1 /* 2 * CDDL HEADER START 3 * 4 * The contents of this file are subject to the terms of the 5 * Common Development and Distribution License (the "License"). 6 * You may not use this file except in compliance with the License. 7 * 8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE 9 * or http://www.opensolaris.org/os/licensing. 10 * See the License for the specific language governing permissions 11 * and limitations under the License. 12 * 13 * When distributing Covered Code, include this CDDL HEADER in each 14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE. 15 * If applicable, add the following below this CDDL HEADER, with the 16 * fields enclosed by brackets "[]" replaced with your own identifying 17 * information: Portions Copyright [yyyy] [name of copyright owner] 18 * 19 * CDDL HEADER END 20 */ 21 22 /* 23 * Copyright 2009 Sun Microsystems, Inc. All rights reserved. 24 * Use is subject to license terms. 25 * Copyright (c) 2016, Joyent, Inc. All rights reserved. 26 */ 27 28 #include <sys/param.h> 29 #include <sys/sysmacros.h> 30 #include <sys/vm.h> 31 #include <sys/proc.h> 32 #include <sys/tuneable.h> 33 #include <sys/systm.h> 34 #include <sys/cmn_err.h> 35 #include <sys/debug.h> 36 #include <sys/sdt.h> 37 #include <sys/mutex.h> 38 #include <sys/bitmap.h> 39 #include <sys/atomic.h> 40 #include <sys/kobj.h> 41 #include <sys/disp.h> 42 #include <vm/seg_kmem.h> 43 #include <sys/zone.h> 44 #include <sys/netstack.h> 45 46 /* 47 * What we use so that the zones framework can tell us about new zones, 48 * which we use to create new stacks. 49 */ 50 static zone_key_t netstack_zone_key; 51 52 static int netstack_initialized = 0; 53 54 /* 55 * Track the registered netstacks. 56 * The global lock protects 57 * - ns_reg 58 * - the list starting at netstack_head and following the netstack_next 59 * pointers. 60 */ 61 static kmutex_t netstack_g_lock; 62 63 /* 64 * Registry of netstacks with their create/shutdown/destory functions. 65 */ 66 static struct netstack_registry ns_reg[NS_MAX]; 67 68 /* 69 * Global list of existing stacks. We use this when a new zone with 70 * an exclusive IP instance is created. 71 * 72 * Note that in some cases a netstack_t needs to stay around after the zone 73 * has gone away. This is because there might be outstanding references 74 * (from TCP TIME_WAIT connections, IPsec state, etc). The netstack_t data 75 * structure and all the foo_stack_t's hanging off of it will be cleaned up 76 * when the last reference to it is dropped. 77 * However, the same zone might be rebooted. That is handled using the 78 * assumption that the zones framework picks a new zoneid each time a zone 79 * is (re)booted. We assert for that condition in netstack_zone_create(). 80 * Thus the old netstack_t can take its time for things to time out. 81 */ 82 static netstack_t *netstack_head; 83 84 /* 85 * To support kstat_create_netstack() using kstat_zone_add we need 86 * to track both 87 * - all zoneids that use the global/shared stack 88 * - all kstats that have been added for the shared stack 89 */ 90 struct shared_zone_list { 91 struct shared_zone_list *sz_next; 92 zoneid_t sz_zoneid; 93 }; 94 95 struct shared_kstat_list { 96 struct shared_kstat_list *sk_next; 97 kstat_t *sk_kstat; 98 }; 99 100 static kmutex_t netstack_shared_lock; /* protects the following two */ 101 static struct shared_zone_list *netstack_shared_zones; 102 static struct shared_kstat_list *netstack_shared_kstats; 103 104 static void *netstack_zone_create(zoneid_t zoneid); 105 static void netstack_zone_shutdown(zoneid_t zoneid, void *arg); 106 static void netstack_zone_destroy(zoneid_t zoneid, void *arg); 107 108 static void netstack_shared_zone_add(zoneid_t zoneid); 109 static void netstack_shared_zone_remove(zoneid_t zoneid); 110 static void netstack_shared_kstat_add(kstat_t *ks); 111 static void netstack_shared_kstat_remove(kstat_t *ks); 112 113 typedef boolean_t applyfn_t(kmutex_t *, netstack_t *, int); 114 115 static void apply_all_netstacks(int, applyfn_t *); 116 static void apply_all_modules(netstack_t *, applyfn_t *); 117 static void apply_all_modules_reverse(netstack_t *, applyfn_t *); 118 static boolean_t netstack_apply_create(kmutex_t *, netstack_t *, int); 119 static boolean_t netstack_apply_shutdown(kmutex_t *, netstack_t *, int); 120 static boolean_t netstack_apply_destroy(kmutex_t *, netstack_t *, int); 121 static boolean_t wait_for_zone_creator(netstack_t *, kmutex_t *); 122 static boolean_t wait_for_nms_inprogress(netstack_t *, nm_state_t *, 123 kmutex_t *); 124 125 void 126 netstack_init(void) 127 { 128 mutex_init(&netstack_g_lock, NULL, MUTEX_DEFAULT, NULL); 129 mutex_init(&netstack_shared_lock, NULL, MUTEX_DEFAULT, NULL); 130 131 netstack_initialized = 1; 132 133 /* 134 * We want to be informed each time a zone is created or 135 * destroyed in the kernel, so we can maintain the 136 * stack instance information. 