/* $OpenBSD: parse.y,v 1.56 2002/02/27 18:11:45 dhartmei Exp $ */ /* * Copyright (c) 2001 Markus Friedl. All rights reserved. * Copyright (c) 2001 Daniel Hartmeier. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "pfctl_parser.h" static struct pfctl *pf = NULL; static FILE *fin = NULL; static int debug = 0; static int lineno = 1; static int errors = 0; static int natmode = 0; struct node_if { char ifname[IFNAMSIZ]; u_int8_t not; struct node_if *next; }; struct node_proto { u_int8_t proto; struct node_proto *next; }; struct node_host { struct pf_addr addr; struct pf_addr mask; u_int8_t af; u_int8_t not; struct node_host *next; }; struct node_port { u_int16_t port[2]; u_int8_t op; struct node_port *next; }; struct node_icmp { u_int8_t code; u_int8_t type; u_int8_t proto; struct node_icmp *next; }; struct peer { struct node_host *host; struct node_port *port; }; int rule_consistent(struct pf_rule *); int yyparse(void); struct pf_rule_addr *new_addr(void); void ipmask(struct pf_addr *, u_int8_t); void expand_rule_hosts(struct pf_rule *, struct node_if *, struct node_proto *, struct node_host *, struct node_port *, struct node_host *, struct node_port *, struct node_icmp *); void expand_rule_protos(struct pf_rule *, struct node_if *, struct node_proto *, struct node_host *, struct node_port *, struct node_host *, struct node_port *, struct node_icmp *); void expand_rule(struct pf_rule *, struct node_if *, struct node_proto *, struct node_host *, struct node_port *, struct node_host *, struct node_port *, struct node_icmp *); struct sym { struct sym *next; char *nam; char *val; }; struct sym *symhead = NULL; int symset(char *name, char *val); char * symget(char *name); struct ifaddrs *ifa0_lookup(char *ifa_name); struct ifaddrs *ifa4_lookup(char *ifa_name); struct ifaddrs *ifa6_lookup(char *ifa_name); typedef struct { union { u_int32_t number; int i; char *string; struct { u_int8_t b1; u_int8_t b2; u_int16_t w; } 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_port *port; struct peer peer; struct { struct peer src, dst; } fromto; struct { char *string; struct pf_addr *addr; u_int8_t rt; u_int8_t af; } route; struct redirection { struct node_host *address; struct range rport; } *redirection; } v; int lineno; } YYSTYPE; %} %token PASS BLOCK SCRUB RETURN IN OUT LOG LOGALL 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 IPV6ADDR ERROR ALLOWOPTS FASTROUTE ROUTETO DUPTO NO LABEL %token STRING %token NUMBER %token PORTUNARY PORTBINARY %type interface if_list if_item_not if_item %type port icmptype icmp6type minttl %type no dir log quick af keep nodf allowopts %type action flag flags blockspec %type dport rport %type proto proto_list proto_item %type icmpspec icmp_list icmp6_list icmp_item icmp6_item %type fromto %type ipportspec %type ipspec xhost host address host_list IPV6ADDR %type portspec port_list port_item %type route %type redirection %type label %% ruleset : /* empty */ | ruleset '\n' | ruleset pfrule '\n' | ruleset natrule '\n' | ruleset binatrule '\n' | ruleset rdrrule '\n' | ruleset varset '\n' | ruleset error '\n' { errors++; } ; varset : STRING PORTUNARY STRING { if (pf->opts & PF_OPT_VERBOSE) printf("%s = %s\n", $1, $3); if (symset($1, $3) == -1) { yyerror("cannot store variable %s", $1); YYERROR; } } ; pfrule : action dir log quick interface route af proto fromto flags icmpspec keep nodf minttl allowopts label { struct pf_rule r; if (natmode) { yyerror("filter rule not permitted in nat mode"); YYERROR; } memset(&r, 0, sizeof(r)); r.action = $1.b1; if ($1.b2) r.rule_flag |= PFRULE_RETURNRST; else r.return_icmp = $1.w; r.direction = $2; r.log = $3; r.quick = $4; r.af = $7; r.flags = $10.b1; r.flagset = $10.b2; r.keep_state = $12; if ($13) r.rule_flag |= PFRULE_NODF; if ($14) r.min_ttl = $14; r.allow_opts = $15; if ($6.rt) { r.rt = $6.rt; if ($6.string) { memcpy(r.rt_ifname, $6.string, sizeof(r.rt_ifname)); free($6.string); } if ($6.addr) { if (!r.af) r.af = $6.af; else if (r.af != $6.af) { yyerror("address family" " mismatch"); YYERROR; } memcpy(&r.rt_addr, $6.addr, sizeof(r.rt_addr)); free($6.addr); } } if ($16) { if (strlen($16) >= PF_RULE_LABEL_SIZE) { yyerror("rule label too long (max " "%d chars)", PF_RULE_LABEL_SIZE-1); YYERROR; } strcpy(r.label, $16); free($16); } expand_rule(&r, $5, $8, $9.src.host, $9.src.port, $9.dst.host, $9.dst.port, $11); } ; action : PASS { $$.b1 = PF_PASS; $$.b2 = $$.w = 0; } | BLOCK blockspec { $$ = $2; $$.b1 = PF_DROP; } | SCRUB { $$.b1 = PF_SCRUB; $$.b2 = $$.w = 0; } ; blockspec : /* empty */ { $$.b2 = 0; $$.w = 0; } | RETURNRST { $$.b2 = 1; $$.w = 0;} | RETURNICMP { $$.b2 = 0; $$.w = (ICMP_UNREACH << 8) | ICMP_UNREACH_PORT; } | RETURNICMP6 { $$.b2 = 0; $$.w = (ICMP6_DST_UNREACH << 8) | ICMP6_DST_UNREACH_NOPORT; } | RETURNICMP '(' NUMBER ')' { $$.w = (ICMP_UNREACH << 8) | $3; $$.b2 = 0; } | RETURNICMP '(' STRING ')' { struct icmpcodeent *p; if ((p = geticmpcodebyname(ICMP_UNREACH, $3, AF_INET)) == NULL) { yyerror("unknown icmp code %s", $3); YYERROR; } $$.w = (p->type << 8) | p->code; $$.b2 = 0; } | RETURNICMP6 '(' NUMBER ')' { $$.w = (ICMP6_DST_UNREACH << 8) | $3; $$.b2 = 0; } | RETURNICMP6 '(' STRING ')' { struct icmpcodeent *p; if ((p = geticmpcodebyname(ICMP6_DST_UNREACH, $3, AF_INET6)) == NULL) { yyerror("unknown icmp code %s", $3); YYERROR; } $$.w = (p->type << 8) | p->code; $$.b2 = 0; } ; dir : IN { $$ = PF_IN; } | OUT { $$ = PF_OUT; } ; log : /* empty */ { $$ = 0; } | LOG { $$ = 1; } | LOGALL { $$ = 2; } ; quick : /* empty */ { $$ = 0; } | QUICK { $$ = 1; } ; interface : /* empty */ { $$ = NULL; } | ON if_item_not { $$ = $2; } | ON '{' if_list '}' { $$ = $3; } ; if_list : if_item_not { $$ = $1; } | if_list ',' if_item_not { $3->next = $1; $$ = $3; } ; if_item_not : '!' if_item { $$ = $2; $$->not = 1; } | if_item { $$ = $1; } if_item : STRING { if (ifa0_lookup($1) == NULL) { yyerror("unknown interface %s", $1); YYERROR; } $$ = malloc(sizeof(struct node_if)); if ($$ == NULL) err(1, "if_item: malloc"); strlcpy($$->ifname, $1, IFNAMSIZ); $$->not = 0; $$->next = NULL; } ; af : /* empty */ { $$ = 0; } | INET { $$ = AF_INET; } | INET6 { $$ = AF_INET6; } proto : /* empty */ { $$ = NULL; } | PROTO proto_item { $$ = $2; } | PROTO '{' proto_list '}' { $$ = $3; } ; proto_list : proto_item { $$ = $1; } | proto_list ',' proto_item { $3->next = $1; $$ = $3; } ; proto_item : NUMBER { struct protoent *p; if ((p = getprotobynumber($1)) == NULL) { yyerror("unknown protocol %d", $1); YYERROR; } $$ = malloc(sizeof(struct node_proto)); if ($$ == NULL) err(1, "proto_item: malloc"); $$->proto = p->p_proto; $$->next = NULL; } | STRING { struct protoent *p; if ((p = getprotobyname($1)) == NULL) { yyerror("unknown protocol %s", $1); YYERROR; } $$ = malloc(sizeof(struct node_proto)); if ($$ == NULL) err(1, "proto_item: malloc"); $$->proto = p->p_proto; $$->next = NULL; } ; fromto : ALL { $$.src.host = NULL; $$.src.port = NULL; $$.dst.host = NULL; $$.dst.port = NULL; } | FROM ipportspec TO ipportspec { $$.src = $2; $$.dst = $4; } ; ipportspec : ipspec { $$.host = $1; $$.port = NULL; } | ipspec PORT portspec { $$.host = $1; $$.port = $3; } ; ipspec : ANY { $$ = NULL; } | xhost { $$ = $1; } | '{' host_list '}' { $$ = $2; } ; host_list : xhost { $$ = $1; } | host_list ',' xhost { $3->next = $1; $$ = $3; } ; xhost : '!' host { $$ = $2; $$->not = 1; } | host { $$ = $1; } ; host : address { $$ = $1; if ($$->af == AF_INET) ipmask(&$$->mask, 32); else ipmask(&$$->mask, 128); } | address '/' NUMBER { if ($$->af == AF_INET) { if ($3 < 0 || $3 > 32) { yyerror("illegal netmask value %d", $3); YYERROR; } } else { if ($3 < 0 || $3 > 128) { yyerror("illegal netmask value %d", $3); YYERROR; } } $$ = $1; ipmask(&$$->mask, $3); } ; address : STRING { struct hostent *hp; struct ifaddrs *ifa; if (ifa0_lookup($1)) { /* an interface with this name exists */ if ((ifa = ifa4_lookup($1))) { struct sockaddr_in *sin = (struct sockaddr_in *) ifa->ifa_addr; $$ = calloc(1, sizeof(struct node_host)); if ($$ == NULL) err(1, "address: calloc"); $$->af = AF_INET; memcpy(&$$->addr, &sin->sin_addr, sizeof(u_int32_t)); } else if ((ifa = ifa6_lookup($1))) { struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *) ifa->ifa_addr; $$ = calloc(1, sizeof(struct node_host)); if ($$ == NULL) err(1, "address: calloc"); $$->af = AF_INET6; memcpy(&$$->addr, &sin6->sin6_addr, sizeof(struct pf_addr)); } else { yyerror("interface %s has no IP " "addresses", $1); YYERROR; } } else if ((hp = gethostbyname2($1, AF_INET)) == NULL) { if ((hp = gethostbyname2($1, AF_INET6)) == NULL) { yyerror("cannot resolve %s", $1); YYERROR; } else { $$ = calloc(1, sizeof(struct node_host)); if ($$ == NULL) err(1, "address: calloc"); $$->af = AF_INET6; memcpy(&$$->addr, hp->h_addr, sizeof(struct pf_addr)); } } else { $$ = calloc(1, sizeof(struct node_host)); if ($$ == NULL) err(1, "address: calloc"); $$->af = AF_INET; memcpy(&$$->addr, hp->h_addr, sizeof(u_int32_t)); } } | NUMBER '.' NUMBER '.' NUMBER '.' NUMBER { if ($1 < 0 || $3 < 0 || $5 < 0 || $7 < 0 || $1 > 255 || $3 > 255 || $5 > 255 || $7 > 255) { yyerror("illegal ip address %d.%d.%d.%d", $1, $3, $5, $7); YYERROR; } $$ = calloc(1, sizeof(struct node_host)); if ($$ == NULL) err(1, "address: calloc"); $$->af = AF_INET; $$->addr.addr32[0] = htonl(($1 << 24) | ($3 << 16) | ($5 << 8) | $7); } | IPV6ADDR { $$ = $1; } ; portspec : port_item { $$ = $1; } | '{' port_list '}' { $$ = $2; } ; port_list : port_item { $$ = $1; } | port_list ',' port_item { $3->next = $1; $$ = $3; } ; port_item : port { $$ = malloc(sizeof(struct node_port)); if ($$ == NULL) err(1, "port_item: malloc"); $$->port[0] = $1; $$->port[1] = $1; $$->op = PF_OP_EQ; $$->next = NULL; } | PORTUNARY port { $$ = malloc(sizeof(struct node_port)); if ($$ == NULL) err(1, "port_item: malloc"); $$->port[0] = $2; $$->port[1] = $2; $$->op = $1; $$->next = NULL; } | port PORTBINARY port { $$ = malloc(sizeof(struct node_port)); if ($$ == NULL) err(1, "port_item: malloc"); $$->port[0] = $1; $$->port[1] = $3; $$->op = $2; $$->next = NULL; } ; port : NUMBER { if ($1 < 0 || $1 > 65535) { yyerror("illegal port value %d", $1); YYERROR; } $$ = htons($1); } | STRING { struct servent *s = NULL; s = getservbyname($1, "tcp"); if (s == NULL) s = getservbyname($1, "udp"); if (s == NULL) { yyerror("unknown protocol %s", $1); YYERROR; } $$ = s->s_port; } ; flag : STRING { int f; if ((f = parse_flags($1)) < 0) { yyerror("bad flags %s", $1); YYERROR; } $$.b1 = f; } ; flags : /* empty */ { $$.b1 = 0; $$.b2 = 0; } | FLAGS flag { $$.b1 = $2.b1; $$.b2 = 63; } | FLAGS flag "/" flag { $$.b1 = $2.b1; $$.b2 = $4.b1; } | FLAGS "/" flag { $$.b1 = 0; $$.b2 = $3.b1; } ; icmpspec : /* empty */ { $$ = NULL; } | ICMPTYPE icmp_item { $$ = $2; } | ICMPTYPE '{' icmp_list '}' { $$ = $3; } | ICMP6TYPE icmp6_item { $$ = $2; } | ICMP6TYPE '{' icmp6_list '}' { $$ = $3; } ; icmp_list : icmp_item { $$ = $1; } | icmp_list ',' icmp_item { $3->next = $1; $$ = $3; } ; icmp6_list : icmp6_item { $$ = $1; } | icmp6_list ',' icmp6_item { $3->next = $1; $$ = $3; } ; icmp_item : icmptype { $$ = malloc(sizeof(struct node_icmp)); if ($$ == NULL) err(1, "icmp_item: malloc"); $$->type = $1; $$->code = 0; $$->proto = IPPROTO_ICMP; $$->next = NULL; } | icmptype CODE NUMBER { $$ = malloc(sizeof(struct node_icmp)); if ($$ == NULL) err(1, "icmp_item: malloc"); if ($3 < 0 || $3 > 255) { yyerror("illegal icmp code %d", $3); YYERROR; } $$->type = $1; $$->code = $3 + 1; $$->proto = IPPROTO_ICMP; $$->next = NULL; } | icmptype CODE STRING { struct icmpcodeent *p; $$ = malloc(sizeof(struct node_icmp)); if ($$ == NULL) err(1, "icmp_item: malloc"); $$->type = $1; if ((p = geticmpcodebyname($1, $3, AF_INET)) == NULL) { yyerror("unknown icmp-code %s", $3); YYERROR; } $$->code = p->code + 1; $$->proto = IPPROTO_ICMP; $$->next = NULL; } ; icmp6_item : icmp6type { $$ = malloc(sizeof(struct node_icmp)); if ($$ == NULL) err(1, "icmp_item: malloc"); $$->type = $1; $$->code = 0; $$->proto = IPPROTO_ICMPV6; $$->next = NULL; } | icmp6type CODE NUMBER { $$ = malloc(sizeof(struct node_icmp)); if ($$ == NULL) err(1, "icmp_item: malloc"); if ($3 < 0 || $3 > 255) { yyerror("illegal icmp6 code %d", $3); YYERROR; } $$->type = $1; $$->code = $3 + 1; $$->proto = IPPROTO_ICMPV6; $$->next = NULL; } | icmp6type CODE STRING { struct icmpcodeent *p; $$ = malloc(sizeof(struct node_icmp)); if ($$ == NULL) err(1, "icmp_item: malloc"); $$->type = $1; if ((p = geticmpcodebyname($1, $3, AF_INET6)) == NULL) { yyerror("unknown icmp6-code %s", $3); YYERROR; } $$->code = p->code + 1; $$->proto = IPPROTO_ICMPV6; $$->next = NULL; } ; icmptype : STRING { struct icmptypeent *p; if ((p = geticmptypebyname($1, AF_INET)) == NULL) { yyerror("unknown icmp-type %s", $1); YYERROR; } $$ = p->type + 1; } | NUMBER { if ($1 < 0 || $1 > 255) { yyerror("illegal icmp type %d", $1); YYERROR; } $$ = $1 + 1; } ; icmp6type : STRING { struct icmptypeent *p; if ((p = geticmptypebyname($1, AF_INET6)) == NULL) { yyerror("unknown ipv6-icmp-type %s", $1); YYERROR; } $$ = p->type + 1; } | NUMBER { if ($1 < 0 || $1 > 255) { yyerror("illegal icmp6 type %d", $1); YYERROR; } $$ = $1 + 1; } ; keep : /* empty */ { $$ = 0; } | KEEP STATE { $$ = PF_STATE_NORMAL; } | MODULATE STATE { $$ = PF_STATE_MODULATE; } ; minttl : /* empty */ { $$ = 0; } | MINTTL NUMBER { if ($2 < 0 || $2 > 255) { yyerror("illegal min-ttl value %d", $2); YYERROR; } $$ = $2; } ; nodf : /* empty */ { $$ = 0; } | NODF { $$ = 1; } ; allowopts : /* empty */ { $$ = 0; } | ALLOWOPTS { $$ = 1; } label : /* empty */ { $$ = NULL; } | LABEL STRING { if (($$ = strdup($2)) == NULL) { yyerror("rule label strdup() failed"); YYERROR; } } ; no : /* empty */ { $$ = 0; } | NO { $$ = 1; } ; rport : port { $$.a = $1; $$.b = $$.t = 0; } | port ':' '*' { $$.a = $1; $$.b = 0; $$.t = PF_RPORT_RANGE; } ; redirection : /* empty */ { $$ = NULL; } | ARROW address { $$ = malloc(sizeof(struct redirection)); if ($$ == NULL) err(1, "redirection: malloc"); $$->address = $2; $$->rport.a = $$->rport.b = $$->rport.t = 0; } | ARROW address PORT rport { $$ = malloc(sizeof(struct redirection)); if ($$ == NULL) err(1, "redirection: malloc"); $$->address = $2; $$->rport = $4; } ; natrule : no NAT interface proto FROM ipspec TO ipspec redirection { struct pf_nat nat; if (!natmode) { yyerror("nat rule not permitted in filter mode"); YYERROR; } memset(&nat, 0, sizeof(nat)); nat.no = $1; if ($3 != NULL) { memcpy(nat.ifname, $3->ifname, sizeof(nat.ifname)); nat.ifnot = $3->not; free($3); } if ($4 != NULL) { nat.proto = $4->proto; free($4); } if ($6 != NULL && $8 != NULL && $6->af != $8->af) { yyerror("nat ip versions must match"); YYERROR; } if ($6 != NULL) { nat.af = $6->af; memcpy(&nat.saddr, &$6->addr, sizeof(nat.saddr)); memcpy(&nat.smask, &$6->mask, sizeof(nat.smask)); nat.snot = $6->not; free($6); } if ($8 != NULL) { nat.af = $8->af; memcpy(&nat.daddr, &$8->addr, sizeof(nat.daddr)); memcpy(&nat.dmask, &$8->mask, sizeof(nat.dmask)); nat.dnot = $8->not; free($8); } if (nat.no) { if ($9 != NULL) { yyerror("'no nat' rule does not need '->'"); YYERROR; } } else { if ($9 == NULL || $9->address == NULL) { yyerror("'nat' rule requires '-> address'"); YYERROR; } if (nat.af && $9->address->af != nat.af) { yyerror("nat ip versions must match"); YYERROR; } nat.af = $9->address->af; memcpy(&nat.raddr, &$9->address->addr, sizeof(nat.raddr)); free($9->address); free($9); } pfctl_add_nat(pf, &nat); } ; binatrule : no BINAT interface proto FROM address TO ipspec redirection { struct pf_binat binat; if (!natmode) { yyerror("binat rule not permitted in filter mode"); YYERROR; } memset(&binat, 0, sizeof(binat)); binat.no = $1; if ($3 != NULL) { memcpy(binat.ifname, $3->ifname, sizeof(binat.ifname)); free($3); } if ($4 != NULL) { binat.proto = $4->proto; free($4); } if ($6 != NULL && $8 != NULL && $6->af != $8->af) { yyerror("binat ip versions must match"); YYERROR; } if ($6 != NULL) { binat.af = $6->af; memcpy(&binat.saddr, &$6->addr, sizeof(binat.saddr)); free($6); } if ($8 != NULL) { binat.af = $8->af; memcpy(&binat.daddr, &$8->addr, sizeof(binat.daddr)); memcpy(&binat.dmask, &$8->mask, sizeof(binat.dmask)); binat.dnot = $8->not; free($8); } if (binat.no) { if ($9 != NULL) { yyerror("'no binat' rule does not need" " '->'"); YYERROR; } } else { if ($9 == NULL || $9->address == NULL) { yyerror("'binat' rule