1 /* $NetBSD: mdb6.c,v 1.9 2025/12/24 18:48:34 thorpej Exp $ */ 2 3 /* 4 * Copyright (C) 2007-2017 by Internet Systems Consortium, Inc. ("ISC") 5 * 6 * This Source Code Form is subject to the terms of the Mozilla Public 7 * License, v. 2.0. If a copy of the MPL was not distributed with this 8 * file, You can obtain one at http://mozilla.org/MPL/2.0/. 9 * 10 * THE SOFTWARE IS PROVIDED "AS IS" AND ISC DISCLAIMS ALL WARRANTIES WITH 11 * REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY 12 * AND FITNESS. IN NO EVENT SHALL ISC BE LIABLE FOR ANY SPECIAL, DIRECT, 13 * INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM 14 * LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE 15 * OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR 16 * PERFORMANCE OF THIS SOFTWARE. 17 */ 18 19 #include <sys/cdefs.h> 20 __RCSID("$NetBSD: mdb6.c,v 1.9 2025/12/24 18:48:34 thorpej Exp $"); 21 22 23 /*! 24 * \todo assert() 25 * \todo simplify functions, as pool is now in iaaddr 26 */ 27 28 /*! \file server/mdb6.c 29 * 30 * \page ipv6structures IPv6 Structures Overview 31 * 32 * A brief description of the IPv6 structures as reverse engineered. 33 * 34 * There are four major data structures in the lease configuraion. 35 * 36 * - shared_network - The shared network is the outer enclosing scope for a 37 * network region that shares a broadcast domain. It is 38 * composed of one or more subnets all of which are valid 39 * in the given region. The share network may be 40 * explicitly defined or implicitly created if there is 41 * only a subnet statement. This structrure is shared 42 * with v4. Each shared network statment or naked subnet 43 * will map to one of these structures 44 * 45 * - subnet - The subnet structure mostly specifies the address range 46 * that could be valid in a given region. This structute 47 * doesn't include the addresses that the server can delegate 48 * those are in the ipv6_pool. This structure is also shared 49 * with v4. Each subnet statement will map to one of these 50 * structures. 51 * 52 * - ipv6_pond - The pond structure is a grouping of the address and prefix 53 * information via the pointers to the ipv6_pool and the 54 * allowability of this pool for given clinets via the permit 55 * lists and the valid TIMEs. This is equivilent to the v4 56 * pool structure and would have been named ip6_pool except 57 * that the name was already in use. Generally each pool6 58 * statement will map to one of these structures. In addition 59 * there may be one or for each group of naked range6 and 60 * prefix6 statements within a shared network that share 61 * the same group of statements. 62 * 63 * - ipv6_pool - this contains information about a pool of addresses or prefixes 64 * that the server is using. This includes a hash table that 65 * tracks the active items and a pair of heap tables one for 66 * active items and one for non-active items. The heap tables 67 * are used to determine the next items to be modified due to 68 * timing events (expire mostly). 69 * 70 * The linkages then look like this: 71 * \verbatim 72 *+--------------+ +-------------+ 73 *|Shared Network| | ipv6_pond | 74 *| group | | group | 75 *| | | permit info | 76 *| | | next ----> 77 *| ponds ---->| | 78 *| |<---- shared | 79 *| Subnets | | pools | 80 *+-----|--------+ +------|------+ 81 * | ^ | ^ 82 * | | v | 83 * | | +-----------|-+ 84 * | | | ipv6_pool | | 85 * | | | type | | 86 * | | | ipv6_pond | 87 * | | | | 88 * | | | next ----> 89 * | | | | 90 * | | | subnet | 91 * | | +-----|-------+ 92 * | | | 93 * | | v 94 * | | +-------------+ 95 * | | | subnet | 96 * | +---------- shared | 97 * +----------->| | 98 * | group | 99 * +-------------+ 100 * 101 * The shared network contains a list of all the subnets that are on a broadcast 102 * doamin. These can be used to determine if an address makes sense in a given 103 * domain, but the subnets do not contain the addresses the server can delegate. 104 * Those are stored in the ponds and pools. 105 * 106 * In the simple case to find an acceptable address the server would first find 107 * the shared network the client is on based on either the interface used to 108 * receive the request or the relay agent's information. From the shared 109 * network the server will walk through it's list of ponds. For each pond it 110 * will evaluate the permit information against the (already done) classification. 111 * If it finds an acceptable pond it will then walk through the pools for that 112 * pond. The server first checks the type of the pool (NA, TA and PD) agaisnt the 113 * request and if they match it attemps to find an address within that pool. On 114 * success the address is used, on failure the server steps to the next pool and 115 * if necessary to the next pond. 116 * 117 * When the server is successful in finding an address it will execute any 118 * statements assocaited with the pond, then the subnet, then the shared 119 * network the group field is for in the above picture). 120 * 121 * In configurations that don't include either a shared network or a pool6 122 * statement (or both) the missing pieces are created. 123 * 124 * 125 * There are three major data structuress involved in the lease database: 126 * 127 * - ipv6_pool - see above 128 * - ia_xx - this contains information about a single IA from a request 129 * normally it will contain one pointer to a lease for the client 130 * but it may contain more in some circumstances. There are 3 131 * hash tables to aid in accessing these one each for NA, TA and PD. 132 * - iasubopt - the v6 lease structure. These are created dynamically when 133 * a client asks for something and will eventually be destroyed 134 * if the client doesn't re-ask for that item. A lease has space 135 * for backpointers to the IA and to the pool to which it belongs. 136 * The pool backpointer is always filled, the IA pointer may not be. 137 * 138 * In normal use we then have something like this: 139 * 140 * \verbatim 141 * ia hash tables 142 * ia_na_active +----------------+ 143 * ia_ta_active +------------+ | pool | 144 * ia_pd_active | iasubopt |<--| active hash | 145 * +-----------------+ | aka lease |<--| active heap | 146 * | ia_xx | | pool ptr |-->| | 147 * | iasubopt array |<---| iaptr |<--| inactive heap | 148 * | lease ptr |--->| | | | 149 * +-----------------+ +------------+ +----------------+ 150 * \endverbatim 151 * 152 * For the pool either the inactive heap will have a pointer 153 * or both the active heap and the active hash will have pointers. 154 * 155 * I think there are several major items to notice. The first is 156 * that as a lease moves around it will be added to and removed 157 * from the address hash table in the pool and between the active 158 * and inactive hash tables. The hash table and the active heap 159 * are used when the lease is either active or abandoned. The 160 * inactive heap is used for all other states. In particular a 161 * lease that has expired or been released will be cleaned 162 * (DDNS removal etc) and then moved to the inactive heap. After 163 * some time period (currently 1 hour) it will be freed. 164 * 165 * The second is that when a client requests specific addresses, 166 * either because it previously owned them or if the server supplied 167 * them as part of a solicit, the server will try to lookup the ia_xx 168 * associated with the client and find the addresses there. If it 169 * does find appropriate leases it moves them from the old IA to 170 * a new IA and eventually replaces the old IA with the new IA 171 * in the IA hash tables. 172 * 173 */ 174 #include "config.h" 175 176 #include <sys/types.h> 177 #include <time.h> 178 #include <netinet/in.h> 179 180 #include <stdarg.h> 181 #include "dhcpd.h" 182 #include "omapip/omapip.h" 183 #include "omapip/hash.h" 184 #include <isc/md.h> 185 186 HASH_FUNCTIONS(ia, unsigned char *, struct ia_xx, ia_hash_t, 187 ia_reference, ia_dereference, do_string_hash) 188 189 ia_hash_t *ia_na_active; 190 ia_hash_t *ia_ta_active; 191 ia_hash_t *ia_pd_active; 192 193 HASH_FUNCTIONS(iasubopt, struct in6_addr *, struct iasubopt, iasubopt_hash_t, 194 iasubopt_reference, iasubopt_dereference, do_string_hash) 195 196 struct ipv6_pool **pools; 197 int num_pools; 198 199 /* 200 * Create a new IAADDR/PREFIX structure. 201 * 202 * - iasubopt must be a pointer to a (struct iasubopt *) pointer previously 203 * initialized to NULL 204 */ 205 isc_result_t 206 iasubopt_allocate(struct iasubopt **iasubopt, const char *file, int line) { 207 struct iasubopt *tmp; 208 209 if (iasubopt == NULL) { 210 log_error("%s(%d): NULL pointer reference", file, line); 211 return DHCP_R_INVALIDARG; 212 } 213 if (*iasubopt != NULL) { 214 log_error("%s(%d): non-NULL pointer", file, line); 215 return DHCP_R_INVALIDARG; 216 } 217 218 tmp = dmalloc(sizeof(*tmp), file, line); 219 if (tmp == NULL) { 220 return ISC_R_NOMEMORY; 221 } 222 223 tmp->refcnt = 1; 224 tmp->state = FTS_FREE; 225 tmp->active_index = 0; 226 tmp->inactive_index = 0; 227 tmp->plen = 255; 228 229 *iasubopt = tmp; 230 return ISC_R_SUCCESS; 231 } 232 233 /* 234 * Reference an IAADDR/PREFIX structure. 235 * 236 * - iasubopt must be a pointer to a (struct iasubopt *) pointer previously 237 * initialized to NULL 238 */ 239 isc_result_t 240 iasubopt_reference(struct iasubopt **iasubopt, struct iasubopt *src, 241 const char *file, int line) { 242 if (iasubopt == NULL) { 243 log_error("%s(%d): NULL pointer reference", file, line); 244 return DHCP_R_INVALIDARG; 245 } 246 if (*iasubopt != NULL) { 247 log_error("%s(%d): non-NULL pointer", file, line); 248 return DHCP_R_INVALIDARG; 249 } 250 if (src == NULL) { 251 log_error("%s(%d): NULL pointer reference", file, line); 252 return DHCP_R_INVALIDARG; 253 } 254 *iasubopt = src; 255 src->refcnt++; 256 return ISC_R_SUCCESS; 257 } 258 259 260 /* 261 * Dereference an IAADDR/PREFIX structure. 262 * 263 * If it is the last reference, then the memory for the 264 * structure is freed. 265 */ 266 isc_result_t 267 iasubopt_dereference(struct iasubopt **iasubopt, const char *file, int line) { 268 struct iasubopt *tmp; 269 270 if ((iasubopt == NULL) || (*iasubopt == NULL)) { 271 log_error("%s(%d): NULL pointer", file, line); 272 return DHCP_R_INVALIDARG; 273 } 274 275 tmp = *iasubopt; 276 *iasubopt = NULL; 277 278 tmp->refcnt--; 279 if (tmp->refcnt < 0) { 280 log_error("%s(%d): negative refcnt", file, line); 281 tmp->refcnt = 0; 282 } 283 if (tmp->refcnt == 0) { 284 if (tmp->ia != NULL) { 285 ia_dereference(&(tmp->ia), file, line); 286 } 287 if (tmp->ipv6_pool != NULL) { 288 ipv6_pool_dereference(&(tmp->ipv6_pool), file, line); 289 } 290 if (tmp->scope != NULL) { 291 binding_scope_dereference(&tmp->scope, file, line); 292 } 293 294 if (tmp->on_star.on_expiry != NULL) { 295 executable_statement_dereference 296 (&tmp->on_star.on_expiry, MDL); 297 } 298 if (tmp->on_star.on_commit != NULL) { 299 executable_statement_dereference 300 (&tmp->on_star.on_commit, MDL); 301 } 302 if (tmp->on_star.on_release != NULL) { 303 executable_statement_dereference 304 (&tmp->on_star.on_release, MDL); 305 } 306 307 dfree(tmp, file, line); 308 } 309 310 return ISC_R_SUCCESS; 311 } 312 313 /* 314 * Make the key that we use for IA. 315 */ 316 isc_result_t 317 ia_make_key(struct data_string *key, u_int32_t iaid, 318 const char *duid, unsigned int duid_len, 319 const char *file, int line) { 320 321 memset(key, 0, sizeof(*key)); 322 key->len = duid_len + sizeof(iaid); 323 if (!buffer_allocate(&(key->buffer), key->len, file, line)) { 324 return ISC_R_NOMEMORY; 325 } 326 key->data = key->buffer->data; 327 memcpy((char *)key->data, &iaid, sizeof(iaid)); 328 memcpy((char *)key->data + sizeof(iaid), duid, duid_len); 329 330 return ISC_R_SUCCESS; 331 } 332 333 /* 334 * Create a new IA structure. 