1181344Sdfr/*- 2181344Sdfr * SPDX-License-Identifier: BSD-2-Clause 3208291Suqs * 4181344Sdfr * Copyright (c) 2002-2009 Luigi Rizzo, Universita` di Pisa 5181344Sdfr * 6181344Sdfr * Redistribution and use in source and binary forms, with or without 7181344Sdfr * modification, are permitted provided that the following conditions 8181344Sdfr * are met: 9181344Sdfr * 1. Redistributions of source code must retain the above copyright 10181344Sdfr * notice, this list of conditions and the following disclaimer. 11181344Sdfr * 2. Redistributions in binary form must reproduce the above copyright 12181344Sdfr * notice, this list of conditions and the following disclaimer in the 13181344Sdfr * documentation and/or other materials provided with the distribution. 14181344Sdfr * 15181344Sdfr * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND 16181344Sdfr * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 17181344Sdfr * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 18181344Sdfr * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE 19181344Sdfr * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 20181344Sdfr * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 21181344Sdfr * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 22181344Sdfr * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 23181344Sdfr * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 24181344Sdfr * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 25181344Sdfr * SUCH DAMAGE. 26181344Sdfr */ 27203026Sgavin 28181344Sdfr#ifndef _IPFW2_H 29181344Sdfr#define _IPFW2_H 30181344Sdfr 31181344Sdfr/* 32181344Sdfr * The default rule number. By the design of ip_fw, the default rule 33181344Sdfr * is the last one, so its number can also serve as the highest number 34181344Sdfr * allowed for a rule. The ip_fw code relies on both meanings of this 35181344Sdfr * constant. 36181344Sdfr */ 37181344Sdfr#define IPFW_DEFAULT_RULE 65535 38181344Sdfr 39181344Sdfr#define RESVD_SET 31 /*set for default and persistent rules*/ 40181344Sdfr#define IPFW_MAX_SETS 32 /* Number of sets supported by ipfw*/ 41181344Sdfr 42181344Sdfr/* 43181344Sdfr * Compat values for old clients 44181344Sdfr */ 45181344Sdfr#ifndef _KERNEL 46181344Sdfr#define IPFW_TABLES_MAX 65535 47181344Sdfr#define IPFW_TABLES_DEFAULT 128 48181344Sdfr#endif 49236668Sjoel 50181344Sdfr/* 51181344Sdfr * Most commands (queue, pipe, tag, untag, limit...) can have a 16-bit 52181344Sdfr * argument between 1 and 65534. The value 0 (IP_FW_TARG) is used 53181344Sdfr * to represent 'tablearg' value, e.g. indicate the use of a 'tablearg' 54181344Sdfr * result of the most recent table() lookup. 55181344Sdfr * Note that 16bit is only a historical limit, resulting from 56181344Sdfr * the use of a 16-bit fields for that value. In reality, we can have 57181344Sdfr * 2^32 pipes, queues, tag values and so on. 58181344Sdfr */ 59181344Sdfr#define IPFW_ARG_MIN 1 60181344Sdfr#define IPFW_ARG_MAX 65534 61181344Sdfr#define IP_FW_TABLEARG 65535 /* Compat value for old clients */ 62181344Sdfr#define IP_FW_TARG 0 /* Current tablearg value */ 63181344Sdfr#define IP_FW_NAT44_GLOBAL 65535 /* arg1 value for "nat global" */ 64181344Sdfr 65181344Sdfr/* 66181344Sdfr * Number of entries in the call stack of the call/return commands. 67181344Sdfr * Call stack currently is an uint16_t array with rule numbers. 68181344Sdfr */ 69181344Sdfr#define IPFW_CALLSTACK_SIZE 16 70181344Sdfr 71181344Sdfr/* IP_FW3 header/opcodes */ 72181344Sdfrtypedef struct _ip_fw3_opheader { 73181344Sdfr uint16_t opcode; /* Operation opcode */ 74181344Sdfr uint16_t version; /* Opcode version */ 75181344Sdfr uint16_t reserved[2]; /* Align to 64-bit boundary */ 76181344Sdfr} ip_fw3_opheader; 77203025Sgavin 78181344Sdfr/* IP_FW3 opcodes */ 79181344Sdfr#define IP_FW_TABLE_XADD 86 /* add entry */ 80181344Sdfr#define IP_FW_TABLE_XDEL 87 /* delete entry */ 81181344Sdfr#define IP_FW_TABLE_XGETSIZE 88 /* get table size (deprecated) */ 82181344Sdfr#define IP_FW_TABLE_XLIST 89 /* list table contents */ 83#define IP_FW_TABLE_XDESTROY 90 /* destroy table */ 84#define IP_FW_TABLES_XLIST 92 /* list all tables */ 85#define IP_FW_TABLE_XINFO 93 /* request info for one table */ 86#define IP_FW_TABLE_XFLUSH 94 /* flush table data */ 87#define IP_FW_TABLE_XCREATE 95 /* create new table */ 88#define IP_FW_TABLE_XMODIFY 96 /* modify existing table */ 89#define IP_FW_XGET 97 /* Retrieve configuration */ 90#define IP_FW_XADD 98 /* add rule */ 91#define IP_FW_XDEL 99 /* del rule */ 92#define IP_FW_XMOVE 100 /* move rules to different set */ 93#define IP_FW_XZERO 101 /* clear accounting */ 94#define IP_FW_XRESETLOG 102 /* zero rules logs */ 95#define IP_FW_SET_SWAP 103 /* Swap between 2 sets */ 96#define IP_FW_SET_MOVE 104 /* Move one set to another one */ 97#define IP_FW_SET_ENABLE 105 /* Enable/disable