system/freebsd-src
system/freebsd-src
1
0
Fork 0
mirror of https://github.com/freebsd/freebsd-src synced 2024-09-06 17:18:32 +00:00
Code Issues Packages Projects Releases Wiki Activity
freebsd-src/usr.sbin/routed/table.c

1889 lines
44 KiB
C
Raw Normal View History

SGI's version of routed(8), including support for router discovery, RIP version 2, and better configuration. Thanks to Vernon Schryver at SGI for doing the work to make this available to the free software community. This import is mostly conflicts because of the trailing whitespace issue. Obtained from: Vernon Schryver <vjs@mica.denver.sgi.com>
1996-05-30 16:19:16 +00:00
/*
* Copyright (c) 1983, 1988, 1993
* The Regents of the University of California. 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. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS 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 REGENTS 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.
*/
#ifndef lint
static char sccsid[] = "@(#)tables.c 8.1 (Berkeley) 6/5/93";
#endif /* not lint */
#ident "$Revision: 1.2 $"
#include "defs.h"
struct radix_node_head *rhead; /* root of the radix tree */
int need_flash = 1; /* flash update needed
* start =1 to suppress the 1st
*/
struct timeval age_timer; /* next check of old routes */
struct timeval need_kern = { /* need to update kernel table */
EPOCH+MIN_WAITTIME-1
};
int stopint;
naddr age_bad_gate;
/* It is desirable to "aggregate" routes, to combine differing routes of
* the same metric and next hop into a common route with a smaller netmask
* or to suppress redundant routes, routes that add no information to
* routes with smaller netmasks.
*
* A route is redundant if and only if any and all routes with smaller
* but matching netmasks and nets are the same. Since routes are
* kept sorted in the radix tree, redundant routes always come second.
*
* There are two kinds of aggregations. First, two routes of the same bit
* mask and differing only in the least significant bit of the network
* number can be combined into a single route with a coarser mask.
*
* Second, a route can be suppressed in favor of another route with a more
* coarse mask provided no incompatible routes with intermediate masks
* are present. The second kind of aggregation involves suppressing routes.
* A route must not be suppressed if an incompatible route exists with
* an intermediate mask, since the suppressed route would be covered
* by the intermediate.
*
* This code relies on the radix tree walk encountering routes
* sorted first by address, with the smallest address first.
*/
struct ag_info ag_slots[NUM_AG_SLOTS], *ag_avail, *ag_corsest, *ag_finest;
/* #define DEBUG_AG */
#ifdef DEBUG_AG
#define CHECK_AG() {int acnt = 0; struct ag_info *cag; \
for (cag = ag_avail; cag != 0; cag = cag->ag_fine) \
acnt++; \
for (cag = ag_corsest; cag != 0; cag = cag->ag_fine) \
acnt++; \
if (acnt != NUM_AG_SLOTS) { \
(void)fflush(stderr); \
abort(); \
} \
}
#else
#define CHECK_AG()
#endif
/* Output the contents of an aggregation table slot.
* This function must always be immediately followed with the deletion
* of the target slot.
*/
static void
ag_out(struct ag_info *ag,
void (*out)(struct ag_info *))
{
struct ag_info *ag_cors;
naddr bit;
/* If we have both the even and odd twins, then the immediate parent,
* if it is present is redundant, unless it manages to aggregate
* something. On successive calls, this code detects the
* even and odd twins, and marks the parent.
*
* Note that the order in which the radix tree code emits routes
* ensures that the twins are seen before the parent is emitted.
*/
ag_cors = ag->ag_cors;
if (ag_cors != 0
&& ag_cors->ag_mask == ag->ag_mask<<1
&& ag_cors->ag_dst_h == (ag->ag_dst_h & ag_cors->ag_mask)) {
ag_cors->ag_state |= ((ag_cors->ag_dst_h == ag->ag_dst_h)
? AGS_REDUN0
: AGS_REDUN1);
}
/* Skip it if this route is itself redundant.
*
* It is ok to change the contents of the slot here, since it is
* always deleted next.
*/
if (ag->ag_state & AGS_REDUN0) {
if (ag->ag_state & AGS_REDUN1)
return;
bit = (-ag->ag_mask) >> 1;
ag->ag_dst_h |= bit;
ag->ag_mask |= bit;
} else if (ag->ag_state & AGS_REDUN1) {
bit = (-ag->ag_mask) >> 1;
ag->ag_mask |= bit;
}
out(ag);
}
static void
ag_del(struct ag_info *ag)
{
CHECK_AG();
if (ag->ag_cors == 0)
ag_corsest = ag->ag_fine;
else
ag->ag_cors->ag_fine = ag->ag_fine;
if (ag->ag_fine == 0)
ag_finest = ag->ag_cors;
else
ag->ag_fine->ag_cors = ag->ag_cors;
ag->ag_fine = ag_avail;
ag_avail = ag;
CHECK_AG();
}
/* Flush routes waiting for aggretation.
* This must not suppress a route unless it is known that among all
* routes with coarser masks that match it, the one with the longest
* mask is appropriate. This is ensured by scanning the routes
* in lexical order, and with the most restritive mask first
* among routes to the same destination.
*/
void
ag_flush(naddr lim_dst_h, /* flush routes to here */
naddr lim_mask, /* matching this mask */
void (*out)(struct ag_info *))
{
struct ag_info *ag, *ag_cors;
naddr dst_h;
for (ag = ag_finest;
ag != 0 && ag->ag_mask >= lim_mask;
ag = ag_cors) {
ag_cors = ag->ag_cors;
/* work on only the specified routes */
dst_h = ag->ag_dst_h;
if ((dst_h & lim_mask) != lim_dst_h)
continue;
if (!(ag->ag_state & AGS_SUPPRESS))
ag_out(ag, out);
else for ( ; ; ag_cors = ag_cors->ag_cors) {
/* Look for a route that can suppress the
* current route */
if (ag_cors == 0) {
/* failed, so output it and look for
* another route to work on
*/
ag_out(ag, out);
break;
}
if ((dst_h & ag_cors->ag_mask) == ag_cors->ag_dst_h) {
/* We found a route with a coarser mask that
* aggregates the current target.
*
* If it has a different next hop, it
* cannot replace the target, so output
* the target.
*/
if (ag->ag_gate != ag_cors->ag_gate
&& !(ag->ag_state & AGS_DEAD)
&& !(ag_cors->ag_state & AGS_RDISC)) {
ag_out(ag, out);
break;
}
/* If it has a good enough metric, it replaces
* the target.