137 */ 138 zone_key_create(&netstack_zone_key, netstack_zone_create, 139 netstack_zone_shutdown, netstack_zone_destroy); 140 } 141 142 /* 143 * Register a new module with the framework. 144 * This registers interest in changes to the set of netstacks. 145 * The createfn and destroyfn are required, but the shutdownfn can be 146 * NULL. 147 * Note that due to the current zsd implementation, when the create 148 * function is called the zone isn't fully present, thus functions 149 * like zone_find_by_* will fail, hence the create function can not 150 * use many zones kernel functions including zcmn_err(). 151 */ 152 void 153 netstack_register(int moduleid, 154 void *(*module_create)(netstackid_t, netstack_t *), 155 void (*module_shutdown)(netstackid_t, void *), 156 void (*module_destroy)(netstackid_t, void *)) 157 { 158 netstack_t *ns; 159 160 ASSERT(netstack_initialized); 161 ASSERT(moduleid >= 0 && moduleid < NS_MAX); 162 ASSERT(module_create != NULL); 163 164 /* 165 * Make instances created after this point in time run the create 166 * callback. 167 */ 168 mutex_enter(&netstack_g_lock); 169 ASSERT(ns_reg[moduleid].nr_create == NULL); 170 ASSERT(ns_reg[moduleid].nr_flags == 0); 171 ns_reg[moduleid].nr_create = module_create; 172 ns_reg[moduleid].nr_shutdown = module_shutdown; 173 ns_reg[moduleid].nr_destroy = module_destroy; 174 ns_reg[moduleid].nr_flags = NRF_REGISTERED; 175 176 /* 177 * Determine the set of stacks that exist before we drop the lock. 178 * Set NSS_CREATE_NEEDED for each of those. 179 * netstacks which have been deleted will have NSS_CREATE_COMPLETED 180 * set, but check NSF_CLOSING to be sure. 181 */ 182 for (ns = netstack_head; ns != NULL; ns = ns->netstack_next) { 183 nm_state_t *nms = &ns->netstack_m_state[moduleid]; 184 185 mutex_enter(&ns->netstack_lock); 186 if (!(ns->netstack_flags & NSF_CLOSING) && 187 (nms->nms_flags & NSS_CREATE_ALL) == 0) { 188 nms->nms_flags |= NSS_CREATE_NEEDED; 189 DTRACE_PROBE2(netstack__create__needed, 190 netstack_t *, ns, int, moduleid); 191 } 192 mutex_exit(&ns->netstack_lock); 193 } 194 mutex_exit(&netstack_g_lock); 195 196 /* 197 * At this point in time a new instance can be created or an instance 198 * can be destroyed, or some other module can register or unregister. 199 * Make sure we either run all the create functions for this moduleid 200 * or we wait for any other creators for this moduleid. 201 */ 202 apply_all_netstacks(moduleid, netstack_apply_create); 203 } 204 205 void 206 netstack_unregister(int moduleid) 207 { 208 netstack_t *ns; 209 210 ASSERT(moduleid >= 0 && moduleid < NS_MAX); 211 212 ASSERT(ns_reg[moduleid].nr_create != NULL); 213 ASSERT(ns_reg[moduleid].nr_flags & NRF_REGISTERED); 214 215 mutex_enter(&netstack_g_lock); 216 /* 217 * Determine the set of stacks that exist before we drop the lock. 218 * Set NSS_SHUTDOWN_NEEDED and NSS_DESTROY_NEEDED for each of those. 219 * That ensures that when we return all the callbacks for existing 220 * instances have completed. And since we set NRF_DYING no new 221 * instances can use this module. 222 */ 223 for (ns = netstack_head; ns != NULL; ns = ns->netstack_next) { 224 boolean_t created = B_FALSE; 225 nm_state_t *nms = &ns->netstack_m_state[moduleid]; 226 227 mutex_enter(&ns->netstack_lock); 228 229 /* 230 * We need to be careful here. We could actually have a netstack 231 * being created as we speak waiting for us to let go of this 232 * lock to proceed. It may have set NSS_CREATE_NEEDED, but not 233 * have gotten to the point of completing it yet. If 234 * NSS_CREATE_NEEDED, we can safely just remove it here and 235 * never create the module. However, if NSS_CREATE_INPROGRESS is 236 * set, we need to still flag this module for shutdown and 237 * deletion, just as though it had reached NSS_CREATE_COMPLETED. 238 * 239 * It is safe to do that because of two different guarantees 240 * that exist in the system. The first is that before we do a 241 * create, shutdown, or destroy, we ensure that nothing else is 242 * in progress in the system for this netstack and wait for it 243 * to complete. Secondly, because the zone is being created, we 244 * know that the following call to apply_all_netstack will block 245 * on the zone finishing its initialization. 