sets */ 98#define IP_FW_TABLE_XFIND 106 /* finds an entry */ 99#define IP_FW_XIFLIST 107 /* list tracked interfaces */ 100#define IP_FW_TABLES_ALIST 108 /* list table algorithms */ 101#define IP_FW_TABLE_XSWAP 109 /* swap two tables */ 102#define IP_FW_TABLE_VLIST 110 /* dump table value hash */ 103 104#define IP_FW_NAT44_XCONFIG 111 /* Create/modify NAT44 instance */ 105#define IP_FW_NAT44_DESTROY 112 /* Destroys NAT44 instance */ 106#define IP_FW_NAT44_XGETCONFIG 113 /* Get NAT44 instance config */ 107#define IP_FW_NAT44_LIST_NAT 114 /* List all NAT44 instances */ 108#define IP_FW_NAT44_XGETLOG 115 /* Get log from NAT44 instance */ 109 110#define IP_FW_DUMP_SOPTCODES 116 /* Dump available sopts/versions */ 111#define IP_FW_DUMP_SRVOBJECTS 117 /* Dump existing named objects */ 112 113#define IP_FW_NAT64STL_CREATE 130 /* Create stateless NAT64 instance */ 114#define IP_FW_NAT64STL_DESTROY 131 /* Destroy stateless NAT64 instance */ 115#define IP_FW_NAT64STL_CONFIG 132 /* Modify stateless NAT64 instance */ 116#define IP_FW_NAT64STL_LIST 133 /* List stateless NAT64 instances */ 117#define IP_FW_NAT64STL_STATS 134 /* Get NAT64STL instance statistics */ 118#define IP_FW_NAT64STL_RESET_STATS 135 /* Reset NAT64STL instance statistics */ 119 120#define IP_FW_NAT64LSN_CREATE 140 /* Create stateful NAT64 instance */ 121#define IP_FW_NAT64LSN_DESTROY 141 /* Destroy stateful NAT64 instance */ 122#define IP_FW_NAT64LSN_CONFIG 142 /* Modify stateful NAT64 instance */ 123#define IP_FW_NAT64LSN_LIST 143 /* List stateful NAT64 instances */ 124#define IP_FW_NAT64LSN_STATS 144 /* Get NAT64LSN instance statistics */ 125#define IP_FW_NAT64LSN_LIST_STATES 145 /* Get stateful NAT64 states */ 126#define IP_FW_NAT64LSN_RESET_STATS 146 /* Reset NAT64LSN instance statistics */ 127 128#define IP_FW_NPTV6_CREATE 150 /* Create NPTv6 instance */ 129#define IP_FW_NPTV6_DESTROY 151 /* Destroy NPTv6 instance */ 130#define IP_FW_NPTV6_CONFIG 152 /* Modify NPTv6 instance */ 131#define IP_FW_NPTV6_LIST 153 /* List NPTv6 instances */ 132#define IP_FW_NPTV6_STATS 154 /* Get NPTv6 instance statistics */ 133#define IP_FW_NPTV6_RESET_STATS 155 /* Reset NPTv6 instance statistics */ 134 135#define IP_FW_NAT64CLAT_CREATE 160 /* Create clat NAT64 instance */ 136#define IP_FW_NAT64CLAT_DESTROY 161 /* Destroy clat NAT64 instance */ 137#define IP_FW_NAT64CLAT_CONFIG 162 /* Modify clat NAT64 instance */ 138#define IP_FW_NAT64CLAT_LIST 163 /* List clat NAT64 instances */ 139#define IP_FW_NAT64CLAT_STATS 164 /* Get NAT64CLAT instance statistics */ 140#define IP_FW_NAT64CLAT_RESET_STATS 165 /* Reset NAT64CLAT instance statistics */ 141 142/* 143 * The kernel representation of ipfw rules is made of a list of 144 * 'instructions' (for all practical purposes equivalent to BPF 145 * instructions), which specify which fields of the packet 146 * (or its metadata) should be analysed. 147 * 148 * Each instruction is stored in a structure which begins with 149 * "ipfw_insn", and can contain extra fields depending on the 150 * instruction type (listed below). 151 * Note that the code is written so that individual instructions 152 * have a size which is a multiple of 32 bits. This means that, if 153 * such structures contain pointers or other 64-bit entities, 154 * (there is just one instance now) they may end up unaligned on 155 * 64-bit architectures, so the must be handled with care. 156 * 157 * "enum ipfw_opcodes" are the opcodes supported. We can have up 158 * to 256 different opcodes. When adding new opcodes, they should 159 * be appended to the end of the opcode list before O_LAST_OPCODE, 160 * this will prevent the ABI from being broken, otherwise users 161 * will have to recompile ipfw(8) when they update the kernel. 162 */ 163 164enum ipfw_opcodes { /* arguments (4 byte each) */ 165 O_NOP, 166 167 O_IP_SRC, /* u32 = IP */ 168 O_IP_SRC_MASK, /* ip = IP/mask */ 169 O_IP_SRC_ME, /* none */ 170 O_IP_SRC_SET, /* u32=base, arg1=len, bitmap */ 171 172 O_IP_DST, /* u32 = IP */ 173 O_IP_DST_MASK, /* ip = IP/mask */ 174 O_IP_DST_ME, /* none */ 175 O_IP_DST_SET, /* u32=base, arg1=len, bitmap */ 176 177 O_IP_SRCPORT, /* (n)port list:mask 4 byte ea */ 178 O_IP_DSTPORT, /* (n)port list:mask 4 byte ea */ 179 O_PROTO, /* arg1=protocol */ 180 181 O_MACADDR2, /* 2 mac addr:mask */ 182 O_MAC_TYPE, /* same as srcport */ 183 184 O_LAYER2, /* none */ 185 O_IN, /* none */ 186 O_FRAG, /* none */ 187 188 O_RECV, /* none */ 189 O_XMIT, /* none */ 190 O_VIA, /* none */ 191 192 O_IPOPT, /* arg1 = 2*u8 bitmap */ 193 O_IPLEN, /* arg1 = len */ 194 O_IPID, /* arg1 = id */ 195 196 O_IPTOS, /* arg1 = id */ 197 O_IPPRECEDENCE, /* arg1 = precedence << 5 */ 198 O_IPTTL, /* arg1 = TTL */ 199 200 O_IPVER, /* arg1 = version */ 201 O_UID, /* u32 = id */ 202 O_GID, /* u32 = id */ 203 O_ESTAB, /* none (tcp established) */ 204 O_TCPFLAGS, /* arg1 = 2*u8 bitmap */ 205 O_TCPWIN, /* arg1 = desired win */ 206 O_TCPSEQ, /* u32 = desired seq. */ 207 O_TCPACK, /* u32 = desired seq. */ 208 O_ICMPTYPE, /* u32 = icmp bitmap */ 209 O_TCPOPTS, /* arg1 = 2*u8 bitmap */ 210 211 O_VERREVPATH, /* none */ 212 O_VERSRCREACH, /* none */ 213 214 O_PROBE_STATE, /* none */ 215 O_KEEP_STATE, /* none */ 216 O_LIMIT, /* ipfw_insn_limit */ 217 O_LIMIT_PARENT, /* dyn_type, not an opcode. */ 218 219 /* 220 * These are really 'actions'. 