freebsd-nq/usr.sbin/ppp/ipcp.c

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/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 1996 - 2001 Brian Somers <brian@Awfulhak.org>
* based on work by Toshiharu OHNO <tony-o@iij.ad.jp>
* Internet Initiative Japan, Inc (IIJ)
* All rights reserved.
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*
* 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.
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*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND 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 AUTHOR 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.
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*
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* $FreeBSD$
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*/
#include <sys/param.h>
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#include <netinet/in_systm.h>
#include <netinet/in.h>
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#include <netinet/ip.h>
#include <arpa/inet.h>
#include <sys/socket.h>
#include <net/if.h>
#include <net/route.h>
#include <netdb.h>
#include <sys/un.h>
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#include <errno.h>
#include <fcntl.h>
#include <resolv.h>
#include <stdarg.h>
#include <stdlib.h>
#include <string.h>
#include <sys/stat.h>
#include <termios.h>
#include <unistd.h>
#ifndef NONAT
#ifdef LOCALNAT
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#include "alias.h"
#else
#include <alias.h>
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#endif
#endif
#include "layer.h"
#include "ua.h"
#include "defs.h"
#include "command.h"
#include "mbuf.h"
#include "log.h"
#include "timer.h"
#include "fsm.h"
#include "proto.h"
#include "iplist.h"
#include "throughput.h"
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#include "slcompress.h"
#include "lqr.h"
#include "hdlc.h"
#include "lcp.h"
#include "ncpaddr.h"
#include "ip.h"
#include "ipcp.h"
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#include "filter.h"
#include "descriptor.h"
#include "vjcomp.h"
#include "async.h"
o Move struct lcp and struct ccp into struct link. o Remove bundle2lcp(), bundle2ccp() and bundle2link(). They're too resource-hungry and we have `owner pointers' to do their job. o Make our FSM understand LCPs that are always ST_OPENED (with a minimum code that != 1). o Send FSM code rejects for invalid codes. o Make our bundle fsm_parent deal with multiple links. o Make timer diagnostics pretty and allow access via ~t in `term' mode (not just when logging debug) and `show timers'. Only show timers every second in debug mode, otherwise we get too many diagnostics to be useful (we probably still do). Also, don't restrict ~m in term mode to depend on debug logging. o Rationalise our bundles' phases. o Create struct mp (multilink protocol). This is both an NCP and a type of struct link. It feeds off other NCPs for output, passing fragmented packets into the queues of available datalinks. It also gets PROTO_MP input, reassembles the fragments into ppp frames, and passes them back to the HDLC layer that the fragments were passed from. ** It's not yet possible to enter multilink mode :-( ** o Add `set weight' (requires context) for deciding on a links weighting in multilink mode. Weighting is simplistic (and probably badly implemented) for now. o Remove the function pointers in struct link. They ended up only applying to physical links. o Configure our tun device with an MTU equal to the MRU from struct mp's LCP and a speed equal to the sum of our link speeds. o `show {lcp,ccp,proto}' and `set deflate' now have optional context and use ChooseLink() to decide on which `struct link' to use. This allows behaviour as before when in non-multilink mode, and allows access to the MP logical link in multilink mode. o Ignore reconnect and redial values when in -direct mode and when cleaning up. Always redial when in -ddial or -dedicated mode (unless cleaning up). o Tell our links to `staydown' when we close them due to a signal. o Remove remaining `#ifdef SIGALRM's (ppp doesn't function without alarms). o Don't bother strdup()ing our physical link name. o Various other cosmetic changes.
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#include "ccp.h"
#include "link.h"
#include "physical.h"
o Move struct lcp and struct ccp into struct link. o Remove bundle2lcp(), bundle2ccp() and bundle2link(). They're too resource-hungry and we have `owner pointers' to do their job. o Make our FSM understand LCPs that are always ST_OPENED (with a minimum code that != 1). o Send FSM code rejects for invalid codes. o Make our bundle fsm_parent deal with multiple links. o Make timer diagnostics pretty and allow access via ~t in `term' mode (not just when logging debug) and `show timers'. Only show timers every second in debug mode, otherwise we get too many diagnostics to be useful (we probably still do). Also, don't restrict ~m in term mode to depend on debug logging. o Rationalise our bundles' phases. o Create struct mp (multilink protocol). This is both an NCP and a type of struct link. It feeds off other NCPs for output, passing fragmented packets into the queues of available datalinks. It also gets PROTO_MP input, reassembles the fragments into ppp frames, and passes them back to the HDLC layer that the fragments were passed from. ** It's not yet possible to enter multilink mode :-( ** o Add `set weight' (requires context) for deciding on a links weighting in multilink mode. Weighting is simplistic (and probably badly implemented) for now. o Remove the function pointers in struct link. They ended up only applying to physical links. o Configure our tun device with an MTU equal to the MRU from struct mp's LCP and a speed equal to the sum of our link speeds. o `show {lcp,ccp,proto}' and `set deflate' now have optional context and use ChooseLink() to decide on which `struct link' to use. This allows behaviour as before when in non-multilink mode, and allows access to the MP logical link in multilink mode. o Ignore reconnect and redial values when in -direct mode and when cleaning up. Always redial when in -ddial or -dedicated mode (unless cleaning up). o Tell our links to `staydown' when we close them due to a signal. o Remove remaining `#ifdef SIGALRM's (ppp doesn't function without alarms). o Don't bother strdup()ing our physical link name. o Various other cosmetic changes.
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#include "mp.h"
#ifndef NORADIUS
#include "radius.h"
#endif
#include "ipv6cp.h"
#include "ncp.h"
o Move struct lcp and struct ccp into struct link. o Remove bundle2lcp(), bundle2ccp() and bundle2link(). They're too resource-hungry and we have `owner pointers' to do their job. o Make our FSM understand LCPs that are always ST_OPENED (with a minimum code that != 1). o Send FSM code rejects for invalid codes. o Make our bundle fsm_parent deal with multiple links. o Make timer diagnostics pretty and allow access via ~t in `term' mode (not just when logging debug) and `show timers'. Only show timers every second in debug mode, otherwise we get too many diagnostics to be useful (we probably still do). Also, don't restrict ~m in term mode to depend on debug logging. o Rationalise our bundles' phases. o Create struct mp (multilink protocol). This is both an NCP and a type of struct link. It feeds off other NCPs for output, passing fragmented packets into the queues of available datalinks. It also gets PROTO_MP input, reassembles the fragments into ppp frames, and passes them back to the HDLC layer that the fragments were passed from. ** It's not yet possible to enter multilink mode :-( ** o Add `set weight' (requires context) for deciding on a links weighting in multilink mode. Weighting is simplistic (and probably badly implemented) for now. o Remove the function pointers in struct link. They ended up only applying to physical links. o Configure our tun device with an MTU equal to the MRU from struct mp's LCP and a speed equal to the sum of our link speeds. o `show {lcp,ccp,proto}' and `set deflate' now have optional context and use ChooseLink() to decide on which `struct link' to use. This allows behaviour as before when in non-multilink mode, and allows access to the MP logical link in multilink mode. o Ignore reconnect and redial values when in -direct mode and when cleaning up. Always redial when in -ddial or -dedicated mode (unless cleaning up). o Tell our links to `staydown' when we close them due to a signal. o Remove remaining `#ifdef SIGALRM's (ppp doesn't function without alarms). o Don't bother strdup()ing our physical link name. o Various other cosmetic changes.
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#include "bundle.h"
#include "id.h"
#include "arp.h"
#include "systems.h"
#include "prompt.h"
#include "route.h"
#include "iface.h"
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#undef REJECTED
#define REJECTED(p, x) ((p)->peer_reject & (1<<(x)))
#define issep(ch) ((ch) == ' ' || (ch) == '\t')
#define isip(ch) (((ch) >= '0' && (ch) <= '9') || (ch) == '.')