246 */ 247 if (nms->nms_flags & NSS_CREATE_NEEDED) 248 nms->nms_flags &= ~NSS_CREATE_NEEDED; 249 250 if (nms->nms_flags & NSS_CREATE_INPROGRESS || 251 nms->nms_flags & NSS_CREATE_COMPLETED) 252 created = B_TRUE; 253 254 if (ns_reg[moduleid].nr_shutdown != NULL && created && 255 (nms->nms_flags & NSS_CREATE_COMPLETED) && 256 (nms->nms_flags & NSS_SHUTDOWN_ALL) == 0) { 257 nms->nms_flags |= NSS_SHUTDOWN_NEEDED; 258 DTRACE_PROBE2(netstack__shutdown__needed, 259 netstack_t *, ns, int, moduleid); 260 } 261 if ((ns_reg[moduleid].nr_flags & NRF_REGISTERED) && 262 ns_reg[moduleid].nr_destroy != NULL && created && 263 (nms->nms_flags & NSS_DESTROY_ALL) == 0) { 264 nms->nms_flags |= NSS_DESTROY_NEEDED; 265 DTRACE_PROBE2(netstack__destroy__needed, 266 netstack_t *, ns, int, moduleid); 267 } 268 mutex_exit(&ns->netstack_lock); 269 } 270 /* 271 * Prevent any new netstack from calling the registered create 272 * function, while keeping the function pointers in place until the 273 * shutdown and destroy callbacks are complete. 274 */ 275 ns_reg[moduleid].nr_flags |= NRF_DYING; 276 mutex_exit(&netstack_g_lock); 277 278 apply_all_netstacks(moduleid, netstack_apply_shutdown); 279 apply_all_netstacks(moduleid, netstack_apply_destroy); 280 281 /* 282 * Clear the nms_flags so that we can handle this module 283 * being loaded again. 284 * Also remove the registered functions. 285 */ 286 mutex_enter(&netstack_g_lock); 287 ASSERT(ns_reg[moduleid].nr_flags & NRF_REGISTERED); 288 ASSERT(ns_reg[moduleid].nr_flags & NRF_DYING); 289 for (ns = netstack_head; ns != NULL; ns = ns->netstack_next) { 290 nm_state_t *nms = &ns->netstack_m_state[moduleid]; 291 292 mutex_enter(&ns->netstack_lock); 293 if (nms->nms_flags & NSS_DESTROY_COMPLETED) { 294 nms->nms_flags = 0; 295 DTRACE_PROBE2(netstack__destroy__done, 296 netstack_t *, ns, int, moduleid); 297 } 298 mutex_exit(&ns->netstack_lock); 299 } 300 301 ns_reg[moduleid].nr_create = NULL; 302 ns_reg[moduleid].nr_shutdown = NULL; 303 ns_reg[moduleid].nr_destroy = NULL; 304 ns_reg[moduleid].nr_flags = 0; 305 mutex_exit(&netstack_g_lock); 306 } 307 308 /* 309 * Lookup and/or allocate a netstack for this zone. 310 */ 311 static void * 312 netstack_zone_create(zoneid_t zoneid) 313 { 314 netstackid_t stackid; 315 netstack_t *ns; 316 netstack_t **nsp; 317 zone_t *zone; 318 int i; 319 320 ASSERT(netstack_initialized); 321 322 zone = zone_find_by_id_nolock(zoneid); 323 ASSERT(zone != NULL); 324 325 if (zone->zone_flags & ZF_NET_EXCL) { 326 stackid = zoneid; 327 } else { 328 /* Look for the stack instance for the global */ 329 stackid = GLOBAL_NETSTACKID; 330 } 331 332 /* Allocate even if it isn't needed; simplifies locking */ 333 ns = (netstack_t *)kmem_zalloc(sizeof (netstack_t), KM_SLEEP); 334 335 /* Look if there is a matching stack instance */ 336 mutex_enter(&netstack_g_lock); 337 for (nsp = &netstack_head; *nsp != NULL; 338 nsp = &((*nsp)->netstack_next)) { 339 if ((*nsp)->netstack_stackid == stackid) { 340 /* 341 * Should never find a pre-existing exclusive stack 342 */ 343 VERIFY(stackid == GLOBAL_NETSTACKID); 344 kmem_free(ns, sizeof (netstack_t)); 345 ns = *nsp; 346 mutex_enter(&ns->netstack_lock); 347 ns->netstack_numzones++; 348 mutex_exit(&ns->netstack_lock); 349 mutex_exit(&netstack_g_lock); 350 DTRACE_PROBE1(netstack__inc__numzones, 351 netstack_t *, ns); 352 /* Record that we have a new shared stack zone */ 353 netstack_shared_zone_add(zoneid); 354 zone->zone_netstack = ns; 355 return (ns); 356 } 357 } 358 /* Not found */ 359 mutex_init(&ns->netstack_lock, NULL, MUTEX_DEFAULT, NULL); 360 cv_init(&ns->netstack_cv, NULL, CV_DEFAULT, NULL); 361 ns->netstack_stackid = zoneid; 362 ns->netstack_numzones = 1; 363 ns->netstack_refcnt = 1; /* Decremented by netstack_zone_destroy */ 364 ns->netstack_flags = NSF_UNINIT; 365 *nsp = ns; 366 zone->zone_netstack = ns; 367 368 mutex_enter(&ns->netstack_lock); 369 /* 370 * Mark this netstack as having a CREATE running so 371 * any netstack_register/netstack_unregister waits for 372 * the existing create callbacks to complete in moduleid order 373 */ 374 ns->netstack_flags |= NSF_ZONE_CREATE; 375 376 /* 377 * Determine the set of module create functions that need to be 378 * called before we drop the lock. 379 * Set NSS_CREATE_NEEDED for each of those. 