*/
if (ag_cors->ag_pref <= ag->ag_pref) {
if (ag_cors->ag_seqno > ag->ag_seqno)
ag_cors->ag_seqno = ag->ag_seqno;
if (AG_IS_REDUN(ag->ag_state)
&& ag_cors->ag_mask==ag->ag_mask<<1) {
if (ag_cors->ag_dst_h == dst_h)
ag_cors->ag_state |= AGS_REDUN0;
else
ag_cors->ag_state |= AGS_REDUN1;
}
break;
}
}
}
/* That route has either been output or suppressed */
ag_cors = ag->ag_cors;
ag_del(ag);
}
CHECK_AG();
}
/* Try to aggregate a route with previous routes.
*/
void
ag_check(naddr dst,
naddr mask,
naddr gate,
char metric,
char pref,
u_int seqno,
u_short tag,
u_short state,
void (*out)(struct ag_info *)) /* output using this */
{
struct ag_info *ag, *nag, *ag_cors;
naddr xaddr;
int x;
NTOHL(dst);
/* Punt non-contiguous subnet masks.
*
* (X & -X) contains a single bit if and only if X is a power of 2.
* (X + (X & -X)) == 0 if and only if X is a power of 2.
*/
if ((mask & -mask) + mask != 0) {
struct ag_info nc_ag;
nc_ag.ag_dst_h = dst;
nc_ag.ag_mask = mask;
nc_ag.ag_gate = gate;
nc_ag.ag_metric = metric;
nc_ag.ag_pref = pref;
nc_ag.ag_tag = tag;
nc_ag.ag_state = state;
nc_ag.ag_seqno = seqno;
out(&nc_ag);
return;
}
/* Search for the right slot in the aggregation table.
*/
ag_cors = 0;
ag = ag_corsest;
while (ag != 0) {
if (ag->ag_mask >= mask)
break;
/* Suppress routes as we look.
* A route to an address less than the current destination
* will not be affected by the current route or any route
* seen hereafter. That means it is safe to suppress it.
* This check keeps poor routes (eg. with large hop counts)
* from preventing suppresion of finer routes.
*/
if (ag_cors != 0
&& ag->ag_dst_h < dst
&& (ag->ag_state & AGS_SUPPRESS)
&& ag_cors->ag_pref <= ag->ag_pref
&& (ag->ag_dst_h & ag_cors->ag_mask) == ag_cors->ag_dst_h
&& (ag_cors->ag_gate == ag->ag_gate
|| (ag->ag_state & AGS_DEAD)
|| (ag_cors->ag_state & AGS_RDISC))) {
if (ag_cors->ag_seqno > ag->ag_seqno)
ag_cors->ag_seqno = ag->ag_seqno;
if (AG_IS_REDUN(ag->ag_state)
&& ag_cors->ag_mask==ag->ag_mask<<1) {
if (ag_cors->ag_dst_h == dst)
ag_cors->ag_state |= AGS_REDUN0;
else
ag_cors->ag_state |= AGS_REDUN1;
}
ag_del(ag);
CHECK_AG();
} else {
ag_cors = ag;
}
ag = ag_cors->ag_fine;
}
/* If we find the even/odd twin of the new route, and if the
* masks and so forth are equal, we can aggregate them.
* We can probably promote one of the pair.
*
* Since the routes are encountered in lexical order,
* the new route must be odd. However, the second or later
* times around this loop, it could be the even twin promoted
* from the even/odd pair of twins of the finer route.
*/
while (ag != 0
&& ag->ag_mask == mask
&& ((ag->ag_dst_h ^ dst) & (mask<<1)) == 0) {
/* When a promoted route encounters the same but explicit
* route, assume the new one has been promoted, and
* so its gateway, metric and tag are right.
*
* Routes are encountered in lexical order, so an even/odd
* pair is never promoted until the parent route is
* already present. So we know that the new route
* is a promoted pair and the route already in the slot
* is the explicit route that was made redundant by
* the pair.
*
* The sequence number only controls flash updating, and
* so should be the smaller of the two.
*/
if (ag->ag_dst_h == dst) {
ag->ag_metric = metric;
ag->ag_pref = pref;
ag->ag_gate = gate;
ag->ag_tag = tag;
if (ag->ag_seqno > seqno)
ag->ag_seqno = seqno;
/* some bits are set only if both routes have them */
ag->ag_state &= ~(~state & (AGS_PROMOTE | AGS_RIPV2));
/* others are set if they are set on either route */
ag->ag_state |= (state & (AGS_REDUN0 | AGS_REDUN1
| AGS_GATEWAY
| AGS_SUPPRESS));
return;
}
/* If one of the routes can be promoted and suppressed
* and the other can at least be suppressed, they
* can be combined.
* Note that any route that can be promoted is always
* marked to be eligible to be suppressed.
*/
if (!((state & AGS_PROMOTE)
&& (ag->ag_state & AGS_SUPPRESS))
&& !((ag->ag_state & AGS_PROMOTE)
&& (state & AGS_SUPPRESS)))
break;
/* A pair of even/odd twin routes can be combined
* if either is redundant, or if they are via the
* same gateway and have the same metric.
* Except that the kernel does not care about the
* metric.
*/
if (AG_IS_REDUN(ag->ag_state)
|| AG_IS_REDUN(state)
|| (ag->ag_gate == gate
&& ag->ag_pref == pref
&& (state & ag->ag_state & AGS_PROMOTE) != 0
&& ag->ag_tag == tag)) {
/* We have both the even and odd pairs.
* Since the routes are encountered in order,
* the route in the slot must be the even twin.
*
* Combine and promote the pair of routes.
*/
if (seqno > ag->ag_seqno)
seqno = ag->ag_seqno;
if (!AG_IS_REDUN(state))
state &= ~AGS_REDUN1;
if (AG_IS_REDUN(ag->ag_state))
state |= AGS_REDUN0;
else
state &= ~AGS_REDUN0;
state |= (ag->ag_state & AGS_RIPV2);
/* Get rid of the even twin that was already
* in the slot.
*/
ag_del(ag);
} else if (ag->ag_pref >= pref
&& (ag->ag_state & AGS_PROMOTE)) {
/* If we cannot combine the pair, maybe the route
* with the worse metric can be promoted.
*
* Promote the old, even twin, by giving its slot
* in the table to the new, odd twin.
*/
ag->ag_dst_h = dst;
xaddr = ag->ag_gate;
ag->ag_gate = gate;
gate = xaddr;
x = ag->ag_tag;
ag->ag_tag = tag;
tag = x;
x = ag->ag_state;
ag->ag_state = state;
state = x;
if (!AG_IS_REDUN(state))
state &= ~AGS_REDUN0;
x = ag->ag_metric;
ag->ag_metric = metric;
metric = x;
x = ag->ag_pref;
ag->ag_pref = pref;
pref = x;
if (seqno >= ag->ag_seqno)
seqno = ag->ag_seqno;
else
ag->ag_seqno = seqno;
} else {
if (!(state & AGS_PROMOTE))
break; /* cannot promote either twin */
/* promote the new, odd twin by shaving its
* mask and address.
