net/npf/npf_ruleset.c

 1.1     rmind /*-
1.41     rmind  * Copyright (c) 2009-2015 The NetBSD Foundation, Inc.
 1.1     rmind  * All rights reserved.
 1.1     rmind  *
 1.1     rmind  * This material is based upon work partially supported by The
 1.1     rmind  * NetBSD Foundation under a contract with Mindaugas Rasiukevicius.
 1.1     rmind  *
 1.1     rmind  * Redistribution and use in source and binary forms, with or without
 1.1     rmind  * modification, are permitted provided that the following conditions
 1.1     rmind  * are met:
 1.1     rmind  * 1. Redistributions of source code must retain the above copyright
 1.1     rmind  *    notice, this list of conditions and the following disclaimer.
 1.1     rmind  * 2. Redistributions in binary form must reproduce the above copyright
 1.1     rmind  *    notice, this list of conditions and the following disclaimer in the
 1.1     rmind  *    documentation and/or other materials provided with the distribution.
 1.1     rmind  *
 1.1     rmind  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.1     rmind  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.1     rmind  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.1     rmind  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.1     rmind  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1     rmind  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1     rmind  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1     rmind  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1     rmind  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1     rmind  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1     rmind  * POSSIBILITY OF SUCH DAMAGE.
 1.1     rmind  */
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * NPF ruleset module.
 1.1     rmind  */
 1.1     rmind
1.43  christos #ifdef _KERNEL
 1.1     rmind #include <sys/cdefs.h>
1.47     rmind __KERNEL_RCSID(0, "$NetBSD: npf_ruleset.c,v 1.47 2018/09/29 14:41:36 rmind Exp $");
 1.1     rmind
 1.1     rmind #include <sys/param.h>
1.11     rmind #include <sys/types.h>
 1.1     rmind
1.20     rmind #include <sys/atomic.h>
 1.1     rmind #include <sys/kmem.h>
 1.1     rmind #include <sys/queue.h>
1.17     rmind #include <sys/mbuf.h>
 1.1     rmind #include <sys/types.h>
 1.1     rmind
1.17     rmind #include <net/bpf.h>
1.20     rmind #include <net/bpfjit.h>
 1.3     rmind #include <net/pfil.h>
 1.1     rmind #include <net/if.h>
1.43  christos #endif
 1.1     rmind
 1.1     rmind #include "npf_impl.h"
 1.1     rmind
 1.4     rmind struct npf_ruleset {
1.18     rmind 	/*
1.18     rmind 	 * - List of all rules.
1.18     rmind 	 * - Dynamic (i.e. named) rules.
1.18     rmind 	 * - G/C list for convenience.
1.18     rmind 	 */
1.17     rmind 	LIST_HEAD(, npf_rule)	rs_all;
1.17     rmind 	LIST_HEAD(, npf_rule)	rs_dynamic;
1.18     rmind 	LIST_HEAD(, npf_rule)	rs_gc;
1.17     rmind
1.19     rmind 	/* Unique ID counter. */
1.19     rmind 	uint64_t		rs_idcnt;
1.19     rmind
1.17     rmind 	/* Number of array slots and active rules. */
1.17     rmind 	u_int			rs_slots;
1.17     rmind 	u_int			rs_nitems;
1.17     rmind
1.17     rmind 	/* Array of ordered rules. */
1.17     rmind 	npf_rule_t *		rs_rules[];
 1.4     rmind };
 1.4     rmind
 1.1     rmind struct npf_rule {
1.17     rmind 	/* Attributes, interface and skip slot. */
 1.4     rmind 	uint32_t		r_attr;
 1.4     rmind 	u_int			r_ifid;
1.17     rmind 	u_int			r_skip_to;
1.17     rmind
1.17     rmind 	/* Code to process, if any. */
1.17     rmind 	int			r_type;
1.27     rmind 	bpfjit_func_t		r_jcode;
1.17     rmind 	void *			r_code;
1.36     rmind 	u_int			r_clen;
1.17     rmind
1.17     rmind 	/* NAT policy (optional), rule procedure and subset. */
1.17     rmind 	npf_natpolicy_t *	r_natp;
 1.4     rmind 	npf_rproc_t *		r_rproc;
1.17     rmind
1.42     rmind 	union {
1.42     rmind 		/*
1.42     rmind 		 * Dynamic group: rule subset and a group list entry.
1.42     rmind 		 */
1.42     rmind 		struct {
1.42     rmind 			npf_rule_t *		r_subset;
1.42     rmind 			LIST_ENTRY(npf_rule)	r_dentry;
1.42     rmind 		};
1.17     rmind
1.42     rmind 		/*
1.42     rmind 		 * Dynamic rule: priority, parent group and next rule.
1.42     rmind 		 */
1.42     rmind 		struct {
1.42     rmind 			int			r_priority;
1.42     rmind 			npf_rule_t *		r_parent;
1.42     rmind 			npf_rule_t *		r_next;
1.42     rmind 		};
1.42     rmind 	};
1.17     rmind
1.36     rmind 	/* Rule ID, name and the optional key. */
1.19     rmind 	uint64_t		r_id;
1.36     rmind 	char			r_name[NPF_RULE_MAXNAMELEN];
1.36     rmind 	uint8_t			r_key[NPF_RULE_MAXKEYLEN];
1.18     rmind
1.36     rmind 	/* All-list entry and the auxiliary info. */
1.17     rmind 	LIST_ENTRY(npf_rule)	r_aentry;
1.47     rmind 	nvlist_t *		r_info;
1.47     rmind 	size_t			r_info_len;
1.36     rmind };
1.17     rmind
1.37     rmind #define	SKIPTO_ADJ_FLAG		(1U << 31)
1.37     rmind #define	SKIPTO_MASK		(SKIPTO_ADJ_FLAG - 1)
1.37     rmind
1.47     rmind static nvlist_t *	npf_rule_export(npf_t *, const npf_rule_t *);
 1.1     rmind
1.31     rmind /*
1.31     rmind  * Private attributes - must be in the NPF_RULE_PRIVMASK range.