380 * Skip any with NRF_DYING set, since those are in the process of 381 * going away, by checking for flags being exactly NRF_REGISTERED. 382 */ 383 for (i = 0; i < NS_MAX; i++) { 384 nm_state_t *nms = &ns->netstack_m_state[i]; 385 386 cv_init(&nms->nms_cv, NULL, CV_DEFAULT, NULL); 387 388 if ((ns_reg[i].nr_flags == NRF_REGISTERED) && 389 (nms->nms_flags & NSS_CREATE_ALL) == 0) { 390 nms->nms_flags |= NSS_CREATE_NEEDED; 391 DTRACE_PROBE2(netstack__create__needed, 392 netstack_t *, ns, int, i); 393 } 394 } 395 mutex_exit(&ns->netstack_lock); 396 mutex_exit(&netstack_g_lock); 397 398 apply_all_modules(ns, netstack_apply_create); 399 400 /* Tell any waiting netstack_register/netstack_unregister to proceed */ 401 mutex_enter(&ns->netstack_lock); 402 ns->netstack_flags &= ~NSF_UNINIT; 403 ASSERT(ns->netstack_flags & NSF_ZONE_CREATE); 404 ns->netstack_flags &= ~NSF_ZONE_CREATE; 405 cv_broadcast(&ns->netstack_cv); 406 mutex_exit(&ns->netstack_lock); 407 408 return (ns); 409 } 410 411 /* ARGSUSED */ 412 static void 413 netstack_zone_shutdown(zoneid_t zoneid, void *arg) 414 { 415 netstack_t *ns = (netstack_t *)arg; 416 int i; 417 418 ASSERT(arg != NULL); 419 420 mutex_enter(&ns->netstack_lock); 421 ASSERT(ns->netstack_numzones > 0); 422 if (ns->netstack_numzones != 1) { 423 /* Stack instance being used by other zone */ 424 mutex_exit(&ns->netstack_lock); 425 ASSERT(ns->netstack_stackid == GLOBAL_NETSTACKID); 426 return; 427 } 428 mutex_exit(&ns->netstack_lock); 429 430 mutex_enter(&netstack_g_lock); 431 mutex_enter(&ns->netstack_lock); 432 /* 433 * Mark this netstack as having a SHUTDOWN running so 434 * any netstack_register/netstack_unregister waits for 435 * the existing create callbacks to complete in moduleid order 436 */ 437 ASSERT(!(ns->netstack_flags & NSF_ZONE_INPROGRESS)); 438 ns->netstack_flags |= NSF_ZONE_SHUTDOWN; 439 440 /* 441 * Determine the set of stacks that exist before we drop the lock. 442 * Set NSS_SHUTDOWN_NEEDED for each of those. 443 */ 444 for (i = 0; i < NS_MAX; i++) { 445 nm_state_t *nms = &ns->netstack_m_state[i]; 446 447 if ((ns_reg[i].nr_flags & NRF_REGISTERED) && 448 ns_reg[i].nr_shutdown != NULL && 449 (nms->nms_flags & NSS_CREATE_COMPLETED) && 450 (nms->nms_flags & NSS_SHUTDOWN_ALL) == 0) { 451 nms->nms_flags |= NSS_SHUTDOWN_NEEDED; 452 DTRACE_PROBE2(netstack__shutdown__needed, 453 netstack_t *, ns, int, i); 454 } 455 } 456 mutex_exit(&ns->netstack_lock); 457 mutex_exit(&netstack_g_lock); 458 459 /* 460 * Call the shutdown function for all registered modules for this 461 * netstack. 462 */ 463 apply_all_modules_reverse(ns, netstack_apply_shutdown); 464 465 /* Tell any waiting netstack_register/netstack_unregister to proceed */ 466 mutex_enter(&ns->netstack_lock); 467 ASSERT(ns->netstack_flags & NSF_ZONE_SHUTDOWN); 468 ns->netstack_flags &= ~NSF_ZONE_SHUTDOWN; 469 cv_broadcast(&ns->netstack_cv); 470 mutex_exit(&ns->netstack_lock); 471 } 472 473 /* 474 * Common routine to release a zone. 475 * If this was the last zone using the stack instance then prepare to 476 * have the refcnt dropping to zero free the zone. 477 */ 478 /* ARGSUSED */ 479 static void 480 netstack_zone_destroy(zoneid_t zoneid, void *arg) 481 { 482 netstack_t *ns = (netstack_t *)arg; 483 484 ASSERT(arg != NULL); 485 486 mutex_enter(&ns->netstack_lock); 487 ASSERT(ns->netstack_numzones > 0); 488 ns->netstack_numzones--; 489 if (ns->netstack_numzones != 0) { 490 /* Stack instance being used by other zone */ 491 mutex_exit(&ns->netstack_lock); 492 ASSERT(ns->netstack_stackid == GLOBAL_NETSTACKID); 493 /* Record that we a shared stack zone has gone away */ 494 netstack_shared_zone_remove(zoneid); 495 return; 496 } 497 /* 498 * Set CLOSING so that netstack_find_by will not find it. 499 */ 500 ns->netstack_flags |= NSF_CLOSING; 501 mutex_exit(&ns->netstack_lock); 502 DTRACE_PROBE1(netstack__dec__numzones, netstack_t *, ns); 503 /* No other thread can call zone_destroy for this stack */ 504 505 /* 506 * Decrease refcnt to account for the one in netstack_zone_init() 507 */ 508 netstack_rele(ns); 509 } 510 511 /* 512 * Called when the reference count drops to zero. 513 * Call the destroy functions for each registered module. 514 */ 515 static void 516 netstack_stack_inactive(netstack_t *ns) 517 { 518 int i; 519 520 mutex_enter(&netstack_g_lock); 521 mutex_enter(&ns->netstack_lock); 522 /* 523 * Mark this netstack as having a DESTROY running so 524 * any netstack_register/netstack_unregister waits for 525 * the existing destroy callbacks to complete in reverse moduleid order 526 */ 527 ASSERT(!