NetBSD/dist/pf/sbin/pfctl/parse.y

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/* $NetBSD: parse.y,v 1.12 2009/06/16 05:16:52 minskim Exp $ */
/* $OpenBSD: parse.y,v 1.519 2007/06/21 19:30:03 henning Exp $ */
/*
* Copyright (c) 2001 Markus Friedl. All rights reserved.
* Copyright (c) 2001 Daniel Hartmeier. All rights reserved.
* Copyright (c) 2001 Theo de Raadt. All rights reserved.
* Copyright (c) 2002,2003 Henning Brauer. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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.
*/
%{
#include <sys/types.h>
#include <sys/socket.h>
#include <net/if.h>
#include <netinet/in.h>
#include <netinet/in_systm.h>
#include <netinet/ip.h>
#include <netinet/ip_icmp.h>
#include <netinet/icmp6.h>
#include <net/pfvar.h>
#include <arpa/inet.h>
#include <altq/altq.h>
#include <altq/altq_cbq.h>
#include <altq/altq_priq.h>
#include <altq/altq_hfsc.h>
#include <stdio.h>
#include <stdlib.h>
#include <netdb.h>
#include <stdarg.h>
#include <errno.h>
#include <string.h>
#include <ctype.h>
#include <math.h>
#include <err.h>
#include <limits.h>
#include <pwd.h>
#include <grp.h>
#include <md5.h>
#include "pfctl_parser.h"
#include "pfctl.h"
#ifndef RT_TABLEID_MAX
#define RT_TABLEID_MAX 255
#endif /* !RT_TABLEID_MAX */
static struct pfctl *pf = NULL;
static FILE *fin = NULL;
static int debug = 0;
static int lineno = 1;
static int errors = 0;
static int rulestate = 0;
static u_int16_t returnicmpdefault =
(ICMP_UNREACH << 8) | ICMP_UNREACH_PORT;
static u_int16_t returnicmp6default =
(ICMP6_DST_UNREACH << 8) | ICMP6_DST_UNREACH_NOPORT;
static int blockpolicy = PFRULE_DROP;
static int require_order = 1;
static int default_statelock;
enum {
PFCTL_STATE_NONE,
PFCTL_STATE_OPTION,
PFCTL_STATE_SCRUB,
PFCTL_STATE_QUEUE,
PFCTL_STATE_NAT,
PFCTL_STATE_FILTER
};
struct node_proto {
u_int8_t proto;
struct node_proto *next;
struct node_proto *tail;
};
struct node_port {
u_int16_t port[2];
u_int8_t op;
struct node_port *next;
struct node_port *tail;
};
struct node_uid {
uid_t uid[2];
u_int8_t op;
struct node_uid *next;
struct node_uid *tail;
};
struct node_gid {
gid_t gid[2];
u_int8_t op;
struct node_gid *next;
struct node_gid *tail;
};
struct node_icmp {
u_int8_t code;
u_int8_t type;
u_int8_t proto;
struct node_icmp *next;
struct node_icmp *tail;
};
enum { PF_STATE_OPT_MAX, PF_STATE_OPT_NOSYNC, PF_STATE_OPT_SRCTRACK,
PF_STATE_OPT_MAX_SRC_STATES, PF_STATE_OPT_MAX_SRC_CONN,
PF_STATE_OPT_MAX_SRC_CONN_RATE, PF_STATE_OPT_MAX_SRC_NODES,
PF_STATE_OPT_OVERLOAD, PF_STATE_OPT_STATELOCK,
PF_STATE_OPT_TIMEOUT };
enum { PF_SRCTRACK_NONE, PF_SRCTRACK, PF_SRCTRACK_GLOBAL, PF_SRCTRACK_RULE };
struct node_state_opt {
int type;
union {
u_int32_t max_states;
u_int32_t max_src_states;
u_int32_t max_src_conn;
struct {
u_int32_t limit;
u_int32_t seconds;
} max_src_conn_rate;
struct {
u_int8_t flush;
char tblname[PF_TABLE_NAME_SIZE];
} overload;
u_int32_t max_src_nodes;
u_int8_t src_track;
u_int32_t statelock;
struct {
int number;
u_int32_t seconds;
} timeout;
} data;
struct node_state_opt *next;
struct node_state_opt *tail;
};
struct peer {
struct node_host *host;
struct node_port *port;
};
struct node_queue {
char queue[PF_QNAME_SIZE];
char parent[PF_QNAME_SIZE];
char ifname[IFNAMSIZ];
int scheduler;
struct node_queue *next;
struct node_queue *tail;
} *queues = NULL;
struct node_qassign {
char *qname;
char *pqname;
};
struct filter_opts {
int marker;
#define FOM_FLAGS 0x01
#define FOM_ICMP 0x02
#define FOM_TOS 0x04
#define FOM_KEEP 0x08
#define FOM_SRCTRACK 0x10
struct node_uid *uid;
struct node_gid *gid;
struct {
u_int8_t b1;
u_int8_t b2;
u_int16_t w;
u_int16_t w2;
} flags;
struct node_icmp *icmpspec;
u_int32_t tos;
u_int32_t prob;
struct {
int action;
struct node_state_opt *options;
} keep;
int fragment;
int allowopts;
char *label;
struct node_qassign queues;
char *tag;
char *match_tag;
u_int8_t match_tag_not;
int rtableid;
} filter_opts;
struct antispoof_opts {
char *label;
int rtableid;
} antispoof_opts;
struct scrub_opts {
int marker;
#define SOM_MINTTL 0x01
#define SOM_MAXMSS 0x02
#define SOM_FRAGCACHE 0x04
int nodf;
int minttl;
int maxmss;
int fragcache;
int randomid;
int reassemble_tcp;
int rtableid;
} scrub_opts;
struct queue_opts {
int marker;
#define QOM_BWSPEC 0x01
#define QOM_SCHEDULER 0x02
#define QOM_PRIORITY 0x04
#define QOM_TBRSIZE 0x08
#define QOM_QLIMIT 0x10
struct node_queue_bw queue_bwspec;
struct node_queue_opt scheduler;
int priority;
int tbrsize;
int qlimit;
} queue_opts;
struct table_opts {
int flags;
int init_addr;
struct node_tinithead init_nodes;
} table_opts;
struct pool_opts {
int marker;
#define POM_TYPE 0x01
#define POM_STICKYADDRESS 0x02
u_int8_t opts;
int type;
int staticport;
struct pf_poolhashkey *key;
} pool_opts;
struct node_hfsc_opts hfsc_opts;
int yyerror(const char *, ...);
int disallow_table(struct node_host *, const char *);
int disallow_urpf_failed(struct node_host *, const char *);
int disallow_alias(struct node_host *, const char *);
int rule_consistent(struct pf_rule *, int);
int filter_consistent(struct pf_rule *, int);
int nat_consistent(struct pf_rule *);
int rdr_consistent(struct pf_rule *);
int process_tabledef(char *, struct table_opts *);
int yyparse(void);
void expand_label_str(char *, size_t, const char *, const char *);
void expand_label_if(const char *, char *, size_t, const char *);
void expand_label_addr(const char *, char *, size_t, u_int8_t,
struct node_host *);
void expand_label_port(const char *, char *, size_t, struct node_port *);
void expand_label_proto(const char *, char *, size_t, u_int8_t);
void expand_label_nr(const char *, char *, size_t);
void expand_label(char *, size_t, const char *, u_int8_t, struct node_host *,
struct node_port *, struct node_host *, struct node_port *,
u_int8_t);
void expand_rule(struct pf_rule *, struct node_if *, struct node_host *,
struct node_proto *, struct node_os*, struct node_host *,
struct node_port *, struct node_host *, struct node_port *,
struct node_uid *, struct node_gid *, struct node_icmp *,
const char *);
int expand_altq(struct pf_altq *, struct node_if *, struct node_queue *,
struct node_queue_bw bwspec, struct node_queue_opt *);
int expand_queue(struct pf_altq *, struct node_if *, struct node_queue *,
struct node_queue_bw, struct node_queue_opt *);
int expand_skip_interface(struct node_if *);
int check_rulestate(int);
int kw_cmp(const void *, const void *);
int lookup(char *);
int lgetc(FILE *);
int lungetc(int);
int findeol(void);
int yylex(void);
int atoul(char *, u_long *);
int getservice(char *);
int rule_label(struct pf_rule *, char *);
TAILQ_HEAD(symhead, sym) symhead = TAILQ_HEAD_INITIALIZER(symhead);
struct sym {
TAILQ_ENTRY(sym) entries;
int used;
int persist;
char *nam;
char *val;
};
int symset(const char *, const char *, int);
char *symget(const char *);
void mv_rules(struct pf_ruleset *, struct pf_ruleset *);
void decide_address_family(struct node_host *, sa_family_t *);
void remove_invalid_hosts(struct node_host **, sa_family_t *);
int invalid_redirect(struct node_host *, sa_family_t);
u_int16_t parseicmpspec(char *, sa_family_t);
TAILQ_HEAD(loadanchorshead, loadanchors)
loadanchorshead = TAILQ_HEAD_INITIALIZER(loadanchorshead);
struct loadanchors {
TAILQ_ENTRY(loadanchors) entries;
char *anchorname;
char *filename;
};
typedef struct {
union {
u_int32_t number;
int i;
char *string;
int rtableid;
struct {
u_int8_t b1;
u_int8_t b2;
u_int16_t w;
u_int16_t w2;
} b;
struct range {
int a;
int b;
int t;
} range;
struct node_if *interface;
struct node_proto *proto;
struct node_icmp *icmp;
struct node_host *host;
struct node_os *os;
struct node_port *port;
struct node_uid *uid;
struct node_gid *gid;
struct node_state_opt *state_opt;
struct peer peer;
struct {
struct peer src, dst;
struct node_os *src_os;
} fromto;
struct {
struct node_host *host;
u_int8_t rt;
u_int8_t pool_opts;
sa_family_t af;
struct pf_poolhashkey *key;
} route;
struct redirection {
struct node_host *host;
struct range rport;
} *redirection;
struct {
int action;
struct node_state_opt *options;
} keep_state;
struct {
u_int8_t log;
u_int8_t logif;
u_int8_t quick;
} logquick;
struct {
int neg;
char *name;
} tagged;
struct pf_poolhashkey *hashkey;
struct node_queue *queue;
struct node_queue_opt queue_options;
struct node_queue_bw queue_bwspec;
struct node_qassign qassign;
struct filter_opts filter_opts;
struct antispoof_opts antispoof_opts;
struct queue_opts queue_opts;
struct scrub_opts scrub_opts;
struct table_opts table_opts;
struct pool_opts pool_opts;
struct node_hfsc_opts hfsc_opts;
} v;
int lineno;
} YYSTYPE;
#define DYNIF_MULTIADDR(addr) ((addr).type == PF_ADDR_DYNIFTL && \
(!((addr).iflags & PFI_AFLAG_NOALIAS) || \
!isdigit((unsigned char)(addr).v.ifname[strlen((addr).v.ifname)-1])))
%}
%token PASS BLOCK SCRUB RETURN IN OS OUT LOG QUICK ON FROM TO FLAGS
%token RETURNRST RETURNICMP RETURNICMP6 PROTO INET INET6 ALL ANY ICMPTYPE
%token ICMP6TYPE CODE KEEP MODULATE STATE PORT RDR NAT BINAT ARROW NODF
%token MINTTL ERROR ALLOWOPTS FASTROUTE FILENAME ROUTETO DUPTO REPLYTO NO LABEL
%token NOROUTE URPFFAILED FRAGMENT USER GROUP MAXMSS MAXIMUM TTL TOS DROP TABLE
%token REASSEMBLE FRAGDROP FRAGCROP ANCHOR NATANCHOR RDRANCHOR BINATANCHOR
%token SET OPTIMIZATION TIMEOUT LIMIT LOGINTERFACE BLOCKPOLICY RANDOMID
%token REQUIREORDER SYNPROXY FINGERPRINTS NOSYNC DEBUG SKIP HOSTID
%token ANTISPOOF FOR
%token BITMASK RANDOM SOURCEHASH ROUNDROBIN STATICPORT PROBABILITY
%token ALTQ CBQ PRIQ HFSC BANDWIDTH TBRSIZE LINKSHARE REALTIME UPPERLIMIT
%token QUEUE PRIORITY QLIMIT RTABLE
%token LOAD RULESET_OPTIMIZATION
%token STICKYADDRESS MAXSRCSTATES MAXSRCNODES SOURCETRACK GLOBAL RULE
%token MAXSRCCONN MAXSRCCONNRATE OVERLOAD FLUSH
%token TAGGED TAG IFBOUND FLOATING STATEPOLICY ROUTE
%token <v.string> STRING
%token <v.i> PORTBINARY
%type <v.interface> interface if_list if_item_not if_item
%type <v.number> number icmptype icmp6type uid gid
%type <v.number> tos not yesno
%type <v.i> no dir af fragcache optimizer
%type <v.i> sourcetrack flush unaryop statelock
%type <v.b> action nataction natpasslog scrubaction
%type <v.b> flags flag blockspec
%type <v.range> port rport
%type <v.hashkey> hashkey
%type <v.proto> proto proto_list proto_item
%type <v.icmp> icmpspec
%type <v.icmp> icmp_list icmp_item
%type <v.icmp> icmp6_list icmp6_item
%type <v.fromto> fromto
%type <v.peer> ipportspec from to
%type <v.host> ipspec xhost host dynaddr host_list
%type <v.host> redir_host_list redirspec
%type <v.host> route_host route_host_list routespec
%type <v.os> os xos os_list
%type <v.port> portspec port_list port_item
%type <v.uid> uids uid_list uid_item
%type <v.gid> gids gid_list gid_item
%type <v.route> route
%type <v.redirection> redirection redirpool
%type <v.string> label string tag anchorname
%type <v.keep_state> keep
%type <v.state_opt> state_opt_spec state_opt_list state_opt_item
%type <v.state_opt> opt_statelock
%type <v.logquick> logquick quick log logopts logopt
%type <v.interface> antispoof_ifspc antispoof_iflst antispoof_if
%type <v.qassign> qname
%type <v.queue> qassign qassign_list qassign_item
%type <v.queue_options> scheduler
%type <v.number> cbqflags_list cbqflags_item
%type <v.number> priqflags_list priqflags_item
%type <v.hfsc_opts> hfscopts_list hfscopts_item hfsc_opts
%type <v.queue_bwspec> bandwidth
%type <v.filter_opts> filter_opts filter_opt filter_opts_l
%type <v.antispoof_opts> antispoof_opts antispoof_opt antispoof_opts_l
%type <v.queue_opts> queue_opts queue_opt queue_opts_l
%type <v.scrub_opts> scrub_opts scrub_opt scrub_opts_l
%type <v.table_opts> table_opts table_opt table_opts_l
%type <v.pool_opts> pool_opts pool_opt pool_opts_l
%type <v.tagged> tagged
%type <v.rtableid> rtable
%%
ruleset : /* empty */
| ruleset '\n'
| ruleset option '\n'
| ruleset scrubrule '\n'
| ruleset natrule '\n'
| ruleset binatrule '\n'
| ruleset pfrule '\n'
| ruleset anchorrule '\n'
| ruleset loadrule '\n'
| ruleset altqif '\n'
| ruleset queuespec '\n'
| ruleset varset '\n'
| ruleset antispoof '\n'
| ruleset tabledef '\n'
| '{' fakeanchor '}' '\n';
| ruleset error '\n' { errors++; }
;
/*
* apply to previouslys specified rule: must be careful to note
* what that is: pf or nat or binat or rdr
*/
fakeanchor : fakeanchor '\n'
| fakeanchor anchorrule '\n'
| fakeanchor binatrule '\n'
| fakeanchor natrule '\n'
| fakeanchor pfrule '\n'
| fakeanchor error '\n'
;
optimizer : string {
if (!strcmp($1, "none"))
$$ = 0;
else if (!strcmp($1, "basic"))
$$ = PF_OPTIMIZE_BASIC;
else if (!strcmp($1, "profile"))
$$ = PF_OPTIMIZE_BASIC | PF_OPTIMIZE_PROFILE;
else {
yyerror("unknown ruleset-optimization %s", $$);
YYERROR;
}
}
;
option : SET OPTIMIZATION STRING {
if (check_rulestate(PFCTL_STATE_OPTION)) {
free($3);
YYERROR;
}
if (pfctl_set_optimization(pf, $3) != 0) {
yyerror("unknown optimization %s", $3);
free($3);
YYERROR;
}
free($3);
}
| SET RULESET_OPTIMIZATION optimizer {
if (!(pf->opts & PF_OPT_OPTIMIZE)) {
pf->opts |= PF_OPT_OPTIMIZE;
pf->optimize = $3;
}
}
| SET TIMEOUT timeout_spec
| SET TIMEOUT '{' timeout_list '}'
| SET LIMIT limit_spec
| SET LIMIT '{' limit_list '}'
| SET LOGINTERFACE STRING {
if (check_rulestate(PFCTL_STATE_OPTION)) {
free($3);
YYERROR;
}
if (pfctl_set_logif(pf, $3) != 0) {
yyerror("error setting loginterface %s", $3);
free($3);
YYERROR;
}
free($3);
}
| SET HOSTID number {
if ($3 == 0) {
yyerror("hostid must be non-zero");
YYERROR;
}
if (pfctl_set_hostid(pf, $3) != 0) {
yyerror("error setting hostid %08x", $3);
YYERROR;
}
}
| SET BLOCKPOLICY DROP {
if (pf->opts & PF_OPT_VERBOSE)
printf("set block-policy drop\n");
if (check_rulestate(PFCTL_STATE_OPTION))
YYERROR;
blockpolicy = PFRULE_DROP;
}
| SET BLOCKPOLICY RETURN {
if (pf->opts & PF_OPT_VERBOSE)
printf("set block-policy return\n");
if (check_rulestate(PFCTL_STATE_OPTION))
YYERROR;
blockpolicy = PFRULE_RETURN;
}
| SET REQUIREORDER yesno {
if (pf->opts & PF_OPT_VERBOSE)
printf("set require-order %s\n",
$3 == 1 ? "yes" : "no");
require_order = $3;
}
| SET FINGERPRINTS STRING {
if (pf->opts & PF_OPT_VERBOSE)
printf("set fingerprints \"%s\"\n", $3);
if (check_rulestate(PFCTL_STATE_OPTION)) {
free($3);
YYERROR;
}
if (!pf->anchor->name[0]) {
if (pfctl_file_fingerprints(pf->dev,
pf->opts, $3)) {
yyerror("error loading "
"fingerprints %s", $3);
free($3);
YYERROR;
}
}
free($3);
}
| SET STATEPOLICY statelock {
if (pf->opts & PF_OPT_VERBOSE)
switch ($3) {
case 0:
printf("set state-policy floating\n");
break;
case PFRULE_IFBOUND:
printf("set state-policy if-bound\n");
break;
}
default_statelock = $3;
}
| SET DEBUG STRING {
if (check_rulestate(PFCTL_STATE_OPTION)) {
free($3);
YYERROR;
}
if (pfctl_set_debug(pf, $3) != 0) {
yyerror("error setting debuglevel %s", $3);
free($3);
YYERROR;
}
free($3);
}
| SET SKIP interface {
if (expand_skip_interface($3) != 0) {
yyerror("error setting skip interface(s)");
YYERROR;
}
}
;
string : string STRING {
if (asprintf(&$$, "%s %s", $1, $2) == -1)
err(1, "string: asprintf");
free($1);
free($2);
}
| STRING
;
varset : STRING '=' string {
if (pf->opts & PF_OPT_VERBOSE)
printf("%s = \"%s\"\n", $1, $3);
if (symset($1, $3, 0) == -1)
err(1, "cannot store variable %s", $1);
free($1);
free($3);
}
;
anchorname : STRING { $$ = $1; }
| /* empty */ { $$ = NULL; }
;
optnl : optnl '\n'
|
;
pfa_anchorlist : pfrule optnl
| anchorrule optnl
| pfa_anchorlist pfrule optnl
| pfa_anchorlist anchorrule optnl
;
pfa_anchor : '{'
{
char ta[PF_ANCHOR_NAME_SIZE];
struct pf_ruleset *rs;
/* steping into a brace anchor */
pf->asd++;
pf->bn++;
pf->brace = 1;
/* create a holding ruleset in the root */
snprintf(ta, PF_ANCHOR_NAME_SIZE, "_%d", pf->bn);
rs = pf_find_or_create_ruleset(ta);
if (rs == NULL)
err(1, "pfa_anchor: pf_find_or_create_ruleset");
pf->astack[pf->asd] = rs->anchor;
pf->anchor = rs->anchor;
} '\n' pfa_anchorlist '}'
{
pf->alast = pf->anchor;
pf->asd--;
pf->anchor = pf->astack[pf->asd];
}
| /* empty */
;
anchorrule : ANCHOR anchorname dir quick interface af proto fromto
filter_opts pfa_anchor
{
struct pf_rule r;
if (check_rulestate(PFCTL_STATE_FILTER)) {
if ($2)
free($2);
YYERROR;
}
if ($2 && ($2[0] == '_' || strstr($2, "/_") != NULL)) {
free($2);
yyerror("anchor names beginning with '_' "
"are reserved for internal use");
YYERROR;
}
memset(&r, 0, sizeof(r));
if (pf->astack[pf->asd + 1]) {
/* move inline rules into relative location */
pf_anchor_setup(&r,
&pf->astack[pf->asd]->ruleset,
$2 ? $2 : pf->alast->name);
if (r.anchor == NULL)
err(1, "anchorrule: unable to "
"create ruleset");
if (pf->alast != r.anchor) {
if (r.anchor->match) {
yyerror("inline anchor '%s' "
"already exists",
r.anchor->name);
YYERROR;
}
mv_rules(&pf->alast->ruleset,
&r.anchor->ruleset);
}
pf_remove_if_empty_ruleset(&pf->alast->ruleset);
pf->alast = r.anchor;
} else {
if (!$2) {
yyerror("anchors without explicit "
"rules must specify a name");
YYERROR;
}
}
r.direction = $3;
r.quick = $4.quick;
r.af = $6;
r.prob = $9.prob;
r.rtableid = $9.rtableid;
if ($9.match_tag)
if (strlcpy(r.match_tagname, $9.match_tag,
PF_TAG_NAME_SIZE) >= PF_TAG_NAME_SIZE) {
yyerror("tag too long, max %u chars",
PF_TAG_NAME_SIZE - 1);
YYERROR;
}
r.match_tag_not = $9.match_tag_not;
decide_address_family($8.src.host, &r.af);
decide_address_family($8.dst.host, &r.af);
expand_rule(&r, $5, NULL, $7, $8.src_os,
$8.src.host, $8.src.port, $8.dst.host, $8.dst.port,
0, 0, 0, pf->astack[pf->asd + 1] ?