1.31     rmind  */
1.31     rmind #define	NPF_RULE_KEEPNAT	(0x01000000 & NPF_RULE_PRIVMASK)
1.31     rmind
1.17     rmind #define	NPF_DYNAMIC_GROUP_P(attr) \
1.17     rmind     (((attr) & NPF_DYNAMIC_GROUP) == NPF_DYNAMIC_GROUP)
1.17     rmind
1.19     rmind #define	NPF_DYNAMIC_RULE_P(attr) \
1.19     rmind     (((attr) & NPF_DYNAMIC_GROUP) == NPF_RULE_DYNAMIC)
1.19     rmind
 1.1     rmind npf_ruleset_t *
1.17     rmind npf_ruleset_create(size_t slots)
 1.1     rmind {
1.17     rmind 	size_t len = offsetof(npf_ruleset_t, rs_rules[slots]);
 1.1     rmind 	npf_ruleset_t *rlset;
 1.1     rmind
1.17     rmind 	rlset = kmem_zalloc(len, KM_SLEEP);
1.17     rmind 	LIST_INIT(&rlset->rs_dynamic);
1.17     rmind 	LIST_INIT(&rlset->rs_all);
1.19     rmind 	LIST_INIT(&rlset->rs_gc);
1.19     rmind 	rlset->rs_slots = slots;
1.19     rmind
 1.1     rmind 	return rlset;
 1.1     rmind }
 1.1     rmind
 1.1     rmind void
 1.1     rmind npf_ruleset_destroy(npf_ruleset_t *rlset)
 1.1     rmind {
1.17     rmind 	size_t len = offsetof(npf_ruleset_t, rs_rules[rlset->rs_slots]);
 1.1     rmind 	npf_rule_t *rl;
 1.1     rmind
1.17     rmind 	while ((rl = LIST_FIRST(&rlset->rs_all)) != NULL) {
1.42     rmind 		if (NPF_DYNAMIC_GROUP_P(rl->r_attr)) {
1.42     rmind 			/*
1.42     rmind 			 * Note: r_subset may point to the rules which
1.42     rmind 			 * were inherited by a new ruleset.
1.42     rmind 			 */
1.42     rmind 			rl->r_subset = NULL;
1.42     rmind 			LIST_REMOVE(rl, r_dentry);
1.42     rmind 		}
1.42     rmind 		if (NPF_DYNAMIC_RULE_P(rl->r_attr)) {
1.42     rmind 			/* Not removing from r_subset, see above. */
1.42     rmind 			KASSERT(rl->r_parent != NULL);
1.42     rmind 		}
1.42     rmind 		LIST_REMOVE(rl, r_aentry);
 1.1     rmind 		npf_rule_free(rl);
 1.1     rmind 	}
1.17     rmind 	KASSERT(LIST_EMPTY(&rlset->rs_dynamic));
1.43  christos
1.43  christos 	npf_ruleset_gc(rlset);
1.18     rmind 	KASSERT(LIST_EMPTY(&rlset->rs_gc));
1.17     rmind 	kmem_free(rlset, len);
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * npf_ruleset_insert: insert the rule into the specified ruleset.
 1.1     rmind  */
 1.1     rmind void
 1.1     rmind npf_ruleset_insert(npf_ruleset_t *rlset, npf_rule_t *rl)
 1.1     rmind {
1.17     rmind 	u_int n = rlset->rs_nitems;
1.17     rmind
1.17     rmind 	KASSERT(n < rlset->rs_slots);
1.17     rmind
1.17     rmind 	LIST_INSERT_HEAD(&rlset->rs_all, rl, r_aentry);
1.17     rmind 	if (NPF_DYNAMIC_GROUP_P(rl->r_attr)) {
1.17     rmind 		LIST_INSERT_HEAD(&rlset->rs_dynamic, rl, r_dentry);
1.24     rmind 	} else {
1.24     rmind 		KASSERTMSG(rl->r_parent == NULL, "cannot be dynamic rule");
1.24     rmind 		rl->r_attr &= ~NPF_RULE_DYNAMIC;
1.17     rmind 	}
1.17     rmind
1.17     rmind 	rlset->rs_rules[n] = rl;
1.17     rmind 	rlset->rs_nitems++;
1.45  christos 	rl->r_id = ++rlset->rs_idcnt;
1.17     rmind
1.17     rmind 	if (rl->r_skip_to < ++n) {
1.37     rmind 		rl->r_skip_to = SKIPTO_ADJ_FLAG | n;
1.17     rmind 	}
1.17     rmind }
1.17     rmind
1.46     rmind npf_rule_t *
1.17     rmind npf_ruleset_lookup(npf_ruleset_t *rlset, const char *name)
1.17     rmind {
1.17     rmind 	npf_rule_t *rl;
1.17     rmind
1.17     rmind 	LIST_FOREACH(rl, &rlset->rs_dynamic, r_dentry) {
1.17     rmind 		KASSERT(NPF_DYNAMIC_GROUP_P(rl->r_attr));
1.17     rmind 		if (strncmp(rl->r_name, name, NPF_RULE_MAXNAMELEN) == 0)
1.17     rmind 			break;
1.17     rmind 	}
1.17     rmind 	return rl;
1.17     rmind }
1.17     rmind
1.39     rmind /*
1.39     rmind  * npf_ruleset_add: insert dynamic rule into the (active) ruleset.
1.39     rmind  */
1.17     rmind int
1.17     rmind npf_ruleset_add(npf_ruleset_t *rlset, const char *rname, npf_rule_t *rl)
1.17     rmind {
1.42     rmind 	npf_rule_t *rg, *it, *target;
1.42     rmind 	int priocmd;
1.17     rmind
1.42     rmind 	if (!NPF_DYNAMIC_RULE_P(rl->r_attr)) {
1.42     rmind 		return EINVAL;
1.42     rmind 	}
1.17     rmind 	rg = npf_ruleset_lookup(rlset, rname);
1.17     rmind 	if (rg == NULL) {
1.19     rmind 		return ESRCH;
1.19     rmind 	}
1.17     rmind
1.19     rmind 	/* Dynamic rule - assign a unique ID and save the parent. */
1.19     rmind 	rl->r_id = ++rlset->rs_idcnt;
1.17     rmind 	rl->r_parent = rg;
1.17     rmind
1.17     rmind 	/*
1.17     rmind 	 * Rule priority: (highest) 1, 2 ... n (lowest).
1.17     rmind 	 * Negative priority indicates an operation and is reset to zero.
1.17     rmind 	 */
1.17     rmind 	if ((priocmd = rl->r_priority) < 0) {
1.17     rmind 		rl->r_priority = 0;
1.17     rmind 	}
1.17     rmind
1.42     rmind 	/*
1.42     rmind 	 * WARNING: once rg->subset or target->r_next of an *active*
1.42     rmind 	 * rule is set, then our rule becomes globally visible and active.
