blob: 9fc8e4e2d9db9f38b4373b91d4774dbf623d504c [file] [log] [blame] [raw]
/*
* Copyright (C) 2012 by Darren Reed.
*
* See the IPFILTER.LICENCE file for details on licencing.
*
* Added redirect stuff and a variety of bug fixes. (mcn@EnGarde.com)
*/
#include <stdio.h>
#include <string.h>
#include <fcntl.h>
#include <errno.h>
#include <sys/types.h>
#if !defined(__SVR4) && !defined(__svr4__)
#include <strings.h>
#else
#include <sys/byteorder.h>
#endif
#include <sys/time.h>
#include <sys/param.h>
#include <stdlib.h>
#include <unistd.h>
#include <stddef.h>
#include <sys/file.h>
#define _KERNEL
#include <sys/uio.h>
#undef _KERNEL
#include <sys/socket.h>
#include <sys/ioctl.h>
#if defined(sun) && (defined(__svr4__) || defined(__SVR4))
# include <sys/ioccom.h>
# include <sys/sysmacros.h>
#endif
#include <netinet/in.h>
#include <netinet/in_systm.h>
#include <netinet/ip.h>
#include <netinet/tcp.h>
#include <net/if.h>
#if __FreeBSD_version >= 300000
# include <net/if_var.h>
#endif
#include <netdb.h>
#include <arpa/nameser.h>
#include <arpa/inet.h>
#include <resolv.h>
#include <ctype.h>
#if defined(linux)
# include <linux/a.out.h>
#else
# include <nlist.h>
#endif
#include "ipf.h"
#include "netinet/ipl.h"
#include "kmem.h"
#ifdef __hpux
# define nlist nlist64
#endif
#if defined(sun) && !SOLARIS2
# define STRERROR(x) sys_errlist[x]
extern char *sys_errlist[];
#else
# define STRERROR(x) strerror(x)
#endif
#if !defined(lint)
static const char sccsid[] ="@(#)ipnat.c 1.9 6/5/96 (C) 1993 Darren Reed";
static const char rcsid[] = "@(#)$Id$";
#endif
#if SOLARIS
#define bzero(a,b) memset(a,0,b)
#endif
int use_inet6 = 0;
char thishost[MAXHOSTNAMELEN];
extern char *optarg;
void dostats __P((int, natstat_t *, int, int, int *));
void dotable __P((natstat_t *, int, int, int, char *));
void flushtable __P((int, int, int *));
void usage __P((char *));
int main __P((int, char*[]));
void showhostmap __P((natstat_t *nsp));
void natstat_dead __P((natstat_t *, char *));
void dostats_live __P((int, natstat_t *, int, int *));
void showhostmap_dead __P((natstat_t *));
void showhostmap_live __P((int, natstat_t *));
void dostats_dead __P((natstat_t *, int, int *));
int nat_matcharray __P((nat_t *, int *));
int opts;
int nohdrfields = 0;
wordtab_t *nat_fields = NULL;
void usage(name)
char *name;
{
fprintf(stderr, "Usage: %s [-CFhlnrRsv] [-f <filename>]\n", name);
exit(1);
}
int main(argc, argv)
int argc;
char *argv[];
{
int fd, c, mode, *natfilter;
char *file, *core, *kernel;
natstat_t ns, *nsp;
ipfobj_t obj;
fd = -1;
opts = 0;
nsp = &ns;
file = NULL;
core = NULL;
kernel = NULL;
mode = O_RDWR;
natfilter = NULL;
assigndefined(getenv("IPNAT_PREDEFINED"));
while ((c = getopt(argc, argv, "CdFf:hlm:M:N:nO:prRsv")) != -1)
switch (c)
{
case 'C' :
opts |= OPT_CLEAR;
break;
case 'd' :
opts |= OPT_DEBUG;
break;
case 'f' :
file = optarg;
break;
case 'F' :
opts |= OPT_FLUSH;
break;
case 'h' :
opts |=OPT_HITS;
break;
case 'l' :
opts |= OPT_LIST;
mode = O_RDONLY;
break;
case 'm' :
natfilter = parseipfexpr(optarg, NULL);
break;
case 'M' :
core = optarg;
break;
case 'N' :
kernel = optarg;
break;
case 'n' :
opts |= OPT_DONOTHING|OPT_DONTOPEN;
mode = O_RDONLY;
break;
case 'O' :