(ns->netstack_flags & NSF_ZONE_INPROGRESS)); 528 ns->netstack_flags |= NSF_ZONE_DESTROY; 529 /* 530 * If the shutdown callback wasn't called earlier (e.g., if this is 531 * a netstack shared between multiple zones), then we schedule it now. 532 * 533 * Determine the set of stacks that exist before we drop the lock. 534 * Set NSS_DESTROY_NEEDED for each of those. That 535 * ensures that when we return all the callbacks for existing 536 * instances have completed. 537 */ 538 for (i = 0; i < NS_MAX; i++) { 539 nm_state_t *nms = &ns->netstack_m_state[i]; 540 541 if ((ns_reg[i].nr_flags & NRF_REGISTERED) && 542 ns_reg[i].nr_shutdown != NULL && 543 (nms->nms_flags & NSS_CREATE_COMPLETED) && 544 (nms->nms_flags & NSS_SHUTDOWN_ALL) == 0) { 545 nms->nms_flags |= NSS_SHUTDOWN_NEEDED; 546 DTRACE_PROBE2(netstack__shutdown__needed, 547 netstack_t *, ns, int, i); 548 } 549 550 if ((ns_reg[i].nr_flags & NRF_REGISTERED) && 551 ns_reg[i].nr_destroy != NULL && 552 (nms->nms_flags & NSS_CREATE_COMPLETED) && 553 (nms->nms_flags & NSS_DESTROY_ALL) == 0) { 554 nms->nms_flags |= NSS_DESTROY_NEEDED; 555 DTRACE_PROBE2(netstack__destroy__needed, 556 netstack_t *, ns, int, i); 557 } 558 } 559 mutex_exit(&ns->netstack_lock); 560 mutex_exit(&netstack_g_lock); 561 562 /* 563 * Call the shutdown and destroy functions for all registered modules 564 * for this netstack. 565 * 566 * Since there are some ordering dependencies between the modules we 567 * tear them down in the reverse order of what was used to create them. 568 * 569 * Since a netstack_t is never reused (when a zone is rebooted it gets 570 * a new zoneid == netstackid i.e. a new netstack_t is allocated) we 571 * leave nms_flags the way it is i.e. with NSS_DESTROY_COMPLETED set. 572 * That is different than in the netstack_unregister() case. 573 */ 574 apply_all_modules_reverse(ns, netstack_apply_shutdown); 575 apply_all_modules_reverse(ns, netstack_apply_destroy); 576 577 /* Tell any waiting netstack_register/netstack_unregister to proceed */ 578 mutex_enter(&ns->netstack_lock); 579 ASSERT(ns->netstack_flags & NSF_ZONE_DESTROY); 580 ns->netstack_flags &= ~NSF_ZONE_DESTROY; 581 cv_broadcast(&ns->netstack_cv); 582 mutex_exit(&ns->netstack_lock); 583 } 584 585 /* 586 * Apply a function to all netstacks for a particular moduleid. 587 * 588 * If there is any zone activity (due to a zone being created, shutdown, 589 * or destroyed) we wait for that to complete before we proceed. This ensures 590 * that the moduleids are processed in order when a zone is created or 591 * destroyed. 592 * 593 * The applyfn has to drop netstack_g_lock if it does some work. 594 * In that case we don't follow netstack_next, 595 * even if it is possible to do so without any hazards. This is 596 * because we want the design to allow for the list of netstacks threaded 597 * by netstack_next to change in any arbitrary way during the time the 598 * lock was dropped. 599 * 600 * It is safe to restart the loop at netstack_head since the applyfn 601 * changes netstack_m_state as it processes things, so a subsequent 602 * pass through will have no effect in applyfn, hence the loop will terminate 603 * in at worst O(N^2). 604 */ 605 static void 606 apply_all_netstacks(int moduleid, applyfn_t *applyfn) 607 { 608 netstack_t *ns; 609 610 mutex_enter(&netstack_g_lock); 611 ns = netstack_head; 612 while (ns != NULL) { 613 if (wait_for_zone_creator(ns, &netstack_g_lock)) { 614 /* Lock dropped - restart at head */ 615 ns = netstack_head; 616 } else if ((applyfn)(&netstack_g_lock, ns, moduleid)) { 617 /* Lock dropped - restart at head */ 618 ns = netstack_head; 619 } else { 620 ns = ns->netstack_next; 621 } 622 } 623 mutex_exit(&netstack_g_lock); 624 } 625 626 /* 627 * Apply a function to all moduleids for a particular netstack. 