freebsd-nq/sbin/pfctl/pfctl_optimize.c
Kristof Provost 7296d6c9bf pfctl: Fix ifgroup check
We cannot just assume that any name which ends with a letter is a group
That's not been true since we allowed renaming of network interfaces. It's also
not true for things like epair0a.

Try to retrieve the group members for the name to check, since we'll get ENOENT
if the group doesn't exist.

MFC after:	1 week
Event:		Aberdeen hackathon 2019
2019-04-19 10:52:54 +00:00

1667 lines
48 KiB
C

/* $OpenBSD: pfctl_optimize.c,v 1.17 2008/05/06 03:45:21 mpf Exp $ */
/*
* Copyright (c) 2004 Mike Frantzen <frantzen@openbsd.org>
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/types.h>
#include <sys/ioctl.h>
#include <sys/socket.h>
#include <net/if.h>
#include <net/pfvar.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <assert.h>
#include <ctype.h>
#include <err.h>
#include <errno.h>
#include <stddef.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "pfctl_parser.h"
#include "pfctl.h"
/* The size at which a table becomes faster than individual rules */
#define TABLE_THRESHOLD 6
/* #define OPT_DEBUG 1 */
#ifdef OPT_DEBUG
# define DEBUG(str, v...) \
printf("%s: " str "\n", __FUNCTION__ , ## v)
#else
# define DEBUG(str, v...) ((void)0)
#endif
/*
* A container that lets us sort a superblock to optimize the skip step jumps
*/
struct pf_skip_step {
int ps_count; /* number of items */
TAILQ_HEAD( , pf_opt_rule) ps_rules;
TAILQ_ENTRY(pf_skip_step) ps_entry;
};
/*
* A superblock is a block of adjacent rules of similar action. If there
* are five PASS rules in a row, they all become members of a superblock.
* Once we have a superblock, we are free to re-order any rules within it
* in order to improve performance; if a packet is passed, it doesn't matter
* who passed it.
*/
struct superblock {
TAILQ_HEAD( , pf_opt_rule) sb_rules;
TAILQ_ENTRY(superblock) sb_entry;
struct superblock *sb_profiled_block;
TAILQ_HEAD(skiplist, pf_skip_step) sb_skipsteps[PF_SKIP_COUNT];
};
TAILQ_HEAD(superblocks, superblock);
/*
* Description of the PF rule structure.
*/
enum {
BARRIER, /* the presence of the field puts the rule in its own block */
BREAK, /* the field may not differ between rules in a superblock */
NOMERGE, /* the field may not differ between rules when combined */
COMBINED, /* the field may itself be combined with other rules */
DC, /* we just don't care about the field */
NEVER}; /* we should never see this field set?!? */
static struct pf_rule_field {
const char *prf_name;
int prf_type;
size_t prf_offset;
size_t prf_size;
} pf_rule_desc[] = {
#define PF_RULE_FIELD(field, ty) \
{#field, \
ty, \
offsetof(struct pf_rule, field), \
sizeof(((struct pf_rule *)0)->field)}
/*
* The presence of these fields in a rule put the rule in its own
* superblock. Thus it will not be optimized. It also prevents the
* rule from being re-ordered at all.
*/
PF_RULE_FIELD(label, BARRIER),
PF_RULE_FIELD(prob, BARRIER),
PF_RULE_FIELD(max_states, BARRIER),
PF_RULE_FIELD(max_src_nodes, BARRIER),
PF_RULE_FIELD(max_src_states, BARRIER),
PF_RULE_FIELD(max_src_conn, BARRIER),
PF_RULE_FIELD(max_src_conn_rate, BARRIER),
PF_RULE_FIELD(anchor, BARRIER), /* for now */
/*
* These fields must be the same between all rules in the same superblock.
* These rules are allowed to be re-ordered but only among like rules.
* For instance we can re-order all 'tag "foo"' rules because they have the
* same tag. But we can not re-order between a 'tag "foo"' and a
* 'tag "bar"' since that would change the meaning of the ruleset.
*/
PF_RULE_FIELD(tagname, BREAK),
PF_RULE_FIELD(keep_state, BREAK),
PF_RULE_FIELD(qname, BREAK),
PF_RULE_FIELD(pqname, BREAK),
PF_RULE_FIELD(rt, BREAK),
PF_RULE_FIELD(allow_opts, BREAK),
PF_RULE_FIELD(rule_flag, BREAK),
PF_RULE_FIELD(action, BREAK),
PF_RULE_FIELD(log, BREAK),
PF_RULE_FIELD(quick, BREAK),
PF_RULE_FIELD(return_ttl, BREAK),
PF_RULE_FIELD(overload_tblname, BREAK),
PF_RULE_FIELD(flush, BREAK),
PF_RULE_FIELD(rpool, BREAK),
PF_RULE_FIELD(logif, BREAK),
/*
* Any fields not listed in this structure act as BREAK fields
*/
/*
* These fields must not differ when we merge two rules together but
* their difference isn't enough to put the rules in different superblocks.
* There are no problems re-ordering any rules with these fields.
*/
PF_RULE_FIELD(af, NOMERGE),
PF_RULE_FIELD(ifnot, NOMERGE),
PF_RULE_FIELD(ifname, NOMERGE), /* hack for IF groups */
PF_RULE_FIELD(match_tag_not, NOMERGE),
PF_RULE_FIELD(match_tagname, NOMERGE),
PF_RULE_FIELD(os_fingerprint, NOMERGE),
PF_RULE_FIELD(timeout, NOMERGE),
PF_RULE_FIELD(return_icmp, NOMERGE),
PF_RULE_FIELD(return_icmp6, NOMERGE),
PF_RULE_FIELD(uid, NOMERGE),
PF_RULE_FIELD(gid, NOMERGE),
PF_RULE_FIELD(direction, NOMERGE),
PF_RULE_FIELD(proto, NOMERGE),
PF_RULE_FIELD(type, NOMERGE),
PF_RULE_FIELD(code, NOMERGE),
PF_RULE_FIELD(flags, NOMERGE),
PF_RULE_FIELD(flagset, NOMERGE),
PF_RULE_FIELD(tos, NOMERGE),
PF_RULE_FIELD(src.port, NOMERGE),
PF_RULE_FIELD(dst.port, NOMERGE),
PF_RULE_FIELD(src.port_op, NOMERGE),
PF_RULE_FIELD(dst.port_op, NOMERGE),
PF_RULE_FIELD(src.neg, NOMERGE),
PF_RULE_FIELD(dst.neg, NOMERGE),
/* These fields can be merged */
PF_RULE_FIELD(src.addr, COMBINED),
PF_RULE_FIELD(dst.addr, COMBINED),
/* We just don't care about these fields. They're set by the kernel */
PF_RULE_FIELD(skip, DC),
PF_RULE_FIELD(evaluations, DC),
PF_RULE_FIELD(packets, DC),
PF_RULE_FIELD(bytes, DC),
PF_RULE_FIELD(kif, DC),
PF_RULE_FIELD(states_cur, DC),
PF_RULE_FIELD(states_tot, DC),
PF_RULE_FIELD(src_nodes, DC),
PF_RULE_FIELD(nr, DC),
PF_RULE_FIELD(entries, DC),
PF_RULE_FIELD(qid, DC),
PF_RULE_FIELD(pqid, DC),
PF_RULE_FIELD(anchor_relative, DC),
