/* $OpenBSD: pfvar.h,v 1.58 2001/12/10 18:28:32 dhartmei Exp $ */ /* * Copyright (c) 2001 Daniel Hartmeier * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * - Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * - 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. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 * COPYRIGHT HOLDERS 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 _NET_PFVAR_H_ #define _NET_PFVAR_H_ #include #include enum { PF_IN=0, PF_OUT=1 }; enum { PF_PASS=0, PF_DROP=1, PF_SCRUB=2 }; enum { PF_OP_IRG=1, PF_OP_EQ=2, PF_OP_NE=3, PF_OP_LT=4, PF_OP_LE=5, PF_OP_GT=6, PF_OP_GE=7, PF_OP_XRG=8 }; enum { PF_DEBUG_NONE=0, PF_DEBUG_URGENT=1, PF_DEBUG_MISC=2 }; enum { PF_CHANGE_ADD_HEAD=1, PF_CHANGE_ADD_TAIL=2, PF_CHANGE_ADD_BEFORE=3, PF_CHANGE_ADD_AFTER=4, PF_CHANGE_REMOVE=5 }; enum { PFTM_TCP_FIRST_PACKET=0, PFTM_TCP_OPENING=1, PFTM_TCP_ESTABLISHED=2, PFTM_TCP_CLOSING=3, PFTM_TCP_FIN_WAIT=4, PFTM_TCP_CLOSED=5, PFTM_UDP_FIRST_PACKET=6, PFTM_UDP_SINGLE=7, PFTM_UDP_MULTIPLE=8, PFTM_ICMP_FIRST_PACKET=9, PFTM_ICMP_ERROR_REPLY=10, PFTM_OTHER_FIRST_PACKET=11, PFTM_OTHER_SINGLE=12, PFTM_OTHER_MULTIPLE=13, PFTM_FRAG=14, PFTM_INTERVAL=15, PFTM_MAX=16 }; enum { PF_FASTROUTE=1, PF_ROUTETO=2, PF_DUPTO=3 }; struct pf_addr { union { struct in_addr v4; struct in6_addr v6; u_int8_t addr8[16]; u_int16_t addr16[8]; u_int32_t addr32[4]; } pfa; /* 128-bit address */ #define v4 pfa.v4 #define v6 pfa.v6 #define addr8 pfa.addr8 #define addr16 pfa.addr16 #define addr32 pfa.addr32 }; /* * Address manipulation macros */ #ifdef _KERNEL #ifdef INET #ifndef INET6 #define PF_INET_ONLY #endif /* ! INET6 */ #endif /* INET */ #ifdef INET6 #ifndef INET #define PF_INET6_ONLY #endif /* ! INET */ #endif /* INET6 */ #ifdef INET #ifdef INET6 #define PF_INET_INET6 #endif /* INET6 */ #endif /* INET */ #else #define PF_INET_INET6 #endif /* _KERNEL */ /* Both IPv4 and IPv6 */ #ifdef PF_INET_INET6 #define PF_AEQ(a, b, c) \ ((c == AF_INET && (a)->addr32[0] == (b)->addr32[0]) || \ (c == AF_INET6 && (a)->addr32[0] == (b)->addr32[0] && \ (a)->addr32[1] == (b)->addr32[1] && \ (a)->addr32[2] == (b)->addr32[2] && \ (a)->addr32[3] == (b)->addr32[3])) \ #define PF_ANEQ(a, b, c) \ ((c == AF_INET && (a)->addr32[0] != (b)->addr32[0]) || \ (c == AF_INET6 && ((a)->addr32[0] != (b)->addr32[0] || \ (a)->addr32[1] != (b)->addr32[1] || \ (a)->addr32[2] != (b)->addr32[2] || \ (a)->addr32[3] != (b)->addr32[3]))) \ #define PF_AZERO(a, c) \ ((c == AF_INET && !(a)->addr32[0]) || \ (c == AF_INET6 && !(a)->addr32[0] && \ !(a)->addr32[1] && !(a)->addr32[2] && \ !(a)->addr32[3] )) \ #define PF_MATCHA(n, a, m, b, f) \ pf_match_addr(n, a, m, b, f) #define PF_ACPY(a, b, f) \ pf_addrcpy(a, b, f) #else /* Just IPv6 */ #ifdef PF_INET6_ONLY #define PF_AEQ(a, b, c) \ ((a)->addr32[0] == (b)->addr32[0] && \ (a)->addr32[1] == (b)->addr32[1] && \ (a)->addr32[2] == (b)->addr32[2] && \ (a)->addr32[3] == (b)->addr32[3]) \ #define PF_ANEQ(a, b, c) \ ((a)->addr32[0] != (b)->addr32[0] || \ (a)->addr32[1] != (b)->addr32[1] || \ (a)->addr32[2] != (b)->addr32[2] || \ (a)->addr32[3] != (b)->addr32[3]) \ #define PF_AZERO(a, c) \ (!(a)->addr32[0] && \ !(a)->addr32[1] && \ !