nat_fields = parsefields(natfields, optarg);
break;
case 'p' :
opts |= OPT_PURGE;
break;
case 'R' :
opts |= OPT_NORESOLVE;
break;
case 'r' :
opts |= OPT_REMOVE;
break;
case 's' :
opts |= OPT_STAT;
mode = O_RDONLY;
break;
case 'v' :
opts |= OPT_VERBOSE;
break;
default :
usage(argv[0]);
}
if (((opts & OPT_PURGE) != 0) && ((opts & OPT_REMOVE) == 0)) {
(void) fprintf(stderr, "%s: -p must be used with -r\n",
argv[0]);
exit(1);
}
initparse();
if ((kernel != NULL) || (core != NULL)) {
(void) setgid(getgid());
(void) setuid(getuid());
}
if (!(opts & OPT_DONOTHING)) {
if (((fd = open(IPNAT_NAME, mode)) == -1) &&
((fd = open(IPNAT_NAME, O_RDONLY)) == -1)) {
(void) fprintf(stderr, "%s: open: %s\n", IPNAT_NAME,
STRERROR(errno));
exit(1);
}
}
bzero((char *)&ns, sizeof(ns));
if ((opts & OPT_DONOTHING) == 0) {
if (checkrev(IPL_NAME) == -1) {
fprintf(stderr, "User/kernel version check failed\n");
exit(1);
}
}
if (!(opts & OPT_DONOTHING) && (kernel == NULL) && (core == NULL)) {
bzero((char *)&obj, sizeof(obj));
obj.ipfo_rev = IPFILTER_VERSION;
obj.ipfo_type = IPFOBJ_NATSTAT;
obj.ipfo_size = sizeof(*nsp);
obj.ipfo_ptr = (void *)nsp;
if (ioctl(fd, SIOCGNATS, &obj) == -1) {
ipferror(fd, "ioctl(SIOCGNATS)");
exit(1);
}
(void) setgid(getgid());
(void) setuid(getuid());
} else if ((kernel != NULL) || (core != NULL)) {
if (openkmem(kernel, core) == -1)
exit(1);
natstat_dead(nsp, kernel);
if (opts & (OPT_LIST|OPT_STAT))
dostats(fd, nsp, opts, 0, natfilter);
exit(0);
}
if (opts & (OPT_FLUSH|OPT_CLEAR))
flushtable(fd, opts, natfilter);
if (file) {
return ipnat_parsefile(fd, ipnat_addrule, ioctl, file);
}
if (opts & (OPT_LIST|OPT_STAT))
dostats(fd, nsp, opts, 1, natfilter);
return 0;
}
/*
* Read NAT statistic information in using a symbol table and memory file
* rather than doing ioctl's.
*/
void natstat_dead(nsp, kernel)
natstat_t *nsp;
char *kernel;
{
struct nlist nat_nlist[10] = {
{ "nat_table" }, /* 0 */
{ "nat_list" },
{ "maptable" },
{ "ipf_nattable_sz" },
{ "ipf_natrules_sz" },
{ "ipf_rdrrules_sz" }, /* 5 */
{ "ipf_hostmap_sz" },
{ "nat_instances" },
{ NULL }
};
void *tables[2];
if (nlist(kernel, nat_nlist) == -1) {
fprintf(stderr, "nlist error\n");
return;
}
/*
* Normally the ioctl copies all of these values into the structure
* for us, before returning it to userland, so here we must copy each
* one in individually.
*/
kmemcpy((char *)&tables, nat_nlist[0].n_value, sizeof(tables));
nsp->ns_side[0].ns_table = tables[0];
nsp->ns_side[1].ns_table = tables[1];
kmemcpy((char *)&nsp->ns_list, nat_nlist[1].n_value,
sizeof(nsp->ns_list));
kmemcpy((char *)&nsp->ns_maptable, nat_nlist[2].n_value,
sizeof(nsp->ns_maptable));
kmemcpy((char *)&nsp->ns_nattab_sz, nat_nlist[3].n_value,
sizeof(nsp->ns_nattab_sz));
kmemcpy((char *)&nsp->ns_rultab_sz, nat_nlist[4].n_value,
sizeof(nsp->ns_rultab_sz));
kmemcpy((char *)&nsp->ns_rdrtab_sz, nat_nlist[5].n_value,
sizeof(nsp->ns_rdrtab_sz));
kmemcpy((char *)&nsp->ns_hostmap_sz, nat_nlist[6].n_value,
sizeof(nsp->ns_hostmap_sz));
kmemcpy((char *)&nsp->ns_instances, nat_nlist[7].n_value,
sizeof(nsp->ns_instances));
}
/*
* Issue an ioctl to flush either the NAT rules table or the active mapping
* table or both.
