minix/lib/liblwip/netif/ppp/fsm.c
Ambarisha B 7e55dbac33 LIBLWIP - updated to LwIP trunk
commit a4a41b9023ef5b3a7c4a1cd82fb167fc63e706df
Author: goldsimon <goldsimon@gmx.de>
Date:   Wed Sep 26 21:50:42 2012 +0200

- This also brings in LwIP's IPv6 codebase

Signed-off-by: Tomas Hruby <tom@minix3.org>
2013-03-25 16:51:24 +01:00

890 lines
23 KiB
C

/*****************************************************************************
* fsm.c - Network Control Protocol Finite State Machine program file.
*
* Copyright (c) 2003 by Marc Boucher, Services Informatiques (MBSI) inc.
* portions Copyright (c) 1997 by Global Election Systems Inc.
*
* The authors hereby grant permission to use, copy, modify, distribute,
* and license this software and its documentation for any purpose, provided
* that existing copyright notices are retained in all copies and that this
* notice and the following disclaimer are included verbatim in any
* distributions. No written agreement, license, or royalty fee is required
* for any of the authorized uses.
*
* THIS SOFTWARE IS PROVIDED BY THE CONTRIBUTORS *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 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.
*
******************************************************************************
* REVISION HISTORY
*
* 03-01-01 Marc Boucher <marc@mbsi.ca>
* Ported to lwIP.
* 97-12-01 Guy Lancaster <lancasterg@acm.org>, Global Election Systems Inc.
* Original based on BSD fsm.c.
*****************************************************************************/
/*
* fsm.c - {Link, IP} Control Protocol Finite State Machine.
*
* Copyright (c) 1989 Carnegie Mellon University.
* All rights reserved.
*
* Redistribution and use in source and binary forms are permitted
* provided that the above copyright notice and this paragraph are
* duplicated in all such forms and that any documentation,
* advertising materials, and other materials related to such
* distribution and use acknowledge that the software was developed
* by Carnegie Mellon University. The name of the
* University may not be used to endorse or promote products derived
* from this software without specific prior written permission.
* THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED
* WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR A PARTICULAR PURPOSE.
*/
/*
* TODO:
* Randomize fsm id on link/init.
* Deal with variable outgoing MTU.
*/
#include "lwip/opt.h"
#if PPP_SUPPORT /* don't build if not configured for use in lwipopts.h */
#include "ppp_impl.h"
#include "pppdebug.h"
#include "fsm.h"
#include <string.h>
#if PPP_DEBUG
static const char *ppperr_strerr[] = {
"LS_INITIAL", /* LS_INITIAL 0 */
"LS_STARTING", /* LS_STARTING 1 */
"LS_CLOSED", /* LS_CLOSED 2 */
"LS_STOPPED", /* LS_STOPPED 3 */
"LS_CLOSING", /* LS_CLOSING 4 */
"LS_STOPPING", /* LS_STOPPING 5 */
"LS_REQSENT", /* LS_REQSENT 6 */
"LS_ACKRCVD", /* LS_ACKRCVD 7 */
"LS_ACKSENT", /* LS_ACKSENT 8 */
"LS_OPENED" /* LS_OPENED 9 */
};
#endif /* PPP_DEBUG */
static void fsm_timeout (void *);
static void fsm_rconfreq (fsm *, u_char, u_char *, int);
static void fsm_rconfack (fsm *, int, u_char *, int);
static void fsm_rconfnakrej (fsm *, int, int, u_char *, int);
static void fsm_rtermreq (fsm *, int, u_char *, int);
static void fsm_rtermack (fsm *);
static void fsm_rcoderej (fsm *, u_char *, int);
static void fsm_sconfreq (fsm *, int);
#define PROTO_NAME(f) ((f)->callbacks->proto_name)
int peer_mru[NUM_PPP];
/*
* fsm_init - Initialize fsm.
*
* Initialize fsm state.
*/
void
fsm_init(fsm *f)
{
f->state = LS_INITIAL;
f->flags = 0;
f->id = 0; /* XXX Start with random id? */
f->timeouttime = FSM_DEFTIMEOUT;
f->maxconfreqtransmits = FSM_DEFMAXCONFREQS;
f->maxtermtransmits = FSM_DEFMAXTERMREQS;
f->maxnakloops = FSM_DEFMAXNAKLOOPS;
f->term_reason_len = 0;
}
/*
* fsm_lowerup - The lower layer is up.