(a)->addr32[2] && \ !(a)->addr32[3] ) \ #define PF_MATCHA(n, a, m, b, f) \ pf_match_addr(n, a, m, b, f) #define PF_ACPY(a, b, f) \ pf_addrcpy(a, b, f) #else /* Just IPv4 */ #ifdef PF_INET_ONLY #define PF_AEQ(a, b, c) \ ((a)->addr32[0] == (b)->addr32[0]) #define PF_ANEQ(a, b, c) \ ((a)->addr32[0] != (b)->addr32[0]) #define PF_AZERO(a, c) \ (!(a)->addr32[0]) #define PF_MATCHA(n, a, m, b, f) \ pf_match_addr(n, a, m, b, f) #define PF_ACPY(a, b, f) \ (a)->v4.s_addr = (b)->v4.s_addr #endif /* PF_INET_ONLY */ #endif /* PF_INET6_ONLY */ #endif /* PF_INET_INET6 */ struct pf_rule_addr { struct pf_addr addr; struct pf_addr mask; u_int16_t port[2]; u_int8_t not; u_int8_t port_op; }; struct pf_rule { char ifname[IFNAMSIZ]; char rt_ifname[IFNAMSIZ]; struct ifnet *ifp; struct ifnet *rt_ifp; struct pf_rule_addr src; struct pf_rule_addr dst; struct pf_addr rt_addr; #define PF_SKIP_IFP 0 #define PF_SKIP_AF 1 #define PF_SKIP_PROTO 2 #define PF_SKIP_SRC_ADDR 3 #define PF_SKIP_SRC_PORT 4 #define PF_SKIP_DST_ADDR 5 #define PF_SKIP_DST_PORT 6 #define PF_SKIP_COUNT 7 struct pf_rule *skip[PF_SKIP_COUNT]; TAILQ_ENTRY(pf_rule) entries; u_int64_t evaluations; u_int64_t packets; u_int64_t bytes; u_int16_t nr; u_int16_t return_icmp; u_int8_t action; u_int8_t direction; u_int8_t log; u_int8_t quick; #define PF_STATE_NORMAL 0x1 #define PF_STATE_MODULATE 0x2 u_int8_t keep_state; u_int8_t af; u_int8_t proto; u_int8_t type; u_int8_t code; u_int8_t flags; u_int8_t flagset; u_int8_t rule_flag; u_int8_t min_ttl; /* minimum ttl for packet normalize */ u_int8_t allow_opts; u_int8_t rt; }; #define PFRULE_RETURNRST 0x01 #define PFRULE_NODF 0x02 struct pf_state_host { struct pf_addr addr; u_int16_t port; }; struct pf_state_peer { u_int32_t seqlo; /* Max sequence number sent */ u_int32_t seqhi; /* Max the other end ACKd + win */ u_int32_t seqdiff; /* Sequence number modulator */ u_int16_t max_win; u_int8_t state; }; struct pf_state { TAILQ_ENTRY(pf_state) entries; struct pf_state_host lan; struct pf_state_host gwy; struct pf_state_host ext; struct pf_state_peer src; struct pf_state_peer dst; struct pf_rule *rule; u_int32_t creation; u_int32_t expire; u_int32_t packets; u_int32_t bytes; u_int8_t af; u_int8_t proto; u_int8_t direction; u_int8_t log; u_int8_t allow_opts; }; #define MATCH_TUPLE(h,r,d,i,a) \ ( \ (r->direction == d) && \ (r->ifp == NULL || r->ifp == i) && \ (!r->proto || r->proto == h->ip_p) && \ (!r->src.mask.addr32[0] || \ pf_match_addr(r->src.not, &(r)->src.addr, \ &(r)->src.mask, (struct pf_addr *)&h->ip_src.s_addr, a)) && \ (!r->dst.mask.addr32[0] || \ pf_match_addr(r->dst.not, &(r)->dst.addr, \ &(r)->dst.mask, (struct pf_addr *)&h->ip_dst.s_addr, a)) \ ) struct pf_nat { char ifname[IFNAMSIZ]; struct ifnet *ifp; TAILQ_ENTRY(pf_nat) entries; struct pf_addr saddr; struct pf_addr smask; struct pf_addr daddr; struct pf_addr dmask; struct pf_addr raddr; u_int8_t af; u_int8_t proto; u_int8_t snot; u_int8_t dnot; u_int8_t ifnot; }; struct pf_binat { char ifname[IFNAMSIZ]; struct ifnet *ifp; TAILQ_ENTRY(pf_binat) entries; struct pf_addr saddr; struct pf_addr daddr; struct pf_addr dmask; struct pf_addr raddr; u_int8_t af; u_int8_t proto; u_int8_t