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struct compreq {
u_short proto;
u_char slots;
u_char compcid;
};
static int IpcpLayerUp(struct fsm *);
static void IpcpLayerDown(struct fsm *);
static void IpcpLayerStart(struct fsm *);
static void IpcpLayerFinish(struct fsm *);
static void IpcpInitRestartCounter(struct fsm *, int);
static void IpcpSendConfigReq(struct fsm *);
static void IpcpSentTerminateReq(struct fsm *);
static void IpcpSendTerminateAck(struct fsm *, u_char);
static void IpcpDecodeConfig(struct fsm *, u_char *, u_char *, int,
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struct fsm_decode *);
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extern struct libalias *la;
static struct fsm_callbacks ipcp_Callbacks = {
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IpcpLayerUp,
IpcpLayerDown,
IpcpLayerStart,
IpcpLayerFinish,
IpcpInitRestartCounter,
IpcpSendConfigReq,
IpcpSentTerminateReq,
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IpcpSendTerminateAck,
IpcpDecodeConfig,
fsm_NullRecvResetReq,
fsm_NullRecvResetAck
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};
static const char *
protoname(int proto)
{
static struct {
int id;
const char *txt;
} cftypes[] = {
/* Check out the latest ``Assigned numbers'' rfc (rfc1700.txt) */
{ 1, "IPADDRS" }, /* IP-Addresses */ /* deprecated */
{ 2, "COMPPROTO" }, /* IP-Compression-Protocol */
{ 3, "IPADDR" }, /* IP-Address */
{ 129, "PRIDNS" }, /* 129: Primary DNS Server Address */
{ 130, "PRINBNS" }, /* 130: Primary NBNS Server Address */
{ 131, "SECDNS" }, /* 131: Secondary DNS Server Address */
{ 132, "SECNBNS" } /* 132: Secondary NBNS Server Address */
};
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unsigned f;
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for (f = 0; f < sizeof cftypes / sizeof *cftypes; f++)
if (cftypes[f].id == proto)
return cftypes[f].txt;
return NumStr(proto, NULL, 0);
}
void
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ipcp_AddInOctets(struct ipcp *ipcp, int n)
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{
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throughput_addin(&ipcp->throughput, n);
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}
void
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ipcp_AddOutOctets(struct ipcp *ipcp, int n)
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{
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throughput_addout(&ipcp->throughput, n);
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}
void
ipcp_LoadDNS(struct ipcp *ipcp)
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{
int fd;
ipcp->ns.dns[0].s_addr = ipcp->ns.dns[1].s_addr = INADDR_NONE;
if (ipcp->ns.resolv != NULL) {
free(ipcp->ns.resolv);
ipcp->ns.resolv = NULL;
}
if (ipcp->ns.resolv_nons != NULL) {
free(ipcp->ns.resolv_nons);
ipcp->ns.resolv_nons = NULL;
}
ipcp->ns.resolver = 0;
if ((fd = open(_PATH_RESCONF, O_RDONLY)) != -1) {
struct stat st;
if (fstat(fd, &st) == 0) {
ssize_t got;
/*
* Note, ns.resolv and ns.resolv_nons are assumed to always point to
* buffers of the same size! See the strcpy() below.
*/
if ((ipcp->ns.resolv_nons = (char *)malloc(st.st_size + 1)) == NULL)
log_Printf(LogERROR, "Failed to malloc %lu for %s: %s\n",
(unsigned long)st.st_size, _PATH_RESCONF, strerror(errno));
else if ((ipcp->ns.resolv = (char *)malloc(st.st_size + 1)) == NULL) {
log_Printf(LogERROR, "Failed(2) to malloc %lu for %s: %s\n",
(unsigned long)st.st_size, _PATH_RESCONF, strerror(errno));
free(ipcp->ns.resolv_nons);
ipcp->ns.resolv_nons = NULL;
} else if ((got = read(fd, ipcp->ns.resolv, st.st_size)) != st.st_size) {
if (got == -1)
log_Printf(LogERROR, "Failed to read %s: %s\n",
_PATH_RESCONF, strerror(errno));
else
log_Printf(LogERROR, "Failed to read %s, got %lu not %lu\n",
_PATH_RESCONF, (unsigned long)got,
(unsigned long)st.st_size);
free(ipcp->ns.resolv_nons);
ipcp->ns.resolv_nons = NULL;
free(ipcp->ns.resolv);
ipcp->ns.resolv = NULL;
} else {
char *cp, *cp_nons, *ncp, ch;
int n;
ipcp->ns.resolv[st.st_size] = '\0';
ipcp->ns.resolver = 1;
cp_nons = ipcp->ns.resolv_nons;
cp = ipcp->ns.resolv;
n = 0;
while ((ncp = strstr(cp, "nameserver")) != NULL) {
if (ncp != cp) {
memcpy(cp_nons, cp, ncp - cp);
cp_nons += ncp - cp;
}
if ((ncp != cp && ncp[-1] != '\n') || !issep(ncp[10])) {
memcpy(cp_nons, ncp, 9);
cp_nons += 9;
cp = ncp + 9; /* Can't match "nameserver" at cp... */
continue;
}
for (cp = ncp + 11; issep(*cp); cp++) /* Skip whitespace */
;
for (ncp = cp; isip(*ncp); ncp++) /* Jump over IP */
;
ch = *ncp;
*ncp = '\0';
if (n < 2 && inet_aton(cp, ipcp->ns.dns))
n++;
*ncp = ch;
if ((cp = strchr(ncp, '\n')) == NULL) /* Point at next line */
cp = ncp + strlen(ncp);
else
cp++;
}
/*
* Note, cp_nons and cp always point to buffers of the same size, so
* strcpy is ok!
*/
strcpy(cp_nons, cp); /* Copy the end - including the NUL */
cp_nons += strlen(cp_nons) - 1;
while (cp_nons >= ipcp->ns.resolv_nons && *cp_nons == '\n')
*cp_nons-- = '\0';
if (n == 2 && ipcp->ns.dns[0].s_addr == INADDR_ANY) {
ipcp->ns.dns[0].s_addr = ipcp->ns.dns[1].s_addr;
ipcp->ns.dns[1].s_addr = INADDR_ANY;
}
bundle_AdjustDNS(ipcp->fsm.bundle);
}
} else
log_Printf(LogERROR, "Failed to stat opened %s: %s\n",
_PATH_RESCONF, strerror(errno));
close(fd);
}
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}
int
ipcp_WriteDNS(struct ipcp *ipcp)
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{
const char *paddr;
mode_t mask;
FILE *fp;
if (ipcp->ns.dns[0].s_addr == INADDR_ANY &&
ipcp->ns.dns[1].s_addr == INADDR_ANY) {
log_Printf(LogIPCP, "%s not modified: All nameservers NAKd\n",
_PATH_RESCONF);
return 0;
}
if (ipcp->ns.dns[0].s_addr == INADDR_ANY) {
ipcp->ns.dns[0].s_addr = ipcp->ns.dns[1].s_addr;
ipcp->ns.dns[1].s_addr = INADDR_ANY;
}
mask = umask(022);
if ((fp = ID0fopen(_PATH_RESCONF, "w")) != NULL) {
umask(mask);
if (ipcp->ns.resolv_nons)
fputs(ipcp->ns.resolv_nons, fp);
paddr = inet_ntoa(ipcp->ns.dns[0]);
log_Printf(LogIPCP, "Primary nameserver set to %s\n", paddr);
fprintf(fp, "\nnameserver %s\n", paddr);
if (ipcp->ns.dns[1].s_addr != INADDR_ANY &&
ipcp->ns.dns[1].s_addr != INADDR_NONE &&
ipcp->ns.dns[1].s_addr != ipcp->ns.dns[0].s_addr) {
paddr = inet_ntoa(ipcp->ns.dns[1]);
log_Printf(LogIPCP, "Secondary nameserver set to %s\n", paddr);
fprintf(fp, "nameserver %s\n", paddr);
}
if (fclose(fp) == EOF) {