pf->alast->name : $2);
free($2);
pf->astack[pf->asd + 1] = NULL;
}
| NATANCHOR string interface af proto fromto rtable {
struct pf_rule r;
if (check_rulestate(PFCTL_STATE_NAT)) {
free($2);
YYERROR;
}
memset(&r, 0, sizeof(r));
r.action = PF_NAT;
r.af = $4;
r.rtableid = $7;
decide_address_family($6.src.host, &r.af);
decide_address_family($6.dst.host, &r.af);
expand_rule(&r, $3, NULL, $5, $6.src_os,
$6.src.host, $6.src.port, $6.dst.host, $6.dst.port,
0, 0, 0, $2);
free($2);
}
| RDRANCHOR string interface af proto fromto rtable {
struct pf_rule r;
if (check_rulestate(PFCTL_STATE_NAT)) {
free($2);
YYERROR;
}
memset(&r, 0, sizeof(r));
r.action = PF_RDR;
r.af = $4;
r.rtableid = $7;
decide_address_family($6.src.host, &r.af);
decide_address_family($6.dst.host, &r.af);
if ($6.src.port != NULL) {
yyerror("source port parameter not supported"
" in rdr-anchor");
YYERROR;
}
if ($6.dst.port != NULL) {
if ($6.dst.port->next != NULL) {
yyerror("destination port list "
"expansion not supported in "
"rdr-anchor");
YYERROR;
} else if ($6.dst.port->op != PF_OP_EQ) {
yyerror("destination port operators"
" not supported in rdr-anchor");
YYERROR;
}
r.dst.port[0] = $6.dst.port->port[0];
r.dst.port[1] = $6.dst.port->port[1];
r.dst.port_op = $6.dst.port->op;
}
expand_rule(&r, $3, NULL, $5, $6.src_os,
$6.src.host, $6.src.port, $6.dst.host, $6.dst.port,
0, 0, 0, $2);
free($2);
}
| BINATANCHOR string interface af proto fromto rtable {
struct pf_rule r;
if (check_rulestate(PFCTL_STATE_NAT)) {
free($2);
YYERROR;
}
memset(&r, 0, sizeof(r));
r.action = PF_BINAT;
r.af = $4;
r.rtableid = $7;
if ($5 != NULL) {
if ($5->next != NULL) {
yyerror("proto list expansion"
" not supported in binat-anchor");
YYERROR;
}
r.proto = $5->proto;
free($5);
}
if ($6.src.host != NULL || $6.src.port != NULL ||
$6.dst.host != NULL || $6.dst.port != NULL) {
yyerror("fromto parameter not supported"
" in binat-anchor");
YYERROR;
}
decide_address_family($6.src.host, &r.af);
decide_address_family($6.dst.host, &r.af);
pfctl_add_rule(pf, &r, $2);
free($2);
}
;
loadrule : LOAD ANCHOR string FROM string {
struct loadanchors *loadanchor;
if (strlen(pf->anchor->name) + 1 +
strlen($3) >= MAXPATHLEN) {
yyerror("anchorname %s too long, max %u\n",
$3, MAXPATHLEN - 1);
free($3);
YYERROR;
}
loadanchor = calloc(1, sizeof(struct loadanchors));
if (loadanchor == NULL)
err(1, "loadrule: calloc");
if ((loadanchor->anchorname = malloc(MAXPATHLEN)) ==
NULL)
err(1, "loadrule: malloc");
if (pf->anchor->name[0])
snprintf(loadanchor->anchorname, MAXPATHLEN,
"%s/%s", pf->anchor->name, $3);
else
strlcpy(loadanchor->anchorname, $3, MAXPATHLEN);
if ((loadanchor->filename = strdup($5)) == NULL)
err(1, "loadrule: strdup");
TAILQ_INSERT_TAIL(&loadanchorshead, loadanchor,
entries);
free($3);
free($5);
};
scrubaction : no SCRUB {
$$.b2 = $$.w = 0;
if ($1)
$$.b1 = PF_NOSCRUB;
else
$$.b1 = PF_SCRUB;
}
;
scrubrule : scrubaction dir logquick interface af proto fromto scrub_opts
{
struct pf_rule r;
if (check_rulestate(PFCTL_STATE_SCRUB))
YYERROR;
memset(&r, 0, sizeof(r));
r.action = $1.b1;
r.direction = $2;
r.log = $3.log;
r.logif = $3.logif;
if ($3.quick) {
yyerror("scrub rules do not support 'quick'");
YYERROR;
}
r.af = $5;
if ($8.nodf)
r.rule_flag |= PFRULE_NODF;
if ($8.randomid)
r.rule_flag |= PFRULE_RANDOMID;
if ($8.reassemble_tcp) {
if (r.direction != PF_INOUT) {
yyerror("reassemble tcp rules can not "
"specify direction");
YYERROR;
}
r.rule_flag |= PFRULE_REASSEMBLE_TCP;
}
if ($8.minttl)
r.min_ttl = $8.minttl;
if ($8.maxmss)
r.max_mss = $8.maxmss;
if ($8.fragcache)
r.rule_flag |= $8.fragcache;
r.rtableid = $8.rtableid;
expand_rule(&r, $4, NULL, $6, $7.src_os,
$7.src.host, $7.src.port, $7.dst.host, $7.dst.port,
NULL, NULL, NULL, "");
}
;
scrub_opts : {
bzero(&scrub_opts, sizeof scrub_opts);
scrub_opts.rtableid = -1;
}
scrub_opts_l
{ $$ = scrub_opts; }
| /* empty */ {
bzero(&scrub_opts, sizeof scrub_opts);
scrub_opts.rtableid = -1;
$$ = scrub_opts;
}
;
scrub_opts_l : scrub_opts_l scrub_opt
| scrub_opt
;
scrub_opt : NODF {
if (scrub_opts.nodf) {
yyerror("no-df cannot be respecified");
YYERROR;
}
scrub_opts.nodf = 1;
}
| MINTTL number {
if (scrub_opts.marker & SOM_MINTTL) {
yyerror("min-ttl cannot be respecified");
YYERROR;
}
if ($2 > 255) {
yyerror("illegal min-ttl value %d", $2);
YYERROR;
}
scrub_opts.marker |= SOM_MINTTL;
scrub_opts.minttl = $2;
}
| MAXMSS number {
if (scrub_opts.marker & SOM_MAXMSS) {
yyerror("max-mss cannot be respecified");
YYERROR;
}
if ($2 > 65535) {
yyerror("illegal max-mss value %d", $2);
YYERROR;
}
scrub_opts.marker |= SOM_MAXMSS;
scrub_opts.maxmss = $2;
}
| fragcache {
if (scrub_opts.marker & SOM_FRAGCACHE) {
yyerror("fragcache cannot be respecified");
YYERROR;
}
scrub_opts.marker |= SOM_FRAGCACHE;
scrub_opts.fragcache = $1;
}
| REASSEMBLE STRING {
if (strcasecmp($2, "tcp") != 0) {
yyerror("scrub reassemble supports only tcp, "
"not '%s'", $2);
free($2);
YYERROR;
}
free($2);
if (scrub_opts.reassemble_tcp) {
yyerror("reassemble tcp cannot be respecified");
YYERROR;
}
scrub_opts.reassemble_tcp = 1;
}
| RANDOMID {
if (scrub_opts.randomid) {
yyerror("random-id cannot be respecified");
YYERROR;
}
scrub_opts.randomid = 1;
}
| RTABLE number {
if ($2 > RT_TABLEID_MAX || $2 < 0) {
yyerror("invalid rtable id");
YYERROR;
}
scrub_opts.rtableid = $2;
}
;
fragcache : FRAGMENT REASSEMBLE { $$ = 0; /* default */ }
| FRAGMENT FRAGCROP { $$ = PFRULE_FRAGCROP; }
| FRAGMENT FRAGDROP { $$ = PFRULE_FRAGDROP; }
;
antispoof : ANTISPOOF logquick antispoof_ifspc af antispoof_opts {
struct pf_rule r;
struct node_host *h = NULL, *hh;
struct node_if *i, *j;
if (check_rulestate(PFCTL_STATE_FILTER))
YYERROR;
for (i = $3; i; i = i->next) {
bzero(&r, sizeof(r));
r.action = PF_DROP;
r.direction = PF_IN;
r.log = $2.log;
r.logif = $2.logif;
r.quick = $2.quick;
r.af = $4;
if (rule_label(&r, $5.label))
YYERROR;
r.rtableid = $5.rtableid;
j = calloc(1, sizeof(struct node_if));
if (j == NULL)
err(1, "antispoof: calloc");
if (strlcpy(j->ifname, i->ifname,
sizeof(j->ifname)) >= sizeof(j->ifname)) {
free(j);
yyerror("interface name too long");
YYERROR;
}
j->not = 1;
if (i->dynamic) {
h = calloc(1, sizeof(*h));
if (h == NULL)
err(1, "address: calloc");
h->addr.type = PF_ADDR_DYNIFTL;
set_ipmask(h, 128);
if (strlcpy(h->addr.v.ifname, i->ifname,
sizeof(h->addr.v.ifname)) >=
sizeof(h->addr.v.ifname)) {
free(h);
yyerror(
"interface name too long");
YYERROR;
}
hh = malloc(sizeof(*hh));
if (hh == NULL)
err(1, "address: malloc");
bcopy(h, hh, sizeof(*hh));
h->addr.iflags = PFI_AFLAG_NETWORK;
} else {
h = ifa_lookup(j->ifname,
PFI_AFLAG_NETWORK);
hh = NULL;
}
if (h != NULL)
expand_rule(&r, j, NULL, NULL, NULL, h,
NULL, NULL, NULL, NULL, NULL,
NULL, "");
if ((i->ifa_flags & IFF_LOOPBACK) == 0) {
bzero(&r, sizeof(r));
r.action = PF_DROP;
r.direction = PF_IN;
r.log = $2.log;
r.quick = $2.quick;
r.af = $4;
if (rule_label(&r, $5.label))
YYERROR;
r.rtableid = $5.rtableid;
if (hh != NULL)
h = hh;
else
h = ifa_lookup(i->ifname, 0);
if (h != NULL)
expand_rule(&r, NULL, NULL,
NULL, NULL, h, NULL, NULL,
NULL, NULL, NULL, NULL, "");
} else
free(hh);
}
free($5.label);
}
;
antispoof_ifspc : FOR antispoof_if { $$ = $2; }
| FOR '{' antispoof_iflst '}' { $$ = $3; }
;
antispoof_iflst : antispoof_if { $$ = $1; }
| antispoof_iflst comma antispoof_if {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
antispoof_if : if_item { $$ = $1; }
| '(' if_item ')' {
$2->dynamic = 1;
$$ = $2;
}
;
antispoof_opts : {
bzero(&antispoof_opts, sizeof antispoof_opts);
antispoof_opts.rtableid = -1;
}
antispoof_opts_l
{ $$ = antispoof_opts; }
| /* empty */ {
bzero(&antispoof_opts, sizeof antispoof_opts);
antispoof_opts.rtableid = -1;
$$ = antispoof_opts;
}
;
antispoof_opts_l : antispoof_opts_l antispoof_opt
| antispoof_opt
;
antispoof_opt : label {
if (antispoof_opts.label) {
yyerror("label cannot be redefined");
YYERROR;
}
antispoof_opts.label = $1;
}
| RTABLE number {
if ($2 > RT_TABLEID_MAX || $2 < 0) {
yyerror("invalid rtable id");
YYERROR;
}
antispoof_opts.rtableid = $2;
}
;
not : '!' { $$ = 1; }
| /* empty */ { $$ = 0; }
;
tabledef : TABLE '<' STRING '>' table_opts {
struct node_host *h, *nh;
struct node_tinit *ti, *nti;
if (strlen($3) >= PF_TABLE_NAME_SIZE) {
yyerror("table name too long, max %d chars",
PF_TABLE_NAME_SIZE - 1);
free($3);
YYERROR;
}
if (pf->loadopt & PFCTL_FLAG_TABLE)
if (process_tabledef($3, &$5)) {
free($3);
YYERROR;
}
free($3);
for (ti = SIMPLEQ_FIRST(&$5.init_nodes);
ti != NULL; ti = nti) {
if (ti->file)
free(ti->file);
for (h = ti->host; h != NULL; h = nh) {
nh = h->next;
free(h);
}
nti = SIMPLEQ_NEXT(ti, entries);
free(ti);
}
}
;
table_opts : {
bzero(&table_opts, sizeof table_opts);
SIMPLEQ_INIT(&table_opts.init_nodes);
}
table_opts_l
{ $$ = table_opts; }
| /* empty */
{
bzero(&table_opts, sizeof table_opts);
SIMPLEQ_INIT(&table_opts.init_nodes);
$$ = table_opts;
}
;
table_opts_l : table_opts_l table_opt
| table_opt
;
table_opt : STRING {
if (!strcmp($1, "const"))
table_opts.flags |= PFR_TFLAG_CONST;
else if (!strcmp($1, "persist"))
table_opts.flags |= PFR_TFLAG_PERSIST;
else {
yyerror("invalid table option '%s'", $1);
free($1);
YYERROR;
}
free($1);
}
| '{' '}' { table_opts.init_addr = 1; }
| '{' host_list '}' {
struct node_host *n;
struct node_tinit *ti;
for (n = $2; n != NULL; n = n->next) {
switch (n->addr.type) {
case PF_ADDR_ADDRMASK:
continue; /* ok */
case PF_ADDR_DYNIFTL:
yyerror("dynamic addresses are not "
"permitted inside tables");
break;
case PF_ADDR_TABLE:
yyerror("tables cannot contain tables");
break;
case PF_ADDR_NOROUTE:
yyerror("\"no-route\" is not permitted "
"inside tables");
break;
case PF_ADDR_URPFFAILED:
yyerror("\"urpf-failed\" is not "
"permitted inside tables");
break;
default:
yyerror("unknown address type %d",
n->addr.type);
}
YYERROR;
}
if (!(ti = calloc(1, sizeof(*ti))))
err(1, "table_opt: calloc");
ti->host = $2;
SIMPLEQ_INSERT_TAIL(&table_opts.init_nodes, ti,
entries);
table_opts.init_addr = 1;
}
| FILENAME STRING {
struct node_tinit *ti;
if (!(ti = calloc(1, sizeof(*ti))))
err(1, "table_opt: calloc");
ti->file = $2;
SIMPLEQ_INSERT_TAIL(&table_opts.init_nodes, ti,
entries);
table_opts.init_addr = 1;
}
;
altqif : ALTQ interface queue_opts QUEUE qassign {
struct pf_altq a;
if (check_rulestate(PFCTL_STATE_QUEUE))
YYERROR;
memset(&a, 0, sizeof(a));
if ($3.scheduler.qtype == ALTQT_NONE) {
yyerror("no scheduler specified!");
YYERROR;
}
a.scheduler = $3.scheduler.qtype;
a.qlimit = $3.qlimit;
a.tbrsize = $3.tbrsize;
if ($5 == NULL) {
yyerror("no child queues specified");
YYERROR;
}
if (expand_altq(&a, $2, $5, $3.queue_bwspec,
&$3.scheduler))
YYERROR;
}
;
queuespec : QUEUE STRING interface queue_opts qassign {
struct pf_altq a;
if (check_rulestate(PFCTL_STATE_QUEUE)) {
free($2);
YYERROR;
}
memset(&a, 0, sizeof(a));
if (strlcpy(a.qname, $2, sizeof(a.qname)) >=
sizeof(a.qname)) {
yyerror("queue name too long (max "
"%d chars)", PF_QNAME_SIZE-1);
free($2);
YYERROR;
}
free($2);
if ($4.tbrsize) {
yyerror("cannot specify tbrsize for queue");
YYERROR;
}
if ($4.priority > 255) {
yyerror("priority out of range: max 255");