335 * 336 * - ia must be a pointer to a (struct ia_xx *) pointer previously 337 * initialized to NULL 338 * - iaid and duid are values from the client 339 * 340 * XXXsk: we don't concern ourself with the byte order of the IAID, 341 * which might be a problem if we transfer this structure 342 * between machines of different byte order 343 */ 344 isc_result_t 345 ia_allocate(struct ia_xx **ia, u_int32_t iaid, 346 const char *duid, unsigned int duid_len, 347 const char *file, int line) { 348 struct ia_xx *tmp; 349 350 if (ia == NULL) { 351 log_error("%s(%d): NULL pointer reference", file, line); 352 return DHCP_R_INVALIDARG; 353 } 354 if (*ia != NULL) { 355 log_error("%s(%d): non-NULL pointer", file, line); 356 return DHCP_R_INVALIDARG; 357 } 358 359 tmp = dmalloc(sizeof(*tmp), file, line); 360 if (tmp == NULL) { 361 return ISC_R_NOMEMORY; 362 } 363 364 if (ia_make_key(&tmp->iaid_duid, iaid, 365 duid, duid_len, file, line) != ISC_R_SUCCESS) { 366 dfree(tmp, file, line); 367 return ISC_R_NOMEMORY; 368 } 369 370 tmp->refcnt = 1; 371 372 *ia = tmp; 373 return ISC_R_SUCCESS; 374 } 375 376 /* 377 * Reference an IA structure. 378 * 379 * - ia must be a pointer to a (struct ia_xx *) pointer previously 380 * initialized to NULL 381 */ 382 isc_result_t 383 ia_reference(struct ia_xx **ia, struct ia_xx *src, 384 const char *file, int line) { 385 if (ia == NULL) { 386 log_error("%s(%d): NULL pointer reference", file, line); 387 return DHCP_R_INVALIDARG; 388 } 389 if (*ia != NULL) { 390 log_error("%s(%d): non-NULL pointer", file, line); 391 return DHCP_R_INVALIDARG; 392 } 393 if (src == NULL) { 394 log_error("%s(%d): NULL pointer reference", file, line); 395 return DHCP_R_INVALIDARG; 396 } 397 *ia = src; 398 src->refcnt++; 399 return ISC_R_SUCCESS; 400 } 401 402 /* 403 * Dereference an IA structure. 404 * 405 * If it is the last reference, then the memory for the 406 * structure is freed. 407 */ 408 isc_result_t 409 ia_dereference(struct ia_xx **ia, const char *file, int line) { 410 struct ia_xx *tmp; 411 int i; 412 413 if ((ia == NULL) || (*ia == NULL)) { 414 log_error("%s(%d): NULL pointer", file, line); 415 return DHCP_R_INVALIDARG; 416 } 417 418 tmp = *ia; 419 *ia = NULL; 420 421 tmp->refcnt--; 422 if (tmp->refcnt < 0) { 423 log_error("%s(%d): negative refcnt", file, line); 424 tmp->refcnt = 0; 425 } 426 if (tmp->refcnt == 0) { 427 if (tmp->iasubopt != NULL) { 428 for (i=0; i<tmp->num_iasubopt; i++) { 429 iasubopt_dereference(&(tmp->iasubopt[i]), 430 file, line); 431 } 432 dfree(tmp->iasubopt, file, line); 433 } 434 data_string_forget(&(tmp->iaid_duid), file, line); 435 dfree(tmp, file, line); 436 } 437 return ISC_R_SUCCESS; 438 } 439 440 441 /* 442 * Add an IAADDR/PREFIX entry to an IA structure. 443 */ 444 isc_result_t 445 ia_add_iasubopt(struct ia_xx *ia, struct iasubopt *iasubopt, 446 const char *file, int line) { 447 int max; 448 struct iasubopt **new; 449 450 /* 451 * Grow our array if we need to. 452 * 453 * Note: we pick 4 as the increment, as that seems a reasonable 454 * guess as to how many addresses/prefixes we might expect 455 * on an interface. 456 */ 457 if (ia->max_iasubopt <= ia->num_iasubopt) { 458 max = ia->max_iasubopt + 4; 459 new = dmalloc(max * sizeof(struct iasubopt *), file, line); 460 if (new == NULL) { 461 return ISC_R_NOMEMORY; 462 } 463 memcpy(new, ia->iasubopt, 464 ia->num_iasubopt * sizeof(struct iasubopt *)); 465 ia->iasubopt = new; 466 ia->max_iasubopt = max; 467 } 468 469 iasubopt_reference(&(ia->iasubopt[ia->num_iasubopt]), iasubopt, 470 file, line); 471 ia->num_iasubopt++; 472 473 return ISC_R_SUCCESS; 474 } 475 476 /* 477 * Remove an IAADDR/PREFIX entry to an IA structure. 478 * 479 * Note: if a suboption appears more than once, then only ONE will be removed. 480 */ 481 void 482 ia_remove_iasubopt(struct ia_xx *ia, struct iasubopt *iasubopt, 483 const char *file, int line) { 484 int i, j; 485 if (ia == NULL || iasubopt == NULL) 486 return; 487 488 for (i=0; i<ia->num_iasubopt; i++) { 489 if (ia->iasubopt[i] == iasubopt) { 490 /* move remaining suboption pointers down one */ 491 for (j=i+1; j < ia->num_iasubopt; j++) { 492 ia->iasubopt[j-1] = ia->iasubopt[j]; 493 } 494 /* decrease our total count */ 495 /* remove the back-reference in the suboption itself */ 496 ia_dereference(&iasubopt->ia, file, line); 497 /* remove this sub option */ 498 iasubopt_dereference(&iasubopt, file, line); 499 ia->num_iasubopt--; 500 return; 501 } 502 } 503 log_error("%s(%d): IAADDR/PREFIX not in IA", file, line); 504 } 505 506 /* 507 * Remove all addresses/prefixes from an IA. 508 */ 509 void 510 ia_remove_all_lease(struct ia_xx *ia, const char *file, int line) { 511 int i; 512 513 for (i=0; i<ia->num_iasubopt; i++) { 514 ia_dereference(&(ia->iasubopt[i]->ia), file, line); 515 iasubopt_dereference(&(ia->iasubopt[i]), file, line); 516 } 517 ia->num_iasubopt = 0; 518 } 519 520 /* 521 * Compare two IA. 522 */ 523 isc_boolean_t 524 ia_equal(const struct ia_xx *a, const struct ia_xx *b) 525 { 526 isc_boolean_t found; 527 int i, j; 528 529 /* 530 * Handle cases where one or both of the inputs is NULL. 531 */ 532 if (a == NULL) { 533 if (b == NULL) { 534 return ISC_TRUE; 535 } else { 536 return ISC_FALSE; 537 } 538 } 539 540 /* 541 * Check the type is the same. 542 */ 543 if (a->ia_type != b->ia_type) { 544 return ISC_FALSE; 545 } 546 547 /* 548 * Check the DUID is the same. 549 */ 550 if (a->iaid_duid.len != b->iaid_duid.len) { 551 return ISC_FALSE; 552 } 553 if (memcmp(a->iaid_duid.data, 554 b->iaid_duid.data, a->iaid_duid.len) != 0) { 555 return ISC_FALSE; 556 } 557 558 /* 559 * Make sure we have the same number of addresses/prefixes in each. 560 */ 561 if (a->num_iasubopt != b->num_iasubopt) { 562 return ISC_FALSE; 563 } 564 565 /* 566 * Check that each address/prefix is present in both. 567 */ 568 for (i=0; i<a->num_iasubopt; i++) { 569 found = ISC_FALSE; 570 for (j=0; j<a->num_iasubopt; j++) { 571 if (a->iasubopt[i]->plen != b->iasubopt[i]->plen) 572 continue; 573 if (memcmp(&(a->iasubopt[i]->addr), 574 &(b->iasubopt[j]->addr), 575 sizeof(struct in6_addr)) == 0) { 576 found = ISC_TRUE; 577 break; 578 } 579 } 580 if (!found) { 581 return ISC_FALSE; 582 } 583 } 584 585 /* 586 * These are the same in every way we care about. 587 */ 588 return ISC_TRUE; 589 } 590 591 /* 592 * Helper function for lease heaps. 593 * Makes the top of the heap the oldest lease. 594 */ 595 static isc_boolean_t 596 lease_older(void *a, void *b) { 597 struct iasubopt *la = (struct iasubopt *)a; 598 struct iasubopt *lb = (struct iasubopt *)b; 599 600 if (la->hard_lifetime_end_time == lb->hard_lifetime_end_time) { 601 return difftime(la->soft_lifetime_end_time, 602 lb->soft_lifetime_end_time) < 0; 603 } else { 604 return difftime(la->hard_lifetime_end_time, 605 lb->hard_lifetime_end_time) < 0; 606 } 607 } 608 609 /* 610 * Helper functions for lease address/prefix heaps. 611 * Callback when an address's position in the heap changes. 612 */ 613 static void 614 active_changed(void *iasubopt, unsigned int new_heap_index) { 615 ((struct iasubopt *)iasubopt)->active_index = new_heap_index; 616 } 617 618 static void 619 inactive_changed(void *iasubopt, unsigned int new_heap_index) { 620 ((struct iasubopt *)iasubopt)->inactive_index = new_heap_index; 621 } 622 623 /*! 624 * 625 * \brief Create a new IPv6 lease pool structure 626 * 627 * Allocate space for a new ipv6_pool structure and return a reference 628 * to it, includes setting the reference count to 1. 629 * 630 * \param pool = space for returning a referenced pointer to the pool. 631 * This must point to a space that has been initialzied 632 * to NULL by the caller. 633 * \param[in] type = The type of the pool NA, TA or PD 634 * \param[in] start_addr = The first address in the range for the pool 635 * \param[in] bits = The contiguous bits of the pool 636 637 * 638 * \return 639 * ISC_R_SUCCESS = The pool was successfully created, pool points to it. 640 * DHCP_R_INVALIDARG = One of the arugments was invalid, pool has not been 641 * modified 642 * ISC_R_NOMEMORY = The system wasn't able to allocate memory, pool has 643 * not been modified. 644 */ 645 isc_result_t 646 ipv6_pool_allocate(struct ipv6_pool **pool, u_int16_t type, 647 const struct in6_addr *start_addr, int bits, 648 int units, const char *file, int line) { 649 struct ipv6_pool *tmp; 650 651 if (pool == NULL) { 652 log_error("%s(%d): NULL pointer reference", file, line); 653 return DHCP_R_INVALIDARG; 654 } 655 if (*pool != NULL) { 656 log_error("%s(%d): non-NULL pointer", file, line); 657 return DHCP_R_INVALIDARG; 658 } 659 660 tmp = dmalloc(sizeof(*tmp), file, line); 661 if (tmp == NULL) { 662 return ISC_R_NOMEMORY; 663 } 664 665 tmp->refcnt = 1; 666 tmp->pool_type = type; 667 tmp->start_addr = *start_addr; 668 tmp->bits = bits; 669 tmp->units = units; 670 if (!iasubopt_new_hash(&tmp->leases, DEFAULT_HASH_SIZE, file, line)) { 671 dfree(tmp, file, line); 672 return ISC_R_NOMEMORY; 673 } 674 isc_heap_create(dhcp_gbl_ctx.mctx, lease_older, active_changed, 675 0, &(tmp->active_timeouts)); 676 isc_heap_create(dhcp_gbl_ctx.mctx, lease_older, inactive_changed, 677 0, &(tmp->inactive_timeouts)); 678 679 *pool = tmp; 680 return ISC_R_SUCCESS; 681 } 682 683 /*! 684 * 685 * \brief reference an IPv6 pool structure. 686 * 687 * This function genreates a reference to an ipv6_pool structure 688 * and increments the reference count on the structure. 689 * 690 * \param[out] pool = space for returning a referenced pointer to the pool. 691 * This must point to a space that has been initialzied 692 * to NULL by the caller. 693 * \param[in] src = A pointer to the pool to reference. This must not be 694 * NULL. 695 * 696 * \return 697 * ISC_R_SUCCESS = The pool was successfully referenced, pool now points 698 * to src. 699 * DHCP_R_INVALIDARG = One of the arugments was invalid, pool has not been 700 * modified. 701 */ 702 isc_result_t 703 ipv6_pool_reference(struct ipv6_pool **pool, struct ipv6_pool *src, 704 const char *file, int line) { 705 if (pool == NULL) { 706 log_error("%s(%d): NULL pointer reference", file, line); 707 return DHCP_R_INVALIDARG; 708 } 709 if (*pool != NULL) { 710 log_error("%s(%d): non-NULL pointer", file, line); 711 return DHCP_R_INVALIDARG; 712 } 713 if (src == NULL) { 714 log_error("%s(%d): NULL pointer reference", file, line); 715 return DHCP_R_INVALIDARG; 716 } 717 *pool = src; 718 src->refcnt++; 719 return ISC_R_SUCCESS; 720 } 721 722 /* 723 * Note: Each IAADDR/PREFIX in a pool is referenced by the pool. This is needed 724 * to prevent the lease from being garbage collected out from under the 725 * pool. 726 * 727 * The references are made from the hash and from the heap. The following 728 * helper functions dereference these when a pool is destroyed. 729 */ 730 731 /* 732 * Helper function for pool cleanup. 