628 * 629 * Since the netstack linkage doesn't matter in this case we can 630 * ignore whether the function drops the lock. 631 */ 632 static void 633 apply_all_modules(netstack_t *ns, applyfn_t *applyfn) 634 { 635 int i; 636 637 mutex_enter(&netstack_g_lock); 638 for (i = 0; i < NS_MAX; i++) { 639 /* 640 * We don't care whether the lock was dropped 641 * since we are not iterating over netstack_head. 642 */ 643 (void) (applyfn)(&netstack_g_lock, ns, i); 644 } 645 mutex_exit(&netstack_g_lock); 646 } 647 648 /* Like the above but in reverse moduleid order */ 649 static void 650 apply_all_modules_reverse(netstack_t *ns, applyfn_t *applyfn) 651 { 652 int i; 653 654 mutex_enter(&netstack_g_lock); 655 for (i = NS_MAX-1; i >= 0; i--) { 656 /* 657 * We don't care whether the lock was dropped 658 * since we are not iterating over netstack_head. 659 */ 660 (void) (applyfn)(&netstack_g_lock, ns, i); 661 } 662 mutex_exit(&netstack_g_lock); 663 } 664 665 /* 666 * Call the create function for the ns and moduleid if CREATE_NEEDED 667 * is set. 668 * If some other thread gets here first and sets *_INPROGRESS, then 669 * we wait for that thread to complete so that we can ensure that 670 * all the callbacks are done when we've looped over all netstacks/moduleids. 671 * 672 * When we call the create function, we temporarily drop the netstack_lock 673 * held by the caller, and return true to tell the caller it needs to 674 * re-evalute the state. 675 */ 676 static boolean_t 677 netstack_apply_create(kmutex_t *lockp, netstack_t *ns, int moduleid) 678 { 679 void *result; 680 netstackid_t stackid; 681 nm_state_t *nms = &ns->netstack_m_state[moduleid]; 682 boolean_t dropped = B_FALSE; 683 684 ASSERT(MUTEX_HELD(lockp)); 685 mutex_enter(&ns->netstack_lock); 686 687 if (wait_for_nms_inprogress(ns, nms, lockp)) 688 dropped = B_TRUE; 689 690 if (nms->nms_flags & NSS_CREATE_NEEDED) { 691 nms->nms_flags &= ~NSS_CREATE_NEEDED; 692 nms->nms_flags |= NSS_CREATE_INPROGRESS; 693 DTRACE_PROBE2(netstack__create__inprogress, 694 netstack_t *, ns, int, moduleid); 695 mutex_exit(&ns->netstack_lock); 696 mutex_exit(lockp); 697 dropped = B_TRUE; 698 699 ASSERT(ns_reg[moduleid].nr_create != NULL); 700 stackid = ns->netstack_stackid; 701 DTRACE_PROBE2(netstack__create__start, 702 netstackid_t, stackid, 703 netstack_t *, ns); 704 result = (ns_reg[moduleid].nr_create)(stackid, ns); 705 DTRACE_PROBE2(netstack__create__end, 706 void *, result, netstack_t *, ns); 707 708 ASSERT(result != NULL); 709 mutex_enter(lockp); 710 mutex_enter(&ns->netstack_lock); 711 ns->netstack_modules[moduleid] = result; 712 nms->nms_flags &= ~NSS_CREATE_INPROGRESS; 713 nms->nms_flags |= NSS_CREATE_COMPLETED; 714 cv_broadcast(&nms->nms_cv); 715 DTRACE_PROBE2(netstack__create__completed, 716 netstack_t *, ns, int, moduleid); 717 mutex_exit(&ns->netstack_lock); 718 return (dropped); 719 } else { 720 mutex_exit(&ns->netstack_lock); 721 return (dropped); 722 } 723 } 724 725 /* 726 * Call the shutdown function for the ns and moduleid if SHUTDOWN_NEEDED 727 * is set. 728 * If some other thread gets here first and sets *_INPROGRESS, then 729 * we wait for that thread to complete so that we can ensure that 730 * all the callbacks are done when we've looped over all netstacks/moduleids. 731 * 732 * When we call the shutdown function, we temporarily drop the netstack_lock 733 * held by the caller, and return true to tell the caller it needs to 734 * re-evalute the state. 735 */ 736 static boolean_t 737 netstack_apply_shutdown(kmutex_t *lockp, netstack_t *ns, int moduleid) 738 { 739 netstackid_t stackid; 740 void * netstack_module; 741 nm_state_t *nms = &ns->netstack_m_state[moduleid]; 742 boolean_t dropped = B_FALSE; 743 744 ASSERT(MUTEX_HELD(lockp)); 745 mutex_enter(&ns->netstack_lock); 746 747 if (wait_for_nms_inprogress(ns, nms, lockp)) 748 dropped = B_TRUE; 749 750 if (nms->nms_flags & NSS_SHUTDOWN_NEEDED) { 751 nms->nms_flags &= ~NSS_SHUTDOWN_NEEDED; 752 nms->nms_flags |= NSS_SHUTDOWN_INPROGRESS; 753 DTRACE_PROBE2(netstack__shutdown__inprogress, 754 netstack_t *, ns, int, moduleid); 755 mutex_exit(&ns->netstack_lock); 756 mutex_exit(lockp); 757 dropped = B_TRUE; 758 759 ASSERT(ns_reg[moduleid].nr_shutdown != NULL); 760 stackid = ns->netstack_stackid; 761 netstack_module = ns->netstack_modules[moduleid]; 762 DTRACE_PROBE2(netstack__shutdown__start, 763 netstackid_t, stackid, 764 void *, netstack_module); 765 (ns_reg[moduleid].nr_shutdown)(stackid, netstack_module); 766 DTRACE_PROBE1(netstack__shutdown__end, 767 netstack_t *, ns); 768 769 mutex_enter(lockp); 770 mutex_enter(&ns->netstack_lock); 771 nms->nms_flags &= ~NSS_SHUTDOWN_INPROGRESS; 772 nms->nms_flags |= NSS_SHUTDOWN_COMPLETED; 773 cv_broadcast(&nms->nms_cv); 774 DTRACE_PROBE2(netstack__shutdown__completed, 775 netstack_t *, ns, int, moduleid); 776 mutex_exit(&ns->netstack_lock); 777 return (dropped); 778 } else { 779 mutex_exit(&ns->netstack_lock); 780 return (dropped); 781 } 782 } 783 784 /* 785 * Call the destroy function for the ns and moduleid if DESTROY_NEEDED 786 * is set. 787 * If some other thread gets here first and sets *_INPROGRESS, then 788 * we wait for that thread to complete so that we can ensure that 789 * all the callbacks are done when we've looped over all netstacks/moduleids. 