*/
void flushtable(fd, opts, match)
int fd, opts, *match;
{
int n = 0;
if (opts & OPT_FLUSH) {
n = 0;
if (!(opts & OPT_DONOTHING)) {
if (match != NULL) {
ipfobj_t obj;
obj.ipfo_rev = IPFILTER_VERSION;
obj.ipfo_size = match[0] * sizeof(int);
obj.ipfo_type = IPFOBJ_IPFEXPR;
obj.ipfo_ptr = match;
if (ioctl(fd, SIOCMATCHFLUSH, &obj) == -1) {
ipferror(fd, "ioctl(SIOCMATCHFLUSH)");
n = -1;
} else {
n = obj.ipfo_retval;
}
} else if (ioctl(fd, SIOCIPFFL, &n) == -1) {
ipferror(fd, "ioctl(SIOCIPFFL)");
n = -1;
}
}
if (n >= 0)
printf("%d entries flushed from NAT table\n", n);
}
if (opts & OPT_CLEAR) {
n = 1;
if (!(opts & OPT_DONOTHING) && ioctl(fd, SIOCIPFFL, &n) == -1)
ipferror(fd, "ioctl(SIOCCNATL)");
else
printf("%d entries flushed from NAT list\n", n);
}
}
/*
* Display NAT statistics.
*/
void dostats_dead(nsp, opts, filter)
natstat_t *nsp;
int opts, *filter;
{
nat_t *np, nat;
ipnat_t ipn;
int i;
if (nat_fields == NULL) {
printf("List of active MAP/Redirect filters:\n");
while (nsp->ns_list) {
if (kmemcpy((char *)&ipn, (long)nsp->ns_list,
sizeof(ipn))) {
perror("kmemcpy");
break;
}
if (opts & OPT_HITS)
printf("%lu ", ipn.in_hits);
printnat(&ipn, opts & (OPT_DEBUG|OPT_VERBOSE));
nsp->ns_list = ipn.in_next;
}
}
if (nat_fields == NULL) {
printf("\nList of active sessions:\n");
} else if (nohdrfields == 0) {
for (i = 0; nat_fields[i].w_value != 0; i++) {
printfieldhdr(natfields, nat_fields + i);
if (nat_fields[i + 1].w_value != 0)
printf("\t");
}
printf("\n");
}
for (np = nsp->ns_instances; np; np = nat.nat_next) {
if (kmemcpy((char *)&nat, (long)np, sizeof(nat)))
break;
if ((filter != NULL) && (nat_matcharray(&nat, filter) == 0))
continue;
if (nat_fields != NULL) {
for (i = 0; nat_fields[i].w_value != 0; i++) {
printnatfield(&nat, nat_fields[i].w_value);
if (nat_fields[i + 1].w_value != 0)
printf("\t");
}
printf("\n");
} else {
printactivenat(&nat, opts, nsp->ns_ticks);
if (nat.nat_aps) {
int proto;
if (nat.nat_dir & NAT_OUTBOUND)
proto = nat.nat_pr[1];
else
proto = nat.nat_pr[0];
printaps(nat.nat_aps, opts, proto);
}
}
}
if (opts & OPT_VERBOSE)
showhostmap_dead(nsp);
}
void dotable(nsp, fd, alive, which, side)
natstat_t *nsp;
int fd, alive, which;
char *side;
{
int sz, i, used, maxlen, minlen, totallen;
ipftable_t table;
u_int *buckets;
ipfobj_t obj;
sz = sizeof(*buckets) * nsp->ns_nattab_sz;
buckets = (u_int *)malloc(sz);
if (buckets == NULL) {
fprintf(stderr,
"cannot allocate memory (%d) for buckets\n", sz);
return;
}
obj.ipfo_rev = IPFILTER_VERSION;
obj.ipfo_type = IPFOBJ_GTABLE;
obj.ipfo_size = sizeof(table);
obj.ipfo_ptr = &table;
if (which == 0) {
table.ita_type = IPFTABLE_BUCKETS_NATIN;
} else if (which == 1) {
table.ita_type = IPFTABLE_BUCKETS_NATOUT;
}
table.ita_table = buckets;
if (alive) {
if (ioctl(fd, SIOCGTABL, &obj) != 0) {
ipferror(fd, "SIOCFTABL");
free(buckets);
return;
}
} else {
if (kmemcpy((char *)buckets, (u_long)nsp->ns_nattab_sz, sz)) {
free(buckets);
return;
}
}
minlen = nsp->ns_side[which].ns_inuse;
totallen = 0;
maxlen = 0;
used = 0;
for (i = 0; i < nsp->ns_nattab_sz; i++) {
if (buckets[i] > maxlen)
maxlen = buckets[i];
if (buckets[i] < minlen)
minlen = buckets[i];
if (buckets[i] != 0)
used++;
totallen += buckets[i];
}
printf("%d%%\thash efficiency %s\n",
totallen ? used * 100 / totallen : 0, side);
printf("%2.2f%%\tbucket usage %s\n",
((float)used / nsp->ns_nattab_sz) * 100.0, side);
printf("%d\tminimal length %s\n", minlen, side);
printf("%d\tmaximal length %s\n", maxlen, side);
printf("%.3f\taverage length %s\n",
used ? ((float)totallen / used) : 0.0, side);
free(buckets);
}
void dostats(fd, nsp, opts, alive, filter)
natstat_t *nsp;
int fd, opts, alive, *filter;
{
/*
* Show statistics ?