733 * Dereference each of the hash entries in a pool. 734 */ 735 static isc_result_t 736 dereference_hash_entry(const void *name, unsigned len, void *value) { 737 struct iasubopt *iasubopt = (struct iasubopt *)value; 738 739 iasubopt_dereference(&iasubopt, MDL); 740 return ISC_R_SUCCESS; 741 } 742 743 /* 744 * Helper function for pool cleanup. 745 * Dereference each of the heap entries in a pool. 746 */ 747 static void 748 dereference_heap_entry(void *value, void *dummy) { 749 struct iasubopt *iasubopt = (struct iasubopt *)value; 750 751 iasubopt_dereference(&iasubopt, MDL); 752 } 753 754 /*! 755 * 756 * \brief de-reference an IPv6 pool structure. 757 * 758 * This function decrements the reference count in an ipv6_pool structure. 759 * If this was the last reference then the memory for the structure is 760 * freed. 761 * 762 * \param[in] pool = A pointer to the pointer to the pool that should be 763 * de-referenced. On success the pointer to the pool 764 * is cleared. It must not be NULL and must not point 765 * to NULL. 766 * 767 * \return 768 * ISC_R_SUCCESS = The pool was successfully de-referenced, pool now points 769 * to NULL 770 * DHCP_R_INVALIDARG = One of the arugments was invalid, pool has not been 771 * modified. 772 */ 773 isc_result_t 774 ipv6_pool_dereference(struct ipv6_pool **pool, const char *file, int line) { 775 struct ipv6_pool *tmp; 776 777 if ((pool == NULL) || (*pool == NULL)) { 778 log_error("%s(%d): NULL pointer", file, line); 779 return DHCP_R_INVALIDARG; 780 } 781 782 tmp = *pool; 783 *pool = NULL; 784 785 tmp->refcnt--; 786 if (tmp->refcnt < 0) { 787 log_error("%s(%d): negative refcnt", file, line); 788 tmp->refcnt = 0; 789 } 790 if (tmp->refcnt == 0) { 791 iasubopt_hash_foreach(tmp->leases, dereference_hash_entry); 792 iasubopt_free_hash_table(&(tmp->leases), file, line); 793 isc_heap_foreach(tmp->active_timeouts, 794 dereference_heap_entry, NULL); 795 isc_heap_destroy(&(tmp->active_timeouts)); 796 isc_heap_foreach(tmp->inactive_timeouts, 797 dereference_heap_entry, NULL); 798 isc_heap_destroy(&(tmp->inactive_timeouts)); 799 dfree(tmp, file, line); 800 } 801 802 return ISC_R_SUCCESS; 803 } 804 805 /* 806 * Create an address by hashing the input, and using that for 807 * the non-network part. 808 */ 809 static void 810 build_address6(struct in6_addr *addr, 811 const struct in6_addr *net_start_addr, int net_bits, 812 const struct data_string *input) { 813 int net_bytes; 814 int i; 815 unsigned int len; 816 char *str; 817 const char *net_str; 818 819 isc_md(ISC_MD_MD5, input->data, input->len, (void *)addr, &len); 820 821 /* 822 * Copy the [0..128] network bits over. 823 */ 824 str = (char *)addr; 825 net_str = (const char *)net_start_addr; 826 net_bytes = net_bits / 8; 827 for (i = 0; i < net_bytes; i++) { 828 str[i] = net_str[i]; 829 } 830 switch (net_bits % 8) { 831 case 1: str[i] = (str[i] & 0x7F) | (net_str[i] & 0x80); break; 832 case 2: str[i] = (str[i] & 0x3F) | (net_str[i] & 0xC0); break; 833 case 3: str[i] = (str[i] & 0x1F) | (net_str[i] & 0xE0); break; 834 case 4: str[i] = (str[i] & 0x0F) | (net_str[i] & 0xF0); break; 835 case 5: str[i] = (str[i] & 0x07) | (net_str[i] & 0xF8); break; 836 case 6: str[i] = (str[i] & 0x03) | (net_str[i] & 0xFC); break; 837 case 7: str[i] = (str[i] & 0x01) | (net_str[i] & 0xFE); break; 838 } 839 840 /* 841 * Set the universal/local bit ("u bit") to zero for /64s. The 842 * individual/group bit ("g bit") is unchanged, because the g-bit 843 * has no meaning when the u-bit is cleared. 844 */ 845 if (net_bits == 64) 846 str[8] &= ~0x02; 847 } 848 849 #ifdef EUI_64 850 int 851 valid_eui_64_duid(const struct data_string* uid, int offset) { 852 if (uid->len == (offset + EUI_64_ID_LEN)) { 853 const unsigned char* duid = uid->data + offset; 854 return (((duid[0] == 0x00 && duid[1] == 0x03) && 855 (duid[2] == 0x00 && duid[3] == 0x1b))); 856 } 857 858 return(0); 859 } 860 861 862 /* 863 * Create an EUI-64 address 864 */ 865 static isc_result_t 866 build_address6_eui_64(struct in6_addr *addr, 867 const struct in6_addr *net_start_addr, int net_bits, 868 const struct data_string *iaid_duid, int duid_beg) { 869 870 if (net_bits != 64) { 871 log_error("build_address_eui_64: network is not 64 bits"); 872 return (ISC_R_FAILURE); 873 } 874 875 if (valid_eui_64_duid(iaid_duid, duid_beg)) { 876 const unsigned char *duid = iaid_duid->data + duid_beg; 877 878 /* copy network prefix to the high 64 bits */ 879 memcpy(addr->s6_addr, net_start_addr->s6_addr, 8); 880 881 /* copy Link-layer address to low 64 bits */ 882 memcpy(addr->s6_addr + 8, duid + 4, 8); 883 884 /* RFC-3315 Any address assigned by a server that is based 885 * on an EUI-64 identifier MUST include an interface identifier 886 * with the "u" (universal/local) and "g" (individual/group) 887 * bits of the interface identifier set appropriately, as 888 * indicated in section 2.5.1 of RFC 2373 [5]. */ 889 addr->s6_addr[8] |= 0x02; 890 return (ISC_R_SUCCESS); 891 } 892 893 log_error("build_address_eui_64: iaid_duid not a valid EUI-64: %s", 894 print_hex_1(iaid_duid->len, iaid_duid->data, 60)); 895 return (ISC_R_FAILURE); 896 } 897 898 int 899 valid_for_eui_64_pool(struct ipv6_pool* pool, struct data_string* uid, 900 int duid_beg, struct in6_addr* ia_addr) { 901 struct in6_addr test_addr; 902 /* If it's not an EUI-64 pool bail */ 903 if (!pool->ipv6_pond->use_eui_64) { 904 return (0); 905 } 906 907 if (!valid_eui_64_duid(uid, duid_beg)) { 908 /* Dynamic lease in a now eui_64 pond, toss it*/ 909 return (0); 910 } 911 912 /* Call build_address6_eui_64() and compare it's result to 913 * this lease and see if they match. */ 914 memset (&test_addr, 0, sizeof(test_addr)); 915 build_address6_eui_64(&test_addr, &pool->start_addr, pool->bits, 916 uid, duid_beg); 917 918 return (!memcmp(ia_addr, &test_addr, sizeof(test_addr))); 919 } 920 #endif 921 922 923 /* 924 * Create a temporary address by a variant of RFC 4941 algo. 925 * Note: this should not be used for prefixes shorter than 64 bits. 926 */ 927 static void 928 build_temporary6(struct in6_addr *addr, 929 const struct in6_addr *net_start_addr, int net_bits, 930 const struct data_string *input) { 931 static u_int32_t history[2]; 932 static u_int32_t counter = 0; 933 unsigned char md[16] = {0}; 934 unsigned int len; 935 936 /* 937 * First time/time to reseed. 938 * Please use a good pseudo-random generator here! 939 */ 940 if (counter == 0) { 941 history[0] = arc4random(); 942 history[1] = arc4random(); 943 } 944 945 /* 946 * Use MD5 as recommended by RFC 4941. 947 */ 948 isc_md(ISC_MD_MD5, input->data, input->len, (void *)&history[0], &len); 949 950 /* 951 * Build the address. 952 */ 953 if (net_bits == 64) { 954 memcpy(&addr->s6_addr[0], &net_start_addr->s6_addr[0], 8); 955 memcpy(&addr->s6_addr[8], md, 8); 956 addr->s6_addr[8] &= ~0x02; 957 } else { 958 int net_bytes; 959 int i; 960 char *str; 961 const char *net_str; 962 963 /* 964 * Copy the [0..128] network bits over. 965 */ 966 str = (char *)addr; 967 net_str = (const char *)net_start_addr; 968 net_bytes = net_bits / 8; 969 for (i = 0; i < net_bytes; i++) { 970 str[i] = net_str[i]; 971 } 972 memcpy(str + net_bytes, md, 16 - net_bytes); 973 switch (net_bits % 8) { 974 case 1: str[i] = (str[i] & 0x7F) | (net_str[i] & 0x80); break; 975 case 2: str[i] = (str[i] & 0x3F) | (net_str[i] & 0xC0); break; 976 case 3: str[i] = (str[i] & 0x1F) | (net_str[i] & 0xE0); break; 977 case 4: str[i] = (str[i] & 0x0F) | (net_str[i] & 0xF0); break; 978 case 5: str[i] = (str[i] & 0x07) | (net_str[i] & 0xF8); break; 979 case 6: str[i] = (str[i] & 0x03) | (net_str[i] & 0xFC); break; 980 case 7: str[i] = (str[i] & 0x01) | (net_str[i] & 0xFE); break; 981 } 982 } 983 984 985 /* 986 * Save history for the next call. 987 */ 988 memcpy((unsigned char *)&history[0], md + 8, 8); 989 counter++; 990 } 991 992 /* Reserved Subnet Router Anycast ::0:0:0:0. */ 993 static struct in6_addr rtany; 994 /* Reserved Subnet Anycasts ::fdff:ffff:ffff:ff80-::fdff:ffff:ffff:ffff. */ 995 static struct in6_addr resany; 996 997 /* 998 * Create a lease for the given address and client duid. 999 * 1000 * - pool must be a pointer to a (struct ipv6_pool *) pointer previously 1001 * initialized to NULL 1002 * 1003 * Right now we simply hash the DUID, and if we get a collision, we hash 1004 * again until we find a free address. We try this a fixed number of times, 1005 * to avoid getting stuck in a loop (this is important on small pools 1006 * where we can run out of space). 1007 * 1008 * We return the number of attempts that it took to find an available 1009 * lease. This tells callers when a pool is are filling up, as 1010 * well as an indication of how full the pool is; statistically the 1011 * more full a pool is the more attempts must be made before finding 1012 * a free lease. Realistically this will only happen in very full 1013 * pools. 1014 * 1015 * We probably want different algorithms depending on the network size, in 1016 * the long term. 1017 */ 1018 isc_result_t 1019 create_lease6(struct ipv6_pool *pool, struct iasubopt **addr, 1020 unsigned int *attempts, 1021 const struct data_string *uid, time_t soft_lifetime_end_time) { 1022 struct data_string ds; 1023 struct in6_addr tmp; 1024 struct iasubopt *test_iaaddr; 1025 struct data_string new_ds; 1026 struct iasubopt *iaaddr; 1027 isc_result_t result; 1028 isc_boolean_t reserved_iid; 1029 static isc_boolean_t init_resiid = ISC_FALSE; 1030 1031 /* 1032 * Fill the reserved IIDs. 1033 */ 1034 if (!init_resiid) { 1035 memset(&rtany, 0, 16); 1036 memset(&resany, 0, 8); 1037 resany.s6_addr[8] = 0xfd; 1038 memset(&resany.s6_addr[9], 0xff, 6); 1039 init_resiid = ISC_TRUE; 1040 } 1041 1042 /* 1043 * Use the UID as our initial seed for the hash 1044 */ 1045 memset(&ds, 0, sizeof(ds)); 1046 data_string_copy(&ds, (struct data_string *)uid, MDL); 1047 1048 *attempts = 0; 1049 for (;;) { 1050 /* 1051 * Give up at some point. 1052 */ 1053 if (++(*attempts) > 100) { 1054 data_string_forget(&ds, MDL); 1055 return ISC_R_NORESOURCES; 1056 } 1057 1058 /* 1059 * Build a resource. 1060 */ 1061 switch (pool->pool_type) { 1062 case D6O_IA_NA: 1063 /* address */ 1064 build_address6(&tmp, &pool->start_addr, 1065 pool->bits, &ds); 1066 break; 1067 case D6O_IA_TA: 1068 /* temporary address */ 1069 build_temporary6(&tmp, &pool->start_addr, 1070 pool->bits, &ds); 1071 break; 1072 case D6O_IA_PD: 1073 /* prefix */ 1074 log_error("create_lease6: prefix pool."); 1075 data_string_forget(&ds, MDL); 1076 return DHCP_R_INVALIDARG; 1077 default: 1078 log_error("create_lease6: untyped pool."); 1079 data_string_forget(&ds, MDL); 1080 return DHCP_R_INVALIDARG; 1081 } 1082 1083 /* 1084 * Avoid reserved interface IDs. (cf. RFC 5453) 1085 */ 1086 reserved_iid = ISC_FALSE; 1087 if (memcmp(&tmp.s6_addr[8], &rtany.s6_addr[8], 8) == 0) { 1088 reserved_iid = ISC_TRUE; 1089 } 1090 if (!reserved_iid && 1091 (memcmp(&tmp.s6_addr[8], &resany.s6_addr[8], 7) == 0) && 1092 ((tmp.s6_addr[15] & 0x80) == 0x80)) { 1093 reserved_iid = ISC_TRUE; 1094 } 1095 1096 /* 1097 * If this address is not in use, we're happy with it 1098 */ 1099 test_iaaddr = NULL; 1100 if (!reserved_iid && 1101 (iasubopt_hash_lookup(&test_iaaddr, pool->leases, 1102 &tmp, sizeof(tmp), MDL) == 0)) { 1103 break; 1104 } 1105 if (test_iaaddr != NULL) 1106 iasubopt_dereference(&test_iaaddr, MDL); 1107 1108 /* 1109 * Otherwise, we create a new input, adding the address 1110 */ 1111 memset(&new_ds, 0, sizeof(new_ds)); 1112 new_ds.len = ds.len + sizeof(tmp); 1113 if (!buffer_allocate(&new_ds.buffer, new_ds.len, MDL)) { 1114 data_string_forget(&ds, MDL); 1115 return ISC_R_NOMEMORY; 1116 } 1117 new_ds.data = new_ds.buffer->data; 1118 memcpy(new_ds.buffer->data, ds.data, ds.len); 1119 memcpy(new_ds.buffer->data + ds.len, &tmp, sizeof(tmp)); 1120 data_string_forget(&ds, MDL); 1121 data_string_copy(&ds, &new_ds, MDL); 1122 data_string_forget(&new_ds, MDL); 1123 } 1124 1125 data_string_forget(&ds, MDL); 1126 1127 /* 1128 * We're happy with the address, create an IAADDR 1129 * to hold it. 1130 */ 1131 iaaddr = NULL; 1132 result = iasubopt_allocate(&iaaddr, MDL); 1133 if (result != ISC_R_SUCCESS) { 1134 return result; 1135 } 1136 iaaddr->plen = 0; 1137 memcpy(&iaaddr->addr, &tmp, sizeof(iaaddr->addr)); 1138 1139 /* 1140 * Add the lease to the pool (note state is free, not active?!). 