1.42     rmind 	 * Must issue a load fence to ensure rl->r_next visibility first.
1.42     rmind 	 */
1.17     rmind 	switch (priocmd) {
1.17     rmind 	case NPF_PRI_LAST:
1.17     rmind 	default:
1.42     rmind 		target = NULL;
1.42     rmind 		it = rg->r_subset;
1.42     rmind 		while (it && it->r_priority <= rl->r_priority) {
1.42     rmind 			target = it;
1.42     rmind 			it = it->r_next;
1.42     rmind 		}
1.42     rmind 		if (target) {
1.42     rmind 			rl->r_next = target->r_next;
1.42     rmind 			membar_producer();
1.42     rmind 			target->r_next = rl;
1.42     rmind 			break;
1.17     rmind 		}
1.42     rmind 		/* FALLTHROUGH */
1.42     rmind
1.42     rmind 	case NPF_PRI_FIRST:
1.42     rmind 		rl->r_next = rg->r_subset;
1.42     rmind 		membar_producer();
1.42     rmind 		rg->r_subset = rl;
1.17     rmind 		break;
1.17     rmind 	}
1.17     rmind
1.17     rmind 	/* Finally, add into the all-list. */
1.17     rmind 	LIST_INSERT_HEAD(&rlset->rs_all, rl, r_aentry);
1.17     rmind 	return 0;
1.17     rmind }
1.17     rmind
1.42     rmind static void
1.42     rmind npf_ruleset_unlink(npf_rule_t *rl, npf_rule_t *prev)
1.42     rmind {
1.42     rmind 	KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr));
1.42     rmind 	if (prev) {
1.42     rmind 		prev->r_next = rl->r_next;
1.42     rmind 	} else {
1.42     rmind 		npf_rule_t *rg = rl->r_parent;
1.42     rmind 		rg->r_subset = rl->r_next;
1.42     rmind 	}
1.42     rmind 	LIST_REMOVE(rl, r_aentry);
1.42     rmind }
1.42     rmind
1.39     rmind /*
1.39     rmind  * npf_ruleset_remove: remove the dynamic rule given the rule ID.
1.39     rmind  */
1.18     rmind int
1.19     rmind npf_ruleset_remove(npf_ruleset_t *rlset, const char *rname, uint64_t id)
1.17     rmind {
1.42     rmind 	npf_rule_t *rg, *prev = NULL;
1.17     rmind
1.17     rmind 	if ((rg = npf_ruleset_lookup(rlset, rname)) == NULL) {
1.19     rmind 		return ESRCH;
1.17     rmind 	}
1.42     rmind 	for (npf_rule_t *rl = rg->r_subset; rl; rl = rl->r_next) {
1.24     rmind 		KASSERT(rl->r_parent == rg);
1.42     rmind 		KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr));
1.24     rmind
1.17     rmind 		/* Compare ID.  On match, remove and return. */
1.19     rmind 		if (rl->r_id == id) {
1.42     rmind 			npf_ruleset_unlink(rl, prev);
1.18     rmind 			LIST_INSERT_HEAD(&rlset->rs_gc, rl, r_aentry);
1.19     rmind 			return 0;
1.17     rmind 		}
1.42     rmind 		prev = rl;
1.17     rmind 	}
1.19     rmind 	return ENOENT;
1.17     rmind }
1.17     rmind
1.39     rmind /*
1.39     rmind  * npf_ruleset_remkey: remove the dynamic rule given the rule key.
1.39     rmind  */
1.18     rmind int
1.17     rmind npf_ruleset_remkey(npf_ruleset_t *rlset, const char *rname,
1.17     rmind     const void *key, size_t len)
1.17     rmind {
1.42     rmind 	npf_rule_t *rg, *rlast = NULL, *prev = NULL, *lastprev = NULL;
 1.1     rmind
1.17     rmind 	KASSERT(len && len <= NPF_RULE_MAXKEYLEN);
1.17     rmind
1.17     rmind 	if ((rg = npf_ruleset_lookup(rlset, rname)) == NULL) {
1.19     rmind 		return ESRCH;
1.17     rmind 	}
1.18     rmind
1.42     rmind 	/* Compare the key and find the last in the list. */
1.42     rmind 	for (npf_rule_t *rl = rg->r_subset; rl; rl = rl->r_next) {
1.24     rmind 		KASSERT(rl->r_parent == rg);
1.42     rmind 		KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr));
1.17     rmind 		if (memcmp(rl->r_key, key, len) == 0) {
1.42     rmind 			lastprev = prev;
1.42     rmind 			rlast = rl;
1.17     rmind 		}
1.42     rmind 		prev = rl;
1.42     rmind 	}
1.42     rmind 	if (!rlast) {
1.42     rmind 		return ENOENT;
 1.1     rmind 	}
1.42     rmind 	npf_ruleset_unlink(rlast, lastprev);
1.42     rmind 	LIST_INSERT_HEAD(&rlset->rs_gc, rlast, r_aentry);
1.42     rmind 	return 0;
1.18     rmind }
1.18     rmind
1.39     rmind /*
1.39     rmind  * npf_ruleset_list: serialise and return the dynamic rules.
1.39     rmind  */
1.47     rmind nvlist_t *
1.43  christos npf_ruleset_list(npf_t *npf, npf_ruleset_t *rlset, const char *rname)
1.18     rmind {
1.47     rmind 	nvlist_t *rgroup;
1.42     rmind 	npf_rule_t *rg;
1.18     rmind
1.43  christos 	KASSERT(npf_config_locked_p(npf));
1.36     rmind
1.18     rmind 	if ((rg = npf_ruleset_lookup(rlset, rname)) == NULL) {
1.18     rmind 		return NULL;
1.18     rmind 	}
1.47     rmind 	if ((rgroup = nvlist_create(0)) == NULL) {
1.18     rmind 		return NULL;
1.18     rmind 	}
1.42     rmind 	for (npf_rule_t *rl = rg->r_subset; rl; rl = rl->r_next) {
1.47     rmind 		nvlist_t *rule;
1.36     rmind
1.24     rmind 		KASSERT(rl->r_parent == rg);
1.42     rmind 		KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr));
1.36     rmind
1.47     rmind 		rule = npf_rule_export(npf, rl);
1.47     rmind 		if (!rule) {
1.47     rmind 			nvlist_destroy(rgroup);
1.18     rmind 			return NULL;
1.18     rmind 		}
1.47     rmind 		nvlist_append_nvlist_array(rgroup, "rules", rule);
1.47     rmind 		nvlist_destroy(rule);
1.18     rmind 	}
1.47     rmind 	return rgroup;
1.18     rmind }
1.18     rmind
1.39     rmind /*
1.39     rmind  * npf_ruleset_flush: flush the dynamic rules in the ruleset by inserting
1.39     rmind  * them into the G/C list.