PF_RULE_FIELD(anchor_wildcard, DC),
PF_RULE_FIELD(tag, DC),
PF_RULE_FIELD(match_tag, DC),
PF_RULE_FIELD(overload_tbl, DC),
/* These fields should never be set in a PASS/BLOCK rule */
PF_RULE_FIELD(natpass, NEVER),
PF_RULE_FIELD(max_mss, NEVER),
PF_RULE_FIELD(min_ttl, NEVER),
PF_RULE_FIELD(set_tos, NEVER),
};
int add_opt_table(struct pfctl *, struct pf_opt_tbl **, sa_family_t,
struct pf_rule_addr *);
int addrs_combineable(struct pf_rule_addr *, struct pf_rule_addr *);
int addrs_equal(struct pf_rule_addr *, struct pf_rule_addr *);
int block_feedback(struct pfctl *, struct superblock *);
int combine_rules(struct pfctl *, struct superblock *);
void comparable_rule(struct pf_rule *, const struct pf_rule *, int);
int construct_superblocks(struct pfctl *, struct pf_opt_queue *,
struct superblocks *);
void exclude_supersets(struct pf_rule *, struct pf_rule *);
int interface_group(const char *);
int load_feedback_profile(struct pfctl *, struct superblocks *);
int optimize_superblock(struct pfctl *, struct superblock *);
int pf_opt_create_table(struct pfctl *, struct pf_opt_tbl *);
void remove_from_skipsteps(struct skiplist *, struct superblock *,
struct pf_opt_rule *, struct pf_skip_step *);
int remove_identical_rules(struct pfctl *, struct superblock *);
int reorder_rules(struct pfctl *, struct superblock *, int);
int rules_combineable(struct pf_rule *, struct pf_rule *);
void skip_append(struct superblock *, int, struct pf_skip_step *,
struct pf_opt_rule *);
int skip_compare(int, struct pf_skip_step *, struct pf_opt_rule *);
void skip_init(void);
int skip_cmp_af(struct pf_rule *, struct pf_rule *);
int skip_cmp_dir(struct pf_rule *, struct pf_rule *);
int skip_cmp_dst_addr(struct pf_rule *, struct pf_rule *);
int skip_cmp_dst_port(struct pf_rule *, struct pf_rule *);
int skip_cmp_ifp(struct pf_rule *, struct pf_rule *);
int skip_cmp_proto(struct pf_rule *, struct pf_rule *);
int skip_cmp_src_addr(struct pf_rule *, struct pf_rule *);
int skip_cmp_src_port(struct pf_rule *, struct pf_rule *);
int superblock_inclusive(struct superblock *, struct pf_opt_rule *);
void superblock_free(struct pfctl *, struct superblock *);
static int (*skip_comparitors[PF_SKIP_COUNT])(struct pf_rule *,
struct pf_rule *);
static const char *skip_comparitors_names[PF_SKIP_COUNT];
#define PF_SKIP_COMPARITORS { \
{ "ifp", PF_SKIP_IFP, skip_cmp_ifp }, \
{ "dir", PF_SKIP_DIR, skip_cmp_dir }, \
{ "af", PF_SKIP_AF, skip_cmp_af }, \
{ "proto", PF_SKIP_PROTO, skip_cmp_proto }, \
{ "saddr", PF_SKIP_SRC_ADDR, skip_cmp_src_addr }, \
{ "sport", PF_SKIP_SRC_PORT, skip_cmp_src_port }, \
{ "daddr", PF_SKIP_DST_ADDR, skip_cmp_dst_addr }, \
{ "dport", PF_SKIP_DST_PORT, skip_cmp_dst_port } \
}
static struct pfr_buffer table_buffer;
static int table_identifier;
int
pfctl_optimize_ruleset(struct pfctl *pf, struct pf_ruleset *rs)
{
struct superblocks superblocks;
struct pf_opt_queue opt_queue;
struct superblock *block;
struct pf_opt_rule *por;
struct pf_rule *r;
struct pf_rulequeue *old_rules;
DEBUG("optimizing ruleset");
memset(&table_buffer, 0, sizeof(table_buffer));
skip_init();
TAILQ_INIT(&opt_queue);
old_rules = rs->rules[PF_RULESET_FILTER].active.ptr;
rs->rules[PF_RULESET_FILTER].active.ptr =
rs->rules[PF_RULESET_FILTER].inactive.ptr;
rs->rules[PF_RULESET_FILTER].inactive.ptr = old_rules;
/*
* XXX expanding the pf_opt_rule format throughout pfctl might allow
* us to avoid all this copying.
*/
while ((r = TAILQ_FIRST(rs->rules[PF_RULESET_FILTER].inactive.ptr))
!= NULL) {
TAILQ_REMOVE(rs->rules[PF_RULESET_FILTER].inactive.ptr, r,
entries);
if ((por = calloc(1, sizeof(*por))) == NULL)
err(1, "calloc");
memcpy(&por->por_rule, r, sizeof(*r));
if (TAILQ_FIRST(&r->rpool.list) != NULL) {
TAILQ_INIT(&por->por_rule.rpool.list);
pfctl_move_pool(&r->rpool, &por->por_rule.rpool);
} else
bzero(&por->por_rule.rpool,
sizeof(por->por_rule.rpool));
TAILQ_INSERT_TAIL(&opt_queue, por, por_entry);
}
TAILQ_INIT(&superblocks);
if (construct_superblocks(pf, &opt_queue, &superblocks))
goto error;
if (pf->optimize & PF_OPTIMIZE_PROFILE) {
if (load_feedback_profile(pf, &superblocks))
goto error;
}
TAILQ_FOREACH(block, &superblocks, sb_entry) {
if (optimize_superblock(pf, block))
goto error;
}
rs->anchor->refcnt = 0;
while ((block = TAILQ_FIRST(&superblocks))) {
TAILQ_REMOVE(&superblocks, block, sb_entry);
while ((por = TAILQ_FIRST(&block->sb_rules))) {
TAILQ_REMOVE(&block->sb_rules, por, por_entry);
por->por_rule.nr = rs->anchor->refcnt++;
if ((r = calloc(1, sizeof(*r))) == NULL)
err(1, "calloc");
memcpy(r, &por->por_rule, sizeof(*r));
TAILQ_INIT(&r->rpool.list);
pfctl_move_pool(&por->por_rule.rpool, &r->rpool);
TAILQ_INSERT_TAIL(
rs->rules[PF_RULESET_FILTER].active.ptr,
r, entries);
free(por);
}
free(block);
}
return (0);
error:
while ((por = TAILQ_FIRST(&opt_queue))) {
TAILQ_REMOVE(&opt_queue, por, por_entry);
if (por->por_src_tbl) {
pfr_buf_clear(por->por_src_tbl->pt_buf);
free(por->por_src_tbl->pt_buf);
free(por->por_src_tbl);
}
if (por->por_dst_tbl) {
pfr_buf_clear(por->por_dst_tbl->pt_buf);
free(por->por_dst_tbl->pt_buf);
free(por->por_dst_tbl);
}
free(por);
}
while ((block = TAILQ_FIRST(&superblocks))) {
TAILQ_REMOVE(&superblocks, block, sb_entry);
superblock_free(pf, block);
}
return (1);
}
/*
* Go ahead and optimize a superblock
*/
int
optimize_superblock(struct pfctl *pf, struct superblock *block)
{
#ifdef OPT_DEBUG
struct pf_opt_rule *por;
#endif /* OPT_DEBUG */
/* We have a few optimization passes:
* 1) remove duplicate rules or rules that are a subset of other
* rules
* 2) combine otherwise identical rules with different IP addresses
* into a single rule and put the addresses in a table.