1141 */ 1142 result = add_lease6(pool, iaaddr, soft_lifetime_end_time); 1143 if (result == ISC_R_SUCCESS) { 1144 iasubopt_reference(addr, iaaddr, MDL); 1145 } 1146 iasubopt_dereference(&iaaddr, MDL); 1147 return result; 1148 } 1149 1150 #ifdef EUI_64 1151 /*! 1152 * \brief Assign an EUI-64 address from a pool for a given iaid-duid 1153 * 1154 * \param pool - pool from which the address is assigned 1155 * \param iaddr - pointer to the iasubopt to contain the assigned address is 1156 * \param uid - data_string containing the iaid-duid tuple 1157 * \param soft_lifetime_end_time - lifetime of the lease for a solicit? 1158 * 1159 * \return status indicating success or nature of the failure 1160 */ 1161 isc_result_t 1162 create_lease6_eui_64(struct ipv6_pool *pool, struct iasubopt **addr, 1163 const struct data_string *uid, 1164 time_t soft_lifetime_end_time) { 1165 struct in6_addr tmp; 1166 struct iasubopt *test_iaaddr; 1167 struct iasubopt *iaaddr; 1168 isc_result_t result; 1169 static isc_boolean_t init_resiid = ISC_FALSE; 1170 1171 /* Fill the reserved IIDs. */ 1172 if (!init_resiid) { 1173 memset(&rtany, 0, 16); 1174 memset(&resany, 0, 8); 1175 resany.s6_addr[8] = 0xfd; 1176 memset(&resany.s6_addr[9], 0xff, 6); 1177 init_resiid = ISC_TRUE; 1178 } 1179 1180 /* Pool must be IA_NA */ 1181 if (pool->pool_type != D6O_IA_NA) { 1182 log_error("create_lease6_eui_64: pool type is not IA_NA."); 1183 return (DHCP_R_INVALIDARG); 1184 } 1185 1186 /* Attempt to build the address */ 1187 if (build_address6_eui_64 (&tmp, &pool->start_addr, pool->bits, 1188 uid, IAID_LEN) != ISC_R_SUCCESS) { 1189 log_error("create_lease6_eui_64: build_address6_eui_64 failed"); 1190 return (ISC_R_FAILURE); 1191 } 1192 1193 /* Avoid reserved interface IDs. (cf. RFC 5453) */ 1194 if ((memcmp(&tmp.s6_addr[8], &rtany.s6_addr[8], 8) == 0) || 1195 ((memcmp(&tmp.s6_addr[8], &resany.s6_addr[8], 7) == 0) && 1196 ((tmp.s6_addr[15] & 0x80) == 0x80))) { 1197 log_error("create_lease6_eui_64: " 1198 "address conflicts with reserved IID"); 1199 return (ISC_R_FAILURE); 1200 } 1201 1202 /* If this address is not in use, we're happy with it */ 1203 test_iaaddr = NULL; 1204 if (iasubopt_hash_lookup(&test_iaaddr, pool->leases, 1205 &tmp, sizeof(tmp), MDL) != 0) { 1206 1207 /* See if it's ours. Static leases won't have an ia */ 1208 int ours = 0; 1209 if (!test_iaaddr->ia) { 1210 log_error("create_lease6_eui_64: " 1211 "address %s is assigned to static lease", 1212 pin6_addr(&test_iaaddr->addr)); 1213 } else { 1214 /* Not sure if this can actually happen */ 1215 struct data_string* found = &test_iaaddr->ia->iaid_duid; 1216 ours = ((found->len == uid->len) && 1217 (!memcmp(found->data, uid->data, uid->len))); 1218 log_error("create_lease6_eui_64: " 1219 "address %s belongs to %s", 1220 pin6_addr(&test_iaaddr->addr), 1221 print_hex_1(found->len, found->data, 60)); 1222 } 1223 1224 iasubopt_dereference(&test_iaaddr, MDL); 1225 if (!ours) { 1226 /* Cant' use it */ 1227 return (ISC_R_FAILURE); 1228 } 1229 } 1230 1231 /* We're happy with the address, create an IAADDR to hold it. */ 1232 iaaddr = NULL; 1233 result = iasubopt_allocate(&iaaddr, MDL); 1234 if (result != ISC_R_SUCCESS) { 1235 log_error("create_lease6_eui_64: could not allocate iasubop"); 1236 return result; 1237 } 1238 iaaddr->plen = 0; 1239 memcpy(&iaaddr->addr, &tmp, sizeof(iaaddr->addr)); 1240 1241 /* Add the lease to the pool and the reply */ 1242 result = add_lease6(pool, iaaddr, soft_lifetime_end_time); 1243 if (result == ISC_R_SUCCESS) { 1244 iasubopt_reference(addr, iaaddr, MDL); 1245 } 1246 1247 iasubopt_dereference(&iaaddr, MDL); 1248 return result; 1249 } 1250 #endif 1251 1252 /*! 1253 * 1254 * \brief Cleans up leases when reading from a lease file 1255 * 1256 * This function is only expected to be run when reading leases in from a file. 1257 * It checks to see if a lease already exists for the new leases's address. 1258 * We don't add expired leases to the structures when reading a lease file 1259 * which limits what can happen. We have two variables the owners of the leases 1260 * being the same or different and the new lease being active or non-active: 1261 * Owners active 1262 * same no remove old lease and its connections 1263 * same yes nothing to do, other code will update the structures. 1264 * diff no nothing to do 1265 * diff yes this combination shouldn't happen, we should only have a 1266 * single active lease per address at a time and that lease 1267 * should move to non-active before any other lease can 1268 * become active for that address. 1269 * Currently we delete the previous lease and pass an error 1270 * to the caller who should log an error. 1271 * 1272 * When we remove a lease we remove it from the hash table and active heap 1273 * (remember only active leases are in the structures at this time) for the 1274 * pool, and from the IA's array. If, after we've removed the pointer from 1275 * IA's array to the lease, the IA has no more pointers we remove it from 1276 * the appropriate hash table as well. 1277 * 1278 * \param[in] ia_table = the hash table for the IA 1279 * \param[in] pool = the pool to update 1280 * \param[in] lease = the new lease we want to add 1281 * \param[in] ia = the new ia we are building 1282 * 1283 * \return 1284 * ISC_R_SUCCESS = the incoming lease and any previous lease were in 1285 * an expected state - one of the first 3 options above. 1286 * If necessary the old lease was removed. 1287 * ISC_R_FAILURE = there is already an active lease for the address in 1288 * the incoming lease. This shouldn't happen if it does 1289 * flag an error for the caller to log. 1290 */ 1291 1292 isc_result_t 1293 cleanup_lease6(ia_hash_t *ia_table, 1294 struct ipv6_pool *pool, 1295 struct iasubopt *lease, 1296 struct ia_xx *ia) { 1297 1298 struct iasubopt *test_iasubopt, *tmp_iasubopt; 1299 struct ia_xx *old_ia; 1300 isc_result_t status = ISC_R_SUCCESS; 1301 1302 test_iasubopt = NULL; 1303 old_ia = NULL; 1304 1305 /* 1306 * Look up the address - if we don't find a lease 1307 * we don't need to do anything. 1308 */ 1309 if (iasubopt_hash_lookup(&test_iasubopt, pool->leases, 1310 &lease->addr, sizeof(lease->addr), 1311 MDL) == 0) { 1312 return (ISC_R_SUCCESS); 1313 } 1314 1315 if (test_iasubopt->ia == NULL) { 1316 /* no old ia, no work to do */ 1317 iasubopt_dereference(&test_iasubopt, MDL); 1318 return (status); 1319 } 1320 1321 ia_reference(&old_ia, test_iasubopt->ia, MDL); 1322 1323 if ((old_ia->iaid_duid.len == ia->iaid_duid.len) && 1324 (memcmp((unsigned char *)ia->iaid_duid.data, 1325 (unsigned char *)old_ia->iaid_duid.data, 1326 ia->iaid_duid.len) == 0)) { 1327 /* same IA */ 1328 if ((lease->state == FTS_ACTIVE) || 1329 (lease->state == FTS_ABANDONED)) { 1330 /* still active, no need to delete */ 1331 goto cleanup; 1332 } 1333 } else { 1334 /* different IA */ 1335 if ((lease->state != FTS_ACTIVE) && 1336 (lease->state != FTS_ABANDONED)) { 1337 /* new lease isn't active, no work */ 1338 goto cleanup; 1339 } 1340 1341 /* 1342 * We appear to have two active leases, this shouldn't happen. 1343 * Before a second lease can be set to active the first lease 1344 * should be set to inactive (released, expired etc). For now 1345 * delete the previous lease and indicate a failure to the 1346 * caller so it can generate a warning. 1347 * In the future we may try and determine which is the better 1348 * lease to keep. 1349 */ 1350 1351 status = ISC_R_FAILURE; 1352 } 1353 1354 /* 1355 * Remove the old lease from the active heap and from the hash table 1356 * then remove the lease from the IA and clean up the IA if necessary. 1357 */ 1358 isc_heap_delete(pool->active_timeouts, test_iasubopt->active_index); 1359 pool->num_active--; 1360 if (pool->ipv6_pond) 1361 pool->ipv6_pond->num_active--; 1362 1363 if (lease->state == FTS_ABANDONED) { 1364 pool->num_abandoned--; 1365 if (pool->ipv6_pond) 1366 pool->ipv6_pond->num_abandoned--; 1367 } 1368 1369 iasubopt_hash_delete(pool->leases, &test_iasubopt->addr, 1370 sizeof(test_iasubopt->addr), MDL); 1371 ia_remove_iasubopt(old_ia, test_iasubopt, MDL); 1372 if (old_ia->num_iasubopt <= 0) { 1373 ia_hash_delete(ia_table, 1374 (unsigned char *)old_ia->iaid_duid.data, 1375 old_ia->iaid_duid.len, MDL); 1376 } 1377 1378 /* 1379 * We derefenrece the subopt here as we've just removed it from 1380 * the hash table in the pool. We need to make a copy as we 1381 * need to derefernece it again later. 1382 */ 1383 tmp_iasubopt = test_iasubopt; 1384 iasubopt_dereference(&tmp_iasubopt, MDL); 1385 1386 cleanup: 1387 ia_dereference(&old_ia, MDL); 1388 1389 /* 1390 * Clean up the reference, this is in addition to the deference 1391 * above after removing the entry from the hash table 1392 */ 1393 iasubopt_dereference(&test_iasubopt, MDL); 1394 1395 return (status); 1396 } 1397 1398 /* 1399 * Put a lease in the pool directly. This is intended to be used when 1400 * loading leases from the file. 1401 */ 1402 isc_result_t 1403 add_lease6(struct ipv6_pool *pool, struct iasubopt *lease, 1404 time_t valid_lifetime_end_time) { 1405 struct iasubopt *test_iasubopt; 1406 struct iasubopt *tmp_iasubopt; 1407 1408 /* If a state was not assigned by the caller, assume active. */ 1409 if (lease->state == 0) 1410 lease->state = FTS_ACTIVE; 1411 1412 ipv6_pool_reference(&lease->ipv6_pool, pool, MDL); 1413 1414 /* 1415 * If this IAADDR/PREFIX is already in our structures, remove the 1416 * old one. 1417 */ 1418 test_iasubopt = NULL; 1419 if (iasubopt_hash_lookup(&test_iasubopt, pool->leases, 1420 &lease->addr, sizeof(lease->addr), MDL)) { 1421 /* XXX: we should probably ask the lease what heap it is on 1422 * (as a consistency check). 1423 * XXX: we should probably have one function to "put this lease 1424 * on its heap" rather than doing these if's everywhere. If 1425 * you add more states to this list, don't. 1426 */ 1427 if ((test_iasubopt->state == FTS_ACTIVE) || 1428 (test_iasubopt->state == FTS_ABANDONED)) { 1429 isc_heap_delete(pool->active_timeouts, 1430 test_iasubopt->active_index); 1431 pool->num_active--; 1432 if (pool->ipv6_pond) 1433 pool->ipv6_pond->num_active--; 1434 1435 if (test_iasubopt->state == FTS_ABANDONED) { 1436 pool->num_abandoned--; 1437 if (pool->ipv6_pond) 1438 pool->ipv6_pond->num_abandoned--; 1439 } 1440 } else { 1441 isc_heap_delete(pool->inactive_timeouts, 1442 test_iasubopt->inactive_index); 1443 pool->num_inactive--; 1444 } 1445 1446 iasubopt_hash_delete(pool->leases, &test_iasubopt->addr, 1447 sizeof(test_iasubopt->addr), MDL); 1448 1449 /* 1450 * We're going to do a bit of evil trickery here. 1451 * 1452 * We need to dereference the entry once to remove our 1453 * current reference (in test_iasubopt), and then one 1454 * more time to remove the reference left when the 1455 * address was added to the pool before. 