1.39     rmind  */
1.18     rmind int
1.18     rmind npf_ruleset_flush(npf_ruleset_t *rlset, const char *rname)
1.18     rmind {
1.18     rmind 	npf_rule_t *rg, *rl;
1.18     rmind
1.18     rmind 	if ((rg = npf_ruleset_lookup(rlset, rname)) == NULL) {
1.19     rmind 		return ESRCH;
1.18     rmind 	}
1.42     rmind
1.42     rmind 	rl = atomic_swap_ptr(&rg->r_subset, NULL);
1.42     rmind 	membar_producer();
1.42     rmind
1.42     rmind 	while (rl) {
1.42     rmind 		KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr));
1.24     rmind 		KASSERT(rl->r_parent == rg);
1.42     rmind
1.42     rmind 		LIST_REMOVE(rl, r_aentry);
1.18     rmind 		LIST_INSERT_HEAD(&rlset->rs_gc, rl, r_aentry);
1.42     rmind 		rl = rl->r_next;
1.18     rmind 	}
1.45  christos 	rlset->rs_idcnt = 0;
1.18     rmind 	return 0;
1.18     rmind }
1.18     rmind
1.39     rmind /*
1.39     rmind  * npf_ruleset_gc: destroy the rules in G/C list.
1.39     rmind  */
1.39     rmind void
1.39     rmind npf_ruleset_gc(npf_ruleset_t *rlset)
1.39     rmind {
1.39     rmind 	npf_rule_t *rl;
1.39     rmind
1.39     rmind 	while ((rl = LIST_FIRST(&rlset->rs_gc)) != NULL) {
1.39     rmind 		LIST_REMOVE(rl, r_aentry);
1.39     rmind 		npf_rule_free(rl);
1.39     rmind 	}
1.39     rmind }
1.39     rmind
1.39     rmind /*
1.39     rmind  * npf_ruleset_export: serialise and return the static rules.
1.39     rmind  */
1.36     rmind int
1.47     rmind npf_ruleset_export(npf_t *npf, const npf_ruleset_t *rlset,
1.47     rmind     const char *key, nvlist_t *npf_dict)
1.36     rmind {
1.47     rmind 	const unsigned nitems = rlset->rs_nitems;
1.47     rmind 	unsigned n = 0;
1.36     rmind 	int error = 0;
1.36     rmind
1.43  christos 	KASSERT(npf_config_locked_p(npf));
1.36     rmind
1.37     rmind 	while (n < nitems) {
1.37     rmind 		const npf_rule_t *rl = rlset->rs_rules[n];
1.36     rmind 		const npf_natpolicy_t *natp = rl->r_natp;
1.47     rmind 		nvlist_t *rule;
1.36     rmind
1.47     rmind 		rule = npf_rule_export(npf, rl);
1.47     rmind 		if (!rule) {
1.47     rmind 			error = ENOMEM;
1.36     rmind 			break;
1.36     rmind 		}
1.47     rmind 		if (natp && (error = npf_nat_policyexport(natp, rule)) != 0) {
1.47     rmind 			nvlist_destroy(rule);
1.36     rmind 			break;
1.36     rmind 		}
1.47     rmind 		nvlist_append_nvlist_array(npf_dict, key, rule);
1.47     rmind 		nvlist_destroy(rule);
1.37     rmind 		n++;
1.36     rmind 	}
1.36     rmind 	return error;
1.36     rmind }
1.36     rmind
1.17     rmind /*
1.31     rmind  * npf_ruleset_reload: prepare the new ruleset by scanning the active
1.39     rmind  * ruleset and: 1) sharing the dynamic rules 2) sharing NAT policies.
1.17     rmind  *
1.31     rmind  * => The active (old) ruleset should be exclusively locked.
1.17     rmind  */
1.17     rmind void
1.43  christos npf_ruleset_reload(npf_t *npf, npf_ruleset_t *newset,
1.43  christos     npf_ruleset_t *oldset, bool load)
1.17     rmind {
1.31     rmind 	npf_rule_t *rg, *rl;
1.35     rmind 	uint64_t nid = 0;
1.17     rmind
1.43  christos 	KASSERT(npf_config_locked_p(npf));
1.17     rmind
1.31     rmind 	/*
1.31     rmind 	 * Scan the dynamic rules and share (migrate) if needed.
1.31     rmind 	 */
1.31     rmind 	LIST_FOREACH(rg, &newset->rs_dynamic, r_dentry) {
1.42     rmind 		npf_rule_t *active_rgroup;
1.18     rmind
1.31     rmind 		/* Look for a dynamic ruleset group with such name. */
1.42     rmind 		active_rgroup = npf_ruleset_lookup(oldset, rg->r_name);
1.42     rmind 		if (active_rgroup == NULL) {
1.17     rmind 			continue;
1.17     rmind 		}
1.18     rmind
1.18     rmind 		/*
1.42     rmind 		 * ATOMICITY: Copy the head pointer of the linked-list,
1.42     rmind 		 * but do not remove the rules from the active r_subset.
1.42     rmind 		 * This is necessary because the rules are still active
1.42     rmind 		 * and therefore are accessible for inspection via the
1.42     rmind 		 * old ruleset.
1.18     rmind 		 */
1.42     rmind 		rg->r_subset = active_rgroup->r_subset;
1.42     rmind
1.42     rmind 		/*
1.42     rmind 		 * We can safely migrate to the new all-rule list and
1.42     rmind 		 * reset the parent rule, though.
