npf_ruleset.c revision 1.51.20.1
1 1.1 rmind /*- 2 1.51 rmind * Copyright (c) 2020 Mindaugas Rasiukevicius <rmind at noxt eu> 3 1.41 rmind * Copyright (c) 2009-2015 The NetBSD Foundation, Inc. 4 1.1 rmind * All rights reserved. 5 1.1 rmind * 6 1.1 rmind * This material is based upon work partially supported by The 7 1.1 rmind * NetBSD Foundation under a contract with Mindaugas Rasiukevicius. 8 1.1 rmind * 9 1.1 rmind * Redistribution and use in source and binary forms, with or without 10 1.1 rmind * modification, are permitted provided that the following conditions 11 1.1 rmind * are met: 12 1.1 rmind * 1. Redistributions of source code must retain the above copyright 13 1.1 rmind * notice, this list of conditions and the following disclaimer. 14 1.1 rmind * 2. Redistributions in binary form must reproduce the above copyright 15 1.1 rmind * notice, this list of conditions and the following disclaimer in the 16 1.1 rmind * documentation and/or other materials provided with the distribution. 17 1.1 rmind * 18 1.1 rmind * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 19 1.1 rmind * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 20 1.1 rmind * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 21 1.1 rmind * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 22 1.1 rmind * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 23 1.1 rmind * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 24 1.1 rmind * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 25 1.1 rmind * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 26 1.1 rmind * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 27 1.1 rmind * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 28 1.1 rmind * POSSIBILITY OF SUCH DAMAGE. 29 1.1 rmind */ 30 1.1 rmind 31 1.1 rmind /* 32 1.1 rmind * NPF ruleset module. 33 1.1 rmind */ 34 1.1 rmind 35 1.43 christos #ifdef _KERNEL 36 1.1 rmind #include <sys/cdefs.h> 37 1.51.20.1 martin __KERNEL_RCSID(0, "$NetBSD: npf_ruleset.c,v 1.51.20.1 2023/08/23 18:19:32 martin Exp $"); 38 1.1 rmind 39 1.1 rmind #include <sys/param.h> 40 1.11 rmind #include <sys/types.h> 41 1.1 rmind 42 1.20 rmind #include <sys/atomic.h> 43 1.1 rmind #include <sys/kmem.h> 44 1.1 rmind #include <sys/queue.h> 45 1.17 rmind #include <sys/mbuf.h> 46 1.1 rmind #include <sys/types.h> 47 1.1 rmind 48 1.17 rmind #include <net/bpf.h> 49 1.20 rmind #include <net/bpfjit.h> 50 1.3 rmind #include <net/pfil.h> 51 1.1 rmind #include <net/if.h> 52 1.43 christos #endif 53 1.1 rmind 54 1.1 rmind #include "npf_impl.h" 55 1.1 rmind 56 1.4 rmind struct npf_ruleset { 57 1.18 rmind /* 58 1.18 rmind * - List of all rules. 59 1.18 rmind * - Dynamic (i.e. named) rules. 60 1.18 rmind * - G/C list for convenience. 61 1.18 rmind */ 62 1.17 rmind LIST_HEAD(, npf_rule) rs_all; 63 1.17 rmind LIST_HEAD(, npf_rule) rs_dynamic; 64 1.18 rmind LIST_HEAD(, npf_rule) rs_gc; 65 1.17 rmind 66 1.19 rmind /* Unique ID counter. */ 67 1.19 rmind uint64_t rs_idcnt; 68 1.19 rmind 69 1.17 rmind /* Number of array slots and active rules. */ 70 1.51 rmind unsigned rs_slots; 71 1.51 rmind unsigned rs_nitems; 72 1.17 rmind 73 1.17 rmind /* Array of ordered rules. */ 74 1.17 rmind npf_rule_t * rs_rules[]; 75 1.4 rmind }; 76 1.4 rmind 77 1.1 rmind struct npf_rule { 78 1.17 rmind /* Attributes, interface and skip slot. */ 79 1.4 rmind uint32_t r_attr; 80 1.51 rmind unsigned r_ifid; 81 1.51 rmind unsigned r_skip_to; 82 1.17 rmind 83 1.17 rmind /* Code to process, if any. */ 84 1.17 rmind int r_type; 85 1.27 rmind bpfjit_func_t r_jcode; 86 1.17 rmind void * r_code; 87 1.51 rmind unsigned r_clen; 88 1.17 rmind 89 1.17 rmind /* NAT policy (optional), rule procedure and subset. */ 90 1.17 rmind npf_natpolicy_t * r_natp; 91 1.4 rmind npf_rproc_t * r_rproc; 92 1.17 rmind 93 1.42 rmind union { 94 1.42 rmind /* 95 1.42 rmind * Dynamic group: rule subset and a group list entry. 96 1.42 rmind */ 97 1.42 rmind struct { 98 1.42 rmind npf_rule_t * r_subset; 99 1.42 rmind LIST_ENTRY(npf_rule) r_dentry; 100 1.42 rmind }; 101 1.17 rmind 102 1.42 rmind /* 103 1.42 rmind * Dynamic rule: priority, parent group and next rule. 104 1.42 rmind */ 105 1.42 rmind struct { 106 1.42 rmind int r_priority; 107 1.42 rmind npf_rule_t * r_parent; 108 1.42 rmind npf_rule_t * r_next; 109 1.42 rmind }; 110 1.42 rmind }; 111 1.17 rmind 112 1.36 rmind /* Rule ID, name and the optional key. */ 113 1.19 rmind uint64_t r_id; 114 1.36 rmind char r_name[NPF_RULE_MAXNAMELEN]; 115 1.36 rmind uint8_t r_key[NPF_RULE_MAXKEYLEN]; 116 1.18 rmind 117 1.36 rmind /* All-list entry and the auxiliary info. */ 118 1.17 rmind LIST_ENTRY(npf_rule) r_aentry; 119 1.47 rmind nvlist_t * r_info; 120 1.47 rmind size_t r_info_len; 121 1.36 rmind }; 122 1.17 rmind 123 1.37 rmind #define SKIPTO_ADJ_FLAG (1U << 31) 124 1.37 rmind #define SKIPTO_MASK (SKIPTO_ADJ_FLAG - 1) 125 1.37 rmind 126 1.47 rmind static nvlist_t * npf_rule_export(npf_t *, const npf_rule_t *); 127 1.1 rmind 128 1.31 rmind /* 129 1.31 rmind * Private attributes - must be in the NPF_RULE_PRIVMASK range. 