/* * lcp.c - PPP Link Control Protocol. * * Copyright (c) 1984-2000 Carnegie Mellon University. All rights reserved. * * 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. * * 3. The name "Carnegie Mellon University" must not be used to * endorse or promote products derived from this software without * prior written permission. For permission or any legal * details, please contact * Office of Technology Transfer * Carnegie Mellon University * 5000 Forbes Avenue * Pittsburgh, PA 15213-3890 * (412) 268-4387, fax: (412) 268-7395 * tech-transfer@andrew.cmu.edu * * 4. Redistributions of any form whatsoever must retain the following * acknowledgment: * "This product includes software developed by Computing Services * at Carnegie Mellon University (http://www.cmu.edu/computing/)." * * CARNEGIE MELLON UNIVERSITY DISCLAIMS ALL WARRANTIES WITH REGARD TO * THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY * AND FITNESS, IN NO EVENT SHALL CARNEGIE MELLON UNIVERSITY BE LIABLE * FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN * AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING * OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #define RCSID "$Id: lcp.c,v 1.74 2004/11/13 02:28:15 paulus Exp $" /* * TODO: */ #include <stdio.h> #include <string.h> #include <stdlib.h> #include "pppd.h" #include "fsm.h" #include "lcp.h" #include "chap-new.h" #include "magic.h" static const char rcsid[] = RCSID; /* * When the link comes up we want to be able to wait for a short while, * or until seeing some input from the peer, before starting to send * configure-requests. We do this by delaying the fsm_lowerup call. */ /* steal a bit in fsm flags word */ #define DELAYED_UP 0x100 static void lcp_delayed_up __P((void *)); /* * LCP-related command-line options. */ int lcp_echo_interval = 0; /* Interval between LCP echo-requests */ int lcp_echo_fails = 0; /* Tolerance to unanswered echo-requests */ bool lax_recv = 0; /* accept control chars in asyncmap */ bool noendpoint = 0; /* don't send/accept endpoint discriminator */ static int noopt __P((char **)); #ifdef HAVE_MULTILINK static int setendpoint __P((char **)); static void printendpoint __P((option_t *, void (*)(void *, char *, ...), void *)); #endif /* HAVE_MULTILINK */ static option_t lcp_option_list[] = { /* LCP options */ { "-all", o_special_noarg, (void *)noopt, "Don't request/allow any LCP options" }, { "noaccomp", o_bool, &lcp_wantoptions[0].neg_accompression, "Disable address/control compression", OPT_A2CLR, &lcp_allowoptions[0].neg_accompression }, { "-ac", o_bool, &lcp_wantoptions[0].neg_accompression, "Disable address/control compression", OPT_ALIAS | OPT_A2CLR, &lcp_allowoptions[0].neg_accompression }, { "asyncmap", o_uint32, &lcp_wantoptions[0].asyncmap, "Set asyncmap (for received packets)", OPT_OR, &lcp_wantoptions[0].neg_asyncmap }, { "-as", o_uint32, &lcp_wantoptions[0].asyncmap, "Set asyncmap (for received packets)", OPT_ALIAS | OPT_OR, &lcp_wantoptions[0].neg_asyncmap }, { "default-asyncmap", o_uint32, &lcp_wantoptions[0].asyncmap, "Disable asyncmap negotiation", OPT_OR | OPT_NOARG | OPT_VAL(~0U) | OPT_A2CLR, &lcp_allowoptions[0].neg_asyncmap }, { "-am", o_uint32, &lcp_wantoptions[0].asyncmap, "Disable asyncmap negotiation", OPT_ALIAS | OPT_OR | OPT_NOARG | OPT_VAL(~0U) | OPT_A2CLR, &lcp_allowoptions[0].neg_asyncmap }, { "nomagic", o_bool, &lcp_wantoptions[0].neg_magicnumber, "Disable magic number negotiation (looped-back line detection)", OPT_A2CLR, &lcp_allowoptions[0].neg_magicnumber }, { "-mn", o_bool, &lcp_wantoptions[0].neg_magicnumber, "Disable magic number negotiation (looped-back line detection)", OPT_ALIAS | OPT_A2CLR, &lcp_allowoptions[0].neg_magicnumber }, { "mru", o_int, &lcp_wantoptions[0].mru, "Set MRU (maximum received packet size) for negotiation", OPT_PRIO, &lcp_wantoptions[0].neg_mru }, { "default-mru", o_bool, &lcp_wantoptions[0].neg_mru, "Disable MRU negotiation (use default 1500)", OPT_PRIOSUB | OPT_A2CLR, &lcp_allowoptions[0].neg_mru }, { "-mru", o_bool, &lcp_wantoptions[0].neg_mru, "Disable MRU negotiation (use default 1500)", OPT_ALIAS | OPT_PRIOSUB | OPT_A2CLR, &lcp_allowoptions[0].neg_mru }, { "mtu", o_int, &lcp_allowoptions[0].mru, "Set our MTU", OPT_LIMITS, NULL, MAXMRU, MINMRU }, { "nopcomp", o_bool, &lcp_wantoptions[0].neg_pcompression, "Disable protocol field compression", OPT_A2CLR, &lcp_allowoptions[0].neg_pcompression }, { "-pc", o_bool, &lcp_wantoptions[0].neg_pcompression, "Disable protocol field compression", OPT_ALIAS | OPT_A2CLR, &lcp_allowoptions[0].neg_pcompression }, { "passive", o_bool, &lcp_wantoptions[0].passive, "Set passive mode", 1 }, { "-p", o_bool, &lcp_wantoptions[0].passive, "Set passive mode", OPT_ALIAS | 1 }, { "silent", o_bool, &lcp_wantoptions[0].silent, "Set silent mode", 1 }, { "lcp-echo-failure", o_int, &lcp_echo_fails, "Set number of consecutive echo failures to indicate link failure", OPT_PRIO }, { "lcp-echo-interval", o_int, &lcp_echo_interval, "Set time in seconds between LCP echo requests", OPT_PRIO }, { "lcp-restart", o_int, &lcp_fsm[0].timeouttime, "Set time in seconds between LCP retransmissions", OPT_PRIO }, { "lcp-max-terminate", o_int, &lcp_fsm[0].maxtermtransmits, "Set maximum number of LCP terminate-request transmissions", OPT_PRIO }, { "lcp-max-configure", o_int, &lcp_fsm[0].maxconfreqtransmits, "Set maximum number of LCP configure-request transmissions", OPT_PRIO }, { "lcp-max-failure", o_int, &lcp_fsm[0].maxnakloops, "Set limit on number of LCP configure-naks", OPT_PRIO }, { "receive-all", o_bool, &lax_recv, "Accept all received control characters", 1 }, #ifdef HAVE_MULTILINK { "mrru", o_int, &lcp_wantoptions[0].mrru, "Maximum received packet size for multilink bundle", OPT_PRIO, &lcp_wantoptions[0].neg_mrru }, { "mpshortseq", o_bool, &lcp_wantoptions[0].neg_ssnhf, "Use short sequence numbers in multilink headers", OPT_PRIO | 1, &lcp_allowoptions[0].neg_ssnhf }, { "nompshortseq", o_bool, &lcp_wantoptions[0].neg_ssnhf, "Don't use short sequence numbers in multilink headers", OPT_PRIOSUB | OPT_A2CLR, &lcp_allowoptions[0].neg_ssnhf }, { "endpoint", o_special, (void *) setendpoint, "Endpoint discriminator for multilink", OPT_PRIO | OPT_A2PRINTER, (void *) printendpoint }, #endif /* HAVE_MULTILINK */ { "noendpoint", o_bool, &noendpoint, "Don't send or accept multilink endpoint discriminator", 1 }, {NULL} }; /* global vars */ fsm lcp_fsm[NUM_PPP]; /* LCP fsm structure (global)*/ lcp_options lcp_wantoptions[NUM_PPP]; /* Options that we want to request */ lcp_options