1.42     rmind 		 */
1.42     rmind 		for (rl = rg->r_subset; rl; rl = rl->r_next) {
1.42     rmind 			KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr));
1.18     rmind 			LIST_REMOVE(rl, r_aentry);
1.31     rmind 			LIST_INSERT_HEAD(&newset->rs_all, rl, r_aentry);
1.42     rmind
1.42     rmind 			KASSERT(rl->r_parent == active_rgroup);
1.19     rmind 			rl->r_parent = rg;
1.18     rmind 		}
 1.1     rmind 	}
1.19     rmind
1.31     rmind 	/*
1.40     rmind 	 * If performing the load of connections then NAT policies may
1.40     rmind 	 * already have translated connections associated with them and
1.40     rmind 	 * we should not share or inherit anything.
1.40     rmind 	 */
1.40     rmind 	if (load)
1.40     rmind 		return;
1.40     rmind
1.40     rmind 	/*
1.31     rmind 	 * Scan all rules in the new ruleset and share NAT policies.
1.35     rmind 	 * Also, assign a unique ID for each policy here.
1.31     rmind 	 */
1.31     rmind 	LIST_FOREACH(rl, &newset->rs_all, r_aentry) {
1.31     rmind 		npf_natpolicy_t *np;
1.31     rmind 		npf_rule_t *actrl;
1.31     rmind
1.31     rmind 		/* Does the rule have a NAT policy associated? */
1.31     rmind 		if ((np = rl->r_natp) == NULL) {
1.31     rmind 			continue;
1.31     rmind 		}
1.35     rmind
1.38     rmind 		/*
1.38     rmind 		 * First, try to share the active port map.  If this
1.38     rmind 		 * policy will be unused, npf_nat_freepolicy() will
1.38     rmind 		 * drop the reference.
1.38     rmind 		 */
1.38     rmind 		npf_ruleset_sharepm(oldset, np);
1.38     rmind
1.31     rmind 		/* Does it match with any policy in the active ruleset? */
1.38     rmind 		LIST_FOREACH(actrl, &oldset->rs_all, r_aentry) {
1.38     rmind 			if (!actrl->r_natp)
1.38     rmind 				continue;
1.38     rmind 			if ((actrl->r_attr & NPF_RULE_KEEPNAT) != 0)
1.38     rmind 				continue;
1.38     rmind 			if (npf_nat_cmppolicy(actrl->r_natp, np))
1.38     rmind 				break;
1.38     rmind 		}
1.38     rmind 		if (!actrl) {
1.38     rmind 			/* No: just set the ID and continue. */
1.35     rmind 			npf_nat_setid(np, ++nid);
1.31     rmind 			continue;
1.31     rmind 		}
1.31     rmind
1.38     rmind 		/* Yes: inherit the matching NAT policy. */
1.31     rmind 		rl->r_natp = actrl->r_natp;
1.35     rmind 		npf_nat_setid(rl->r_natp, ++nid);
1.31     rmind
1.31     rmind 		/*
1.31     rmind 		 * Finally, mark the active rule to not destroy its NAT
1.31     rmind 		 * policy later as we inherited it (but the rule must be
1.31     rmind 		 * kept active for now).  Destroy the new/unused policy.
1.31     rmind 		 */
1.31     rmind 		actrl->r_attr |= NPF_RULE_KEEPNAT;
1.31     rmind 		npf_nat_freepolicy(np);
1.31     rmind 	}
1.31     rmind
1.19     rmind 	/* Inherit the ID counter. */
1.31     rmind 	newset->rs_idcnt = oldset->rs_idcnt;
 1.1     rmind }
 1.1     rmind
1.39     rmind /*
1.39     rmind  * npf_ruleset_sharepm: attempt to share the active NAT portmap.
1.39     rmind  */
 1.6     rmind npf_rule_t *
 1.6     rmind npf_ruleset_sharepm(npf_ruleset_t *rlset, npf_natpolicy_t *mnp)
 1.6     rmind {
 1.6     rmind 	npf_natpolicy_t *np;
 1.6     rmind 	npf_rule_t *rl;
 1.6     rmind
1.39     rmind 	/*
1.39     rmind 	 * Scan the NAT policies in the ruleset and match with the
1.39     rmind 	 * given policy based on the translation IP address.  If they
1.39     rmind 	 * match - adjust the given NAT policy to use the active NAT
1.39     rmind 	 * portmap.  In such case the reference on the old portmap is
1.39     rmind 	 * dropped and acquired on the active one.
1.39     rmind 	 */
1.17     rmind 	LIST_FOREACH(rl, &rlset->rs_all, r_aentry) {
 1.6     rmind 		np = rl->r_natp;
 1.6     rmind 		if (np == NULL || np == mnp)
 1.6     rmind 			continue;
 1.6     rmind 		if (npf_nat_sharepm(np, mnp))
 1.6     rmind 			break;
 1.6     rmind 	}
 1.6     rmind 	return rl;
 1.6     rmind }
 1.6     rmind
1.35     rmind npf_natpolicy_t *
1.35     rmind npf_ruleset_findnat(npf_ruleset_t *rlset, uint64_t id)
1.35     rmind {
1.35     rmind 	npf_rule_t *rl;
1.35     rmind
1.35     rmind 	LIST_FOREACH(rl, &rlset->rs_all, r_aentry) {
1.35     rmind 		npf_natpolicy_t *np = rl->r_natp;
1.35     rmind 		if (np && npf_nat_getid(np) == id) {
1.35     rmind 			return np;
1.35     rmind 		}
1.35     rmind 	}
1.35     rmind 	return NULL;
1.35     rmind }
1.35     rmind
 1.1     rmind /*
1.13     rmind  * npf_ruleset_freealg: inspect the ruleset and disassociate specified
1.13     rmind  * ALG from all NAT entries using it.
1.13     rmind  */
1.13     rmind void
1.13     rmind npf_ruleset_freealg(npf_ruleset_t *rlset, npf_alg_t *alg)
1.13     rmind {
1.13     rmind 	npf_rule_t *rl;
1.17     rmind 	npf_natpolicy_t *np;
1.13     rmind
1.17     rmind 	LIST_FOREACH(rl, &rlset->rs_all, r_aentry) {
1.17     rmind 		if ((np = rl->r_natp) != NULL) {
1.13     rmind 			npf_nat_freealg(np, alg);
1.13     rmind 		}
1.13     rmind 	}
1.13     rmind }
1.13     rmind
1.13     rmind /*
1.25     rmind  * npf_rule_alloc: allocate a rule and initialise it.