790 * 791 * When we call the destroy function, we temporarily drop the netstack_lock 792 * held by the caller, and return true to tell the caller it needs to 793 * re-evalute the state. 794 */ 795 static boolean_t 796 netstack_apply_destroy(kmutex_t *lockp, netstack_t *ns, int moduleid) 797 { 798 netstackid_t stackid; 799 void * netstack_module; 800 nm_state_t *nms = &ns->netstack_m_state[moduleid]; 801 boolean_t dropped = B_FALSE; 802 803 ASSERT(MUTEX_HELD(lockp)); 804 mutex_enter(&ns->netstack_lock); 805 806 if (wait_for_nms_inprogress(ns, nms, lockp)) 807 dropped = B_TRUE; 808 809 if (nms->nms_flags & NSS_DESTROY_NEEDED) { 810 nms->nms_flags &= ~NSS_DESTROY_NEEDED; 811 nms->nms_flags |= NSS_DESTROY_INPROGRESS; 812 DTRACE_PROBE2(netstack__destroy__inprogress, 813 netstack_t *, ns, int, moduleid); 814 mutex_exit(&ns->netstack_lock); 815 mutex_exit(lockp); 816 dropped = B_TRUE; 817 818 ASSERT(ns_reg[moduleid].nr_destroy != NULL); 819 stackid = ns->netstack_stackid; 820 netstack_module = ns->netstack_modules[moduleid]; 821 DTRACE_PROBE2(netstack__destroy__start, 822 netstackid_t, stackid, 823 void *, netstack_module); 824 (ns_reg[moduleid].nr_destroy)(stackid, netstack_module); 825 DTRACE_PROBE1(netstack__destroy__end, 826 netstack_t *, ns); 827 828 mutex_enter(lockp); 829 mutex_enter(&ns->netstack_lock); 830 ns->netstack_modules[moduleid] = NULL; 831 nms->nms_flags &= ~NSS_DESTROY_INPROGRESS; 832 nms->nms_flags |= NSS_DESTROY_COMPLETED; 833 cv_broadcast(&nms->nms_cv); 834 DTRACE_PROBE2(netstack__destroy__completed, 835 netstack_t *, ns, int, moduleid); 836 mutex_exit(&ns->netstack_lock); 837 return (dropped); 838 } else { 839 mutex_exit(&ns->netstack_lock); 840 return (dropped); 841 } 842 } 843 844 /* 845 * If somebody is creating the netstack (due to a new zone being created) 846 * then we wait for them to complete. This ensures that any additional 847 * netstack_register() doesn't cause the create functions to run out of 848 * order. 849 * Note that we do not need such a global wait in the case of the shutdown 850 * and destroy callbacks, since in that case it is sufficient for both 851 * threads to set NEEDED and wait for INPROGRESS to ensure ordering. 852 * Returns true if lockp was temporarily dropped while waiting. 853 */ 854 static boolean_t 855 wait_for_zone_creator(netstack_t *ns, kmutex_t *lockp) 856 { 857 boolean_t dropped = B_FALSE; 858 859 mutex_enter(&ns->netstack_lock); 860 while (ns->netstack_flags & NSF_ZONE_CREATE) { 861 DTRACE_PROBE1(netstack__wait__zone__inprogress, 862 netstack_t *, ns); 863 if (lockp != NULL) { 864 dropped = B_TRUE; 865 mutex_exit(lockp); 866 } 867 cv_wait(&ns->netstack_cv, &ns->netstack_lock); 868 if (lockp != NULL) { 869 /* First drop netstack_lock to preserve order */ 870 mutex_exit(&ns->netstack_lock); 871 mutex_enter(lockp); 872 mutex_enter(&ns->netstack_lock); 873 } 874 } 875 mutex_exit(&ns->netstack_lock); 876 return (dropped); 877 } 878 879 /* 880 * Wait for any INPROGRESS flag to be cleared for the netstack/moduleid 881 * combination. 882 * Returns true if lockp was temporarily dropped while waiting. 883 */ 884 static boolean_t 885 wait_for_nms_inprogress(netstack_t *ns, nm_state_t *nms, kmutex_t *lockp) 886 { 887 boolean_t dropped = B_FALSE; 888 889 while (nms->nms_flags & NSS_ALL_INPROGRESS) { 890 DTRACE_PROBE2(netstack__wait__nms__inprogress, 891 netstack_t *, ns, nm_state_t *, nms); 892 if (lockp != NULL) { 893 dropped = B_TRUE; 894 mutex_exit(lockp); 895 } 896 cv_wait(&nms->nms_cv, &ns->netstack_lock); 897 if (lockp != NULL) { 898 /* First drop netstack_lock to preserve order */ 899 mutex_exit(&ns->netstack_lock); 900 mutex_enter(lockp); 901 mutex_enter(&ns->netstack_lock); 902 } 903 } 904 return (dropped); 905 } 906 907 /* 908 * Get the stack instance used in caller's zone. 909 * Increases the reference count, caller must do a netstack_rele. 910 * It can't be called after zone_destroy() has started. 911 */ 912 netstack_t * 913 netstack_get_current(void) 914 { 915 netstack_t *ns; 916 917 ns = curproc->p_zone->zone_netstack; 918 ASSERT(ns != NULL); 919 if (ns->netstack_flags & (NSF_UNINIT|NSF_CLOSING)) 920 return (NULL); 921 922 netstack_hold(ns); 923 924 return (ns); 925 } 926 927 /* 928 * Find a stack instance given the cred. 929 * This is used by the modules to potentially allow for a future when 930 * something other than the zoneid is used to determine the stack. 