lcp_gotoptions[NUM_PPP]; /* Options that peer ack'd */ lcp_options lcp_allowoptions[NUM_PPP]; /* Options we allow peer to request */ lcp_options lcp_hisoptions[NUM_PPP]; /* Options that we ack'd */ static int lcp_echos_pending = 0; /* Number of outstanding echo msgs */ static int lcp_echo_number = 0; /* ID number of next echo frame */ static int lcp_echo_timer_running = 0; /* set if a timer is running */ static u_char nak_buffer[PPP_MRU]; /* where we construct a nak packet */ /* * Callbacks for fsm code. (CI = Configuration Information) */ static void lcp_resetci __P((fsm *)); /* Reset our CI */ static int lcp_cilen __P((fsm *)); /* Return length of our CI */ static void lcp_addci __P((fsm *, u_char *, int *)); /* Add our CI to pkt */ static int lcp_ackci __P((fsm *, u_char *, int)); /* Peer ack'd our CI */ static int lcp_nakci __P((fsm *, u_char *, int, int)); /* Peer nak'd our CI */ static int lcp_rejci __P((fsm *, u_char *, int)); /* Peer rej'd our CI */ static int lcp_reqci __P((fsm *, u_char *, int *, int)); /* Rcv peer CI */ static void lcp_up __P((fsm *)); /* We're UP */ static void lcp_down __P((fsm *)); /* We're DOWN */ static void lcp_starting __P((fsm *)); /* We need lower layer up */ static void lcp_finished __P((fsm *)); /* We need lower layer down */ static int lcp_extcode __P((fsm *, int, int, u_char *, int)); static void lcp_rprotrej __P((fsm *, u_char *, int)); /* * routines to send LCP echos to peer */ static void lcp_echo_lowerup __P((int)); static void lcp_echo_lowerdown __P((int)); static void LcpEchoTimeout __P((void *)); static void lcp_received_echo_reply __P((fsm *, int, u_char *, int)); static void LcpSendEchoRequest __P((fsm *)); static void LcpLinkFailure __P((fsm *)); static void LcpEchoCheck __P((fsm *)); static fsm_callbacks lcp_callbacks = { /* LCP callback routines */ lcp_resetci, /* Reset our Configuration Information */ lcp_cilen, /* Length of our Configuration Information */ lcp_addci, /* Add our Configuration Information */ lcp_ackci, /* ACK our Configuration Information */ lcp_nakci, /* NAK our Configuration Information */ lcp_rejci, /* Reject our Configuration Information */ lcp_reqci, /* Request peer's Configuration Information */ lcp_up, /* Called when fsm reaches OPENED state */ lcp_down, /* Called when fsm leaves OPENED state */ lcp_starting, /* Called when we want the lower layer up */ lcp_finished, /* Called when we want the lower layer down */ NULL, /* Called when Protocol-Reject received */ NULL, /* Retransmission is necessary */ lcp_extcode, /* Called to handle LCP-specific codes */ "LCP" /* String name of protocol */ }; /* * Protocol entry points. * Some of these are called directly. */ static void lcp_init __P((int)); static void lcp_input __P((int, u_char *, int)); static void lcp_protrej __P((int)); static int lcp_printpkt __P((u_char *, int, void (*) __P((void *, char *, ...)), void *)); struct protent lcp_protent = { PPP_LCP, lcp_init, lcp_input, lcp_protrej, lcp_lowerup, lcp_lowerdown, lcp_open, lcp_close, lcp_printpkt, NULL, 1, "LCP", NULL, lcp_option_list, NULL, NULL, NULL }; int lcp_loopbackfail = DEFLOOPBACKFAIL; /* * Length of each type of configuration option (in octets) */ #define CILEN_VOID 2 #define CILEN_CHAR 3 #define CILEN_SHORT 4 /* CILEN_VOID + 2 */ #define CILEN_CHAP 5 /* CILEN_VOID + 2 + 1 */ #define CILEN_LONG 6 /* CILEN_VOID + 4 */ #define CILEN_LQR 8 /* CILEN_VOID + 2 + 4 */ #define CILEN_CBCP 3 #define CODENAME(x) ((x) == CONFACK ? "ACK" : \ (x) == CONFNAK ? "NAK" : "REJ") /* * noopt - Disable all options (why?). */ static int noopt(argv) char **argv; { BZERO((char *) &lcp_wantoptions[0], sizeof (struct lcp_options)); BZERO((char *) &lcp_allowoptions[0], sizeof (struct lcp_options)); return (1); } #ifdef HAVE_MULTILINK static int setendpoint(argv) char **argv; { if (str_to_epdisc(&lcp_wantoptions[0].endpoint, *argv)) { lcp_wantoptions[0].neg_endpoint = 1; return 1; } option_error("Can't parse '%s' as an endpoint discriminator", *argv); return 0; } static void printendpoint(opt, printer, arg) option_t *opt; void (*printer) __P((void *, char *, ...)); void *arg; { printer(arg, "%s", epdisc_to_str(&lcp_wantoptions[0].endpoint)); } #endif /* HAVE_MULTILINK */ /* * lcp_init - Initialize LCP. */ static void lcp_init(unit) int unit; { fsm *f = &lcp_fsm[unit]; lcp_options *wo = &lcp_wantoptions[unit]; lcp_options *ao = &lcp_allowoptions[unit]; f->unit = unit; f->protocol = PPP_LCP; f->callbacks = &lcp_callbacks; fsm_init(f); BZERO(wo, sizeof(*wo)); wo->neg_mru = 1; wo->mru = DEFMRU; wo->neg_asyncmap = 1; wo->neg_magicnumber = 1; wo->neg_pcompression = 1; wo->neg_accompression = 1; BZERO(ao, sizeof(*ao)); ao->neg_mru = 1; ao->mru = MAXMRU; ao->neg_asyncmap = 1; ao->neg_chap = 1; ao->chap_mdtype = chap_mdtype_all; ao->neg_upap = 1; ao->neg_eap = 1; ao->neg_magicnumber = 1; ao->neg_pcompression = 1; ao->neg_accompression = 1; ao->neg_endpoint = 1; } /* * lcp_open - LCP is allowed to come up. */ void lcp_open(unit) int unit; { fsm *f = &lcp_fsm[unit]; lcp_options *wo = &lcp_wantoptions[unit]; f->flags &= ~(OPT_PASSIVE | OPT_SILENT); if (wo->passive) f->flags |= OPT_PASSIVE; if (wo->silent) f->flags |= OPT_SILENT; fsm_open(f); } /* * lcp_close - Take LCP down. */ void lcp_close(unit, reason) int unit; char *reason; { fsm *f = &lcp_fsm[unit]; if (phase != PHASE_DEAD && phase != PHASE_MASTER) new_phase(PHASE_TERMINATE); if (f->state == STOPPED && f->flags & (OPT_PASSIVE|OPT_SILENT)) { /* * This action is not strictly according to the FSM in RFC1548, * but it does mean that the program terminates if you do a * lcp_close() in passive/silent mode when a connection hasn't * been established. */ f->state = CLOSED; lcp_finished(f); } else fsm_close(f, reason); } /* * lcp_lowerup - The lower layer is up. */ void lcp_lowerup(unit) int unit; { lcp_options *wo = &lcp_wantoptions[unit]; fsm *f = &lcp_fsm[unit]; /* * Don't use A/C or protocol compression on transmission, * but accept A/C and protocol compressed packets * if we are going to ask for A/C and protocol compression. */ if (ppp_send_config(unit, PPP_MRU, 0xffffffff, 0, 0) < 0 || ppp_recv_config(unit, PPP_MRU, (lax_recv? 0: 0xffffffff), wo->neg_pcompression, wo->neg_accompression) < 0) return; peer_mru[unit] = PPP_MRU; if (listen_time != 0) { f->flags |= DELAYED_UP; timeout(lcp_delayed_up, f, 0, listen_time * 1000); } else fsm_lowerup(f); } /* * lcp_lowerdown - The lower layer is down. */ void lcp_lowerdown(unit) int unit; { fsm *f = &lcp_fsm[unit]; if (f->flags & DELAYED_UP) f->flags &= ~DELAYED_UP; else fsm_lowerdown(&lcp_fsm[unit]); } /* * lcp_delayed_up - Bring the lower layer up now. */ static void lcp_delayed_up(arg) void *arg; { fsm *f = arg; if (f->flags & DELAYED_UP) { f->flags &= ~DELAYED_UP; fsm_lowerup(f); } } /* * lcp_input - Input LCP packet. */ static void lcp_input(unit, p, len) int unit; u_char *p; int len; { fsm *f = &lcp_fsm[unit]; if (f->flags & DELAYED_UP) { f->flags &= ~DELAYED_UP; fsm_lowerup(f); } fsm_input(f, p, len); } /* * lcp_extcode - Handle a LCP-specific code. */ static int lcp_extcode(f, code, id, inp, len) fsm *f; int code, id; u_char *inp; int len; { u_char *magp; switch( code ){ case PROTREJ: lcp_rprotrej(f, inp, len); break; case ECHOREQ: if (f->state != OPENED) break; magp = inp; PUTLONG(lcp_gotoptions[f->unit].magicnumber, magp); fsm_sdata(f, ECHOREP, id, inp, len); break; case ECHOREP: lcp_received_echo_reply(f, id, inp, len); break; case DISCREQ: break; default: return 0; } return 1; } /* * lcp_rprotrej - Receive an Protocol-Reject. * * Figure out which protocol is rejected and inform it. */ static void lcp_rprotrej(f, inp, len) fsm *f; u_char *inp; int len; { int i; struct protent *protp; u_short prot; if (len < 2) { LCPDEBUG(("lcp_rprotrej: Rcvd short Protocol-Reject packet!")); return; } GETSHORT(prot, inp); /* * Protocol-Reject packets received in any state other than the LCP * OPENED state SHOULD be silently discarded. */ if( f->state != OPENED ){ LCPDEBUG(("Protocol-Reject discarded: LCP in state %d", f->state)); return; } /* * Upcall the proper Protocol-Reject routine. */ for (i = 0; (protp = protocols[i]) != NULL; ++i) if (protp->protocol == prot && protp->enabled_flag) { (*protp->protrej)(f->unit); return; } warn("Protocol-Reject for unsupported protocol 0x%x", prot); } /* * lcp_protrej - A Protocol-Reject was received. */ /*ARGSUSED*/ static void lcp_protrej(unit) int unit; { /* * Can't reject LCP! */ error("Received Protocol-Reject for LCP!"); fsm_protreject(&lcp_fsm[unit]); } /* * lcp_sprotrej - Send a Protocol-Reject for some protocol. */ void lcp_sprotrej(unit, p, len) int unit; u_char *p; int len; { /* * Send back the protocol and the information field of the * rejected packet. We only get here if LCP is in the OPENED state. */ p += 2; len -= 2; fsm_sdata(&lcp_fsm[unit], PROTREJ, ++lcp_fsm[unit].id, p, len); } /* * lcp_resetci - Reset our CI. */ static void lcp_resetci(f) fsm *f; { lcp_options *wo = &lcp_wantoptions[f->unit]; lcp_options *go = &lcp_gotoptions[f->unit]; lcp_options *ao = &lcp_allowoptions[f->unit]; wo->magicnumber = magic(); wo->numloops = 0; *go = *wo; if (!multilink) { go->neg_mrru = 0; go->neg_ssnhf = 0; go->neg_endpoint = 0; } if (noendpoint) ao->neg_endpoint = 0; peer_mru[f->unit] = PPP_MRU; auth_reset(f->unit); } /* * lcp_cilen - Return length of our CI. */ static int lcp_cilen(f) fsm *f; { lcp_options *go = &lcp_gotoptions[f->unit]; #define LENCIVOID(neg) ((neg) ? CILEN_VOID : 0) #define LENCICHAP(neg) ((neg) ? CILEN_CHAP : 0) #define LENCISHORT(neg) ((neg) ? CILEN_SHORT : 0) #define LENCILONG(neg) ((neg) ? CILEN_LONG : 0) #define LENCILQR(neg) ((neg) ? CILEN_LQR: 0) #define LENCICBCP(neg) ((neg) ? CILEN_CBCP: 0) /* * NB: we only ask for one of CHAP, UPAP, or EAP, even if we will * accept more than one. We prefer EAP first, then CHAP, then * PAP. */ return (LENCISHORT(go->neg_mru && go->mru != DEFMRU) + LENCILONG(go->neg_asyncmap && go->asyncmap != 0xFFFFFFFF) + LENCISHORT(go->neg_eap) + LENCICHAP(!go->neg_eap && go->neg_chap) + LENCISHORT(!go->neg_eap && !go->neg_chap && go->neg_upap) + LENCILQR(go->neg_lqr) + LENCICBCP(go->neg_cbcp) + LENCILONG(go->neg_magicnumber) + LENCIVOID(go->neg_pcompression) + LENCIVOID(go->neg_accompression) + LENCISHORT(go->neg_mrru) + LENCIVOID(go->neg_ssnhf) + (go->neg_endpoint? CILEN_CHAR + go->endpoint.length: 0)); } /* * lcp_addci - Add our desired CIs to a packet. */ static void lcp_addci(f, ucp, lenp) fsm *f; u_char *ucp; int *lenp; { lcp_options *go = &lcp_gotoptions[f->unit]; u_char *start_ucp = ucp; #define ADDCIVOID(opt, neg) \ if (neg) { \ PUTCHAR(opt, ucp); \ PUTCHAR(CILEN_VOID, ucp); \ } #define ADDCISHORT(opt, neg, val) \ if (neg) { \ PUTCHAR(opt, ucp); \ PUTCHAR(CILEN_SHORT, ucp); \ PUTSHORT(val, ucp); \ } #define ADDCICHAP(opt, neg, val) \ if (neg) { \ PUTCHAR((opt), ucp); \ PUTCHAR(CILEN_CHAP, ucp); \ PUTSHORT(PPP_CHAP, ucp); \ PUTCHAR((CHAP_DIGEST(val)), ucp); \ } #define ADDCILONG(opt, neg, val) \ if (neg) { \ PUTCHAR(opt, ucp); \ PUTCHAR(CILEN_LONG, ucp); \ PUTLONG(val, ucp); \ } #define ADDCILQR(opt, neg, val) \ if (neg) { \ PUTCHAR(opt, ucp); \ PUTCHAR(CILEN_LQR, ucp); \ PUTSHORT(PPP_LQR, ucp); \ PUTLONG(val, ucp); \ } #define ADDCICHAR(opt, neg, val) \ if (neg) { \ PUTCHAR(opt, ucp); \ PUTCHAR(CILEN_CHAR, ucp); \ PUTCHAR(val, ucp); \ } #define ADDCIENDP(opt, neg, class, val, len) \ if (neg) { \ int i; \ PUTCHAR(opt, ucp); \ PUTCHAR(CILEN_CHAR + len, ucp); \ PUTCHAR(class, ucp); \ for (i = 0; i < len; ++i) \ PUTCHAR(val[i], ucp); \ } ADDCISHORT(CI_MRU, go->neg_mru && go->mru != DEFMRU, go->mru); ADDCILONG(CI_ASYNCMAP, go->neg_asyncmap && go->asyncmap != 0xFFFFFFFF, go->asyncmap); ADDCISHORT(CI_AUTHTYPE, go->neg_eap, PPP_EAP); ADDCICHAP(CI_AUTHTYPE, !go->neg_eap && go->neg_chap, go->chap_mdtype); ADDCISHORT(CI_AUTHTYPE, !go->neg_eap && !go->neg_chap && go->neg_upap, PPP_PAP); ADDCILQR(CI_QUALITY, go->neg_lqr, go->lqr_period); ADDCICHAR(CI_CALLBACK, go->neg_cbcp, CBCP_OPT); ADDCILONG(CI_MAGICNUMBER, go->neg_magicnumber, go->magicnumber); ADDCIVOID(CI_PCOMPRESSION, go->neg_pcompression); ADDCIVOID(CI_ACCOMPRESSION, go->neg_accompression); ADDCISHORT(CI_MRRU, go->neg_mrru, go->mrru); ADDCIVOID(CI_SSNHF, go->neg_ssnhf); ADDCIENDP(CI_EPDISC, go->neg_endpoint, go->endpoint.class, go->endpoint.value, go->endpoint.length); if (ucp - start_ucp != *lenp) { /* this should never happen, because peer_mtu should be 1500 */ error("Bug in lcp_addci: wrong length"); } } /* * lcp_ackci - Ack our CIs. * This should not modify any state if the Ack is bad. * * Returns: * 0 - Ack was bad. * 1 - Ack was good. */ static int lcp_ackci(f, p, len) fsm *f; u_char *p; int len; { lcp_options *go = &lcp_gotoptions[f->unit]; u_char cilen, citype, cichar; u_short cishort; u_int32_t cilong; /* * CIs must be in exactly the same order that we sent. * Check packet length and CI length at each step. * If we find any deviations, then this packet is bad. */ #define ACKCIVOID(opt, neg) \ if (neg) { \ if ((len -= CILEN_VOID) < 0) \ goto bad; \ GETCHAR(citype, p); \ GETCHAR(cilen, p); \ if (cilen != CILEN_VOID || \ citype != opt) \ goto bad; \ } #define ACKCISHORT(opt, neg, val) \ if (neg) { \ if ((len -= CILEN_SHORT) < 0) \ goto bad; \ GETCHAR(citype, p); \ GETCHAR(cilen, p); \ if (cilen != CILEN_SHORT || \ citype != opt) \ goto bad; \ GETSHORT(cishort, p); \ if (cishort != val) \ goto bad; \ } #define ACKCICHAR(opt, neg, val) \ if (neg) { \ if ((len -= CILEN_CHAR) < 0) \ goto bad; \ GETCHAR(citype, p); \ GETCHAR(cilen, p); \ if (cilen != CILEN_CHAR || \ citype != opt) \ goto bad; \ GETCHAR(cichar, p); \ if (cichar != val) \ goto bad; \ } #define ACKCICHAP(opt, neg, val) \ if (neg) { \ if ((len -= CILEN_CHAP) < 0) \ goto bad; \ GETCHAR(citype, p); \ GETCHAR(cilen, p); \ if (cilen != CILEN_CHAP || \ citype != (opt)) \ goto bad; \ GETSHORT(cishort, p); \ if (cishort != PPP_CHAP) \ goto bad; \ GETCHAR(cichar, p); \ if (cichar != (CHAP_DIGEST(val))) \ goto bad; \ } #define ACKCILONG(opt, neg, val) \ if (neg) { \ if ((len -= CILEN_LONG) < 0) \ goto bad; \ GETCHAR(citype, p); \ GETCHAR(cilen, p); \ if (cilen != CILEN_LONG || \ citype != opt) \ goto bad; \ GETLONG(cilong, p); \ if (cilong != val) \ goto bad; \ } #define ACKCILQR(opt, neg, val) \ if (neg) { \ if ((len -= CILEN_LQR) < 0) \ goto bad; \ GETCHAR(citype, p); \ GETCHAR(cilen, p); \ if (cilen != CILEN_LQR || \ citype != opt) \ goto bad; \ GETSHORT(cishort, p); \ if (cishort != PPP_LQR) \ goto bad; \ GETLONG(cilong, p); \ if (cilong != val) \ goto bad; \ } #define ACKCIENDP(opt, neg, class, val, vlen) \ if (neg) { \ int i; \ if ((len -= CILEN_CHAR + vlen) < 0) \ goto bad; \ GETCHAR(citype, p); \ GETCHAR(cilen, p); \ if (cilen != CILEN_CHAR + vlen || \ citype != opt) \ goto bad; \ GETCHAR(cichar, p); \ if (cichar != class) \ goto bad; \ for (i = 0; i < vlen; ++i) { \ GETCHAR(cichar, p); \ if (cichar != val[i]) \ goto bad; \ } \ } ACKCISHORT(CI_MRU, go->neg_mru && go->mru != DEFMRU, go->mru); ACKCILONG(CI_ASYNCMAP, go->neg_asyncmap && go->asyncmap != 0xFFFFFFFF, go->asyncmap); ACKCISHORT(CI_AUTHTYPE, go->neg_eap, PPP_EAP); ACKCICHAP(CI_AUTHTYPE, !go->neg_eap && go->neg_chap, go->chap_mdtype); ACKCISHORT(CI_AUTHTYPE, !go->neg_eap && !go->neg_chap && go->neg_upap, PPP_PAP); ACKCILQR(CI_QUALITY, go->neg_lqr, go->lqr_period); ACKCICHAR(CI_CALLBACK, go->neg_cbcp, CBCP_OPT); ACKCILONG(CI_MAGICNUMBER, go->neg_magicnumber, go->magicnumber); ACKCIVOID(CI_PCOMPRESSION, go->neg_pcompression); ACKCIVOID(CI_ACCOMPRESSION, go->neg_accompression); ACKCISHORT(CI_MRRU, go->neg_mrru, go->mrru); ACKCIVOID(CI_SSNHF, go->neg_ssnhf); ACKCIENDP(CI_EPDISC, go->neg_endpoint, go->endpoint.class, go->endpoint.value, go->endpoint.length); /* * If there are any remaining CIs, then this packet is bad. */ if (len != 0) goto bad; return (1); bad: LCPDEBUG(("lcp_acki: received bad Ack!")); return (0); } /* * lcp_nakci - Peer has sent a NAK for some of our CIs. * This should not modify any state if the Nak is bad * or if LCP is in the OPENED state. * * Returns: * 0 - Nak was bad. * 1 - Nak was good. */ static int lcp_nakci(f, p, len, treat_as_reject) fsm *f; u_char *p; int len; int treat_as_reject; { lcp_options *go = &lcp_gotoptions[f->unit]; lcp_options *wo = &lcp_wantoptions[f->unit]; u_char citype, cichar, *next; u_short cishort; u_int32_t cilong; lcp_options no; /* options we've seen Naks for */ lcp_options try; /* options to request next time */ int looped_back = 0; int cilen; BZERO(&no, sizeof(no)); try = *go; /* * Any Nak'd CIs must be in exactly the same order that we sent. * Check packet length and CI length at each step. * If we find any deviations, then this packet is bad. */ #define NAKCIVOID(opt, neg) \ if (go->neg && \ len >= CILEN_VOID && \ p[1] == CILEN_VOID && \ p[0] == opt) { \ len -= CILEN_VOID; \ INCPTR(CILEN_VOID, p); \ no.neg = 1; \ try.neg = 0; \ } #define NAKCICHAP(opt, neg, code) \ if (go->neg && \ len >= CILEN_CHAP && \ p[1] == CILEN_CHAP && \ p[0] == opt) { \ len -= CILEN_CHAP; \ INCPTR(2, p); \ GETSHORT(cishort, p); \ GETCHAR(cichar, p); \ no.neg = 1; \ code \ } #define NAKCICHAR(opt, neg, code) \ if (go->neg && \ len >= CILEN_CHAR && \ p[1] == CILEN_CHAR && \ p[0] == opt) { \ len -= CILEN_CHAR; \ INCPTR(2, p); \ GETCHAR(cichar, p); \ no.neg = 1; \ code \ } #define NAKCISHORT(opt, neg, code) \ if (go->neg && \ len >= CILEN_SHORT && \ p[1] == CILEN_SHORT && \ p[0] == opt) { \ len -= CILEN_SHORT; \ INCPTR(2, p); \ GETSHORT(cishort, p); \ no.neg = 1; \ code \ } #define NAKCILONG(opt, neg, code) \ if (go->neg && \ len >= CILEN_LONG && \ p[1] == CILEN_LONG && \ p[0] == opt) { \ len -= CILEN_LONG; \ INCPTR(2, p); \ GETLONG(cilong, p); \ no.neg = 1; \ code \ } #define NAKCILQR(opt, neg, code) \ if (go->neg && \ len >= CILEN_LQR && \ p[1] == CILEN_LQR && \ p[0] == opt) { \ len -= CILEN_LQR; \ INCPTR(2, p); \ GETSHORT(cishort, p); \ GETLONG(cilong, p); \ no.neg = 1; \ code \ } #define NAKCIENDP(opt, neg) \ if (go->neg && \ len >= CILEN_CHAR && \ p[0] == opt && \ p[1] >= CILEN_CHAR && \ p[1] <= len) { \ len -= p[1]; \ INCPTR(p[1], p); \ no.neg = 1; \ try.neg = 0; \ } /* * NOTE! There must be no assignments to individual fields of *go in * the code below. Any such assignment is a BUG! */ /* * We don't care if they want to send us smaller packets than * we want. Therefore, accept any MRU less than what we asked for, * but then ignore the new value when setting the MRU in the kernel. * If they send us a bigger MRU than what we asked, accept it, up to * the limit of the default MRU we'd get if we didn't negotiate. */ if (go->neg_mru && go->mru != DEFMRU) { NAKCISHORT(CI_MRU, neg_mru, if (cishort <= wo->mru || cishort <= DEFMRU) try.mru = cishort; ); } /* * Add any characters they want to our (receive-side) asyncmap. */ if (go->neg_asyncmap && go->asyncmap != 0xFFFFFFFF) { NAKCILONG(CI_ASYNCMAP, neg_asyncmap, try.asyncmap = go->asyncmap | cilong; ); } /* * If they've nak'd our authentication-protocol, check whether * they are proposing a different protocol, or a different * hash algorithm for CHAP. */ if ((go->neg_chap || go->neg_upap || go->neg_eap) && len >= CILEN_SHORT && p[0] == CI_AUTHTYPE && p[1] >= CILEN_SHORT && p[1] <= len) { cilen = p[1]; len -= cilen; no.neg_chap = go->neg_chap; no.neg_upap = go->neg_upap; no.neg_eap = go->neg_eap; INCPTR(2, p); GETSHORT(cishort, p); if (cishort == PPP_PAP && cilen == CILEN_SHORT) { /* If we were asking for EAP, then we need to stop that. */ if (go->neg_eap) try.neg_eap = 0; /* If we were asking for CHAP, then we need to stop that. */ else if (go->neg_chap) try.neg_chap = 0; /* * If we weren't asking for CHAP or EAP, then