requires" " '-> address'"); YYERROR; } if (binat.af && $9->address->af != binat.af) { yyerror("binat ip versions must match"); YYERROR; } binat.af = $9->address->af; memcpy(&binat.raddr, &$9->address->addr, sizeof(binat.raddr)); free($9->address); free($9); } pfctl_add_binat(pf, &binat); } rdrrule : no RDR interface proto FROM ipspec TO ipspec dport redirection { struct pf_rdr rdr; if (!natmode) { yyerror("rdr rule not permitted in filter mode"); YYERROR; } memset(&rdr, 0, sizeof(rdr)); rdr.no = $1; if ($3 != NULL) { memcpy(rdr.ifname, $3->ifname, sizeof(rdr.ifname)); rdr.ifnot = $3->not; free($3); } if ($4 != NULL) { rdr.proto = $4->proto; free($4); } if ($6 != NULL && $8 != NULL && $6->af != $8->af) { yyerror("rdr ip versions must match"); YYERROR; } if ($6 != NULL) { rdr.af = $6->af; memcpy(&rdr.saddr, &$6->addr, sizeof(rdr.saddr)); memcpy(&rdr.smask, &$6->mask, sizeof(rdr.smask)); rdr.snot = $6->not; free($6); } if ($8 != NULL) { rdr.af = $8->af; memcpy(&rdr.daddr, &$8->addr, sizeof(rdr.daddr)); memcpy(&rdr.dmask, &$8->mask, sizeof(rdr.dmask)); rdr.dnot = $8->not; free($8); } rdr.dport = $9.a; rdr.dport2 = $9.b; rdr.opts |= $9.t; if (rdr.no) { if ($10 != NULL) { yyerror("'no rdr' rule does not need '->'"); YYERROR; } } else { if ($10 == NULL || $10->address == NULL) { yyerror("'rdr' rule requires '-> address'"); YYERROR; } if (rdr.af && $10->address->af != rdr.af) { yyerror("rdr ip versions must match"); YYERROR; } rdr.af = $10->address->af; memcpy(&rdr.raddr, &$10->address->addr, sizeof(rdr.raddr)); free($10->address); rdr.rport = $10->rport.a; rdr.opts |= $10->rport.t; free($10); } if (rdr.proto && rdr.proto != IPPROTO_TCP && rdr.proto != IPPROTO_UDP && (rdr.dport || rdr.dport2 || rdr.rport)) { yyerror("rdr ports are only valid for proto tcp/udp"); YYERROR; } pfctl_add_rdr(pf, &rdr); } ; dport : /* empty */ { $$.a = $$.b = $$.t = 0; } | PORT port { $$.a = $2; $$.b = $$.t = 0; } | PORT port ':' port { $$.a = $2; $$.b = $4; $$.t = PF_DPORT_RANGE; } ; route : /* empty */ { $$.string = NULL; $$.rt = 0; $$.addr = NULL; $$.af = 0; } | FASTROUTE { $$.string = NULL; $$.rt = PF_FASTROUTE; $$.addr = NULL; } | ROUTETO STRING ':' address { $$.string = strdup($2); $$.rt = PF_ROUTETO; $$.addr = &$4->addr; $$.af = $4->af; } | ROUTETO STRING { $$.string = strdup($2); $$.rt = PF_ROUTETO; $$.addr = NULL; } | DUPTO STRING ':' address { $$.string = strdup($2); $$.rt = PF_DUPTO; $$.addr = &$4->addr; $$.af = $4->af; } | DUPTO STRING { $$.string = strdup($2); $$.rt = PF_DUPTO; $$.addr = NULL; } ; %% int yyerror(char *fmt, ...) { va_list ap; extern 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 rule_consistent(struct pf_rule *r) { int problems = 0; if (r->action == PF_SCRUB) { if (r->quick) { yyerror("quick does not apply to scrub"); problems++; } if (r->keep_state == PF_STATE_MODULATE) { yyerror("modulate state does not apply to scrub"); problems++; } if (r->keep_state == PF_STATE_NORMAL) { yyerror("keep state does not apply to scrub"); problems++; } if (r->src.port_op) { yyerror("src port does not apply to scrub"); problems++; } if (r->dst.port_op) { yyerror("dst port does not apply to scrub"); problems++; } if (r->type || r->code) { yyerror("icmp-type/code does not apply to scrub"); problems++; } } else { if (r->rule_flag & PFRULE_NODF) { yyerror("nodf only applies to scrub"); problems++; } if (r->min_ttl) { yyerror("min-ttl only applies to scrub"); problems++; } } 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->proto == IPPROTO_ICMP && r->af == AF_INET6) || (r->proto == IPPROTO_ICMPV6 && r->af == AF_INET)) { yyerror("icmp version does not match address family"); problems++; } if (!