*/
if (seqno > ag->ag_seqno)
seqno = ag->ag_seqno;
else
ag->ag_seqno = seqno;
if (!AG_IS_REDUN(state))
state &= ~AGS_REDUN1;
}
mask <<= 1;
dst &= mask;
if (ag_cors == 0) {
ag = ag_corsest;
break;
}
ag = ag_cors;
ag_cors = ag->ag_cors;
}
/* When we can no longer promote and combine routes,
* flush the old route in the target slot. Also flush
* any finer routes that we know will never be aggregated by
* the new route.
*
* In case we moved toward coarser masks,
* get back where we belong
*/
if (ag != 0
&& ag->ag_mask < mask) {
ag_cors = ag;
ag = ag->ag_fine;
}
/* Empty the target slot
*/
if (ag != 0 && ag->ag_mask == mask) {
ag_flush(ag->ag_dst_h, ag->ag_mask, out);
ag = (ag_cors == 0) ? ag_corsest : ag_cors->ag_fine;
}
#ifdef DEBUG_AG
(void)fflush(stderr);
if (ag == 0 && ag_cors != ag_finest)
abort();
if (ag_cors == 0 && ag != ag_corsest)
abort();
if (ag != 0 && ag->ag_cors != ag_cors)
abort();
if (ag_cors != 0 && ag_cors->ag_fine != ag)
abort();
CHECK_AG();
#endif
/* Save the new route on the end of the table.
*/
nag = ag_avail;
ag_avail = nag->ag_fine;
nag->ag_dst_h = dst;
nag->ag_mask = mask;
nag->ag_gate = gate;
nag->ag_metric = metric;
nag->ag_pref = pref;
nag->ag_tag = tag;
nag->ag_state = state;
nag->ag_seqno = seqno;
nag->ag_fine = ag;
if (ag != 0)
ag->ag_cors = nag;
else
ag_finest = nag;
nag->ag_cors = ag_cors;
if (ag_cors == 0)
ag_corsest = nag;
else
ag_cors->ag_fine = nag;
CHECK_AG();
}
static char *
rtm_type_name(u_char type)
{
static char *rtm_types[] = {
"RTM_ADD",
"RTM_DELETE",
"RTM_CHANGE",
"RTM_GET",
"RTM_LOSING",
"RTM_REDIRECT",
"RTM_MISS",
"RTM_LOCK",
"RTM_OLDADD",
"RTM_OLDDEL",
"RTM_RESOLVE",
"RTM_NEWADDR",
"RTM_DELADDR",
"RTM_IFINFO"
};
static char name0[10];
if (type > sizeof(rtm_types)/sizeof(rtm_types[0])
|| type == 0) {
sprintf(name0, "RTM type %#x", type);
return name0;
} else {
return rtm_types[type-1];
}
}
/* Trim a mask in a sockaddr
* Produce a length of 0 for an address of 0.
* Otherwise produce the index of the first zero byte.
*/
void
#ifdef _HAVE_SIN_LEN
masktrim(struct sockaddr_in *ap)
#else
masktrim(struct sockaddr_in_new *ap)
#endif
{
register char *cp;
if (ap->sin_addr.s_addr == 0) {
ap->sin_len = 0;
return;
}
cp = (char *)(&ap->sin_addr.s_addr+1);
while (*--cp != 0)
continue;
ap->sin_len = cp - (char*)ap + 1;
}
/* Tell the kernel to add, delete or change a route
*/
static void
rtioctl(int action, /* RTM_DELETE, etc */
naddr dst,
naddr gate,
naddr mask,
int metric,
int flags)
{
struct {
struct rt_msghdr w_rtm;
struct sockaddr_in w_dst;
struct sockaddr_in w_gate;
#ifdef _HAVE_SA_LEN
struct sockaddr_in w_mask;
#else
struct sockaddr_in_new w_mask;
#endif
} w;
long cc;
again:
bzero(&w, sizeof(w));
w.w_rtm.rtm_msglen = sizeof(w);
w.w_rtm.rtm_version = RTM_VERSION;
w.w_rtm.rtm_type = action;
w.w_rtm.rtm_flags = flags;
w.w_rtm.rtm_seq = ++rt_sock_seqno;
w.w_rtm.rtm_addrs = RTA_DST|RTA_GATEWAY;
if (metric != 0) {
w.w_rtm.rtm_rmx.rmx_hopcount = metric;
w.w_rtm.rtm_inits |= RTV_HOPCOUNT;
}
w.w_dst.sin_family = AF_INET;
w.w_dst.sin_addr.s_addr = dst;
w.w_gate.sin_family = AF_INET;
w.w_gate.sin_addr.s_addr = gate;
#ifdef _HAVE_SA_LEN
w.w_dst.sin_len = sizeof(w.w_dst);
w.w_gate.sin_len = sizeof(w.w_gate);
#endif
if (mask == HOST_MASK) {
w.w_rtm.rtm_flags |= RTF_HOST;
w.w_rtm.rtm_msglen -= sizeof(w.w_mask);
} else {
w.w_rtm.rtm_addrs |= RTA_NETMASK;
w.w_mask.sin_addr.s_addr = htonl(mask);
#ifdef _HAVE_SA_LEN
masktrim(&w.w_mask);
if (w.w_mask.sin_len == 0)
w.w_mask.sin_len = sizeof(long);
w.w_rtm.rtm_msglen -= (sizeof(w.w_mask) - w.w_mask.sin_len);
#endif
}
#ifndef NO_INSTALL
cc = write(rt_sock, &w, w.w_rtm.rtm_msglen);
if (cc == w.w_rtm.rtm_msglen)
return;
if (cc < 0) {
if (errno == ESRCH && action == RTM_CHANGE) {
trace_msg("route to %s disappeared before CHANGE",
addrname(dst, mask, 0));
action = RTM_ADD;
goto again;
}
msglog("write(rt_sock) %s %s: %s",
rtm_type_name(action), addrname(dst, mask, 0),
strerror(errno));
} else {
msglog("write(rt_sock) wrote %d instead of %d",
cc, w.w_rtm.rtm_msglen);
}
#endif
}
#define KHASH_SIZE 71 /* should be prime */
#define KHASH(a,m) khash_bins[((a) ^ (m)) % KHASH_SIZE]
static struct khash {
struct khash *k_next;
naddr k_dst;
naddr k_mask;
naddr k_gate;
short k_metric;
u_short k_state;
#define KS_NEW 0x001
#define KS_DELETE 0x002
#define KS_ADD 0x004
#define KS_CHANGE 0x008
#define KS_DEL_ADD 0x010
#define KS_STATIC 0x020
#define KS_GATEWAY 0x040
#define KS_DYNAMIC 0x080
#define KS_DELETED 0x100 /* already deleted */
time_t k_hold;
time_t k_time;
#define K_HOLD_LIM 30
} *khash_bins[KHASH_SIZE];
static struct khash*
kern_find(naddr dst, naddr mask, struct khash ***ppk)
{
struct khash *k, **pk;
for (pk = &KHASH(dst,mask); (k = *pk) != 0; pk = &k->k_next) {
if (k->k_dst == dst && k->k_mask == mask)
break;
}
if (ppk != 0)
*ppk = pk;
return k;
}
static struct khash*
kern_add(naddr dst, naddr mask)
{
struct khash *k, **pk;
k = kern_find(dst, mask, &pk);
if (k != 0)
return k;
k = (struct khash *)malloc(sizeof(*k));
bzero(k, sizeof(*k));
k->k_dst = dst;
k->k_mask = mask;
k->k_state = KS_NEW;
k->k_time = now.tv_sec;
k->k_hold = now.tv_sec;
*pk = k;
return k;
}
/* add a route the kernel told us
* rt_xaddrs() must have already been called.