* 3) re-order the rules to improve kernel skip steps
* 4) re-order the 'quick' rules based on feedback from the
* active ruleset statistics
*
* XXX combine_rules() doesn't combine v4 and v6 rules. would just
* have to keep af in the table container, make af 'COMBINE' and
* twiddle the af on the merged rule
* XXX maybe add a weighting to the metric on skipsteps when doing
* reordering. sometimes two sequential tables will be better
* that four consecutive interfaces.
* XXX need to adjust the skipstep count of everything after PROTO,
* since they aren't actually checked on a proto mismatch in
* pf_test_{tcp, udp, icmp}()
* XXX should i treat proto=0, af=0 or dir=0 special in skepstep
* calculation since they are a DC?
* XXX keep last skiplist of last superblock to influence this
* superblock. '5 inet6 log' should make '3 inet6' come before '4
* inet' in the next superblock.
* XXX would be useful to add tables for ports
* XXX we can also re-order some mutually exclusive superblocks to
* try merging superblocks before any of these optimization passes.
* for instance a single 'log in' rule in the middle of non-logging
* out rules.
*/
/* shortcut. there will be a lot of 1-rule superblocks */
if (!TAILQ_NEXT(TAILQ_FIRST(&block->sb_rules), por_entry))
return (0);
#ifdef OPT_DEBUG
printf("--- Superblock ---\n");
TAILQ_FOREACH(por, &block->sb_rules, por_entry) {
printf(" ");
print_rule(&por->por_rule, por->por_rule.anchor ?
por->por_rule.anchor->name : "", 1, 0);
}
#endif /* OPT_DEBUG */
if (remove_identical_rules(pf, block))
return (1);
if (combine_rules(pf, block))
return (1);
if ((pf->optimize & PF_OPTIMIZE_PROFILE) &&
TAILQ_FIRST(&block->sb_rules)->por_rule.quick &&
block->sb_profiled_block) {
if (block_feedback(pf, block))
return (1);
} else if (reorder_rules(pf, block, 0)) {
return (1);
}
/*
* Don't add any optimization passes below reorder_rules(). It will
* have divided superblocks into smaller blocks for further refinement
* and doesn't put them back together again. What once was a true
* superblock might have been split into multiple superblocks.
*/
#ifdef OPT_DEBUG
printf("--- END Superblock ---\n");
#endif /* OPT_DEBUG */
return (0);
}
/*
* Optimization pass #1: remove identical rules
*/
int
remove_identical_rules(struct pfctl *pf, struct superblock *block)
{
struct pf_opt_rule *por1, *por2, *por_next, *por2_next;
struct pf_rule a, a2, b, b2;
for (por1 = TAILQ_FIRST(&block->sb_rules); por1; por1 = por_next) {
por_next = TAILQ_NEXT(por1, por_entry);
for (por2 = por_next; por2; por2 = por2_next) {
por2_next = TAILQ_NEXT(por2, por_entry);
comparable_rule(&a, &por1->por_rule, DC);
comparable_rule(&b, &por2->por_rule, DC);
memcpy(&a2, &a, sizeof(a2));
memcpy(&b2, &b, sizeof(b2));
exclude_supersets(&a, &b);
exclude_supersets(&b2, &a2);
if (memcmp(&a, &b, sizeof(a)) == 0) {
DEBUG("removing identical rule nr%d = *nr%d*",
por1->por_rule.nr, por2->por_rule.nr);
TAILQ_REMOVE(&block->sb_rules, por2, por_entry);
if (por_next == por2)
por_next = TAILQ_NEXT(por1, por_entry);
free(por2);
} else if (memcmp(&a2, &b2, sizeof(a2)) == 0) {
DEBUG("removing identical rule *nr%d* = nr%d",
por1->por_rule.nr, por2->por_rule.nr);
TAILQ_REMOVE(&block->sb_rules, por1, por_entry);
free(por1);
break;
}
}
}
return (0);
}
/*
* Optimization pass #2: combine similar rules with different addresses
* into a single rule and a table
*/
int
combine_rules(struct pfctl *pf, struct superblock *block)
{
struct pf_opt_rule *p1, *p2, *por_next;
int src_eq, dst_eq;
if ((pf->loadopt & PFCTL_FLAG_TABLE) == 0) {
warnx("Must enable table loading for optimizations");
return (1);
}
/* First we make a pass to combine the rules. O(n log n) */
TAILQ_FOREACH(p1, &block->sb_rules, por_entry) {
for (p2 = TAILQ_NEXT(p1, por_entry); p2; p2 = por_next) {
por_next = TAILQ_NEXT(p2, por_entry);
src_eq = addrs_equal(&p1->por_rule.src,
&p2->por_rule.src);
dst_eq = addrs_equal(&p1->por_rule.dst,
&p2->por_rule.dst);
if (src_eq && !dst_eq && p1->por_src_tbl == NULL &&
p2->por_dst_tbl == NULL &&
p2->por_src_tbl == NULL &&
rules_combineable(&p1->por_rule, &p2->por_rule) &&
addrs_combineable(&p1->por_rule.dst,
&p2->por_rule.dst)) {
DEBUG("can combine rules nr%d = nr%d",
p1->por_rule.nr, p2->por_rule.nr);
if (p1->por_dst_tbl == NULL &&
add_opt_table(pf, &p1->por_dst_tbl,
p1->por_rule.af, &p1->por_rule.dst))
return (1);
if (add_opt_table(pf, &p1->por_dst_tbl,
p1->por_rule.af, &p2->por_rule.dst))
return (1);
p2->por_dst_tbl = p1->por_dst_tbl;
if (p1->por_dst_tbl->pt_rulecount >=
TABLE_THRESHOLD) {
TAILQ_REMOVE(&block->sb_rules, p2,
por_entry);
free(p2);
}
} else if (!src_eq && dst_eq && p1->por_dst_tbl == NULL
&& p2->por_src_tbl == NULL &&
p2->por_dst_tbl == NULL &&
rules_combineable(&p1->por_rule, &p2->por_rule) &&
addrs_combineable(&p1->por_rule.src,
&p2->por_rule.src)) {
DEBUG("can combine rules nr%d = nr%d",
p1->por_rule.nr, p2->por_rule.nr);
if (p1->por_src_tbl == NULL &&
add_opt_table(pf, &p1->por_src_tbl,
p1->por_rule.af, &p1->por_rule.src))
return (1);
if (add_opt_table(pf, &p1->por_src_tbl,
p1->por_rule.af, &p2->por_rule.src))
return (1);
p2->por_src_tbl = p1->por_src_tbl;
if (p1->por_src_tbl->pt_rulecount >=
TABLE_THRESHOLD) {
TAILQ_REMOVE(&block->sb_rules, p2,
por_entry);
free(p2);
}
}
}
}
/*
* Then we make a final pass to create a valid table name and
* insert the name into the rules.