 1.1     rmind  */
 1.4     rmind npf_rule_t *
1.47     rmind npf_rule_alloc(npf_t *npf, const nvlist_t *rule)
 1.1     rmind {
 1.4     rmind 	npf_rule_t *rl;
 1.7     rmind 	const char *rname;
1.47     rmind 	const void *key, *info;
1.47     rmind 	size_t len;
 1.1     rmind
1.47     rmind 	/* Allocate a rule structure and keep the information. */
1.11     rmind 	rl = kmem_zalloc(sizeof(npf_rule_t), KM_SLEEP);
1.47     rmind 	info = dnvlist_get_binary(rule, "info", &rl->r_info_len, NULL, 0);
1.47     rmind 	if (info) {
1.47     rmind 		rl->r_info = kmem_alloc(rl->r_info_len, KM_SLEEP);
1.47     rmind 		memcpy(rl->r_info, info, rl->r_info_len);
1.47     rmind 	}
 1.4     rmind 	rl->r_natp = NULL;
 1.4     rmind
1.11     rmind 	/* Name (optional) */
1.47     rmind 	if ((rname = dnvlist_get_string(rule, "name", NULL)) != NULL) {
1.17     rmind 		strlcpy(rl->r_name, rname, NPF_RULE_MAXNAMELEN);
 1.7     rmind 	} else {
 1.7     rmind 		rl->r_name[0] = '\0';
 1.7     rmind 	}
 1.7     rmind
1.11     rmind 	/* Attributes, priority and interface ID (optional). */
1.47     rmind 	rl->r_attr = dnvlist_get_number(rule, "attr", 0);
1.31     rmind 	rl->r_attr &= ~NPF_RULE_PRIVMASK;
1.26     rmind
1.42     rmind 	if (NPF_DYNAMIC_RULE_P(rl->r_attr)) {
1.42     rmind 		/* Priority of the dynamic rule. */
1.47     rmind 		rl->r_priority = dnvlist_get_number(rule, "prio", 0);
1.42     rmind 	} else {
1.42     rmind 		/* The skip-to index.  No need to validate it. */
1.47     rmind 		rl->r_skip_to = dnvlist_get_number(rule, "skip-to", 0);
1.42     rmind 	}
1.42     rmind
1.42     rmind 	/* Interface name; register and get the npf-if-id. */
1.47     rmind 	if ((rname = dnvlist_get_string(rule, "ifname", NULL)) != NULL) {
1.43  christos 		if ((rl->r_ifid = npf_ifmap_register(npf, rname)) == 0) {
1.26     rmind 			kmem_free(rl, sizeof(npf_rule_t));
1.26     rmind 			return NULL;
1.26     rmind 		}
1.26     rmind 	} else {
1.26     rmind 		rl->r_ifid = 0;
1.26     rmind 	}
 1.4     rmind
1.17     rmind 	/* Key (optional). */
1.47     rmind 	if ((key = dnvlist_get_binary(rule, "key", &len, NULL, 0)) != NULL) {
1.17     rmind 		if (len > NPF_RULE_MAXKEYLEN) {
1.17     rmind 			kmem_free(rl, sizeof(npf_rule_t));
1.17     rmind 			return NULL;
1.17     rmind 		}
1.17     rmind 		memcpy(rl->r_key, key, len);
 1.4     rmind 	}
1.36     rmind 	return rl;
1.36     rmind }
1.36     rmind
1.47     rmind static nvlist_t *
1.47     rmind npf_rule_export(npf_t *npf, const npf_rule_t *rl)
1.36     rmind {
1.47     rmind 	nvlist_t *rule = nvlist_create(0);
1.47     rmind 	unsigned skip_to = 0;
1.47     rmind 	npf_rproc_t *rp;
1.36     rmind
1.47     rmind 	nvlist_add_number(rule, "attr", rl->r_attr);
1.47     rmind 	nvlist_add_number(rule, "prio", rl->r_priority);
1.37     rmind 	if ((rl->r_skip_to & SKIPTO_ADJ_FLAG) == 0) {
1.37     rmind 		skip_to = rl->r_skip_to & SKIPTO_MASK;
1.37     rmind 	}
1.47     rmind 	nvlist_add_number(rule, "skip-to", skip_to);
1.47     rmind 	nvlist_add_number(rule, "code-type", rl->r_type);
1.36     rmind 	if (rl->r_code) {
1.47     rmind 		nvlist_add_binary(rule, "code", rl->r_code, rl->r_clen);
1.36     rmind 	}
1.36     rmind 	if (rl->r_ifid) {
1.43  christos 		const char *ifname = npf_ifmap_getname(npf, rl->r_ifid);
1.47     rmind 		nvlist_add_string(rule, "ifname", ifname);
1.36     rmind 	}
1.47     rmind 	nvlist_add_number(rule, "id", rl->r_id);
1.36     rmind
1.36     rmind 	if (rl->r_name[0]) {
1.47     rmind 		nvlist_add_string(rule, "name", rl->r_name);
1.36     rmind 	}
1.19     rmind 	if (NPF_DYNAMIC_RULE_P(rl->r_attr)) {
1.47     rmind 		nvlist_add_binary(rule, "key", rl->r_key, NPF_RULE_MAXKEYLEN);
1.18     rmind 	}
1.37     rmind 	if (rl->r_info) {
1.47     rmind 		nvlist_add_binary(rule, "info", rl->r_info, rl->r_info_len);
1.37     rmind 	}
1.47     rmind 	if ((rp = npf_rule_getrproc(rl)) != NULL) {
1.47     rmind 		const char *rname = npf_rproc_getname(rp);
1.47     rmind 		nvlist_add_string(rule, "rproc", rname);
1.44  christos 		npf_rproc_release(rp);
1.44  christos 	}
1.47     rmind 	return rule;
1.17     rmind }
1.17     rmind
1.17     rmind /*
1.17     rmind  * npf_rule_setcode: assign filter code to the rule.
1.17     rmind  *
1.20     rmind  * => The code must be validated by the caller.
1.20     rmind  * => JIT compilation may be performed here.
1.17     rmind  */
1.17     rmind void
1.17     rmind npf_rule_setcode(npf_rule_t *rl, const int type, void *code, size_t size)
1.17     rmind {
1.25     rmind 	KASSERT(type == NPF_CODE_BPF);
1.28     rmind
1.28     rmind 	rl->r_type = type;
1.36     rmind 	rl->r_code = code;
1.36     rmind 	rl->r_clen = size;
1.36     rmind 	rl->r_jcode = npf_bpf_compile(code, size);
1.17     rmind }
1.17     rmind
1.17     rmind /*
1.17     rmind  * npf_rule_setrproc: assign a rule procedure and hold a reference on it.