130 1.31 rmind */ 131 1.31 rmind #define NPF_RULE_KEEPNAT (0x01000000 & NPF_RULE_PRIVMASK) 132 1.31 rmind 133 1.17 rmind #define NPF_DYNAMIC_GROUP_P(attr) \ 134 1.17 rmind (((attr) & NPF_DYNAMIC_GROUP) == NPF_DYNAMIC_GROUP) 135 1.17 rmind 136 1.19 rmind #define NPF_DYNAMIC_RULE_P(attr) \ 137 1.19 rmind (((attr) & NPF_DYNAMIC_GROUP) == NPF_RULE_DYNAMIC) 138 1.19 rmind 139 1.1 rmind npf_ruleset_t * 140 1.17 rmind npf_ruleset_create(size_t slots) 141 1.1 rmind { 142 1.17 rmind size_t len = offsetof(npf_ruleset_t, rs_rules[slots]); 143 1.1 rmind npf_ruleset_t *rlset; 144 1.1 rmind 145 1.17 rmind rlset = kmem_zalloc(len, KM_SLEEP); 146 1.17 rmind LIST_INIT(&rlset->rs_dynamic); 147 1.17 rmind LIST_INIT(&rlset->rs_all); 148 1.19 rmind LIST_INIT(&rlset->rs_gc); 149 1.19 rmind rlset->rs_slots = slots; 150 1.19 rmind 151 1.1 rmind return rlset; 152 1.1 rmind } 153 1.1 rmind 154 1.1 rmind void 155 1.1 rmind npf_ruleset_destroy(npf_ruleset_t *rlset) 156 1.1 rmind { 157 1.17 rmind size_t len = offsetof(npf_ruleset_t, rs_rules[rlset->rs_slots]); 158 1.1 rmind npf_rule_t *rl; 159 1.1 rmind 160 1.17 rmind while ((rl = LIST_FIRST(&rlset->rs_all)) != NULL) { 161 1.42 rmind if (NPF_DYNAMIC_GROUP_P(rl->r_attr)) { 162 1.42 rmind /* 163 1.42 rmind * Note: r_subset may point to the rules which 164 1.42 rmind * were inherited by a new ruleset. 165 1.42 rmind */ 166 1.42 rmind rl->r_subset = NULL; 167 1.42 rmind LIST_REMOVE(rl, r_dentry); 168 1.42 rmind } 169 1.42 rmind if (NPF_DYNAMIC_RULE_P(rl->r_attr)) { 170 1.42 rmind /* Not removing from r_subset, see above. */ 171 1.42 rmind KASSERT(rl->r_parent != NULL); 172 1.42 rmind } 173 1.42 rmind LIST_REMOVE(rl, r_aentry); 174 1.1 rmind npf_rule_free(rl); 175 1.1 rmind } 176 1.17 rmind KASSERT(LIST_EMPTY(&rlset->rs_dynamic)); 177 1.43 christos 178 1.43 christos npf_ruleset_gc(rlset); 179 1.18 rmind KASSERT(LIST_EMPTY(&rlset->rs_gc)); 180 1.17 rmind kmem_free(rlset, len); 181 1.1 rmind } 182 1.1 rmind 183 1.1 rmind /* 184 1.1 rmind * npf_ruleset_insert: insert the rule into the specified ruleset. 185 1.1 rmind */ 186 1.1 rmind void 187 1.1 rmind npf_ruleset_insert(npf_ruleset_t *rlset, npf_rule_t *rl) 188 1.1 rmind { 189 1.51 rmind unsigned n = rlset->rs_nitems; 190 1.17 rmind 191 1.17 rmind KASSERT(n < rlset->rs_slots); 192 1.17 rmind 193 1.17 rmind LIST_INSERT_HEAD(&rlset->rs_all, rl, r_aentry); 194 1.17 rmind if (NPF_DYNAMIC_GROUP_P(rl->r_attr)) { 195 1.17 rmind LIST_INSERT_HEAD(&rlset->rs_dynamic, rl, r_dentry); 196 1.24 rmind } else { 197 1.24 rmind KASSERTMSG(rl->r_parent == NULL, "cannot be dynamic rule"); 198 1.24 rmind rl->r_attr &= ~NPF_RULE_DYNAMIC; 199 1.17 rmind } 200 1.17 rmind 201 1.17 rmind rlset->rs_rules[n] = rl; 202 1.17 rmind rlset->rs_nitems++; 203 1.45 christos rl->r_id = ++rlset->rs_idcnt; 204 1.17 rmind 205 1.17 rmind if (rl->r_skip_to < ++n) { 206 1.37 rmind rl->r_skip_to = SKIPTO_ADJ_FLAG | n; 207 1.17 rmind } 208 1.17 rmind } 209 1.17 rmind 210 1.46 rmind npf_rule_t * 211 1.17 rmind npf_ruleset_lookup(npf_ruleset_t *rlset, const char *name) 212 1.17 rmind { 213 1.17 rmind npf_rule_t *rl; 214 1.17 rmind 215 1.17 rmind LIST_FOREACH(rl, &rlset->rs_dynamic, r_dentry) { 216 1.17 rmind KASSERT(NPF_DYNAMIC_GROUP_P(rl->r_attr)); 217 1.17 rmind if (strncmp(rl->r_name, name, NPF_RULE_MAXNAMELEN) == 0) 218 1.17 rmind break; 219 1.17 rmind } 220 1.17 rmind return rl; 221 1.17 rmind } 222 1.17 rmind 223 1.39 rmind /* 224 1.39 rmind * npf_ruleset_add: insert dynamic rule into the (active) ruleset. 225 1.39 rmind */ 226 1.17 rmind int 227 1.17 rmind npf_ruleset_add(npf_ruleset_t *rlset, const char *rname, npf_rule_t *rl) 228 1.17 rmind { 229 1.42 rmind npf_rule_t *rg, *it, *target; 230 1.42 rmind int priocmd; 231 1.17 rmind 232 1.42 rmind if (!NPF_DYNAMIC_RULE_P(rl->r_attr)) { 233 1.42 rmind return EINVAL; 234 1.42 rmind } 235 1.17 rmind rg = npf_ruleset_lookup(rlset, rname); 236 1.17 rmind if (rg == NULL) { 237 1.19 rmind return ESRCH; 238 1.19 rmind } 239 1.17 rmind 240 1.19 rmind /* Dynamic rule - assign a unique ID and save the parent. */ 241 1.19 rmind rl->r_id = ++rlset->rs_idcnt; 242 1.17 rmind rl->r_parent = rg; 243 1.17 rmind 244 1.17 rmind /* 245 1.17 rmind * Rule priority: (highest) 1, 2 ... n (lowest). 