*/
if (opts & OPT_STAT) {
printnatside("in", &nsp->ns_side[0]);
dotable(nsp, fd, alive, 0, "in");
printnatside("out", &nsp->ns_side[1]);
dotable(nsp, fd, alive, 1, "out");
printf("%lu\tlog successes\n", nsp->ns_side[0].ns_log);
printf("%lu\tlog failures\n", nsp->ns_side[1].ns_log);
printf("%lu\tadded in\n%lu\tadded out\n",
nsp->ns_side[0].ns_added,
nsp->ns_side[1].ns_added);
printf("%u\tactive\n", nsp->ns_active);
printf("%lu\ttransparent adds\n", nsp->ns_addtrpnt);
printf("%lu\tdivert build\n", nsp->ns_divert_build);
printf("%lu\texpired\n", nsp->ns_expire);
printf("%lu\tflush all\n", nsp->ns_flush_all);
printf("%lu\tflush closing\n", nsp->ns_flush_closing);
printf("%lu\tflush queue\n", nsp->ns_flush_queue);
printf("%lu\tflush state\n", nsp->ns_flush_state);
printf("%lu\tflush timeout\n", nsp->ns_flush_timeout);
printf("%lu\thostmap new\n", nsp->ns_hm_new);
printf("%lu\thostmap fails\n", nsp->ns_hm_newfail);
printf("%lu\thostmap add\n", nsp->ns_hm_addref);
printf("%lu\thostmap NULL rule\n", nsp->ns_hm_nullnp);
printf("%lu\tlog ok\n", nsp->ns_log_ok);
printf("%lu\tlog fail\n", nsp->ns_log_fail);
printf("%u\torphan count\n", nsp->ns_orphans);
printf("%u\trule count\n", nsp->ns_rules);
printf("%u\tmap rules\n", nsp->ns_rules_map);
printf("%u\trdr rules\n", nsp->ns_rules_rdr);
printf("%u\twilds\n", nsp->ns_wilds);
if (opts & OPT_VERBOSE)
printf("list %p\n", nsp->ns_list);
}
if (opts & OPT_LIST) {
if (alive)
dostats_live(fd, nsp, opts, filter);
else
dostats_dead(nsp, opts, filter);
}
}
/*
* Display NAT statistics.
*/
void dostats_live(fd, nsp, opts, filter)
natstat_t *nsp;
int fd, opts, *filter;
{
ipfgeniter_t iter;
char buffer[2000];
ipfobj_t obj;
ipnat_t *ipn;
nat_t nat;
int i;
bzero((char *)&obj, sizeof(obj));
obj.ipfo_rev = IPFILTER_VERSION;
obj.ipfo_type = IPFOBJ_GENITER;
obj.ipfo_size = sizeof(iter);
obj.ipfo_ptr = &iter;
iter.igi_type = IPFGENITER_IPNAT;
iter.igi_nitems = 1;
iter.igi_data = buffer;
ipn = (ipnat_t *)buffer;
/*
* Show list of NAT rules and NAT sessions ?