*/
static void
rtm_add(struct rt_msghdr *rtm)
{
struct khash *k;
struct interface *ifp;
struct rt_entry *rt;
naddr mask;
if (rtm->rtm_flags & RTF_HOST) {
mask = HOST_MASK;
} else if (RTINFO_NETMASK != 0) {
mask = ntohl(S_ADDR(RTINFO_NETMASK));
} else {
msglog("punt %s without mask",
rtm_type_name(rtm->rtm_type));
return;
}
if (RTINFO_GATE == 0
|| RTINFO_GATE->sa_family != AF_INET) {
msglog("punt %s without gateway",
rtm_type_name(rtm->rtm_type));
return;
}
k = kern_add(S_ADDR(RTINFO_DST), mask);
k->k_gate = S_ADDR(RTINFO_GATE);
k->k_metric = rtm->rtm_rmx.rmx_hopcount;
if (k->k_metric < 0)
k->k_metric = 0;
else if (k->k_metric > HOPCNT_INFINITY)
k->k_metric = HOPCNT_INFINITY;
k->k_state &= ~(KS_NEW | KS_DELETED | KS_GATEWAY | KS_STATIC);
if (rtm->rtm_flags & RTF_GATEWAY)
k->k_state |= KS_GATEWAY;
if (rtm->rtm_flags & RTF_STATIC)
k->k_state |= KS_STATIC;
if (rtm->rtm_flags & RTF_DYNAMIC)
k->k_state |= KS_DYNAMIC;
k->k_time = now.tv_sec;
k->k_hold = now.tv_sec;
/* Put static routes with real metrics into the daemon table so
* they can be advertised.
*/
if (!(k->k_state & KS_STATIC))
return;
if (RTINFO_IFP != 0
&& RTINFO_IFP->sdl_nlen != 0) {
RTINFO_IFP->sdl_data[RTINFO_IFP->sdl_nlen] = '\0';
ifp = ifwithname(RTINFO_IFP->sdl_data, k->k_gate);
} else {
ifp = iflookup(k->k_gate);
}
if (ifp == 0) {
msglog("static route %s --> %s impossibly lacks ifp",
addrname(S_ADDR(RTINFO_DST), mask, 0),
naddr_ntoa(k->k_gate));
return;
}
if (k->k_metric == 0)
return;
rt = rtget(k->k_dst, k->k_mask);
if (rt != 0) {
if (rt->rt_ifp != ifp
|| 0 != (rt->rt_state & RS_NET_S)) {
rtdelete(rt);
rt = 0;
} else if (!(rt->rt_state & (RS_IF
| RS_LOCAL
| RS_MHOME
| RS_GW))) {
rtchange(rt, RS_STATIC,
k->k_gate, ifp->int_addr,
k->k_metric, 0, ifp,
now.tv_sec, 0);
}
}
if (rt == 0)
rtadd(k->k_dst, k->k_mask, k->k_gate,
ifp->int_addr, k->k_metric,
0, RS_STATIC, ifp);
}
/* deal with packet loss
*/
static void
rtm_lose(struct rt_msghdr *rtm)
{
if (RTINFO_GATE == 0
|| RTINFO_GATE->sa_family != AF_INET) {
msglog("punt %s without gateway",
rtm_type_name(rtm->rtm_type));
return;
}
if (!supplier)
rdisc_age(S_ADDR(RTINFO_GATE));
age(S_ADDR(RTINFO_GATE));
}
/* Clean the kernel table by copying it to the daemon image.
* Eventually the daemon will delete any extra routes.
*/
void
flush_kern(void)
{
size_t needed;
int mib[6];
char *buf, *next, *lim;
struct rt_msghdr *rtm;
struct interface *ifp;
static struct sockaddr_in gate_sa;
mib[0] = CTL_NET;
mib[1] = PF_ROUTE;
mib[2] = 0; /* protocol */
mib[3] = 0; /* wildcard address family */
mib[4] = NET_RT_DUMP;
mib[5] = 0; /* no flags */
if (sysctl(mib, 6, 0, &needed, 0, 0) < 0) {
DBGERR(1,"RT_DUMP-sysctl-estimate");
return;
}
buf = malloc(needed);
if (sysctl(mib, 6, buf, &needed, 0, 0) < 0)
BADERR(1,"RT_DUMP");
lim = buf + needed;
for (next = buf; next < lim; next += rtm->rtm_msglen) {
rtm = (struct rt_msghdr *)next;
rt_xaddrs((struct sockaddr *)(rtm+1),
(struct sockaddr *)(next + rtm->rtm_msglen),
rtm->rtm_addrs);
if (RTINFO_DST == 0
|| RTINFO_DST->sa_family != AF_INET)
continue;
if (RTINFO_GATE == 0)
continue;
if (RTINFO_GATE->sa_family != AF_INET) {
if (RTINFO_GATE->sa_family != AF_LINK)
continue;
ifp = ifwithindex(((struct sockaddr_dl *)
RTINFO_GATE)->sdl_index);
if (ifp == 0)
continue;
gate_sa.sin_addr.s_addr = ifp->int_addr;
#ifdef _HAVE_SA_LEN
gate_sa.sin_len = sizeof(gate_sa);
#endif
gate_sa.sin_family = AF_INET;
RTINFO_GATE = (struct sockaddr *)&gate_sa;
}
/* ignore multicast addresses
*/
if (IN_MULTICAST(ntohl(S_ADDR(RTINFO_DST))))
continue;
/* Note static routes and interface routes.
*/
rtm_add(rtm);
}
free(buf);
}
/* Listen to announcements from the kernel
*/
void
read_rt(void)
{
long cc;
struct interface *ifp;
naddr mask;
union {
struct {
struct rt_msghdr rtm;
struct sockaddr addrs[RTAX_MAX];
} r;
struct if_msghdr ifm;
} m;
char pid_str[10+19+1];
for (;;) {
cc = read(rt_sock, &m, sizeof(m));
if (cc <= 0) {
if (cc < 0 && errno != EWOULDBLOCK)
LOGERR("read(rt_sock)");
return;
}
if (m.r.rtm.rtm_version != RTM_VERSION) {
msglog("bogus routing message version %d",
m.r.rtm.rtm_version);
continue;
}
/* Ignore our own results.