246 1.17 rmind * Negative priority indicates an operation and is reset to zero. 247 1.17 rmind */ 248 1.17 rmind if ((priocmd = rl->r_priority) < 0) { 249 1.17 rmind rl->r_priority = 0; 250 1.17 rmind } 251 1.17 rmind 252 1.42 rmind /* 253 1.42 rmind * WARNING: once rg->subset or target->r_next of an *active* 254 1.42 rmind * rule is set, then our rule becomes globally visible and active. 255 1.42 rmind * Must issue a load fence to ensure rl->r_next visibility first. 256 1.42 rmind */ 257 1.17 rmind switch (priocmd) { 258 1.17 rmind case NPF_PRI_LAST: 259 1.17 rmind default: 260 1.42 rmind target = NULL; 261 1.42 rmind it = rg->r_subset; 262 1.42 rmind while (it && it->r_priority <= rl->r_priority) { 263 1.42 rmind target = it; 264 1.42 rmind it = it->r_next; 265 1.42 rmind } 266 1.42 rmind if (target) { 267 1.51 rmind atomic_store_relaxed(&rl->r_next, target->r_next); 268 1.42 rmind membar_producer(); 269 1.51 rmind atomic_store_relaxed(&target->r_next, rl); 270 1.42 rmind break; 271 1.17 rmind } 272 1.42 rmind /* FALLTHROUGH */ 273 1.42 rmind 274 1.42 rmind case NPF_PRI_FIRST: 275 1.51 rmind atomic_store_relaxed(&rl->r_next, rg->r_subset); 276 1.42 rmind membar_producer(); 277 1.51 rmind atomic_store_relaxed(&rg->r_subset, rl); 278 1.17 rmind break; 279 1.17 rmind } 280 1.17 rmind 281 1.17 rmind /* Finally, add into the all-list. */ 282 1.17 rmind LIST_INSERT_HEAD(&rlset->rs_all, rl, r_aentry); 283 1.17 rmind return 0; 284 1.17 rmind } 285 1.17 rmind 286 1.42 rmind static void 287 1.42 rmind npf_ruleset_unlink(npf_rule_t *rl, npf_rule_t *prev) 288 1.42 rmind { 289 1.42 rmind KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr)); 290 1.42 rmind if (prev) { 291 1.42 rmind prev->r_next = rl->r_next; 292 1.42 rmind } else { 293 1.42 rmind npf_rule_t *rg = rl->r_parent; 294 1.42 rmind rg->r_subset = rl->r_next; 295 1.42 rmind } 296 1.42 rmind LIST_REMOVE(rl, r_aentry); 297 1.42 rmind } 298 1.42 rmind 299 1.39 rmind /* 300 1.39 rmind * npf_ruleset_remove: remove the dynamic rule given the rule ID. 301 1.39 rmind */ 302 1.18 rmind int 303 1.19 rmind npf_ruleset_remove(npf_ruleset_t *rlset, const char *rname, uint64_t id) 304 1.17 rmind { 305 1.42 rmind npf_rule_t *rg, *prev = NULL; 306 1.17 rmind 307 1.17 rmind if ((rg = npf_ruleset_lookup(rlset, rname)) == NULL) { 308 1.19 rmind return ESRCH; 309 1.17 rmind } 310 1.42 rmind for (npf_rule_t *rl = rg->r_subset; rl; rl = rl->r_next) { 311 1.24 rmind KASSERT(rl->r_parent == rg); 312 1.42 rmind KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr)); 313 1.24 rmind 314 1.17 rmind /* Compare ID. On match, remove and return. */ 315 1.19 rmind if (rl->r_id == id) { 316 1.42 rmind npf_ruleset_unlink(rl, prev); 317 1.18 rmind LIST_INSERT_HEAD(&rlset->rs_gc, rl, r_aentry); 318 1.19 rmind return 0; 319 1.17 rmind } 320 1.42 rmind prev = rl; 321 1.17 rmind } 322 1.19 rmind return ENOENT; 323 1.17 rmind } 324 1.17 rmind 325 1.39 rmind /* 326 1.39 rmind * npf_ruleset_remkey: remove the dynamic rule given the rule key. 327 1.39 rmind */ 328 1.18 rmind int 329 1.17 rmind npf_ruleset_remkey(npf_ruleset_t *rlset, const char *rname, 330 1.17 rmind const void *key, size_t len) 331 1.17 rmind { 332 1.42 rmind npf_rule_t *rg, *rlast = NULL, *prev = NULL, *lastprev = NULL; 333 1.1 rmind 334 1.17 rmind KASSERT(len && len <= NPF_RULE_MAXKEYLEN); 335 1.17 rmind 336 1.17 rmind if ((rg = npf_ruleset_lookup(rlset, rname)) == NULL) { 337 1.19 rmind return ESRCH; 338 1.17 rmind } 339 1.18 rmind 340 1.42 rmind /* Compare the key and find the last in the list. */ 341 1.42 rmind for (npf_rule_t *rl = rg->r_subset; rl; rl = rl->r_next) { 342 1.24 rmind KASSERT(rl->r_parent == rg); 343 1.42 rmind KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr)); 344 1.17 rmind if (memcmp(rl->r_key, key, len) == 0) { 345 1.42 rmind lastprev = prev; 346 1.42 rmind rlast = rl; 347 1.17 rmind } 348 1.42 rmind prev = rl; 349 1.42 rmind } 350 1.42 rmind if (!rlast) { 351 1.42 rmind return ENOENT; 352 1.1 rmind } 353 1.42 rmind npf_ruleset_unlink(rlast, lastprev); 354 1.42 rmind LIST_INSERT_HEAD(&rlset->rs_gc, rlast, r_aentry); 355 1.42 rmind return 0; 356 1.18 rmind } 357 1.18 rmind 358 1.39 rmind /* 359 1.39 rmind * npf_ruleset_list: serialise and return the dynamic rules. 