*/
void
fsm_lowerup(fsm *f)
{
int oldState = f->state;
LWIP_UNUSED_ARG(oldState);
switch( f->state ) {
case LS_INITIAL:
f->state = LS_CLOSED;
break;
case LS_STARTING:
if( f->flags & OPT_SILENT ) {
f->state = LS_STOPPED;
} else {
/* Send an initial configure-request */
fsm_sconfreq(f, 0);
f->state = LS_REQSENT;
}
break;
default:
FSMDEBUG(LOG_INFO, ("%s: Up event in state %d (%s)!\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
}
FSMDEBUG(LOG_INFO, ("%s: lowerup state %d (%s) -> %d (%s)\n",
PROTO_NAME(f), oldState, ppperr_strerr[oldState], f->state, ppperr_strerr[f->state]));
}
/*
* fsm_lowerdown - The lower layer is down.
*
* Cancel all timeouts and inform upper layers.
*/
void
fsm_lowerdown(fsm *f)
{
int oldState = f->state;
LWIP_UNUSED_ARG(oldState);
switch( f->state ) {
case LS_CLOSED:
f->state = LS_INITIAL;
break;
case LS_STOPPED:
f->state = LS_STARTING;
if( f->callbacks->starting ) {
(*f->callbacks->starting)(f);
}
break;
case LS_CLOSING:
f->state = LS_INITIAL;
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
break;
case LS_STOPPING:
case LS_REQSENT:
case LS_ACKRCVD:
case LS_ACKSENT:
f->state = LS_STARTING;
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
break;
case LS_OPENED:
if( f->callbacks->down ) {
(*f->callbacks->down)(f);
}
f->state = LS_STARTING;
break;
default:
FSMDEBUG(LOG_INFO, ("%s: Down event in state %d (%s)!\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
}
FSMDEBUG(LOG_INFO, ("%s: lowerdown state %d (%s) -> %d (%s)\n",
PROTO_NAME(f), oldState, ppperr_strerr[oldState], f->state, ppperr_strerr[f->state]));
}
/*
* fsm_open - Link is allowed to come up.
*/
void
fsm_open(fsm *f)
{
int oldState = f->state;
LWIP_UNUSED_ARG(oldState);
switch( f->state ) {
case LS_INITIAL:
f->state = LS_STARTING;
if( f->callbacks->starting ) {
(*f->callbacks->starting)(f);
}
break;
case LS_CLOSED:
if( f->flags & OPT_SILENT ) {
f->state = LS_STOPPED;
} else {
/* Send an initial configure-request */
fsm_sconfreq(f, 0);
f->state = LS_REQSENT;
}
break;
case LS_CLOSING:
f->state = LS_STOPPING;
/* fall through */
case LS_STOPPED:
case LS_OPENED:
if( f->flags & OPT_RESTART ) {
fsm_lowerdown(f);
fsm_lowerup(f);
}
break;
}
FSMDEBUG(LOG_INFO, ("%s: open state %d (%s) -> %d (%s)\n",
PROTO_NAME(f), oldState, ppperr_strerr[oldState], f->state, ppperr_strerr[f->state]));
}
#if 0 /* backport pppd 2.4.4b1; */
/*
* terminate_layer - Start process of shutting down the FSM
*
* Cancel any timeout running, notify upper layers we're done, and
* send a terminate-request message as configured.
*/
static void
terminate_layer(fsm *f, int nextstate)
{
/* @todo */
}
#endif
/*
* fsm_close - Start closing connection.
*
* Cancel timeouts and either initiate close or possibly go directly to
* the LS_CLOSED state.
*/
void
fsm_close(fsm *f, char *reason)
{
int oldState = f->state;
LWIP_UNUSED_ARG(oldState);
f->term_reason = reason;
f->term_reason_len = (reason == NULL ? 0 : (int)strlen(reason));
switch( f->state ) {
case LS_STARTING:
f->state = LS_INITIAL;
break;
case LS_STOPPED:
f->state = LS_CLOSED;
break;
case LS_STOPPING:
f->state = LS_CLOSING;
break;
case LS_REQSENT:
case LS_ACKRCVD:
case LS_ACKSENT:
case LS_OPENED:
if( f->state != LS_OPENED ) {
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
} else if( f->callbacks->down ) {
(*f->callbacks->down)(f); /* Inform upper layers we're down */
}
/* Init restart counter, send Terminate-Request */
f->retransmits = f->maxtermtransmits;
fsm_sdata(f, TERMREQ, f->reqid = ++f->id,
(u_char *) f->term_reason, f->term_reason_len);
TIMEOUT(fsm_timeout, f, f->timeouttime);
--f->retransmits;
f->state = LS_CLOSING;
break;
}
FSMDEBUG(LOG_INFO, ("%s: close reason=%s state %d (%s) -> %d (%s)\n",
PROTO_NAME(f), reason, oldState, ppperr_strerr[oldState], f->state, ppperr_strerr[f->state]));
}
/*
* fsm_timeout - Timeout expired.