1456 */ 1457 tmp_iasubopt = test_iasubopt; 1458 iasubopt_dereference(&test_iasubopt, MDL); 1459 iasubopt_dereference(&tmp_iasubopt, MDL); 1460 } 1461 1462 /* 1463 * Add IAADDR/PREFIX to our structures. 1464 */ 1465 tmp_iasubopt = NULL; 1466 iasubopt_reference(&tmp_iasubopt, lease, MDL); 1467 if ((tmp_iasubopt->state == FTS_ACTIVE) || 1468 (tmp_iasubopt->state == FTS_ABANDONED)) { 1469 tmp_iasubopt->hard_lifetime_end_time = valid_lifetime_end_time; 1470 iasubopt_hash_add(pool->leases, &tmp_iasubopt->addr, 1471 sizeof(tmp_iasubopt->addr), lease, MDL); 1472 isc_heap_insert(pool->active_timeouts, tmp_iasubopt); 1473 pool->num_active++; 1474 if (pool->ipv6_pond) 1475 pool->ipv6_pond->num_active++; 1476 1477 if (tmp_iasubopt->state == FTS_ABANDONED) { 1478 pool->num_abandoned++; 1479 if (pool->ipv6_pond) 1480 pool->ipv6_pond->num_abandoned++; 1481 } 1482 1483 } else { 1484 tmp_iasubopt->soft_lifetime_end_time = valid_lifetime_end_time; 1485 isc_heap_insert(pool->inactive_timeouts, tmp_iasubopt); 1486 pool->num_inactive++; 1487 } 1488 iasubopt_hash_delete(pool->leases, &lease->addr, 1489 sizeof(lease->addr), MDL); 1490 iasubopt_dereference(&tmp_iasubopt, MDL); 1491 /* 1492 * Note: we intentionally leave tmp_iasubopt referenced; there 1493 * is a reference in the heap/hash, after all. 1494 */ 1495 1496 return ISC_R_SUCCESS; 1497 } 1498 1499 /* 1500 * Determine if an address is present in a pool or not. 1501 */ 1502 isc_boolean_t 1503 lease6_exists(const struct ipv6_pool *pool, const struct in6_addr *addr) { 1504 struct iasubopt *test_iaaddr; 1505 1506 test_iaaddr = NULL; 1507 if (iasubopt_hash_lookup(&test_iaaddr, pool->leases, 1508 (void *)addr, sizeof(*addr), MDL)) { 1509 iasubopt_dereference(&test_iaaddr, MDL); 1510 return ISC_TRUE; 1511 } else { 1512 return ISC_FALSE; 1513 } 1514 } 1515 1516 /*! 1517 * 1518 * \brief Check if address is available to a lease 1519 * 1520 * Determine if the address in the lease is available to that 1521 * lease. Either the address isn't in use or it is in use 1522 * but by that lease. 1523 * 1524 * \param[in] lease = lease to check 1525 * 1526 * \return 1527 * ISC_TRUE = The lease is allowed to use that address 1528 * ISC_FALSE = The lease isn't allowed to use that address 1529 */ 1530 isc_boolean_t 1531 lease6_usable(struct iasubopt *lease) { 1532 struct iasubopt *test_iaaddr; 1533 isc_boolean_t status = ISC_TRUE; 1534 1535 test_iaaddr = NULL; 1536 if (iasubopt_hash_lookup(&test_iaaddr, lease->ipv6_pool->leases, 1537 (void *)&lease->addr, 1538 sizeof(lease->addr), MDL)) { 1539 if (test_iaaddr != lease) { 1540 status = ISC_FALSE; 1541 } 1542 iasubopt_dereference(&test_iaaddr, MDL); 1543 } 1544 1545 return (status); 1546 } 1547 1548 /* 1549 * Put the lease on our active pool. 1550 */ 1551 static isc_result_t 1552 move_lease_to_active(struct ipv6_pool *pool, struct iasubopt *lease) { 1553 isc_heap_insert(pool->active_timeouts, lease); 1554 iasubopt_hash_add(pool->leases, &lease->addr, 1555 sizeof(lease->addr), lease, MDL); 1556 isc_heap_delete(pool->inactive_timeouts, 1557 lease->inactive_index); 1558 pool->num_active++; 1559 pool->num_inactive--; 1560 lease->state = FTS_ACTIVE; 1561 if (pool->ipv6_pond) 1562 pool->ipv6_pond->num_active++; 1563 1564 return ISC_R_SUCCESS; 1565 } 1566 1567 /*! 1568 * 1569 * \brief Renew a lease in the pool. 1570 * 1571 * The hard_lifetime_end_time of the lease should be set to 1572 * the current expiration time. 1573 * The soft_lifetime_end_time of the lease should be set to 1574 * the desired expiration time. 1575 * 1576 * This routine will compare the two and call the correct 1577 * heap routine to move the lease. If the lease is active 1578 * and the new expiration time is greater (the normal case) 1579 * then we call isc_heap_decreased() as a larger time is a 1580 * lower priority. If the new expiration time is less then 1581 * we call isc_heap_increased(). 1582 * 1583 * If the lease is abandoned then it will be on the active list 1584 * and we will always call isc_heap_increased() as the previous 1585 * expiration would have been all 1s (as close as we can get 1586 * to infinite). 1587 * 1588 * If the lease is moving to active we call that routine 1589 * which will move it from the inactive list to the active list. 1590 * 1591 * \param pool = a pool the lease belongs to 1592 * \param lease = the lease to be renewed 1593 * 1594 * \return result of the renew operation (ISC_R_SUCCESS if successful, 1595 ISC_R_NOMEMORY when run out of memory) 1596 */ 1597 isc_result_t 1598 renew_lease6(struct ipv6_pool *pool, struct iasubopt *lease) { 1599 time_t old_end_time = lease->hard_lifetime_end_time; 1600 lease->hard_lifetime_end_time = lease->soft_lifetime_end_time; 1601 lease->soft_lifetime_end_time = 0; 1602 1603 if (lease->state == FTS_ACTIVE) { 1604 if (old_end_time <= lease->hard_lifetime_end_time) { 1605 isc_heap_decreased(pool->active_timeouts, 1606 lease->active_index); 1607 } else { 1608 isc_heap_increased(pool->active_timeouts, 1609 lease->active_index); 1610 } 1611 return ISC_R_SUCCESS; 1612 } else if (lease->state == FTS_ABANDONED) { 1613 char tmp_addr[INET6_ADDRSTRLEN]; 1614 lease->state = FTS_ACTIVE; 1615 isc_heap_increased(pool->active_timeouts, lease->active_index); 1616 log_info("Reclaiming previously abandoned address %s", 1617 inet_ntop(AF_INET6, &(lease->addr), tmp_addr, 1618 sizeof(tmp_addr))); 1619 1620 pool->num_abandoned--; 1621 if (pool->ipv6_pond) 1622 pool->ipv6_pond->num_abandoned--; 1623 1624 return ISC_R_SUCCESS; 1625 } else { 1626 return move_lease_to_active(pool, lease); 1627 } 1628 } 1629 1630 /* 1631 * Put the lease on our inactive pool, with the specified state. 1632 */ 1633 static isc_result_t 1634 move_lease_to_inactive(struct ipv6_pool *pool, struct iasubopt *lease, 1635 binding_state_t state) { 1636 1637 isc_heap_insert(pool->inactive_timeouts, lease); 1638 /* 1639 * Handle expire and release statements 1640 * To get here we must be active and have done a commit so 1641 * we should run the proper statements if they exist, though 1642 * that will change when we remove the inactive heap. 1643 * In addition we get rid of the references for both as we 1644 * can only do one (expire or release) on a lease 1645 */ 1646 if (lease->on_star.on_expiry != NULL) { 1647 if (state == FTS_EXPIRED) { 1648 execute_statements(NULL, NULL, NULL, 1649 NULL, NULL, NULL, 1650 &lease->scope, 1651 lease->on_star.on_expiry, 1652 &lease->on_star); 1653 } 1654 executable_statement_dereference 1655 (&lease->on_star.on_expiry, MDL); 1656 } 1657 1658 if (lease->on_star.on_release != NULL) { 1659 if (state == FTS_RELEASED) { 1660 execute_statements(NULL, NULL, NULL, 1661 NULL, NULL, NULL, 1662 &lease->scope, 1663 lease->on_star.on_release, 1664 &lease->on_star); 1665 } 1666 executable_statement_dereference 1667 (&lease->on_star.on_release, MDL); 1668 } 1669 1670 #if defined (NSUPDATE) 1671 /* Process events upon expiration. */ 1672 if (pool->pool_type != D6O_IA_PD) { 1673 (void) ddns_removals(NULL, lease, NULL, ISC_FALSE); 1674 } 1675 #endif 1676 1677 /* Binding scopes are no longer valid after expiry or 1678 * release. 1679 */ 1680 if (lease->scope != NULL) { 1681 binding_scope_dereference(&lease->scope, MDL); 1682 } 1683 1684 iasubopt_hash_delete(pool->leases, 1685 &lease->addr, sizeof(lease->addr), MDL); 1686 isc_heap_delete(pool->active_timeouts, lease->active_index); 1687 lease->state = state; 1688 pool->num_active--; 1689 pool->num_inactive++; 1690 if (pool->ipv6_pond) 1691 pool->ipv6_pond->num_active--; 1692 1693 if (lease->state == FTS_ABANDONED) { 1694 pool->num_abandoned--; 1695 if (pool->ipv6_pond) 1696 pool->ipv6_pond->num_abandoned--; 1697 } 1698 return ISC_R_SUCCESS; 1699 } 1700 1701 /* 1702 * Expire the oldest lease if it's lifetime_end_time is 1703 * older than the given time. 1704 * 1705 * - leasep must be a pointer to a (struct iasubopt *) pointer previously 1706 * initialized to NULL 1707 * 1708 * On return leasep has a reference to the removed entry. It is left 1709 * pointing to NULL if the oldest lease has not expired. 1710 */ 1711 isc_result_t 1712 expire_lease6(struct iasubopt **leasep, struct ipv6_pool *pool, time_t now) { 1713 struct iasubopt *tmp; 1714 isc_result_t result; 1715 1716 if (leasep == NULL) { 1717 log_error("%s(%d): NULL pointer reference", MDL); 1718 return DHCP_R_INVALIDARG; 1719 } 1720 if (*leasep != NULL) { 1721 log_error("%s(%d): non-NULL pointer", MDL); 1722 return DHCP_R_INVALIDARG; 1723 } 1724 1725 if (pool->num_active > 0) { 1726 tmp = (struct iasubopt *) 1727 isc_heap_element(pool->active_timeouts, 1); 1728 if (now > tmp->hard_lifetime_end_time) { 1729 result = move_lease_to_inactive(pool, tmp, 1730 FTS_EXPIRED); 1731 if (result == ISC_R_SUCCESS) { 1732 iasubopt_reference(leasep, tmp, MDL); 1733 } 1734 return result; 1735 } 1736 } 1737 return ISC_R_SUCCESS; 1738 } 1739 1740 1741 /* 1742 * For a declined lease, leave it on the "active" pool, but mark 1743 * it as declined. Give it an infinite (well, really long) life. 1744 */ 1745 isc_result_t 1746 decline_lease6(struct ipv6_pool *pool, struct iasubopt *lease) { 1747 isc_result_t result; 1748 1749 if ((lease->state != FTS_ACTIVE) && 1750 (lease->state != FTS_ABANDONED)) { 1751 result = move_lease_to_active(pool, lease); 1752 if (result != ISC_R_SUCCESS) { 1753 return result; 1754 } 1755 } 1756 lease->state = FTS_ABANDONED; 1757 1758 pool->num_abandoned++; 1759 if (pool->ipv6_pond) 1760 pool->ipv6_pond->num_abandoned++; 1761 1762 lease->hard_lifetime_end_time = MAX_TIME; 1763 isc_heap_decreased(pool->active_timeouts, lease->active_index); 1764 return ISC_R_SUCCESS; 1765 } 1766 1767 /* 1768 * Put the returned lease on our inactive pool. 1769 */ 1770 isc_result_t 1771 release_lease6(struct ipv6_pool *pool, struct iasubopt *lease) { 1772 if (lease->state == FTS_ACTIVE) { 1773 return move_lease_to_inactive(pool, lease, FTS_RELEASED); 1774 } else { 1775 return ISC_R_SUCCESS; 1776 } 1777 } 1778 1779 /* 1780 * Create a prefix by hashing the input, and using that for 1781 * the part subject to allocation. 1782 */ 1783 static void 1784 build_prefix6(struct in6_addr *pref, 1785 const struct in6_addr *net_start_pref, 1786 int pool_bits, int pref_bits, 1787 const struct data_string *input) { 1788 int net_bytes; 1789 int i; 1790 unsigned int len; 1791 char *str; 1792 const char *net_str; 1793 1794 /* 1795 * Use MD5 to get a nice 128 bit hash of the input. 1796 * Yes, we know MD5 isn't cryptographically sound. 