360 1.39 rmind */ 361 1.51 rmind int 362 1.51 rmind npf_ruleset_list(npf_t *npf, npf_ruleset_t *rlset, const char *rname, 363 1.51 rmind nvlist_t *rlset_nvl) 364 1.18 rmind { 365 1.51 rmind const npf_rule_t *rg; 366 1.18 rmind 367 1.43 christos KASSERT(npf_config_locked_p(npf)); 368 1.36 rmind 369 1.18 rmind if ((rg = npf_ruleset_lookup(rlset, rname)) == NULL) { 370 1.51 rmind return ESRCH; 371 1.18 rmind } 372 1.51 rmind for (const npf_rule_t *rl = rg->r_subset; rl; rl = rl->r_next) { 373 1.47 rmind nvlist_t *rule; 374 1.36 rmind 375 1.24 rmind KASSERT(rl->r_parent == rg); 376 1.42 rmind KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr)); 377 1.36 rmind 378 1.51 rmind if ((rule = npf_rule_export(npf, rl)) == NULL) { 379 1.51 rmind return ENOMEM; 380 1.18 rmind } 381 1.51 rmind nvlist_append_nvlist_array(rlset_nvl, "rules", rule); 382 1.47 rmind nvlist_destroy(rule); 383 1.18 rmind } 384 1.51 rmind return 0; 385 1.18 rmind } 386 1.18 rmind 387 1.39 rmind /* 388 1.39 rmind * npf_ruleset_flush: flush the dynamic rules in the ruleset by inserting 389 1.39 rmind * them into the G/C list. 390 1.39 rmind */ 391 1.18 rmind int 392 1.18 rmind npf_ruleset_flush(npf_ruleset_t *rlset, const char *rname) 393 1.18 rmind { 394 1.18 rmind npf_rule_t *rg, *rl; 395 1.18 rmind 396 1.18 rmind if ((rg = npf_ruleset_lookup(rlset, rname)) == NULL) { 397 1.19 rmind return ESRCH; 398 1.18 rmind } 399 1.42 rmind 400 1.42 rmind rl = atomic_swap_ptr(&rg->r_subset, NULL); 401 1.42 rmind membar_producer(); 402 1.42 rmind 403 1.42 rmind while (rl) { 404 1.42 rmind KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr)); 405 1.24 rmind KASSERT(rl->r_parent == rg); 406 1.42 rmind 407 1.42 rmind LIST_REMOVE(rl, r_aentry); 408 1.18 rmind LIST_INSERT_HEAD(&rlset->rs_gc, rl, r_aentry); 409 1.42 rmind rl = rl->r_next; 410 1.18 rmind } 411 1.45 christos rlset->rs_idcnt = 0; 412 1.18 rmind return 0; 413 1.18 rmind } 414 1.18 rmind 415 1.39 rmind /* 416 1.39 rmind * npf_ruleset_gc: destroy the rules in G/C list. 417 1.39 rmind */ 418 1.39 rmind void 419 1.39 rmind npf_ruleset_gc(npf_ruleset_t *rlset) 420 1.39 rmind { 421 1.39 rmind npf_rule_t *rl; 422 1.39 rmind 423 1.39 rmind while ((rl = LIST_FIRST(&rlset->rs_gc)) != NULL) { 424 1.39 rmind LIST_REMOVE(rl, r_aentry); 425 1.39 rmind npf_rule_free(rl); 426 1.39 rmind } 427 1.39 rmind } 428 1.39 rmind 429 1.39 rmind /* 430 1.39 rmind * npf_ruleset_export: serialise and return the static rules. 431 1.39 rmind */ 432 1.36 rmind int 433 1.47 rmind npf_ruleset_export(npf_t *npf, const npf_ruleset_t *rlset, 434 1.51 rmind const char *key, nvlist_t *npf_nv) 435 1.36 rmind { 436 1.47 rmind const unsigned nitems = rlset->rs_nitems; 437 1.47 rmind unsigned n = 0; 438 1.36 rmind int error = 0; 439 1.36 rmind 440 1.43 christos KASSERT(npf_config_locked_p(npf)); 441 1.36 rmind 442 1.37 rmind while (n < nitems) { 443 1.37 rmind const npf_rule_t *rl = rlset->rs_rules[n]; 444 1.36 rmind const npf_natpolicy_t *natp = rl->r_natp; 445 1.47 rmind nvlist_t *rule; 446 1.36 rmind 447 1.47 rmind rule = npf_rule_export(npf, rl); 448 1.47 rmind if (!rule) { 449 1.47 rmind error = ENOMEM; 450 1.36 rmind break; 451 1.36 rmind } 452 1.51 rmind if (natp && (error = npf_natpolicy_export(natp, rule)) != 0) { 453 1.47 rmind nvlist_destroy(rule); 454 1.36 rmind break; 455 1.36 rmind } 456 1.51 rmind nvlist_append_nvlist_array(npf_nv, key, rule); 457 1.47 rmind nvlist_destroy(rule); 458 1.37 rmind n++; 459 1.36 rmind } 460 1.36 rmind return error; 461 1.36 rmind } 462 1.36 rmind 463 1.17 rmind /* 464 1.31 rmind * npf_ruleset_reload: prepare the new ruleset by scanning the active 465 1.39 rmind * ruleset and: 1) sharing the dynamic rules 2) sharing NAT policies. 466 1.17 rmind * 467 1.31 rmind * => The active (old) ruleset should be exclusively locked. 468 1.17 rmind */ 469 1.17 rmind void 470 1.43 christos npf_ruleset_reload(npf_t *npf, npf_ruleset_t *newset, 471 1.43 christos npf_ruleset_t *oldset, bool load) 472 1.17 rmind { 473 1.31 rmind npf_rule_t *rg, *rl; 474 1.35 rmind uint64_t nid = 0; 475 1.17 rmind 476 1.43 christos KASSERT(npf_config_locked_p(npf)); 477 1.17 rmind 478 1.31 rmind /* 479 1.31 rmind * Scan the dynamic rules and share (migrate) if needed. 480 1.31 rmind */ 481 1.31 rmind LIST_FOREACH(rg, &newset->rs_dynamic, r_dentry) { 482 1.42 rmind npf_rule_t *active_rgroup; 483 1.18 rmind 484 1.31 rmind /* Look for a dynamic ruleset group with such name. */ 485 1.42 rmind active_rgroup = npf_ruleset_lookup(oldset, rg->r_name); 486 1.42 rmind if (active_rgroup == NULL) { 487 1.17 rmind continue; 488 1.17 rmind } 489 1.18 rmind 490 1.18 rmind /* 491 1.42 rmind * ATOMICITY: Copy the head pointer of the linked-list, 492 1.42 rmind * but do not remove the rules from the active r_subset. 