*/
for (p1 = TAILQ_FIRST(&block->sb_rules); p1; p1 = por_next) {
por_next = TAILQ_NEXT(p1, por_entry);
assert(p1->por_src_tbl == NULL || p1->por_dst_tbl == NULL);
if (p1->por_src_tbl && p1->por_src_tbl->pt_rulecount >=
TABLE_THRESHOLD) {
if (p1->por_src_tbl->pt_generated) {
/* This rule is included in a table */
TAILQ_REMOVE(&block->sb_rules, p1, por_entry);
free(p1);
continue;
}
p1->por_src_tbl->pt_generated = 1;
if ((pf->opts & PF_OPT_NOACTION) == 0 &&
pf_opt_create_table(pf, p1->por_src_tbl))
return (1);
pf->tdirty = 1;
if (pf->opts & PF_OPT_VERBOSE)
print_tabledef(p1->por_src_tbl->pt_name,
PFR_TFLAG_CONST, 1,
&p1->por_src_tbl->pt_nodes);
memset(&p1->por_rule.src.addr, 0,
sizeof(p1->por_rule.src.addr));
p1->por_rule.src.addr.type = PF_ADDR_TABLE;
strlcpy(p1->por_rule.src.addr.v.tblname,
p1->por_src_tbl->pt_name,
sizeof(p1->por_rule.src.addr.v.tblname));
pfr_buf_clear(p1->por_src_tbl->pt_buf);
free(p1->por_src_tbl->pt_buf);
p1->por_src_tbl->pt_buf = NULL;
}
if (p1->por_dst_tbl && p1->por_dst_tbl->pt_rulecount >=
TABLE_THRESHOLD) {
if (p1->por_dst_tbl->pt_generated) {
/* This rule is included in a table */
TAILQ_REMOVE(&block->sb_rules, p1, por_entry);
free(p1);
continue;
}
p1->por_dst_tbl->pt_generated = 1;
if ((pf->opts & PF_OPT_NOACTION) == 0 &&
pf_opt_create_table(pf, p1->por_dst_tbl))
return (1);
pf->tdirty = 1;
if (pf->opts & PF_OPT_VERBOSE)
print_tabledef(p1->por_dst_tbl->pt_name,
PFR_TFLAG_CONST, 1,
&p1->por_dst_tbl->pt_nodes);
memset(&p1->por_rule.dst.addr, 0,
sizeof(p1->por_rule.dst.addr));
p1->por_rule.dst.addr.type = PF_ADDR_TABLE;
strlcpy(p1->por_rule.dst.addr.v.tblname,
p1->por_dst_tbl->pt_name,
sizeof(p1->por_rule.dst.addr.v.tblname));
pfr_buf_clear(p1->por_dst_tbl->pt_buf);
free(p1->por_dst_tbl->pt_buf);
p1->por_dst_tbl->pt_buf = NULL;
}
}
return (0);
}
/*
* Optimization pass #3: re-order rules to improve skip steps
*/
int
reorder_rules(struct pfctl *pf, struct superblock *block, int depth)
{
struct superblock *newblock;
struct pf_skip_step *skiplist;
struct pf_opt_rule *por;
int i, largest, largest_list, rule_count = 0;
TAILQ_HEAD( , pf_opt_rule) head;
/*
* Calculate the best-case skip steps. We put each rule in a list
* of other rules with common fields
*/
for (i = 0; i < PF_SKIP_COUNT; i++) {
TAILQ_FOREACH(por, &block->sb_rules, por_entry) {
TAILQ_FOREACH(skiplist, &block->sb_skipsteps[i],
ps_entry) {
if (skip_compare(i, skiplist, por) == 0)
break;
}
if (skiplist == NULL) {
if ((skiplist = calloc(1, sizeof(*skiplist))) ==
NULL)
err(1, "calloc");
TAILQ_INIT(&skiplist->ps_rules);
TAILQ_INSERT_TAIL(&block->sb_skipsteps[i],
skiplist, ps_entry);
}
skip_append(block, i, skiplist, por);
}
}
TAILQ_FOREACH(por, &block->sb_rules, por_entry)
rule_count++;
/*
* Now we're going to ignore any fields that are identical between
* all of the rules in the superblock and those fields which differ
* between every rule in the superblock.
*/
largest = 0;
for (i = 0; i < PF_SKIP_COUNT; i++) {
skiplist = TAILQ_FIRST(&block->sb_skipsteps[i]);
if (skiplist->ps_count == rule_count) {
DEBUG("(%d) original skipstep '%s' is all rules",
depth, skip_comparitors_names[i]);
skiplist->ps_count = 0;
} else if (skiplist->ps_count == 1) {
skiplist->ps_count = 0;
} else {
DEBUG("(%d) original skipstep '%s' largest jump is %d",
depth, skip_comparitors_names[i],
skiplist->ps_count);
if (skiplist->ps_count > largest)
largest = skiplist->ps_count;
}
}
if (largest == 0) {
/* Ugh. There is NO commonality in the superblock on which
* optimize the skipsteps optimization.
*/
goto done;
}
/*
* Now we're going to empty the superblock rule list and re-create
* it based on a more optimal skipstep order.
*/
TAILQ_INIT(&head);
while ((por = TAILQ_FIRST(&block->sb_rules))) {
TAILQ_REMOVE(&block->sb_rules, por, por_entry);
TAILQ_INSERT_TAIL(&head, por, por_entry);
}
while (!TAILQ_EMPTY(&head)) {
largest = 1;
/*
* Find the most useful skip steps remaining
*/
for (i = 0; i < PF_SKIP_COUNT; i++) {
skiplist = TAILQ_FIRST(&block->sb_skipsteps[i]);
if (skiplist->ps_count > largest) {
largest = skiplist->ps_count;
largest_list = i;
}
}
if (largest <= 1) {
/*
* Nothing useful left. Leave remaining rules in order.
*/
DEBUG("(%d) no more commonality for skip steps", depth);
while ((por = TAILQ_FIRST(&head))) {
TAILQ_REMOVE(&head, por, por_entry);
TAILQ_INSERT_TAIL(&block->sb_rules, por,
por_entry);
}
} else {
/*
* There is commonality. Extract those common rules
* and place them in the ruleset adjacent to each
* other.
*/
skiplist = TAILQ_FIRST(&block->sb_skipsteps[
largest_list]);
DEBUG("(%d) skipstep '%s' largest jump is %d @ #%d",
depth, skip_comparitors_names[largest_list],
largest, TAILQ_FIRST(&TAILQ_FIRST(&block->
sb_skipsteps [largest_list])->ps_rules)->
por_rule.nr);
TAILQ_REMOVE(&block->sb_skipsteps[largest_list],
skiplist, ps_entry);
/*
* There may be further commonality inside these
* rules. So we'll split them off into they're own
* superblock and pass it back into the optimizer.
*/
if (skiplist->ps_count > 2) {
if ((newblock = calloc(1, sizeof(*newblock)))
== NULL) {
warn("calloc");
return (1);
}
TAILQ_INIT(&newblock->sb_rules);
for (i = 0; i < PF_SKIP_COUNT; i++)
TAILQ_INIT(&newblock->sb_skipsteps[i]);
TAILQ_INSERT_BEFORE(block, newblock, sb_entry);
DEBUG("(%d) splitting off %d rules from superblock @ #%d",
depth, skiplist->ps_count,
TAILQ_FIRST(&skiplist->ps_rules)->
por_rule.nr);
} else {
newblock = block;
}
while ((por = TAILQ_FIRST(&skiplist->ps_rules))) {
TAILQ_REMOVE(&head, por, por_entry);
TAILQ_REMOVE(&skiplist->ps_rules, por,
por_skip_entry[largest_list]);
TAILQ_INSERT_TAIL(&newblock->sb_rules, por,
por_entry);
/* Remove this rule from all other skiplists */
remove_from_skipsteps(&block->sb_skipsteps[
largest_list], block, por, skiplist);
}
free(skiplist);
if (newblock != block)
if (reorder_rules(pf, newblock, depth + 1))
return (1);
}
}
done:
for (i = 0; i < PF_SKIP_COUNT; i++) {
while ((skiplist = TAILQ_FIRST(&block->sb_skipsteps[i]))) {
TAILQ_REMOVE(&block->sb_skipsteps[i], skiplist,
ps_entry);
free(skiplist);
}
}
return (0);
}
/*
* Optimization pass #4: re-order 'quick' rules based on feedback from the
* currently running ruleset
*/
int
block_feedback(struct pfctl *pf, struct superblock *block)
{
TAILQ_HEAD( , pf_opt_rule) queue;
struct pf_opt_rule *por1, *por2;
u_int64_t total_count = 0;
struct pf_rule a, b;
/*
* Walk through all of the profiled superblock's rules and copy
* the counters onto our rules.