1797 * No, we don't care. 1798 */ 1799 isc_md(ISC_MD_MD5, input->data, input->len, (void *)&pref, &len); 1800 1801 /* 1802 * Copy the network bits over. 1803 */ 1804 str = (char *)pref; 1805 net_str = (const char *)net_start_pref; 1806 net_bytes = pool_bits / 8; 1807 for (i = 0; i < net_bytes; i++) { 1808 str[i] = net_str[i]; 1809 } 1810 i = net_bytes; 1811 switch (pool_bits % 8) { 1812 case 1: str[i] = (str[i] & 0x7F) | (net_str[i] & 0x80); break; 1813 case 2: str[i] = (str[i] & 0x3F) | (net_str[i] & 0xC0); break; 1814 case 3: str[i] = (str[i] & 0x1F) | (net_str[i] & 0xE0); break; 1815 case 4: str[i] = (str[i] & 0x0F) | (net_str[i] & 0xF0); break; 1816 case 5: str[i] = (str[i] & 0x07) | (net_str[i] & 0xF8); break; 1817 case 6: str[i] = (str[i] & 0x03) | (net_str[i] & 0xFC); break; 1818 case 7: str[i] = (str[i] & 0x01) | (net_str[i] & 0xFE); break; 1819 } 1820 /* 1821 * Zero the remaining bits. 1822 */ 1823 net_bytes = pref_bits / 8; 1824 for (i=net_bytes+1; i<16; i++) { 1825 str[i] = 0; 1826 } 1827 i = net_bytes; 1828 switch (pref_bits % 8) { 1829 case 0: str[i] &= 0; break; 1830 case 1: str[i] &= 0x80; break; 1831 case 2: str[i] &= 0xC0; break; 1832 case 3: str[i] &= 0xE0; break; 1833 case 4: str[i] &= 0xF0; break; 1834 case 5: str[i] &= 0xF8; break; 1835 case 6: str[i] &= 0xFC; break; 1836 case 7: str[i] &= 0xFE; break; 1837 } 1838 } 1839 1840 /* 1841 * Create a lease for the given prefix and client duid. 1842 * 1843 * - pool must be a pointer to a (struct ipv6_pool *) pointer previously 1844 * initialized to NULL 1845 * 1846 * Right now we simply hash the DUID, and if we get a collision, we hash 1847 * again until we find a free prefix. We try this a fixed number of times, 1848 * to avoid getting stuck in a loop (this is important on small pools 1849 * where we can run out of space). 1850 * 1851 * We return the number of attempts that it took to find an available 1852 * prefix. This tells callers when a pool is are filling up, as 1853 * well as an indication of how full the pool is; statistically the 1854 * more full a pool is the more attempts must be made before finding 1855 * a free prefix. Realistically this will only happen in very full 1856 * pools. 1857 * 1858 * We probably want different algorithms depending on the network size, in 1859 * the long term. 1860 */ 1861 isc_result_t 1862 create_prefix6(struct ipv6_pool *pool, struct iasubopt **pref, 1863 unsigned int *attempts, 1864 const struct data_string *uid, 1865 time_t soft_lifetime_end_time) { 1866 struct data_string ds; 1867 struct in6_addr tmp; 1868 struct iasubopt *test_iapref; 1869 struct data_string new_ds; 1870 struct iasubopt *iapref; 1871 isc_result_t result; 1872 1873 /* 1874 * Use the UID as our initial seed for the hash 1875 */ 1876 memset(&ds, 0, sizeof(ds)); 1877 data_string_copy(&ds, (struct data_string *)uid, MDL); 1878 1879 *attempts = 0; 1880 for (;;) { 1881 /* 1882 * Give up at some point. 1883 */ 1884 if (++(*attempts) > 10) { 1885 data_string_forget(&ds, MDL); 1886 return ISC_R_NORESOURCES; 1887 } 1888 1889 /* 1890 * Build a prefix 1891 */ 1892 build_prefix6(&tmp, &pool->start_addr, 1893 pool->bits, pool->units, &ds); 1894 1895 /* 1896 * If this prefix is not in use, we're happy with it 1897 */ 1898 test_iapref = NULL; 1899 if (iasubopt_hash_lookup(&test_iapref, pool->leases, 1900 &tmp, sizeof(tmp), MDL) == 0) { 1901 break; 1902 } 1903 iasubopt_dereference(&test_iapref, MDL); 1904 1905 /* 1906 * Otherwise, we create a new input, adding the prefix 1907 */ 1908 memset(&new_ds, 0, sizeof(new_ds)); 1909 new_ds.len = ds.len + sizeof(tmp); 1910 if (!buffer_allocate(&new_ds.buffer, new_ds.len, MDL)) { 1911 data_string_forget(&ds, MDL); 1912 return ISC_R_NOMEMORY; 1913 } 1914 new_ds.data = new_ds.buffer->data; 1915 memcpy(new_ds.buffer->data, ds.data, ds.len); 1916 memcpy(&new_ds.buffer->data[0] + ds.len, &tmp, sizeof(tmp)); 1917 data_string_forget(&ds, MDL); 1918 data_string_copy(&ds, &new_ds, MDL); 1919 data_string_forget(&new_ds, MDL); 1920 } 1921 1922 data_string_forget(&ds, MDL); 1923 1924 /* 1925 * We're happy with the prefix, create an IAPREFIX 1926 * to hold it. 1927 */ 1928 iapref = NULL; 1929 result = iasubopt_allocate(&iapref, MDL); 1930 if (result != ISC_R_SUCCESS) { 1931 return result; 1932 } 1933 iapref->plen = (u_int8_t)pool->units; 1934 memcpy(&iapref->addr, &tmp, sizeof(iapref->addr)); 1935 1936 /* 1937 * Add the prefix to the pool (note state is free, not active?!). 1938 */ 1939 result = add_lease6(pool, iapref, soft_lifetime_end_time); 1940 if (result == ISC_R_SUCCESS) { 1941 iasubopt_reference(pref, iapref, MDL); 1942 } 1943 iasubopt_dereference(&iapref, MDL); 1944 return result; 1945 } 1946 1947 /* 1948 * Determine if a prefix is present in a pool or not. 1949 */ 1950 isc_boolean_t 1951 prefix6_exists(const struct ipv6_pool *pool, 1952 const struct in6_addr *pref, u_int8_t plen) { 1953 struct iasubopt *test_iapref; 1954 1955 if ((int)plen != pool->units) 1956 return ISC_FALSE; 1957 1958 test_iapref = NULL; 1959 if (iasubopt_hash_lookup(&test_iapref, pool->leases, 1960 (void *)pref, sizeof(*pref), MDL)) { 1961 iasubopt_dereference(&test_iapref, MDL); 1962 return ISC_TRUE; 1963 } else { 1964 return ISC_FALSE; 1965 } 1966 } 1967 1968 /* 1969 * Mark an IPv6 address/prefix as unavailable from a pool. 1970 * 1971 * This is used for host entries and the addresses of the server itself. 1972 */ 1973 static isc_result_t 1974 mark_lease_unavailable(struct ipv6_pool *pool, const struct in6_addr *addr) { 1975 struct iasubopt *dummy_iasubopt; 1976 isc_result_t result; 1977 1978 dummy_iasubopt = NULL; 1979 result = iasubopt_allocate(&dummy_iasubopt, MDL); 1980 if (result == ISC_R_SUCCESS) { 1981 dummy_iasubopt->addr = *addr; 1982 iasubopt_hash_add(pool->leases, &dummy_iasubopt->addr, 1983 sizeof(*addr), dummy_iasubopt, MDL); 1984 } 1985 return result; 1986 } 1987 1988 /* 1989 * Add a pool. 1990 */ 1991 isc_result_t 1992 add_ipv6_pool(struct ipv6_pool *pool) { 1993 struct ipv6_pool **new_pools; 1994 1995 new_pools = dmalloc(sizeof(struct ipv6_pool *) * (num_pools+1), MDL); 1996 if (new_pools == NULL) { 1997 return ISC_R_NOMEMORY; 1998 } 1999 2000 if (num_pools > 0) { 2001 memcpy(new_pools, pools, 2002 sizeof(struct ipv6_pool *) * num_pools); 2003 dfree(pools, MDL); 2004 } 2005 pools = new_pools; 2006 2007 pools[num_pools] = NULL; 2008 ipv6_pool_reference(&pools[num_pools], pool, MDL); 2009 num_pools++; 2010 return ISC_R_SUCCESS; 2011 } 2012 2013 static void 2014 cleanup_old_expired(struct ipv6_pool *pool) { 2015 struct iasubopt *tmp; 2016 struct ia_xx *ia; 2017 struct ia_xx *ia_active; 2018 unsigned char *tmpd; 2019 time_t timeout; 2020 2021 while (pool->num_inactive > 0) { 2022 tmp = (struct iasubopt *) 2023 isc_heap_element(pool->inactive_timeouts, 1); 2024 if (tmp->hard_lifetime_end_time != 0) { 2025 timeout = tmp->hard_lifetime_end_time; 2026 timeout += EXPIRED_IPV6_CLEANUP_TIME; 2027 } else { 2028 timeout = tmp->soft_lifetime_end_time; 2029 } 2030 if (cur_time < timeout) { 2031 break; 2032 } 2033 2034 isc_heap_delete(pool->inactive_timeouts, tmp->inactive_index); 2035 pool->num_inactive--; 2036 2037 if (tmp->ia != NULL) { 2038 /* 2039 * Check to see if this IA is in an active list, 2040 * but has no remaining resources. If so, remove it 2041 * from the active list. 2042 */ 2043 ia = NULL; 2044 ia_reference(&ia, tmp->ia, MDL); 2045 ia_remove_iasubopt(ia, tmp, MDL); 2046 ia_active = NULL; 2047 tmpd = (unsigned char *)ia->iaid_duid.data; 2048 if ((ia->ia_type == D6O_IA_NA) && 2049 (ia->num_iasubopt <= 0) && 2050 (ia_hash_lookup(&ia_active, ia_na_active, tmpd, 2051 ia->iaid_duid.len, MDL) == 0) && 2052 (ia_active == ia)) { 2053 ia_hash_delete(ia_na_active, tmpd, 2054 ia->iaid_duid.len, MDL); 2055 } 2056 if ((ia->ia_type == D6O_IA_TA) && 2057 (ia->num_iasubopt <= 0) && 2058 (ia_hash_lookup(&ia_active, ia_ta_active, tmpd, 2059 ia->iaid_duid.len, MDL) == 0) && 2060 (ia_active == ia)) { 2061 ia_hash_delete(ia_ta_active, tmpd, 2062 ia->iaid_duid.len, MDL); 2063 } 2064 if ((ia->ia_type == D6O_IA_PD) && 2065 (ia->num_iasubopt <= 0) && 2066 (ia_hash_lookup(&ia_active, ia_pd_active, tmpd, 2067 ia->iaid_duid.len, MDL) == 0) && 2068 (ia_active == ia)) { 2069 ia_hash_delete(ia_pd_active, tmpd, 2070 ia->iaid_duid.len, MDL); 2071 } 2072 ia_dereference(&ia, MDL); 2073 } else { 2074 iasubopt_dereference(&tmp, MDL); 2075 } 2076 } 2077 } 2078 2079 static void 2080 lease_timeout_support(void *vpool) { 2081 struct ipv6_pool *pool; 2082 struct iasubopt *lease; 2083 2084 pool = (struct ipv6_pool *)vpool; 2085 for (;;) { 2086 /* 2087 * Get the next lease scheduled to expire. 2088 * 2089 * Note that if there are no leases in the pool, 2090 * expire_lease6() will return ISC_R_SUCCESS with 2091 * a NULL lease. 2092 * 2093 * expire_lease6() will call move_lease_to_inactive() which 2094 * calls ddns_removals() do we want that on the standard 2095 * expiration timer or a special 'depref' timer? Original 2096 * query from DH, moved here by SAR. 2097 */ 2098 lease = NULL; 2099 if (expire_lease6(&lease, pool, cur_time) != ISC_R_SUCCESS) { 2100 break; 2101 } 2102 if (lease == NULL) { 2103 break; 2104 } 2105 2106 write_ia(lease->ia); 2107 2108 iasubopt_dereference(&lease, MDL); 2109 } 2110 2111 /* 2112 * If appropriate commit and rotate the lease file 2113 * As commit_leases_timed() checks to see if we've done any writes 2114 * we don't bother tracking if this function called write _ia 2115 */ 2116 (void) commit_leases_timed(); 2117 2118 /* 2119 * Do some cleanup of our expired leases. 2120 */ 2121 cleanup_old_expired(pool); 2122 2123 /* 2124 * Schedule next round of expirations. 2125 */ 2126 schedule_lease_timeout(pool); 2127 } 2128 2129 /* 2130 * For a given pool, add a timer that will remove the next 2131 * lease to expire. 2132 */ 2133 void 2134 schedule_lease_timeout(struct ipv6_pool *pool) { 2135 struct iasubopt *tmp; 2136 time_t timeout; 2137 time_t next_timeout; 2138 struct timeval tv; 2139 2140 next_timeout = MAX_TIME; 2141 2142 if (pool->num_active > 0) { 2143 tmp = (struct iasubopt *) 2144 isc_heap_element(pool->active_timeouts, 1); 2145 if (tmp->hard_lifetime_end_time < next_timeout) { 2146 next_timeout = tmp->hard_lifetime_end_time + 1; 2147 } 2148 } 2149 2150 if (pool->num_inactive > 0) { 2151 tmp = (struct iasubopt *) 2152 isc_heap_element(pool->inactive_timeouts, 1); 2153 if (tmp->hard_lifetime_end_time != 0) { 2154 timeout = tmp->hard_lifetime_end_time; 2155 timeout += EXPIRED_IPV6_CLEANUP_TIME; 2156 } else { 2157 timeout = tmp->soft_lifetime_end_time + 1; 2158 } 2159 if (timeout < next_timeout) { 2160 next_timeout = timeout; 2161 } 2162 } 2163 2164 if (next_timeout < MAX_TIME) { 2165 tv.tv_sec = next_timeout; 2166 tv.tv_usec = 0; 2167 add_timeout(&tv, lease_timeout_support, pool, 2168 (tvref_t)ipv6_pool_reference, 2169 (tvunref_t)ipv6_pool_dereference); 2170 } 2171 } 2172 2173 /* 2174 * Schedule timeouts across all pools. 2175 */ 2176 void 2177 schedule_all_ipv6_lease_timeouts(void) { 2178 int i; 2179 2180 for (i=0; i<num_pools; i++) { 2181 schedule_lease_timeout(pools[i]); 2182 } 2183 } 2184 2185 /* 2186 * Given an address and the length of the network mask, return 2187 * only the network portion. 2188 * 2189 * Examples: 2190 * 2191 * "fe80::216:6fff:fe49:7d9b", length 64 = "fe80::" 2192 * "2001:888:1936:2:216:6fff:fe49:7d9b", length 48 = "2001:888:1936::" 2193 */ 2194 static void 2195 ipv6_network_portion(struct in6_addr *result, 2196 const struct in6_addr *addr, int bits) { 2197 unsigned char *addrp; 2198 int mask_bits; 2199 int bytes; 2200 int extra_bits; 2201 int i; 2202 2203 static const unsigned char bitmasks[] = { 2204 0x00, 0xFE, 0xFC, 0xF8, 2205 0xF0, 0xE0, 0xC0, 0x80, 2206 }; 2207 2208 /* 2209 * Sanity check our bits. ;) 2210 */ 2211 if ((bits < 0) || (bits > 128)) { 2212 log_fatal("ipv6_network_portion: bits %d not between 0 and 128", 2213 bits); 2214 } 2215 2216 /* 2217 * Copy our address portion. 2218 */ 2219 *result = *addr; 2220 addrp = ((unsigned char *)result) + 15; 2221 2222 /* 2223 * Zero out masked portion. 