we were asking for * PAP, in which case this Nak is bad. */ else goto bad; } else if (cishort == PPP_CHAP && cilen == CILEN_CHAP) { GETCHAR(cichar, p); /* Stop asking for EAP, if we were. */ if (go->neg_eap) { try.neg_eap = 0; /* Try to set up to use their suggestion, if possible */ if (CHAP_CANDIGEST(go->chap_mdtype, cichar)) try.chap_mdtype = CHAP_MDTYPE_D(cichar); } else if (go->neg_chap) { /* * We were asking for our preferred algorithm, they must * want something different. */ if (cichar != CHAP_DIGEST(go->chap_mdtype)) { if (CHAP_CANDIGEST(go->chap_mdtype, cichar)) { /* Use their suggestion if we support it ... */ try.chap_mdtype = CHAP_MDTYPE_D(cichar); } else { /* ... otherwise, try our next-preferred algorithm. */ try.chap_mdtype &= ~(CHAP_MDTYPE(try.chap_mdtype)); if (try.chap_mdtype == MDTYPE_NONE) /* out of algos */ try.neg_chap = 0; } } else { /* * Whoops, they Nak'd our algorithm of choice * but then suggested it back to us. */ goto bad; } } else { /* * Stop asking for PAP if we were asking for it. */ try.neg_upap = 0; } } else { /* * If we were asking for EAP, and they're Conf-Naking EAP, * well, that's just strange. Nobody should do that. */ if (cishort == PPP_EAP && cilen == CILEN_SHORT && go->neg_eap) dbglog("Unexpected Conf-Nak for EAP"); /* * We don't recognize what they're suggesting. * Stop asking for what we were asking for. */ if (go->neg_eap) try.neg_eap = 0; else if (go->neg_chap) try.neg_chap = 0; else try.neg_upap = 0; p += cilen - CILEN_SHORT; } } /* * If they can't cope with our link quality protocol, we'll have * to stop asking for LQR. We haven't got any other protocol. * If they Nak the reporting period, take their value XXX ? */ NAKCILQR(CI_QUALITY, neg_lqr, if (cishort != PPP_LQR) try.neg_lqr = 0; else try.lqr_period = cilong; ); /* * Only implementing CBCP...not the rest of the callback options */ NAKCICHAR(CI_CALLBACK, neg_cbcp, try.neg_cbcp = 0; ); /* * Check for a looped-back line. */ NAKCILONG(CI_MAGICNUMBER, neg_magicnumber, try.magicnumber = magic(); looped_back = 1; ); /* * Peer shouldn't send Nak for protocol compression or * address/control compression requests; they should send * a Reject instead. If they send a Nak, treat it as a Reject. */ NAKCIVOID(CI_PCOMPRESSION, neg_pcompression); NAKCIVOID(CI_ACCOMPRESSION, neg_accompression); /* * Nak for MRRU option - accept their value if it is smaller * than the one we want. */ if (go->neg_mrru) { NAKCISHORT(CI_MRRU, neg_mrru, if (treat_as_reject) try.neg_mrru = 0; else if (cishort <= wo->mrru) try.mrru = cishort; ); } /* * Nak for short sequence numbers shouldn't be sent, treat it * like a reject. */ NAKCIVOID(CI_SSNHF, neg_ssnhf); /* * Nak of the endpoint discriminator option is not permitted, * treat it like a reject. */ NAKCIENDP(CI_EPDISC, neg_endpoint); /* * There may be remaining CIs, if the peer is requesting negotiation * on an option that we didn't include in our request packet. * If we see an option that we requested, or one we've already seen * in this packet, then this packet is bad. * If we wanted to respond by starting to negotiate on the requested * option(s), we could, but we don't, because except for the * authentication type and quality protocol, if we are not negotiating * an option, it is because we were told not to. * For the authentication type, the Nak from the peer means * `let me authenticate myself with you' which is a bit pointless. * For the quality protocol, the Nak means `ask me to send you quality * reports', but if we didn't ask for them, we don't want them. * An option we don't recognize represents the peer asking to * negotiate some option we don't support, so ignore it. */ while (len >= CILEN_VOID) { GETCHAR(citype, p); GETCHAR(cilen, p); if (cilen < CILEN_VOID || (len -= cilen) < 0) goto bad; next = p + cilen - 2; switch (citype) { case CI_MRU: if ((go->neg_mru && go->mru != DEFMRU) || no.neg_mru || cilen != CILEN_SHORT) goto bad; GETSHORT(cishort, p); if (cishort < DEFMRU) { try.neg_mru = 1; try.mru = cishort; } break; case CI_ASYNCMAP: if ((go->neg_asyncmap && go->asyncmap != 0xFFFFFFFF) || no.neg_asyncmap || cilen != CILEN_LONG) goto bad; break; case CI_AUTHTYPE: if (go->neg_chap || no.neg_chap || go->neg_upap || no.neg_upap || go->neg_eap || no.neg_eap) goto bad; break; case CI_MAGICNUMBER: if (go->neg_magicnumber || no.neg_magicnumber || cilen != CILEN_LONG) goto bad; break; case CI_PCOMPRESSION: if (go->neg_pcompression || no.neg_pcompression || cilen != CILEN_VOID) goto bad; break; case CI_ACCOMPRESSION: if (go->neg_accompression || no.neg_accompression || cilen != CILEN_VOID) goto bad; break; case CI_QUALITY: if (go->neg_lqr || no.neg_lqr || cilen != CILEN_LQR) goto bad; break; case CI_MRRU: if (go->neg_mrru || no.neg_mrru || cilen != CILEN_SHORT) goto bad; break; case CI_SSNHF: if (go->neg_ssnhf || no.neg_ssnhf || cilen != CILEN_VOID) goto bad; try.neg_ssnhf = 1; break; case CI_EPDISC: if (go->neg_endpoint || no.neg_endpoint || cilen < CILEN_CHAR) goto bad; break; } p = next; } /* * OK, the Nak is good. Now we can update state. * If there are any options left we ignore them. */ if (f->state != OPENED) { if (looped_back) { if (++try.numloops >= lcp_loopbackfail) { notice("Serial line is looped back."); lcp_close(f->unit, "Loopback detected"); status = EXIT_LOOPBACK; } } else try.numloops = 0; *go = try; } return 1; bad: LCPDEBUG(("lcp_nakci: received bad Nak!")); return 0; } /* * lcp_rejci - Peer has Rejected some of our CIs. * This should not modify any state if the Reject is bad * or if LCP is in the OPENED state. * * Returns: * 0 - Reject was bad. * 1 - Reject was good. */ static int lcp_rejci(f, p, len) fsm *f; u_char *p; int len; { lcp_options *go = &lcp_gotoptions[f->unit]; u_char cichar; u_short cishort; u_int32_t cilong; lcp_options try; /* options to request next time */ try = *go; /* * Any Rejected CIs must be in exactly the same order that we sent. * Check packet length and CI length at each step. * If we find any deviations, then this packet is bad. */ #define REJCIVOID(opt, neg) \ if (go->neg && \ len >= CILEN_VOID && \ p[1] == CILEN_VOID && \ p[0] == opt) { \ len -= CILEN_VOID; \ INCPTR(CILEN_VOID, p); \ try.neg = 0; \ } #define REJCISHORT(opt, neg, val) \ if (go->neg && \ len >= CILEN_SHORT && \ p[1] == CILEN_SHORT && \ p[0] == opt) { \ len -= CILEN_SHORT; \ INCPTR(2, p); \ GETSHORT(cishort, p); \ /* Check rejected value. */ \ if (cishort != val) \ goto bad; \ try.neg = 0; \ } #define REJCICHAP(opt, neg, val) \ if (go->neg && \ len >= CILEN_CHAP && \ p[1] == CILEN_CHAP && \ p[0] == opt) { \ len -= CILEN_CHAP; \ INCPTR(2, p); \ GETSHORT(cishort, p); \ GETCHAR(cichar, p); \ /* Check rejected value. */ \ if ((cishort != PPP_CHAP) || (cichar != (CHAP_DIGEST(val)))) \ goto bad; \ try.neg = 0; \ try.neg_eap = try.neg_upap = 0; \ } #define REJCILONG(opt, neg, val) \ if (go->neg && \ len >= CILEN_LONG && \ p[1] == CILEN_LONG && \ p[0] == opt) { \ len -= CILEN_LONG; \ INCPTR(2, p); \ GETLONG(cilong, p); \ /* Check rejected value. */ \ if (cilong != val) \ goto bad; \ try.neg = 0; \ } #define REJCILQR(opt, neg, val) \ if (go->neg && \ len >= CILEN_LQR && \ p[1] == CILEN_LQR && \ p[0] == opt) { \ len -= CILEN_LQR; \ INCPTR(2, p); \ GETSHORT(cishort, p); \ GETLONG(cilong, p); \ /* Check rejected value. */ \ if (cishort != PPP_LQR || cilong != val) \ goto bad; \ try.neg = 0; \ } #define REJCICBCP(opt, neg, val) \ if (go->neg && \ len >= CILEN_CBCP && \ p[1] == CILEN_CBCP && \ p[0] == opt) { \ len -= CILEN_CBCP; \ INCPTR(2, p); \ GETCHAR(cichar, p); \ /* Check rejected value. */ \ if (cichar != val) \ goto bad; \ try.neg = 0; \ } #define REJCIENDP(opt, neg, class, val, vlen) \ if (go->neg && \ len >= CILEN_CHAR + vlen && \ p[0] == opt && \ p[1] == CILEN_CHAR + vlen) { \ int i; \ len -= CILEN_CHAR + vlen; \ INCPTR(2, p); \ GETCHAR(cichar, p); \ if (cichar != class) \ goto bad; \ for (i = 0; i < vlen; ++i) { \ GETCHAR(cichar, p); \ if (cichar != val[i]) \ goto bad; \ } \ try.neg = 0; \ } REJCISHORT(CI_MRU, neg_mru, go->mru); REJCILONG(CI_ASYNCMAP, neg_asyncmap, go->asyncmap); REJCISHORT(CI_AUTHTYPE, neg_eap, PPP_EAP); if (!go->neg_eap) { REJCICHAP(CI_AUTHTYPE, neg_chap, go->chap_mdtype); if (!go->neg_chap) { REJCISHORT(CI_AUTHTYPE, neg_upap, PPP_PAP); } } REJCILQR(CI_QUALITY, neg_lqr, go->lqr_period); REJCICBCP(CI_CALLBACK, neg_cbcp, CBCP_OPT); REJCILONG(CI_MAGICNUMBER, neg_magicnumber, go->magicnumber); REJCIVOID(CI_PCOMPRESSION, neg_pcompression); REJCIVOID(CI_ACCOMPRESSION, neg_accompression); REJCISHORT(CI_MRRU, neg_mrru, go->mrru); REJCIVOID(CI_SSNHF, neg_ssnhf); REJCIENDP(CI_EPDISC, neg_endpoint, go->endpoint.class, go->endpoint.value, go->endpoint.length); /* * If there are any remaining CIs, then this packet is bad. */ if (len != 0) goto bad; /* * Now we can update state. */ if (f->state != OPENED) *go = try; return 1; bad: LCPDEBUG(("lcp_rejci: received bad Reject!")); return 0; } /* * lcp_reqci - Check the peer's requested CIs and send appropriate response. * * Returns: CONFACK, CONFNAK or CONFREJ and input packet modified * appropriately. If reject_if_disagree is non-zero, doesn't return * CONFNAK; returns CONFREJ if it can't return CONFACK. */ static int lcp_reqci(f, inp, lenp, reject_if_disagree) fsm *f; u_char *inp; /* Requested CIs */ int *lenp; /* Length of requested CIs */ int reject_if_disagree; { lcp_options *go = &lcp_gotoptions[f->unit]; lcp_options *ho = &lcp_hisoptions[f->unit]; lcp_options *ao = &lcp_allowoptions[f->unit]; u_char *cip, *next; /* Pointer to current and next CIs */ int cilen, citype, cichar; /* Parsed len, type, char value */ u_short cishort; /* Parsed short value */ u_int32_t cilong; /* Parse long value */ int rc = CONFACK; /* Final packet return code */ int orc; /* Individual option return code */ u_char *p; /* Pointer to next char to parse */ u_char *rejp; /* Pointer to next char in reject frame */ u_char *nakp; /* Pointer to next char in Nak frame */ int l = *lenp; /* Length left */ /* * Reset all his options. */ BZERO(ho, sizeof(*ho)); /* * Process all his options. */ next = inp; nakp = nak_buffer; rejp = inp; while (l) { orc = CONFACK; /* Assume success */ cip = p = next; /* Remember begining of CI */ if (l < 2 || /* Not enough data for CI header or */ p[1] < 2 || /* CI length too small or */ p[1] > l) { /* CI length too big? */ LCPDEBUG(("lcp_reqci: bad CI length!")); orc = CONFREJ; /* Reject bad CI */ cilen = l; /* Reject till end of packet */ l = 0; /* Don't loop again */ citype = 0; goto endswitch; } GETCHAR(citype, p); /* Parse CI type */ GETCHAR(cilen, p); /* Parse CI length */ l -= cilen; /* Adjust remaining length */ next += cilen; /* Step to next CI */ switch (citype) { /* Check CI type */ case CI_MRU: if (!ao->neg_mru || /* Allow option? */ cilen != CILEN_SHORT) { /* Check CI length */ orc = CONFREJ; /* Reject CI */ break; } GETSHORT(cishort, p); /* Parse MRU */ /* * He must be able to receive at least our minimum. * No need to check a maximum. If he sends a large number, * we'll just ignore it. */ if (cishort < MINMRU) { orc = CONFNAK; /* Nak CI */ PUTCHAR(CI_MRU, nakp); PUTCHAR(CILEN_SHORT, nakp); PUTSHORT(MINMRU, nakp); /* Give him a hint */ break; } ho->neg_mru = 1; /* Remember he sent MRU */ ho->mru = cishort; /* And remember value */ break; case CI_ASYNCMAP: if (!ao->neg_asyncmap || cilen != CILEN_LONG) { orc = CONFREJ; break; } GETLONG(cilong, p); /* * Asyncmap must have set at least the bits * which are set in lcp_allowoptions[unit].asyncmap. */ if ((ao->asyncmap & ~cilong) != 0) { orc = CONFNAK; PUTCHAR(CI_ASYNCMAP, nakp); PUTCHAR(CILEN_LONG, nakp); PUTLONG(ao->asyncmap | cilong, nakp); break; } ho->neg_asyncmap = 1; ho->asyncmap = cilong; break; case CI_AUTHTYPE: if (cilen < CILEN_SHORT || !(ao->neg_upap || ao->neg_chap || ao->neg_eap)) { /* * Reject the option if we're not willing to authenticate. */ dbglog("No auth is possible"); orc = CONFREJ; break; } GETSHORT(cishort, p); /* * Authtype must be PAP, CHAP, or EAP. * * Note: if more than one of ao->neg_upap, ao->neg_chap, and * ao->neg_eap are set, and the peer sends a Configure-Request * with two or more authenticate-protocol requests, then we will * reject the second request. * Whether we end up doing CHAP, UPAP, or EAP depends then on * the ordering of the CIs in the peer's Configure-Request. */ if (cishort == PPP_PAP) { /* we've already accepted CHAP or EAP */ if (ho->neg_chap || ho->neg_eap || cilen != CILEN_SHORT) { LCPDEBUG(("lcp_reqci: rcvd AUTHTYPE PAP, rejecting...")); orc = CONFREJ; break; } if (!ao->neg_upap) { /* we don't want to do PAP */ orc = CONFNAK; /* NAK it and suggest CHAP or EAP */ PUTCHAR(CI_AUTHTYPE, nakp); if (ao->neg_eap) { PUTCHAR(CILEN_SHORT, nakp); PUTSHORT(PPP_EAP, nakp); } else { PUTCHAR(CILEN_CHAP, nakp); PUTSHORT(PPP_CHAP, nakp); PUTCHAR(CHAP_DIGEST(ao->chap_mdtype), nakp); } break; } ho->neg_upap = 1; break; } if (cishort == PPP_CHAP) { /* we've already accepted PAP or EAP */ if (ho->neg_upap || ho->neg_eap || cilen != CILEN_CHAP) { LCPDEBUG(("lcp_reqci: rcvd AUTHTYPE CHAP, rejecting...")); orc = CONFREJ; break; } if (!ao->neg_chap) { /* we don't want to do CHAP */ orc = CONFNAK; /* NAK it and suggest EAP or PAP */ PUTCHAR(CI_AUTHTYPE, nakp); PUTCHAR(CILEN_SHORT, nakp); if (ao->neg_eap) { PUTSHORT(PPP_EAP, nakp); } else { PUTSHORT(PPP_PAP, nakp); } break; } GETCHAR(cichar, p); /* get digest type */ if (!