YYERROR;
}
a.priority = $4.priority;
a.qlimit = $4.qlimit;
a.scheduler = $4.scheduler.qtype;
if (expand_queue(&a, $3, $5, $4.queue_bwspec,
&$4.scheduler)) {
yyerror("errors in queue definition");
YYERROR;
}
}
;
queue_opts : {
bzero(&queue_opts, sizeof queue_opts);
queue_opts.priority = DEFAULT_PRIORITY;
queue_opts.qlimit = DEFAULT_QLIMIT;
queue_opts.scheduler.qtype = ALTQT_NONE;
queue_opts.queue_bwspec.bw_percent = 100;
}
queue_opts_l
{ $$ = queue_opts; }
| /* empty */ {
bzero(&queue_opts, sizeof queue_opts);
queue_opts.priority = DEFAULT_PRIORITY;
queue_opts.qlimit = DEFAULT_QLIMIT;
queue_opts.scheduler.qtype = ALTQT_NONE;
queue_opts.queue_bwspec.bw_percent = 100;
$$ = queue_opts;
}
;
queue_opts_l : queue_opts_l queue_opt
| queue_opt
;
queue_opt : BANDWIDTH bandwidth {
if (queue_opts.marker & QOM_BWSPEC) {
yyerror("bandwidth cannot be respecified");
YYERROR;
}
queue_opts.marker |= QOM_BWSPEC;
queue_opts.queue_bwspec = $2;
}
| PRIORITY number {
if (queue_opts.marker & QOM_PRIORITY) {
yyerror("priority cannot be respecified");
YYERROR;
}
if ($2 > 255) {
yyerror("priority out of range: max 255");
YYERROR;
}
queue_opts.marker |= QOM_PRIORITY;
queue_opts.priority = $2;
}
| QLIMIT number {
if (queue_opts.marker & QOM_QLIMIT) {
yyerror("qlimit cannot be respecified");
YYERROR;
}
if ($2 > 65535) {
yyerror("qlimit out of range: max 65535");
YYERROR;
}
queue_opts.marker |= QOM_QLIMIT;
queue_opts.qlimit = $2;
}
| scheduler {
if (queue_opts.marker & QOM_SCHEDULER) {
yyerror("scheduler cannot be respecified");
YYERROR;
}
queue_opts.marker |= QOM_SCHEDULER;
queue_opts.scheduler = $1;
}
| TBRSIZE number {
if (queue_opts.marker & QOM_TBRSIZE) {
yyerror("tbrsize cannot be respecified");
YYERROR;
}
if ($2 > 65535) {
yyerror("tbrsize too big: max 65535");
YYERROR;
}
queue_opts.marker |= QOM_TBRSIZE;
queue_opts.tbrsize = $2;
}
;
bandwidth : STRING {
double bps;
char *cp;
$$.bw_percent = 0;
bps = strtod($1, &cp);
if (cp != NULL) {
if (!strcmp(cp, "b"))
; /* nothing */
else if (!strcmp(cp, "Kb"))
bps *= 1000;
else if (!strcmp(cp, "Mb"))
bps *= 1000 * 1000;
else if (!strcmp(cp, "Gb"))
bps *= 1000 * 1000 * 1000;
else if (!strcmp(cp, "%")) {
if (bps < 0 || bps > 100) {
yyerror("bandwidth spec "
"out of range");
free($1);
YYERROR;
}
$$.bw_percent = bps;
bps = 0;
} else {
yyerror("unknown unit %s", cp);
free($1);
YYERROR;
}
}
free($1);
$$.bw_absolute = (u_int32_t)bps;
}
;
scheduler : CBQ {
$$.qtype = ALTQT_CBQ;
$$.data.cbq_opts.flags = 0;
}
| CBQ '(' cbqflags_list ')' {
$$.qtype = ALTQT_CBQ;
$$.data.cbq_opts.flags = $3;
}
| PRIQ {
$$.qtype = ALTQT_PRIQ;
$$.data.priq_opts.flags = 0;
}
| PRIQ '(' priqflags_list ')' {
$$.qtype = ALTQT_PRIQ;
$$.data.priq_opts.flags = $3;
}
| HFSC {
$$.qtype = ALTQT_HFSC;
bzero(&$$.data.hfsc_opts,
sizeof(struct node_hfsc_opts));
}
| HFSC '(' hfsc_opts ')' {
$$.qtype = ALTQT_HFSC;
$$.data.hfsc_opts = $3;
}
;
cbqflags_list : cbqflags_item { $$ |= $1; }
| cbqflags_list comma cbqflags_item { $$ |= $3; }
;
cbqflags_item : STRING {
if (!strcmp($1, "default"))
$$ = CBQCLF_DEFCLASS;
#ifdef CBQCLF_BORROW
else if (!strcmp($1, "borrow"))
$$ = CBQCLF_BORROW;
#endif
else if (!strcmp($1, "red"))
$$ = CBQCLF_RED;
else if (!strcmp($1, "ecn"))
$$ = CBQCLF_RED|CBQCLF_ECN;
else if (!strcmp($1, "rio"))
$$ = CBQCLF_RIO;
else {
yyerror("unknown cbq flag \"%s\"", $1);
free($1);
YYERROR;
}
free($1);
}
;
priqflags_list : priqflags_item { $$ |= $1; }
| priqflags_list comma priqflags_item { $$ |= $3; }
;
priqflags_item : STRING {
if (!strcmp($1, "default"))
$$ = PRCF_DEFAULTCLASS;
else if (!strcmp($1, "red"))
$$ = PRCF_RED;
else if (!strcmp($1, "ecn"))
$$ = PRCF_RED|PRCF_ECN;
else if (!strcmp($1, "rio"))
$$ = PRCF_RIO;
else {
yyerror("unknown priq flag \"%s\"", $1);
free($1);
YYERROR;
}
free($1);
}
;
hfsc_opts : {
bzero(&hfsc_opts,
sizeof(struct node_hfsc_opts));
}
hfscopts_list {
$$ = hfsc_opts;
}
;
hfscopts_list : hfscopts_item
| hfscopts_list comma hfscopts_item
;
hfscopts_item : LINKSHARE bandwidth {
if (hfsc_opts.linkshare.used) {
yyerror("linkshare already specified");
YYERROR;
}
hfsc_opts.linkshare.m2 = $2;
hfsc_opts.linkshare.used = 1;
}
| LINKSHARE '(' bandwidth comma number comma bandwidth ')'
{
if (hfsc_opts.linkshare.used) {
yyerror("linkshare already specified");
YYERROR;
}
hfsc_opts.linkshare.m1 = $3;
hfsc_opts.linkshare.d = $5;
hfsc_opts.linkshare.m2 = $7;
hfsc_opts.linkshare.used = 1;
}
| REALTIME bandwidth {
if (hfsc_opts.realtime.used) {
yyerror("realtime already specified");
YYERROR;
}
hfsc_opts.realtime.m2 = $2;
hfsc_opts.realtime.used = 1;
}
| REALTIME '(' bandwidth comma number comma bandwidth ')'
{
if (hfsc_opts.realtime.used) {
yyerror("realtime already specified");
YYERROR;
}
hfsc_opts.realtime.m1 = $3;
hfsc_opts.realtime.d = $5;
hfsc_opts.realtime.m2 = $7;
hfsc_opts.realtime.used = 1;
}
| UPPERLIMIT bandwidth {
if (hfsc_opts.upperlimit.used) {
yyerror("upperlimit already specified");
YYERROR;
}
hfsc_opts.upperlimit.m2 = $2;
hfsc_opts.upperlimit.used = 1;
}
| UPPERLIMIT '(' bandwidth comma number comma bandwidth ')'
{
if (hfsc_opts.upperlimit.used) {
yyerror("upperlimit already specified");
YYERROR;
}
hfsc_opts.upperlimit.m1 = $3;
hfsc_opts.upperlimit.d = $5;
hfsc_opts.upperlimit.m2 = $7;
hfsc_opts.upperlimit.used = 1;
}
| STRING {
if (!strcmp($1, "default"))
hfsc_opts.flags |= HFCF_DEFAULTCLASS;
else if (!strcmp($1, "red"))
hfsc_opts.flags |= HFCF_RED;
else if (!strcmp($1, "ecn"))
hfsc_opts.flags |= HFCF_RED|HFCF_ECN;
else if (!strcmp($1, "rio"))
hfsc_opts.flags |= HFCF_RIO;
else {
yyerror("unknown hfsc flag \"%s\"", $1);
free($1);
YYERROR;
}
free($1);
}
;
qassign : /* empty */ { $$ = NULL; }
| qassign_item { $$ = $1; }
| '{' qassign_list '}' { $$ = $2; }
;
qassign_list : qassign_item { $$ = $1; }
| qassign_list comma qassign_item {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
qassign_item : STRING {
$$ = calloc(1, sizeof(struct node_queue));
if ($$ == NULL)
err(1, "qassign_item: calloc");
if (strlcpy($$->queue, $1, sizeof($$->queue)) >=
sizeof($$->queue)) {
yyerror("queue name '%s' too long (max "
"%d chars)", $1, sizeof($$->queue)-1);
free($1);
free($$);
YYERROR;
}
free($1);
$$->next = NULL;
$$->tail = $$;
}
;
pfrule : action dir logquick interface route af proto fromto
filter_opts
{
struct pf_rule r;
struct node_state_opt *o;
struct node_proto *proto;
int srctrack = 0;
int statelock = 0;
int adaptive = 0;
if (check_rulestate(PFCTL_STATE_FILTER))
YYERROR;
memset(&r, 0, sizeof(r));
r.action = $1.b1;
switch ($1.b2) {
case PFRULE_RETURNRST:
r.rule_flag |= PFRULE_RETURNRST;
r.return_ttl = $1.w;
break;
case PFRULE_RETURNICMP:
r.rule_flag |= PFRULE_RETURNICMP;
r.return_icmp = $1.w;
r.return_icmp6 = $1.w2;
break;
case PFRULE_RETURN:
r.rule_flag |= PFRULE_RETURN;
r.return_icmp = $1.w;
r.return_icmp6 = $1.w2;
break;
}
r.direction = $2;
r.log = $3.log;
r.logif = $3.logif;
r.quick = $3.quick;
r.prob = $9.prob;
r.rtableid = $9.rtableid;
r.af = $6;
if ($9.tag)
if (strlcpy(r.tagname, $9.tag,
PF_TAG_NAME_SIZE) >= PF_TAG_NAME_SIZE) {
yyerror("tag too long, max %u chars",
PF_TAG_NAME_SIZE - 1);
YYERROR;
}
if ($9.match_tag)
if (strlcpy(r.match_tagname, $9.match_tag,
PF_TAG_NAME_SIZE) >= PF_TAG_NAME_SIZE) {
yyerror("tag too long, max %u chars",
PF_TAG_NAME_SIZE - 1);
YYERROR;
}
r.match_tag_not = $9.match_tag_not;
if (rule_label(&r, $9.label))
YYERROR;
free($9.label);
r.flags = $9.flags.b1;
r.flagset = $9.flags.b2;
if (($9.flags.b1 & $9.flags.b2) != $9.flags.b1) {
yyerror("flags always false");
YYERROR;
}
if ($9.flags.b1 || $9.flags.b2 || $8.src_os) {
for (proto = $7; proto != NULL &&
proto->proto != IPPROTO_TCP;
proto = proto->next)
; /* nothing */
if (proto == NULL && $7 != NULL) {
if ($9.flags.b1 || $9.flags.b2)
yyerror(
"flags only apply to tcp");
if ($8.src_os)
yyerror(
"OS fingerprinting only "
"apply to tcp");
YYERROR;
}
#if 0
if (($9.flags.b1 & parse_flags("S")) == 0 &&
$8.src_os) {
yyerror("OS fingerprinting requires "
"the SYN TCP flag (flags S/SA)");
YYERROR;
}
#endif
}
r.tos = $9.tos;
r.keep_state = $9.keep.action;
/* 'keep state' by default on pass rules. */
if (!r.keep_state && !r.action &&
!($9.marker & FOM_KEEP))
r.keep_state = PF_STATE_NORMAL;
o = $9.keep.options;
while (o) {
struct node_state_opt *p = o;
switch (o->type) {
case PF_STATE_OPT_MAX:
if (r.max_states) {
yyerror("state option 'max' "
"multiple definitions");
YYERROR;
}
r.max_states = o->data.max_states;
break;
case PF_STATE_OPT_NOSYNC:
if (r.rule_flag & PFRULE_NOSYNC) {
yyerror("state option 'sync' "
"multiple definitions");
YYERROR;
}
r.rule_flag |= PFRULE_NOSYNC;
break;
case PF_STATE_OPT_SRCTRACK:
if (srctrack) {
yyerror("state option "
"'source-track' "
"multiple definitions");
YYERROR;
}
srctrack = o->data.src_track;
r.rule_flag |= PFRULE_SRCTRACK;
break;
case PF_STATE_OPT_MAX_SRC_STATES:
if (r.max_src_states) {
yyerror("state option "
"'max-src-states' "
"multiple definitions");
YYERROR;
}
if (o->data.max_src_states == 0) {
yyerror("'max-src-states' must "
"be > 0");
YYERROR;
}
r.max_src_states =
o->data.max_src_states;
r.rule_flag |= PFRULE_SRCTRACK;
break;
case PF_STATE_OPT_OVERLOAD:
if (r.overload_tblname[0]) {
yyerror("multiple 'overload' "
"table definitions");
YYERROR;
}
if (strlcpy(r.overload_tblname,
o->data.overload.tblname,
PF_TABLE_NAME_SIZE) >=
PF_TABLE_NAME_SIZE) {
yyerror("state option: "
"strlcpy");
YYERROR;
}
r.flush = o->data.overload.flush;
break;
case PF_STATE_OPT_MAX_SRC_CONN:
if (r.max_src_conn) {
yyerror("state option "
"'max-src-conn' "
"multiple definitions");
YYERROR;
}
if (o->data.max_src_conn == 0) {
yyerror("'max-src-conn' "
"must be > 0");
YYERROR;
}
r.max_src_conn =
o->data.max_src_conn;
r.rule_flag |= PFRULE_SRCTRACK |
PFRULE_RULESRCTRACK;
break;
case PF_STATE_OPT_MAX_SRC_CONN_RATE:
if (r.max_src_conn_rate.limit) {
yyerror("state option "
"'max-src-conn-rate' "
"multiple definitions");
YYERROR;
}
if (!o->data.max_src_conn_rate.limit ||
!o->data.max_src_conn_rate.seconds) {
yyerror("'max-src-conn-rate' "
"values must be > 0");
YYERROR;
}
if (o->data.max_src_conn_rate.limit >
PF_THRESHOLD_MAX) {
yyerror("'max-src-conn-rate' "
"maximum rate must be < %u",
PF_THRESHOLD_MAX);
YYERROR;
}
r.max_src_conn_rate.limit =
o->data.max_src_conn_rate.limit;
r.max_src_conn_rate.seconds =
o->data.max_src_conn_rate.seconds;
r.rule_flag |= PFRULE_SRCTRACK |
PFRULE_RULESRCTRACK;
break;
case PF_STATE_OPT_MAX_SRC_NODES:
if (r.max_src_nodes) {
yyerror("state option "
"'max-src-nodes' "
"multiple definitions");
YYERROR;
}
if (o->data.max_src_nodes == 0) {
yyerror("'max-src-nodes' must "
"be > 0");
YYERROR;
}
r.max_src_nodes =
o->data.max_src_nodes;
r.rule_flag |= PFRULE_SRCTRACK |
PFRULE_RULESRCTRACK;
break;
case PF_STATE_OPT_STATELOCK:
if (statelock) {
yyerror("state locking option: "
"multiple definitions");
YYERROR;
}
statelock = 1;
r.rule_flag |= o->data.statelock;
break;
case PF_STATE_OPT_TIMEOUT:
if (o->data.timeout.number ==
PFTM_ADAPTIVE_START ||
o->data.timeout.number ==
PFTM_ADAPTIVE_END)
adaptive = 1;
if (r.timeout[o->data.timeout.number]) {
yyerror("state timeout %s "
"multiple definitions",
pf_timeouts[o->data.