2224 */ 2225 mask_bits = 128 - bits; 2226 bytes = mask_bits / 8; 2227 extra_bits = mask_bits % 8; 2228 2229 for (i=0; i<bytes; i++) { 2230 *addrp = 0; 2231 addrp--; 2232 } 2233 if (extra_bits) { 2234 *addrp &= bitmasks[extra_bits]; 2235 } 2236 } 2237 2238 /* 2239 * Determine if the given address/prefix is in the pool. 2240 */ 2241 isc_boolean_t 2242 ipv6_in_pool(const struct in6_addr *addr, const struct ipv6_pool *pool) { 2243 struct in6_addr tmp; 2244 2245 ipv6_network_portion(&tmp, addr, pool->bits); 2246 if (memcmp(&tmp, &pool->start_addr, sizeof(tmp)) == 0) { 2247 return ISC_TRUE; 2248 } else { 2249 return ISC_FALSE; 2250 } 2251 } 2252 2253 /* 2254 * Find the pool that contains the given address. 2255 * 2256 * - pool must be a pointer to a (struct ipv6_pool *) pointer previously 2257 * initialized to NULL 2258 */ 2259 isc_result_t 2260 find_ipv6_pool(struct ipv6_pool **pool, u_int16_t type, 2261 const struct in6_addr *addr) { 2262 int i; 2263 2264 if (pool == NULL) { 2265 log_error("%s(%d): NULL pointer reference", MDL); 2266 return DHCP_R_INVALIDARG; 2267 } 2268 if (*pool != NULL) { 2269 log_error("%s(%d): non-NULL pointer", MDL); 2270 return DHCP_R_INVALIDARG; 2271 } 2272 2273 for (i=0; i<num_pools; i++) { 2274 if (pools[i]->pool_type != type) 2275 continue; 2276 if (ipv6_in_pool(addr, pools[i])) { 2277 ipv6_pool_reference(pool, pools[i], MDL); 2278 return ISC_R_SUCCESS; 2279 } 2280 } 2281 return ISC_R_NOTFOUND; 2282 } 2283 2284 /* 2285 * Helper function for the various functions that act across all 2286 * pools. 2287 */ 2288 static isc_result_t 2289 change_leases(struct ia_xx *ia, 2290 isc_result_t (*change_func)(struct ipv6_pool *, 2291 struct iasubopt *)) { 2292 isc_result_t retval; 2293 isc_result_t renew_retval; 2294 struct ipv6_pool *pool; 2295 struct in6_addr *addr; 2296 int i; 2297 2298 retval = ISC_R_SUCCESS; 2299 for (i=0; i<ia->num_iasubopt; i++) { 2300 pool = NULL; 2301 addr = &ia->iasubopt[i]->addr; 2302 if (find_ipv6_pool(&pool, ia->ia_type, 2303 addr) == ISC_R_SUCCESS) { 2304 renew_retval = change_func(pool, ia->iasubopt[i]); 2305 if (renew_retval != ISC_R_SUCCESS) { 2306 retval = renew_retval; 2307 } 2308 } 2309 /* XXXsk: should we warn if we don't find a pool? */ 2310 } 2311 return retval; 2312 } 2313 2314 /* 2315 * Renew all leases in an IA from all pools. 2316 * 2317 * The new lifetime should be in the soft_lifetime_end_time 2318 * and will be moved to hard_lifetime_end_time by renew_lease6. 2319 */ 2320 isc_result_t 2321 renew_leases(struct ia_xx *ia) { 2322 return change_leases(ia, renew_lease6); 2323 } 2324 2325 /* 2326 * Release all leases in an IA from all pools. 2327 */ 2328 isc_result_t 2329 release_leases(struct ia_xx *ia) { 2330 return change_leases(ia, release_lease6); 2331 } 2332 2333 /* 2334 * Decline all leases in an IA from all pools. 2335 */ 2336 isc_result_t 2337 decline_leases(struct ia_xx *ia) { 2338 return change_leases(ia, decline_lease6); 2339 } 2340 2341 #ifdef DHCPv6 2342 /* 2343 * Helper function to output leases. 2344 */ 2345 static int write_error; 2346 2347 static isc_result_t 2348 write_ia_leases(const void *name, unsigned len, void *value) { 2349 struct ia_xx *ia = (struct ia_xx *)value; 2350 2351 if (!write_error) { 2352 if (!write_ia(ia)) { 2353 write_error = 1; 2354 } 2355 } 2356 return ISC_R_SUCCESS; 2357 } 2358 2359 /* 2360 * Write all DHCPv6 information. 2361 */ 2362 int 2363 write_leases6(void) { 2364 int nas, tas, pds; 2365 2366 write_error = 0; 2367 write_server_duid(); 2368 nas = ia_hash_foreach(ia_na_active, write_ia_leases); 2369 if (write_error) { 2370 return 0; 2371 } 2372 tas = ia_hash_foreach(ia_ta_active, write_ia_leases); 2373 if (write_error) { 2374 return 0; 2375 } 2376 pds = ia_hash_foreach(ia_pd_active, write_ia_leases); 2377 if (write_error) { 2378 return 0; 2379 } 2380 2381 log_info("Wrote %d NA, %d TA, %d PD leases to lease file.", 2382 nas, tas, pds); 2383 return 1; 2384 } 2385 #endif /* DHCPv6 */ 2386 2387 static isc_result_t 2388 mark_hosts_unavailable_support(const void *name, unsigned len, void *value) { 2389 struct host_decl *h; 2390 struct data_string fixed_addr; 2391 struct in6_addr addr; 2392 struct ipv6_pool *p; 2393 2394 h = (struct host_decl *)value; 2395 2396 /* 2397 * If the host has no address, we don't need to mark anything. 2398 */ 2399 if (h->fixed_addr == NULL) { 2400 return ISC_R_SUCCESS; 2401 } 2402 2403 /* 2404 * Evaluate the fixed address. 2405 */ 2406 memset(&fixed_addr, 0, sizeof(fixed_addr)); 2407 if (!evaluate_option_cache(&fixed_addr, NULL, NULL, NULL, NULL, NULL, 2408 &global_scope, h->fixed_addr, MDL)) { 2409 log_error("mark_hosts_unavailable: " 2410 "error evaluating host address."); 2411 return ISC_R_SUCCESS; 2412 } 2413 if (fixed_addr.len != 16) { 2414 log_error("mark_hosts_unavailable: " 2415 "host address is not 128 bits."); 2416 return ISC_R_SUCCESS; 2417 } 2418 memcpy(&addr, fixed_addr.data, 16); 2419 data_string_forget(&fixed_addr, MDL); 2420 2421 /* 2422 * Find the pool holding this host, and mark the address. 2423 * (I suppose it is arguably valid to have a host that does not 2424 * sit in any pool.) 2425 */ 2426 p = NULL; 2427 if (find_ipv6_pool(&p, D6O_IA_NA, &addr) == ISC_R_SUCCESS) { 2428 mark_lease_unavailable(p, &addr); 2429 ipv6_pool_dereference(&p, MDL); 2430 } 2431 if (find_ipv6_pool(&p, D6O_IA_TA, &addr) == ISC_R_SUCCESS) { 2432 mark_lease_unavailable(p, &addr); 2433 ipv6_pool_dereference(&p, MDL); 2434 } 2435 2436 return ISC_R_SUCCESS; 2437 } 2438 2439 void 2440 mark_hosts_unavailable(void) { 2441 hash_foreach(host_name_hash, mark_hosts_unavailable_support); 2442 } 2443 2444 static isc_result_t 2445 mark_phosts_unavailable_support(const void *name, unsigned len, void *value) { 2446 struct host_decl *h; 2447 struct iaddrcidrnetlist *l; 2448 struct in6_addr pref; 2449 struct ipv6_pool *p; 2450 2451 h = (struct host_decl *)value; 2452 2453 /* 2454 * If the host has no prefix, we don't need to mark anything. 2455 */ 2456 if (h->fixed_prefix == NULL) { 2457 return ISC_R_SUCCESS; 2458 } 2459 2460 /* 2461 * Get the fixed prefixes. 2462 */ 2463 for (l = h->fixed_prefix; l != NULL; l = l->next) { 2464 if (l->cidrnet.lo_addr.len != 16) { 2465 continue; 2466 } 2467 memcpy(&pref, l->cidrnet.lo_addr.iabuf, 16); 2468 2469 /* 2470 * Find the pool holding this host, and mark the prefix. 2471 * (I suppose it is arguably valid to have a host that does not 2472 * sit in any pool.) 2473 */ 2474 p = NULL; 2475 if (find_ipv6_pool(&p, D6O_IA_PD, &pref) != ISC_R_SUCCESS) { 2476 continue; 2477 } 2478 if (l->cidrnet.bits != p->units) { 2479 ipv6_pool_dereference(&p, MDL); 2480 continue; 2481 } 2482 mark_lease_unavailable(p, &pref); 2483 ipv6_pool_dereference(&p, MDL); 2484 } 2485 2486 return ISC_R_SUCCESS; 2487 } 2488 2489 void 2490 mark_phosts_unavailable(void) { 2491 hash_foreach(host_name_hash, mark_phosts_unavailable_support); 2492 } 2493 2494 void 2495 mark_interfaces_unavailable(void) { 2496 struct interface_info *ip; 2497 int i; 2498 struct ipv6_pool *p; 2499 2500 ip = interfaces; 2501 while (ip != NULL) { 2502 for (i=0; i<ip->v6address_count; i++) { 2503 p = NULL; 2504 if (find_ipv6_pool(&p, D6O_IA_NA, &ip->v6addresses[i]) 2505 == ISC_R_SUCCESS) { 2506 mark_lease_unavailable(p, 2507 &ip->v6addresses[i]); 2508 ipv6_pool_dereference(&p, MDL); 2509 } 2510 if (find_ipv6_pool(&p, D6O_IA_TA, &ip->v6addresses[i]) 2511 == ISC_R_SUCCESS) { 2512 mark_lease_unavailable(p, 2513 &ip->v6addresses[i]); 2514 ipv6_pool_dereference(&p, MDL); 2515 } 2516 } 2517 ip = ip->next; 2518 } 2519 } 2520 2521 /*! 2522 * \brief Create a new IPv6 pond structure. 2523 * 2524 * Allocate space for a new ipv6_pond structure and return a reference 2525 * to it, includes setting the reference count to 1. 2526 * 2527 * \param pond = space for returning a referenced pointer to the pond. 2528 * This must point to a space that has been initialzied 2529 * to NULL by the caller. 2530 * 2531 * \return 2532 * ISC_R_SUCCESS = The pond was successfully created, pond points to it. 2533 * DHCP_R_INVALIDARG = One of the arugments was invalid, pond has not been 2534 * modified 2535 * ISC_R_NOMEMORY = The system wasn't able to allocate memory, pond has 2536 * not been modified. 2537 */ 2538 isc_result_t 2539 ipv6_pond_allocate(struct ipv6_pond **pond, const char *file, int line) { 2540 struct ipv6_pond *tmp; 2541 2542 if (pond == NULL) { 2543 log_error("%s(%d): NULL pointer reference", file, line); 2544 return DHCP_R_INVALIDARG; 2545 } 2546 if (*pond != NULL) { 2547 log_error("%s(%d): non-NULL pointer", file, line); 2548 return DHCP_R_INVALIDARG; 2549 } 2550 2551 tmp = dmalloc(sizeof(*tmp), file, line); 2552 if (tmp == NULL) { 2553 return ISC_R_NOMEMORY; 2554 } 2555 2556 tmp->refcnt = 1; 2557 2558 *pond = tmp; 2559 return ISC_R_SUCCESS; 2560 } 2561 2562 /*! 2563 * 2564 * \brief reference an IPv6 pond structure. 2565 * 2566 * This function genreates a reference to an ipv6_pond structure 2567 * and increments the reference count on the structure. 2568 * 2569 * \param[out] pond = space for returning a referenced pointer to the pond. 2570 * This must point to a space that has been initialzied 2571 * to NULL by the caller. 2572 * \param[in] src = A pointer to the pond to reference. This must not be 2573 * NULL. 2574 * 2575 * \return 2576 * ISC_R_SUCCESS = The pond was successfully referenced, pond now points 2577 * to src. 2578 * DHCP_R_INVALIDARG = One of the arugments was invalid, pond has not been 2579 * modified. 2580 */ 2581 isc_result_t 2582 ipv6_pond_reference(struct ipv6_pond **pond, struct ipv6_pond *src, 2583 const char *file, int line) { 2584 if (pond == NULL) { 2585 log_error("%s(%d): NULL pointer reference", file, line); 2586 return DHCP_R_INVALIDARG; 2587 } 2588 if (*pond != NULL) { 2589 log_error("%s(%d): non-NULL pointer", file, line); 2590 return DHCP_R_INVALIDARG; 2591 } 2592 if (src == NULL) { 2593 log_error("%s(%d): NULL pointer reference", file, line); 2594 return DHCP_R_INVALIDARG; 2595 } 2596 *pond = src; 2597 src->refcnt++; 2598 return ISC_R_SUCCESS; 2599 } 2600 2601 /*! 2602 * 2603 * \brief de-reference an IPv6 pond structure. 2604 * 2605 * This function decrements the reference count in an ipv6_pond structure. 2606 * If this was the last reference then the memory for the structure is 2607 * freed. 2608 * 2609 * \param[in] pond = A pointer to the pointer to the pond that should be 2610 * de-referenced. On success the pointer to the pond 2611 * is cleared. It must not be NULL and must not point 2612 * to NULL. 2613 * 2614 * \return 2615 * ISC_R_SUCCESS = The pond was successfully de-referenced, pond now points 2616 * to NULL 2617 * DHCP_R_INVALIDARG = One of the arugments was invalid, pond has not been 2618 * modified. 2619 */ 2620 2621 isc_result_t 2622 ipv6_pond_dereference(struct ipv6_pond **pond, const char *file, int line) { 2623 struct ipv6_pond *tmp; 2624 2625 if ((pond == NULL) || (*pond == NULL)) { 2626 log_error("%s(%d): NULL pointer", file, line); 2627 return DHCP_R_INVALIDARG; 2628 } 2629 2630 tmp = *pond; 2631 *pond = NULL; 2632 2633 tmp->refcnt--; 2634 if (tmp->refcnt < 0) { 2635 log_error("%s(%d): negative refcnt", file, line); 2636 tmp->refcnt = 0; 2637 } 2638 if (tmp->refcnt == 0) { 2639 dfree(tmp, file, line); 2640 } 2641 2642 return ISC_R_SUCCESS; 2643 } 2644 2645 #ifdef EUI_64 2646 /* 2647 * Enables/disables EUI-64 address assignment for a pond 2648 * 2649 * Excecutes statements down to the pond's scope and sets the pond's 2650 * use_eui_64 flag accordingly. In addition it iterates over the 2651 * pond's pools ensuring they are all /64. Anything else is deemed 2652 * invalid for EUI-64. It returns the number of invalid pools 2653 * detected. This is done post-parsing as use-eui-64 can be set 2654 * down to the pool scope and we can't reliably do it until the 2655 * entire configuration has been parsed. 