(CHAP_CANDIGEST(ao->chap_mdtype, cichar))) { /* * We can't/won't do the requested type, * suggest something else. */ orc = CONFNAK; PUTCHAR(CI_AUTHTYPE, nakp); PUTCHAR(CILEN_CHAP, nakp); PUTSHORT(PPP_CHAP, nakp); PUTCHAR(CHAP_DIGEST(ao->chap_mdtype), nakp); break; } ho->chap_mdtype = CHAP_MDTYPE_D(cichar); /* save md type */ ho->neg_chap = 1; break; } if (cishort == PPP_EAP) { /* we've already accepted CHAP or PAP */ if (ho->neg_chap || ho->neg_upap || cilen != CILEN_SHORT) { LCPDEBUG(("lcp_reqci: rcvd AUTHTYPE EAP, rejecting...")); orc = CONFREJ; break; } if (!ao->neg_eap) { /* we don't want to do EAP */ orc = CONFNAK; /* NAK it and suggest CHAP or PAP */ PUTCHAR(CI_AUTHTYPE, nakp); if (ao->neg_chap) { PUTCHAR(CILEN_CHAP, nakp); PUTSHORT(PPP_CHAP, nakp); PUTCHAR(CHAP_DIGEST(ao->chap_mdtype), nakp); } else { PUTCHAR(CILEN_SHORT, nakp); PUTSHORT(PPP_PAP, nakp); } break; } ho->neg_eap = 1; break; } /* * We don't recognize the protocol they're asking for. * Nak it with something we're willing to do. * (At this point we know ao->neg_upap || ao->neg_chap || * ao->neg_eap.) */ orc = CONFNAK; PUTCHAR(CI_AUTHTYPE, nakp); if (ao->neg_eap) { PUTCHAR(CILEN_SHORT, nakp); PUTSHORT(PPP_EAP, nakp); } else if (ao->neg_chap) { PUTCHAR(CILEN_CHAP, nakp); PUTSHORT(PPP_CHAP, nakp); PUTCHAR(CHAP_DIGEST(ao->chap_mdtype), nakp); } else { PUTCHAR(CILEN_SHORT, nakp); PUTSHORT(PPP_PAP, nakp); } break; case CI_QUALITY: if (!ao->neg_lqr || cilen != CILEN_LQR) { orc = CONFREJ; break; } GETSHORT(cishort, p); GETLONG(cilong, p); /* * Check the protocol and the reporting period. * XXX When should we Nak this, and what with? */ if (cishort != PPP_LQR) { orc = CONFNAK; PUTCHAR(CI_QUALITY, nakp); PUTCHAR(CILEN_LQR, nakp); PUTSHORT(PPP_LQR, nakp); PUTLONG(ao->lqr_period, nakp); break; } break; case CI_MAGICNUMBER: if (!(ao->neg_magicnumber || go->neg_magicnumber) || cilen != CILEN_LONG) { orc = CONFREJ; break; } GETLONG(cilong, p); /* * He must have a different magic number. */ if (go->neg_magicnumber && cilong == go->magicnumber) { cilong = magic(); /* Don't put magic() inside macro! */ orc = CONFNAK; PUTCHAR(CI_MAGICNUMBER, nakp); PUTCHAR(CILEN_LONG, nakp); PUTLONG(cilong, nakp); break; } ho->neg_magicnumber = 1; ho->magicnumber = cilong; break; case CI_PCOMPRESSION: if (!ao->neg_pcompression || cilen != CILEN_VOID) { orc = CONFREJ; break; } ho->neg_pcompression = 1; break; case CI_ACCOMPRESSION: if (!ao->neg_accompression || cilen != CILEN_VOID) { orc = CONFREJ; break; } ho->neg_accompression = 1; break; case CI_MRRU: if (!ao->neg_mrru || !multilink || cilen != CILEN_SHORT) { orc = CONFREJ; break; } GETSHORT(cishort, p); /* possibly should insist on a minimum/maximum MRRU here */ ho->neg_mrru = 1; ho->mrru = cishort; break; case CI_SSNHF: if (!ao->neg_ssnhf || !multilink || cilen != CILEN_VOID) { orc = CONFREJ; break; } ho->neg_ssnhf = 1; break; case CI_EPDISC: if (!ao->neg_endpoint || cilen < CILEN_CHAR || cilen > CILEN_CHAR + MAX_ENDP_LEN) { orc = CONFREJ; break; } GETCHAR(cichar, p); cilen -= CILEN_CHAR; ho->neg_endpoint = 1; ho->endpoint.class = cichar; ho->endpoint.length = cilen; BCOPY(p, ho->endpoint.value, cilen); INCPTR(cilen, p); break; default: LCPDEBUG(("lcp_reqci: rcvd unknown option %d", citype)); orc = CONFREJ; break; } endswitch: if (orc == CONFACK && /* Good CI */ rc != CONFACK) /* but prior CI wasnt? */ continue; /* Don't send this one */ if (orc == CONFNAK) { /* Nak this CI? */ if (reject_if_disagree /* Getting fed up with sending NAKs? */ && citype != CI_MAGICNUMBER) { orc = CONFREJ; /* Get tough if so */ } else { if (rc == CONFREJ) /* Rejecting prior CI? */ continue; /* Don't send this one */ rc = CONFNAK; } } if (orc == CONFREJ) { /* Reject this CI */ rc = CONFREJ; if (cip != rejp) /* Need to move rejected CI? */ BCOPY(cip, rejp, cilen); /* Move it */ INCPTR(cilen, rejp); /* Update output pointer */ } } /* * If we wanted to send additional NAKs (for unsent CIs), the * code would go here. The extra NAKs would go at *nakp. * At present there are no cases where we want to ask the * peer to negotiate an option. */ switch (rc) { case CONFACK: *lenp = next - inp; break; case CONFNAK: /* * Copy the Nak'd options from the nak_buffer to the caller's buffer. */ *lenp = nakp - nak_buffer; BCOPY(nak_buffer, inp, *lenp); break; case CONFREJ: *lenp = rejp - inp; break; } LCPDEBUG(("lcp_reqci: returning CONF%s.", CODENAME(rc))); return (rc); /* Return final code */ } /* * lcp_up - LCP has come UP. */ static void lcp_up(f) fsm *f; { lcp_options *wo = &lcp_wantoptions[f->unit]; lcp_options *ho = &lcp_hisoptions[f->unit]; lcp_options *go = &lcp_gotoptions[f->unit]; lcp_options *ao = &lcp_allowoptions[f->unit]; int mtu, mru; if (!go->neg_magicnumber) go->magicnumber = 0; if (!ho->neg_magicnumber) ho->magicnumber = 0; /* * Set our MTU to the smaller of the MTU we wanted and * the MRU our peer wanted. If we negotiated an MRU, * set our MRU to the larger of value we wanted and * the value we got in the negotiation. * Note on the MTU: the link MTU can be the MRU the peer wanted, * the interface MTU is set to the lowest of that, the * MTU we want to use, and our link MRU. */ mtu = ho->neg_mru? ho->mru: PPP_MRU; mru = go->neg_mru? MAX(wo->mru, go->mru): PPP_MRU; #ifdef HAVE_MULTILINK if (!