221 */ 222 223 O_LOG, /* ipfw_insn_log */ 224 O_PROB, /* u32 = match probability */ 225 226 O_CHECK_STATE, /* none */ 227 O_ACCEPT, /* none */ 228 O_DENY, /* none */ 229 O_REJECT, /* arg1=icmp arg (same as deny) */ 230 O_COUNT, /* none */ 231 O_SKIPTO, /* arg1=next rule number */ 232 O_PIPE, /* arg1=pipe number */ 233 O_QUEUE, /* arg1=queue number */ 234 O_DIVERT, /* arg1=port number */ 235 O_TEE, /* arg1=port number */ 236 O_FORWARD_IP, /* fwd sockaddr */ 237 O_FORWARD_MAC, /* fwd mac */ 238 O_NAT, /* nope */ 239 O_REASS, /* none */ 240 241 /* 242 * More opcodes. 243 */ 244 O_IPSEC, /* has ipsec history */ 245 O_IP_SRC_LOOKUP, /* arg1=table number, u32=value */ 246 O_IP_DST_LOOKUP, /* arg1=table number, u32=value */ 247 O_ANTISPOOF, /* none */ 248 O_JAIL, /* u32 = id */ 249 O_ALTQ, /* u32 = altq classif. qid */ 250 O_DIVERTED, /* arg1=bitmap (1:loop, 2:out) */ 251 O_TCPDATALEN, /* arg1 = tcp data len */ 252 O_IP6_SRC, /* address without mask */ 253 O_IP6_SRC_ME, /* my addresses */ 254 O_IP6_SRC_MASK, /* address with the mask */ 255 O_IP6_DST, 256 O_IP6_DST_ME, 257 O_IP6_DST_MASK, 258 O_FLOW6ID, /* for flow id tag in the ipv6 pkt */ 259 O_ICMP6TYPE, /* icmp6 packet type filtering */ 260 O_EXT_HDR, /* filtering for ipv6 extension header */ 261 O_IP6, 262 263 /* 264 * actions for ng_ipfw 265 */ 266 O_NETGRAPH, /* send to ng_ipfw */ 267 O_NGTEE, /* copy to ng_ipfw */ 268 269 O_IP4, 270 271 O_UNREACH6, /* arg1=icmpv6 code arg (deny) */ 272 273 O_TAG, /* arg1=tag number */ 274 O_TAGGED, /* arg1=tag number */ 275 276 O_SETFIB, /* arg1=FIB number */ 277 O_FIB, /* arg1=FIB desired fib number */ 278 279 O_SOCKARG, /* socket argument */ 280 281 O_CALLRETURN, /* arg1=called rule number */ 282 283 O_FORWARD_IP6, /* fwd sockaddr_in6 */ 284 285 O_DSCP, /* 2 u32 = DSCP mask */ 286 O_SETDSCP, /* arg1=DSCP value */ 287 O_IP_FLOW_LOOKUP, /* arg1=table number, u32=value */ 288 289 O_EXTERNAL_ACTION, /* arg1=id of external action handler */ 290 O_EXTERNAL_INSTANCE, /* arg1=id of eaction handler instance */ 291 O_EXTERNAL_DATA, /* variable length data */ 292 293 O_SKIP_ACTION, /* none */ 294 O_TCPMSS, /* arg1=MSS value */ 295 296 O_MAC_SRC_LOOKUP, /* arg1=table number, u32=value */ 297 O_MAC_DST_LOOKUP, /* arg1=table number, u32=value */ 298 299 O_SETMARK, /* u32 = value */ 300 O_MARK, /* 2 u32 = value, bitmask */ 301 302 O_LAST_OPCODE /* not an opcode! */ 303}; 304 305/* 306 * Defines key types used by lookup instruction 307 */ 308enum ipfw_table_lookup_type { 309 LOOKUP_DST_IP, 310 LOOKUP_SRC_IP, 311 LOOKUP_DST_PORT, 312 LOOKUP_SRC_PORT, 313 LOOKUP_UID, 314 LOOKUP_JAIL, 315 LOOKUP_DSCP, 316 LOOKUP_DST_MAC, 317 LOOKUP_SRC_MAC, 318 LOOKUP_MARK, 319}; 320 321/* 322 * The extension header are filtered only for presence using a bit 323 * vector with a flag for each header. 324 */ 325#define EXT_FRAGMENT 0x1 326#define EXT_HOPOPTS 0x2 327#define EXT_ROUTING 0x4 328#define EXT_AH 0x8 329#define EXT_ESP 0x10 330#define EXT_DSTOPTS 0x20 331#define EXT_RTHDR0 0x40 332#define EXT_RTHDR2 0x80 333 334/* 335 * Template for instructions. 336 * 337 * ipfw_insn is used for all instructions which require no operands, 338 * a single 16-bit value (arg1), or a couple of 8-bit values. 339 * 340 * For other instructions which require different/larger arguments 341 * we have derived structures, ipfw_insn_*. 342 * 343 * The size of the instruction (in 32-bit words) is in the low 344 * 6 bits of "len". The 2 remaining bits are used to implement 345 * NOT and OR on individual instructions. Given a type, you can 346 * compute the length to be put in "len" using F_INSN_SIZE(t) 347 * 348 * F_NOT negates the match result of the instruction. 349 * 350 * F_OR is used to build or blocks. By default, instructions 351 * are evaluated as part of a logical AND. An "or" block 352 * { X or Y or Z } contains F_OR set in all but the last 353 * instruction of the block. A match will cause the code 354 * to skip past the last instruction of the block. 355 * 356 * NOTA BENE: in a couple of places we assume that 357 * sizeof(ipfw_insn) == sizeof(u_int32_t) 358 * this needs to be fixed. 