1.17     rmind  */
1.17     rmind void
1.17     rmind npf_rule_setrproc(npf_rule_t *rl, npf_rproc_t *rp)
1.17     rmind {
1.17     rmind 	npf_rproc_acquire(rp);
 1.6     rmind 	rl->r_rproc = rp;
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
 1.1     rmind  * npf_rule_free: free the specified rule.
 1.1     rmind  */
 1.1     rmind void
 1.1     rmind npf_rule_free(npf_rule_t *rl)
 1.1     rmind {
 1.4     rmind 	npf_natpolicy_t *np = rl->r_natp;
 1.4     rmind 	npf_rproc_t *rp = rl->r_rproc;
 1.1     rmind
1.31     rmind 	if (np && (rl->r_attr & NPF_RULE_KEEPNAT) == 0) {
 1.4     rmind 		/* Free NAT policy. */
 1.4     rmind 		npf_nat_freepolicy(np);
 1.4     rmind 	}
 1.4     rmind 	if (rp) {
 1.6     rmind 		/* Release rule procedure. */
 1.4     rmind 		npf_rproc_release(rp);
 1.4     rmind 	}
1.17     rmind 	if (rl->r_code) {
1.20     rmind 		/* Free byte-code. */
1.17     rmind 		kmem_free(rl->r_code, rl->r_clen);
 1.1     rmind 	}
1.20     rmind 	if (rl->r_jcode) {
1.20     rmind 		/* Free JIT code. */
1.28     rmind 		bpf_jit_freecode(rl->r_jcode);
1.20     rmind 	}
1.36     rmind 	if (rl->r_info) {
1.47     rmind 		kmem_free(rl->r_info, rl->r_info_len);
1.18     rmind 	}
 1.4     rmind 	kmem_free(rl, sizeof(npf_rule_t));
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
1.19     rmind  * npf_rule_getid: return the unique ID of a rule.
1.10     rmind  * npf_rule_getrproc: acquire a reference and return rule procedure, if any.
 1.1     rmind  * npf_rule_getnat: get NAT policy assigned to the rule.
 1.1     rmind  */
 1.1     rmind
1.19     rmind uint64_t
1.19     rmind npf_rule_getid(const npf_rule_t *rl)
1.19     rmind {
1.19     rmind 	KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr));
1.19     rmind 	return rl->r_id;
1.19     rmind }
1.19     rmind
1.10     rmind npf_rproc_t *
1.30     rmind npf_rule_getrproc(const npf_rule_t *rl)
1.10     rmind {
1.10     rmind 	npf_rproc_t *rp = rl->r_rproc;
1.10     rmind
1.10     rmind 	if (rp) {
1.10     rmind 		npf_rproc_acquire(rp);
1.10     rmind 	}
1.10     rmind 	return rp;
1.10     rmind }
1.10     rmind
 1.1     rmind npf_natpolicy_t *
 1.1     rmind npf_rule_getnat(const npf_rule_t *rl)
 1.1     rmind {
 1.4     rmind 	return rl->r_natp;
 1.1     rmind }
 1.1     rmind
 1.4     rmind /*
 1.4     rmind  * npf_rule_setnat: assign NAT policy to the rule and insert into the
 1.4     rmind  * NAT policy list in the ruleset.
 1.4     rmind  */
 1.1     rmind void
 1.1     rmind npf_rule_setnat(npf_rule_t *rl, npf_natpolicy_t *np)
 1.1     rmind {
 1.4     rmind 	KASSERT(rl->r_natp == NULL);
 1.4     rmind 	rl->r_natp = np;
 1.1     rmind }
 1.1     rmind
1.17     rmind /*
1.17     rmind  * npf_rule_inspect: match the interface, direction and run the filter code.
1.29     rmind  * Returns true if rule matches and false otherwise.
1.17     rmind  */
1.17     rmind static inline bool
1.29     rmind npf_rule_inspect(const npf_rule_t *rl, bpf_args_t *bc_args,
1.29     rmind     const int di_mask, const u_int ifid)
1.17     rmind {
1.17     rmind 	/* Match the interface. */
1.29     rmind 	if (rl->r_ifid && rl->r_ifid != ifid) {
1.17     rmind 		return false;
1.17     rmind 	}
1.17     rmind
1.17     rmind 	/* Match the direction. */
1.17     rmind 	if ((rl->r_attr & NPF_RULE_DIMASK) != NPF_RULE_DIMASK) {
1.17     rmind 		if ((rl->r_attr & di_mask) == 0)
1.17     rmind 			return false;
1.17     rmind 	}
1.17     rmind
1.24     rmind 	/* Any code? */
1.36     rmind 	if (!rl->r_code) {
1.24     rmind 		KASSERT(rl->r_jcode == NULL);
1.17     rmind 		return true;
1.17     rmind 	}
1.25     rmind 	KASSERT(rl->r_type == NPF_CODE_BPF);
1.29     rmind 	return npf_bpf_filter(bc_args, rl->r_code, rl->r_jcode) != 0;
1.17     rmind }
1.17     rmind
1.17     rmind /*
1.17     rmind  * npf_rule_reinspect: re-inspect the dynamic rule by iterating its list.
1.17     rmind  * This is only for the dynamic rules.  Subrules cannot have nested rules.
1.17     rmind  */
1.42     rmind static inline npf_rule_t *
1.42     rmind npf_rule_reinspect(const npf_rule_t *rg, bpf_args_t *bc_args,
1.29     rmind     const int di_mask, const u_int ifid)
 1.7     rmind {
1.17     rmind 	npf_rule_t *final_rl = NULL, *rl;
1.17     rmind
1.42     rmind 	KASSERT(NPF_DYNAMIC_GROUP_P(rg->r_attr));
 1.7     rmind
1.42     rmind 	for (rl = rg->r_subset; rl; rl = rl->r_next) {
1.42     rmind 		KASSERT(!final_rl || rl->r_priority >= final_rl->r_priority);
1.29     rmind 		if (!npf_rule_inspect(rl, bc_args, di_mask, ifid)) {
 1.7     rmind 			continue;
1.17     rmind 		}
1.17     rmind 		if (rl->r_attr & NPF_RULE_FINAL) {
1.17     rmind 			return rl;
1.17     rmind 		}
1.17     rmind 		final_rl = rl;
 1.7     rmind 	}
1.17     rmind 	return final_rl;
 1.7     rmind }
 1.1     rmind
 1.1     rmind /*
 1.7     rmind  * npf_ruleset_inspect: inspect the packet against the given ruleset.