*/
TAILQ_FOREACH(por1, &block->sb_profiled_block->sb_rules, por_entry) {
comparable_rule(&a, &por1->por_rule, DC);
total_count += por1->por_rule.packets[0] +
por1->por_rule.packets[1];
TAILQ_FOREACH(por2, &block->sb_rules, por_entry) {
if (por2->por_profile_count)
continue;
comparable_rule(&b, &por2->por_rule, DC);
if (memcmp(&a, &b, sizeof(a)) == 0) {
por2->por_profile_count =
por1->por_rule.packets[0] +
por1->por_rule.packets[1];
break;
}
}
}
superblock_free(pf, block->sb_profiled_block);
block->sb_profiled_block = NULL;
/*
* Now we pull all of the rules off the superblock and re-insert them
* in sorted order.
*/
TAILQ_INIT(&queue);
while ((por1 = TAILQ_FIRST(&block->sb_rules)) != NULL) {
TAILQ_REMOVE(&block->sb_rules, por1, por_entry);
TAILQ_INSERT_TAIL(&queue, por1, por_entry);
}
while ((por1 = TAILQ_FIRST(&queue)) != NULL) {
TAILQ_REMOVE(&queue, por1, por_entry);
/* XXX I should sort all of the unused rules based on skip steps */
TAILQ_FOREACH(por2, &block->sb_rules, por_entry) {
if (por1->por_profile_count > por2->por_profile_count) {
TAILQ_INSERT_BEFORE(por2, por1, por_entry);
break;
}
}
#ifdef __FreeBSD__
if (por2 == NULL)
#else
if (por2 == TAILQ_END(&block->sb_rules))
#endif
TAILQ_INSERT_TAIL(&block->sb_rules, por1, por_entry);
}
return (0);
}
/*
* Load the current ruleset from the kernel and try to associate them with
* the ruleset we're optimizing.
*/
int
load_feedback_profile(struct pfctl *pf, struct superblocks *superblocks)
{
struct superblock *block, *blockcur;
struct superblocks prof_superblocks;
struct pf_opt_rule *por;
struct pf_opt_queue queue;
struct pfioc_rule pr;
struct pf_rule a, b;
int nr, mnr;
TAILQ_INIT(&queue);
TAILQ_INIT(&prof_superblocks);
memset(&pr, 0, sizeof(pr));
pr.rule.action = PF_PASS;
if (ioctl(pf->dev, DIOCGETRULES, &pr)) {
warn("DIOCGETRULES");
return (1);
}
mnr = pr.nr;
DEBUG("Loading %d active rules for a feedback profile", mnr);
for (nr = 0; nr < mnr; ++nr) {
struct pf_ruleset *rs;
if ((por = calloc(1, sizeof(*por))) == NULL) {
warn("calloc");
return (1);
}
pr.nr = nr;
if (ioctl(pf->dev, DIOCGETRULE, &pr)) {
warn("DIOCGETRULES");
return (1);
}
memcpy(&por->por_rule, &pr.rule, sizeof(por->por_rule));
rs = pf_find_or_create_ruleset(pr.anchor_call);
por->por_rule.anchor = rs->anchor;
if (TAILQ_EMPTY(&por->por_rule.rpool.list))
memset(&por->por_rule.rpool, 0,
sizeof(por->por_rule.rpool));
TAILQ_INSERT_TAIL(&queue, por, por_entry);
/* XXX pfctl_get_pool(pf->dev, &pr.rule.rpool, nr, pr.ticket,
* PF_PASS, pf->anchor) ???
* ... pfctl_clear_pool(&pr.rule.rpool)
*/
}
if (construct_superblocks(pf, &queue, &prof_superblocks))
return (1);
/*
* Now we try to associate the active ruleset's superblocks with
* the superblocks we're compiling.
*/
block = TAILQ_FIRST(superblocks);
blockcur = TAILQ_FIRST(&prof_superblocks);
while (block && blockcur) {
comparable_rule(&a, &TAILQ_FIRST(&block->sb_rules)->por_rule,
BREAK);
comparable_rule(&b, &TAILQ_FIRST(&blockcur->sb_rules)->por_rule,
BREAK);
if (memcmp(&a, &b, sizeof(a)) == 0) {
/* The two superblocks lined up */
block->sb_profiled_block = blockcur;
} else {
DEBUG("superblocks don't line up between #%d and #%d",
TAILQ_FIRST(&block->sb_rules)->por_rule.nr,
TAILQ_FIRST(&blockcur->sb_rules)->por_rule.nr);
break;
}
block = TAILQ_NEXT(block, sb_entry);
blockcur = TAILQ_NEXT(blockcur, sb_entry);
}
/* Free any superblocks we couldn't link */
while (blockcur) {
block = TAILQ_NEXT(blockcur, sb_entry);
superblock_free(pf, blockcur);
blockcur = block;
}
return (0);
}
/*
* Compare a rule to a skiplist to see if the rule is a member
*/
int
skip_compare(int skipnum, struct pf_skip_step *skiplist,
struct pf_opt_rule *por)
{
struct pf_rule *a, *b;
if (skipnum >= PF_SKIP_COUNT || skipnum < 0)
errx(1, "skip_compare() out of bounds");
a = &por->por_rule;
b = &TAILQ_FIRST(&skiplist->ps_rules)->por_rule;
return ((skip_comparitors[skipnum])(a, b));
}
/*
* Add a rule to a skiplist
*/
void
skip_append(struct superblock *superblock, int skipnum,
struct pf_skip_step *skiplist, struct pf_opt_rule *por)
{
struct pf_skip_step *prev;
skiplist->ps_count++;
TAILQ_INSERT_TAIL(&skiplist->ps_rules, por, por_skip_entry[skipnum]);
/* Keep the list of skiplists sorted by whichever is larger */
while ((prev = TAILQ_PREV(skiplist, skiplist, ps_entry)) &&
prev->ps_count < skiplist->ps_count) {
TAILQ_REMOVE(&superblock->sb_skipsteps[skipnum],
skiplist, ps_entry);
TAILQ_INSERT_BEFORE(prev, skiplist, ps_entry);
}
}
/*
* Remove a rule from the other skiplist calculations.