359 * 360 */ 361typedef struct _ipfw_insn { /* template for instructions */ 362 _Alignas(_Alignof(u_int32_t)) u_int8_t opcode; 363 u_int8_t len; /* number of 32-bit words */ 364#define F_NOT 0x80 365#define F_OR 0x40 366#define F_LEN_MASK 0x3f 367#define F_LEN(cmd) ((cmd)->len & F_LEN_MASK) 368 369 u_int16_t arg1; 370} ipfw_insn; 371 372/* 373 * The F_INSN_SIZE(type) computes the size, in 4-byte words, of 374 * a given type. 375 */ 376#define F_INSN_SIZE(t) ((sizeof (t))/sizeof(u_int32_t)) 377 378/* 379 * This is used to store an array of 16-bit entries (ports etc.) 380 */ 381typedef struct _ipfw_insn_u16 { 382 ipfw_insn o; 383 u_int16_t ports[2]; /* there may be more */ 384} ipfw_insn_u16; 385 386/* 387 * This is used to store an array of 32-bit entries 388 * (uid, single IPv4 addresses etc.) 389 */ 390typedef struct _ipfw_insn_u32 { 391 ipfw_insn o; 392 u_int32_t d[1]; /* one or more */ 393} ipfw_insn_u32; 394 395/* 396 * This is used to store IP addr-mask pairs. 397 */ 398typedef struct _ipfw_insn_ip { 399 ipfw_insn o; 400 struct in_addr addr; 401 struct in_addr mask; 402} ipfw_insn_ip; 403 404/* 405 * This is used to forward to a given address (ip). 406 */ 407typedef struct _ipfw_insn_sa { 408 ipfw_insn o; 409 struct sockaddr_in sa; 410} ipfw_insn_sa; 411 412/* 413 * This is used to forward to a given address (ipv6). 414 */ 415typedef struct _ipfw_insn_sa6 { 416 ipfw_insn o; 417 struct sockaddr_in6 sa; 418} ipfw_insn_sa6; 419 420/* 421 * This is used for MAC addr-mask pairs. 422 */ 423typedef struct _ipfw_insn_mac { 424 ipfw_insn o; 425 u_char addr[12]; /* dst[6] + src[6] */ 426 u_char mask[12]; /* dst[6] + src[6] */ 427} ipfw_insn_mac; 428 429/* 430 * This is used for interface match rules (recv xx, xmit xx). 431 */ 432typedef struct _ipfw_insn_if { 433 ipfw_insn o; 434 union { 435 struct in_addr ip; 436 int glob; 437 uint16_t kidx; 438 } p; 439 char name[IFNAMSIZ]; 440} ipfw_insn_if; 441 442/* 443 * This is used for storing an altq queue id number. 444 */ 445typedef struct _ipfw_insn_altq { 446 ipfw_insn o; 447 u_int32_t qid; 448} ipfw_insn_altq; 449 450/* 451 * This is used for limit rules. 452 */ 453typedef struct _ipfw_insn_limit { 454 ipfw_insn o; 455 u_int8_t _pad; 456 u_int8_t limit_mask; /* combination of DYN_* below */ 457#define DYN_SRC_ADDR 0x1 458#define DYN_SRC_PORT 0x2 459#define DYN_DST_ADDR 0x4 460#define DYN_DST_PORT 0x8 461 462 u_int16_t conn_limit; 463} ipfw_insn_limit; 464 465/* 466 * This is used for log instructions. 467 */ 468typedef struct _ipfw_insn_log { 469 ipfw_insn o; 470 u_int32_t max_log; /* how many do we log -- 0 = all */ 471 u_int32_t log_left; /* how many left to log */ 472} ipfw_insn_log; 473 474/* Legacy NAT structures, compat only */ 475#ifndef _KERNEL 476/* 477 * Data structures required by both ipfw(8) and ipfw(4) but not part of the 478 * management API are protected by IPFW_INTERNAL. 479 */ 480#ifdef IPFW_INTERNAL 481/* Server pool support (LSNAT). */ 482struct cfg_spool { 483 LIST_ENTRY(cfg_spool) _next; /* chain of spool instances */ 484 struct in_addr addr; 485 u_short port; 486}; 487#endif 488 489/* Redirect modes id. */ 490#define REDIR_ADDR 0x01 491#define REDIR_PORT 0x02 492#define REDIR_PROTO 0x04 493 494#ifdef IPFW_INTERNAL 495/* Nat redirect configuration. */ 496struct cfg_redir { 497 LIST_ENTRY(cfg_redir) _next; /* chain of redir instances */ 498 u_int16_t mode; /* type of redirect mode */ 499 struct in_addr laddr; /* local ip address */ 500 struct in_addr paddr; /* public ip address */ 501 struct in_addr raddr; /* remote ip address */ 502 u_short lport; /* local port */ 503 u_short pport; /* public port */ 504 u_short rport; /* remote port */ 505 u_short pport_cnt; /* number of public ports */ 506 u_short rport_cnt; /* number of remote ports */ 507 int proto; /* protocol: tcp/udp */ 508 struct alias_link **alink; 509 /* num of entry in spool chain */ 510 u_int16_t spool_cnt; 511 /* chain of spool instances */ 512 LIST_HEAD(spool_chain, cfg_spool) spool_chain; 513}; 514#endif 515 516#ifdef IPFW_INTERNAL 517/* Nat configuration data struct. */ 518struct cfg_nat { 519 /* chain of nat instances */ 520 LIST_ENTRY(cfg_nat) _next; 521 int id; /* nat id */ 522 struct in_addr ip; /* nat ip address */ 523 char if_name[IF_NAMESIZE]; /* interface name */ 524 int mode; /* aliasing mode */ 525 struct libalias *lib; /* libalias instance */ 526 /* number of entry in spool chain */ 527 int redir_cnt; 528 /* chain of redir instances */ 529 LIST_HEAD(redir_chain, cfg_redir) redir_chain; 530}; 531#endif 532 533#define SOF_NAT sizeof(struct cfg_nat) 534#define SOF_REDIR sizeof(struct cfg_redir) 535#define SOF_SPOOL sizeof(struct cfg_spool) 536 537#endif /* ifndef _KERNEL */ 538 539struct nat44_cfg_spool { 540 struct in_addr addr; 541 uint16_t port; 542 uint16_t spare; 543}; 544#define NAT44_REDIR_ADDR 0x01 545#define NAT44_REDIR_PORT 0x02 546#define NAT44_REDIR_PROTO 0x04 547 548/* Nat redirect configuration. */ 549struct nat44_cfg_redir { 550 struct in_addr laddr; /* local ip address */ 551 struct