*/
if (m.r.rtm.rtm_type <= RTM_CHANGE
&& m.r.rtm.rtm_pid == mypid) {
static int complained = 0;
if (!complained) {
msglog("receiving our own change messages");
complained = 1;
}
continue;
}
if (m.r.rtm.rtm_type == RTM_IFINFO) {
ifp = ifwithindex(m.ifm.ifm_index);
if (ifp == 0)
trace_msg("note %s with flags %#x"
" for index #%d\n",
rtm_type_name(m.r.rtm.rtm_type),
m.ifm.ifm_flags,
m.ifm.ifm_index);
else
trace_msg("note %s with flags %#x for %s\n",
rtm_type_name(m.r.rtm.rtm_type),
m.ifm.ifm_flags,
ifp->int_name);
/* After being informed of a change to an interface,
* check them all now if the check would otherwise
* be a long time from now, if the interface is
* not known, or if the interface has been turned
* off or on.
*/
if (ifinit_timer.tv_sec-now.tv_sec>=CHECK_BAD_INTERVAL
|| ifp == 0
|| ((ifp->int_if_flags ^ m.ifm.ifm_flags)
& IFF_UP_RUNNING) != 0)
ifinit_timer.tv_sec = now.tv_sec;
continue;
}
if (m.r.rtm.rtm_type <= RTM_CHANGE)
(void)sprintf(pid_str," from pid %d",m.r.rtm.rtm_pid);
else
pid_str[0] = '\0';
rt_xaddrs(m.r.addrs, &m.r.addrs[RTAX_MAX],
m.r.rtm.rtm_addrs);
if (RTINFO_DST == 0) {
trace_msg("ignore %s%s without dst\n",
rtm_type_name(m.r.rtm.rtm_type), pid_str);
continue;
}
if (RTINFO_DST->sa_family != AF_INET) {
trace_msg("ignore %s%s for AF %d\n",
rtm_type_name(m.r.rtm.rtm_type), pid_str,
RTINFO_DST->sa_family);
continue;
}
mask = ((RTINFO_NETMASK != 0)
? ntohl(S_ADDR(RTINFO_NETMASK))
: (m.r.rtm.rtm_flags & RTF_HOST)
? HOST_MASK
: std_mask(S_ADDR(RTINFO_DST)));
if (RTINFO_GATE == 0
|| RTINFO_GATE->sa_family != AF_INET) {
trace_msg("%s for %s%s\n",
rtm_type_name(m.r.rtm.rtm_type),
addrname(S_ADDR(RTINFO_DST), mask, 0),
pid_str);
} else {
trace_msg("%s %s --> %s%s\n",
rtm_type_name(m.r.rtm.rtm_type),
addrname(S_ADDR(RTINFO_DST), mask, 0),
saddr_ntoa(RTINFO_GATE),
pid_str);
}
switch (m.r.rtm.rtm_type) {
case RTM_ADD:
case RTM_CHANGE:
if (m.r.rtm.rtm_errno != 0) {
trace_msg("ignore %s%s with \"%s\" error\n",
rtm_type_name(m.r.rtm.rtm_type),
pid_str,
strerror(m.r.rtm.rtm_errno));
} else {
rtm_add(&m.r.rtm);
}
break;
case RTM_REDIRECT:
if (m.r.rtm.rtm_errno != 0) {
trace_msg("ignore %s with \"%s\" from %s"
" for %s-->%s\n",
rtm_type_name(m.r.rtm.rtm_type),
strerror(m.r.rtm.rtm_errno),
saddr_ntoa(RTINFO_AUTHOR),
saddr_ntoa(RTINFO_GATE),
addrname(S_ADDR(RTINFO_DST),
mask, 0));
} else {
rtm_add(&m.r.rtm);
}
break;
case RTM_DELETE:
if (m.r.rtm.rtm_errno != 0) {
trace_msg("ignore %s%s with \"%s\" error\n",
rtm_type_name(m.r.rtm.rtm_type),
pid_str,
strerror(m.r.rtm.rtm_errno));
} else {
del_static(S_ADDR(RTINFO_DST), mask, 1);
}
break;
case RTM_LOSING:
rtm_lose(&m.r.rtm);
break;
default:
break;
}
}
}
/* after aggregating, note routes that belong in the kernel
*/
static void
kern_out(struct ag_info *ag)
{
struct khash *k;
/* Do not install bad routes if they are not already present.
* This includes routes that had RS_NET_S for interfaces that
* recently died.
*/
if (ag->ag_metric == HOPCNT_INFINITY
&& 0 == kern_find(htonl(ag->ag_dst_h), ag->ag_mask, 0))
return;
k = kern_add(htonl(ag->ag_dst_h), ag->ag_mask);
/* will need to add new entry */
if (k->k_state & KS_NEW) {
k->k_state = KS_ADD;
if (ag->ag_state & AGS_GATEWAY)
k->k_state |= KS_GATEWAY;
k->k_gate = ag->ag_gate;
k->k_metric = ag->ag_metric;
return;
}
/* modify existing kernel entry if necessary */
k->k_state &= ~(KS_DELETE | KS_DYNAMIC);
if (k->k_gate != ag->ag_gate
|| k->k_metric != ag->ag_metric) {
k->k_gate = ag->ag_gate;
k->k_metric = ag->ag_metric;
k->k_state |= KS_CHANGE;
}
if ((k->k_state & KS_GATEWAY)
&& !(ag->ag_state & AGS_GATEWAY)) {
k->k_state &= ~KS_GATEWAY;
k->k_state |= (KS_ADD | KS_DEL_ADD);
} else if (!(k->k_state & KS_GATEWAY)
&& (ag->ag_state & AGS_GATEWAY)) {
k->k_state |= KS_GATEWAY;
k->k_state |= (KS_ADD | KS_DEL_ADD);
}
#undef RT
}
/* ARGSUSED */
static int
walk_kern(struct radix_node *rn,
struct walkarg *w)
{
#define RT ((struct rt_entry *)rn)
char pref;
u_int ags = 0;
/* Do not install synthetic routes */
if (0 != (RT->rt_state & RS_NET_S))
return 0;
/* Do not install routes for "external" remote interfaces.
*/
if ((RT->rt_state & RS_IF)
&& RT->rt_ifp != 0
&& (RT->rt_ifp->int_state & IS_EXTERNAL))
return 0;
/* If it is not an interface, or an alias for an interface,
* it must be a "gateway."
*
* If it is a "remote" interface, it is also a "gateway" to
* the kernel if is not a alias.