log_Printf(LogERROR, "write(): Failed updating %s: %s\n", _PATH_RESCONF,
strerror(errno));
return 0;
}
} else {
umask(mask);
log_Printf(LogERROR,"fopen(\"%s\", \"w\") failed: %s\n", _PATH_RESCONF,
strerror(errno));
}
return 1;
}
void
ipcp_RestoreDNS(struct ipcp *ipcp)
{
if (ipcp->ns.resolver) {
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ssize_t got, len;
int fd;
if ((fd = ID0open(_PATH_RESCONF, O_WRONLY|O_TRUNC, 0644)) != -1) {
len = strlen(ipcp->ns.resolv);
if ((got = write(fd, ipcp->ns.resolv, len)) != len) {
if (got == -1)
log_Printf(LogERROR, "Failed rewriting %s: write: %s\n",
_PATH_RESCONF, strerror(errno));
else
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log_Printf(LogERROR, "Failed rewriting %s: wrote %ld of %ld\n",
_PATH_RESCONF, (long)got, (long)len);
}
close(fd);
} else
log_Printf(LogERROR, "Failed rewriting %s: open: %s\n", _PATH_RESCONF,
strerror(errno));
} else if (remove(_PATH_RESCONF) == -1)
log_Printf(LogERROR, "Failed removing %s: %s\n", _PATH_RESCONF,
strerror(errno));
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}
int
ipcp_Show(struct cmdargs const *arg)
{
struct ipcp *ipcp = &arg->bundle->ncp.ipcp;
prompt_Printf(arg->prompt, "%s [%s]\n", ipcp->fsm.name,
State2Nam(ipcp->fsm.state));
if (ipcp->fsm.state == ST_OPENED) {
prompt_Printf(arg->prompt, " His side: %s, %s\n",
inet_ntoa(ipcp->peer_ip), vj2asc(ipcp->peer_compproto));
prompt_Printf(arg->prompt, " My side: %s, %s\n",
inet_ntoa(ipcp->my_ip), vj2asc(ipcp->my_compproto));
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prompt_Printf(arg->prompt, " Queued packets: %lu\n",
(unsigned long)ipcp_QueueLen(ipcp));
}
prompt_Printf(arg->prompt, "\nDefaults:\n");
prompt_Printf(arg->prompt, " FSM retry = %us, max %u Config"
" REQ%s, %u Term REQ%s\n", ipcp->cfg.fsm.timeout,
ipcp->cfg.fsm.maxreq, ipcp->cfg.fsm.maxreq == 1 ? "" : "s",
ipcp->cfg.fsm.maxtrm, ipcp->cfg.fsm.maxtrm == 1 ? "" : "s");
prompt_Printf(arg->prompt, " My Address: %s\n",
ncprange_ntoa(&ipcp->cfg.my_range));
if (ipcp->cfg.HaveTriggerAddress)
prompt_Printf(arg->prompt, " Trigger address: %s\n",
inet_ntoa(ipcp->cfg.TriggerAddress));
prompt_Printf(arg->prompt, " VJ compression: %s (%d slots %s slot "
"compression)\n", command_ShowNegval(ipcp->cfg.vj.neg),
ipcp->cfg.vj.slots, ipcp->cfg.vj.slotcomp ? "with" : "without");
if (iplist_isvalid(&ipcp->cfg.peer_list))
prompt_Printf(arg->prompt, " His Address: %s\n",
ipcp->cfg.peer_list.src);
else
prompt_Printf(arg->prompt, " His Address: %s\n",
ncprange_ntoa(&ipcp->cfg.peer_range));
prompt_Printf(arg->prompt, " DNS: %s",
ipcp->cfg.ns.dns[0].s_addr == INADDR_NONE ?
"none" : inet_ntoa(ipcp->cfg.ns.dns[0]));
if (ipcp->cfg.ns.dns[1].s_addr != INADDR_NONE)
prompt_Printf(arg->prompt, ", %s",
inet_ntoa(ipcp->cfg.ns.dns[1]));
prompt_Printf(arg->prompt, ", %s\n",
command_ShowNegval(ipcp->cfg.ns.dns_neg));
prompt_Printf(arg->prompt, " Resolver DNS: %s",
ipcp->ns.dns[0].s_addr == INADDR_NONE ?
"none" : inet_ntoa(ipcp->ns.dns[0]));
if (ipcp->ns.dns[1].s_addr != INADDR_NONE &&
ipcp->ns.dns[1].s_addr != ipcp->ns.dns[0].s_addr)
prompt_Printf(arg->prompt, ", %s",
inet_ntoa(ipcp->ns.dns[1]));
prompt_Printf(arg->prompt, "\n NetBIOS NS: %s, ",
inet_ntoa(ipcp->cfg.ns.nbns[0]));
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prompt_Printf(arg->prompt, "%s\n\n",
inet_ntoa(ipcp->cfg.ns.nbns[1]));
throughput_disp(&ipcp->throughput, arg->prompt);
return 0;
}
int
ipcp_vjset(struct cmdargs const *arg)
{
if (arg->argc != arg->argn+2)
return -1;
if (!strcasecmp(arg->argv[arg->argn], "slots")) {
int slots;
slots = atoi(arg->argv[arg->argn+1]);
if (slots < 4 || slots > 16)
return 1;
arg->bundle->ncp.ipcp.cfg.vj.slots = slots;
return 0;
} else if (!strcasecmp(arg->argv[arg->argn], "slotcomp")) {
if (!strcasecmp(arg->argv[arg->argn+1], "on"))
arg->bundle->ncp.ipcp.cfg.vj.slotcomp = 1;
else if (!strcasecmp(arg->argv[arg->argn+1], "off"))
arg->bundle->ncp.ipcp.cfg.vj.slotcomp = 0;
else
return 2;
return 0;
}
return -1;
}
void
ipcp_Init(struct ipcp *ipcp, struct bundle *bundle, struct link *l,
const struct fsm_parent *parent)
{
struct hostent *hp;
struct in_addr host;
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char name[MAXHOSTNAMELEN];
static const char * const timer_names[] =
o Move struct lcp and struct ccp into struct link. o Remove bundle2lcp(), bundle2ccp() and bundle2link(). They're too resource-hungry and we have `owner pointers' to do their job. o Make our FSM understand LCPs that are always ST_OPENED (with a minimum code that != 1). o Send FSM code rejects for invalid codes. o Make our bundle fsm_parent deal with multiple links. o Make timer diagnostics pretty and allow access via ~t in `term' mode (not just when logging debug) and `show timers'. Only show timers every second in debug mode, otherwise we get too many diagnostics to be useful (we probably still do). Also, don't restrict ~m in term mode to depend on debug logging. o Rationalise our bundles' phases. o Create struct mp (multilink protocol). This is both an NCP and a type of struct link. It feeds off other NCPs for output, passing fragmented packets into the queues of available datalinks. It also gets PROTO_MP input, reassembles the fragments into ppp frames, and passes them back to the HDLC layer that the fragments were passed from. ** It's not yet possible to enter multilink mode :-( ** o Add `set weight' (requires context) for deciding on a links weighting in multilink mode. Weighting is simplistic (and probably badly implemented) for now. o Remove the function pointers in struct link. They ended up only applying to physical links. o Configure our tun device with an MTU equal to the MRU from struct mp's LCP and a speed equal to the sum of our link speeds. o `show {lcp,ccp,proto}' and `set deflate' now have optional context and use ChooseLink() to decide on which `struct link' to use. This allows behaviour as before when in non-multilink mode, and allows access to the MP logical link in multilink mode. o Ignore reconnect and redial values when in -direct mode and when cleaning up. Always redial when in -ddial or -dedicated mode (unless cleaning up). o Tell our links to `staydown' when we close them due to a signal. o Remove remaining `#ifdef SIGALRM's (ppp doesn't function without alarms). o Don't bother strdup()ing our physical link name. o Various other cosmetic changes.