in_addr paddr; /* public ip address */ 552 struct in_addr raddr; /* remote ip address */ 553 uint16_t lport; /* local port */ 554 uint16_t pport; /* public port */ 555 uint16_t rport; /* remote port */ 556 uint16_t pport_cnt; /* number of public ports */ 557 uint16_t rport_cnt; /* number of remote ports */ 558 uint16_t mode; /* type of redirect mode */ 559 uint16_t spool_cnt; /* num of entry in spool chain */ 560 uint16_t spare; 561 uint32_t proto; /* protocol: tcp/udp */ 562}; 563 564/* Nat configuration data struct. */ 565struct nat44_cfg_nat { 566 char name[64]; /* nat name */ 567 char if_name[64]; /* interface name */ 568 uint32_t size; /* structure size incl. redirs */ 569 struct in_addr ip; /* nat IPv4 address */ 570 uint32_t mode; /* aliasing mode */ 571 uint32_t redir_cnt; /* number of entry in spool chain */ 572 u_short alias_port_lo; /* low range for port aliasing */ 573 u_short alias_port_hi; /* high range for port aliasing */ 574}; 575 576/* Nat command. */ 577typedef struct _ipfw_insn_nat { 578 ipfw_insn o; 579 struct cfg_nat *nat; 580} ipfw_insn_nat; 581 582/* Apply ipv6 mask on ipv6 addr */ 583#define APPLY_MASK(addr,mask) do { \ 584 (addr)->__u6_addr.__u6_addr32[0] &= (mask)->__u6_addr.__u6_addr32[0]; \ 585 (addr)->__u6_addr.__u6_addr32[1] &= (mask)->__u6_addr.__u6_addr32[1]; \ 586 (addr)->__u6_addr.__u6_addr32[2] &= (mask)->__u6_addr.__u6_addr32[2]; \ 587 (addr)->__u6_addr.__u6_addr32[3] &= (mask)->__u6_addr.__u6_addr32[3]; \ 588} while (0) 589 590/* Structure for ipv6 */ 591typedef struct _ipfw_insn_ip6 { 592 ipfw_insn o; 593 struct in6_addr addr6; 594 struct in6_addr mask6; 595} ipfw_insn_ip6; 596 597/* Used to support icmp6 types */ 598typedef struct _ipfw_insn_icmp6 { 599 ipfw_insn o; 600 uint32_t d[7]; /* XXX This number si related to the netinet/icmp6.h 601 * define ICMP6_MAXTYPE 602 * as follows: n = ICMP6_MAXTYPE/32 + 1 603 * Actually is 203 604 */ 605} ipfw_insn_icmp6; 606 607/* 608 * Here we have the structure representing an ipfw rule. 609 * 610 * Layout: 611 * struct ip_fw_rule 612 * [ counter block, size = rule->cntr_len ] 613 * [ one or more instructions, size = rule->cmd_len * 4 ] 614 * 615 * It starts with a general area (with link fields). 616 * Counter block may be next (if rule->cntr_len > 0), 617 * followed by an array of one or more instructions, which the code 618 * accesses as an array of 32-bit values. rule->cmd_len represents 619 * the total instructions legth in u32 worrd, while act_ofs represents 620 * rule action offset in u32 words. 621 * 622 * When assembling instruction, remember the following: 623 * 624 * + if a rule has a "keep-state" (or "limit") option, then the 625 * first instruction (at r->cmd) MUST BE an O_PROBE_STATE 626 * + if a rule has a "log" option, then the first action 627 * (at ACTION_PTR(r)) MUST be O_LOG 628 * + if a rule has an "altq" option, it comes after "log" 629 * + if a rule has an O_TAG option, it comes after "log" and "altq" 630 * 631 * 632 * All structures (excluding instructions) are u64-aligned. 633 * Please keep this. 634 */ 635 636struct ip_fw_rule { 637 uint16_t act_ofs; /* offset of action in 32-bit units */ 638 uint16_t cmd_len; /* # of 32-bit words in cmd */ 639 uint16_t spare; 640 uint8_t set; /* rule set (0..31) */ 641 uint8_t flags; /* rule flags */ 642 uint32_t rulenum; /* rule number */ 643 uint32_t id; /* rule id */ 644 645 ipfw_insn cmd[1]; /* storage for commands */ 646}; 647#define IPFW_RULE_NOOPT 0x01 /* Has no options in body */ 648#define IPFW_RULE_JUSTOPTS 0x02 /* new format of rule body */ 649 650/* Unaligned version */ 651 652/* Base ipfw rule counter block. */ 653struct ip_fw_bcounter { 654 uint16_t size; /* Size of counter block, bytes */ 655 uint8_t flags; /* flags for given block */ 656 uint8_t spare; 657 uint32_t timestamp; /* tv_sec of last match */ 658 uint64_t pcnt; /* Packet counter */ 659 uint64_t bcnt; /* Byte counter */ 660}; 661 662#ifndef _KERNEL 663/* 664 * Legacy rule format 665 */ 666struct ip_fw { 667 struct ip_fw *x_next; /* linked list of rules */ 668 struct ip_fw *next_rule; /* ptr to next [skipto] rule */ 669 /* 'next_rule' is used to pass up 'set_disable' status */ 670 671 uint16_t act_ofs; /* offset of action in 32-bit units */ 672 uint16_t cmd_len; /* # of 32-bit words in cmd */ 673 uint16_t rulenum; /* rule number */ 674 uint8_t set; /* rule set (0..31) */ 675 uint8_t _pad; /* padding */ 676 uint32_t id; /* rule id */ 677 678 /* These fields are present in all rules. */ 679 uint64_t pcnt; /* Packet counter */ 680 uint64_t bcnt; /* Byte counter */ 681 uint32_t timestamp; /* tv_sec of last match */ 682 683 ipfw_insn cmd[1]; /* storage for commands */ 684}; 685#endif 686 687#define ACTION_PTR(rule) \ 688 (ipfw_insn *)( (u_int32_t *)((rule)->cmd) + ((rule)->act_ofs) ) 689 690#define RULESIZE(rule) (sizeof(*(rule)) + (rule)->cmd_len * 4 - 4) 691 692#if 1 // should be moved to in.h 693/* 694 * This structure is used as a flow mask and a flow id for various 695 * parts of the code. 696 * addr_type is used in userland and kernel to mark the address type. 697 * fib is used in the kernel to record the fib in use. 698 * _flags is used in the kernel to store tcp flags for dynamic rules. 