*/
static void
fsm_timeout(void *arg)
{
fsm *f = (fsm *) arg;
switch (f->state) {
case LS_CLOSING:
case LS_STOPPING:
if( f->retransmits <= 0 ) {
FSMDEBUG(LOG_WARNING, ("%s: timeout sending Terminate-Request state=%d (%s)\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
/*
* We've waited for an ack long enough. Peer probably heard us.
*/
f->state = (f->state == LS_CLOSING)? LS_CLOSED: LS_STOPPED;
if( f->callbacks->finished ) {
(*f->callbacks->finished)(f);
}
} else {
FSMDEBUG(LOG_WARNING, ("%s: timeout resending Terminate-Requests state=%d (%s)\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
/* Send Terminate-Request */
fsm_sdata(f, TERMREQ, f->reqid = ++f->id,
(u_char *) f->term_reason, f->term_reason_len);
TIMEOUT(fsm_timeout, f, f->timeouttime);
--f->retransmits;
}
break;
case LS_REQSENT:
case LS_ACKRCVD:
case LS_ACKSENT:
if (f->retransmits <= 0) {
FSMDEBUG(LOG_WARNING, ("%s: timeout sending Config-Requests state=%d (%s)\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
f->state = LS_STOPPED;
if( (f->flags & OPT_PASSIVE) == 0 && f->callbacks->finished ) {
(*f->callbacks->finished)(f);
}
} else {
FSMDEBUG(LOG_WARNING, ("%s: timeout resending Config-Request state=%d (%s)\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
/* Retransmit the configure-request */
if (f->callbacks->retransmit) {
(*f->callbacks->retransmit)(f);
}
fsm_sconfreq(f, 1); /* Re-send Configure-Request */
if( f->state == LS_ACKRCVD ) {
f->state = LS_REQSENT;
}
}
break;
default:
FSMDEBUG(LOG_INFO, ("%s: UNHANDLED timeout event in state %d (%s)!\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
}
}
/*
* fsm_input - Input packet.
*/
void
fsm_input(fsm *f, u_char *inpacket, int l)
{
u_char *inp = inpacket;
u_char code, id;
int len;
/*
* Parse header (code, id and length).
* If packet too short, drop it.
*/
if (l < HEADERLEN) {
FSMDEBUG(LOG_WARNING, ("fsm_input(%x): Rcvd short header.\n",
f->protocol));
return;
}
GETCHAR(code, inp);
GETCHAR(id, inp);
GETSHORT(len, inp);
if (len < HEADERLEN) {
FSMDEBUG(LOG_INFO, ("fsm_input(%x): Rcvd illegal length.\n",
f->protocol));
return;
}
if (len > l) {
FSMDEBUG(LOG_INFO, ("fsm_input(%x): Rcvd short packet.\n",
f->protocol));
return;
}
len -= HEADERLEN; /* subtract header length */
if( f->state == LS_INITIAL || f->state == LS_STARTING ) {
FSMDEBUG(LOG_INFO, ("fsm_input(%x): Rcvd packet in state %d (%s).\n",
f->protocol, f->state, ppperr_strerr[f->state]));
return;
}
FSMDEBUG(LOG_INFO, ("fsm_input(%s):%d,%d,%d\n", PROTO_NAME(f), code, id, l));
/*
* Action depends on code.
*/
switch (code) {
case CONFREQ:
fsm_rconfreq(f, id, inp, len);
break;
case CONFACK:
fsm_rconfack(f, id, inp, len);
break;
case CONFNAK:
case CONFREJ:
fsm_rconfnakrej(f, code, id, inp, len);
break;
case TERMREQ:
fsm_rtermreq(f, id, inp, len);
break;
case TERMACK:
fsm_rtermack(f);
break;
case CODEREJ:
fsm_rcoderej(f, inp, len);
break;
default:
FSMDEBUG(LOG_INFO, ("fsm_input(%s): default: \n", PROTO_NAME(f)));
if( !f->callbacks->extcode ||
!(*f->callbacks->extcode)(f, code, id, inp, len) ) {
fsm_sdata(f, CODEREJ, ++f->id, inpacket, len + HEADERLEN);
}
break;
}
}
/*
* fsm_rconfreq - Receive Configure-Request.