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{"IPCP restart", "IPCP openmode", "IPCP stopped"};
fsm_Init(&ipcp->fsm, "IPCP", PROTO_IPCP, 1, IPCP_MAXCODE, LogIPCP,
o Move struct lcp and struct ccp into struct link. o Remove bundle2lcp(), bundle2ccp() and bundle2link(). They're too resource-hungry and we have `owner pointers' to do their job. o Make our FSM understand LCPs that are always ST_OPENED (with a minimum code that != 1). o Send FSM code rejects for invalid codes. o Make our bundle fsm_parent deal with multiple links. o Make timer diagnostics pretty and allow access via ~t in `term' mode (not just when logging debug) and `show timers'. Only show timers every second in debug mode, otherwise we get too many diagnostics to be useful (we probably still do). Also, don't restrict ~m in term mode to depend on debug logging. o Rationalise our bundles' phases. o Create struct mp (multilink protocol). This is both an NCP and a type of struct link. It feeds off other NCPs for output, passing fragmented packets into the queues of available datalinks. It also gets PROTO_MP input, reassembles the fragments into ppp frames, and passes them back to the HDLC layer that the fragments were passed from. ** It's not yet possible to enter multilink mode :-( ** o Add `set weight' (requires context) for deciding on a links weighting in multilink mode. Weighting is simplistic (and probably badly implemented) for now. o Remove the function pointers in struct link. They ended up only applying to physical links. o Configure our tun device with an MTU equal to the MRU from struct mp's LCP and a speed equal to the sum of our link speeds. o `show {lcp,ccp,proto}' and `set deflate' now have optional context and use ChooseLink() to decide on which `struct link' to use. This allows behaviour as before when in non-multilink mode, and allows access to the MP logical link in multilink mode. o Ignore reconnect and redial values when in -direct mode and when cleaning up. Always redial when in -ddial or -dedicated mode (unless cleaning up). o Tell our links to `staydown' when we close them due to a signal. o Remove remaining `#ifdef SIGALRM's (ppp doesn't function without alarms). o Don't bother strdup()ing our physical link name. o Various other cosmetic changes.
1998-04-03 19:21:56 +00:00
bundle, l, parent, &ipcp_Callbacks, timer_names);
ipcp->cfg.vj.slots = DEF_VJ_STATES;
ipcp->cfg.vj.slotcomp = 1;
memset(&ipcp->cfg.my_range, '\0', sizeof ipcp->cfg.my_range);
host.s_addr = htonl(INADDR_LOOPBACK);
ipcp->cfg.netmask.s_addr = INADDR_ANY;
if (gethostname(name, sizeof name) == 0) {
hp = gethostbyname(name);
if (hp && hp->h_addrtype == AF_INET && hp->h_length == sizeof host.s_addr)
memcpy(&host.s_addr, hp->h_addr, sizeof host.s_addr);
}
ncprange_setip4(&ipcp->cfg.my_range, host, ipcp->cfg.netmask);
ncprange_setip4(&ipcp->cfg.peer_range, ipcp->cfg.netmask, ipcp->cfg.netmask);
iplist_setsrc(&ipcp->cfg.peer_list, "");
ipcp->cfg.HaveTriggerAddress = 0;
ipcp->cfg.ns.dns[0].s_addr = INADDR_NONE;
ipcp->cfg.ns.dns[1].s_addr = INADDR_NONE;
ipcp->cfg.ns.dns_neg = 0;
ipcp->cfg.ns.nbns[0].s_addr = INADDR_ANY;
ipcp->cfg.ns.nbns[1].s_addr = INADDR_ANY;
ipcp->cfg.fsm.timeout = DEF_FSMRETRY;
ipcp->cfg.fsm.maxreq = DEF_FSMTRIES;
ipcp->cfg.fsm.maxtrm = DEF_FSMTRIES;
ipcp->cfg.vj.neg = NEG_ENABLED|NEG_ACCEPTED;
memset(&ipcp->vj, '\0', sizeof ipcp->vj);
ipcp->ns.resolv = NULL;
ipcp->ns.resolv_nons = NULL;
ipcp->ns.writable = 1;
ipcp_LoadDNS(ipcp);
throughput_init(&ipcp->throughput, SAMPLE_PERIOD);
memset(ipcp->Queue, '\0', sizeof ipcp->Queue);
ipcp_Setup(ipcp, INADDR_NONE);
}
void
ipcp_Destroy(struct ipcp *ipcp)
{
throughput_destroy(&ipcp->throughput);
if (ipcp->ns.resolv != NULL) {
free(ipcp->ns.resolv);
ipcp->ns.resolv = NULL;
}
if (ipcp->ns.resolv_nons != NULL) {
free(ipcp->ns.resolv_nons);
ipcp->ns.resolv_nons = NULL;
}
}
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void
ipcp_SetLink(struct ipcp *ipcp, struct link *l)
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{
ipcp->fsm.link = l;
}
void
ipcp_Setup(struct ipcp *ipcp, u_int32_t mask)
{
struct iface *iface = ipcp->fsm.bundle->iface;
struct ncpaddr ipaddr;
struct in_addr peer;
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int pos;
unsigned n;
ipcp->fsm.open_mode = 0;
ipcp->ifmask.s_addr = mask == INADDR_NONE ? ipcp->cfg.netmask.s_addr : mask;
if (iplist_isvalid(&ipcp->cfg.peer_list)) {
/* Try to give the peer a previously configured IP address */
for (n = 0; n < iface->addrs; n++) {
if (!ncpaddr_getip4(&iface->addr[n].peer, &peer))
continue;
if ((pos = iplist_ip2pos(&ipcp->cfg.peer_list, peer)) != -1) {
ncpaddr_setip4(&ipaddr, iplist_setcurpos(&ipcp->cfg.peer_list, pos));
break;
}
}
if (n == iface->addrs)
/* Ok, so none of 'em fit.... pick a random one */
ncpaddr_setip4(&ipaddr, iplist_setrandpos(&ipcp->cfg.peer_list));
ncprange_sethost(&ipcp->cfg.peer_range, &ipaddr);
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}
ipcp->heis1172 = 0;
ipcp->peer_req = 0;
ncprange_getip4addr(&ipcp->cfg.peer_range, &ipcp->peer_ip);
ipcp->peer_compproto = 0;
if (ipcp->cfg.HaveTriggerAddress) {
/*
* Some implementations of PPP require that we send a
* *special* value as our address, even though the rfc specifies
* full negotiation (e.g. "0.0.0.0" or Not "0.0.0.0").
*/
ipcp->my_ip = ipcp->cfg.TriggerAddress;
log_Printf(LogIPCP, "Using trigger address %s\n",
inet_ntoa(ipcp->cfg.TriggerAddress));
} else {
/*
* Otherwise, if we've used an IP number before and it's still within
* the network specified on the ``set ifaddr'' line, we really
* want to keep that IP number so that we can keep any existing
* connections that are bound to that IP.