*/
void
remove_from_skipsteps(struct skiplist *head, struct superblock *block,
struct pf_opt_rule *por, struct pf_skip_step *active_list)
{
struct pf_skip_step *sk, *next;
struct pf_opt_rule *p2;
int i, found;
for (i = 0; i < PF_SKIP_COUNT; i++) {
sk = TAILQ_FIRST(&block->sb_skipsteps[i]);
if (sk == NULL || sk == active_list || sk->ps_count <= 1)
continue;
found = 0;
do {
TAILQ_FOREACH(p2, &sk->ps_rules, por_skip_entry[i])
if (p2 == por) {
TAILQ_REMOVE(&sk->ps_rules, p2,
por_skip_entry[i]);
found = 1;
sk->ps_count--;
break;
}
} while (!found && (sk = TAILQ_NEXT(sk, ps_entry)));
if (found && sk) {
/* Does this change the sorting order? */
while ((next = TAILQ_NEXT(sk, ps_entry)) &&
next->ps_count > sk->ps_count) {
TAILQ_REMOVE(head, sk, ps_entry);
TAILQ_INSERT_AFTER(head, next, sk, ps_entry);
}
#ifdef OPT_DEBUG
next = TAILQ_NEXT(sk, ps_entry);
assert(next == NULL || next->ps_count <= sk->ps_count);
#endif /* OPT_DEBUG */
}
}
}
/* Compare two rules AF field for skiplist construction */
int
skip_cmp_af(struct pf_rule *a, struct pf_rule *b)
{
if (a->af != b->af || a->af == 0)
return (1);
return (0);
}
/* Compare two rules DIRECTION field for skiplist construction */
int
skip_cmp_dir(struct pf_rule *a, struct pf_rule *b)
{
if (a->direction == 0 || a->direction != b->direction)
return (1);
return (0);
}
/* Compare two rules DST Address field for skiplist construction */
int
skip_cmp_dst_addr(struct pf_rule *a, struct pf_rule *b)
{
if (a->dst.neg != b->dst.neg ||
a->dst.addr.type != b->dst.addr.type)
return (1);
/* XXX if (a->proto != b->proto && a->proto != 0 && b->proto != 0
* && (a->proto == IPPROTO_TCP || a->proto == IPPROTO_UDP ||
* a->proto == IPPROTO_ICMP
* return (1);
*/
switch (a->dst.addr.type) {
case PF_ADDR_ADDRMASK:
if (memcmp(&a->dst.addr.v.a.addr, &b->dst.addr.v.a.addr,
sizeof(a->dst.addr.v.a.addr)) ||
memcmp(&a->dst.addr.v.a.mask, &b->dst.addr.v.a.mask,
sizeof(a->dst.addr.v.a.mask)) ||
(a->dst.addr.v.a.addr.addr32[0] == 0 &&
a->dst.addr.v.a.addr.addr32[1] == 0 &&
a->dst.addr.v.a.addr.addr32[2] == 0 &&
a->dst.addr.v.a.addr.addr32[3] == 0))
return (1);
return (0);
case PF_ADDR_DYNIFTL:
if (strcmp(a->dst.addr.v.ifname, b->dst.addr.v.ifname) != 0 ||
a->dst.addr.iflags != b->dst.addr.iflags ||
memcmp(&a->dst.addr.v.a.mask, &b->dst.addr.v.a.mask,
sizeof(a->dst.addr.v.a.mask)))
return (1);
return (0);
case PF_ADDR_NOROUTE:
case PF_ADDR_URPFFAILED:
return (0);
case PF_ADDR_TABLE:
return (strcmp(a->dst.addr.v.tblname, b->dst.addr.v.tblname));
}
return (1);
}
/* Compare two rules DST port field for skiplist construction */
int
skip_cmp_dst_port(struct pf_rule *a, struct pf_rule *b)
{
/* XXX if (a->proto != b->proto && a->proto != 0 && b->proto != 0
* && (a->proto == IPPROTO_TCP || a->proto == IPPROTO_UDP ||
* a->proto == IPPROTO_ICMP
* return (1);
*/
if (a->dst.port_op == PF_OP_NONE || a->dst.port_op != b->dst.port_op ||
a->dst.port[0] != b->dst.port[0] ||
a->dst.port[1] != b->dst.port[1])
return (1);
return (0);
}
/* Compare two rules IFP field for skiplist construction */
int
skip_cmp_ifp(struct pf_rule *a, struct pf_rule *b)
{
if (strcmp(a->ifname, b->ifname) || a->ifname[0] == '\0')
return (1);
return (a->ifnot != b->ifnot);
}
/* Compare two rules PROTO field for skiplist construction */
int
skip_cmp_proto(struct pf_rule *a, struct pf_rule *b)
{
return (a->proto != b->proto || a->proto == 0);
}
/* Compare two rules SRC addr field for skiplist construction */
int
skip_cmp_src_addr(struct pf_rule *a, struct pf_rule *b)
{
if (a->src.neg != b->src.neg ||
a->src.addr.type != b->src.addr.type)
return (1);
/* XXX if (a->proto != b->proto && a->proto != 0 && b->proto != 0
* && (a->proto == IPPROTO_TCP || a->proto == IPPROTO_UDP ||
* a->proto == IPPROTO_ICMP
* return (1);
*/
switch (a->src.addr.type) {
case PF_ADDR_ADDRMASK:
if (memcmp(&a->src.addr.v.a.addr, &b->src.addr.v.a.addr,
sizeof(a->src.addr.v.a.addr)) ||
memcmp(&a->src.addr.v.a.mask, &b->src.addr.v.a.mask,
sizeof(a->src.addr.v.a.mask)) ||
(a->src.addr.v.a.addr.addr32[0] == 0 &&
a->src.addr.v.a.addr.addr32[1] == 0 &&
a->src.addr.v.a.addr.addr32[2] == 0 &&
a->src.addr.v.a.addr.addr32[3] == 0))
return (1);
return (0);
case PF_ADDR_DYNIFTL:
if (strcmp(a->src.addr.v.ifname, b->src.addr.v.ifname) != 0 ||
a->src.addr.iflags != b->src.addr.iflags ||
memcmp(&a->src.addr.v.a.mask, &b->src.addr.v.a.mask,
sizeof(a->src.addr.v.a.mask)))
return (1);
return (0);
case PF_ADDR_NOROUTE:
case PF_ADDR_URPFFAILED:
return (0);
case PF_ADDR_TABLE:
return (strcmp(a->src.addr.v.tblname, b->src.addr.v.tblname));
}
return (1);
}
/* Compare two rules SRC port field for skiplist construction */
int
skip_cmp_src_port(struct pf_rule *a, struct pf_rule *b)
{
if (a->src.port_op == PF_OP_NONE || a->src.port_op != b->src.port_op ||
a->src.port[0] != b->src.port[0] ||
a->src.port[1] != b->src.port[1])
return (1);
/* XXX if (a->proto != b->proto && a->proto != 0 && b->proto != 0
* && (a->proto == IPPROTO_TCP || a->proto == IPPROTO_UDP ||
* a->proto == IPPROTO_ICMP
* return (1);
*/
return (0);
}
void
skip_init(void)
{
struct {
char *name;
int skipnum;
int (*func)(struct pf_rule *, struct pf_rule *);
} comps[] = PF_SKIP_COMPARITORS;
int skipnum, i;
for (skipnum = 0; skipnum < PF_SKIP_COUNT; skipnum++) {
for (i = 0; i < sizeof(comps)/sizeof(*comps); i++)
if (comps[i].skipnum == skipnum) {
skip_comparitors[skipnum] = comps[i].func;
skip_comparitors_names[skipnum] = comps[i].name;
}
}
for (skipnum = 0; skipnum < PF_SKIP_COUNT; skipnum++)
if (skip_comparitors[skipnum] == NULL)
errx(1, "Need to add skip step comparitor to pfctl?!");
}
/*
* Add a host/netmask to a table
*/
int
add_opt_table(struct pfctl *pf, struct pf_opt_tbl **tbl, sa_family_t af,
struct pf_rule_addr *addr)
{
#ifdef OPT_DEBUG
char buf[128];
#endif /* OPT_DEBUG */
static int tablenum = 0;
struct node_host node_host;
if (*tbl == NULL) {
if ((*tbl = calloc(1, sizeof(**tbl))) == NULL ||
((*tbl)->pt_buf = calloc(1, sizeof(*(*tbl)->pt_buf))) ==
NULL)
err(1, "calloc");
(*tbl)->pt_buf->pfrb_type = PFRB_ADDRS;
SIMPLEQ_INIT(&(*tbl)->pt_nodes);
/* This is just a temporary table name */
snprintf((*tbl)->pt_name, sizeof((*tbl)->pt_name), "%s%d",
PF_OPT_TABLE_PREFIX, tablenum++);
DEBUG("creating table <%s>", (*tbl)->pt_name);
}
memset(&node_host, 0, sizeof(node_host));
node_host.af = af;
node_host.addr = addr->addr;
#ifdef OPT_DEBUG
DEBUG("<%s> adding %s/%d", (*tbl)->pt_name, inet_ntop(af,
&node_host.addr.v.a.addr, buf, sizeof(buf)),
unmask(&node_host.addr.v.a.mask, af));
#endif /* OPT_DEBUG */
if (append_addr_host((*tbl)->pt_buf, &node_host, 0, 0)) {
warn("failed to add host");
return (1);
}
if (pf->opts & PF_OPT_VERBOSE) {
struct node_tinit *ti;
if ((ti = calloc(1, sizeof(*ti))) == NULL)
err(1, "malloc");
if ((ti->host = malloc(sizeof(*ti->host))) == NULL)
err(1, "malloc");
memcpy(ti->host, &node_host, sizeof(*ti->host));
SIMPLEQ_INSERT_TAIL(&(*tbl)->pt_nodes, ti, entries);
}
(*tbl)->pt_rulecount++;
if ((*tbl)->pt_rulecount == TABLE_THRESHOLD)
DEBUG("table <%s> now faster than skip steps", (*tbl)->pt_name);
return (0);
}
/*
* Do the dirty work of choosing an unused table name and creating it.