*/
static void
fsm_rconfreq(fsm *f, u_char id, u_char *inp, int len)
{
int code, reject_if_disagree;
FSMDEBUG(LOG_INFO, ("fsm_rconfreq(%s): Rcvd id %d state=%d (%s)\n",
PROTO_NAME(f), id, f->state, ppperr_strerr[f->state]));
switch( f->state ) {
case LS_CLOSED:
/* Go away, we're closed */
fsm_sdata(f, TERMACK, id, NULL, 0);
return;
case LS_CLOSING:
case LS_STOPPING:
return;
case LS_OPENED:
/* Go down and restart negotiation */
if( f->callbacks->down ) {
(*f->callbacks->down)(f); /* Inform upper layers */
}
fsm_sconfreq(f, 0); /* Send initial Configure-Request */
break;
case LS_STOPPED:
/* Negotiation started by our peer */
fsm_sconfreq(f, 0); /* Send initial Configure-Request */
f->state = LS_REQSENT;
break;
}
/*
* Pass the requested configuration options
* to protocol-specific code for checking.
*/
if (f->callbacks->reqci) { /* Check CI */
reject_if_disagree = (f->nakloops >= f->maxnakloops);
code = (*f->callbacks->reqci)(f, inp, &len, reject_if_disagree);
} else if (len) {
code = CONFREJ; /* Reject all CI */
} else {
code = CONFACK;
}
/* send the Ack, Nak or Rej to the peer */
fsm_sdata(f, (u_char)code, id, inp, len);
if (code == CONFACK) {
if (f->state == LS_ACKRCVD) {
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
f->state = LS_OPENED;
if (f->callbacks->up) {
(*f->callbacks->up)(f); /* Inform upper layers */
}
} else {
f->state = LS_ACKSENT;
}
f->nakloops = 0;
} else {
/* we sent CONFACK or CONFREJ */
if (f->state != LS_ACKRCVD) {
f->state = LS_REQSENT;
}
if( code == CONFNAK ) {
++f->nakloops;
}
}
}
/*
* fsm_rconfack - Receive Configure-Ack.
*/
static void
fsm_rconfack(fsm *f, int id, u_char *inp, int len)
{
FSMDEBUG(LOG_INFO, ("fsm_rconfack(%s): Rcvd id %d state=%d (%s)\n",
PROTO_NAME(f), id, f->state, ppperr_strerr[f->state]));
if (id != f->reqid || f->seen_ack) { /* Expected id? */
return; /* Nope, toss... */
}
if( !(f->callbacks->ackci? (*f->callbacks->ackci)(f, inp, len): (len == 0)) ) {
/* Ack is bad - ignore it */
FSMDEBUG(LOG_INFO, ("%s: received bad Ack (length %d)\n",
PROTO_NAME(f), len));
return;
}
f->seen_ack = 1;
switch (f->state) {
case LS_CLOSED:
case LS_STOPPED:
fsm_sdata(f, TERMACK, (u_char)id, NULL, 0);
break;
case LS_REQSENT:
f->state = LS_ACKRCVD;
f->retransmits = f->maxconfreqtransmits;
break;
case LS_ACKRCVD:
/* Huh? an extra valid Ack? oh well... */
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
fsm_sconfreq(f, 0);
f->state = LS_REQSENT;
break;
case LS_ACKSENT:
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
f->state = LS_OPENED;
f->retransmits = f->maxconfreqtransmits;
if (f->callbacks->up) {
(*f->callbacks->up)(f); /* Inform upper layers */
}
break;
case LS_OPENED:
/* Go down and restart negotiation */
if (f->callbacks->down) {
(*f->callbacks->down)(f); /* Inform upper layers */
}
fsm_sconfreq(f, 0); /* Send initial Configure-Request */
f->state = LS_REQSENT;
break;
}
}
/*
* fsm_rconfnakrej - Receive Configure-Nak or Configure-Reject.