 1.1     rmind  *
1.25     rmind  * Loop through the rules in the set and run the byte-code of each rule
 1.7     rmind  * against the packet (nbuf chain).  If sub-ruleset is found, inspect it.
 1.1     rmind  */
 1.1     rmind npf_rule_t *
1.34     rmind npf_ruleset_inspect(npf_cache_t *npc, const npf_ruleset_t *rlset,
1.34     rmind     const int di, const int layer)
 1.1     rmind {
1.34     rmind 	nbuf_t *nbuf = npc->npc_nbuf;
 1.7     rmind 	const int di_mask = (di & PFIL_IN) ? NPF_RULE_IN : NPF_RULE_OUT;
1.17     rmind 	const u_int nitems = rlset->rs_nitems;
1.29     rmind 	const u_int ifid = nbuf->nb_ifid;
1.17     rmind 	npf_rule_t *final_rl = NULL;
1.29     rmind 	bpf_args_t bc_args;
1.17     rmind 	u_int n = 0;
 1.1     rmind
1.33     rmind 	KASSERT(((di & PFIL_IN) != 0) ^ ((di & PFIL_OUT) != 0));
1.29     rmind
1.33     rmind 	/*
1.33     rmind 	 * Prepare the external memory store and the arguments for
1.43  christos 	 * the BPF programs to be executed.  Reset mbuf before taking
1.43  christos 	 * any pointers for the BPF.
1.33     rmind 	 */
1.33     rmind 	uint32_t bc_words[NPF_BPF_NWORDS];
1.43  christos
1.43  christos 	nbuf_reset(nbuf);
1.34     rmind 	npf_bpf_prepare(npc, &bc_args, bc_words);
1.17     rmind
1.17     rmind 	while (n < nitems) {
1.17     rmind 		npf_rule_t *rl = rlset->rs_rules[n];
1.37     rmind 		const u_int skip_to = rl->r_skip_to & SKIPTO_MASK;
1.17     rmind 		const uint32_t attr = rl->r_attr;
1.17     rmind
1.16     rmind 		KASSERT(!nbuf_flag_p(nbuf, NBUF_DATAREF_RESET));
1.17     rmind 		KASSERT(n < skip_to);
 1.1     rmind
1.17     rmind 		/* Group is a barrier: return a matching if found any. */
1.17     rmind 		if ((attr & NPF_RULE_GROUP) != 0 && final_rl) {
1.17     rmind 			break;
1.17     rmind 		}
1.17     rmind
1.17     rmind 		/* Main inspection of the rule. */
1.29     rmind 		if (!npf_rule_inspect(rl, &bc_args, di_mask, ifid)) {
1.17     rmind 			n = skip_to;
 1.1     rmind 			continue;
 1.1     rmind 		}
1.17     rmind
1.17     rmind 		if (NPF_DYNAMIC_GROUP_P(attr)) {
1.17     rmind 			/*
1.17     rmind 			 * If this is a dynamic rule, re-inspect the subrules.
1.17     rmind 			 * If it has any matching rule, then it is final.
1.17     rmind 			 */
1.29     rmind 			rl = npf_rule_reinspect(rl, &bc_args, di_mask, ifid);
1.17     rmind 			if (rl != NULL) {
1.17     rmind 				final_rl = rl;
1.17     rmind 				break;
1.17     rmind 			}
1.17     rmind 		} else if ((attr & NPF_RULE_GROUP) == 0) {
1.17     rmind 			/*
1.17     rmind 			 * Groups themselves are not matching.
1.17     rmind 			 */
1.17     rmind 			final_rl = rl;
 1.1     rmind 		}
1.17     rmind
 1.1     rmind 		/* Set the matching rule and check for "final". */
1.17     rmind 		if (attr & NPF_RULE_FINAL) {
 1.2     rmind 			break;
 1.1     rmind 		}
1.17     rmind 		n++;
 1.2     rmind 	}
1.16     rmind
1.16     rmind 	KASSERT(!nbuf_flag_p(nbuf, NBUF_DATAREF_RESET));
 1.7     rmind 	return final_rl;
 1.1     rmind }
 1.1     rmind
 1.1     rmind /*
1.17     rmind  * npf_rule_conclude: return decision and the flags for conclusion.
 1.1     rmind  *
 1.1     rmind  * => Returns ENETUNREACH if "block" and 0 if "pass".
 1.1     rmind  */
 1.1     rmind int
1.45  christos npf_rule_conclude(const npf_rule_t *rl, npf_match_info_t *mi)
 1.1     rmind {
 1.1     rmind 	/* If not passing - drop the packet. */
1.45  christos 	mi->mi_retfl = rl->r_attr;
1.45  christos 	mi->mi_rid = rl->r_id;
1.17     rmind 	return (rl->r_attr & NPF_RULE_PASS) ? 0 : ENETUNREACH;
 1.1     rmind }
1.41     rmind
1.41     rmind
1.41     rmind #if defined(DDB) || defined(_NPF_TESTING)
1.41     rmind
1.41     rmind void
1.43  christos npf_ruleset_dump(npf_t *npf, const char *name)
1.41     rmind {
1.43  christos 	npf_ruleset_t *rlset = npf_config_ruleset(npf);
1.41     rmind 	npf_rule_t *rg, *rl;
1.41     rmind
1.41     rmind 	LIST_FOREACH(rg, &rlset->rs_dynamic, r_dentry) {
1.41     rmind 		printf("ruleset '%s':\n", rg->r_name);
1.42     rmind 		for (rl = rg->r_subset; rl; rl = rl->r_next) {
1.41     rmind 			printf("\tid %"PRIu64", key: ", rl->r_id);
1.41     rmind 			for (u_int i = 0; i < NPF_RULE_MAXKEYLEN; i++)
1.41     rmind 				printf("%x", rl->r_key[i]);
1.41     rmind 			printf("\n");
1.41     rmind 		}
1.41     rmind 	}
1.41     rmind }
1.41     rmind
1.41     rmind #endif