2656 */ 2657 int 2658 set_eui_64(struct ipv6_pond *pond) { 2659 int invalid_cnt = 0; 2660 struct option_state* options = NULL; 2661 struct option_cache *oc = NULL; 2662 option_state_allocate(&options, MDL); 2663 execute_statements_in_scope(NULL, NULL, NULL, NULL, NULL, options, 2664 &global_scope, pond->group, NULL, NULL); 2665 2666 pond->use_eui_64 = 2667 ((oc = lookup_option(&server_universe, options, SV_USE_EUI_64)) 2668 && 2669 (evaluate_boolean_option_cache (NULL, NULL, NULL, NULL, 2670 options, NULL, &global_scope, 2671 oc, MDL))); 2672 if (pond->use_eui_64) { 2673 // Check all pools are valid 2674 int i = 0; 2675 struct ipv6_pool* p; 2676 while((p = pond->ipv6_pools[i++]) != NULL) { 2677 if (p->bits != 64) { 2678 log_error("Pool %s/%d cannot use EUI-64," 2679 " prefix must 64", 2680 pin6_addr(&p->start_addr), p->bits); 2681 invalid_cnt++; 2682 } else { 2683 log_debug("Pool: %s/%d - will use EUI-64", 2684 pin6_addr(&p->start_addr), p->bits); 2685 } 2686 } 2687 } 2688 2689 /* Don't need the options anymore. */ 2690 option_state_dereference(&options, MDL); 2691 return (invalid_cnt); 2692 } 2693 #endif 2694 2695 /* 2696 * Emits a log for each pond that has been flagged as being a "jumbo range" 2697 * A pond is considered a "jumbo range" when the total number of elements 2698 * exceeds the maximum value of POND_TRACK_MAX (currently maximum value 2699 * that can be stored by ipv6_pond.num_total). Since we disable threshold 2700 * logging for jumbo ranges, we need to report this to the user. This 2701 * function allows us to report jumbo ponds after config parsing, so the 2702 * logs can be seen both on the console (-T) and the log facility (i.e syslog). 2703 * 2704 * Note, threshold logging is done at the pond level, so we need emit a list 2705 * of the addresses ranges of the pools in the pond affected. 2706 */ 2707 void 2708 report_jumbo_ranges() { 2709 struct shared_network* s; 2710 char log_buf[1084]; 2711 #ifdef EUI_64 2712 int invalid_cnt = 0; 2713 #endif 2714 2715 /* Loop thru all the networks looking for jumbo range ponds */ 2716 for (s = shared_networks; s; s = s -> next) { 2717 struct ipv6_pond* pond = s->ipv6_pond; 2718 while (pond) { 2719 #ifdef EUI_64 2720 /* while we're here, set the pond's use_eui_64 flag */ 2721 invalid_cnt += set_eui_64(pond); 2722 #endif 2723 /* if its a jumbo and has pools(sanity check) */ 2724 if (pond->jumbo_range == 1 && (pond->ipv6_pools)) { 2725 struct ipv6_pool* pool; 2726 char *bufptr = log_buf; 2727 size_t space_left = sizeof(log_buf) - 1; 2728 int i = 0; 2729 int used = 0; 2730 2731 /* Build list containing the start-address/CIDR 2732 * of each pool */ 2733 *bufptr = '\0'; 2734 while ((pool = pond->ipv6_pools[i++]) && 2735 (space_left > (INET6_ADDRSTRLEN + 6))) { 2736 /* more than one so add a comma */ 2737 if (i > 1) { 2738 *bufptr++ = ','; 2739 *bufptr++ = ' '; 2740 *bufptr = '\0'; 2741 space_left -= 2; 2742 } 2743 2744 /* add the address */ 2745 inet_ntop(AF_INET6, &pool->start_addr, 2746 bufptr, INET6_ADDRSTRLEN); 2747 2748 used = strlen(bufptr); 2749 bufptr += used; 2750 space_left -= used; 2751 2752 /* add the CIDR */ 2753 sprintf (bufptr, "/%d",pool->bits); 2754 used = strlen(bufptr); 2755 bufptr += used; 2756 space_left -= used; 2757 *bufptr = '\0'; 2758 } 2759 2760 log_info("Threshold logging disabled for shared" 2761 " subnet of ranges: %s", log_buf); 2762 } 2763 pond = pond->next; 2764 } 2765 2766 } 2767 2768 #ifdef EUI_64 2769 if (invalid_cnt) { 2770 log_fatal ("%d pool(s) are invalid for EUI-64 use", 2771 invalid_cnt); 2772 } 2773 #endif 2774 } 2775 2776 2777 #ifdef DHCPv6 2778 /* 2779 * \brief Tests that 16-bit hardware type is less than 256 2780 * 2781 * XXX: DHCPv6 gives a 16-bit field for the htype. DHCPv4 gives an 2782 * 8-bit field. To change the semantics of the generic 'hardware' 2783 * structure, we would have to adjust many DHCPv4 sources (from 2784 * interface to DHCPv4 lease code), and we would have to update the 2785 * 'hardware' config directive (probably being reverse compatible and 2786 * providing a new upgrade/replacement primitive). This is a little 2787 * too much to change for now. Hopefully we will revisit this before 2788 * hardware types exceeding 8 bits are assigned. 2789 * 2790 * Uses a static variable to limit log occurence to once per startup 2791 * 2792 * \param htype hardware type value to test 2793 * 2794 * \return returns 0 if the value is too large 2795 * 2796 */ 2797 static int 2798 htype_bounds_check(uint16_t htype) { 2799 static int log_once = 0; 2800 2801 if (htype & 0xFF00) { 2802 if (!log_once) { 2803 log_error("Attention: At least one client advertises a " 2804 "hardware type of %d, which exceeds the software " 2805 "limitation of 255.", htype); 2806 log_once = 1; 2807 } 2808 2809 return(0); 2810 } 2811 2812 return(1); 2813 } 2814 2815 /*! 2816 * \brief Look for hosts by MAC address if it's available 2817 * 2818 * Checks the inbound packet against host declarations which specified: 2819 * 2820 * "hardware ethernet <MAC>;" 2821 * 2822 * For directly connected clients, the function will use the MAC address 2823 * contained in packet:haddr if it's populated. \TODO - While the logic is in 2824 * place for this search, the socket layer does not yet populate packet:haddr, 2825 * this is to be done under rt41523. 2826 * 2827 * For relayed clients, the function will use the MAC address from the 2828 * client-linklayer-address option if it has been supplied by the relay 2829 * directly connected to the client. 2830 * 2831 * \param hp[out] - pointer to storage for the host delcaration if found 2832 * \param packet - received packet 2833 * \param opt_state - option state to search 2834 * \param file - source file 2835 * \param line - line number 2836 * 2837 * \return non-zero if a matching host was found, zero otherwise 2838 */ 2839 static int 2840 find_hosts_by_haddr6(struct host_decl **hp, 2841 struct packet *packet, 2842 struct option_state *opt_state, 2843 const char *file, int line) { 2844 int found = 0; 2845 int htype; 2846 int hlen; 2847 2848 /* For directly connected clients, use packet:haddr if populated */ 2849 if (packet->dhcpv6_container_packet == NULL) { 2850 if (packet->haddr) { 2851 htype = packet->haddr->hbuf[0]; 2852 hlen = packet->haddr->hlen - 1, 2853 log_debug("find_hosts_by_haddr6: using packet->haddr," 2854 " type: %d, len: %d", htype, hlen); 2855 found = find_hosts_by_haddr (hp, htype, 2856 &packet->haddr->hbuf[1], 2857 hlen, MDL); 2858 } 2859 } else { 2860 /* The first container packet is the from the relay directly 2861 * connected to the client. Per RFC 6939, that is only relay 2862 * that may supply the client linklayer address option. */ 2863 struct packet *relay_packet = packet->dhcpv6_container_packet; 2864 struct option_state *relay_state = relay_packet->options; 2865 struct data_string rel_addr; 2866 struct option_cache *oc; 2867 2868 /* Look for the option in the first relay packet */ 2869 oc = lookup_option(&dhcpv6_universe, relay_state, 2870 D6O_CLIENT_LINKLAYER_ADDR); 2871 if (!oc) { 2872 /* Not there, so bail */ 2873 return (0); 2874 } 2875 2876 /* The option is present, fetch the address data */ 2877 memset(&rel_addr, 0, sizeof(rel_addr)); 2878 if (!evaluate_option_cache(&rel_addr, relay_packet, NULL, NULL, 2879 relay_state, NULL, &global_scope, 2880 oc, MDL)) { 2881 log_error("find_hosts_by_add6:" 2882 "Error evaluating option cache"); 2883 return (0); 2884 } 2885 2886 /* The relay address data should be: 2887 * byte 0 - 1 = hardware type 2888 * bytes 2 - hlen = hardware address 2889 * where hlen ( hardware address len) is option data len - 2 */ 2890 hlen = rel_addr.len - 2; 2891 if (hlen > 0 && hlen <= HARDWARE_ADDR_LEN) { 2892 htype = getUShort(rel_addr.data); 2893 if (htype_bounds_check(htype)) { 2894 /* Looks valid, let's search with it */ 2895 log_debug("find_hosts_by_haddr6:" 2896 "using relayed haddr" 2897 " type: %d, len: %d", htype, hlen); 2898 found = find_hosts_by_haddr (hp, htype, 2899 &rel_addr.data[2], 2900 hlen, MDL); 2901 } 2902 } 2903 2904 data_string_forget(&rel_addr, MDL); 2905 } 2906 2907 return (found); 2908 } 2909 2910 /* 2911 * find_host_by_duid_chaddr() synthesizes a DHCPv4-like 'hardware' 2912 * parameter from a DHCPv6 supplied DUID (client-identifier option), 2913 * and may seek to use client or relay supplied hardware addresses. 2914 */ 2915 static int 2916 find_hosts_by_duid_chaddr(struct host_decl **host, 2917 const struct data_string *client_id) { 2918 int htype, hlen; 2919 const unsigned char *chaddr; 2920 2921 /* 2922 * The DUID-LL and DUID-LLT must have a 2-byte DUID type and 2-byte 2923 * htype. 2924 */ 2925 if (client_id->len < 4) 2926 return 0; 2927 2928 /* 2929 * The third and fourth octets of the DUID-LL and DUID-LLT 2930 * is the hardware type, but in 16 bits. 2931 */ 2932 htype = getUShort(client_id->data + 2); 2933 hlen = 0; 2934 chaddr = NULL; 2935 2936 /* The first two octets of the DUID identify the type. */ 2937 switch(getUShort(client_id->data)) { 2938 case DUID_LLT: 2939 if (client_id->len > 8) { 2940 hlen = client_id->len - 8; 2941 chaddr = client_id->data + 8; 2942 } 2943 break; 2944 2945 case DUID_LL: 2946 /* 2947 * Note that client_id->len must be greater than or equal 2948 * to four to get to this point in the function. 2949 */ 2950 hlen = client_id->len - 4; 2951 chaddr = client_id->data + 4; 2952 break; 2953 2954 default: 2955 break; 2956 } 2957 2958 if ((hlen == 0) || (hlen > HARDWARE_ADDR_LEN) || 2959 !htype_bounds_check(htype)) { 2960 return (0); 2961 } 2962 2963 return find_hosts_by_haddr(host, htype, chaddr, hlen, MDL); 2964 } 2965 2966 /* 2967 * \brief Finds a host record that matches the packet, if any 2968 * 2969 * This function centralizes the logic for matching v6 client 2970 * packets to host declarations. We check in the following order 2971 * for matches with: 2972 * 2973 * 1. client_id if specified 2974 * 2. MAC address when explicitly available 2975 * 3. packet option 2976 * 4. synthesized hardware address - this is done last as some 2977 * synthesis methods are not consided to be reliable 2978 * 2979 * \param[out] host - pointer to storage for the located host 2980 * \param packet - inbound client packet 2981 * \param client_id - client identifier (if one) 2982 * \param file - source file 2983 * \param line - source file line number 2984 * \return non-zero if a host is found, zero otherwise 2985 */ 2986 int 2987 find_hosts6(struct host_decl** host, struct packet* packet, 2988 const struct data_string* client_id, char* file, int line) { 2989 return (find_hosts_by_uid(host, client_id->data, client_id->len, MDL) 2990 || find_hosts_by_haddr6(host, packet, packet->options, MDL) 2991 || find_hosts_by_option(host, packet, packet->options, MDL) 2992 || find_hosts_by_duid_chaddr(host, client_id)); 2993 } 2994 #endif 2995 2996 /* unittest moved to server/tests/mdb6_unittest.c */ 2997