*/
static void
fsm_rconfnakrej(fsm *f, int code, int id, u_char *inp, int len)
{
int (*proc) (fsm *, u_char *, int);
int ret;
FSMDEBUG(LOG_INFO, ("fsm_rconfnakrej(%s): Rcvd id %d state=%d (%s)\n",
PROTO_NAME(f), id, f->state, ppperr_strerr[f->state]));
if (id != f->reqid || f->seen_ack) { /* Expected id? */
return; /* Nope, toss... */
}
proc = (code == CONFNAK)? f->callbacks->nakci: f->callbacks->rejci;
if (!proc || !((ret = proc(f, inp, len)))) {
/* Nak/reject is bad - ignore it */
FSMDEBUG(LOG_INFO, ("%s: received bad %s (length %d)\n",
PROTO_NAME(f), (code==CONFNAK? "Nak": "reject"), len));
return;
}
f->seen_ack = 1;
switch (f->state) {
case LS_CLOSED:
case LS_STOPPED:
fsm_sdata(f, TERMACK, (u_char)id, NULL, 0);
break;
case LS_REQSENT:
case LS_ACKSENT:
/* They didn't agree to what we wanted - try another request */
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
if (ret < 0) {
f->state = LS_STOPPED; /* kludge for stopping CCP */
} else {
fsm_sconfreq(f, 0); /* Send Configure-Request */
}
break;
case LS_ACKRCVD:
/* Got a Nak/reject when we had already had an Ack?? oh well... */
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
fsm_sconfreq(f, 0);
f->state = LS_REQSENT;
break;
case LS_OPENED:
/* Go down and restart negotiation */
if (f->callbacks->down) {
(*f->callbacks->down)(f); /* Inform upper layers */
}
fsm_sconfreq(f, 0); /* Send initial Configure-Request */
f->state = LS_REQSENT;
break;
}
}
/*
* fsm_rtermreq - Receive Terminate-Req.
*/
static void
fsm_rtermreq(fsm *f, int id, u_char *p, int len)
{
LWIP_UNUSED_ARG(p);
FSMDEBUG(LOG_INFO, ("fsm_rtermreq(%s): Rcvd id %d state=%d (%s)\n",
PROTO_NAME(f), id, f->state, ppperr_strerr[f->state]));
switch (f->state) {
case LS_ACKRCVD:
case LS_ACKSENT:
f->state = LS_REQSENT; /* Start over but keep trying */
break;
case LS_OPENED:
if (len > 0) {
FSMDEBUG(LOG_INFO, ("%s terminated by peer (%p)\n", PROTO_NAME(f), p));
} else {
FSMDEBUG(LOG_INFO, ("%s terminated by peer\n", PROTO_NAME(f)));
}
if (f->callbacks->down) {
(*f->callbacks->down)(f); /* Inform upper layers */
}
f->retransmits = 0;
f->state = LS_STOPPING;
TIMEOUT(fsm_timeout, f, f->timeouttime);
break;
}
fsm_sdata(f, TERMACK, (u_char)id, NULL, 0);
}
/*
* fsm_rtermack - Receive Terminate-Ack.
*/
static void
fsm_rtermack(fsm *f)
{
FSMDEBUG(LOG_INFO, ("fsm_rtermack(%s): state=%d (%s)\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
switch (f->state) {
case LS_CLOSING:
UNTIMEOUT(fsm_timeout, f);
f->state = LS_CLOSED;
if( f->callbacks->finished ) {
(*f->callbacks->finished)(f);
}
break;
case LS_STOPPING:
UNTIMEOUT(fsm_timeout, f);
f->state = LS_STOPPED;
if( f->callbacks->finished ) {
(*f->callbacks->finished)(f);
}
break;
case LS_ACKRCVD:
f->state = LS_REQSENT;
break;
case LS_OPENED:
if (f->callbacks->down) {
(*f->callbacks->down)(f); /* Inform upper layers */
}
fsm_sconfreq(f, 0);
break;
default:
FSMDEBUG(LOG_INFO, ("fsm_rtermack(%s): UNHANDLED state=%d (%s)!!!\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
}
}
/*
* fsm_rcoderej - Receive an Code-Reject.
*/
static void
fsm_rcoderej(fsm *f, u_char *inp, int len)
{
u_char code, id;
FSMDEBUG(LOG_INFO, ("fsm_rcoderej(%s): state=%d (%s)\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
if (len < HEADERLEN) {
FSMDEBUG(LOG_INFO, ("fsm_rcoderej: Rcvd short Code-Reject packet!\n"));
return;
}
GETCHAR(code, inp);
GETCHAR(id, inp);
FSMDEBUG(LOG_WARNING, ("%s: Rcvd Code-Reject for code %d, id %d\n",
PROTO_NAME(f), code, id));
if( f->state == LS_ACKRCVD ) {
f->state = LS_REQSENT;
}
}
/*
* fsm_protreject - Peer doesn't speak this protocol.