*/
if (!(RT->rt_state & RS_IF)
|| RT->rt_ifp == 0
|| ((RT->rt_ifp->int_state & IS_REMOTE)
&& RT->rt_ifp->int_metric == 0))
ags |= (AGS_GATEWAY | AGS_SUPPRESS | AGS_PROMOTE);
if (RT->rt_metric == HOPCNT_INFINITY) {
pref = HOPCNT_INFINITY;
ags |= (AGS_DEAD | AGS_SUPPRESS);
} else {
pref = 1;
}
if (RT->rt_state & RS_RDISC)
ags |= AGS_RDISC;
ag_check(RT->rt_dst, RT->rt_mask, RT->rt_gate,
RT->rt_metric, pref,
0, 0, ags, kern_out);
return 0;
#undef RT
}
/* Update the kernel table to match the daemon table.
*/
void
fix_kern(void)
{
int i, flags;
struct khash *k, **pk;
need_kern = age_timer;
/* Walk daemon table, updating the copy of the kernel table.
*/
(void)rn_walktree(rhead, walk_kern, 0);
ag_flush(0,0,kern_out);
for (i = 0; i < KHASH_SIZE; i++) {
for (pk = &khash_bins[i]; (k = *pk) != 0; ) {
/* Do not touch static routes */
if (k->k_state & KS_STATIC) {
pk = &k->k_next;
continue;
}
/* check hold on routes deleted by the operator */
if (k->k_hold > now.tv_sec) {
LIM_SEC(need_kern, k->k_hold);
pk = &k->k_next;
continue;
}
if (k->k_state & KS_DELETE) {
if (!(k->k_state & KS_DELETED))
rtioctl(RTM_DELETE,
k->k_dst,k->k_gate,
k->k_mask, 0, 0);
*pk = k->k_next;
free(k);
continue;
}
if (k->k_state & KS_DEL_ADD)
rtioctl(RTM_DELETE,
k->k_dst,k->k_gate,k->k_mask, 0, 0);
flags = (k->k_state & KS_GATEWAY) ? RTF_GATEWAY : 0;
if (k->k_state & KS_ADD) {
rtioctl(RTM_ADD,
k->k_dst, k->k_gate, k->k_mask,
k->k_metric, flags);
} else if (k->k_state & KS_CHANGE) {
rtioctl(RTM_CHANGE,
k->k_dst,k->k_gate,k->k_mask,
k->k_metric, flags);
}
k->k_state &= ~(KS_ADD | KS_CHANGE | KS_DEL_ADD);
/* Unless it seems something else is handling the
* routes in the kernel, mark this route to be
* deleted in the next cycle.
* This deletes routes that disappear from the
* daemon table, since the normal aging code
* will clear the bit for routes that have not
* disappeard from the daemon table.
*/
if (now.tv_sec >= EPOCH+MIN_WAITTIME-1
&& (rip_interfaces != 0 || !supplier))
k->k_state |= KS_DELETE;
pk = &k->k_next;
}
}
}
/* Delete a static route in the image of the kernel table.
*/
void
del_static(naddr dst,
naddr mask,
int gone)
{
struct khash *k;
struct rt_entry *rt;
/* Just mark it in the table to be deleted next time the kernel
* table is updated.
* If it has already been deleted, mark it as such, and set its
* hold timer so that it will not be deleted again for a while.
* This lets the operator delete a route added by the daemon
* and add a replacement.
*/
k = kern_find(dst, mask, 0);
if (k != 0) {
k->k_state &= ~KS_STATIC;
k->k_state |= KS_DELETE;
if (gone) {
k->k_state |= KS_DELETED;
k->k_hold = now.tv_sec + K_HOLD_LIM;
}
}
rt = rtget(dst, mask);
if (rt != 0 && (rt->rt_state & RS_STATIC))
rtbad(rt);
}
/* Delete all routes generated from ICMP Redirects that use a given
* gateway.
*/
void
del_redirects(naddr bad_gate,
time_t old)
{
int i;
struct khash *k;
for (i = 0; i < KHASH_SIZE; i++) {
for (k = khash_bins[i]; k != 0; k = k->k_next) {
if (!(k->k_state & KS_DYNAMIC)
|| 0 != (k->k_state & (KS_STATIC | KS_DELETE)))
continue;
if (k->k_gate != bad_gate
&& k->k_time > old)
continue;
k->k_state |= KS_DELETE;
need_kern.tv_sec = now.tv_sec;
if (TRACEACTIONS)
trace_msg("mark redirected %s --> %s"
" for deletion\n",
addrname(k->k_dst, k->k_mask, 0),
naddr_ntoa(k->k_gate));
}
}
}
/* Start the daemon tables.
*/
void
rtinit(void)
{
extern int max_keylen;
int i;
struct ag_info *ag;
/* Initialize the radix trees */
max_keylen = sizeof(struct sockaddr_in);
rn_init();
rn_inithead((void**)&rhead, 32);
/* mark all of the slots in the table free */
ag_avail = ag_slots;
for (ag = ag_slots, i = 1; i < NUM_AG_SLOTS; i++) {
ag->ag_fine = ag+1;
ag++;
}
}
#ifdef _HAVE_SIN_LEN
static struct sockaddr_in dst_sock = {sizeof(dst_sock), AF_INET};
static struct sockaddr_in mask_sock = {sizeof(mask_sock), AF_INET};
#else
static struct sockaddr_in_new dst_sock = {_SIN_ADDR_SIZE, AF_INET};
static struct sockaddr_in_new mask_sock = {_SIN_ADDR_SIZE, AF_INET};
#endif
void
set_need_flash(void)
{
if (!need_flash) {
need_flash = 1;
/* Do not send the flash update immediately. Wait a little
* while to hear from other routers.
*/
no_flash.tv_sec = now.tv_sec + MIN_WAITTIME;
}
}
/* Get a particular routing table entry
*/
struct rt_entry *
rtget(naddr dst, naddr mask)
{
struct rt_entry *rt;
dst_sock.sin_addr.s_addr = dst;
mask_sock.sin_addr.s_addr = mask;
masktrim(&mask_sock);
rt = (struct rt_entry *)rhead->rnh_lookup(&dst_sock,&mask_sock,rhead);
if (!rt
|| rt->rt_dst != dst
|| rt->rt_mask != mask)
return 0;
return rt;
}
/* Find a route to dst as the kernel would.