699 */ 700struct ipfw_flow_id { 701 uint32_t dst_ip; 702 uint32_t src_ip; 703 uint16_t dst_port; 704 uint16_t src_port; 705 uint8_t fib; /* XXX: must be uint16_t */ 706 uint8_t proto; 707 uint8_t _flags; /* protocol-specific flags */ 708 uint8_t addr_type; /* 4=ip4, 6=ip6, 1=ether ? */ 709 struct in6_addr dst_ip6; 710 struct in6_addr src_ip6; 711 uint32_t flow_id6; 712 uint32_t extra; /* queue/pipe or frag_id */ 713}; 714#endif 715 716#define IS_IP4_FLOW_ID(id) ((id)->addr_type == 4) 717#define IS_IP6_FLOW_ID(id) ((id)->addr_type == 6) 718 719/* 720 * Dynamic ipfw rule. 721 */ 722typedef struct _ipfw_dyn_rule ipfw_dyn_rule; 723 724struct _ipfw_dyn_rule { 725 ipfw_dyn_rule *next; /* linked list of rules. */ 726 struct ip_fw *rule; /* pointer to rule */ 727 /* 'rule' is used to pass up the rule number (from the parent) */ 728 729 ipfw_dyn_rule *parent; /* pointer to parent rule */ 730 u_int64_t pcnt; /* packet match counter */ 731 u_int64_t bcnt; /* byte match counter */ 732 struct ipfw_flow_id id; /* (masked) flow id */ 733 u_int32_t expire; /* expire time */ 734 u_int32_t bucket; /* which bucket in hash table */ 735 u_int32_t state; /* state of this rule (typically a 736 * combination of TCP flags) 737 */ 738#define IPFW_DYN_ORPHANED 0x40000 /* state's parent rule was deleted */ 739 u_int32_t ack_fwd; /* most recent ACKs in forward */ 740 u_int32_t ack_rev; /* and reverse directions (used */ 741 /* to generate keepalives) */ 742 u_int16_t dyn_type; /* rule type */ 743 u_int16_t count; /* refcount */ 744 u_int16_t kidx; /* index of named object */ 745} __packed __aligned(8); 746 747/* 748 * Definitions for IP option names. 749 */ 750#define IP_FW_IPOPT_LSRR 0x01 751#define IP_FW_IPOPT_SSRR 0x02 752#define IP_FW_IPOPT_RR 0x04 753#define IP_FW_IPOPT_TS 0x08 754 755/* 756 * Definitions for TCP option names. 757 */ 758#define IP_FW_TCPOPT_MSS 0x01 759#define IP_FW_TCPOPT_WINDOW 0x02 760#define IP_FW_TCPOPT_SACK 0x04 761#define IP_FW_TCPOPT_TS 0x08 762#define IP_FW_TCPOPT_CC 0x10 763 764#define ICMP_REJECT_RST 0x100 /* fake ICMP code (send a TCP RST) */ 765#define ICMP6_UNREACH_RST 0x100 /* fake ICMPv6 code (send a TCP RST) */ 766#define ICMP_REJECT_ABORT 0x101 /* fake ICMP code (send an SCTP ABORT) */ 767#define ICMP6_UNREACH_ABORT 0x101 /* fake ICMPv6 code (send an SCTP ABORT) */ 768 769/* 770 * These are used for lookup tables. 771 */ 772 773#define IPFW_TABLE_ADDR 1 /* Table for holding IPv4/IPv6 prefixes */ 774#define IPFW_TABLE_INTERFACE 2 /* Table for holding interface names */ 775#define IPFW_TABLE_NUMBER 3 /* Table for holding ports/uid/gid/etc */ 776#define IPFW_TABLE_FLOW 4 /* Table for holding flow data */ 777#define IPFW_TABLE_MAC 5 /* Table for holding mac address prefixes */ 778#define IPFW_TABLE_MAXTYPE 5 /* Maximum valid number */ 779 780#define IPFW_TABLE_CIDR IPFW_TABLE_ADDR /* compat */ 781 782/* Value types */ 783#define IPFW_VTYPE_LEGACY 0xFFFFFFFF /* All data is filled in */ 784#define IPFW_VTYPE_SKIPTO 0x00000001 /* skipto/call/callreturn */ 785#define IPFW_VTYPE_PIPE 0x00000002 /* pipe/queue */ 786#define IPFW_VTYPE_FIB 0x00000004 /* setfib */ 787#define IPFW_VTYPE_NAT 0x00000008 /* nat */ 788#define IPFW_VTYPE_DSCP 0x00000010 /* dscp */ 789#define IPFW_VTYPE_TAG 0x00000020 /* tag/untag */ 790#define IPFW_VTYPE_DIVERT 0x00000040 /* divert/tee */ 791#define IPFW_VTYPE_NETGRAPH 0x00000080 /* netgraph/ngtee */ 792#define IPFW_VTYPE_LIMIT 0x00000100 /* limit */ 793#define IPFW_VTYPE_NH4 0x00000200 /* IPv4 nexthop */ 794#define IPFW_VTYPE_NH6 0x00000400 /* IPv6 nexthop */ 795#define IPFW_VTYPE_MARK 0x00000800 /* [fw]mark */ 796 797/* MAC/InfiniBand/etc address length */ 798#define IPFW_MAX_L2_ADDR_LEN 20 799 800typedef struct _ipfw_table_entry { 801 in_addr_t addr; /* network address */ 802 u_int32_t value; /* value */ 803 u_int16_t tbl; /* table number */ 804 u_int8_t masklen; /* mask length */ 805} ipfw_table_entry; 806 807typedef struct _ipfw_table_xentry { 808 uint16_t len; /* Total entry length */ 809 uint8_t type; /* entry type */ 810 uint8_t masklen; /* mask length */ 811 uint16_t tbl; /* table number */ 812 uint16_t flags; /* record flags */ 813 uint32_t value; /* value */ 814 union { 815 /* Longest field needs to be aligned by 4-byte boundary */ 816 struct in6_addr addr6; /* IPv6 address */ 817 char iface[IF_NAMESIZE]; /* interface name */ 818 } k; 819} ipfw_table_xentry; 820#define IPFW_TCF_INET 0x01 /* CIDR flags: IPv4 record */ 821 