*
* Treat this as a catastrophic error (RXJ-).
*/
void
fsm_protreject(fsm *f)
{
switch( f->state ) {
case LS_CLOSING:
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
/* fall through */
case LS_CLOSED:
f->state = LS_CLOSED;
if( f->callbacks->finished ) {
(*f->callbacks->finished)(f);
}
break;
case LS_STOPPING:
case LS_REQSENT:
case LS_ACKRCVD:
case LS_ACKSENT:
UNTIMEOUT(fsm_timeout, f); /* Cancel timeout */
/* fall through */
case LS_STOPPED:
f->state = LS_STOPPED;
if( f->callbacks->finished ) {
(*f->callbacks->finished)(f);
}
break;
case LS_OPENED:
if( f->callbacks->down ) {
(*f->callbacks->down)(f);
}
/* Init restart counter, send Terminate-Request */
f->retransmits = f->maxtermtransmits;
fsm_sdata(f, TERMREQ, f->reqid = ++f->id,
(u_char *) f->term_reason, f->term_reason_len);
TIMEOUT(fsm_timeout, f, f->timeouttime);
--f->retransmits;
f->state = LS_STOPPING;
break;
default:
FSMDEBUG(LOG_INFO, ("%s: Protocol-reject event in state %d (%s)!\n",
PROTO_NAME(f), f->state, ppperr_strerr[f->state]));
}
}
/*
* fsm_sconfreq - Send a Configure-Request.
*/
static void
fsm_sconfreq(fsm *f, int retransmit)
{
u_char *outp;
int cilen;
if( f->state != LS_REQSENT && f->state != LS_ACKRCVD && f->state != LS_ACKSENT ) {
/* Not currently negotiating - reset options */
if( f->callbacks->resetci ) {
(*f->callbacks->resetci)(f);
}
f->nakloops = 0;
}
if( !retransmit ) {
/* New request - reset retransmission counter, use new ID */
f->retransmits = f->maxconfreqtransmits;
f->reqid = ++f->id;
}
f->seen_ack = 0;
/*
* Make up the request packet
*/
outp = outpacket_buf[f->unit] + PPP_HDRLEN + HEADERLEN;
if( f->callbacks->cilen && f->callbacks->addci ) {
cilen = (*f->callbacks->cilen)(f);
if( cilen > peer_mru[f->unit] - (int)HEADERLEN ) {
cilen = peer_mru[f->unit] - HEADERLEN;
}
if (f->callbacks->addci) {
(*f->callbacks->addci)(f, outp, &cilen);
}
} else {
cilen = 0;
}
/* send the request to our peer */
fsm_sdata(f, CONFREQ, f->reqid, outp, cilen);
/* start the retransmit timer */
--f->retransmits;
TIMEOUT(fsm_timeout, f, f->timeouttime);
FSMDEBUG(LOG_INFO, ("%s: sending Configure-Request, id %d\n",
PROTO_NAME(f), f->reqid));
}
/*
* fsm_sdata - Send some data.
*
* Used for all packets sent to our peer by this module.
*/
void
fsm_sdata( fsm *f, u_char code, u_char id, u_char *data, int datalen)
{
u_char *outp;
int outlen;
/* Adjust length to be smaller than MTU */
outp = outpacket_buf[f->unit];
if (datalen > peer_mru[f->unit] - (int)HEADERLEN) {
datalen = peer_mru[f->unit] - HEADERLEN;
}
if (datalen && data != outp + PPP_HDRLEN + HEADERLEN) {
BCOPY(data, outp + PPP_HDRLEN + HEADERLEN, datalen);
}
outlen = datalen + HEADERLEN;
MAKEHEADER(outp, f->protocol);
PUTCHAR(code, outp);
PUTCHAR(id, outp);
PUTSHORT(outlen, outp);
pppWrite(f->unit, outpacket_buf[f->unit], outlen + PPP_HDRLEN);
FSMDEBUG(LOG_INFO, ("fsm_sdata(%s): Sent code %d,%d,%d.\n",
PROTO_NAME(f), code, id, outlen));
}
#endif /* PPP_SUPPORT */