(r->rule_flag & PFRULE_RETURNRST) && r->return_icmp && ((r->af != AF_INET6 && (r->return_icmp>>8) != ICMP_UNREACH) || (r->af == AF_INET6 && (r->return_icmp>>8) != ICMP6_DST_UNREACH))) { yyerror("return-icmp version does not match address family"); problems++; } if (r->keep_state == PF_STATE_MODULATE && r->proto && r->proto != IPPROTO_TCP) { yyerror("modulate state can only be applied to TCP rules"); problems++; } if (r->allow_opts && r->action != PF_PASS) { yyerror("allow-opts can only be specified for pass rules"); problems++; } return (-problems); } struct keywords { const char *k_name; int k_val; }; #define CHECK_ROOT(T,r) \ do { \ if (r == NULL) { \ r = malloc(sizeof(T)); \ if (r == NULL) \ err(1, "malloc"); \ memset(r, 0, sizeof(T)); \ } \ } while (0) #define FREE_LIST(T,r) \ do { \ T *p, *n = r; \ while (n != NULL) { \ p = n; \ n = n->next; \ free(p); \ } \ } while (0) void expand_rule_hosts(struct pf_rule *r, struct node_if *interface, struct node_proto *proto, struct node_host *src_hosts, struct node_port *src_ports, struct node_host *dst_hosts, struct node_port *dst_ports, struct node_icmp *icmp_type) { struct node_host *src_host, *dst_host; struct node_port *src_port, *dst_port; int nomatch = 0; src_host = src_hosts; while (src_host != NULL) { src_port = src_ports; while (src_port != NULL) { dst_host = dst_hosts; while (dst_host != NULL) { dst_port = dst_ports; while (dst_port != NULL) { memcpy(r->ifname, interface->ifname, sizeof(r->ifname)); r->proto = proto->proto; r->src.addr = src_host->addr; r->src.mask = src_host->mask; r->src.not = 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.mask = dst_host->mask; r->dst.not = 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->type = icmp_type->type; r->code = icmp_type->code; if ((src_host->af && dst_host->af && r->af) && (src_host->af != dst_host->af || src_host->af != r->af || dst_host->af != r->af)) { yyerror("address family" " mismatch"); nomatch++; } else if ((src_host->af && dst_host->af) && (src_host->af != dst_host->af)) { yyerror("address family" " mismatch"); nomatch++; } else if ((src_host->af && r->af) && (src_host->af != r->af)) { yyerror("address family" " mismatch"); nomatch++; } else if ((dst_host->af && r->af) && (dst_host->af != r->af)) { yyerror("address family" " mismatch"); nomatch++; } else if (src_host->af && !r->af) { r->af = src_host->af; } else if (dst_host->af && !r->af) { r->af= dst_host->af; } if (icmp_type->proto && r->proto != icmp_type->proto) { yyerror("icmp-type mismatch"); nomatch++; } if (rule_consistent(r) < 0 || nomatch) yyerror("skipping rule " "due to errors"); else { r->nr = pf->rule_nr++; pfctl_add_rule(pf, r); } dst_port = dst_port->next; } dst_host = dst_host->next; } src_port = src_port->next; } src_host = src_host->next; } } void expand_rule_protos(struct pf_rule *r, struct node_if *interface, struct node_proto *protos, struct node_host *src_hosts, struct node_port *src_ports, struct node_host *dst_hosts, struct node_port *dst_ports, struct node_icmp *icmp_types) { struct node_proto *proto; struct node_icmp *icmp_type; proto = protos; while (proto != NULL) { icmp_type = icmp_types; while (icmp_type != NULL) { expand_rule_hosts(r, interface, proto, src_hosts, src_ports, dst_hosts, dst_ports, icmp_type); icmp_type = icmp_type->next; } proto = proto->next; } } void expand_rule(struct pf_rule *r, struct node_if *interfaces, struct node_proto *protos, struct node_host *src_hosts, struct node_port *src_ports, struct node_host *dst_hosts, struct node_port *dst_ports, struct node_icmp *icmp_types) { struct node_if *interface; CHECK_ROOT(struct node_if, interfaces); CHECK_ROOT(struct node_proto, protos); CHECK_ROOT(struct node_host, src_hosts); CHECK_ROOT(struct node_port, src_ports); CHECK_ROOT(struct node_host, dst_hosts); CHECK_ROOT(struct node_port, dst_ports); CHECK_ROOT(struct node_icmp, icmp_types); interface = interfaces; while (interface != NULL) { expand_rule_protos(r, interface, protos, src_hosts, src_ports, dst_hosts, dst_ports, icmp_types); interface = interface->next; } 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_host, dst_hosts); FREE_LIST(struct node_port, dst_ports); FREE_LIST(struct node_icmp, icmp_types); } #undef FREE_LIST #undef CHECK_ROOT int kw_cmp(k, e) const void *k, *e; { return (strcmp(k, ((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}, { "any", ANY}, { "binat", BINAT}, { "block", BLOCK}, { "code", CODE}, { "dup-to", DUPTO}, { "fastroute", FASTROUTE}, { "flags", FLAGS}, { "from", FROM}, { "icmp-type", ICMPTYPE}, { "in", IN}, { "inet", INET}, { "inet6", INET6}, { "ipv6-icmp-type", ICMP6TYPE}, { "keep", KEEP}, { "label", LABEL}, { "log", LOG}, { "log-all", LOGALL}, { "min-ttl", MINTTL}, { "modulate", MODULATE}, { "nat", NAT}, { "no", NO}, { "no-df", NODF}, { "on", ON}, { "out", OUT}, { "pass", PASS}, { "port", PORT}, { "proto", PROTO}, { "quick", QUICK}, { "rdr", RDR}, { "return", RETURN}, { "return-icmp",RETURNICMP}, { "return-icmp6",RETURNICMP6}, { "return-rst", RETURNRST}, { "route-to", ROUTETO}, { "scrub", SCRUB}, { "state", STATE}, { "to", TO}, }; 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); } } char *parsebuf; int parseindex; int lgetc(FILE *fin) { int c, next; restart: if (parsebuf) { /* Reading characters from the parse buffer, instead of input */ c = parsebuf[parseindex++]; if (c != '\0') return (c); free(parsebuf); parsebuf = NULL; parseindex = 0; goto restart; } c = getc(fin); if (c == '\\') { next = getc(fin); if (next != '\n') { ungetc(next, fin); return (c); } yylval.lineno = lineno; lineno++; goto restart; } return (c); } int lungetc(int c, FILE *fin) { if (parsebuf && parseindex) { /* XXX breaks on index 0 */ parseindex--; return (c); } return ungetc(c, fin); } int findeol() { int c; if (parsebuf) { free(parsebuf); parsebuf = NULL; parseindex = 0; } /* skip to either EOF or the first real EOL */ while (1) { c = lgetc(fin); if (c == '\\') { c = lgetc(fin); if (c == '\n') continue; } if (c == EOF || c == '\n') break; } return (ERROR); } int yylex(void) { char buf[8096], *p, *val; int endc, c, next; int token; top: p = buf; while ((c = lgetc(fin)) == ' ' || c == '\t') ; yylval.lineno = lineno; if (c == '#') while ((c = lgetc(fin)) != '\n' && c != EOF) ; 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, fin); break; } val = symget(buf); if (val == NULL) return (ERROR); parsebuf = strdup(val); if (parsebuf == NULL) err(1, "parsebuf: strdup"); 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') 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 '=': yylval.v.i = PF_OP_EQ; return (PORTUNARY); case '!': next = lgetc(fin); if (next == '=') { yylval.v.i = PF_OP_NE; return (PORTUNARY); } lungetc(next, fin); break; case '<': next = lgetc(fin); if (next == '>') { yylval.v.i = PF_OP_XRG; return (PORTBINARY); } else if (next == '=') { yylval.v.i = PF_OP_LE; } else { yylval.v.i = PF_OP_LT; lungetc(next, fin); } return (PORTUNARY); break; case '>': next = lgetc(fin); if (next == '<') { yylval.v.i = PF_OP_IRG; return (PORTBINARY); } else if (next == '=') { yylval.v.i = PF_OP_GE; } else { yylval.v.i = PF_OP_GT; lungetc(next, fin); } return (PORTUNARY); break; case '-': next = lgetc(fin); if (next == '>') return (ARROW); lungetc(next, fin); break; } /* Need to parse v6 addresses before tokenizing numbers. ick */ if (isxdigit(c) || c == ':') { struct node_host *node = NULL; u_int32_t addr[4]; char lookahead[46]; int i = 0, notv6addr = 0; lookahead[i] = c; while (i < sizeof(lookahead) && (isxdigit(c) || c == ':' || c == '.')) { lookahead[++i] = c = lgetc(fin); } /* quick check avoids calling inet_pton too often */ if (isalnum(c)) { notv6addr++; } lungetc(lookahead[i], fin); lookahead[i] = '\0'; if(!notv6addr && inet_pton(AF_INET6, lookahead, &addr) == 1) { node = calloc(1, sizeof(struct node_host)); node->af = AF_INET6; memcpy (&node->addr, &addr, sizeof(addr)); yylval.v.host = node; return IPV6ADDR; } else { free(node); while (i > 1) { lungetc(lookahead[--i], fin); } c = lookahead[--i]; } } if (isdigit(c)) { int index = 0, base = 10; u_int64_t n = 0; yylval.v.number = 0; while (1) { if (base == 10) { if (!isdigit(c)) break; c -= '0'; } else if (base == 16) { if (isdigit(c)) c -= '0'; else if (c >= 'a' && c <= 'f') c -= 'a' - 10; else if (c >= 'A' && c <= 'F') c -= 'A' - 10; else break; } n = n * base + c; if (n > UINT_MAX) { yyerror("number is too large"); return (ERROR); } c = lgetc(fin); if (c == EOF) break; if (index++ == 0 && n == 0 && c == 'x') { base = 16; c = lgetc(fin); if (c == EOF) break; } } yylval.v.number = (u_int32_t)n; if (c != EOF) lungetc(c, fin); if (debug > 1) fprintf(stderr, "number: %d\n", yylval.v.number); return (NUMBER); } #define allowed_in_string(x) \ (isalnum(x) || (ispunct(x) && x != '(' && x != ')' && \ x != '{' && x != '}' && x != '<' && x != '>' && \ x != '!' && x != '=' && x != '/' && x != '#' && x != ',' && x != ':')) if (isalnum(c)) { do { *p++ = c; if (p-buf >= sizeof buf) { yyerror("string too long"); return (ERROR); } } while ((c = lgetc(fin)) != EOF && (allowed_in_string(c))); lungetc(c, fin); *p = '\0'; token = lookup(buf); yylval.v.string = strdup(buf); if (yylval.v.string == 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) { natmode = 0; fin = input; pf = xpf; errors = 0; yyparse(); return (errors ? -1 : 0); } int parse_nat(FILE *input, struct pfctl *xpf) { natmode = 1; fin = input; pf = xpf; errors = 0; yyparse(); return (errors ? -1 : 0); } void ipmask(struct pf_addr *m, u_int8_t b) { int i, j = 0; while (b >= 32) { m->addr32[j++] = 0xffffffff; b -= 32; } for (i = 31; i > 31-b; --i) m->addr32[j] |= (1 << i); if (b) m->addr32[j] = htonl(m->addr32[j]); } struct pf_rule_addr * new_addr(void) { struct pf_rule_addr *ra; ra = malloc(sizeof(struct pf_rule_addr)); if (ra == NULL) err(1, "new_addr: malloc failed"); memset(ra, 0, sizeof(*ra)); return (ra); } /* * 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(char *nam, char *val) { struct sym *sym; sym = calloc(1, sizeof(*sym)); if (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->next = symhead; symhead = sym; return (0); } char * symget(char *nam) { struct sym *sym; for (sym = symhead; sym; sym = sym->next) if (strcmp(nam, sym->nam) == 0) return (sym->val); return (NULL); } struct ifaddrs **ifa0tab, **ifa4tab, **ifa6tab; int ifa0len, ifa4len, ifa6len; int ifa_comp(const void *p1, const void *p2) { struct ifaddrs *ifa1 = *(struct ifaddrs **)p1; struct ifaddrs *ifa2 = *(struct ifaddrs **)p2; return strcmp(ifa1->ifa_name, ifa2->ifa_name); } void ifa_load(void) { struct ifaddrs *ifap, *ifa; int ifalen = 0; if (getifaddrs(&ifap) < 0) err(1, "getifaddrs"); for (ifa = ifap; ifa; ifa = ifa->ifa_next) ifalen++; /* (over-)allocate tables */ ifa0tab = malloc(ifalen * sizeof(void *)); ifa4tab = malloc(ifalen * sizeof(void *)); ifa6tab = malloc(ifalen * sizeof(void *)); if (!ifa0tab || !ifa4tab || !ifa6tab) err(1, "malloc"); for (ifa = ifap; ifa; ifa = ifa->ifa_next) { if (ifa->ifa_addr->sa_family == AF_LINK) { if (bsearch(&ifa, ifa0tab, ifa0len, sizeof(void *), ifa_comp)) continue; /* take only the first LINK address */ ifa0tab[ifa0len++] = ifa; qsort(ifa0tab, ifa0len, sizeof(void *), ifa_comp); } if (ifa->ifa_addr->sa_family == AF_INET) { if (bsearch(&ifa, ifa4tab, ifa4len, sizeof(void *), ifa_comp)) continue; /* take only the first IPv4 address */ ifa4tab[ifa4len++] = ifa; qsort(ifa4tab, ifa4len, sizeof(void *), ifa_comp); } if (ifa->ifa_addr->sa_family == AF_INET6) { /* XXX - better address selection required! */ if (bsearch(&ifa, ifa6tab, ifa6len, sizeof(void *), ifa_comp)) continue; /* take only the first IPv6 address */ ifa6tab[ifa6len++] = ifa; qsort(ifa6tab, ifa6len, sizeof(void *), ifa_comp); } } /* shrink tables */ ifa0tab = realloc(ifa0tab, ifa0len * sizeof(void *)); ifa4tab = realloc(ifa4tab, ifa4len * sizeof(void *)); ifa6tab = realloc(ifa6tab, ifa6len * sizeof(void *)); if (!ifa0tab || !ifa4tab || !ifa6tab) err(1, "realloc"); } struct ifaddrs * ifa0_lookup(char *ifa_name) { struct ifaddrs ifa, *ifp = &ifa, **ifpp; if (!ifa0tab) ifa_load(); ifa.ifa_name = ifa_name; ifpp = bsearch(&ifp, ifa0tab, ifa0len, sizeof(void *), ifa_comp); return ifpp ? *ifpp : NULL; } struct ifaddrs * ifa4_lookup(char *ifa_name) { struct ifaddrs ifa, *ifp = &ifa, **ifpp; if (!ifa4tab) ifa_load(); ifa.ifa_name = ifa_name; ifpp = bsearch(&ifp, ifa4tab, ifa4len, sizeof(void *), ifa_comp); return ifpp ? *ifpp : NULL; } struct ifaddrs * ifa6_lookup(char *ifa_name) { struct ifaddrs ifa, *ifp = &ifa, **ifpp; if (!ifa6tab) ifa_load(); ifa.ifa_name = ifa_name; ifpp = bsearch(&ifp, ifa6tab, ifa6len, sizeof(void *), ifa_comp); return ifpp ? *ifpp : NULL; }