*/
if (nat_fields == NULL) {
printf("List of active MAP/Redirect filters:\n");
while (nsp->ns_list) {
if (ioctl(fd, SIOCGENITER, &obj) == -1)
break;
if (opts & OPT_HITS)
printf("%lu ", ipn->in_hits);
printnat(ipn, opts & (OPT_DEBUG|OPT_VERBOSE));
nsp->ns_list = ipn->in_next;
}
}
if (nat_fields == NULL) {
printf("\nList of active sessions:\n");
} else if (nohdrfields == 0) {
for (i = 0; nat_fields[i].w_value != 0; i++) {
printfieldhdr(natfields, nat_fields + i);
if (nat_fields[i + 1].w_value != 0)
printf("\t");
}
printf("\n");
}
i = IPFGENITER_IPNAT;
(void) ioctl(fd,SIOCIPFDELTOK, &i);
iter.igi_type = IPFGENITER_NAT;
iter.igi_nitems = 1;
iter.igi_data = &nat;
while (nsp->ns_instances != NULL) {
if (ioctl(fd, SIOCGENITER, &obj) == -1)
break;
if ((filter != NULL) && (nat_matcharray(&nat, filter) == 0))
continue;
if (nat_fields != NULL) {
for (i = 0; nat_fields[i].w_value != 0; i++) {
printnatfield(&nat, nat_fields[i].w_value);
if (nat_fields[i + 1].w_value != 0)
printf("\t");
}
printf("\n");
} else {
printactivenat(&nat, opts, nsp->ns_ticks);
if (nat.nat_aps) {
int proto;
if (nat.nat_dir & NAT_OUTBOUND)
proto = nat.nat_pr[1];
else
proto = nat.nat_pr[0];
printaps(nat.nat_aps, opts, proto);
}
}
nsp->ns_instances = nat.nat_next;
}
if (opts & OPT_VERBOSE)
showhostmap_live(fd, nsp);
i = IPFGENITER_NAT;
(void) ioctl(fd,SIOCIPFDELTOK, &i);
}
/*
* Display the active host mapping table.
*/
void showhostmap_dead(nsp)
natstat_t *nsp;
{
hostmap_t hm, *hmp, **maptable;
u_int hv;
printf("\nList of active host mappings:\n");
maptable = (hostmap_t **)malloc(sizeof(hostmap_t *) *
nsp->ns_hostmap_sz);
if (kmemcpy((char *)maptable, (u_long)nsp->ns_maptable,
sizeof(hostmap_t *) * nsp->ns_hostmap_sz)) {
perror("kmemcpy (maptable)");
return;
}
for (hv = 0; hv < nsp->ns_hostmap_sz; hv++) {
hmp = maptable[hv];
while (hmp) {
if (kmemcpy((char *)&hm, (u_long)hmp, sizeof(hm))) {
perror("kmemcpy (hostmap)");
return;
}
printhostmap(&hm, hv);
hmp = hm.hm_next;
}
}
free(maptable);
}
/*
* Display the active host mapping table.
*/
void showhostmap_live(fd, nsp)
int fd;
natstat_t *nsp;
{
ipfgeniter_t iter;
hostmap_t hm;
ipfobj_t obj;
int i;
bzero((char *)&obj, sizeof(obj));
obj.ipfo_rev = IPFILTER_VERSION;
obj.ipfo_type = IPFOBJ_GENITER;
obj.ipfo_size = sizeof(iter);
obj.ipfo_ptr = &iter;
iter.igi_type = IPFGENITER_HOSTMAP;
iter.igi_nitems = 1;
iter.igi_data = &hm;
printf("\nList of active host mappings:\n");
while (nsp->ns_maplist != NULL) {
if (ioctl(fd, SIOCGENITER, &obj) == -1)
break;
printhostmap(&hm, hm.hm_hv);
nsp->ns_maplist = hm.hm_next;
}
i = IPFGENITER_HOSTMAP;
(void) ioctl(fd,SIOCIPFDELTOK, &i);
}
int nat_matcharray(nat, array)
nat_t *nat;
int *array;
{
int i, n, *x, rv, p;
ipfexp_t *e;
rv = 0;
n = array[0];
x = array + 1;
for (; n > 0; x += 3 + x[3], rv = 0) {
e = (ipfexp_t *)x;
if (e->ipfe_cmd == IPF_EXP_END)
break;
n -= e->ipfe_size;
