp, &sp->scp[i].work_open); } static const char * sppp_cp_type_name(char *buf, size_t buflen, u_char type) { switch (type) { case CONF_REQ: return "conf-req"; case CONF_ACK: return "conf-ack"; case CONF_NAK: return "conf-nak"; case CONF_REJ: return "conf-rej"; case TERM_REQ: return "term-req"; case TERM_ACK: return "term-ack"; case CODE_REJ: return "code-rej"; case PROTO_REJ: return "proto-rej"; case ECHO_REQ: return "echo-req"; case ECHO_REPLY: return "echo-reply"; case DISC_REQ: return "discard-req"; } if (buf != NULL) snprintf(buf, buflen, "0x%02x", type); return buf; } static const char * sppp_auth_type_name(char *buf, size_t buflen, u_short proto, u_char type) { const char *name; switch (proto) { case PPP_CHAP: switch (type) { case CHAP_CHALLENGE: return "challenge"; case CHAP_RESPONSE: return "response"; case CHAP_SUCCESS: return "success"; case CHAP_FAILURE: return "failure"; default: name = "chap"; break; } break; case PPP_PAP: switch (type) { case PAP_REQ: return "req"; case PAP_ACK: return "ack"; case PAP_NAK: return "nak"; default: name = "pap"; break; } break; default: name = "bad"; break; } if (buf != NULL) snprintf(buf, buflen, "%s(%#x) 0x%02x", name, proto, type); return buf; } static const char * sppp_lcp_opt_name(char *buf, size_t buflen, u_char opt) { switch (opt) { case LCP_OPT_MRU: return "mru"; case LCP_OPT_ASYNC_MAP: return "async-map"; case LCP_OPT_AUTH_PROTO: return "auth-proto"; case LCP_OPT_QUAL_PROTO: return "qual-proto"; case LCP_OPT_MAGIC: return "magic"; case LCP_OPT_PROTO_COMP: return "proto-comp"; case LCP_OPT_ADDR_COMP: return "addr-comp"; case LCP_OPT_SELF_DESC_PAD: return "sdpad"; case LCP_OPT_CALL_BACK: return "callback"; case LCP_OPT_COMPOUND_FRMS: return "cmpd-frms"; case LCP_OPT_MP_MRRU: return "mrru"; case LCP_OPT_MP_SSNHF: return "mp-ssnhf"; case LCP_OPT_MP_EID: return "mp-eid"; } if (buf != NULL) snprintf(buf, buflen, "0x%02x", opt); return buf; } static const char * sppp_ipcp_opt_name(char *buf, size_t buflen, u_char opt) { switch (opt) { case IPCP_OPT_ADDRESSES: return "addresses"; case IPCP_OPT_COMPRESSION: return "compression"; case IPCP_OPT_ADDRESS: return "address"; case IPCP_OPT_PRIMDNS: return "primdns"; case IPCP_OPT_SECDNS: return "secdns"; } if (buf != NULL) snprintf(buf, buflen, "0x%02x", opt); return buf; } #ifdef INET6 static const char * sppp_ipv6cp_opt_name(char *buf, size_t buflen, u_char opt) { switch (opt) { case IPV6CP_OPT_IFID: return "ifid"; case IPV6CP_OPT_COMPRESSION: return "compression"; } if (buf != NULL) snprintf(buf, buflen, "0x%02x", opt); return buf; } #endif static const char * sppp_state_name(int state) { switch (state) { case STATE_INITIAL: return "initial"; case STATE_STARTING: return "starting"; case STATE_CLOSED: return "closed"; case STATE_STOPPED: return "stopped"; case STATE_CLOSING: return "closing"; case STATE_STOPPING: return "stopping"; case STATE_REQ_SENT: return "req-sent"; case STATE_ACK_RCVD: return "ack-rcvd"; case STATE_ACK_SENT: return "ack-sent"; case STATE_OPENED: return "opened"; } return "illegal"; } static const char * sppp_phase_name(int phase) { switch (phase) { case SPPP_PHASE_DEAD: return "dead"; case SPPP_PHASE_ESTABLISH: return "establish"; case SPPP_PHASE_TERMINATE: return "terminate"; case SPPP_PHASE_AUTHENTICATE: return "authenticate"; case SPPP_PHASE_NETWORK: return "network"; } return "illegal"; } static const char * sppp_proto_name(char *buf, size_t buflen, u_short proto) { switch (proto) { case PPP_LCP: return "lcp"; case PPP_IPCP: return "ipcp"; case PPP_PAP: return "pap"; case PPP_CHAP: return "chap"; case PPP_IPV6CP: return "ipv6cp"; } if (buf != NULL) { snprintf(buf, sizeof(buf), "0x%04x", (unsigned)proto); } return buf; } static void sppp_print_bytes(const u_char *p, u_short len) { addlog(" %02x", *p++); while (--len > 0) addlog("-%02x", *p++); } static void sppp_print_string(const char *p, u_short len) { u_char c; while (len-- > 0) { c = *p++; /* * Print only ASCII chars directly. RFC 1994 recommends * using only them, but we don't rely on it. */ if (c < ' ' || c > '~') addlog("\\x%x", c); else addlog("%c", c); } } static const char * sppp_dotted_quad(char *buf, size_t buflen, uint32_t addr) { if (buf != NULL) { snprintf(buf, buflen, "%u.%u.%u.