493 1.42 rmind * This is necessary because the rules are still active 494 1.42 rmind * and therefore are accessible for inspection via the 495 1.42 rmind * old ruleset. 496 1.18 rmind */ 497 1.42 rmind rg->r_subset = active_rgroup->r_subset; 498 1.42 rmind 499 1.42 rmind /* 500 1.42 rmind * We can safely migrate to the new all-rule list and 501 1.42 rmind * reset the parent rule, though. 502 1.42 rmind */ 503 1.42 rmind for (rl = rg->r_subset; rl; rl = rl->r_next) { 504 1.42 rmind KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr)); 505 1.18 rmind LIST_REMOVE(rl, r_aentry); 506 1.31 rmind LIST_INSERT_HEAD(&newset->rs_all, rl, r_aentry); 507 1.42 rmind 508 1.42 rmind KASSERT(rl->r_parent == active_rgroup); 509 1.19 rmind rl->r_parent = rg; 510 1.18 rmind } 511 1.1 rmind } 512 1.19 rmind 513 1.31 rmind /* 514 1.51 rmind * If performing the load of connections then NAT policies might 515 1.40 rmind * already have translated connections associated with them and 516 1.40 rmind * we should not share or inherit anything. 517 1.40 rmind */ 518 1.40 rmind if (load) 519 1.40 rmind return; 520 1.40 rmind 521 1.40 rmind /* 522 1.48 rmind * Scan all rules in the new ruleset and inherit the active NAT 523 1.48 rmind * policies if they are the same. Also, assign a unique ID for 524 1.48 rmind * each policy here. 525 1.31 rmind */ 526 1.31 rmind LIST_FOREACH(rl, &newset->rs_all, r_aentry) { 527 1.31 rmind npf_natpolicy_t *np; 528 1.31 rmind npf_rule_t *actrl; 529 1.31 rmind 530 1.31 rmind /* Does the rule have a NAT policy associated? */ 531 1.31 rmind if ((np = rl->r_natp) == NULL) { 532 1.31 rmind continue; 533 1.31 rmind } 534 1.35 rmind 535 1.31 rmind /* Does it match with any policy in the active ruleset? */ 536 1.38 rmind LIST_FOREACH(actrl, &oldset->rs_all, r_aentry) { 537 1.38 rmind if (!actrl->r_natp) 538 1.38 rmind continue; 539 1.38 rmind if ((actrl->r_attr & NPF_RULE_KEEPNAT) != 0) 540 1.38 rmind continue; 541 1.51 rmind if (npf_natpolicy_cmp(actrl->r_natp, np)) 542 1.38 rmind break; 543 1.38 rmind } 544 1.38 rmind if (!actrl) { 545 1.38 rmind /* No: just set the ID and continue. */ 546 1.35 rmind npf_nat_setid(np, ++nid); 547 1.31 rmind continue; 548 1.31 rmind } 549 1.31 rmind 550 1.38 rmind /* Yes: inherit the matching NAT policy. */ 551 1.31 rmind rl->r_natp = actrl->r_natp; 552 1.35 rmind npf_nat_setid(rl->r_natp, ++nid); 553 1.31 rmind 554 1.31 rmind /* 555 1.31 rmind * Finally, mark the active rule to not destroy its NAT 556 1.31 rmind * policy later as we inherited it (but the rule must be 557 1.31 rmind * kept active for now). Destroy the new/unused policy. 558 1.31 rmind */ 559 1.31 rmind actrl->r_attr |= NPF_RULE_KEEPNAT; 560 1.51 rmind npf_natpolicy_destroy(np); 561 1.31 rmind } 562 1.31 rmind 563 1.19 rmind /* Inherit the ID counter. */ 564 1.31 rmind newset->rs_idcnt = oldset->rs_idcnt; 565 1.1 rmind } 566 1.1 rmind 567 1.39 rmind /* 568 1.48 rmind * npf_ruleset_findnat: find a NAT policy in the ruleset by a given ID. 569 1.39 rmind */ 570 1.35 rmind npf_natpolicy_t * 571 1.35 rmind npf_ruleset_findnat(npf_ruleset_t *rlset, uint64_t id) 572 1.35 rmind { 573 1.35 rmind npf_rule_t *rl; 574 1.35 rmind 575 1.35 rmind LIST_FOREACH(rl, &rlset->rs_all, r_aentry) { 576 1.35 rmind npf_natpolicy_t *np = rl->r_natp; 577 1.35 rmind if (np && npf_nat_getid(np) == id) { 578 1.35 rmind return np; 579 1.35 rmind } 580 1.35 rmind } 581 1.35 rmind return NULL; 582 1.35 rmind } 583 1.35 rmind 584 1.1 rmind /* 585 1.13 rmind * npf_ruleset_freealg: inspect the ruleset and disassociate specified 586 1.13 rmind * ALG from all NAT entries using it. 587 1.13 rmind */ 588 1.13 rmind void 589 1.13 rmind npf_ruleset_freealg(npf_ruleset_t *rlset, npf_alg_t *alg) 590 1.13 rmind { 591 1.13 rmind npf_rule_t *rl; 592 1.17 rmind npf_natpolicy_t *np; 593 1.13 rmind 594 1.17 rmind LIST_FOREACH(rl, &rlset->rs_all, r_aentry) { 595 1.17 rmind if ((np = rl->r_natp) != NULL) { 596 1.13 rmind npf_nat_freealg(np, alg); 597 1.13 rmind } 598 1.13 rmind } 599 1.13 rmind } 600 1.13 rmind 601 1.13 rmind /* 602 1.25 rmind * npf_rule_alloc: allocate a rule and initialise it. 603 1.1 rmind */ 604 1.4 rmind npf_rule_t * 605 1.47 rmind npf_rule_alloc(npf_t *npf, const nvlist_t *rule) 606 1.1 rmind { 607 1.4 rmind npf_rule_t *rl; 608 1.7 rmind const char *rname; 609 1.47 rmind const void *key, *info; 610 1.47 rmind