dnot; }; struct pf_rdr { char ifname[IFNAMSIZ]; struct ifnet *ifp; TAILQ_ENTRY(pf_rdr) entries; struct pf_addr saddr; struct pf_addr smask; struct pf_addr daddr; struct pf_addr dmask; struct pf_addr raddr; u_int16_t dport; u_int16_t dport2; u_int16_t rport; u_int8_t af; u_int8_t proto; u_int8_t snot; u_int8_t dnot; u_int8_t ifnot; u_int8_t opts; }; struct pf_tree_key { struct pf_addr addr[2]; u_int16_t port[2]; u_int8_t proto; u_int8_t af; }; TAILQ_HEAD(pf_rulequeue, pf_rule); struct pf_pdesc { struct pf_addr *src; struct pf_addr *dst; u_int16_t *ip_sum; u_int64_t tot_len; /* Make Mickey money */ u_int32_t p_len; /* total length of payload */ u_int16_t flags; /* Let SCRUB trigger behavior in * state code. Easier than tags */ u_int8_t af; u_int8_t proto; union { struct tcphdr *tcp; struct udphdr *udp; struct icmp *icmp; #ifdef INET6 struct icmp6_hdr *icmp6; #endif /* INET6 */ void *any; } hdr; }; /* flags for RDR options */ #define PF_DPORT_RANGE 0x01 /* Dest port uses range */ #define PF_RPORT_RANGE 0x02 /* RDR'ed port uses range */ /* Reasons code for passing/dropping a packet */ #define PFRES_MATCH 0 /* Explicit match of a rule */ #define PFRES_BADOFF 1 /* Bad offset for pull_hdr */ #define PFRES_FRAG 2 /* Dropping following fragment */ #define PFRES_SHORT 3 /* Dropping short packet */ #define PFRES_NORM 4 /* Dropping by normalizer */ #define PFRES_MEMORY 5 /* Dropped due to lacking mem */ #define PFRES_MAX 6 /* total+1 */ #define PFRES_NAMES { \ "match", \ "bad-offset", \ "fragment", \ "short", \ "normalize", \ "memory", \ NULL \ } #define FCNT_STATE_SEARCH 0 #define FCNT_STATE_INSERT 1 #define FCNT_STATE_REMOVALS 2 #define FCNT_MAX 3 #define FCNT_NAMES { \ "state searches", \ "state inserts", \ "state removals", \ NULL \ } #define ACTION_SET(a, x) \ do { \ if ((a) != NULL) \ *(a) = (x); \ } while (0) #define REASON_SET(a, x) \ do { \ if ((a) != NULL) \ *(a) = (x); \ if (x < PFRES_MAX) \ pf_status.counters[x]++; \ } while (0) struct pf_status { u_int64_t counters[PFRES_MAX]; u_int64_t fcounters[FCNT_MAX]; u_int64_t pcounters[2][2][3]; u_int64_t bcounters[2][2]; u_int32_t running; u_int32_t states; u_int32_t since; u_int32_t debug; }; /* * ioctl parameter structures */ struct pfioc_rule { u_int32_t ticket; u_int32_t nr; struct pf_rule rule; }; struct pfioc_changerule { u_int32_t action; struct pf_rule oldrule; struct pf_rule newrule; }; struct pfioc_nat { u_int32_t ticket; u_int32_t nr; struct pf_nat nat; }; struct pfioc_changenat { u_int32_t action; struct pf_nat oldnat; struct pf_nat newnat; }; struct pfioc_natlook { struct pf_addr saddr; struct pf_addr daddr; struct pf_addr rsaddr; struct pf_addr rdaddr; u_int16_t sport; u_int16_t dport; u_int16_t rsport; u_int16_t rdport; u_int8_t af; u_int8_t proto; u_int8_t direction; }; struct pfioc_binat { u_int32_t ticket; u_int32_t nr; struct pf_binat binat; }; struct pfioc_changebinat { u_int32_t action; struct pf_binat oldbinat; struct pf_binat newbinat; }; struct pfioc_rdr { u_int32_t ticket; u_int32_t nr; struct pf_rdr rdr; }; struct pfioc_changerdr { u_int32_t action; struct pf_rdr oldrdr; struct pf_rdr newrdr; }; struct pfioc_state { u_int32_t nr; struct pf_state