822typedef struct _ipfw_table { 823 u_int32_t size; /* size of entries in bytes */ 824 u_int32_t cnt; /* # of entries */ 825 u_int16_t tbl; /* table number */ 826 ipfw_table_entry ent[0]; /* entries */ 827} ipfw_table; 828 829typedef struct _ipfw_xtable { 830 ip_fw3_opheader opheader; /* IP_FW3 opcode */ 831 uint32_t size; /* size of entries in bytes */ 832 uint32_t cnt; /* # of entries */ 833 uint16_t tbl; /* table number */ 834 uint8_t type; /* table type */ 835 ipfw_table_xentry xent[0]; /* entries */ 836} ipfw_xtable; 837 838typedef struct _ipfw_obj_tlv { 839 uint16_t type; /* TLV type */ 840 uint16_t flags; /* TLV-specific flags */ 841 uint32_t length; /* Total length, aligned to u64 */ 842} ipfw_obj_tlv; 843#define IPFW_TLV_TBL_NAME 1 844#define IPFW_TLV_TBLNAME_LIST 2 845#define IPFW_TLV_RULE_LIST 3 846#define IPFW_TLV_DYNSTATE_LIST 4 847#define IPFW_TLV_TBL_ENT 5 848#define IPFW_TLV_DYN_ENT 6 849#define IPFW_TLV_RULE_ENT 7 850#define IPFW_TLV_TBLENT_LIST 8 851#define IPFW_TLV_RANGE 9 852#define IPFW_TLV_EACTION 10 853#define IPFW_TLV_COUNTERS 11 854#define IPFW_TLV_OBJDATA 12 855#define IPFW_TLV_STATE_NAME 14 856 857#define IPFW_TLV_EACTION_BASE 1000 858#define IPFW_TLV_EACTION_NAME(arg) (IPFW_TLV_EACTION_BASE + (arg)) 859 860typedef struct _ipfw_obj_data { 861 ipfw_obj_tlv head; 862 void *data[0]; 863} ipfw_obj_data; 864 865/* Object name TLV */ 866typedef struct _ipfw_obj_ntlv { 867 ipfw_obj_tlv head; /* TLV header */ 868 uint16_t idx; /* Name index */ 869 uint8_t set; /* set, if applicable */ 870 uint8_t type; /* object type, if applicable */ 871 uint32_t spare; /* unused */ 872 char name[64]; /* Null-terminated name */ 873} ipfw_obj_ntlv; 874 875/* IPv4/IPv6 L4 flow description */ 876struct tflow_entry { 877 uint8_t af; 878 uint8_t proto; 879 uint16_t spare; 880 uint16_t sport; 881 uint16_t dport; 882 union { 883 struct { 884 struct in_addr sip; 885 struct in_addr dip; 886 } a4; 887 struct { 888 struct in6_addr sip6; 889 struct in6_addr dip6; 890 } a6; 891 } a; 892}; 893 894/* 64-byte structure representing multi-field table value */ 895typedef struct _ipfw_table_value { 896 uint32_t tag; /* O_TAG/O_TAGGED */ 897 uint32_t pipe; /* O_PIPE/O_QUEUE */ 898 uint16_t divert; /* O_DIVERT/O_TEE */ 899 uint16_t skipto; /* skipto, CALLRET */ 900 uint32_t netgraph; /* O_NETGRAPH/O_NGTEE */ 901 uint32_t fib; /* O_SETFIB */ 902 uint32_t nat; /* O_NAT */ 903 uint32_t nh4; 904 uint8_t dscp; 905 uint8_t spare0; 906 uint16_t kidx; /* value kernel index */ 907 struct in6_addr nh6; 908 uint32_t limit; /* O_LIMIT */ 909 uint32_t zoneid; /* scope zone id for nh6 */ 910 uint32_t mark; /* O_SETMARK/O_MARK */ 911 uint32_t refcnt; /* XXX 64-bit in kernel */ 912} ipfw_table_value; 913 914/* Table entry TLV */ 915typedef struct _ipfw_obj_tentry { 916 ipfw_obj_tlv head; /* TLV header */ 917 uint8_t subtype; /* subtype (IPv4,IPv6) */ 918 uint8_t masklen; /* mask length */ 919 uint8_t result; /* request result */ 920 uint8_t spare0; 921 uint16_t idx; /* Table name index */ 922 uint16_t spare1; 923 union { 924 /* Longest field needs to be aligned by 8-byte boundary */ 925 struct in_addr addr; /* IPv4 address */ 926 uint32_t key; /* uid/gid/port */ 927 struct in6_addr addr6; /* IPv6 address */ 928 char iface[IF_NAMESIZE]; /* interface name */ 929 u_char mac[IPFW_MAX_L2_ADDR_LEN]; /* MAC address */ 930 struct tflow_entry flow; 931 } k; 932 union { 933 ipfw_table_value value; /* value data */ 934 uint32_t kidx; /* value kernel index */ 935 } v; 936} ipfw_obj_tentry; 937#define IPFW_TF_UPDATE 0x01 /* Update record if exists */ 938/* Container TLV */ 939#define IPFW_CTF_ATOMIC 0x01 /* Perform atomic operation */ 940/* Operation results */ 941#define IPFW_TR_IGNORED 0 /* Entry was ignored (rollback) */ 942#define IPFW_TR_ADDED 1 /* Entry was successfully added */ 943#define IPFW_TR_UPDATED 2 /* Entry was successfully updated*/ 944#define IPFW_TR_DELETED 3 /* Entry was successfully deleted*/ 945#define IPFW_TR_LIMIT 4 /* Entry was ignored (limit) */ 946#define IPFW_TR_NOTFOUND 5 /* Entry was not found */ 947#define IPFW_TR_EXISTS 6 /* Entry already exists */ 948#define IPFW_TR_ERROR 7 /* Request has failed (unknown) */ 949 950typedef struct _ipfw_obj_dyntlv { 951 ipfw_obj_tlv head; 952 ipfw_dyn_rule state; 953} ipfw_obj_dyntlv; 954#define IPFW_DF_LAST 0x01 /* Last state in chain */ 955 956/* Containter TLVs */ 957typedef struct _ipfw_obj_ctlv { 958 ipfw_obj_tlv head; /* TLV header */ 959 uint32_t count; /* Number of sub-TLVs */ 960 uint16_t objsize; /* Single object size */ 961 uint8_t version; /* TLV version */ 962 uint8_t flags; /* TLV-specific flags */ 963} ipfw_obj_ctlv; 964 965/* Range TLV */ 966typedef struct _ipfw_range_tlv { 967 ipfw_obj_tlv head; /* TLV header */ 968 uint32_t flags; /* Range flags */ 969 uint16_t start_rule; /* Range start */ 970 