*/
for (n = 0; n < iface->addrs; n++) {
ncprange_getaddr(&iface->addr[n].ifa, &ipaddr);
if (ncprange_contains(&ipcp->cfg.my_range, &ipaddr)) {
ncpaddr_getip4(&ipaddr, &ipcp->my_ip);
break;
}
}
if (n == iface->addrs)
ncprange_getip4addr(&ipcp->cfg.my_range, &ipcp->my_ip);
}
if (IsEnabled(ipcp->cfg.vj.neg)
#ifndef NORADIUS
|| (ipcp->fsm.bundle->radius.valid && ipcp->fsm.bundle->radius.vj)
#endif
)
ipcp->my_compproto = (PROTO_VJCOMP << 16) +
((ipcp->cfg.vj.slots - 1) << 8) +
ipcp->cfg.vj.slotcomp;
else
ipcp->my_compproto = 0;
sl_compress_init(&ipcp->vj.cslc, ipcp->cfg.vj.slots - 1);
ipcp->peer_reject = 0;
ipcp->my_reject = 0;
/* Copy startup values into ipcp->ns.dns */
if (ipcp->cfg.ns.dns[0].s_addr != INADDR_NONE)
memcpy(ipcp->ns.dns, ipcp->cfg.ns.dns, sizeof ipcp->ns.dns);
}
static int
numaddresses(struct in_addr mask)
{
u_int32_t bit, haddr;
int n;
haddr = ntohl(mask.s_addr);
bit = 1;
n = 1;
do {
if (!(haddr & bit))
n <<= 1;
} while (bit <<= 1);
return n;
}
static int
ipcp_proxyarp(struct ipcp *ipcp,
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int (*proxyfun)(struct bundle *, struct in_addr),
const struct iface_addr *addr)
{
struct bundle *bundle = ipcp->fsm.bundle;
struct in_addr peer, mask, ip;
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int n, ret;
if (!ncpaddr_getip4(&addr->peer, &peer)) {
log_Printf(LogERROR, "Oops, ipcp_proxyarp() called with unexpected addr\n");
return 0;
}
ret = 0;
if (Enabled(bundle, OPT_PROXYALL)) {
ncprange_getip4mask(&addr->ifa, &mask);
if ((n = numaddresses(mask)) > 256) {
log_Printf(LogWARN, "%s: Too many addresses for proxyall\n",
ncprange_ntoa(&addr->ifa));
return 0;
}
ip.s_addr = peer.s_addr & mask.s_addr;
if (n >= 4) {
ip.s_addr = htonl(ntohl(ip.s_addr) + 1);
n -= 2;
}
while (n) {
if (!((ip.s_addr ^ peer.s_addr) & mask.s_addr)) {
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if (!(ret = (*proxyfun)(bundle, ip)))
break;
n--;
}
ip.s_addr = htonl(ntohl(ip.s_addr) + 1);
}
ret = !n;
} else if (Enabled(bundle, OPT_PROXY))
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ret = (*proxyfun)(bundle, peer);
return ret;
}
static int
ipcp_SetIPaddress(struct ipcp *ipcp, struct in_addr myaddr,
struct in_addr hisaddr)
{
struct bundle *bundle = ipcp->fsm.bundle;
struct ncpaddr myncpaddr, hisncpaddr;
struct ncprange myrange;
struct in_addr mask;
struct sockaddr_storage ssdst, ssgw, ssmask;
struct sockaddr *sadst, *sagw, *samask;
sadst = (struct sockaddr *)&ssdst;
sagw = (struct sockaddr *)&ssgw;
samask = (struct sockaddr *)&ssmask;
ncpaddr_setip4(&hisncpaddr, hisaddr);
ncpaddr_setip4(&myncpaddr, myaddr);
ncprange_sethost(&myrange, &myncpaddr);
mask = addr2mask(myaddr);
if (ipcp->ifmask.s_addr != INADDR_ANY &&
(ipcp->ifmask.s_addr & mask.s_addr) == mask.s_addr)
ncprange_setip4mask(&myrange, ipcp->ifmask);
if (!iface_Add(bundle->iface, &bundle->ncp, &myrange, &hisncpaddr,
IFACE_ADD_FIRST|IFACE_FORCE_ADD|IFACE_SYSTEM))
return 0;
if (!Enabled(bundle, OPT_IFACEALIAS))
iface_Clear(bundle->iface, &bundle->ncp, AF_INET,
IFACE_CLEAR_ALIASES|IFACE_SYSTEM);
if (bundle->ncp.cfg.sendpipe > 0 || bundle->ncp.cfg.recvpipe > 0) {
ncprange_getsa(&myrange, &ssgw, &ssmask);
ncpaddr_getsa(&hisncpaddr, &ssdst);
rt_Update(bundle, sadst, sagw, samask, NULL, NULL);
}
if (Enabled(bundle, OPT_SROUTES))
route_Change(bundle, bundle->ncp.route, &myncpaddr, &hisncpaddr);
#ifndef NORADIUS
if (bundle->radius.valid)
route_Change(bundle, bundle->radius.routes, &myncpaddr, &hisncpaddr);
#endif
return 1; /* Ok */
}
static struct in_addr
ChooseHisAddr(struct bundle *bundle, struct in_addr gw)
{
struct in_addr try;
u_long f;
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for (f = 0; f < bundle->ncp.ipcp.cfg.peer_list.nItems; f++) {
try = iplist_next(&bundle->ncp.ipcp.cfg.peer_list);
log_Printf(LogDEBUG, "ChooseHisAddr: Check item %ld (%s)\n",
f, inet_ntoa(try));
if (ipcp_SetIPaddress(&bundle->ncp.ipcp, gw, try)) {
log_Printf(LogIPCP, "Selected IP address %s\n", inet_ntoa(try));
break;
}
}
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if (f == bundle->ncp.ipcp.cfg.peer_list.nItems) {
log_Printf(LogDEBUG, "ChooseHisAddr: All addresses in use !\n");
try.s_addr = INADDR_ANY;
}
return try;
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}
static void
IpcpInitRestartCounter(struct fsm *fp, int what)
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{
/* Set fsm timer load */
struct ipcp *ipcp = fsm2ipcp(fp);
fp->FsmTimer.load = ipcp->cfg.fsm.timeout * SECTICKS;
switch (what) {
case FSM_REQ_TIMER:
fp->restart = ipcp->cfg.fsm.maxreq;
break;
case FSM_TRM_TIMER:
fp->restart = ipcp->cfg.fsm.maxtrm;
break;
default:
fp->restart = 1;
break;
}
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}
static void
IpcpSendConfigReq(struct fsm *fp)
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{
/* Send config REQ please */
struct physical *p = link2physical(fp->link);
struct ipcp *ipcp = fsm2ipcp(fp);
u_char buff[MAX_FSM_OPT_LEN];
struct fsm_opt *o;
o = (struct fsm_opt *)buff;
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if ((p && !physical_IsSync(p)) || !REJECTED(ipcp, TY_IPADDR)) {
memcpy(o->data, &ipcp->my_ip.s_addr, 4);
INC_FSM_OPT(TY_IPADDR, 6, o);
}
if (ipcp->my_compproto && !REJECTED(ipcp, TY_COMPPROTO)) {
if (ipcp->heis1172) {
u_int16_t proto = PROTO_VJCOMP;
ua_htons(&proto, o->data);
INC_FSM_OPT(TY_COMPPROTO, 4, o);
} else {
struct compreq req;
req.proto = htons(ipcp->my_compproto >> 16);
req.slots = (ipcp->my_compproto >> 8) & 255;
req.compcid = ipcp->my_compproto & 1;
memcpy(o->data, &req, 4);
INC_FSM_OPT(TY_COMPPROTO, 6, o);
}
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}
if (IsEnabled(ipcp->cfg.ns.dns_neg)) {
if (!REJECTED(ipcp, TY_PRIMARY_DNS - TY_ADJUST_NS)) {
memcpy(o->data, &ipcp->ns.dns[0].s_addr, 4);
INC_FSM_OPT(TY_PRIMARY_DNS, 6, o);
}
if (!REJECTED(ipcp, TY_SECONDARY_DNS - TY_ADJUST_NS)) {
memcpy(o->data, &ipcp->ns.dns[1].s_addr, 4);
INC_FSM_OPT(TY_SECONDARY_DNS, 6, o);
}
}
fsm_Output(fp, CODE_CONFIGREQ, fp->reqid, buff, (u_char *)o - buff,
MB_IPCPOUT);
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}
static void
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IpcpSentTerminateReq(struct fsm *fp __unused)
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{
/* Term REQ just sent by FSM */
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}
static void
IpcpSendTerminateAck(struct fsm *fp, u_char id)
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{
/* Send Term ACK please */
fsm_Output(fp, CODE_TERMACK, id, NULL, 0, MB_IPCPOUT);
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}
static void
IpcpLayerStart(struct fsm *fp)
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{
/* We're about to start up ! */
struct ipcp *ipcp = fsm2ipcp(fp);
log_Printf(LogIPCP, "%s: LayerStart.\n", fp->link->name);
throughput_start(&ipcp->throughput, "IPCP throughput",
Enabled(fp->bundle, OPT_THROUGHPUT));
fp->more.reqs = fp->more.naks = fp->more.rejs = ipcp->cfg.fsm.maxreq * 3;
ipcp->peer_req = 0;
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}
static void
IpcpLayerFinish(struct fsm *fp)
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{
/* We're now down */
struct ipcp *ipcp = fsm2ipcp(fp);
log_Printf(LogIPCP, "%s: LayerFinish.\n", fp->link->name);
throughput_stop(&ipcp->throughput);
throughput_log(&ipcp->throughput, LogIPCP, NULL);
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}
/*
* Called from iface_Add() via ncp_IfaceAddrAdded()
*/
void
ipcp_IfaceAddrAdded(struct ipcp *ipcp, const struct iface_addr *addr)
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{
struct bundle *bundle = ipcp->fsm.bundle;
if (Enabled(bundle, OPT_PROXY) || Enabled(bundle, OPT_PROXYALL))
ipcp_proxyarp(ipcp, arp_SetProxy, addr);
}
/*
* Called from iface_Clear() and iface_Delete() via ncp_IfaceAddrDeleted()
*/
void
ipcp_IfaceAddrDeleted(struct ipcp *ipcp, const struct iface_addr *addr)
{
struct bundle *bundle = ipcp->fsm.bundle;
if (Enabled(bundle, OPT_PROXY) || Enabled(bundle, OPT_PROXYALL))
ipcp_proxyarp(ipcp, arp_ClearProxy, addr);
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}
static void
IpcpLayerDown(struct fsm *fp)
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{
/* About to come down */
struct ipcp *ipcp = fsm2ipcp(fp);
static int recursing;
char addr[16];
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if (!recursing++) {
snprintf(addr, sizeof addr, "%s", inet_ntoa(ipcp->my_ip));
log_Printf(LogIPCP, "%s: LayerDown: %s\n", fp->link->name, addr);
#ifndef NORADIUS
radius_Flush(&fp->bundle->radius);
radius_Account(&fp->bundle->radius, &fp->bundle->radacct,
fp->bundle->links, RAD_STOP, &ipcp->throughput);
if (*fp->bundle->radius.cfg.file && fp->bundle->radius.filterid)
system_Select(fp->bundle, fp->bundle->radius.filterid, LINKDOWNFILE,
NULL, NULL);
radius_StopTimer(&fp->bundle->radius);
#endif
/*
* XXX this stuff should really live in the FSM. Our config should
* associate executable sections in files with events.