timeout.number].name);
YYERROR;
}
r.timeout[o->data.timeout.number] =
o->data.timeout.seconds;
}
o = o->next;
free(p);
}
/* 'flags S/SA' by default on stateful rules */
if (!r.action && !r.flags && !r.flagset &&
!$9.fragment && !($9.marker & FOM_FLAGS) &&
r.keep_state) {
r.flags = parse_flags("S");
r.flagset = parse_flags("SA");
}
if (!adaptive && r.max_states) {
r.timeout[PFTM_ADAPTIVE_START] =
(r.max_states / 10) * 6;
r.timeout[PFTM_ADAPTIVE_END] =
(r.max_states / 10) * 12;
}
if (r.rule_flag & PFRULE_SRCTRACK) {
if (srctrack == PF_SRCTRACK_GLOBAL &&
r.max_src_nodes) {
yyerror("'max-src-nodes' is "
"incompatible with "
"'source-track global'");
YYERROR;
}
if (srctrack == PF_SRCTRACK_GLOBAL &&
r.max_src_conn) {
yyerror("'max-src-conn' is "
"incompatible with "
"'source-track global'");
YYERROR;
}
if (srctrack == PF_SRCTRACK_GLOBAL &&
r.max_src_conn_rate.seconds) {
yyerror("'max-src-conn-rate' is "
"incompatible with "
"'source-track global'");
YYERROR;
}
if (r.timeout[PFTM_SRC_NODE] <
r.max_src_conn_rate.seconds)
r.timeout[PFTM_SRC_NODE] =
r.max_src_conn_rate.seconds;
r.rule_flag |= PFRULE_SRCTRACK;
if (srctrack == PF_SRCTRACK_RULE)
r.rule_flag |= PFRULE_RULESRCTRACK;
}
if (r.keep_state && !statelock)
r.rule_flag |= default_statelock;
if ($9.fragment)
r.rule_flag |= PFRULE_FRAGMENT;
r.allow_opts = $9.allowopts;
decide_address_family($8.src.host, &r.af);
decide_address_family($8.dst.host, &r.af);
if ($5.rt) {
if (!r.direction) {
yyerror("direction must be explicit "
"with rules that specify routing");
YYERROR;
}
r.rt = $5.rt;
r.rpool.opts = $5.pool_opts;
if ($5.key != NULL)
memcpy(&r.rpool.key, $5.key,
sizeof(struct pf_poolhashkey));
}
if (r.rt && r.rt != PF_FASTROUTE) {
decide_address_family($5.host, &r.af);
remove_invalid_hosts(&$5.host, &r.af);
if ($5.host == NULL) {
yyerror("no routing address with "
"matching address family found.");
YYERROR;
}
if ((r.rpool.opts & PF_POOL_TYPEMASK) ==
PF_POOL_NONE && ($5.host->next != NULL ||
$5.host->addr.type == PF_ADDR_TABLE ||
DYNIF_MULTIADDR($5.host->addr)))
r.rpool.opts |= PF_POOL_ROUNDROBIN;
if ((r.rpool.opts & PF_POOL_TYPEMASK) !=
PF_POOL_ROUNDROBIN &&
disallow_table($5.host, "tables are only "
"supported in round-robin routing pools"))
YYERROR;
if ((r.rpool.opts & PF_POOL_TYPEMASK) !=
PF_POOL_ROUNDROBIN &&
disallow_alias($5.host, "interface (%s) "
"is only supported in round-robin "
"routing pools"))
YYERROR;
if ($5.host->next != NULL) {
if ((r.rpool.opts & PF_POOL_TYPEMASK) !=
PF_POOL_ROUNDROBIN) {
yyerror("r.rpool.opts must "
"be PF_POOL_ROUNDROBIN");
YYERROR;
}
}
}
if ($9.queues.qname != NULL) {
if (strlcpy(r.qname, $9.queues.qname,
sizeof(r.qname)) >= sizeof(r.qname)) {
yyerror("rule qname too long (max "
"%d chars)", sizeof(r.qname)-1);
YYERROR;
}
free($9.queues.qname);
}
if ($9.queues.pqname != NULL) {
if (strlcpy(r.pqname, $9.queues.pqname,
sizeof(r.pqname)) >= sizeof(r.pqname)) {
yyerror("rule pqname too long (max "
"%d chars)", sizeof(r.pqname)-1);
YYERROR;
}
free($9.queues.pqname);
}
expand_rule(&r, $4, $5.host, $7, $8.src_os,
$8.src.host, $8.src.port, $8.dst.host, $8.dst.port,
$9.uid, $9.gid, $9.icmpspec, "");
}
;
opt_statelock : statelock
{
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(EXIT_FAILURE, "opt_statelock: calloc");
$$->type = PF_STATE_OPT_STATELOCK;
$$->data.statelock = $1;
$$->next = NULL;
$$->tail = $$;
}
| /* empty */ {
$$ = NULL;
}
;
filter_opts : {
bzero(&filter_opts, sizeof filter_opts);
filter_opts.rtableid = -1;
}
filter_opts_l
{ $$ = filter_opts; }
| /* empty */ {
bzero(&filter_opts, sizeof filter_opts);
filter_opts.rtableid = -1;
$$ = filter_opts;
}
;
filter_opts_l : filter_opts_l filter_opt
| filter_opt
;
filter_opt : USER uids {
if (filter_opts.uid)
$2->tail->next = filter_opts.uid;
filter_opts.uid = $2;
}
| GROUP gids {
if (filter_opts.gid)
$2->tail->next = filter_opts.gid;
filter_opts.gid = $2;
}
| flags {
if (filter_opts.marker & FOM_FLAGS) {
yyerror("flags cannot be redefined");
YYERROR;
}
filter_opts.marker |= FOM_FLAGS;
filter_opts.flags.b1 |= $1.b1;
filter_opts.flags.b2 |= $1.b2;
filter_opts.flags.w |= $1.w;
filter_opts.flags.w2 |= $1.w2;
}
| icmpspec {
if (filter_opts.marker & FOM_ICMP) {
yyerror("icmp-type cannot be redefined");
YYERROR;
}
filter_opts.marker |= FOM_ICMP;
filter_opts.icmpspec = $1;
}
| tos {
if (filter_opts.marker & FOM_TOS) {
yyerror("tos cannot be redefined");
YYERROR;
}
filter_opts.marker |= FOM_TOS;
filter_opts.tos = $1;
}
| keep {
if (filter_opts.marker & FOM_KEEP) {
yyerror("modulate or keep cannot be redefined");
YYERROR;
}
filter_opts.marker |= FOM_KEEP;
filter_opts.keep.action = $1.action;
filter_opts.keep.options = $1.options;
}
| FRAGMENT {
filter_opts.fragment = 1;
}
| ALLOWOPTS {
filter_opts.allowopts = 1;
}
| label {
if (filter_opts.label) {
yyerror("label cannot be redefined");
YYERROR;
}
filter_opts.label = $1;
}
| qname {
if (filter_opts.queues.qname) {
yyerror("queue cannot be redefined");
YYERROR;
}
filter_opts.queues = $1;
}
| TAG string {
filter_opts.tag = $2;
}
| not TAGGED string {
filter_opts.match_tag = $3;
filter_opts.match_tag_not = $1;
}
| PROBABILITY STRING {
char *e;
double p = strtod($2, &e);
if (*e == '%') {
p *= 0.01;
e++;
}
if (*e) {
yyerror("invalid probability: %s", $2);
free($2);
YYERROR;
}
p = floor(p * (UINT_MAX+1.0) + 0.5);
if (p < 1.0 || p >= (UINT_MAX+1.0)) {
yyerror("invalid probability: %s", $2);
free($2);
YYERROR;
}
filter_opts.prob = (u_int32_t)p;
free($2);
}
| RTABLE number {
if ($2 > RT_TABLEID_MAX || $2 < 0) {
yyerror("invalid rtable id");
YYERROR;
}
filter_opts.rtableid = $2;
}
;
action : PASS { $$.b1 = PF_PASS; $$.b2 = $$.w = 0; }
| BLOCK blockspec { $$ = $2; $$.b1 = PF_DROP; }
;
blockspec : /* empty */ {
$$.b2 = blockpolicy;
$$.w = returnicmpdefault;
$$.w2 = returnicmp6default;
}
| DROP {
$$.b2 = PFRULE_DROP;
$$.w = 0;
$$.w2 = 0;
}
| RETURNRST {
$$.b2 = PFRULE_RETURNRST;
$$.w = 0;
$$.w2 = 0;
}
| RETURNRST '(' TTL number ')' {
if ($4 > 255) {
yyerror("illegal ttl value %d", $4);
YYERROR;
}
$$.b2 = PFRULE_RETURNRST;
$$.w = $4;
$$.w2 = 0;
}
| RETURNICMP {
$$.b2 = PFRULE_RETURNICMP;
$$.w = returnicmpdefault;
$$.w2 = returnicmp6default;
}
| RETURNICMP6 {
$$.b2 = PFRULE_RETURNICMP;
$$.w = returnicmpdefault;
$$.w2 = returnicmp6default;
}
| RETURNICMP '(' STRING ')' {
$$.b2 = PFRULE_RETURNICMP;
if (!($$.w = parseicmpspec($3, AF_INET))) {
free($3);
YYERROR;
}
free($3);
$$.w2 = returnicmp6default;
}
| RETURNICMP6 '(' STRING ')' {
$$.b2 = PFRULE_RETURNICMP;
$$.w = returnicmpdefault;
if (!($$.w2 = parseicmpspec($3, AF_INET6))) {
free($3);
YYERROR;
}
free($3);
}
| RETURNICMP '(' STRING comma STRING ')' {
$$.b2 = PFRULE_RETURNICMP;
if (!($$.w = parseicmpspec($3, AF_INET)) ||
!($$.w2 = parseicmpspec($5, AF_INET6))) {
free($3);
free($5);
YYERROR;
}
free($3);
free($5);
}
| RETURN {
$$.b2 = PFRULE_RETURN;
$$.w = returnicmpdefault;
$$.w2 = returnicmp6default;
}
;
dir : /* empty */ { $$ = 0; }
| IN { $$ = PF_IN; }
| OUT { $$ = PF_OUT; }
;
quick : /* empty */ { $$.quick = 0; }
| QUICK { $$.quick = 1; }
;
logquick : /* empty */ { $$.log = 0; $$.quick = 0; $$.logif = 0; }
| log { $$ = $1; $$.quick = 0; }
| QUICK { $$.quick = 1; $$.log = 0; $$.logif = 0; }
| log QUICK { $$ = $1; $$.quick = 1; }
| QUICK log { $$ = $2; $$.quick = 1; }
;
log : LOG { $$.log = PF_LOG; $$.logif = 0; }
| LOG '(' logopts ')' {
$$.log = PF_LOG | $3.log;
$$.logif = $3.logif;
}
;
logopts : logopt { $$ = $1; }
| logopts comma logopt {
$$.log = $1.log | $3.log;
$$.logif = $3.logif;
if ($$.logif == 0)
$$.logif = $1.logif;
}
;
logopt : ALL { $$.log = PF_LOG_ALL; $$.logif = 0; }
| USER { $$.log = PF_LOG_SOCKET_LOOKUP; $$.logif = 0; }
| GROUP { $$.log = PF_LOG_SOCKET_LOOKUP; $$.logif = 0; }
| TO string {
const char *errstr = NULL; /* XXX gcc */
u_int i;
$$.log = 0;
if (strncmp($2, "pflog", 5)) {
yyerror("%s: should be a pflog interface", $2);
free($2);
YYERROR;
}
i = strtonum($2 + 5, 0, 255, &errstr);
if (errstr) {
yyerror("%s: %s", $2, errstr);
free($2);
YYERROR;
}
free($2);
$$.logif = i;
}
;
interface : /* empty */ { $$ = NULL; }
| ON if_item_not { $$ = $2; }
| ON '{' if_list '}' { $$ = $3; }
;
if_list : if_item_not { $$ = $1; }
| if_list comma if_item_not {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
if_item_not : not if_item { $$ = $2; $$->not = $1; }
;
if_item : STRING {
struct node_host *n;
$$ = calloc(1, sizeof(struct node_if));
if ($$ == NULL)
err(1, "if_item: calloc");
if (strlcpy($$->ifname, $1, sizeof($$->ifname)) >=
sizeof($$->ifname)) {
free($1);
free($$);
yyerror("interface name too long");
YYERROR;
}
if ((n = ifa_exists($1)) != NULL)
$$->ifa_flags = n->ifa_flags;
free($1);
$$->not = 0;
$$->next = NULL;
$$->tail = $$;
}
;
af : /* empty */ { $$ = 0; }
| INET { $$ = AF_INET; }
| INET6 { $$ = AF_INET6; }
;
proto : /* empty */ { $$ = NULL; }
| PROTO proto_item { $$ = $2; }
| PROTO '{' proto_list '}' { $$ = $3; }
;
proto_list : proto_item { $$ = $1; }
| proto_list comma proto_item {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
proto_item : STRING {
u_int8_t pr;
u_long ulval;
if (atoul($1, &ulval) == 0) {
if (ulval > 255) {
yyerror("protocol outside range");
free($1);
YYERROR;
}
pr = (u_int8_t)ulval;
} else {
struct protoent *p;
p = getprotobyname($1);
if (p == NULL) {
yyerror("unknown protocol %s", $1);
free($1);
YYERROR;
}
pr = p->p_proto;
}
free($1);
if (pr == 0) {
yyerror("proto 0 cannot be used");
YYERROR;
}
$$ = calloc(1, sizeof(struct node_proto));
if ($$ == NULL)
err(1, "proto_item: calloc");
$$->proto = pr;
$$->next = NULL;
$$->tail = $$;
}
;
fromto : ALL {
$$.src.host = NULL;
$$.src.port = NULL;
$$.dst.host = NULL;
$$.dst.port = NULL;
$$.src_os = NULL;
}
| from os to {
$$.src = $1;
$$.src_os = $2;
$$.dst = $3;
}
;
os : /* empty */ { $$ = NULL; }
| OS xos { $$ = $2; }
| OS '{' os_list '}' { $$ = $3; }
;
xos : STRING {
$$ = calloc(1, sizeof(struct node_os));
if ($$ == NULL)
err(1, "os: calloc");
$$->os = $1;
$$->tail = $$;
}
;
os_list : xos { $$ = $1; }
| os_list comma xos {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
from : /* empty */ {
$$.host = NULL;
$$.port = NULL;
}
| FROM ipportspec {
$$ = $2;
}
;
to : /* empty */ {
$$.host = NULL;
$$.port = NULL;
}
| TO ipportspec {
if (disallow_urpf_failed($2.host, "\"urpf-failed\" is "
"not permitted in a destination address"))
YYERROR;
$$ = $2;
}
;
ipportspec : ipspec {
$$.host = $1;
$$.port = NULL;
}
| ipspec PORT portspec {
$$.host = $1;
$$.port = $3;
}
| PORT portspec {
$$.host = NULL;
$$.port = $2;
}
;
ipspec : ANY { $$ = NULL; }
| xhost { $$ = $1; }
| '{' host_list '}' { $$ = $2; }
;
host_list : ipspec { $$ = $1; }
| host_list comma ipspec {
if ($3 == NULL)
$$ = $1;
else if ($1 == NULL)
$$ = $3;
else {
$1->tail->next = $3;
$1->tail = $3->tail;
$$ = $1;
}
}
;
xhost : not host {
struct node_host *n;
for (n = $2; n != NULL; n = n->next)
n->not = $1;
$$ = $2;
}
| not NOROUTE {
$$ = calloc(1, sizeof(struct node_host));
if ($$ == NULL)
err(1, "xhost: calloc");
$$->addr.type = PF_ADDR_NOROUTE;
$$->next = NULL;
$$->not = $1;
$$->tail = $$;
}
| not URPFFAILED {
$$ = calloc(1, sizeof(struct node_host));
if ($$ == NULL)
err(1, "xhost: calloc");
$$->addr.type = PF_ADDR_URPFFAILED;
$$->next = NULL;
$$->not = $1;
$$->tail = $$;
}
;
host : STRING {
if (($$ = host($1)) == NULL) {
/* error. "any" is handled elsewhere */
free($1);
yyerror("could not parse host specification");
YYERROR;
}
free($1);
}
| STRING '/' number {
char *buf;
if (asprintf(&buf, "%s/%u", $1, $3) == -1)
err(1, "host: asprintf");
free($1);
if (($$ = host(buf)) == NULL) {
/* error. "any" is handled elsewhere */
free(buf);
yyerror("could not parse host specification");
YYERROR;
}
free(buf);
}
| dynaddr
| dynaddr '/' number {
struct node_host *n;
$$ = $1;
for (n = $1; n != NULL; n = n->next)
set_ipmask(n, $3);
}
| '<' STRING '>' {
if (strlen($2) >= PF_TABLE_NAME_SIZE) {
yyerror("table name '%s' too long", $2);
free($2);
YYERROR;
}
$$ = calloc(1, sizeof(struct node_host));
if ($$ == NULL)
err(1, "host: calloc");
$$->addr.type = PF_ADDR_TABLE;
if (strlcpy($$->addr.v.tblname, $2,
sizeof($$->addr.v.tblname)) >=
sizeof($$->addr.v.tblname))
errx(1, "host: strlcpy");
free($2);
$$->next = NULL;
$$->tail = $$;
}
| ROUTE STRING {
$$ = calloc(1, sizeof(struct node_host));
if ($$ == NULL) {
free($2);
err(1, "host: calloc");
}
$$->addr.type = PF_ADDR_RTLABEL;
if (strlcpy($$->addr.v.rtlabelname, $2,
sizeof($$->addr.v.rtlabelname)) >=
sizeof($$->addr.v.rtlabelname)) {
yyerror("route label too long, max %u chars",
sizeof($$->addr.v.rtlabelname) - 1);
free($2);
free($$);
YYERROR;
}
$$->next = NULL;
$$->tail = $$;
free($2);
}
;
number : STRING {
u_long ulval;
if (atoul($1, &ulval) == -1) {
yyerror("%s is not a number", $1);
free($1);
YYERROR;
} else
$$ = ulval;
free($1);
}
;
dynaddr : '(' STRING ')' {
int flags = 0;
char *p, *op;
op = $2;
if (!isalpha((unsigned char)op[0])) {
yyerror("invalid interface name '%s'", op);
free(op);
YYERROR;
}
while ((p = strrchr($2, ':')) != NULL) {
if (!strcmp(p+1, "network"))
flags |= PFI_AFLAG_NETWORK;
else if (!strcmp(p+1, "broadcast"))
flags |= PFI_AFLAG_BROADCAST;
else if (!strcmp(p+1, "peer"))
flags |= PFI_AFLAG_PEER;
else if (!strcmp(p+1, "0"))
flags |= PFI_AFLAG_NOALIAS;
else {
yyerror("interface %s has bad modifier",
$2);
free(op);
YYERROR;
}
*p = '\0';
}
if (flags & (flags - 1) & PFI_AFLAG_MODEMASK) {
free(op);
yyerror("illegal combination of "
"interface modifiers");
YYERROR;
}
$$ = calloc(1, sizeof(struct node_host));
if ($$ == NULL)
err(1, "address: calloc");
$$->af = 0;
set_ipmask($$, 128);
$$->addr.type = PF_ADDR_DYNIFTL;
$$->addr.iflags = flags;
if (strlcpy($$->addr.v.ifname, $2,
sizeof($$->addr.v.ifname)) >=
sizeof($$->addr.v.ifname)) {
free(op);
free($$);
yyerror("interface name too long");
YYERROR;
}
free(op);
$$->next = NULL;
$$->tail = $$;
}
;
portspec : port_item { $$ = $1; }
| '{' port_list '}' { $$ = $2; }
;
port_list : port_item { $$ = $1; }
| port_list comma port_item {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
port_item : port {
$$ = calloc(1, sizeof(struct node_port));
if ($$ == NULL)
err(1, "port_item: calloc");
$$->port[0] = $1.a;
$$->port[1] = $1.b;
if ($1.t)
$$->op = PF_OP_RRG;
else
$$->op = PF_OP_EQ;