(multilink && go->neg_mrru && ho->neg_mrru)) #endif /* HAVE_MULTILINK */ netif_set_mtu(f->unit, MIN(MIN(mtu, mru), ao->mru)); ppp_send_config(f->unit, mtu, (ho->neg_asyncmap? ho->asyncmap: 0xffffffff), ho->neg_pcompression, ho->neg_accompression); ppp_recv_config(f->unit, mru, (lax_recv? 0: go->neg_asyncmap? go->asyncmap: 0xffffffff), go->neg_pcompression, go->neg_accompression); if (ho->neg_mru) peer_mru[f->unit] = ho->mru; lcp_echo_lowerup(f->unit); /* Enable echo messages */ link_established(f->unit); } /* * lcp_down - LCP has gone DOWN. * * Alert other protocols. */ static void lcp_down(f) fsm *f; { lcp_options *go = &lcp_gotoptions[f->unit]; lcp_echo_lowerdown(f->unit); link_down(f->unit); ppp_send_config(f->unit, PPP_MRU, 0xffffffff, 0, 0); ppp_recv_config(f->unit, PPP_MRU, (go->neg_asyncmap? go->asyncmap: 0xffffffff), go->neg_pcompression, go->neg_accompression); peer_mru[f->unit] = PPP_MRU; } /* * lcp_starting - LCP needs the lower layer up. */ static void lcp_starting(f) fsm *f; { link_required(f->unit); } /* * lcp_finished - LCP has finished with the lower layer. */ static void lcp_finished(f) fsm *f; { link_terminated(f->unit); } /* * lcp_printpkt - print the contents of an LCP packet. */ static char *lcp_codenames[] = { "ConfReq", "ConfAck", "ConfNak", "ConfRej", "TermReq", "TermAck", "CodeRej", "ProtRej", "EchoReq", "EchoRep", "DiscReq" }; static int lcp_printpkt(p, plen, printer, arg) u_char *p; int plen; void (*printer) __P((void *, char *, ...)); void *arg; { int code, id, len, olen, i; u_char *pstart, *optend; u_short cishort; u_int32_t cilong; if (plen < HEADERLEN) return 0; pstart = p; GETCHAR(code, p); GETCHAR(id, p); GETSHORT(len, p); if (len < HEADERLEN || len > plen) return 0; if (code >= 1 && code <= sizeof(lcp_codenames) / sizeof(char *)) printer(arg, " %s", lcp_codenames[code-1]); else printer(arg, " code=0x%x", code); printer(arg, " id=0x%x", id); len -= HEADERLEN; switch (code) { case CONFREQ: case CONFACK: case CONFNAK: case CONFREJ: /* print option list */ while (len >= 2) { GETCHAR(code, p); GETCHAR(olen, p); p -= 2; if (olen < 2 || olen > len) { break; } printer(arg, " <"); len -= olen; optend = p + olen; switch (code) { case CI_MRU: if (olen == CILEN_SHORT) { p += 2; GETSHORT(cishort, p); printer(arg, "mru %d", cishort); } break; case CI_ASYNCMAP: if (olen == CILEN_LONG) { p += 2; GETLONG(cilong, p); printer(arg, "asyncmap 0x%x", cilong); } break; case CI_AUTHTYPE: if (olen >= CILEN_SHORT) { p += 2; printer(arg, "auth "); GETSHORT(cishort, p); switch (cishort) { case PPP_PAP: printer(arg, "pap"); break; case PPP_CHAP: printer(arg, "chap"); if (p < optend) { switch (*p) { case CHAP_MD5: printer(arg, " MD5"); ++p; break; #ifdef CHAPMS case CHAP_MICROSOFT: printer(arg, " MS"); ++p; break; case CHAP_MICROSOFT_V2: printer(arg, " MS-v2"); ++p; break; #endif } } break; case PPP_EAP: printer(arg, "eap"); break; default: printer(arg, "0x%x", cishort); } } break; case CI_QUALITY: if (olen >= CILEN_SHORT) { p += 2; printer(arg, "quality "); GETSHORT(cishort, p); switch (cishort) { case PPP_LQR: printer(arg, "lqr"); break; default: printer(arg, "0x%x", cishort); } } break; case CI_CALLBACK: if (olen >= CILEN_CHAR) { p += 2; printer(arg, "callback "); GETCHAR(cishort, p); switch (cishort) { case CBCP_OPT: printer(arg, "CBCP"); break; default: printer(arg, "0x%x", cishort); } } break; case CI_MAGICNUMBER: if (olen == CILEN_LONG) { p += 2; GETLONG(cilong, p); printer(arg, "magic 0x%x", cilong); } break; case CI_PCOMPRESSION: if (olen == CILEN_VOID) { p += 2; printer(arg, "pcomp"); } break; case CI_ACCOMPRESSION: if (olen == CILEN_VOID) { p += 2; printer(arg, "accomp"); } break; case CI_MRRU: if (olen == CILEN_SHORT) { p += 2; GETSHORT(cishort, p); printer(arg, "mrru %d", cishort); } break; case CI_SSNHF: if (olen == CILEN_VOID) { p += 2; printer(arg, "ssnhf"); } break; case CI_EPDISC: #ifdef HAVE_MULTILINK if (olen >= CILEN_CHAR) { struct epdisc epd; p += 2; GETCHAR(epd.class, p); epd.length = olen - CILEN_CHAR; if (epd.length > MAX_ENDP_LEN) epd.length = MAX_ENDP_LEN; if (epd.length > 0) { BCOPY(p, epd.value, epd.length); p += epd.length; } printer(arg, "endpoint [%s]", epdisc_to_str(&epd)); } #else printer(arg, "endpoint"); #endif break; } while (p < optend) { GETCHAR(code, p); printer(arg, " %.2x", code); } printer(arg, ">"); } break; case TERMACK: case TERMREQ: if (len > 0 && *p >= ' ' && *p < 0x7f) { printer(arg, " "); print_string((char *)p, len, printer, arg); p += len; len = 0; } break; case ECHOREQ: case ECHOREP: case DISCREQ: if (len >= 4) { GETLONG(cilong, p); printer(arg, " magic=0x%x", cilong); p += 4; len -= 4; } break; } /* print the rest of the bytes in the packet */ for (i = 0; i < len && i < 32; ++i) { GETCHAR(code, p); printer(arg, " %.2x", code); } if (i < len) { printer(arg, " ..."); p += len - i; } return p - pstart; } /* * Time to shut down the link because there is nothing out there. */ static void LcpLinkFailure (f) fsm *f; { if (f->state == OPENED) { info("No response to %d echo-requests", lcp_echos_pending); notice("Serial link appears to be disconnected."); lcp_close(f->unit, "Peer not responding"); status = EXIT_PEER_DEAD; } } /* * Timer expired for the LCP echo requests from this process. */ static void LcpEchoCheck (f) fsm *f; { LcpSendEchoRequest (f); if (f->state != OPENED) return; /* * Start the timer for the next interval. */ if (lcp_echo_timer_running) warn("assertion lcp_echo_timer_running==0 failed"); TIMEOUT (LcpEchoTimeout, f, lcp_echo_interval); lcp_echo_timer_running = 1; } /* * LcpEchoTimeout - Timer expired on the LCP echo */ static void LcpEchoTimeout (arg) void *arg; { if (lcp_echo_timer_running != 0) { lcp_echo_timer_running = 0; LcpEchoCheck ((fsm *) arg); } } /* * LcpEchoReply - LCP has received a reply to the echo */ static void lcp_received_echo_reply (f, id, inp, len) fsm *f; int id; u_char *inp; int len; { u_int32_t magic; /* Check the magic number - don't count replies from ourselves. */ if (len < 4) { dbglog("lcp: received short Echo-Reply, length %d", len); return; } GETLONG(magic, inp); if (lcp_gotoptions[f->unit].neg_magicnumber && magic == lcp_gotoptions[f->unit].magicnumber) { warn("appear to have received our own echo-reply!"); return; } /* Reset the number of outstanding echo frames */ lcp_echos_pending = 0; } /* * LcpSendEchoRequest - Send an echo request frame to the peer */ static void LcpSendEchoRequest (f) fsm *f; { u_int32_t lcp_magic; u_char pkt[4], *pktp; /* * Detect the failure of the peer at this point. */ if (lcp_echo_fails != 0) { if (lcp_echos_pending >= lcp_echo_fails) { LcpLinkFailure(f); lcp_echos_pending = 0; } } /* * Make and send the echo request frame. */ if (f->state == OPENED) { lcp_magic = lcp_gotoptions[f->unit].magicnumber; pktp = pkt; PUTLONG(lcp_magic, pktp); fsm_sdata(f, ECHOREQ, lcp_echo_number++ & 0xFF, pkt, pktp - pkt); ++lcp_echos_pending; } } /* * lcp_echo_lowerup - Start the timer for the LCP frame */ static void lcp_echo_lowerup (unit) int unit; { fsm *f = &lcp_fsm[unit]; /* Clear the parameters for generating echo frames */ lcp_echos_pending = 0; lcp_echo_number = 0; lcp_echo_timer_running = 0; /* If a timeout interval is specified then start the timer */ if (lcp_echo_interval != 0) LcpEchoCheck (f); } /* * lcp_echo_lowerdown - Stop the timer for the LCP frame */ static void lcp_echo_lowerdown (unit) int unit; { fsm *f = &lcp_fsm[unit]; if (lcp_echo_timer_running != 0) { UNTIMEOUT (LcpEchoTimeout, f); lcp_echo_timer_running = 0; } }