*/
if (system_Select(fp->bundle, addr, LINKDOWNFILE, NULL, NULL) < 0) {
if (bundle_GetLabel(fp->bundle)) {
if (system_Select(fp->bundle, bundle_GetLabel(fp->bundle),
LINKDOWNFILE, NULL, NULL) < 0)
system_Select(fp->bundle, "MYADDR", LINKDOWNFILE, NULL, NULL);
} else
system_Select(fp->bundle, "MYADDR", LINKDOWNFILE, NULL, NULL);
}
ipcp_Setup(ipcp, INADDR_NONE);
}
recursing--;
}
int
ipcp_InterfaceUp(struct ipcp *ipcp)
{
if (!ipcp_SetIPaddress(ipcp, ipcp->my_ip, ipcp->peer_ip)) {
log_Printf(LogERROR, "ipcp_InterfaceUp: unable to set ip address\n");
return 0;
}
if (!iface_SetFlags(ipcp->fsm.bundle->iface->name, IFF_UP)) {
log_Printf(LogERROR, "ipcp_InterfaceUp: Can't set the IFF_UP flag on %s\n",
ipcp->fsm.bundle->iface->name);
return 0;
}
#ifndef NONAT
if (ipcp->fsm.bundle->NatEnabled)
LibAliasSetAddress(la, ipcp->my_ip);
#endif
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return 1;
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}
static int
IpcpLayerUp(struct fsm *fp)
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{
/* We're now up */
struct ipcp *ipcp = fsm2ipcp(fp);
char tbuff[16];
log_Printf(LogIPCP, "%s: LayerUp.\n", fp->link->name);
snprintf(tbuff, sizeof tbuff, "%s", inet_ntoa(ipcp->my_ip));
log_Printf(LogIPCP, "myaddr %s hisaddr = %s\n",
tbuff, inet_ntoa(ipcp->peer_ip));
if (ipcp->peer_compproto >> 16 == PROTO_VJCOMP)
sl_compress_init(&ipcp->vj.cslc, (ipcp->peer_compproto >> 8) & 255);
if (!ipcp_InterfaceUp(ipcp))
return 0;
#ifndef NORADIUS
radius_Account_Set_Ip(&fp->bundle->radacct, &ipcp->peer_ip, &ipcp->ifmask);
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radius_Account(&fp->bundle->radius, &fp->bundle->radacct, fp->bundle->links,
RAD_START, &ipcp->throughput);
if (*fp->bundle->radius.cfg.file && fp->bundle->radius.filterid)
system_Select(fp->bundle, fp->bundle->radius.filterid, LINKUPFILE,
NULL, NULL);
radius_StartTimer(fp->bundle);
#endif
/*
* XXX this stuff should really live in the FSM. Our config should
* associate executable sections in files with events.
*/
if (system_Select(fp->bundle, tbuff, LINKUPFILE, NULL, NULL) < 0) {
if (bundle_GetLabel(fp->bundle)) {
if (system_Select(fp->bundle, bundle_GetLabel(fp->bundle),
LINKUPFILE, NULL, NULL) < 0)
system_Select(fp->bundle, "MYADDR", LINKUPFILE, NULL, NULL);
} else
system_Select(fp->bundle, "MYADDR", LINKUPFILE, NULL, NULL);
}
fp->more.reqs = fp->more.naks = fp->more.rejs = ipcp->cfg.fsm.maxreq * 3;
log_DisplayPrompts();
return 1;
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}
static void
ipcp_ValidateReq(struct ipcp *ipcp, struct in_addr ip, struct fsm_decode *dec)
{
struct bundle *bundle = ipcp->fsm.bundle;
struct iface *iface = bundle->iface;
struct in_addr myaddr, peer;
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unsigned n;
if (iplist_isvalid(&ipcp->cfg.peer_list)) {
ncprange_getip4addr(&ipcp->cfg.my_range, &myaddr);
if (ip.s_addr == INADDR_ANY ||
iplist_ip2pos(&ipcp->cfg.peer_list, ip) < 0 ||
!ipcp_SetIPaddress(ipcp, myaddr, ip)) {
log_Printf(LogIPCP, "%s: Address invalid or already in use\n",
inet_ntoa(ip));
/*
* If we've already had a valid address configured for the peer,
* try NAKing with that so that we don't have to upset things
* too much.
*/
for (n = 0; n < iface->addrs; n++) {
if (!ncpaddr_getip4(&iface->addr[n].peer, &peer))
continue;
if (iplist_ip2pos(&ipcp->cfg.peer_list, peer) >= 0) {
ipcp->peer_ip = peer;
break;
}
}
if (n == iface->addrs) {
/* Just pick an IP number from our list */
ipcp->peer_ip = ChooseHisAddr(bundle, myaddr);
}
if (ipcp->peer_ip.s_addr == INADDR_ANY) {
*dec->rejend++ = TY_IPADDR;
*dec->rejend++ = 6;
memcpy(dec->rejend, &ip.s_addr, 4);
dec->rejend += 4;
} else {
*dec->nakend++ = TY_IPADDR;
*dec->nakend++ = 6;
memcpy(dec->nakend, &ipcp->peer_ip.s_addr, 4);
dec->nakend += 4;
}
return;
}
} else if (ip.s_addr == INADDR_ANY ||
!ncprange_containsip4(&ipcp->cfg.peer_range, ip)) {
/*
* If the destination address is not acceptable, NAK with what we
* want to use.