size_t len; 611 1.1 rmind 612 1.47 rmind /* Allocate a rule structure and keep the information. */ 613 1.11 rmind rl = kmem_zalloc(sizeof(npf_rule_t), KM_SLEEP); 614 1.47 rmind info = dnvlist_get_binary(rule, "info", &rl->r_info_len, NULL, 0); 615 1.47 rmind if (info) { 616 1.47 rmind rl->r_info = kmem_alloc(rl->r_info_len, KM_SLEEP); 617 1.47 rmind memcpy(rl->r_info, info, rl->r_info_len); 618 1.47 rmind } 619 1.4 rmind rl->r_natp = NULL; 620 1.4 rmind 621 1.11 rmind /* Name (optional) */ 622 1.47 rmind if ((rname = dnvlist_get_string(rule, "name", NULL)) != NULL) { 623 1.17 rmind strlcpy(rl->r_name, rname, NPF_RULE_MAXNAMELEN); 624 1.7 rmind } else { 625 1.7 rmind rl->r_name[0] = '\0'; 626 1.7 rmind } 627 1.7 rmind 628 1.11 rmind /* Attributes, priority and interface ID (optional). */ 629 1.47 rmind rl->r_attr = dnvlist_get_number(rule, "attr", 0); 630 1.31 rmind rl->r_attr &= ~NPF_RULE_PRIVMASK; 631 1.26 rmind 632 1.42 rmind if (NPF_DYNAMIC_RULE_P(rl->r_attr)) { 633 1.42 rmind /* Priority of the dynamic rule. */ 634 1.48 rmind rl->r_priority = (int)dnvlist_get_number(rule, "prio", 0); 635 1.42 rmind } else { 636 1.42 rmind /* The skip-to index. No need to validate it. */ 637 1.47 rmind rl->r_skip_to = dnvlist_get_number(rule, "skip-to", 0); 638 1.42 rmind } 639 1.42 rmind 640 1.42 rmind /* Interface name; register and get the npf-if-id. */ 641 1.47 rmind if ((rname = dnvlist_get_string(rule, "ifname", NULL)) != NULL) { 642 1.43 christos if ((rl->r_ifid = npf_ifmap_register(npf, rname)) == 0) { 643 1.26 rmind kmem_free(rl, sizeof(npf_rule_t)); 644 1.26 rmind return NULL; 645 1.26 rmind } 646 1.26 rmind } else { 647 1.26 rmind rl->r_ifid = 0; 648 1.26 rmind } 649 1.4 rmind 650 1.17 rmind /* Key (optional). */ 651 1.47 rmind if ((key = dnvlist_get_binary(rule, "key", &len, NULL, 0)) != NULL) { 652 1.17 rmind if (len > NPF_RULE_MAXKEYLEN) { 653 1.17 rmind kmem_free(rl, sizeof(npf_rule_t)); 654 1.17 rmind return NULL; 655 1.17 rmind } 656 1.17 rmind memcpy(rl->r_key, key, len); 657 1.4 rmind } 658 1.36 rmind return rl; 659 1.36 rmind } 660 1.36 rmind 661 1.47 rmind static nvlist_t * 662 1.47 rmind npf_rule_export(npf_t *npf, const npf_rule_t *rl) 663 1.36 rmind { 664 1.47 rmind nvlist_t *rule = nvlist_create(0); 665 1.47 rmind unsigned skip_to = 0; 666 1.47 rmind npf_rproc_t *rp; 667 1.36 rmind 668 1.47 rmind nvlist_add_number(rule, "attr", rl->r_attr); 669 1.47 rmind nvlist_add_number(rule, "prio", rl->r_priority); 670 1.37 rmind if ((rl->r_skip_to & SKIPTO_ADJ_FLAG) == 0) { 671 1.37 rmind skip_to = rl->r_skip_to & SKIPTO_MASK; 672 1.37 rmind } 673 1.47 rmind nvlist_add_number(rule, "skip-to", skip_to); 674 1.47 rmind nvlist_add_number(rule, "code-type", rl->r_type); 675 1.36 rmind if (rl->r_code) { 676 1.47 rmind nvlist_add_binary(rule, "code", rl->r_code, rl->r_clen); 677 1.36 rmind } 678 1.36 rmind if (rl->r_ifid) { 679 1.49 rmind char ifname[IFNAMSIZ]; 680 1.49 rmind npf_ifmap_copyname(npf, rl->r_ifid, ifname, sizeof(ifname)); 681 1.47 rmind nvlist_add_string(rule, "ifname", ifname); 682 1.36 rmind } 683 1.47 rmind nvlist_add_number(rule, "id", rl->r_id); 684 1.36 rmind 685 1.36 rmind if (rl->r_name[0]) { 686 1.47 rmind nvlist_add_string(rule, "name", rl->r_name); 687 1.36 rmind } 688 1.19 rmind if (NPF_DYNAMIC_RULE_P(rl->r_attr)) { 689 1.47 rmind nvlist_add_binary(rule, "key", rl->r_key, NPF_RULE_MAXKEYLEN); 690 1.18 rmind } 691 1.37 rmind if (rl->r_info) { 692 1.47 rmind nvlist_add_binary(rule, "info", rl->r_info, rl->r_info_len); 693 1.37 rmind } 694 1.47 rmind if ((rp = npf_rule_getrproc(rl)) != NULL) { 695 1.47 rmind const char *rname = npf_rproc_getname(rp); 696 1.47 rmind nvlist_add_string(rule, "rproc", rname); 697 1.44 christos npf_rproc_release(rp); 698 1.44 christos } 699 1.47 rmind return rule; 700 1.17 rmind } 701 1.17 rmind 702 1.17 rmind /* 703 1.17 rmind * npf_rule_setcode: assign filter code to the rule. 704 1.17 rmind * 705 1.20 rmind * => The code must be validated by the caller. 