$$->next = NULL;
$$->tail = $$;
}
| unaryop port {
if ($2.t) {
yyerror("':' cannot be used with an other "
"port operator");
YYERROR;
}
$$ = calloc(1, sizeof(struct node_port));
if ($$ == NULL)
err(1, "port_item: calloc");
$$->port[0] = $2.a;
$$->port[1] = $2.b;
$$->op = $1;
$$->next = NULL;
$$->tail = $$;
}
| port PORTBINARY port {
if ($1.t || $3.t) {
yyerror("':' cannot be used with an other "
"port operator");
YYERROR;
}
$$ = calloc(1, sizeof(struct node_port));
if ($$ == NULL)
err(1, "port_item: calloc");
$$->port[0] = $1.a;
$$->port[1] = $3.a;
$$->op = $2;
$$->next = NULL;
$$->tail = $$;
}
;
port : STRING {
char *p = strchr($1, ':');
if (p == NULL) {
if (($$.a = getservice($1)) == -1) {
free($1);
YYERROR;
}
$$.b = $$.t = 0;
} else {
int port[2];
*p++ = 0;
if ((port[0] = getservice($1)) == -1 ||
(port[1] = getservice(p)) == -1) {
free($1);
YYERROR;
}
$$.a = port[0];
$$.b = port[1];
$$.t = PF_OP_RRG;
}
free($1);
}
;
uids : uid_item { $$ = $1; }
| '{' uid_list '}' { $$ = $2; }
;
uid_list : uid_item { $$ = $1; }
| uid_list comma uid_item {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
uid_item : uid {
$$ = calloc(1, sizeof(struct node_uid));
if ($$ == NULL)
err(1, "uid_item: calloc");
$$->uid[0] = $1;
$$->uid[1] = $1;
$$->op = PF_OP_EQ;
$$->next = NULL;
$$->tail = $$;
}
| unaryop uid {
if ($2 == UID_MAX && $1 != PF_OP_EQ && $1 != PF_OP_NE) {
yyerror("user unknown requires operator = or "
"!=");
YYERROR;
}
$$ = calloc(1, sizeof(struct node_uid));
if ($$ == NULL)
err(1, "uid_item: calloc");
$$->uid[0] = $2;
$$->uid[1] = $2;
$$->op = $1;
$$->next = NULL;
$$->tail = $$;
}
| uid PORTBINARY uid {
if ($1 == UID_MAX || $3 == UID_MAX) {
yyerror("user unknown requires operator = or "
"!=");
YYERROR;
}
$$ = calloc(1, sizeof(struct node_uid));
if ($$ == NULL)
err(1, "uid_item: calloc");
$$->uid[0] = $1;
$$->uid[1] = $3;
$$->op = $2;
$$->next = NULL;
$$->tail = $$;
}
;
uid : STRING {
u_long ulval;
if (atoul($1, &ulval) == -1) {
if (!strcmp($1, "unknown"))
$$ = UID_MAX;
else {
struct passwd *pw;
if ((pw = getpwnam($1)) == NULL) {
yyerror("unknown user %s", $1);
free($1);
YYERROR;
}
$$ = pw->pw_uid;
}
} else {
if (ulval >= UID_MAX) {
free($1);
yyerror("illegal uid value %lu", ulval);
YYERROR;
}
$$ = ulval;
}
free($1);
}
;
gids : gid_item { $$ = $1; }
| '{' gid_list '}' { $$ = $2; }
;
gid_list : gid_item { $$ = $1; }
| gid_list comma gid_item {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
gid_item : gid {
$$ = calloc(1, sizeof(struct node_gid));
if ($$ == NULL)
err(1, "gid_item: calloc");
$$->gid[0] = $1;
$$->gid[1] = $1;
$$->op = PF_OP_EQ;
$$->next = NULL;
$$->tail = $$;
}
| unaryop gid {
if ($2 == GID_MAX && $1 != PF_OP_EQ && $1 != PF_OP_NE) {
yyerror("group unknown requires operator = or "
"!=");
YYERROR;
}
$$ = calloc(1, sizeof(struct node_gid));
if ($$ == NULL)
err(1, "gid_item: calloc");
$$->gid[0] = $2;
$$->gid[1] = $2;
$$->op = $1;
$$->next = NULL;
$$->tail = $$;
}
| gid PORTBINARY gid {
if ($1 == GID_MAX || $3 == GID_MAX) {
yyerror("group unknown requires operator = or "
"!=");
YYERROR;
}
$$ = calloc(1, sizeof(struct node_gid));
if ($$ == NULL)
err(1, "gid_item: calloc");
$$->gid[0] = $1;
$$->gid[1] = $3;
$$->op = $2;
$$->next = NULL;
$$->tail = $$;
}
;
gid : STRING {
u_long ulval;
if (atoul($1, &ulval) == -1) {
if (!strcmp($1, "unknown"))
$$ = GID_MAX;
else {
struct group *grp;
if ((grp = getgrnam($1)) == NULL) {
yyerror("unknown group %s", $1);
free($1);
YYERROR;
}
$$ = grp->gr_gid;
}
} else {
if (ulval >= GID_MAX) {
yyerror("illegal gid value %lu", ulval);
free($1);
YYERROR;
}
$$ = ulval;
}
free($1);
}
;
flag : STRING {
int f;
if ((f = parse_flags($1)) < 0) {
yyerror("bad flags %s", $1);
free($1);
YYERROR;
}
free($1);
$$.b1 = f;
}
;
flags : FLAGS flag '/' flag { $$.b1 = $2.b1; $$.b2 = $4.b1; }
| FLAGS '/' flag { $$.b1 = 0; $$.b2 = $3.b1; }
| FLAGS ANY { $$.b1 = 0; $$.b2 = 0; }
;
icmpspec : ICMPTYPE icmp_item { $$ = $2; }
| ICMPTYPE '{' icmp_list '}' { $$ = $3; }
| ICMP6TYPE icmp6_item { $$ = $2; }
| ICMP6TYPE '{' icmp6_list '}' { $$ = $3; }
;
icmp_list : icmp_item { $$ = $1; }
| icmp_list comma icmp_item {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
icmp6_list : icmp6_item { $$ = $1; }
| icmp6_list comma icmp6_item {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
icmp_item : icmptype {
$$ = calloc(1, sizeof(struct node_icmp));
if ($$ == NULL)
err(1, "icmp_item: calloc");
$$->type = $1;
$$->code = 0;
$$->proto = IPPROTO_ICMP;
$$->next = NULL;
$$->tail = $$;
}
| icmptype CODE STRING {
const struct icmpcodeent *p;
u_long ulval;
if (atoul($3, &ulval) == 0) {
if (ulval > 255) {
free($3);
yyerror("illegal icmp-code %lu", ulval);
YYERROR;
}
} else {
if ((p = geticmpcodebyname($1-1, $3,
AF_INET)) == NULL) {
yyerror("unknown icmp-code %s", $3);
free($3);
YYERROR;
}
ulval = p->code;
}
free($3);
$$ = calloc(1, sizeof(struct node_icmp));
if ($$ == NULL)
err(1, "icmp_item: calloc");
$$->type = $1;
$$->code = ulval + 1;
$$->proto = IPPROTO_ICMP;
$$->next = NULL;
$$->tail = $$;
}
;
icmp6_item : icmp6type {
$$ = calloc(1, sizeof(struct node_icmp));
if ($$ == NULL)
err(1, "icmp_item: calloc");
$$->type = $1;
$$->code = 0;
$$->proto = IPPROTO_ICMPV6;
$$->next = NULL;
$$->tail = $$;
}
| icmp6type CODE STRING {
const struct icmpcodeent *p;
u_long ulval;
if (atoul($3, &ulval) == 0) {
if (ulval > 255) {
yyerror("illegal icmp6-code %lu",
ulval);
free($3);
YYERROR;
}
} else {
if ((p = geticmpcodebyname($1-1, $3,
AF_INET6)) == NULL) {
yyerror("unknown icmp6-code %s", $3);
free($3);
YYERROR;
}
ulval = p->code;
}
free($3);
$$ = calloc(1, sizeof(struct node_icmp));
if ($$ == NULL)
err(1, "icmp_item: calloc");
$$->type = $1;
$$->code = ulval + 1;
$$->proto = IPPROTO_ICMPV6;
$$->next = NULL;
$$->tail = $$;
}
;
icmptype : STRING {
const struct icmptypeent *p;
u_long ulval;
if (atoul($1, &ulval) == 0) {
if (ulval > 255) {
yyerror("illegal icmp-type %lu", ulval);
free($1);
YYERROR;
}
$$ = ulval + 1;
} else {
if ((p = geticmptypebyname($1, AF_INET)) ==
NULL) {
yyerror("unknown icmp-type %s", $1);
free($1);
YYERROR;
}
$$ = p->type + 1;
}
free($1);
}
;
icmp6type : STRING {
const struct icmptypeent *p;
u_long ulval;
if (atoul($1, &ulval) == 0) {
if (ulval > 255) {
yyerror("illegal icmp6-type %lu",
ulval);
free($1);
YYERROR;
}
$$ = ulval + 1;
} else {
if ((p = geticmptypebyname($1, AF_INET6)) ==
NULL) {
yyerror("unknown icmp6-type %s", $1);
free($1);
YYERROR;
}
$$ = p->type + 1;
}
free($1);
}
;
tos : TOS STRING {
if (!strcmp($2, "lowdelay"))
$$ = IPTOS_LOWDELAY;
else if (!strcmp($2, "throughput"))
$$ = IPTOS_THROUGHPUT;
else if (!strcmp($2, "reliability"))
$$ = IPTOS_RELIABILITY;
else if ($2[0] == '0' && $2[1] == 'x')
$$ = strtoul($2, NULL, 16);
else
$$ = strtoul($2, NULL, 10);
if (!$$ || $$ > 255) {
yyerror("illegal tos value %s", $2);
free($2);
YYERROR;
}
free($2);
}
;
sourcetrack : SOURCETRACK { $$ = PF_SRCTRACK; }
| SOURCETRACK GLOBAL { $$ = PF_SRCTRACK_GLOBAL; }
| SOURCETRACK RULE { $$ = PF_SRCTRACK_RULE; }
;
statelock : IFBOUND {
$$ = PFRULE_IFBOUND;
}
| FLOATING {
$$ = 0;
}
;
keep : NO STATE {
$$.action = 0;
$$.options = NULL;
}
| KEEP STATE state_opt_spec {
$$.action = PF_STATE_NORMAL;
$$.options = $3;
}
| MODULATE STATE state_opt_spec {
$$.action = PF_STATE_MODULATE;
$$.options = $3;
}
| SYNPROXY STATE state_opt_spec {
$$.action = PF_STATE_SYNPROXY;
$$.options = $3;
}
;
flush : /* empty */ { $$ = 0; }
| FLUSH { $$ = PF_FLUSH; }
| FLUSH GLOBAL {
$$ = PF_FLUSH | PF_FLUSH_GLOBAL;
}
;
state_opt_spec : '(' state_opt_list ')' { $$ = $2; }
| /* empty */ { $$ = NULL; }
;
state_opt_list : state_opt_item { $$ = $1; }
| state_opt_list comma state_opt_item {
$1->tail->next = $3;
$1->tail = $3;
$$ = $1;
}
;
state_opt_item : MAXIMUM number {
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
$$->type = PF_STATE_OPT_MAX;
$$->data.max_states = $2;
$$->next = NULL;
$$->tail = $$;
}
| NOSYNC {
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
$$->type = PF_STATE_OPT_NOSYNC;
$$->next = NULL;
$$->tail = $$;
}
| MAXSRCSTATES number {
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
$$->type = PF_STATE_OPT_MAX_SRC_STATES;
$$->data.max_src_states = $2;
$$->next = NULL;
$$->tail = $$;
}
| MAXSRCCONN number {
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
$$->type = PF_STATE_OPT_MAX_SRC_CONN;
$$->data.max_src_conn = $2;
$$->next = NULL;
$$->tail = $$;
}
| MAXSRCCONNRATE number '/' number {
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
$$->type = PF_STATE_OPT_MAX_SRC_CONN_RATE;
$$->data.max_src_conn_rate.limit = $2;
$$->data.max_src_conn_rate.seconds = $4;
$$->next = NULL;
$$->tail = $$;
}
| OVERLOAD '<' STRING '>' flush {
if (strlen($3) >= PF_TABLE_NAME_SIZE) {
yyerror("table name '%s' too long", $3);
free($3);
YYERROR;
}
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
if (strlcpy($$->data.overload.tblname, $3,
PF_TABLE_NAME_SIZE) >= PF_TABLE_NAME_SIZE)
errx(1, "state_opt_item: strlcpy");
free($3);
$$->type = PF_STATE_OPT_OVERLOAD;
$$->data.overload.flush = $5;
$$->next = NULL;
$$->tail = $$;
}
| MAXSRCNODES number {
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
$$->type = PF_STATE_OPT_MAX_SRC_NODES;
$$->data.max_src_nodes = $2;
$$->next = NULL;
$$->tail = $$;
}
| sourcetrack {
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
$$->type = PF_STATE_OPT_SRCTRACK;
$$->data.src_track = $1;
$$->next = NULL;
$$->tail = $$;
}
| statelock {
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
$$->type = PF_STATE_OPT_STATELOCK;
$$->data.statelock = $1;
$$->next = NULL;
$$->tail = $$;
}
| STRING number {
int i;
for (i = 0; pf_timeouts[i].name &&
strcmp(pf_timeouts[i].name, $1); ++i)
; /* nothing */
if (!pf_timeouts[i].name) {
yyerror("illegal timeout name %s", $1);
free($1);
YYERROR;
}
if (strchr(pf_timeouts[i].name, '.') == NULL) {
yyerror("illegal state timeout %s", $1);
free($1);
YYERROR;
}
free($1);
$$ = calloc(1, sizeof(struct node_state_opt));
if ($$ == NULL)
err(1, "state_opt_item: calloc");
$$->type = PF_STATE_OPT_TIMEOUT;
$$->data.timeout.number = pf_timeouts[i].timeout;
$$->data.timeout.seconds = $2;
$$->next = NULL;
$$->tail = $$;
}
;
label : LABEL STRING {
$$ = $2;
}
;
qname : QUEUE STRING {
$$.qname = $2;
}
| QUEUE '(' STRING ')' {
$$.qname = $3;
}
| QUEUE '(' STRING comma STRING ')' {
$$.qname = $3;
$$.pqname = $5;
}
;
no : /* empty */ { $$ = 0; }
| NO { $$ = 1; }
;
rport : STRING {
char *p = strchr($1, ':');
if (p == NULL) {
if (($$.a = getservice($1)) == -1) {
free($1);
YYERROR;
}
$$.b = $$.t = 0;
} else if (!strcmp(p+1, "*")) {
*p = 0;
if (($$.a = getservice($1)) == -1) {
free($1);
YYERROR;
}
$$.b = 0;
$$.t = 1;
} else {
*p++ = 0;
if (($$.a = getservice($1)) == -1 ||
($$.b = getservice(p)) == -1) {
free($1);
YYERROR;
}
if ($$.a == $$.b)
$$.b = 0;
$$.t = 0;
}
free($1);
}
;
redirspec : host { $$ = $1; }
| '{' redir_host_list '}' { $$ = $2; }
;
redir_host_list : host { $$ = $1; }
| redir_host_list comma host {
$1->tail->next = $3;
$1->tail = $3->tail;
$$ = $1;
}
;
redirpool : /* empty */ { $$ = NULL; }
| ARROW redirspec {
$$ = calloc(1, sizeof(struct redirection));
if ($$ == NULL)
err(1, "redirection: calloc");
$$->host = $2;
$$->rport.a = $$->rport.b = $$->rport.t = 0;
}
| ARROW redirspec PORT rport {
$$ = calloc(1, sizeof(struct redirection));
if ($$ == NULL)
err(1, "redirection: calloc");
$$->host = $2;
$$->rport = $4;
}
;
hashkey : /* empty */
{
$$ = calloc(1, sizeof(struct pf_poolhashkey));
if ($$ == NULL)
err(1, "hashkey: calloc");
$$->key32[0] = arc4random();
$$->key32[1] = arc4random();
$$->key32[2] = arc4random();
$$->key32[3] = arc4random();
}
| string
{
if (!strncmp($1, "0x", 2)) {
if (strlen($1) != 34) {
free($1);
yyerror("hex key must be 128 bits "
"(32 hex digits) long");
YYERROR;
}
$$ = calloc(1, sizeof(struct pf_poolhashkey));
if ($$ == NULL)
err(1, "hashkey: calloc");
if (sscanf($1, "0x%8x%8x%8x%8x",
&$$->key32[0], &$$->key32[1],
&$$->key32[2], &$$->key32[3]) != 4) {
free($$);
free($1);
yyerror("invalid hex key");
YYERROR;
}
} else {
MD5_CTX context;
$$ = calloc(1, sizeof(struct pf_poolhashkey));
if ($$ == NULL)
err(1, "hashkey: calloc");
MD5Init(&context);
MD5Update(&context, (unsigned char *)$1,
strlen($1));
MD5Final((unsigned char *)$$, &context);
HTONL($$->key32[0]);
HTONL($$->key32[1]);
HTONL($$->key32[2]);
HTONL($$->key32[3]);
}
free($1);
}
;
pool_opts : { bzero(&pool_opts, sizeof pool_opts); }
pool_opts_l
{ $$ = pool_opts; }
| /* empty */ {
bzero(&pool_opts, sizeof pool_opts);
$$ = pool_opts;
}
;
pool_opts_l : pool_opts_l pool_opt
| pool_opt
;
pool_opt : BITMASK {
if (pool_opts.type) {
yyerror("pool type cannot be redefined");
YYERROR;
}
pool_opts.type = PF_POOL_BITMASK;
}
| RANDOM {
if (pool_opts.type) {
yyerror("pool type cannot be redefined");
YYERROR;
}
pool_opts.type = PF_POOL_RANDOM;
}
| SOURCEHASH hashkey {
if (pool_opts.type) {
yyerror("pool type cannot be redefined");
YYERROR;
}
pool_opts.type = PF_POOL_SRCHASH;
pool_opts.key = $2;
}
| ROUNDROBIN {
if (pool_opts.type) {
yyerror("pool type cannot be redefined");
YYERROR;
}
pool_opts.type = PF_POOL_ROUNDROBIN;
}
| STATICPORT {
if (pool_opts.staticport) {
yyerror("static-port cannot be redefined");
YYERROR;
}
pool_opts.staticport = 1;
}
| STICKYADDRESS {
if (filter_opts.marker & POM_STICKYADDRESS) {
yyerror("sticky-address cannot be redefined");
YYERROR;
}
pool_opts.marker |= POM_STICKYADDRESS;
pool_opts.opts |= PF_POOL_STICKYADDR;
}
;
redirection : /* empty */ { $$ = NULL; }
| ARROW host {
$$ = calloc(1, sizeof(struct redirection));
if ($$ == NULL)
err(1, "redirection: calloc");
$$->host = $2;
$$->rport.a = $$->rport.b = $$->rport.t = 0;
}
| ARROW host PORT rport {
$$ = calloc(1, sizeof(struct redirection));
if ($$ == NULL)
err(1, "redirection: calloc");
$$->host = $2;
$$->rport = $4;
}
;
natpasslog : /* empty */ { $$.b1 = $$.b2 = 0; $$.w2 = 0; }
| PASS { $$.b1 = 1; $$.b2 = 0; $$.w2 = 0; }
| PASS log { $$.b1 = 1; $$.b2 = $2.log; $$.w2 = $2.logif; }
| log { $$.b1 = 0; $$.b2 = $1.log; $$.w2 = $1.logif; }
;
nataction : no NAT natpasslog {
if ($1 && $3.b1) {
yyerror("\"pass\" not valid with \"no\"");
YYERROR;
}
if ($1)
$$.b1 = PF_NONAT;
else
$$.b1 = PF_NAT;
$$.b2 = $3.b1;
$$.w = $3.b2;