*/
*dec->nakend++ = TY_IPADDR;
*dec->nakend++ = 6;
for (n = 0; n < iface->addrs; n++)
if (ncprange_contains(&ipcp->cfg.peer_range, &iface->addr[n].peer)) {
/* We prefer the already-configured address */
ncpaddr_getip4addr(&iface->addr[n].peer, (u_int32_t *)dec->nakend);
break;
}
if (n == iface->addrs)
memcpy(dec->nakend, &ipcp->peer_ip.s_addr, 4);
dec->nakend += 4;
return;
}
ipcp->peer_ip = ip;
*dec->ackend++ = TY_IPADDR;
*dec->ackend++ = 6;
memcpy(dec->ackend, &ip.s_addr, 4);
dec->ackend += 4;
}
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static void
IpcpDecodeConfig(struct fsm *fp, u_char *cp, u_char *end, int mode_type,
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struct fsm_decode *dec)
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{
/* Deal with incoming PROTO_IPCP */
struct ncpaddr ncpaddr;
struct ipcp *ipcp = fsm2ipcp(fp);
int gotdnsnak;
u_int32_t compproto;
struct compreq pcomp;
struct in_addr ipaddr, dstipaddr, have_ip;
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char tbuff[100], tbuff2[100];
struct fsm_opt *opt, nak;
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gotdnsnak = 0;
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while (end - cp >= (int)sizeof(opt->hdr)) {
if ((opt = fsm_readopt(&cp)) == NULL)
break;
snprintf(tbuff, sizeof tbuff, " %s[%d]", protoname(opt->hdr.id),
opt->hdr.len);
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switch (opt->hdr.id) {
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case TY_IPADDR: /* RFC1332 */
memcpy(&ipaddr.s_addr, opt->data, 4);
log_Printf(LogIPCP, "%s %s\n", tbuff, inet_ntoa(ipaddr));
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switch (mode_type) {
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case MODE_REQ:
ipcp->peer_req = 1;
ipcp_ValidateReq(ipcp, ipaddr, dec);
break;
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case MODE_NAK:
if (ncprange_containsip4(&ipcp->cfg.my_range, ipaddr)) {
/* Use address suggested by peer */
snprintf(tbuff2, sizeof tbuff2, "%s changing address: %s ", tbuff,
inet_ntoa(ipcp->my_ip));
log_Printf(LogIPCP, "%s --> %s\n", tbuff2, inet_ntoa(ipaddr));
ipcp->my_ip = ipaddr;
ncpaddr_setip4(&ncpaddr, ipcp->my_ip);
bundle_AdjustFilters(fp->bundle, &ncpaddr, NULL);
} else {
log_Printf(log_IsKept(LogIPCP) ? LogIPCP : LogPHASE,
"%s: Unacceptable address!\n", inet_ntoa(ipaddr));
fsm_Close(&ipcp->fsm);
}
break;
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case MODE_REJ:
ipcp->peer_reject |= (1 << opt->hdr.id);
break;
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}
break;
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case TY_COMPPROTO:
memcpy(&pcomp, opt->data, sizeof pcomp);
compproto = (ntohs(pcomp.proto) << 16) + ((int)pcomp.slots << 8) +
pcomp.compcid;
log_Printf(LogIPCP, "%s %s\n", tbuff, vj2asc(compproto));
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switch (mode_type) {
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case MODE_REQ:
if (!IsAccepted(ipcp->cfg.vj.neg))
fsm_rej(dec, opt);
else {
switch (opt->hdr.len) {
case 4: /* RFC1172 */
if (ntohs(pcomp.proto) == PROTO_VJCOMP) {
log_Printf(LogWARN, "Peer is speaking RFC1172 compression "
"protocol !\n");
ipcp->heis1172 = 1;
ipcp->peer_compproto = compproto;
fsm_ack(dec, opt);
} else {
pcomp.proto = htons(PROTO_VJCOMP);
nak.hdr.id = TY_COMPPROTO;
nak.hdr.len = 4;
memcpy(nak.data, &pcomp, 2);
fsm_nak(dec, &nak);
}
break;
case 6: /* RFC1332 */
if (ntohs(pcomp.proto) == PROTO_VJCOMP) {
/* We know pcomp.slots' max value == MAX_VJ_STATES */
if (pcomp.slots >= MIN_VJ_STATES) {
/* Ok, we can do that */
ipcp->peer_compproto = compproto;
ipcp->heis1172 = 0;
fsm_ack(dec, opt);
} else {
/* Get as close as we can to what he wants */
ipcp->heis1172 = 0;
pcomp.slots = MIN_VJ_STATES;
nak.hdr.id = TY_COMPPROTO;
nak.hdr.len = 4;
memcpy(nak.data, &pcomp, 2);
fsm_nak(dec, &nak);
}
} else {
/* What we really want */
pcomp.proto = htons(PROTO_VJCOMP);
pcomp.slots = DEF_VJ_STATES;
pcomp.compcid = 1;
nak.hdr.id = TY_COMPPROTO;
nak.hdr.len = 6;
memcpy(nak.data, &pcomp, sizeof pcomp);
fsm_nak(dec, &nak);
}
break;
default:
fsm_rej(dec, opt);
break;
}
}
break;
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case MODE_NAK:
if (ntohs(pcomp.proto) == PROTO_VJCOMP) {
/* We know pcomp.slots' max value == MAX_VJ_STATES */
if (pcomp.slots < MIN_VJ_STATES)
pcomp.slots = MIN_VJ_STATES;
compproto = (ntohs(pcomp.proto) << 16) + (pcomp.slots << 8) +
pcomp.compcid;
} else
compproto = 0;
log_Printf(LogIPCP, "%s changing compproto: %08x --> %08x\n",
tbuff, ipcp->my_compproto, compproto);
ipcp->my_compproto = compproto;
break;
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case MODE_REJ:
ipcp->peer_reject |= (1 << opt->hdr.id);
break;
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}
break;
case TY_IPADDRS: /* RFC1172 */
memcpy(&ipaddr.s_addr, opt->data, 4);
memcpy(&dstipaddr.s_addr, opt->data + 4, 4);
snprintf(tbuff2, sizeof tbuff2, "%s %s,", tbuff, inet_ntoa(ipaddr));
log_Printf(LogIPCP, "%s %s\n", tbuff2, inet_ntoa(dstipaddr));
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switch (mode_type) {
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case MODE_REQ:
fsm_rej(dec, opt);
break;
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case MODE_NAK:
case MODE_REJ:
break;
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}
break;
case TY_PRIMARY_DNS: /* DNS negotiation (rfc1877) */
case TY_SECONDARY_DNS:
memcpy(&ipaddr.s_addr, opt->data, 4);
log_Printf(LogIPCP, "%s %s\n", tbuff, inet_ntoa(ipaddr));
switch (mode_type) {
case MODE_REQ:
if (!IsAccepted(ipcp->cfg.ns.dns_neg)) {
ipcp->my_reject |= (1 << (opt->hdr.id - TY_ADJUST_NS));
fsm_rej(dec, opt);
break;
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}
have_ip = ipcp->ns.dns[opt->hdr.id == TY_PRIMARY_DNS ? 0 : 1];
if (opt->hdr.id == TY_PRIMARY_DNS && ipaddr.s_addr != have_ip.s_addr &&
ipaddr.s_addr == ipcp->ns.dns[1].s_addr) {
/* Swap 'em 'round */
ipcp->ns.dns[0] = ipcp->ns.dns[1];
ipcp->ns.dns[1] = have_ip;
have_ip = ipcp->ns.dns[0];
}
if (ipaddr.s_addr != have_ip.s_addr) {
/*
* The client has got the DNS stuff wrong (first request) so
* we'll tell 'em how it is
*/
nak.hdr.id = opt->hdr.id;
nak.hdr.len = 6;
memcpy(nak.data, &have_ip.s_addr, 4);
fsm_nak(dec, &nak);
} else {
/*
* Otherwise they have it right (this time) so we send an ack packet
* back confirming it... end of story
*/
fsm_ack(dec, opt);
}
break;
case MODE_NAK:
if (IsEnabled(ipcp->cfg.ns.dns_neg)) {
gotdnsnak = 1;
memcpy(&ipcp->ns.dns[opt->hdr.id == TY_PRIMARY_DNS ? 0 : 1].s_addr,
opt->data, 4);
}
break;
case MODE_REJ: /* Can't do much, stop asking */
ipcp->peer_reject |= (1 << (opt->hdr.id - TY_ADJUST_NS));
break;
}
break;
case TY_PRIMARY_NBNS: /* M$ NetBIOS nameserver hack (rfc1877) */
case TY_SECONDARY_NBNS:
memcpy(&ipaddr.s_addr, opt->data, 4);
log_Printf(LogIPCP, "%s %s\n", tbuff, inet_ntoa(ipaddr));
switch (mode_type) {
case MODE_REQ:
have_ip.s_addr =
ipcp->cfg.ns.nbns[opt->hdr.id == TY_PRIMARY_NBNS ? 0 : 1].s_addr;
if (have_ip.s_addr == INADDR_ANY) {
log_Printf(LogIPCP, "NBNS REQ - rejected - nbns not set\n");
ipcp->my_reject |= (1 << (opt->hdr.id - TY_ADJUST_NS));
fsm_rej(dec, opt);
break;
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}
if (ipaddr.s_addr != have_ip.s_addr) {
nak.hdr.id = opt->hdr.id;
nak.hdr.len = 6;
memcpy(nak.data, &have_ip.s_addr, 4);
fsm_nak(dec, &nak);
} else
fsm_ack(dec, opt);
break;
case MODE_NAK:
log_Printf(LogIPCP, "MS NBNS req %d - NAK??\n", opt->hdr.id);
break;
case MODE_REJ:
log_Printf(LogIPCP, "MS NBNS req %d - REJ??\n", opt->hdr.id);
break;
}
break;
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default:
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if (mode_type != MODE_NOP) {
ipcp->my_reject |= (1 << opt->hdr.id);
fsm_rej(dec, opt);
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}
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break;
}
}
if (gotdnsnak) {
if (ipcp->ns.writable) {
log_Printf(LogDEBUG, "Updating resolver\n");
if (!ipcp_WriteDNS(ipcp)) {
ipcp->peer_reject |= (1 << (TY_PRIMARY_DNS - TY_ADJUST_NS));
ipcp->peer_reject |= (1 << (TY_SECONDARY_DNS - TY_ADJUST_NS));
} else
bundle_AdjustDNS(fp->bundle);
} else {
log_Printf(LogDEBUG, "Not updating resolver (readonly)\n");
bundle_AdjustDNS(fp->bundle);
}
}
if (mode_type != MODE_NOP) {
if (mode_type == MODE_REQ && !ipcp->peer_req) {
if (dec->rejend == dec->rej && dec->nakend == dec->nak) {
/*
* Pretend the peer has requested an IP.