* (be careful with the table name, it might already be used in another anchor)
*/
int
pf_opt_create_table(struct pfctl *pf, struct pf_opt_tbl *tbl)
{
static int tablenum;
struct pfr_table *t;
if (table_buffer.pfrb_type == 0) {
/* Initialize the list of tables */
table_buffer.pfrb_type = PFRB_TABLES;
for (;;) {
pfr_buf_grow(&table_buffer, table_buffer.pfrb_size);
table_buffer.pfrb_size = table_buffer.pfrb_msize;
if (pfr_get_tables(NULL, table_buffer.pfrb_caddr,
&table_buffer.pfrb_size, PFR_FLAG_ALLRSETS))
err(1, "pfr_get_tables");
if (table_buffer.pfrb_size <= table_buffer.pfrb_msize)
break;
}
table_identifier = arc4random();
}
/* XXX would be *really* nice to avoid duplicating identical tables */
/* Now we have to pick a table name that isn't used */
again:
DEBUG("translating temporary table <%s> to <%s%x_%d>", tbl->pt_name,
PF_OPT_TABLE_PREFIX, table_identifier, tablenum);
snprintf(tbl->pt_name, sizeof(tbl->pt_name), "%s%x_%d",
PF_OPT_TABLE_PREFIX, table_identifier, tablenum);
PFRB_FOREACH(t, &table_buffer) {
if (strcasecmp(t->pfrt_name, tbl->pt_name) == 0) {
/* Collision. Try again */
DEBUG("wow, table <%s> in use. trying again",
tbl->pt_name);
table_identifier = arc4random();
goto again;
}
}
tablenum++;
if (pfctl_define_table(tbl->pt_name, PFR_TFLAG_CONST, 1,
pf->astack[0]->name, tbl->pt_buf, pf->astack[0]->ruleset.tticket)) {
warn("failed to create table %s in %s",
tbl->pt_name, pf->astack[0]->name);
return (1);
}
return (0);
}
/*
* Partition the flat ruleset into a list of distinct superblocks
*/
int
construct_superblocks(struct pfctl *pf, struct pf_opt_queue *opt_queue,
struct superblocks *superblocks)
{
struct superblock *block = NULL;
struct pf_opt_rule *por;
int i;
while (!TAILQ_EMPTY(opt_queue)) {
por = TAILQ_FIRST(opt_queue);
TAILQ_REMOVE(opt_queue, por, por_entry);
if (block == NULL || !superblock_inclusive(block, por)) {
if ((block = calloc(1, sizeof(*block))) == NULL) {
warn("calloc");
return (1);
}
TAILQ_INIT(&block->sb_rules);
for (i = 0; i < PF_SKIP_COUNT; i++)
TAILQ_INIT(&block->sb_skipsteps[i]);
TAILQ_INSERT_TAIL(superblocks, block, sb_entry);
}
TAILQ_INSERT_TAIL(&block->sb_rules, por, por_entry);
}
return (0);
}
/*
* Compare two rule addresses
*/
int
addrs_equal(struct pf_rule_addr *a, struct pf_rule_addr *b)
{
if (a->neg != b->neg)
return (0);
return (memcmp(&a->addr, &b->addr, sizeof(a->addr)) == 0);
}
/*
* The addresses are not equal, but can we combine them into one table?
*/
int
addrs_combineable(struct pf_rule_addr *a, struct pf_rule_addr *b)
{
if (a->addr.type != PF_ADDR_ADDRMASK ||
b->addr.type != PF_ADDR_ADDRMASK)
return (0);
if (a->neg != b->neg || a->port_op != b->port_op ||
a->port[0] != b->port[0] || a->port[1] != b->port[1])
return (0);
return (1);
}
/*
* Are we allowed to combine these two rules
*/
int
rules_combineable(struct pf_rule *p1, struct pf_rule *p2)
{
struct pf_rule a, b;
comparable_rule(&a, p1, COMBINED);
comparable_rule(&b, p2, COMBINED);
return (memcmp(&a, &b, sizeof(a)) == 0);
}
/*
* Can a rule be included inside a superblock
*/
int
superblock_inclusive(struct superblock *block, struct pf_opt_rule *por)
{
struct pf_rule a, b;
int i, j;
/* First check for hard breaks */
for (i = 0; i < sizeof(pf_rule_desc)/sizeof(*pf_rule_desc); i++) {
if (pf_rule_desc[i].prf_type == BARRIER) {
for (j = 0; j < pf_rule_desc[i].prf_size; j++)
if (((char *)&por->por_rule)[j +
pf_rule_desc[i].prf_offset] != 0)
return (0);
}
}
/* per-rule src-track is also a hard break */
if (por->por_rule.rule_flag & PFRULE_RULESRCTRACK)
return (0);
/*
* Have to handle interface groups separately. Consider the following
* rules:
* block on EXTIFS to any port 22
* pass on em0 to any port 22
* (where EXTIFS is an arbitrary interface group)
* The optimizer may decide to re-order the pass rule in front of the
* block rule. But what if EXTIFS includes em0??? Such a reordering
* would change the meaning of the ruleset.
* We can't just lookup the EXTIFS group and check if em0 is a member
* because the user is allowed to add interfaces to a group during
* runtime.