$$.w2 = $3.w2;
}
| no RDR natpasslog {
if ($1 && $3.b1) {
yyerror("\"pass\" not valid with \"no\"");
YYERROR;
}
if ($1)
$$.b1 = PF_NORDR;
else
$$.b1 = PF_RDR;
$$.b2 = $3.b1;
$$.w = $3.b2;
$$.w2 = $3.w2;
}
;
natrule : nataction interface af proto fromto tag tagged rtable
redirpool pool_opts opt_statelock
{
struct pf_rule r;
if (check_rulestate(PFCTL_STATE_NAT))
YYERROR;
memset(&r, 0, sizeof(r));
r.action = $1.b1;
r.natpass = $1.b2;
r.log = $1.w;
r.logif = $1.w2;
r.af = $3;
if (!r.af) {
if ($5.src.host && $5.src.host->af &&
!$5.src.host->ifindex)
r.af = $5.src.host->af;
else if ($5.dst.host && $5.dst.host->af &&
!$5.dst.host->ifindex)
r.af = $5.dst.host->af;
}
if ($6 != NULL)
if (strlcpy(r.tagname, $6, PF_TAG_NAME_SIZE) >=
PF_TAG_NAME_SIZE) {
yyerror("tag too long, max %u chars",
PF_TAG_NAME_SIZE - 1);
YYERROR;
}
if ($7.name)
if (strlcpy(r.match_tagname, $7.name,
PF_TAG_NAME_SIZE) >= PF_TAG_NAME_SIZE) {
yyerror("tag too long, max %u chars",
PF_TAG_NAME_SIZE - 1);
YYERROR;
}
r.match_tag_not = $7.neg;
r.rtableid = $8;
if (r.action == PF_NONAT || r.action == PF_NORDR) {
if ($9 != NULL) {
yyerror("translation rule with 'no' "
"does not need '->'");
YYERROR;
}
} else {
if ($9 == NULL || $9->host == NULL) {
yyerror("translation rule requires '-> "
"address'");
YYERROR;
}
if (!r.af && ! $9->host->ifindex)
r.af = $9->host->af;
remove_invalid_hosts(&$9->host, &r.af);
if (invalid_redirect($9->host, r.af))
YYERROR;
if (check_netmask($9->host, r.af))
YYERROR;
r.rpool.proxy_port[0] = ntohs($9->rport.a);
switch (r.action) {
case PF_RDR:
if (!$9->rport.b && $9->rport.t &&
$5.dst.port != NULL) {
r.rpool.proxy_port[1] =
ntohs($9->rport.a) +
(ntohs(
$5.dst.port->port[1]) -
ntohs(
$5.dst.port->port[0]));
} else
r.rpool.proxy_port[1] =
ntohs($9->rport.b);
break;
case PF_NAT:
r.rpool.proxy_port[1] =
ntohs($9->rport.b);
if (!r.rpool.proxy_port[0] &&
!r.rpool.proxy_port[1]) {
r.rpool.proxy_port[0] =
PF_NAT_PROXY_PORT_LOW;
r.rpool.proxy_port[1] =
PF_NAT_PROXY_PORT_HIGH;
} else if (!r.rpool.proxy_port[1])
r.rpool.proxy_port[1] =
r.rpool.proxy_port[0];
break;
default:
break;
}
r.rpool.opts = $10.type;
if ((r.rpool.opts & PF_POOL_TYPEMASK) ==
PF_POOL_NONE && ($9->host->next != NULL ||
$9->host->addr.type == PF_ADDR_TABLE ||
DYNIF_MULTIADDR($9->host->addr)))
r.rpool.opts = PF_POOL_ROUNDROBIN;
if ((r.rpool.opts & PF_POOL_TYPEMASK) !=
PF_POOL_ROUNDROBIN &&
disallow_table($9->host, "tables are only "
"supported in round-robin redirection "
"pools"))
YYERROR;
if ((r.rpool.opts & PF_POOL_TYPEMASK) !=
PF_POOL_ROUNDROBIN &&
disallow_alias($9->host, "interface (%s) "
"is only supported in round-robin "
"redirection pools"))
YYERROR;
if ($9->host->next != NULL) {
if ((r.rpool.opts & PF_POOL_TYPEMASK) !=
PF_POOL_ROUNDROBIN) {
yyerror("only round-robin "
"valid for multiple "
"redirection addresses");
YYERROR;
}
}
}
if ($10.key != NULL)
memcpy(&r.rpool.key, $10.key,
sizeof(struct pf_poolhashkey));
if ($10.opts)
r.rpool.opts |= $10.opts;
if ($10.staticport) {
if (r.action != PF_NAT) {
yyerror("the 'static-port' option is "
"only valid with nat rules");
YYERROR;
}
if (r.rpool.proxy_port[0] !=
PF_NAT_PROXY_PORT_LOW &&
r.rpool.proxy_port[1] !=
PF_NAT_PROXY_PORT_HIGH) {
yyerror("the 'static-port' option can't"
" be used when specifying a port"
" range");
YYERROR;
}
r.rpool.proxy_port[0] = 0;
r.rpool.proxy_port[1] = 0;
}
if ($11 == NULL)
r.rule_flag |= default_statelock;
else {
r.rule_flag |= $11->data.statelock;
free($11);
}
expand_rule(&r, $2, $9 == NULL ? NULL : $9->host, $4,
$5.src_os, $5.src.host, $5.src.port, $5.dst.host,
$5.dst.port, 0, 0, 0, "");
free($9);
}
;
binatrule : no BINAT natpasslog interface af proto FROM host TO ipspec tag
tagged rtable redirection
{
struct pf_rule binat;
struct pf_pooladdr *pa;
if (check_rulestate(PFCTL_STATE_NAT))
YYERROR;
if (disallow_urpf_failed($10, "\"urpf-failed\" is not "
"permitted as a binat destination"))
YYERROR;
memset(&binat, 0, sizeof(binat));
if ($1 && $3.b1) {
yyerror("\"pass\" not valid with \"no\"");
YYERROR;
}
if ($1)
binat.action = PF_NOBINAT;
else
binat.action = PF_BINAT;
binat.natpass = $3.b1;
binat.log = $3.b2;
binat.logif = $3.w2;
binat.af = $5;
if (!binat.af && $8 != NULL && $8->af)
binat.af = $8->af;
if (!binat.af && $10 != NULL && $10->af)
binat.af = $10->af;
if (!binat.af && $14 != NULL && $14->host)
binat.af = $14->host->af;
if (!binat.af) {
yyerror("address family (inet/inet6) "
"undefined");
YYERROR;
}
if ($4 != NULL) {
memcpy(binat.ifname, $4->ifname,
sizeof(binat.ifname));
binat.ifnot = $4->not;
free($4);
}
if ($11 != NULL)
if (strlcpy(binat.tagname, $11,
PF_TAG_NAME_SIZE) >= PF_TAG_NAME_SIZE) {
yyerror("tag too long, max %u chars",
PF_TAG_NAME_SIZE - 1);
YYERROR;
}
if ($12.name)
if (strlcpy(binat.match_tagname, $12.name,
PF_TAG_NAME_SIZE) >= PF_TAG_NAME_SIZE) {
yyerror("tag too long, max %u chars",
PF_TAG_NAME_SIZE - 1);
YYERROR;
}
binat.match_tag_not = $12.neg;
binat.rtableid = $13;
if ($6 != NULL) {
binat.proto = $6->proto;
free($6);
}
if ($8 != NULL && disallow_table($8, "invalid use of "
"table <%s> as the source address of a binat rule"))
YYERROR;
if ($8 != NULL && disallow_alias($8, "invalid use of "
"interface (%s) as the source address of a binat "
"rule"))
YYERROR;
if ($14 != NULL && $14->host != NULL && disallow_table(
$14->host, "invalid use of table <%s> as the "
"redirect address of a binat rule"))
YYERROR;
if ($14 != NULL && $14->host != NULL && disallow_alias(
$14->host, "invalid use of interface (%s) as the "
"redirect address of a binat rule"))
YYERROR;
if ($8 != NULL) {
if ($8->next) {
yyerror("multiple binat ip addresses");
YYERROR;
}
if ($8->addr.type == PF_ADDR_DYNIFTL)
$8->af = binat.af;
if ($8->af != binat.af) {
yyerror("binat ip versions must match");
YYERROR;
}
if (check_netmask($8, binat.af))
YYERROR;
memcpy(&binat.src.addr, &$8->addr,
sizeof(binat.src.addr));
free($8);
}
if ($10 != NULL) {
if ($10->next) {
yyerror("multiple binat ip addresses");
YYERROR;
}
if ($10->af != binat.af && $10->af) {
yyerror("binat ip versions must match");
YYERROR;
}
if (check_netmask($10, binat.af))
YYERROR;
memcpy(&binat.dst.addr, &$10->addr,
sizeof(binat.dst.addr));
binat.dst.neg = $10->not;
free($10);
}
if (binat.action == PF_NOBINAT) {
if ($14 != NULL) {
yyerror("'no binat' rule does not need"
" '->'");
YYERROR;
}
} else {
if ($14 == NULL || $14->host == NULL) {
yyerror("'binat' rule requires"
" '-> address'");
YYERROR;
}
remove_invalid_hosts(&$14->host, &binat.af);
if (invalid_redirect($14->host, binat.af))
YYERROR;
if ($14->host->next != NULL) {
yyerror("binat rule must redirect to "
"a single address");
YYERROR;
}
if (check_netmask($14->host, binat.af))
YYERROR;
if (!PF_AZERO(&binat.src.addr.v.a.mask,
binat.af) &&
!PF_AEQ(&binat.src.addr.v.a.mask,
&$14->host->addr.v.a.mask, binat.af)) {
yyerror("'binat' source mask and "
"redirect mask must be the same");
YYERROR;
}
TAILQ_INIT(&binat.rpool.list);
pa = calloc(1, sizeof(struct pf_pooladdr));
if (pa == NULL)
err(1, "binat: calloc");
pa->addr = $14->host->addr;
pa->ifname[0] = 0;
TAILQ_INSERT_TAIL(&binat.rpool.list,
pa, entries);
free($14);
}
pfctl_add_rule(pf, &binat, "");
}
;
tag : /* empty */ { $$ = NULL; }
| TAG STRING { $$ = $2; }
;
tagged : /* empty */ { $$.neg = 0; $$.name = NULL; }
| not TAGGED string { $$.neg = $1; $$.name = $3; }
;
rtable : /* empty */ { $$ = -1; }
| RTABLE number {
if ($2 > RT_TABLEID_MAX || $2 < 0) {
yyerror("invalid rtable id");
YYERROR;
}
$$ = $2;
}
;
route_host : STRING {
$$ = calloc(1, sizeof(struct node_host));
if ($$ == NULL)
err(1, "route_host: calloc");
$$->ifname = $1;
set_ipmask($$, 128);
$$->next = NULL;
$$->tail = $$;
}
| '(' STRING host ')' {
$$ = $3;
$$->ifname = $2;
}
;
route_host_list : route_host { $$ = $1; }
| route_host_list comma route_host {
if ($1->af == 0)
$1->af = $3->af;
if ($1->af != $3->af) {
yyerror("all pool addresses must be in the "
"same address family");
YYERROR;
}
$1->tail->next = $3;
$1->tail = $3->tail;
$$ = $1;
}
;
routespec : route_host { $$ = $1; }
| '{' route_host_list '}' { $$ = $2; }
;
route : /* empty */ {
$$.host = NULL;
$$.rt = 0;
$$.pool_opts = 0;
}
| FASTROUTE {
$$.host = NULL;
$$.rt = PF_FASTROUTE;
$$.pool_opts = 0;
}
| ROUTETO routespec pool_opts {
$$.host = $2;
$$.rt = PF_ROUTETO;
$$.pool_opts = $3.type | $3.opts;
if ($3.key != NULL)
$$.key = $3.key;
}
| REPLYTO routespec pool_opts {
$$.host = $2;
$$.rt = PF_REPLYTO;
$$.pool_opts = $3.type | $3.opts;
if ($3.key != NULL)
$$.key = $3.key;
}
| DUPTO routespec pool_opts {
$$.host = $2;
$$.rt = PF_DUPTO;
$$.pool_opts = $3.type | $3.opts;
if ($3.key != NULL)
$$.key = $3.key;
}
;
timeout_spec : STRING number
{
if (check_rulestate(PFCTL_STATE_OPTION)) {
free($1);
YYERROR;
}
if (pfctl_set_timeout(pf, $1, $2, 0) != 0) {
yyerror("unknown timeout %s", $1);
free($1);
YYERROR;
}
free($1);
}
;
timeout_list : timeout_list comma timeout_spec
| timeout_spec
;
limit_spec : STRING number
{
if (check_rulestate(PFCTL_STATE_OPTION)) {
free($1);
YYERROR;
}
if (pfctl_set_limit(pf, $1, $2) != 0) {
yyerror("unable to set limit %s %u", $1, $2);
free($1);
YYERROR;
}
free($1);
}
;
limit_list : limit_list comma limit_spec
| limit_spec
;
comma : ','
| /* empty */
;
yesno : NO { $$ = 0; }
| STRING {
if (!strcmp($1, "yes"))
$$ = 1;
else {
yyerror("invalid value '%s', expected 'yes' "
"or 'no'", $1);
free($1);
YYERROR;
}
free($1);
}
;
unaryop : '=' { $$ = PF_OP_EQ; }
| '!' '=' { $$ = PF_OP_NE; }
| '<' '=' { $$ = PF_OP_LE; }
| '<' { $$ = PF_OP_LT; }
| '>' '=' { $$ = PF_OP_GE; }
| '>' { $$ = PF_OP_GT; }
;
%%
int
yyerror(const char *fmt, ...)
{
va_list ap;
extern const char *infile;
errors = 1;
va_start(ap, fmt);
fprintf(stderr, "%s:%d: ", infile, yylval.lineno);
vfprintf(stderr, fmt, ap);
fprintf(stderr, "\n");
va_end(ap);
return (0);
}
int
disallow_table(struct node_host *h, const char *fmt)
{
for (; h != NULL; h = h->next)
if (h->addr.type == PF_ADDR_TABLE) {
yyerror(fmt, h->addr.v.tblname);
return (1);
}
return (0);
}
int
disallow_urpf_failed(struct node_host *h, const char *fmt)
{
for (; h != NULL; h = h->next)
if (h->addr.type == PF_ADDR_URPFFAILED) {
yyerror(fmt);
return (1);
}
return (0);
}
int
disallow_alias(struct node_host *h, const char *fmt)
{
for (; h != NULL; h = h->next)
if (DYNIF_MULTIADDR(h->addr)) {
yyerror(fmt, h->addr.v.tblname);
return (1);
}
return (0);
}
int
rule_consistent(struct pf_rule *r, int anchor_call)
{
int problems = 0;
switch (r->action) {
case PF_PASS:
case PF_DROP:
case PF_SCRUB:
case PF_NOSCRUB:
problems = filter_consistent(r, anchor_call);
break;
case PF_NAT:
case PF_NONAT:
problems = nat_consistent(r);
break;
case PF_RDR:
case PF_NORDR:
problems = rdr_consistent(r);
break;
case PF_BINAT:
case PF_NOBINAT:
default:
break;
}
return (problems);
}
int
filter_consistent(struct pf_rule *r, int anchor_call)
{
int problems = 0;
if (r->proto != IPPROTO_TCP && r->proto != IPPROTO_UDP &&
(r->src.port_op || r->dst.port_op)) {
yyerror("port only applies to tcp/udp");
problems++;
}
if (r->proto != IPPROTO_ICMP && r->proto != IPPROTO_ICMPV6 &&
(r->type || r->code)) {
yyerror("icmp-type/code only applies to icmp");
problems++;
}
if (!r->af && (r->type || r->code)) {
yyerror("must indicate address family with icmp-type/code");
problems++;
}
if (r->overload_tblname[0] &&
r->max_src_conn == 0 && r->max_src_conn_rate.seconds == 0) {
yyerror("'overload' requires 'max-src-conn' "
"or 'max-src-conn-rate'");
problems++;
}
if ((r->proto == IPPROTO_ICMP && r->af == AF_INET6) ||
(r->proto == IPPROTO_ICMPV6 && r->af == AF_INET)) {
yyerror("proto %s doesn't match address family %s",
r->proto == IPPROTO_ICMP ? "icmp" : "icmp6",
r->af == AF_INET ? "inet" : "inet6");
problems++;
}
if (r->allow_opts && r->action != PF_PASS) {
yyerror("allow-opts can only be specified for pass rules");
problems++;
}
if (r->rule_flag & PFRULE_FRAGMENT && (r->src.port_op ||
r->dst.port_op || r->flagset || r->type || r->code)) {
yyerror("fragments can be filtered only on IP header fields");
problems++;
}
if (r->rule_flag & PFRULE_RETURNRST && r->proto != IPPROTO_TCP) {
yyerror("return-rst can only be applied to TCP rules");
problems++;
}
if (r->max_src_nodes && !(r->rule_flag & PFRULE_RULESRCTRACK)) {
yyerror("max-src-nodes requires 'source-track rule'");
problems++;
}
if (r->action == PF_DROP && r->keep_state) {
yyerror("keep state on block rules doesn't make sense");
problems++;
}
return (-problems);
}
int
nat_consistent(struct pf_rule *r)
{
return (0); /* yeah! */
}
int
rdr_consistent(struct pf_rule *r)
{
int problems = 0;
if (r->proto != IPPROTO_TCP && r->proto != IPPROTO_UDP) {
if (r->src.port_op) {
yyerror("src port only applies to tcp/udp");
problems++;
}
if (r->dst.port_op) {
yyerror("dst port only applies to tcp/udp");
problems++;
}
if (r->rpool.proxy_port[0]) {
yyerror("rpool port only applies to tcp/udp");
problems++;
}
}
if (r->dst.port_op &&
r->dst.port_op != PF_OP_EQ && r->dst.port_op != PF_OP_RRG) {
yyerror("invalid port operator for rdr destination port");
problems++;
}
return (-problems);
}
int
process_tabledef(char *name, struct table_opts *opts)
{
struct pfr_buffer ab;
struct node_tinit *ti;
bzero(&ab, sizeof(ab));
ab.pfrb_type = PFRB_ADDRS;
SIMPLEQ_FOREACH(ti, &opts->init_nodes, entries) {
if (ti->file)
if (pfr_buf_load(&ab, ti->file, 0, append_addr)) {
if (errno)
yyerror("cannot load \"%s\": %s",
ti->file, strerror(errno));
else
yyerror("file \"%s\" contains bad data",
ti->file);
goto _error;
}
if (ti->host)
if (append_addr_host(&ab, ti->host, 0, 0)) {
yyerror("cannot create address buffer: %s",
strerror(errno));
goto _error;
}
}
if (pf->opts & PF_OPT_VERBOSE)
print_tabledef(name, opts->flags, opts->init_addr,
&opts->init_nodes);
if (!(pf->opts & PF_OPT_NOACTION) &&
pfctl_define_table(name, opts->flags, opts->init_addr,
pf->anchor->name, &ab, pf->anchor->ruleset.tticket)) {
yyerror("cannot define table %s: %s", name,
pfr_strerror(errno));
goto _error;
}
pf->tdirty = 1;
pfr_buf_clear(&ab);
return (0);
_error:
pfr_buf_clear(&ab);
return (-1);
}
struct keywords {
const char *k_name;
int k_val;
};
/* macro gore, but you should've seen the prior indentation nightmare... */
#define FREE_LIST(T,r) \
do { \
T *p, *node = r; \