p = e->ipfe_cmd >> 16;
if ((p != 0) && (p != nat->nat_pr[1]))
break;
switch (e->ipfe_cmd)
{
case IPF_EXP_IP_PR :
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= (nat->nat_pr[1] == e->ipfe_arg0[i]);
}
break;
case IPF_EXP_IP_SRCADDR :
if (nat->nat_v[0] != 4)
break;
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= ((nat->nat_osrcaddr &
e->ipfe_arg0[i * 2 + 1]) ==
e->ipfe_arg0[i * 2]) ||
((nat->nat_nsrcaddr &
e->ipfe_arg0[i * 2 + 1]) ==
e->ipfe_arg0[i * 2]);
}
break;
case IPF_EXP_IP_DSTADDR :
if (nat->nat_v[0] != 4)
break;
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= ((nat->nat_odstaddr &
e->ipfe_arg0[i * 2 + 1]) ==
e->ipfe_arg0[i * 2]) ||
((nat->nat_ndstaddr &
e->ipfe_arg0[i * 2 + 1]) ==
e->ipfe_arg0[i * 2]);
}
break;
case IPF_EXP_IP_ADDR :
if (nat->nat_v[0] != 4)
break;
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= ((nat->nat_osrcaddr &
e->ipfe_arg0[i * 2 + 1]) ==
e->ipfe_arg0[i * 2]) ||
((nat->nat_nsrcaddr &
e->ipfe_arg0[i * 2 + 1]) ==
e->ipfe_arg0[i * 2]) ||
((nat->nat_odstaddr &
e->ipfe_arg0[i * 2 + 1]) ==
e->ipfe_arg0[i * 2]) ||
((nat->nat_ndstaddr &
e->ipfe_arg0[i * 2 + 1]) ==
e->ipfe_arg0[i * 2]);
}
break;
#ifdef USE_INET6
case IPF_EXP_IP6_SRCADDR :
if (nat->nat_v[0] != 6)
break;
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= IP6_MASKEQ(&nat->nat_osrc6,
&e->ipfe_arg0[i * 8 + 4],
&e->ipfe_arg0[i * 8]) ||
IP6_MASKEQ(&nat->nat_nsrc6,
&e->ipfe_arg0[i * 8 + 4],
&e->ipfe_arg0[i * 8]);
}
break;
case IPF_EXP_IP6_DSTADDR :
if (nat->nat_v[0] != 6)
break;
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= IP6_MASKEQ(&nat->nat_odst6,
&e->ipfe_arg0[i * 8 + 4],
&e->ipfe_arg0[i * 8]) ||
IP6_MASKEQ(&nat->nat_ndst6,
&e->ipfe_arg0[i * 8 + 4],
&e->ipfe_arg0[i * 8]);
}
break;
case IPF_EXP_IP6_ADDR :
if (nat->nat_v[0] != 6)
break;
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= IP6_MASKEQ(&nat->nat_osrc6,
&e->ipfe_arg0[i * 8 + 4],
&e->ipfe_arg0[i * 8]) ||
IP6_MASKEQ(&nat->nat_nsrc6,
&e->ipfe_arg0[i * 8 + 4],
&e->ipfe_arg0[i * 8]) ||
IP6_MASKEQ(&nat->nat_odst6,
&e->ipfe_arg0[i * 8 + 4],
&e->ipfe_arg0[i * 8]) ||
IP6_MASKEQ(&nat->nat_ndst6,
&e->ipfe_arg0[i * 8 + 4],
&e->ipfe_arg0[i * 8]);
}
break;
#endif
case IPF_EXP_UDP_PORT :
case IPF_EXP_TCP_PORT :
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= (nat->nat_osport == e->ipfe_arg0[i]) ||
(nat->nat_nsport == e->ipfe_arg0[i]) ||
(nat->nat_odport == e->ipfe_arg0[i]) ||
(nat->nat_ndport == e->ipfe_arg0[i]);
}
break;
case IPF_EXP_UDP_SPORT :
case IPF_EXP_TCP_SPORT :
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= (nat->nat_osport == e->ipfe_arg0[i]) ||
(nat->nat_nsport == e->ipfe_arg0[i]);
}
break;
case IPF_EXP_UDP_DPORT :
case IPF_EXP_TCP_DPORT :
for (i = 0; !rv && i < e->ipfe_narg; i++) {
rv |= (nat->nat_odport == e->ipfe_arg0[i]) ||
(nat->nat_ndport == e->ipfe_arg0[i]);
}
break;
}
rv ^= e->ipfe_not;
if (rv == 0)
break;
}
return rv;
}