706 1.20 rmind * => JIT compilation may be performed here. 707 1.17 rmind */ 708 1.17 rmind void 709 1.17 rmind npf_rule_setcode(npf_rule_t *rl, const int type, void *code, size_t size) 710 1.17 rmind { 711 1.25 rmind KASSERT(type == NPF_CODE_BPF); 712 1.28 rmind 713 1.28 rmind rl->r_type = type; 714 1.36 rmind rl->r_code = code; 715 1.36 rmind rl->r_clen = size; 716 1.36 rmind rl->r_jcode = npf_bpf_compile(code, size); 717 1.17 rmind } 718 1.17 rmind 719 1.17 rmind /* 720 1.17 rmind * npf_rule_setrproc: assign a rule procedure and hold a reference on it. 721 1.17 rmind */ 722 1.17 rmind void 723 1.17 rmind npf_rule_setrproc(npf_rule_t *rl, npf_rproc_t *rp) 724 1.17 rmind { 725 1.17 rmind npf_rproc_acquire(rp); 726 1.6 rmind rl->r_rproc = rp; 727 1.1 rmind } 728 1.1 rmind 729 1.1 rmind /* 730 1.1 rmind * npf_rule_free: free the specified rule. 731 1.1 rmind */ 732 1.1 rmind void 733 1.1 rmind npf_rule_free(npf_rule_t *rl) 734 1.1 rmind { 735 1.4 rmind npf_natpolicy_t *np = rl->r_natp; 736 1.4 rmind npf_rproc_t *rp = rl->r_rproc; 737 1.1 rmind 738 1.31 rmind if (np && (rl->r_attr & NPF_RULE_KEEPNAT) == 0) { 739 1.51 rmind /* Destroy the NAT policy. */ 740 1.51 rmind npf_natpolicy_destroy(np); 741 1.4 rmind } 742 1.4 rmind if (rp) { 743 1.6 rmind /* Release rule procedure. */ 744 1.4 rmind npf_rproc_release(rp); 745 1.4 rmind } 746 1.17 rmind if (rl->r_code) { 747 1.20 rmind /* Free byte-code. */ 748 1.17 rmind kmem_free(rl->r_code, rl->r_clen); 749 1.1 rmind } 750 1.20 rmind if (rl->r_jcode) { 751 1.20 rmind /* Free JIT code. */ 752 1.28 rmind bpf_jit_freecode(rl->r_jcode); 753 1.20 rmind } 754 1.36 rmind if (rl->r_info) { 755 1.47 rmind kmem_free(rl->r_info, rl->r_info_len); 756 1.18 rmind } 757 1.4 rmind kmem_free(rl, sizeof(npf_rule_t)); 758 1.1 rmind } 759 1.1 rmind 760 1.1 rmind /* 761 1.19 rmind * npf_rule_getid: return the unique ID of a rule. 762 1.10 rmind * npf_rule_getrproc: acquire a reference and return rule procedure, if any. 763 1.1 rmind * npf_rule_getnat: get NAT policy assigned to the rule. 764 1.1 rmind */ 765 1.1 rmind 766 1.19 rmind uint64_t 767 1.19 rmind npf_rule_getid(const npf_rule_t *rl) 768 1.19 rmind { 769 1.19 rmind KASSERT(NPF_DYNAMIC_RULE_P(rl->r_attr)); 770 1.19 rmind return rl->r_id; 771 1.19 rmind } 772 1.19 rmind 773 1.10 rmind npf_rproc_t * 774 1.30 rmind npf_rule_getrproc(const npf_rule_t *rl) 775 1.10 rmind { 776 1.10 rmind npf_rproc_t *rp = rl->r_rproc; 777 1.10 rmind 778 1.10 rmind if (rp) { 779 1.10 rmind npf_rproc_acquire(rp); 780 1.10 rmind } 781 1.10 rmind return rp; 782 1.10 rmind } 783 1.10 rmind 784 1.1 rmind npf_natpolicy_t * 785 1.1 rmind npf_rule_getnat(const npf_rule_t *rl) 786 1.1 rmind { 787 1.4 rmind return rl->r_natp; 788 1.1 rmind } 789 1.1 rmind 790 1.4 rmind /* 791 1.4 rmind * npf_rule_setnat: assign NAT policy to the rule and insert into the 792 1.4 rmind * NAT policy list in the ruleset. 793 1.4 rmind */ 794 1.1 rmind void 795 1.1 rmind npf_rule_setnat(npf_rule_t *rl, npf_natpolicy_t *np) 796 1.1 rmind { 797 1.4 rmind KASSERT(rl->r_natp == NULL); 798 1.4 rmind rl->r_natp = np; 799 1.1 rmind } 800 1.1 rmind 801 1.17 rmind /* 802 1.17 rmind * npf_rule_inspect: match the interface, direction and run the filter code. 803 1.29 rmind * Returns true if rule matches and false otherwise. 804 1.17 rmind */ 805 1.17 rmind static inline bool 806 1.29 rmind npf_rule_inspect(const npf_rule_t *rl, bpf_args_t *bc_args, 807 1.51 rmind const int di_mask, const unsigned ifid) 808 1.17 rmind { 809 1.17 rmind /* Match the interface. */ 810 1.29 rmind if (rl->r_ifid && rl->r_ifid != ifid) { 811 1.17 rmind return false; 812 1.17 rmind } 813 1.17 rmind 814 1.17 rmind /* Match the direction. */ 815 1.17 rmind if ((rl->r_attr & NPF_RULE_DIMASK) != NPF_RULE_DIMASK) { 816 1.17 rmind if ((rl->r_attr & di_mask) == 0) 817 1.17 rmind return false; 818 1.17 rmind } 819 1.17 rmind 820 1.24 rmind /* Any code? */ 821 1.36 rmind if (!rl->r_code) { 822 1.24 rmind KASSERT(rl->r_jcode == NULL); 823 1.17 rmind return true; 824 1.17 rmind } 825 1.25 rmind KASSERT(rl->r_type == NPF_CODE_BPF); 826 1.29 rmind return npf_bpf_filter(bc_args, rl->r_code, rl->r_jcode) != 0; 827 1.17 rmind } 828 1.17 rmind 829 1.17 rmind /* 830 1.17 rmind * npf_rule_reinspect: re-inspect the dynamic rule by iterating its list. 831 1.17 rmind * This is only for the dynamic rules. Subrules cannot have nested rules. 832 1.17 rmind */ 833 1.42 rmind static inline npf_rule_t * 834 1.42 rmind npf_rule_reinspect(const npf_rule_t *rg, bpf_args_t *bc_args, 835 1.51 rmind const int di_mask, const unsigned ifid) 836 1.7 rmind { 837 1.17 rmind npf_rule_t *final_rl = NULL, *rl; 838 1.17 rmind 839 1.42 rmind KASSERT(NPF_DYNAMIC_GROUP_P(rg->r_attr)); 840 1.7 rmind 841 1.51 rmind rl = atomic_load_relaxed(&rg->r_subset); 842 1.51 rmind for (; rl; rl = atomic_load_relaxed(&rl->r_next)) { 843 1.42 rmind KASSERT(!final_rl || rl->r_priority >= final_rl->r_priority); 844 1.29 rmind if (!npf_rule_inspect(rl, bc_args, di_mask, ifid)) { 845 1.7 rmind continue; 846 1.17 rmind } 847 1.17 rmind if (rl->r_attr & NPF_RULE_FINAL) { 848 1.17 rmind return rl; 849 1.17 rmind } 850 1.17 rmind final_rl = rl; 851 1.7 rmind } 852 1.17 rmind return final_rl; 853 1.7 rmind } 854 1.1 rmind 855 1.1 rmind /* 856 1.7 rmind * npf_ruleset_inspect: inspect the packet against the given ruleset. 