while (node != NULL) { \
p = node; \
node = node->next; \
free(p); \
} \
} while (0)
#define LOOP_THROUGH(T,n,r,C) \
do { \
T *n; \
if (r == NULL) { \
r = calloc(1, sizeof(T)); \
if (r == NULL) \
err(1, "LOOP: calloc"); \
r->next = NULL; \
} \
n = r; \
while (n != NULL) { \
do { \
C; \
} while (0); \
n = n->next; \
} \
} while (0)
void
expand_label_str(char *label, size_t len, const char *srch, const char *repl)
{
char *tmp;
char *p, *q;
if ((tmp = calloc(1, len)) == NULL)
err(1, "expand_label_str: calloc");
p = q = label;
while ((q = strstr(p, srch)) != NULL) {
*q = '\0';
if ((strlcat(tmp, p, len) >= len) ||
(strlcat(tmp, repl, len) >= len))
errx(1, "expand_label: label too long");
q += strlen(srch);
p = q;
}
if (strlcat(tmp, p, len) >= len)
errx(1, "expand_label: label too long");
strlcpy(label, tmp, len); /* always fits */
free(tmp);
}
void
expand_label_if(const char *name, char *label, size_t len, const char *ifname)
{
if (strstr(label, name) != NULL) {
if (!*ifname)
expand_label_str(label, len, name, "any");
else
expand_label_str(label, len, name, ifname);
}
}
void
expand_label_addr(const char *name, char *label, size_t len, sa_family_t af,
struct node_host *h)
{
char tmp[64], tmp_not[66];
if (strstr(label, name) != NULL) {
switch (h->addr.type) {
case PF_ADDR_DYNIFTL:
snprintf(tmp, sizeof(tmp), "(%s)", h->addr.v.ifname);
break;
case PF_ADDR_TABLE:
snprintf(tmp, sizeof(tmp), "<%s>", h->addr.v.tblname);
break;
case PF_ADDR_NOROUTE:
snprintf(tmp, sizeof(tmp), "no-route");
break;
case PF_ADDR_URPFFAILED:
snprintf(tmp, sizeof(tmp), "urpf-failed");
break;
case PF_ADDR_ADDRMASK:
if (!af || (PF_AZERO(&h->addr.v.a.addr, af) &&
PF_AZERO(&h->addr.v.a.mask, af)))
snprintf(tmp, sizeof(tmp), "any");
else {
char a[48];
int bits;
if (inet_ntop(af, &h->addr.v.a.addr, a,
sizeof(a)) == NULL)
snprintf(tmp, sizeof(tmp), "?");
else {
bits = unmask(&h->addr.v.a.mask, af);
if ((af == AF_INET && bits < 32) ||
(af == AF_INET6 && bits < 128))
snprintf(tmp, sizeof(tmp),
"%s/%d", a, bits);
else
snprintf(tmp, sizeof(tmp),
"%s", a);
}
}
break;
default:
snprintf(tmp, sizeof(tmp), "?");
break;
}
if (h->not) {
snprintf(tmp_not, sizeof(tmp_not), "! %s", tmp);
expand_label_str(label, len, name, tmp_not);
} else
expand_label_str(label, len, name, tmp);
}
}
void
expand_label_port(const char *name, char *label, size_t len,
struct node_port *port)
{
char a1[6], a2[6], op[13] = "";
if (strstr(label, name) != NULL) {
snprintf(a1, sizeof(a1), "%u", ntohs(port->port[0]));
snprintf(a2, sizeof(a2), "%u", ntohs(port->port[1]));
if (!port->op)
;
else if (port->op == PF_OP_IRG)
snprintf(op, sizeof(op), "%s><%s", a1, a2);
else if (port->op == PF_OP_XRG)
snprintf(op, sizeof(op), "%s<>%s", a1, a2);
else if (port->op == PF_OP_EQ)
snprintf(op, sizeof(op), "%s", a1);
else if (port->op == PF_OP_NE)
snprintf(op, sizeof(op), "!=%s", a1);
else if (port->op == PF_OP_LT)
snprintf(op, sizeof(op), "<%s", a1);
else if (port->op == PF_OP_LE)
snprintf(op, sizeof(op), "<=%s", a1);
else if (port->op == PF_OP_GT)
snprintf(op, sizeof(op), ">%s", a1);
else if (port->op == PF_OP_GE)
snprintf(op, sizeof(op), ">=%s", a1);
expand_label_str(label, len, name, op);
}
}
void
expand_label_proto(const char *name, char *label, size_t len, u_int8_t proto)
{
struct protoent *pe;
char n[4];
if (strstr(label, name) != NULL) {
pe = getprotobynumber(proto);
if (pe != NULL)
expand_label_str(label, len, name, pe->p_name);
else {
snprintf(n, sizeof(n), "%u", proto);
expand_label_str(label, len, name, n);
}
}
}
void
expand_label_nr(const char *name, char *label, size_t len)
{
char n[11];
if (strstr(label, name) != NULL) {
snprintf(n, sizeof(n), "%u", pf->anchor->match);
expand_label_str(label, len, name, n);
}
}
void
expand_label(char *label, size_t len, const char *ifname, sa_family_t af,
struct node_host *src_host, struct node_port *src_port,
struct node_host *dst_host, struct node_port *dst_port,
u_int8_t proto)
{
expand_label_if("$if", label, len, ifname);
expand_label_addr("$srcaddr", label, len, af, src_host);
expand_label_addr("$dstaddr", label, len, af, dst_host);
expand_label_port("$srcport", label, len, src_port);
expand_label_port("$dstport", label, len, dst_port);
expand_label_proto("$proto", label, len, proto);
expand_label_nr("$nr", label, len);
}
int
expand_altq(struct pf_altq *a, struct node_if *interfaces,
struct node_queue *nqueues, struct node_queue_bw bwspec,
struct node_queue_opt *opts)
{
struct pf_altq pa, pb;
char qname[PF_QNAME_SIZE];
struct node_queue *n;
struct node_queue_bw bw;
int errs = 0;
if ((pf->loadopt & PFCTL_FLAG_ALTQ) == 0) {
FREE_LIST(struct node_if, interfaces);
FREE_LIST(struct node_queue, nqueues);
return (0);
}
LOOP_THROUGH(struct node_if, interface, interfaces,
memcpy(&pa, a, sizeof(struct pf_altq));
if (strlcpy(pa.ifname, interface->ifname,
sizeof(pa.ifname)) >= sizeof(pa.ifname))
errx(1, "expand_altq: strlcpy");
if (interface->not) {
yyerror("altq on ! <interface> is not supported");
errs++;
} else {
if (eval_pfaltq(pf, &pa, &bwspec, opts))
errs++;
else
if (pfctl_add_altq(pf, &pa))
errs++;
if (pf->opts & PF_OPT_VERBOSE) {
print_altq(&pf->paltq->altq, 0,
&bwspec, opts);
if (nqueues && nqueues->tail) {
printf("queue { ");
LOOP_THROUGH(struct node_queue, queue,
nqueues,
printf("%s ",
queue->queue);
);
printf("}");
}
printf("\n");
}
if (pa.scheduler == ALTQT_CBQ ||
pa.scheduler == ALTQT_HFSC) {
/* now create a root queue */
memset(&pb, 0, sizeof(struct pf_altq));
if (strlcpy(qname, "root_", sizeof(qname)) >=
sizeof(qname))
errx(1, "expand_altq: strlcpy");
if (strlcat(qname, interface->ifname,
sizeof(qname)) >= sizeof(qname))
errx(1, "expand_altq: strlcat");
if (strlcpy(pb.qname, qname,
sizeof(pb.qname)) >= sizeof(pb.qname))
errx(1, "expand_altq: strlcpy");
if (strlcpy(pb.ifname, interface->ifname,
sizeof(pb.ifname)) >= sizeof(pb.ifname))
errx(1, "expand_altq: strlcpy");
pb.qlimit = pa.qlimit;
pb.scheduler = pa.scheduler;
bw.bw_absolute = pa.ifbandwidth;
bw.bw_percent = 0;
if (eval_pfqueue(pf, &pb, &bw, opts))
errs++;
else
if (pfctl_add_altq(pf, &pb))
errs++;
}
LOOP_THROUGH(struct node_queue, queue, nqueues,
n = calloc(1, sizeof(struct node_queue));
if (n == NULL)
err(1, "expand_altq: calloc");
if (pa.scheduler == ALTQT_CBQ ||
pa.scheduler == ALTQT_HFSC)
if (strlcpy(n->parent, qname,
sizeof(n->parent)) >=
sizeof(n->parent))
errx(1, "expand_altq: strlcpy");
if (strlcpy(n->queue, queue->queue,
sizeof(n->queue)) >= sizeof(n->queue))
errx(1, "expand_altq: strlcpy");
if (strlcpy(n->ifname, interface->ifname,
sizeof(n->ifname)) >= sizeof(n->ifname))
errx(1, "expand_altq: strlcpy");
n->scheduler = pa.scheduler;
n->next = NULL;
n->tail = n;
if (queues == NULL)
queues = n;
else {
queues->tail->next = n;
queues->tail = n;
}
);
}
);
FREE_LIST(struct node_if, interfaces);
FREE_LIST(struct node_queue, nqueues);
return (errs);
}
int
expand_queue(struct pf_altq *a, struct node_if *interfaces,
struct node_queue *nqueues, struct node_queue_bw bwspec,
struct node_queue_opt *opts)
{
struct node_queue *n, *nq;
struct pf_altq pa;
u_int8_t found = 0;
u_int8_t errs = 0;
if ((pf->loadopt & PFCTL_FLAG_ALTQ) == 0) {
FREE_LIST(struct node_queue, nqueues);
return (0);
}
if (queues == NULL) {
yyerror("queue %s has no parent", a->qname);
FREE_LIST(struct node_queue, nqueues);
return (1);
}
LOOP_THROUGH(struct node_if, interface, interfaces,
LOOP_THROUGH(struct node_queue, tqueue, queues,
if (!strncmp(a->qname, tqueue->queue, PF_QNAME_SIZE) &&
(interface->ifname[0] == 0 ||
(!interface->not && !strncmp(interface->ifname,
tqueue->ifname, IFNAMSIZ)) ||
(interface->not && strncmp(interface->ifname,
tqueue->ifname, IFNAMSIZ)))) {
/* found ourself in queues */
found++;
memcpy(&pa, a, sizeof(struct pf_altq));
if (pa.scheduler != ALTQT_NONE &&
pa.scheduler != tqueue->scheduler) {
yyerror("exactly one scheduler type "
"per interface allowed");
errs++;
goto out;
}
pa.scheduler = tqueue->scheduler;
/* scheduler dependent error checking */
switch (pa.scheduler) {
case ALTQT_PRIQ:
if (nqueues != NULL) {
yyerror("priq queues cannot "
"have child queues");
errs++;
goto out;
}
if (bwspec.bw_absolute > 0 ||
bwspec.bw_percent < 100) {
yyerror("priq doesn't take "
"bandwidth");
errs++;
goto out;
}
break;
default:
break;
}
if (strlcpy(pa.ifname, tqueue->ifname,
sizeof(pa.ifname)) >= sizeof(pa.ifname))
errx(1, "expand_queue: strlcpy");
if (strlcpy(pa.parent, tqueue->parent,
sizeof(pa.parent)) >= sizeof(pa.parent))
errx(1, "expand_queue: strlcpy");
if (eval_pfqueue(pf, &pa, &bwspec, opts))
errs++;
else
if (pfctl_add_altq(pf, &pa))
errs++;
for (nq = nqueues; nq != NULL; nq = nq->next) {
if (!strcmp(a->qname, nq->queue)) {
yyerror("queue cannot have "
"itself as child");
errs++;
continue;
}
n = calloc(1,
sizeof(struct node_queue));
if (n == NULL)
err(1, "expand_queue: calloc");
if (strlcpy(n->parent, a->qname,
sizeof(n->parent)) >=
sizeof(n->parent))
errx(1, "expand_queue strlcpy");
if (strlcpy(n->queue, nq->queue,
sizeof(n->queue)) >=
sizeof(n->queue))
errx(1, "expand_queue strlcpy");
if (strlcpy(n->ifname, tqueue->ifname,
sizeof(n->ifname)) >=
sizeof(n->ifname))
errx(1, "expand_queue strlcpy");
n->scheduler = tqueue->scheduler;
n->next = NULL;
n->tail = n;
if (queues == NULL)
queues = n;
else {
queues->tail->next = n;
queues->tail = n;
}
}
if ((pf->opts & PF_OPT_VERBOSE) && (
(found == 1 && interface->ifname[0] == 0) ||
(found > 0 && interface->ifname[0] != 0))) {
print_queue(&pf->paltq->altq, 0,
&bwspec, interface->ifname[0] != 0,
opts);
if (nqueues && nqueues->tail) {
printf("{ ");
LOOP_THROUGH(struct node_queue,
queue, nqueues,
printf("%s ",
queue->queue);
);
printf("}");
}
printf("\n");
}
}
);
);
out:
FREE_LIST(struct node_queue, nqueues);
FREE_LIST(struct node_if, interfaces);
if (!found) {
yyerror("queue %s has no parent", a->qname);
errs++;
}
if (errs)
return (1);
else
return (0);
}
void
expand_rule(struct pf_rule *r,
struct node_if *interfaces, struct node_host *rpool_hosts,
struct node_proto *protos, struct node_os *src_oses,
struct node_host *src_hosts, struct node_port *src_ports,
struct node_host *dst_hosts, struct node_port *dst_ports,
struct node_uid *uids, struct node_gid *gids, struct node_icmp *icmp_types,
const char *anchor_call)
{
sa_family_t af = r->af;
int added = 0, error = 0;
char ifname[IF_NAMESIZE];
char label[PF_RULE_LABEL_SIZE];
char tagname[PF_TAG_NAME_SIZE];
char match_tagname[PF_TAG_NAME_SIZE];
struct pf_pooladdr *pa;
struct node_host *h;
u_int8_t flags, flagset, keep_state;
if (strlcpy(label, r->label, sizeof(label)) >= sizeof(label))
errx(1, "expand_rule: strlcpy");
if (strlcpy(tagname, r->tagname, sizeof(tagname)) >= sizeof(tagname))
errx(1, "expand_rule: strlcpy");
if (strlcpy(match_tagname, r->match_tagname, sizeof(match_tagname)) >=
sizeof(match_tagname))
errx(1, "expand_rule: strlcpy");
flags = r->flags;
flagset = r->flagset;
keep_state = r->keep_state;
LOOP_THROUGH(struct node_if, interface, interfaces,
LOOP_THROUGH(struct node_proto, proto, protos,
LOOP_THROUGH(struct node_icmp, icmp_type, icmp_types,
LOOP_THROUGH(struct node_host, src_host, src_hosts,
LOOP_THROUGH(struct node_port, src_port, src_ports,
LOOP_THROUGH(struct node_os, src_os, src_oses,
LOOP_THROUGH(struct node_host, dst_host, dst_hosts,
LOOP_THROUGH(struct node_port, dst_port, dst_ports,
LOOP_THROUGH(struct node_uid, uid, uids,
LOOP_THROUGH(struct node_gid, gid, gids,
r->af = af;
/* for link-local IPv6 address, interface must match up */
if ((r->af && src_host->af && r->af != src_host->af) ||
(r->af && dst_host->af && r->af != dst_host->af) ||
(src_host->af && dst_host->af &&
src_host->af != dst_host->af) ||
(src_host->ifindex && dst_host->ifindex &&
src_host->ifindex != dst_host->ifindex) ||
(src_host->ifindex && *interface->ifname &&
src_host->ifindex != if_nametoindex(interface->ifname)) ||
(dst_host->ifindex && *interface->ifname &&
dst_host->ifindex != if_nametoindex(interface->ifname)))
continue;
if (!r->af && src_host->af)
r->af = src_host->af;
else if (!r->af && dst_host->af)
r->af = dst_host->af;
if (*interface->ifname)
strlcpy(r->ifname, interface->ifname,
sizeof(r->ifname));
else if (if_indextoname(src_host->ifindex, ifname))
strlcpy(r->ifname, ifname, sizeof(r->ifname));
else if (if_indextoname(dst_host->ifindex, ifname))
strlcpy(r->ifname, ifname, sizeof(r->ifname));
else
memset(r->ifname, '\0', sizeof(r->ifname));
if (strlcpy(r->label, label, sizeof(r->label)) >=
sizeof(r->label))
errx(1, "expand_rule: strlcpy");
if (strlcpy(r->tagname, tagname, sizeof(r->tagname)) >=
sizeof(r->tagname))
errx(1, "expand_rule: strlcpy");
if (strlcpy(r->match_tagname, match_tagname,
sizeof(r->match_tagname)) >= sizeof(r->match_tagname))
errx(1, "expand_rule: strlcpy");
expand_label(r->label, PF_RULE_LABEL_SIZE, r->ifname, r->af,
src_host, src_port, dst_host, dst_port, proto->proto);
expand_label(r->tagname, PF_TAG_NAME_SIZE, r->ifname, r->af,
src_host, src_port, dst_host, dst_port, proto->proto);
expand_label(r->match_tagname, PF_TAG_NAME_SIZE, r->ifname,
r->af, src_host, src_port, dst_host, dst_port,
proto->proto);
error += check_netmask(src_host, r->af);
error += check_netmask(dst_host, r->af);
r->ifnot = interface->not;
r->proto = proto->proto;
r->src.addr = src_host->addr;
r->src.neg = src_host->not;
r->src.port[0] = src_port->port[0];
r->src.port[1] = src_port->port[1];
r->src.port_op = src_port->op;
r->dst.addr = dst_host->addr;
r->dst.neg = dst_host->not;
r->dst.port[0] = dst_port->port[0];
r->dst.port[1] = dst_port->port[1];
r->dst.port_op = dst_port->op;
r->uid.op = uid->op;
r->uid.uid[0] = uid->uid[0];
r->uid.uid[1] = uid->uid[1];
r->gid.op = gid->op;
r->gid.gid[0] = gid->gid[0];
r->gid.gid[1] = gid->gid[1];
r->type = icmp_type->type;
r->code = icmp_type->code;
if ((keep_state == PF_STATE_MODULATE ||
keep_state == PF_STATE_SYNPROXY) &&
r->proto && r->proto != IPPROTO_TCP)
r->keep_state = PF_STATE_NORMAL;
else
r->keep_state = keep_state;
if (r->proto && r->proto != IPPROTO_TCP) {
r->flags = 0;
r->flagset = 0;
} else {
r->flags = flags;
r->flagset = flagset;
}
if (icmp_type->proto && r->proto != icmp_type->proto) {
yyerror("icmp-type mismatch");
error++;
}
if (src_os && src_os->os) {