state; }; struct pfioc_states { int ps_len; union { caddr_t psu_buf; struct pf_state *psu_states; } ps_u; #define ps_buf ps_u.psu_buf #define ps_states ps_u.psu_states }; struct pfioc_if { char ifname[IFNAMSIZ]; }; struct pfioc_tm { int timeout; int seconds; }; /* * ioctl operations */ #define DIOCSTART _IO ('D', 1) #define DIOCSTOP _IO ('D', 2) #define DIOCBEGINRULES _IOWR('D', 3, u_int32_t) #define DIOCADDRULE _IOWR('D', 4, struct pfioc_rule) #define DIOCCOMMITRULES _IOWR('D', 5, u_int32_t) #define DIOCGETRULES _IOWR('D', 6, struct pfioc_rule) #define DIOCGETRULE _IOWR('D', 7, struct pfioc_rule) #define DIOCBEGINNATS _IOWR('D', 8, u_int32_t) #define DIOCADDNAT _IOWR('D', 9, struct pfioc_nat) #define DIOCCOMMITNATS _IOWR('D', 10, u_int32_t) #define DIOCGETNATS _IOWR('D', 11, struct pfioc_nat) #define DIOCGETNAT _IOWR('D', 12, struct pfioc_nat) #define DIOCBEGINRDRS _IOWR('D', 13, u_int32_t) #define DIOCADDRDR _IOWR('D', 14, struct pfioc_rdr) #define DIOCCOMMITRDRS _IOWR('D', 15, u_int32_t) #define DIOCGETRDRS _IOWR('D', 16, struct pfioc_rdr) #define DIOCGETRDR _IOWR('D', 17, struct pfioc_rdr) #define DIOCCLRSTATES _IO ('D', 18) #define DIOCGETSTATE _IOWR('D', 19, struct pfioc_state) #define DIOCSETSTATUSIF _IOWR('D', 20, struct pfioc_if) #define DIOCGETSTATUS _IOWR('D', 21, struct pf_status) #define DIOCCLRSTATUS _IO ('D', 22) #define DIOCNATLOOK _IOWR('D', 23, struct pfioc_natlook) #define DIOCSETDEBUG _IOWR('D', 24, u_int32_t) #define DIOCGETSTATES _IOWR('D', 25, struct pfioc_states) #define DIOCCHANGERULE _IOWR('D', 26, struct pfioc_changerule) #define DIOCCHANGENAT _IOWR('D', 27, struct pfioc_changenat) #define DIOCCHANGERDR _IOWR('D', 28, struct pfioc_changerdr) #define DIOCSETTIMEOUT _IOWR('D', 29, struct pfioc_tm) #define DIOCGETTIMEOUT _IOWR('D', 30, struct pfioc_tm) #define DIOCBEGINBINATS _IOWR('D', 31, u_int32_t) #define DIOCADDBINAT _IOWR('D', 32, struct pfioc_binat) #define DIOCCOMMITBINATS _IOWR('D', 33, u_int32_t) #define DIOCGETBINATS _IOWR('D', 34, struct pfioc_binat) #define DIOCGETBINAT _IOWR('D', 35, struct pfioc_binat) #define DIOCCHANGEBINAT _IOWR('D', 36, struct pfioc_changebinat) #define DIOCADDSTATE _IOWR('D', 37, struct pfioc_state) #ifdef _KERNEL #ifdef INET int pf_test(int, struct ifnet *, struct mbuf **); #endif /* INET */ #ifdef INET6 int pf_test6(int, struct ifnet *, struct mbuf **); #endif /* INET */ struct pf_tree_node; struct pf_state *pf_find_state(struct pf_tree_node *, struct pf_tree_key *); int pf_tree_insert(struct pf_tree_node **, struct pf_tree_node *, struct pf_tree_key *, struct pf_state *); int pf_tree_remove(struct pf_tree_node **, struct pf_tree_node *, struct pf_tree_key *); int pflog_packet(struct ifnet *, struct mbuf *, int, u_short, u_short, struct pf_rule *); int pf_match_addr(u_int8_t, struct pf_addr *, struct pf_addr *, struct pf_addr *, int); int pf_match_port(u_int8_t, u_int16_t, u_int16_t, u_int16_t); void pf_normalize_init(void); int pf_normalize_ip(struct mbuf **, int, struct ifnet *, u_short *); void pf_purge_expired_fragments(void); extern struct pf_rulequeue *pf_rules_active; extern struct pf_status pf_status; #endif /* _KERNEL */ #endif /* _NET_PFVAR_H_ */