* Ergo interface groups become a defacto superblock break :-(
*/
if (interface_group(por->por_rule.ifname) ||
interface_group(TAILQ_FIRST(&block->sb_rules)->por_rule.ifname)) {
if (strcasecmp(por->por_rule.ifname,
TAILQ_FIRST(&block->sb_rules)->por_rule.ifname) != 0)
return (0);
}
comparable_rule(&a, &TAILQ_FIRST(&block->sb_rules)->por_rule, NOMERGE);
comparable_rule(&b, &por->por_rule, NOMERGE);
if (memcmp(&a, &b, sizeof(a)) == 0)
return (1);
#ifdef OPT_DEBUG
for (i = 0; i < sizeof(por->por_rule); i++) {
int closest = -1;
if (((u_int8_t *)&a)[i] != ((u_int8_t *)&b)[i]) {
for (j = 0; j < sizeof(pf_rule_desc) /
sizeof(*pf_rule_desc); j++) {
if (i >= pf_rule_desc[j].prf_offset &&
i < pf_rule_desc[j].prf_offset +
pf_rule_desc[j].prf_size) {
DEBUG("superblock break @ %d due to %s",
por->por_rule.nr,
pf_rule_desc[j].prf_name);
return (0);
}
if (i > pf_rule_desc[j].prf_offset) {
if (closest == -1 ||
i-pf_rule_desc[j].prf_offset <
i-pf_rule_desc[closest].prf_offset)
closest = j;
}
}
if (closest >= 0)
DEBUG("superblock break @ %d on %s+%xh",
por->por_rule.nr,
pf_rule_desc[closest].prf_name,
i - pf_rule_desc[closest].prf_offset -
pf_rule_desc[closest].prf_size);
else
DEBUG("superblock break @ %d on field @ %d",
por->por_rule.nr, i);
return (0);
}
}
#endif /* OPT_DEBUG */
return (0);
}
/*
* Figure out if an interface name is an actual interface or actually a
* group of interfaces.
*/
int
interface_group(const char *ifname)
{
int s;
struct ifgroupreq ifgr;
if (ifname == NULL || !ifname[0])
return (0);
s = get_query_socket();
memset(&ifgr, 0, sizeof(ifgr));
strlcpy(ifgr.ifgr_name, ifname, IFNAMSIZ);
if (ioctl(s, SIOCGIFGMEMB, (caddr_t)&ifgr) == -1) {
if (errno == ENOENT)
return (0);
else
err(1, "SIOCGIFGMEMB");
}
return (1);
}
/*
* Make a rule that can directly compared by memcmp()
*/
void
comparable_rule(struct pf_rule *dst, const struct pf_rule *src, int type)
{
int i;
/*
* To simplify the comparison, we just zero out the fields that are
* allowed to be different and then do a simple memcmp()
*/
memcpy(dst, src, sizeof(*dst));
for (i = 0; i < sizeof(pf_rule_desc)/sizeof(*pf_rule_desc); i++)
if (pf_rule_desc[i].prf_type >= type) {
#ifdef OPT_DEBUG
assert(pf_rule_desc[i].prf_type != NEVER ||
*(((char *)dst) + pf_rule_desc[i].prf_offset) == 0);
#endif /* OPT_DEBUG */
memset(((char *)dst) + pf_rule_desc[i].prf_offset, 0,
pf_rule_desc[i].prf_size);
}
}
/*
* Remove superset information from two rules so we can directly compare them
* with memcmp()
*/
void
exclude_supersets(struct pf_rule *super, struct pf_rule *sub)
{
if (super->ifname[0] == '\0')
memset(sub->ifname, 0, sizeof(sub->ifname));
if (super->direction == PF_INOUT)
sub->direction = PF_INOUT;
if ((super->proto == 0 || super->proto == sub->proto) &&
super->flags == 0 && super->flagset == 0 && (sub->flags ||
sub->flagset)) {
sub->flags = super->flags;
sub->flagset = super->flagset;
}
if (super->proto == 0)
sub->proto = 0;
if (super->src.port_op == 0) {
sub->src.port_op = 0;
sub->src.port[0] = 0;
sub->src.port[1] = 0;
}
if (super->dst.port_op == 0) {
sub->dst.port_op = 0;
sub->dst.port[0] = 0;
sub->dst.port[1] = 0;
}
if (super->src.addr.type == PF_ADDR_ADDRMASK && !super->src.neg &&
!sub->src.neg && super->src.addr.v.a.mask.addr32[0] == 0 &&
super->src.addr.v.a.mask.addr32[1] == 0 &&
super->src.addr.v.a.mask.addr32[2] == 0 &&
super->src.addr.v.a.mask.addr32[3] == 0)
memset(&sub->src.addr, 0, sizeof(sub->src.addr));
else if (super->src.addr.type == PF_ADDR_ADDRMASK &&
sub->src.addr.type == PF_ADDR_ADDRMASK &&
super->src.neg == sub->src.neg &&
super->af == sub->af &&
unmask(&super->src.addr.v.a.mask, super->af) <
unmask(&sub->src.addr.v.a.mask, sub->af) &&
super->src.addr.v.a.addr.addr32[0] ==
(sub->src.addr.v.a.addr.addr32[0] &
super->src.addr.v.a.mask.addr32[0]) &&
super->src.addr.v.a.addr.addr32[1] ==
(sub->src.addr.v.a.addr.addr32[1] &
super->src.addr.v.a.mask.addr32[1]) &&
super->src.addr.v.a.addr.addr32[2] ==
(sub->src.addr.v.a.addr.addr32[2] &
super->src.addr.v.a.mask.addr32[2]) &&
super->src.addr.v.a.addr.addr32[3] ==
(sub->src.addr.v.a.addr.addr32[3] &
super->src.addr.v.a.mask.addr32[3])) {
/* sub->src.addr is a subset of super->src.addr/mask */
memcpy(&sub->src.addr, &super->src.addr, sizeof(sub->src.addr));
}
if (super->dst.addr.type == PF_ADDR_ADDRMASK && !super->dst.neg &&
!sub->dst.neg && super->dst.addr.v.a.mask.addr32[0] == 0 &&
super->dst.addr.v.a.mask.addr32[1] == 0 &&
super->dst.addr.v.a.mask.addr32[2] == 0 &&
super->dst.addr.v.a.mask.addr32[3] == 0)
memset(&sub->dst.addr, 0, sizeof(sub->dst.addr));
else if (super->dst.addr.type == PF_ADDR_ADDRMASK &&
sub->dst.addr.type == PF_ADDR_ADDRMASK &&
super->dst.neg == sub->dst.neg &&
super->af == sub->af &&
unmask(&super->dst.addr.v.a.mask, super->af) <
unmask(&sub->dst.addr.v.a.mask, sub->af) &&
super->dst.addr.v.a.addr.addr32[0] ==
(sub->dst.addr.v.a.addr.addr32[0] &
super->dst.addr.v.a.mask.addr32[0]) &&
super->dst.addr.v.a.addr.addr32[1] ==
(sub->dst.addr.v.a.addr.addr32[1] &
super->dst.addr.v.a.mask.addr32[1]) &&
super->dst.addr.v.a.addr.addr32[2] ==
(sub->dst.addr.v.a.addr.addr32[2] &
super->dst.addr.v.a.mask.addr32[2]) &&
super->dst.addr.v.a.addr.addr32[3] ==
(sub->dst.addr.v.a.addr.addr32[3] &
super->dst.addr.v.a.mask.addr32[3])) {
/* sub->dst.addr is a subset of super->dst.addr/mask */
memcpy(&sub->dst.addr, &super->dst.addr, sizeof(sub->dst.addr));
}
if (super->af == 0)
sub->af = 0;
}
void
superblock_free(struct pfctl *pf, struct superblock *block)
{
struct pf_opt_rule *por;
while ((por = TAILQ_FIRST(&block->sb_rules))) {
TAILQ_REMOVE(&block->sb_rules, por, por_entry);
if (por->por_src_tbl) {
if (por->por_src_tbl->pt_buf) {
pfr_buf_clear(por->por_src_tbl->pt_buf);
free(por->por_src_tbl->pt_buf);
}
free(por->por_src_tbl);
}
if (por->por_dst_tbl) {
if (por->por_dst_tbl->pt_buf) {
pfr_buf_clear(por->por_dst_tbl->pt_buf);
free(por->por_dst_tbl->pt_buf);
}
free(por->por_dst_tbl);
}
free(por);
}
if (block->sb_profiled_block)
superblock_free(pf, block->sb_profiled_block);
free(block);
}