r->os_fingerprint = pfctl_get_fingerprint(src_os->os);
if ((pf->opts & PF_OPT_VERBOSE2) &&
r->os_fingerprint == PF_OSFP_NOMATCH)
fprintf(stderr,
"warning: unknown '%s' OS fingerprint\n",
src_os->os);
} else {
r->os_fingerprint = PF_OSFP_ANY;
}
TAILQ_INIT(&r->rpool.list);
for (h = rpool_hosts; h != NULL; h = h->next) {
pa = calloc(1, sizeof(struct pf_pooladdr));
if (pa == NULL)
err(1, "expand_rule: calloc");
pa->addr = h->addr;
if (h->ifname != NULL) {
if (strlcpy(pa->ifname, h->ifname,
sizeof(pa->ifname)) >=
sizeof(pa->ifname))
errx(1, "expand_rule: strlcpy");
} else
pa->ifname[0] = 0;
TAILQ_INSERT_TAIL(&r->rpool.list, pa, entries);
}
if (rule_consistent(r, anchor_call[0]) < 0 || error)
yyerror("skipping rule due to errors");
else {
r->nr = pf->astack[pf->asd]->match++;
pfctl_add_rule(pf, r, anchor_call);
added++;
}
))))))))));
FREE_LIST(struct node_if, interfaces);
FREE_LIST(struct node_proto, protos);
FREE_LIST(struct node_host, src_hosts);
FREE_LIST(struct node_port, src_ports);
FREE_LIST(struct node_os, src_oses);
FREE_LIST(struct node_host, dst_hosts);
FREE_LIST(struct node_port, dst_ports);
FREE_LIST(struct node_uid, uids);
FREE_LIST(struct node_gid, gids);
FREE_LIST(struct node_icmp, icmp_types);
FREE_LIST(struct node_host, rpool_hosts);
if (!added)
yyerror("rule expands to no valid combination");
}
int
expand_skip_interface(struct node_if *interfaces)
{
int errs = 0;
if (!interfaces || (!interfaces->next && !interfaces->not &&
!strcmp(interfaces->ifname, "none"))) {
if (pf->opts & PF_OPT_VERBOSE)
printf("set skip on none\n");
errs = pfctl_set_interface_flags(pf, "", PFI_IFLAG_SKIP, 0);
return (errs);
}
if (pf->opts & PF_OPT_VERBOSE)
printf("set skip on {");
LOOP_THROUGH(struct node_if, interface, interfaces,
if (pf->opts & PF_OPT_VERBOSE)
printf(" %s", interface->ifname);
if (interface->not) {
yyerror("skip on ! <interface> is not supported");
errs++;
} else
errs += pfctl_set_interface_flags(pf,
interface->ifname, PFI_IFLAG_SKIP, 1);
);
if (pf->opts & PF_OPT_VERBOSE)
printf(" }\n");
FREE_LIST(struct node_if, interfaces);
if (errs)
return (1);
else
return (0);
}
#undef FREE_LIST
#undef LOOP_THROUGH
int
check_rulestate(int desired_state)
{
if (require_order && (rulestate > desired_state)) {
yyerror("Rules must be in order: options, normalization, "
"queueing, translation, filtering");
return (1);
}
rulestate = desired_state;
return (0);
}
int
kw_cmp(const void *k, const void *e)
{
return (strcmp(k, ((const struct keywords *)e)->k_name));
}
int
lookup(char *s)
{
/* this has to be sorted always */
static const struct keywords keywords[] = {
{ "all", ALL},
{ "allow-opts", ALLOWOPTS},
{ "altq", ALTQ},
{ "anchor", ANCHOR},
{ "antispoof", ANTISPOOF},
{ "any", ANY},
{ "bandwidth", BANDWIDTH},
{ "binat", BINAT},
{ "binat-anchor", BINATANCHOR},
{ "bitmask", BITMASK},
{ "block", BLOCK},
{ "block-policy", BLOCKPOLICY},
{ "cbq", CBQ},
{ "code", CODE},
{ "crop", FRAGCROP},
{ "debug", DEBUG},
{ "drop", DROP},
{ "drop-ovl", FRAGDROP},
{ "dup-to", DUPTO},
{ "fastroute", FASTROUTE},
{ "file", FILENAME},
{ "fingerprints", FINGERPRINTS},
{ "flags", FLAGS},
{ "floating", FLOATING},
{ "flush", FLUSH},
{ "for", FOR},
{ "fragment", FRAGMENT},
{ "from", FROM},
{ "global", GLOBAL},
{ "group", GROUP},
{ "hfsc", HFSC},
{ "hostid", HOSTID},
{ "icmp-type", ICMPTYPE},
{ "icmp6-type", ICMP6TYPE},
{ "if-bound", IFBOUND},
{ "in", IN},
{ "inet", INET},
{ "inet6", INET6},
{ "keep", KEEP},
{ "label", LABEL},
{ "limit", LIMIT},
{ "linkshare", LINKSHARE},
{ "load", LOAD},
{ "log", LOG},
{ "loginterface", LOGINTERFACE},
{ "max", MAXIMUM},
{ "max-mss", MAXMSS},
{ "max-src-conn", MAXSRCCONN},
{ "max-src-conn-rate", MAXSRCCONNRATE},
{ "max-src-nodes", MAXSRCNODES},
{ "max-src-states", MAXSRCSTATES},
{ "min-ttl", MINTTL},
{ "modulate", MODULATE},
{ "nat", NAT},
{ "nat-anchor", NATANCHOR},
{ "no", NO},
{ "no-df", NODF},
{ "no-route", NOROUTE},
{ "no-sync", NOSYNC},
{ "on", ON},
{ "optimization", OPTIMIZATION},
{ "os", OS},
{ "out", OUT},
{ "overload", OVERLOAD},
{ "pass", PASS},
{ "port", PORT},
{ "priority", PRIORITY},
{ "priq", PRIQ},
{ "probability", PROBABILITY},
{ "proto", PROTO},
{ "qlimit", QLIMIT},
{ "queue", QUEUE},
{ "quick", QUICK},
{ "random", RANDOM},
{ "random-id", RANDOMID},
{ "rdr", RDR},
{ "rdr-anchor", RDRANCHOR},
{ "realtime", REALTIME},
{ "reassemble", REASSEMBLE},
{ "reply-to", REPLYTO},
{ "require-order", REQUIREORDER},
{ "return", RETURN},
{ "return-icmp", RETURNICMP},
{ "return-icmp6", RETURNICMP6},
{ "return-rst", RETURNRST},
{ "round-robin", ROUNDROBIN},
{ "route", ROUTE},
{ "route-to", ROUTETO},
{ "rtable", RTABLE},
{ "rule", RULE},
{ "ruleset-optimization", RULESET_OPTIMIZATION},
{ "scrub", SCRUB},
{ "set", SET},
{ "skip", SKIP},
{ "source-hash", SOURCEHASH},
{ "source-track", SOURCETRACK},
{ "state", STATE},
{ "state-policy", STATEPOLICY},
{ "static-port", STATICPORT},
{ "sticky-address", STICKYADDRESS},
{ "synproxy", SYNPROXY},
{ "table", TABLE},
{ "tag", TAG},
{ "tagged", TAGGED},
{ "tbrsize", TBRSIZE},
{ "timeout", TIMEOUT},
{ "to", TO},
{ "tos", TOS},
{ "ttl", TTL},
{ "upperlimit", UPPERLIMIT},
{ "urpf-failed", URPFFAILED},
{ "user", USER},
};
const struct keywords *p;
p = bsearch(s, keywords, sizeof(keywords)/sizeof(keywords[0]),
sizeof(keywords[0]), kw_cmp);
if (p) {
if (debug > 1)
fprintf(stderr, "%s: %d\n", s, p->k_val);
return (p->k_val);
} else {
if (debug > 1)
fprintf(stderr, "string: %s\n", s);
return (STRING);
}
}
#define MAXPUSHBACK 128
char *parsebuf;
int parseindex;
char pushback_buffer[MAXPUSHBACK];
int pushback_index = 0;
int
lgetc(FILE *f)
{
int c, next;
if (parsebuf) {
/* Read character from the parsebuffer instead of input. */
if (parseindex >= 0) {
c = parsebuf[parseindex++];
if (c != '\0')
return (c);
parsebuf = NULL;
} else
parseindex++;
}
if (pushback_index)
return (pushback_buffer[--pushback_index]);
while ((c = getc(f)) == '\\') {
next = getc(f);
if (next != '\n') {
c = next;
break;
}
yylval.lineno = lineno;
lineno++;
}
if (c == '\t' || c == ' ') {
/* Compress blanks to a single space. */
do {
c = getc(f);
} while (c == '\t' || c == ' ');
ungetc(c, f);
c = ' ';
}
return (c);
}
int
lungetc(int c)
{
if (c == EOF)
return (EOF);
if (parsebuf) {
parseindex--;
if (parseindex >= 0)
return (c);
}
if (pushback_index < MAXPUSHBACK-1)
return (pushback_buffer[pushback_index++] = c);
else
return (EOF);
}
int
findeol(void)
{
int c;
parsebuf = NULL;
pushback_index = 0;
/* skip to either EOF or the first real EOL */
while (1) {
c = lgetc(fin);
if (c == '\n') {
lineno++;
break;
}
if (c == EOF)
break;
}
return (ERROR);
}
int
yylex(void)
{
char buf[8096];
char *p, *val;
int endc, c, next;
int token;
top:
p = buf;
while ((c = lgetc(fin)) == ' ')
; /* nothing */
yylval.lineno = lineno;
if (c == '#')
while ((c = lgetc(fin)) != '\n' && c != EOF)
; /* nothing */
if (c == '$' && parsebuf == NULL) {
while (1) {
if ((c = lgetc(fin)) == EOF)
return (0);
if (p + 1 >= buf + sizeof(buf) - 1) {
yyerror("string too long");
return (findeol());
}
if (isalnum(c) || c == '_') {
*p++ = (char)c;
continue;
}
*p = '\0';
lungetc(c);
break;
}
val = symget(buf);
if (val == NULL) {
yyerror("macro '%s' not defined", buf);
return (findeol());
}
parsebuf = val;
parseindex = 0;
goto top;
}
switch (c) {
case '\'':
case '"':
endc = c;
while (1) {
if ((c = lgetc(fin)) == EOF)
return (0);
if (c == endc) {
*p = '\0';
break;
}
if (c == '\n') {
lineno++;
continue;
}
if (p + 1 >= buf + sizeof(buf) - 1) {
yyerror("string too long");
return (findeol());
}
*p++ = (char)c;
}
yylval.v.string = strdup(buf);
if (yylval.v.string == NULL)
err(1, "yylex: strdup");
return (STRING);
case '<':
next = lgetc(fin);
if (next == '>') {
yylval.v.i = PF_OP_XRG;
return (PORTBINARY);
}
lungetc(next);
break;
case '>':
next = lgetc(fin);
if (next == '<') {
yylval.v.i = PF_OP_IRG;
return (PORTBINARY);
}
lungetc(next);
break;
case '-':
next = lgetc(fin);
if (next == '>')
return (ARROW);
lungetc(next);
break;
}
#define allowed_in_string(x) \
(isalnum(x) || (ispunct(x) && x != '(' && x != ')' && \
x != '{' && x != '}' && x != '<' && x != '>' && \
x != '!' && x != '=' && x != '/' && x != '#' && \
x != ','))
if (isalnum(c) || c == ':' || c == '_') {
do {
*p++ = c;
if ((unsigned)(p-buf) >= sizeof(buf)) {
yyerror("string too long");
return (findeol());
}
} while ((c = lgetc(fin)) != EOF && (allowed_in_string(c)));
lungetc(c);
*p = '\0';
if ((token = lookup(buf)) == STRING)
if ((yylval.v.string = strdup(buf)) == NULL)
err(1, "yylex: strdup");
return (token);
}
if (c == '\n') {
yylval.lineno = lineno;
lineno++;
}
if (c == EOF)
return (0);
return (c);
}
int
parse_rules(FILE *input, struct pfctl *xpf)
{
struct sym *sym, *next;
fin = input;
pf = xpf;
lineno = 1;
errors = 0;
rulestate = PFCTL_STATE_NONE;
returnicmpdefault = (ICMP_UNREACH << 8) | ICMP_UNREACH_PORT;
returnicmp6default =
(ICMP6_DST_UNREACH << 8) | ICMP6_DST_UNREACH_NOPORT;
blockpolicy = PFRULE_DROP;
require_order = 1;
yyparse();
/* Free macros and check which have not been used. */
for (sym = TAILQ_FIRST(&symhead); sym != NULL; sym = next) {
next = TAILQ_NEXT(sym, entries);
if ((pf->opts & PF_OPT_VERBOSE2) && !sym->used)
fprintf(stderr, "warning: macro '%s' not "
"used\n", sym->nam);
free(sym->nam);
free(sym->val);
TAILQ_REMOVE(&symhead, sym, entries);
free(sym);
}
return (errors ? -1 : 0);
}
/*
* Over-designed efficiency is a French and German concept, so how about
* we wait until they discover this ugliness and make it all fancy.
*/
int
symset(const char *nam, const char *val, int persist)
{
struct sym *sym;
for (sym = TAILQ_FIRST(&symhead); sym && strcmp(nam, sym->nam);
sym = TAILQ_NEXT(sym, entries))
; /* nothing */
if (sym != NULL) {
if (sym->persist == 1)
return (0);
else {
free(sym->nam);
free(sym->val);
TAILQ_REMOVE(&symhead, sym, entries);
free(sym);
}
}
if ((sym = calloc(1, sizeof(*sym))) == NULL)
return (-1);
sym->nam = strdup(nam);
if (sym->nam == NULL) {
free(sym);
return (-1);
}
sym->val = strdup(val);
if (sym->val == NULL) {
free(sym->nam);
free(sym);
return (-1);
}
sym->used = 0;
sym->persist = persist;
TAILQ_INSERT_TAIL(&symhead, sym, entries);
return (0);
}
int
pfctl_cmdline_symset(char *s)
{
char *sym, *val;
int ret;
if ((val = strrchr(s, '=')) == NULL)
return (-1);
if ((sym = malloc(strlen(s) - strlen(val) + 1)) == NULL)
err(1, "pfctl_cmdline_symset: malloc");
strlcpy(sym, s, strlen(s) - strlen(val) + 1);
ret = symset(sym, val + 1, 1);
free(sym);
return (ret);
}
char *
symget(const char *nam)
{
struct sym *sym;
TAILQ_FOREACH(sym, &symhead, entries)
if (strcmp(nam, sym->nam) == 0) {
sym->used = 1;
return (sym->val);
}
return (NULL);
}
void
mv_rules(struct pf_ruleset *src, struct pf_ruleset *dst)
{
int i;
struct pf_rule *r;
for (i = 0; i < PF_RULESET_MAX; ++i) {
while ((r = TAILQ_FIRST(src->rules[i].active.ptr))
!= NULL) {
TAILQ_REMOVE(src->rules[i].active.ptr, r, entries);
TAILQ_INSERT_TAIL(dst->rules[i].active.ptr, r, entries);
dst->anchor->match++;
}
src->anchor->match = 0;
while ((r = TAILQ_FIRST(src->rules[i].inactive.ptr))
!= NULL) {
TAILQ_REMOVE(src->rules[i].inactive.ptr, r, entries);
TAILQ_INSERT_TAIL(dst->rules[i].inactive.ptr,
r, entries);
}
}
}
void
decide_address_family(struct node_host *n, sa_family_t *af)
{
if (*af != 0 || n == NULL)
return;
*af = n->af;
while ((n = n->next) != NULL) {
if (n->af != *af) {
*af = 0;
return;
}
}
}
void
remove_invalid_hosts(struct node_host **nh, sa_family_t *af)
{
struct node_host *n = *nh, *prev = NULL;
while (n != NULL) {
if (*af && n->af && n->af != *af) {
/* unlink and free n */
struct node_host *next = n->next;
/* adjust tail pointer */
if (n == (*nh)->tail)
(*nh)->tail = prev;
/* adjust previous node's next pointer */
if (prev == NULL)
*nh = next;
else
prev->next = next;
/* free node */
if (n->ifname != NULL)
free(n->ifname);
free(n);
n = next;
} else {
if (n->af && !*af)
*af = n->af;
prev = n;
n = n->next;
}
}
}
int
invalid_redirect(struct node_host *nh, sa_family_t af)
{
if (!af) {
struct node_host *n;
/* tables and dyniftl are ok without an address family */
for (n = nh; n != NULL; n = n->next) {
if (n->addr.type != PF_ADDR_TABLE &&
n->addr.type != PF_ADDR_DYNIFTL) {
yyerror("address family not given and "
"translation address expands to multiple "
"address families");
return (1);
}
}
}
if (nh == NULL) {
yyerror("no translation address with matching address family "
"found.");
return (1);
}
return (0);
}
int
atoul(char *s, u_long *ulvalp)
{
u_long ulval;
char *ep;
errno = 0;
ulval = strtoul(s, &ep, 0);
if (s[0] == '\0' || *ep != '\0')
return (-1);
if (errno == ERANGE && ulval == ULONG_MAX)
return (-1);
*ulvalp = ulval;
return (0);
}
int
getservice(char *n)
{
struct servent *s;
u_long ulval;
if (atoul(n, &ulval) == 0) {
if (ulval > 65535) {
yyerror("illegal port value %lu", ulval);
return (-1);
}
return (htons(ulval));
} else {
s = getservbyname(n, "tcp");
if (s == NULL)
s = getservbyname(n, "udp");
if (s == NULL) {
yyerror("unknown port %s", n);
return (-1);
}
return (s->s_port);
}
}
int
rule_label(struct pf_rule *r, char *s)
{
if (s) {
if (strlcpy(r->label, s, sizeof(r->label)) >=
sizeof(r->label)) {
yyerror("rule label too long (max %d chars)",
sizeof(r->label)-1);
return (-1);
}
}
return (0);
}
u_int16_t
parseicmpspec(char *w, sa_family_t af)
{
const struct icmpcodeent *p;
u_long ulval;
u_int8_t icmptype;
if (af == AF_INET)
icmptype = returnicmpdefault >> 8;
else
icmptype = returnicmp6default >> 8;
if (atoul(w, &ulval) == -1) {
if ((p = geticmpcodebyname(icmptype, w, af)) == NULL) {
yyerror("unknown icmp code %s", w);
return (0);
}
ulval = p->code;
}
if (ulval > 255) {
yyerror("invalid icmp code %lu", ulval);
return (0);
}
return (icmptype << 8 | ulval);
}
int
pfctl_load_anchors(int dev, struct pfctl *pf, struct pfr_buffer *trans)
{
struct loadanchors *la;
FILE *fin;
TAILQ_FOREACH(la, &loadanchorshead, entries) {
if (pf->opts & PF_OPT_VERBOSE)
fprintf(stderr, "\nLoading anchor %s from %s\n",
la->anchorname, la->filename);
if ((fin = pfctl_fopen(la->filename, "r")) == NULL) {
warn("%s", la->filename);
continue;
}
if (pfctl_rules(dev, la->filename, fin, pf->opts, pf->optimize,
la->anchorname, trans) == -1)
return (-1);
}
return (0);
}