857 1.1 rmind * 858 1.25 rmind * Loop through the rules in the set and run the byte-code of each rule 859 1.7 rmind * against the packet (nbuf chain). If sub-ruleset is found, inspect it. 860 1.1 rmind */ 861 1.1 rmind npf_rule_t * 862 1.34 rmind npf_ruleset_inspect(npf_cache_t *npc, const npf_ruleset_t *rlset, 863 1.34 rmind const int di, const int layer) 864 1.1 rmind { 865 1.34 rmind nbuf_t *nbuf = npc->npc_nbuf; 866 1.7 rmind const int di_mask = (di & PFIL_IN) ? NPF_RULE_IN : NPF_RULE_OUT; 867 1.51 rmind const unsigned nitems = rlset->rs_nitems; 868 1.51 rmind const unsigned ifid = nbuf->nb_ifid; 869 1.17 rmind npf_rule_t *final_rl = NULL; 870 1.29 rmind bpf_args_t bc_args; 871 1.51 rmind unsigned n = 0; 872 1.1 rmind 873 1.33 rmind KASSERT(((di & PFIL_IN) != 0) ^ ((di & PFIL_OUT) != 0)); 874 1.29 rmind 875 1.33 rmind /* 876 1.33 rmind * Prepare the external memory store and the arguments for 877 1.43 christos * the BPF programs to be executed. Reset mbuf before taking 878 1.43 christos * any pointers for the BPF. 879 1.33 rmind */ 880 1.33 rmind uint32_t bc_words[NPF_BPF_NWORDS]; 881 1.43 christos 882 1.43 christos nbuf_reset(nbuf); 883 1.34 rmind npf_bpf_prepare(npc, &bc_args, bc_words); 884 1.17 rmind 885 1.17 rmind while (n < nitems) { 886 1.17 rmind npf_rule_t *rl = rlset->rs_rules[n]; 887 1.51 rmind const unsigned skip_to = rl->r_skip_to & SKIPTO_MASK; 888 1.17 rmind const uint32_t attr = rl->r_attr; 889 1.17 rmind 890 1.16 rmind KASSERT(!nbuf_flag_p(nbuf, NBUF_DATAREF_RESET)); 891 1.17 rmind KASSERT(n < skip_to); 892 1.1 rmind 893 1.17 rmind /* Group is a barrier: return a matching if found any. */ 894 1.51.20.1 martin if ((attr & NPF_DYNAMIC_GROUP) == NPF_RULE_GROUP && final_rl) { 895 1.17 rmind break; 896 1.17 rmind } 897 1.17 rmind 898 1.17 rmind /* Main inspection of the rule. */ 899 1.29 rmind if (!npf_rule_inspect(rl, &bc_args, di_mask, ifid)) { 900 1.17 rmind n = skip_to; 901 1.1 rmind continue; 902 1.1 rmind } 903 1.17 rmind 904 1.17 rmind if (NPF_DYNAMIC_GROUP_P(attr)) { 905 1.17 rmind /* 906 1.17 rmind * If this is a dynamic rule, re-inspect the subrules. 907 1.17 rmind * If it has any matching rule, then it is final. 908 1.17 rmind */ 909 1.29 rmind rl = npf_rule_reinspect(rl, &bc_args, di_mask, ifid); 910 1.17 rmind if (rl != NULL) { 911 1.17 rmind final_rl = rl; 912 1.17 rmind break; 913 1.17 rmind } 914 1.17 rmind } else if ((attr & NPF_RULE_GROUP) == 0) { 915 1.17 rmind /* 916 1.17 rmind * Groups themselves are not matching. 917 1.17 rmind */ 918 1.17 rmind final_rl = rl; 919 1.1 rmind } 920 1.17 rmind 921 1.1 rmind /* Set the matching rule and check for "final". */ 922 1.17 rmind if (attr & NPF_RULE_FINAL) { 923 1.2 rmind break; 924 1.1 rmind } 925 1.17 rmind n++; 926 1.2 rmind } 927 1.16 rmind 928 1.16 rmind KASSERT(!nbuf_flag_p(nbuf, NBUF_DATAREF_RESET)); 929 1.7 rmind return final_rl; 930 1.1 rmind } 931 1.1 rmind 932 1.1 rmind /* 933 1.17 rmind * npf_rule_conclude: return decision and the flags for conclusion. 934 1.1 rmind * 935 1.1 rmind * => Returns ENETUNREACH if "block" and 0 if "pass". 936 1.1 rmind */ 937 1.1 rmind int 938 1.45 christos npf_rule_conclude(const npf_rule_t *rl, npf_match_info_t *mi) 939 1.1 rmind { 940 1.1 rmind /* If not passing - drop the packet. */ 941 1.45 christos mi->mi_retfl = rl->r_attr; 942 1.45 christos mi->mi_rid = rl->r_id; 943 1.17 rmind return (rl->r_attr & NPF_RULE_PASS) ? 0 : ENETUNREACH; 944 1.1 rmind } 945 1.41 rmind 946 1.41 rmind 947 1.41 rmind #if defined(DDB) || defined(_NPF_TESTING) 948 1.41 rmind 949 1.41 rmind void 950 1.43 christos npf_ruleset_dump(npf_t *npf, const char *name) 951 1.41 rmind { 952 1.43 christos npf_ruleset_t *rlset = npf_config_ruleset(npf); 953 1.41 rmind npf_rule_t *rg, *rl; 954 1.41 rmind 955 1.41 rmind LIST_FOREACH(rg, &rlset->rs_dynamic, r_dentry) { 956 1.41 rmind printf("ruleset '%s':\n", rg->r_name); 957 1.42 rmind for (rl = rg->r_subset; rl; rl = rl->r_next) { 958 1.41 rmind printf("\tid %"PRIu64", key: ", rl->r_id); 959 1.51 rmind for (unsigned i = 0; i < NPF_RULE_MAXKEYLEN; i++) 960 1.41 rmind printf("%x", rl->r_key[i]); 961 1.41 rmind printf("\n"); 962 1.41 rmind } 963 1.41 rmind } 964 1.41 rmind } 965 1.41 rmind 966 1.41 rmind #endif 967
Indexes created Thu Oct 23 22:10:10 GMT 2025