*/
struct rt_entry *
rtfind(naddr dst)
{
dst_sock.sin_addr.s_addr = dst;
return (struct rt_entry *)rhead->rnh_matchaddr(&dst_sock, rhead);
}
/* add a route to the table
*/
void
rtadd(naddr dst,
naddr mask,
naddr gate, /* forward packets here */
naddr router, /* on the authority of this router */
int metric,
u_short tag,
u_int state, /* RS_ for our table */
struct interface *ifp)
{
struct rt_entry *rt;
naddr smask;
int i;
struct rt_spare *rts;
rt = (struct rt_entry *)malloc(sizeof (*rt));
if (rt == 0) {
BADERR(1,"rtadd malloc");
return;
}
bzero(rt, sizeof(*rt));
for (rts = rt->rt_spares, i = NUM_SPARES; i != 0; i--, rts++)
rts->rts_metric = HOPCNT_INFINITY;
rt->rt_nodes->rn_key = (caddr_t)&rt->rt_dst_sock;
rt->rt_dst = dst;
rt->rt_dst_sock.sin_family = AF_INET;
#ifdef _HAVE_SIN_LEN
rt->rt_dst_sock.sin_len = dst_sock.sin_len;
#endif
if (mask != HOST_MASK) {
smask = std_mask(dst);
if ((smask & ~mask) == 0 && mask > smask)
state |= RS_SUBNET;
}
mask_sock.sin_addr.s_addr = mask;
masktrim(&mask_sock);
rt->rt_mask = mask;
rt->rt_state = state;
rt->rt_gate = gate;
rt->rt_router = router;
rt->rt_time = now.tv_sec;
if (metric == HOPCNT_INFINITY) {
rt->rt_time -= POISON_SECS;
rt->rt_hold_down = now.tv_sec+HOLD_TIME;
}
rt->rt_metric = metric;
if ((rt->rt_state & RS_NET_S) == 0)
rt->rt_hold_metric = metric;
else
rt->rt_hold_metric = HOPCNT_INFINITY;
rt->rt_tag = tag;
rt->rt_ifp = ifp;
rt->rt_seqno = update_seqno+1;
if (TRACEACTIONS)
trace_add_del("Add", rt);
need_kern.tv_sec = now.tv_sec;
set_need_flash();
if (0 == rhead->rnh_addaddr(&rt->rt_dst_sock, &mask_sock,
rhead, rt->rt_nodes)) {
msglog("rnh_addaddr() failed for %s mask=%#x",
naddr_ntoa(dst), mask);
}
}
/* notice a changed route
*/
void
rtchange(struct rt_entry *rt,
u_int state, /* new state bits */
naddr gate, /* now forward packets here */
naddr router, /* on the authority of this router */
int metric, /* new metric */
u_short tag,
struct interface *ifp,
time_t new_time,
char *label)
{
if (rt->rt_metric != metric) {
/* Hold down the route if it is bad, but only long enough
* for neighors that do not implement poison-reverse or
* split horizon to hear the bad news.
*/
if (metric == HOPCNT_INFINITY) {
if (new_time > now.tv_sec - POISON_SECS)
new_time = now.tv_sec - POISON_SECS;
if (!(rt->rt_state & RS_RDISC)
&& rt->rt_hold_down < now.tv_sec+HOLD_TIME)
rt->rt_hold_down = now.tv_sec+HOLD_TIME;
if (now.tv_sec < rt->rt_hold_down)
LIM_SEC(age_timer, rt->rt_hold_down+1);
} else {
rt->rt_hold_down = 0;
if ((rt->rt_state & RS_NET_S) == 0)
rt->rt_hold_metric = metric;
}
rt->rt_seqno = update_seqno+1;
set_need_flash();
}
if (rt->rt_gate != gate) {
need_kern.tv_sec = now.tv_sec;
rt->rt_seqno = update_seqno+1;
set_need_flash();
}
state |= (rt->rt_state & RS_SUBNET);
if (TRACEACTIONS)
trace_change(rt, state, gate, router, metric, tag, ifp,
new_time,
label ? label : "Chg ");
rt->rt_state = state;
rt->rt_gate = gate;
rt->rt_router = router;
rt->rt_metric = metric;
rt->rt_tag = tag;
rt->rt_ifp = ifp;
rt->rt_time = new_time;
}
/* switch to a backup route
*/
void
rtswitch(struct rt_entry *rt,
struct rt_spare *rts)
{
struct rt_spare *rts1, swap;
char label[10];
int i;
/* Do not change permanent routes */
if (0 != (rt->rt_state & (RS_GW | RS_MHOME | RS_STATIC | RS_IF)))
return;
/* Do not discard synthetic routes until they go bad */
if (0 != (rt->rt_state & RS_NET_S)
&& rt->rt_metric < HOPCNT_INFINITY)
return;
if (rts == 0) {
/* find the best alternative among the spares */
rts = rt->rt_spares+1;
for (i = NUM_SPARES, rts1 = rts+1; i > 2; i--, rts1++) {
if (BETTER_LINK(rts1,rts))
rts = rts1;
}
}
/* Do not bother if it is not worthwhile.
*/
if (!BETTER_LINK(rts, rt->rt_spares))
return;
/* Do not change the route if it is being held down.
* Honor the hold-down to counter systems that do not support
* split horizon or for other causes of counting to infinity,
* and so only for routes worse than our last good route.
*/
if (now.tv_sec < rt->rt_hold_down
&& rts->rts_metric > rt->rt_hold_metric) {
LIM_SEC(age_timer, rt->rt_hold_down+1);
return;
}
swap = rt->rt_spares[0];
(void)sprintf(label, "Use #%d", rts - rt->rt_spares);
rtchange(rt, rt->rt_state & ~(RS_NET_S | RS_RDISC),
rts->rts_gate, rts->rts_router, rts->rts_metric,
rts->rts_tag, rts->rts_ifp, rts->rts_time, label);
*rts = swap;
}
void
rtdelete(struct rt_entry *rt)
{
struct khash *k;
if (TRACEACTIONS)
trace_add_del("Del", rt);
k = kern_find(rt->rt_dst, rt->rt_mask, 0);
if (k != 0) {
k->k_state |= KS_DELETE;
need_kern.tv_sec = now.tv_sec;
}
dst_sock.sin_addr.s_addr = rt->rt_dst;
mask_sock.sin_addr.s_addr = rt->rt_mask;
masktrim(&mask_sock);
if (rt != (struct rt_entry *)rhead->rnh_deladdr(&dst_sock, &mask_sock,
rhead)) {
msglog("rnh_deladdr() failed");
} else {
free(rt);
}
}
/* Get rid of a bad route, and try to switch to a replacement.
*/
void
rtbad(struct rt_entry *rt)
{
/* Poison the route */
rtchange(rt, rt->rt_state & ~(RS_IF | RS_LOCAL | RS_STATIC),
rt->rt_gate, rt->rt_router, HOPCNT_INFINITY, rt->rt_tag,
0, rt->rt_time, 0);
rtswitch(rt, 0);
}
/* Junk a RS_NET_S route, but save if if it is needed by another interface.
*/
void
rtbad_sub(struct rt_entry *rt)
{
struct interface *ifp, *ifp1;
struct intnet *intnetp;
u_int state;
ifp1 = 0;
state = 0;
if (rt->rt_state & RS_LOCAL) {
/* Is this the route through loopback for the interface?