uint16_t end_rule; /* Range end */ 971 uint32_t set; /* Range set to match */ 972 uint32_t new_set; /* New set to move/swap to */ 973} ipfw_range_tlv; 974#define IPFW_RCFLAG_RANGE 0x01 /* rule range is set */ 975#define IPFW_RCFLAG_ALL 0x02 /* match ALL rules */ 976#define IPFW_RCFLAG_SET 0x04 /* match rules in given set */ 977#define IPFW_RCFLAG_DYNAMIC 0x08 /* match only dynamic states */ 978/* User-settable flags */ 979#define IPFW_RCFLAG_USER (IPFW_RCFLAG_RANGE | IPFW_RCFLAG_ALL | \ 980 IPFW_RCFLAG_SET | IPFW_RCFLAG_DYNAMIC) 981/* Internally used flags */ 982#define IPFW_RCFLAG_DEFAULT 0x0100 /* Do not skip default rule */ 983 984typedef struct _ipfw_ta_tinfo { 985 uint32_t flags; /* Format flags */ 986 uint32_t spare; 987 uint8_t taclass4; /* algorithm class */ 988 uint8_t spare4; 989 uint16_t itemsize4; /* item size in runtime */ 990 uint32_t size4; /* runtime structure size */ 991 uint32_t count4; /* number of items in runtime */ 992 uint8_t taclass6; /* algorithm class */ 993 uint8_t spare6; 994 uint16_t itemsize6; /* item size in runtime */ 995 uint32_t size6; /* runtime structure size */ 996 uint32_t count6; /* number of items in runtime */ 997} ipfw_ta_tinfo; 998#define IPFW_TACLASS_HASH 1 /* algo is based on hash */ 999#define IPFW_TACLASS_ARRAY 2 /* algo is based on array */ 1000#define IPFW_TACLASS_RADIX 3 /* algo is based on radix tree */ 1001 1002#define IPFW_TATFLAGS_DATA 0x0001 /* Has data filled in */ 1003#define IPFW_TATFLAGS_AFDATA 0x0002 /* Separate data per AF */ 1004#define IPFW_TATFLAGS_AFITEM 0x0004 /* diff. items per AF */ 1005 1006typedef struct _ipfw_xtable_info { 1007 uint8_t type; /* table type (addr,iface,..) */ 1008 uint8_t tflags; /* type flags */ 1009 uint16_t mflags; /* modification flags */ 1010 uint16_t flags; /* generic table flags */ 1011 uint16_t spare[3]; 1012 uint32_t vmask; /* bitmask with value types */ 1013 uint32_t set; /* set table is in */ 1014 uint32_t kidx; /* kernel index */ 1015 uint32_t refcnt; /* number of references */ 1016 uint32_t count; /* Number of records */ 1017 uint32_t size; /* Total size of records(export)*/ 1018 uint32_t limit; /* Max number of records */ 1019 char tablename[64]; /* table name */ 1020 char algoname[64]; /* algorithm name */ 1021 ipfw_ta_tinfo ta_info; /* additional algo stats */ 1022} ipfw_xtable_info; 1023/* Generic table flags */ 1024#define IPFW_TGFLAGS_LOCKED 0x01 /* Tables is locked from changes*/ 1025/* Table type-specific flags */ 1026#define IPFW_TFFLAG_SRCIP 0x01 1027#define IPFW_TFFLAG_DSTIP 0x02 1028#define IPFW_TFFLAG_SRCPORT 0x04 1029#define IPFW_TFFLAG_DSTPORT 0x08 1030#define IPFW_TFFLAG_PROTO 0x10 1031/* Table modification flags */ 1032#define IPFW_TMFLAGS_LIMIT 0x0002 /* Change limit value */ 1033#define IPFW_TMFLAGS_LOCK 0x0004 /* Change table lock state */ 1034 1035typedef struct _ipfw_iface_info { 1036 char ifname[64]; /* interface name */ 1037 uint32_t ifindex; /* interface index */ 1038 uint32_t flags; /* flags */ 1039 uint32_t refcnt; /* number of references */ 1040 uint32_t gencnt; /* number of changes */ 1041 uint64_t spare; 1042} ipfw_iface_info; 1043#define IPFW_IFFLAG_RESOLVED 0x01 /* Interface exists */ 1044 1045typedef struct _ipfw_ta_info { 1046 char algoname[64]; /* algorithm name */ 1047 uint32_t type; /* lookup type */ 1048 uint32_t flags; 1049 uint32_t refcnt; 1050 uint32_t spare0; 1051 uint64_t spare1; 1052} ipfw_ta_info; 1053 1054typedef struct _ipfw_obj_header { 1055 ip_fw3_opheader opheader; /* IP_FW3 opcode */ 1056 uint32_t spare; 1057 uint16_t idx; /* object name index */ 1058 uint8_t objtype; /* object type */ 1059 uint8_t objsubtype; /* object subtype */ 1060 ipfw_obj_ntlv ntlv; /* object name tlv */ 1061} ipfw_obj_header; 1062 1063typedef struct _ipfw_obj_lheader { 1064 ip_fw3_opheader opheader; /* IP_FW3 opcode */ 1065 uint32_t set_mask; /* disabled set mask */ 1066 uint32_t count; /* Total objects count */ 1067 uint32_t size; /* Total size (incl. header) */ 1068 uint32_t objsize; /* Size of one object */ 1069} ipfw_obj_lheader; 1070 1071#define IPFW_CFG_GET_STATIC 0x01 1072#define IPFW_CFG_GET_STATES 0x02 1073#define IPFW_CFG_GET_COUNTERS 0x04 1074typedef struct _ipfw_cfg_lheader { 1075 ip_fw3_opheader opheader; /* IP_FW3 opcode */ 1076 uint32_t set_mask; /* enabled set mask */ 1077 uint32_t spare; 1078 uint32_t flags; /* Request flags */ 1079 uint32_t size; /* neded buffer size */ 1080 uint32_t start_rule; 1081 uint32_t end_rule; 1082} ipfw_cfg_lheader; 1083 1084typedef struct _ipfw_range_header { 1085 ip_fw3_opheader opheader; /* IP_FW3 opcode */ 1086 ipfw_range_tlv range; 1087} ipfw_range_header; 1088 1089typedef struct _ipfw_sopt_info { 1090 uint16_t opcode; 1091 uint8_t version; 1092 uint8_t dir; 1093 uint8_t spare; 1094 uint64_t refcnt; 1095} ipfw_sopt_info; 1096 1097#endif /* _IPFW2_H */ 1098