%u", (unsigned int)((addr >> 24) & 0xff), (unsigned int)((addr >> 16) & 0xff), (unsigned int)((addr >> 8) & 0xff), (unsigned int)(addr & 0xff)); } return buf; } /* a dummy, used to drop uninteresting events */ static void sppp_null(struct sppp *unused) { /* do just nothing */ } static void sppp_tls(const struct cp *cp, struct sppp *sp) { SPPP_DLOG(sp, "%s tls\n", cp->name); /* notify lcp that is lower layer */ sp->lcp.protos |= (1 << cp->protoidx); } static void sppp_tlf(const struct cp *cp, struct sppp *sp) { SPPP_DLOG(sp, "%s tlf\n", cp->name); /* notify lcp that is lower layer */ sp->lcp.protos &= ~(1 << cp->protoidx); /* cleanup */ if (sp->scp[cp->protoidx].mbuf_confreq != NULL) { m_freem(sp->scp[cp->protoidx].mbuf_confreq); sp->scp[cp->protoidx].mbuf_confreq = NULL; } if (sp->scp[cp->protoidx].mbuf_confnak != NULL) { m_freem(sp->scp[cp->protoidx].mbuf_confnak); sp->scp[cp->protoidx].mbuf_confnak = NULL; } sppp_lcp_check_and_close(sp); } static void sppp_screply(const struct cp *cp, struct sppp *sp, u_char type, uint8_t ident, size_t msglen, void *msg) { if (msglen == 0) return; switch (type) { case CONF_ACK: case CONF_NAK: case CONF_REJ: break; default: return; } if (sppp_debug_enabled(sp)) { char tbuf[SPPP_CPTYPE_NAMELEN]; const char *cpname; cpname = sppp_cp_type_name(tbuf, sizeof(tbuf), type); SPPP_LOG(sp, LOG_DEBUG, "send %s\n", cpname); } sppp_cp_send(sp, cp->proto, type, ident, msglen, msg); } static void sppp_ifdown(struct sppp *sp, void *xcp __unused) { SPPP_UNLOCK(sp); if_down(&sp->pp_if); IF_PURGE(&sp->pp_cpq); SPPP_LOCK(sp, RW_WRITER); } static void sppp_notify_up(struct sppp *sp) { sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_up); } static void sppp_notify_down(struct sppp *sp) { sppp_wq_add(sp->wq_cp, &sp->scp[IDX_LCP].work_down); } static void sppp_notify_tls_wlocked(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); if (!sp->pp_tls) return; SPPP_UNLOCK(sp); sp->pp_tls(sp); SPPP_LOCK(sp, RW_WRITER); } static void sppp_notify_tlf_wlocked(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); if (!sp->pp_tlf) return; SPPP_UNLOCK(sp); sp->pp_tlf(sp); SPPP_LOCK(sp, RW_WRITER); } static void sppp_notify_con(struct sppp *sp) { if (!sp->pp_con) return; sp->pp_con(sp); } #ifdef INET6 static void sppp_notify_con_wlocked(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); SPPP_UNLOCK(sp); sppp_notify_con(sp); SPPP_LOCK(sp, RW_WRITER); } #endif static void sppp_notify_chg_wlocked(struct sppp *sp) { KASSERT(SPPP_WLOCKED(sp)); if (!sp->pp_chg) return; SPPP_UNLOCK(sp); sp->pp_chg(sp, sp->pp_phase); SPPP_LOCK(sp, RW_WRITER); } static void sppp_wq_work(struct work *wk, void *xsp) { struct sppp *sp; struct sppp_work *work; sp = xsp; work = container_of(wk, struct sppp_work, work); atomic_cas_uint(&work->state, SPPP_WK_BUSY, SPPP_WK_FREE); SPPP_LOCK(sp, RW_WRITER); work->func(sp, work->arg); SPPP_UNLOCK(sp); } static struct workqueue * sppp_wq_create(struct sppp *sp, const char *xnamebuf, pri_t prio, int ipl, int flags) { struct workqueue *wq; int error; error = workqueue_create(&wq, xnamebuf, sppp_wq_work, (void *)sp, prio, ipl, flags); if (error) { panic("%s: workqueue_create failed [%s, %d]\n", sp->pp_if.if_xname, xnamebuf, error); } return wq; } static void sppp_wq_destroy(struct sppp *sp __unused, struct workqueue *wq) { workqueue_destroy(wq); } static void sppp_wq_set(struct sppp_work *work, void (*func)(struct sppp *, void *), void *arg) { work->func = func; work->arg = arg; } static void sppp_wq_add(struct workqueue *wq, struct sppp_work *work) { if (atomic_cas_uint(&work->state, SPPP_WK_FREE, SPPP_WK_BUSY) != SPPP_WK_FREE) return; KASSERT(work->func != NULL); kpreempt_disable(); workqueue_enqueue(wq, &work->work, NULL); kpreempt_enable(); } static void sppp_wq_wait(struct workqueue *wq, struct sppp_work *work) { atomic_swap_uint(&work->state, SPPP_WK_UNAVAIL); workqueue_wait(wq, &work->work); } /* * This file is large. Tell emacs to highlight it nevertheless. * * Local Variables: * hilit-auto-highlight-maxout: 120000 * End: */ /* * Module glue */ MODULE(MODULE_CLASS_MISC, sppp_subr, NULL); static int sppp_subr_modcmd(modcmd_t cmd, void *arg) { switch (cmd) { case MODULE_CMD_INIT: case MODULE_CMD_FINI: return 0; case MODULE_CMD_STAT: case MODULE_CMD_AUTOUNLOAD: default: return ENOTTY; } }