* If so, see if it is used by any other interfaces, a
* point-to-point interface with the same local address.
*/
for (ifp = ifnet; ifp != 0; ifp = ifp->int_next) {
if (ifp->int_metric == HOPCNT_INFINITY)
continue;
/* Save it if another interface needs it
*/
if (ifp->int_addr == rt->rt_ifp->int_addr) {
state |= RS_LOCAL;
ifp1 = ifp;
break;
}
}
}
if (!(state & RS_LOCAL)
&& (rt->rt_state & RS_NET_S)) {
for (ifp = ifnet; ifp != 0; ifp = ifp->int_next) {
if (ifp->int_metric == HOPCNT_INFINITY)
continue;
/* Retain RIPv1 logical network route if
* there is another interface that justifies
* it.
*/
if ((ifp->int_state & IS_NEED_NET_SUB)
&& rt->rt_mask == ifp->int_std_mask
&& rt->rt_dst == ifp->int_std_addr) {
state |= RS_NET_SUB;
ifp1 = ifp;
} else if ((ifp->int_if_flags & IFF_POINTOPOINT)
&& rt->rt_mask == ifp->int_host_mask
&& rt->rt_dst == ifp->int_host_addr
&& ridhosts) {
state |= RS_NET_HOST;
ifp1 = ifp;
}
}
if (ifp1 == 0) {
for (intnetp = intnets;
intnetp != 0;
intnetp = intnetp->intnet_next) {
if (intnetp->intnet_addr == rt->rt_dst
&& intnetp->intnet_mask == rt->rt_mask) {
state |= RS_NET_SUB;
break;
}
}
}
}
if (ifp1 != 0) {
rtchange(rt, (rt->rt_state & ~(RS_NET_S | RS_LOCAL)) | state,
rt->rt_gate, rt->rt_router, NET_S_METRIC,
rt->rt_tag, ifp1, rt->rt_time, 0);
} else {
rtbad(rt);
}
}
/* Called while walking the table looking for sick interfaces
* or after a time change.
*/
/* ARGSUSED */
int
walk_bad(struct radix_node *rn,
struct walkarg *w)
{
#define RT ((struct rt_entry *)rn)
struct rt_spare *rts;
int i;
time_t new_time;
/* fix any spare routes through the interface
*/
rts = RT->rt_spares;
for (i = NUM_SPARES; i != 1; i--) {
rts++;
if (rts->rts_ifp != 0
&& (rts->rts_ifp->int_state & IS_BROKE)) {
new_time = rts->rts_time;
if (new_time >= now_garbage)
new_time = now_garbage-1;
if (TRACEACTIONS)
trace_upslot(RT, rts, rts->rts_gate,
rts->rts_router, 0,
HOPCNT_INFINITY, rts->rts_tag,
new_time);
rts->rts_ifp = 0;
rts->rts_metric = HOPCNT_INFINITY;
rts->rts_time = new_time;
}
}
/* Deal with the main route
*/
/* finished if it has been handled before or if its interface is ok
*/
if (RT->rt_ifp == 0 || !(RT->rt_ifp->int_state & IS_BROKE))
return 0;
/* Bad routes for other than interfaces are easy.
*/
if (!(RT->rt_state & RS_IF)) {
rtbad(RT);
return 0;
}
rtbad_sub(RT);
return 0;
#undef RT
}
/* Check the age of an individual route.
*/
/* ARGSUSED */
static int
walk_age(struct radix_node *rn,
struct walkarg *w)
{
#define RT ((struct rt_entry *)rn)
struct interface *ifp;
struct rt_spare *rts;
int i;
/* age the spare routes */
rts = RT->rt_spares;
for (i = NUM_SPARES; i != 0; i--, rts++) {
ifp = rts->rts_ifp;
if (i == NUM_SPARES) {
if (!AGE_RT(RT, ifp)) {
/* Keep various things from deciding ageless
* routes are stale */
rts->rts_time = now.tv_sec;
continue;
}
/* forget RIP routes after RIP has been turned off.
*/
if (rip_sock < 0 && !(RT->rt_state & RS_RDISC)) {
rtdelete(RT);
return 0;
}
}
if (age_bad_gate == rts->rts_gate
&& rts->rts_time >= now_stale) {
/* age failing routes
*/
rts->rts_time -= SUPPLY_INTERVAL;
} else if (ppp_noage
&& ifp != 0
&& (ifp->int_if_flags & IFF_POINTOPOINT)
&& (ifp->int_state & IS_QUIET)) {
/* optionally do not age routes through quiet
* point-to-point interfaces
*/
rts->rts_time = now.tv_sec;
continue;
}
/* trash the spare routes when they go bad */
if (rts->rts_metric < HOPCNT_INFINITY
&& now_garbage > rts->rts_time) {
if (TRACEACTIONS)
trace_upslot(RT, rts, rts->rts_gate,
rts->rts_router, rts->rts_ifp,
HOPCNT_INFINITY, rts->rts_tag,
rts->rts_time);
rts->rts_metric = HOPCNT_INFINITY;
}
}
/* finished if the active route is still fresh */
if (now_stale <= RT->rt_time)
return 0;
/* try to switch to an alternative */
if (now.tv_sec < RT->rt_hold_down) {
LIM_SEC(age_timer, RT->rt_hold_down+1);
return 0;
} else {
rtswitch(RT, 0);
}
/* Delete a dead route after it has been publically mourned. */
if (now_garbage > RT->rt_time) {
rtdelete(RT);
return 0;
}
/* Start poisoning a bad route before deleting it. */
if (now.tv_sec - RT->rt_time > EXPIRE_TIME)
rtchange(RT, RT->rt_state, RT->rt_gate, RT->rt_router,
HOPCNT_INFINITY, RT->rt_tag, RT->rt_ifp,
RT->rt_time, 0);
return 0;
}
/* Watch for dead routes and interfaces.
*/
void
age(naddr bad_gate)
{
struct interface *ifp;
age_timer.tv_sec = now.tv_sec + (rip_sock < 0
? NEVER
: SUPPLY_INTERVAL);
for (ifp = ifnet; ifp; ifp = ifp->int_next) {
/* Check for dead IS_REMOTE interfaces by timing their
* transmissions.
*/
if ((ifp->int_state & IS_REMOTE)
&& !(ifp->int_state & IS_PASSIVE)
&& (ifp->int_state & IS_ACTIVE)) {
LIM_SEC(age_timer, now.tv_sec+SUPPLY_INTERVAL);
if (now.tv_sec - ifp->int_act_time > EXPIRE_TIME)
ifbad(ifp,
"remote interface %s to %s timed out");
}
}
/* Age routes. */
age_bad_gate = bad_gate;
(void)rn_walktree(rhead, walk_age, 0);
/* Update the kernel routing table. */
fix_kern();
}
Reference in a new issue Copy permalink