* We do this to ensure that we only send one NAK if the only
* reason for the NAK is because the peer isn't sending a
* TY_IPADDR REQ. This stops us from repeatedly trying to tell
* the peer that we have to have an IP address on their end.
*/
ipcp->peer_req = 1;
}
ipaddr.s_addr = INADDR_ANY;
ipcp_ValidateReq(ipcp, ipaddr, dec);
}
fsm_opt_normalise(dec);
}
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}
extern struct mbuf *
ipcp_Input(struct bundle *bundle, struct link *l, struct mbuf *bp)
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{
/* Got PROTO_IPCP from link */
m_settype(bp, MB_IPCPIN);
if (bundle_Phase(bundle) == PHASE_NETWORK)
fsm_Input(&bundle->ncp.ipcp.fsm, bp);
else {
if (bundle_Phase(bundle) < PHASE_NETWORK)
log_Printf(LogIPCP, "%s: Error: Unexpected IPCP in phase %s (ignored)\n",
l->name, bundle_PhaseName(bundle));
m_freem(bp);
}
return NULL;
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}
int
ipcp_UseHisIPaddr(struct bundle *bundle, struct in_addr hisaddr)
{
struct ipcp *ipcp = &bundle->ncp.ipcp;
struct in_addr myaddr;
memset(&ipcp->cfg.peer_range, '\0', sizeof ipcp->cfg.peer_range);
iplist_reset(&ipcp->cfg.peer_list);
ipcp->peer_ip = hisaddr;
ncprange_setip4host(&ipcp->cfg.peer_range, hisaddr);
ncprange_getip4addr(&ipcp->cfg.my_range, &myaddr);
return ipcp_SetIPaddress(ipcp, myaddr, hisaddr);
}
int
ipcp_UseHisaddr(struct bundle *bundle, const char *hisaddr, int setaddr)
{
struct in_addr myaddr;
struct ncp *ncp = &bundle->ncp;
struct ipcp *ipcp = &ncp->ipcp;
struct ncpaddr ncpaddr;
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/* Use `hisaddr' for the peers address (set iface if `setaddr') */
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memset(&ipcp->cfg.peer_range, '\0', sizeof ipcp->cfg.peer_range);
iplist_reset(&ipcp->cfg.peer_list);
if (strpbrk(hisaddr, ",-")) {
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iplist_setsrc(&ipcp->cfg.peer_list, hisaddr);
if (iplist_isvalid(&ipcp->cfg.peer_list)) {
iplist_setrandpos(&ipcp->cfg.peer_list);
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ipcp->peer_ip = ChooseHisAddr(bundle, ipcp->my_ip);
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if (ipcp->peer_ip.s_addr == INADDR_ANY) {
log_Printf(LogWARN, "%s: None available !\n", ipcp->cfg.peer_list.src);
return 0;
}
ncprange_setip4host(&ipcp->cfg.peer_range, ipcp->peer_ip);
} else {
log_Printf(LogWARN, "%s: Invalid range !\n", hisaddr);
return 0;
}
} else if (ncprange_aton(&ipcp->cfg.peer_range, ncp, hisaddr) != 0) {
if (ncprange_family(&ipcp->cfg.my_range) != AF_INET) {
log_Printf(LogWARN, "%s: Not an AF_INET address !\n", hisaddr);
return 0;
}
ncprange_getip4addr(&ipcp->cfg.my_range, &myaddr);
ncprange_getip4addr(&ipcp->cfg.peer_range, &ipcp->peer_ip);
if (setaddr && !ipcp_SetIPaddress(ipcp, myaddr, ipcp->peer_ip))
return 0;
} else
return 0;
ncpaddr_setip4(&ncpaddr, ipcp->peer_ip);
bundle_AdjustFilters(bundle, NULL, &ncpaddr);
return 1; /* Ok */
}
struct in_addr
addr2mask(struct in_addr addr)
{
u_int32_t haddr = ntohl(addr.s_addr);
haddr = IN_CLASSA(haddr) ? IN_CLASSA_NET :
IN_CLASSB(haddr) ? IN_CLASSB_NET :
IN_CLASSC_NET;
addr.s_addr = htonl(haddr);
return addr;
}
size_t
ipcp_QueueLen(struct ipcp *ipcp)
{
struct mqueue *q;
size_t result;
result = 0;
for (q = ipcp->Queue; q < ipcp->Queue + IPCP_QUEUES(ipcp); q++)
result += q->len;
return result;
}
int
ipcp_PushPacket(struct ipcp *ipcp, struct link *l)
{
struct bundle *bundle = ipcp->fsm.bundle;
struct mqueue *queue;
struct mbuf *bp;
int m_len;
u_int32_t secs = 0;
unsigned alivesecs = 0;
if (ipcp->fsm.state != ST_OPENED)
return 0;
/*
* If ccp is not open but is required, do nothing.
*/
if (l->ccp.fsm.state != ST_OPENED && ccp_Required(&l->ccp)) {
log_Printf(LogPHASE, "%s: Not transmitting... waiting for CCP\n", l->name);
return 0;
}
queue = ipcp->Queue + IPCP_QUEUES(ipcp) - 1;
do {
if (queue->top) {
bp = m_dequeue(queue);
bp = mbuf_Read(bp, &secs, sizeof secs);
bp = m_pullup(bp);
m_len = m_length(bp);
if (!FilterCheck(MBUF_CTOP(bp), AF_INET, &bundle->filter.alive,
&alivesecs)) {
if (secs == 0)
secs = alivesecs;
bundle_StartIdleTimer(bundle, secs);
}
link_PushPacket(l, bp, bundle, 0, PROTO_IP);
ipcp_AddOutOctets(ipcp, m_len);
return 1;
}
} while (queue-- != ipcp->Queue);
return 0;
}