931 */ 932 netstack_t * 933 netstack_find_by_cred(const cred_t *cr) 934 { 935 zoneid_t zoneid = crgetzoneid(cr); 936 937 /* Handle the case when cr_zone is NULL */ 938 if (zoneid == (zoneid_t)-1) 939 zoneid = GLOBAL_ZONEID; 940 941 /* For performance ... */ 942 if (curproc->p_zone->zone_id == zoneid) 943 return (netstack_get_current()); 944 else 945 return (netstack_find_by_zoneid(zoneid)); 946 } 947 948 /* 949 * Find a stack instance given the zoneid. 950 * Increases the reference count if found; caller must do a 951 * netstack_rele(). 952 * 953 * If there is no exact match then assume the shared stack instance 954 * matches. 955 * 956 * Skip the unitialized ones. 957 */ 958 netstack_t * 959 netstack_find_by_zoneid(zoneid_t zoneid) 960 { 961 netstack_t *ns; 962 zone_t *zone; 963 964 zone = zone_find_by_id(zoneid); 965 966 if (zone == NULL) 967 return (NULL); 968 969 ns = zone->zone_netstack; 970 ASSERT(ns != NULL); 971 if (ns->netstack_flags & (NSF_UNINIT|NSF_CLOSING)) 972 ns = NULL; 973 else 974 netstack_hold(ns); 975 976 zone_rele(zone); 977 return (ns); 978 } 979 980 /* 981 * Find a stack instance given the zoneid. Can only be called from 982 * the create callback. See the comments in zone_find_by_id_nolock why 983 * that limitation exists. 984 * 985 * Increases the reference count if found; caller must do a 986 * netstack_rele(). 987 * 988 * If there is no exact match then assume the shared stack instance 989 * matches. 990 * 991 * Skip the unitialized ones. 992 */ 993 netstack_t * 994 netstack_find_by_zoneid_nolock(zoneid_t zoneid) 995 { 996 netstack_t *ns; 997 zone_t *zone; 998 999 zone = zone_find_by_id_nolock(zoneid); 1000 1001 if (zone == NULL) 1002 return (NULL); 1003 1004 ns = zone->zone_netstack; 1005 ASSERT(ns != NULL); 1006 1007 if (ns->netstack_flags & (NSF_UNINIT|NSF_CLOSING)) 1008 ns = NULL; 1009 else 1010 netstack_hold(ns); 1011 1012 /* zone_find_by_id_nolock does not have a hold on the zone */ 1013 return (ns); 1014 } 1015 1016 /* 1017 * Find a stack instance given the stackid with exact match? 1018 * Increases the reference count if found; caller must do a 1019 * netstack_rele(). 1020 * 1021 * Skip the unitialized ones. 1022 */ 1023 netstack_t * 1024 netstack_find_by_stackid(netstackid_t stackid) 1025 { 1026 netstack_t *ns; 1027 1028 mutex_enter(&netstack_g_lock); 1029 for (ns = netstack_head; ns != NULL; ns = ns->netstack_next) { 1030 mutex_enter(&ns->netstack_lock); 1031 if (ns->netstack_stackid == stackid && 1032 !(ns->netstack_flags & (NSF_UNINIT|NSF_CLOSING))) { 1033 mutex_exit(&ns->netstack_lock); 1034 netstack_hold(ns); 1035 mutex_exit(&netstack_g_lock); 1036 return (ns); 1037 } 1038 mutex_exit(&ns->netstack_lock); 1039 } 1040 mutex_exit(&netstack_g_lock); 1041 return (NULL); 1042 } 1043 1044 boolean_t 1045 netstack_inuse_by_stackid(netstackid_t stackid) 1046 { 1047 netstack_t *ns; 1048 boolean_t rval = B_FALSE; 1049 1050 mutex_enter(&netstack_g_lock); 1051 1052 for (ns = netstack_head; ns != NULL; ns = ns->netstack_next) { 1053 if (ns->netstack_stackid == stackid) { 1054 rval = B_TRUE; 1055 break; 1056 } 1057 } 1058 1059 mutex_exit(&netstack_g_lock); 1060 1061 return (rval); 1062 } 1063 1064 void 1065 netstack_rele(netstack_t *ns) 1066 { 1067 netstack_t **nsp; 1068 boolean_t found; 1069 int refcnt, numzones; 1070 int i; 1071 1072 mutex_enter(&ns->netstack_lock); 1073 ASSERT(ns->netstack_refcnt > 0); 1074 ns->netstack_refcnt--; 1075 /* 1076 * As we drop the lock additional netstack_rele()s can come in 1077 * and decrement the refcnt to zero and free the netstack_t. 1078 * Store pointers in local variables and if we were not the last 1079 * then don't reference the netstack_t after that. 1080 */ 1081 refcnt = ns->netstack_refcnt; 1082 numzones = ns->netstack_numzones; 1083 DTRACE_PROBE1(netstack__dec__ref, netstack_t *, ns); 1084 mutex_exit(&ns->netstack_lock); 1085 1086 if (refcnt == 0 && numzones == 0) { 1087 /* 1088 * Time to call the destroy functions and free up 1089 * the structure 1090 */ 1091 netstack_stack_inactive(ns); 1092 1093 /* Make sure nothing increased the references */ 1094 ASSERT(ns->netstack_refcnt == 0); 1095 ASSERT(ns->netstack_numzones == 0); 1096 1097 /* Finally remove from list of netstacks */ 1098 mutex_enter(&netstack_g_lock); 1099 found = B_FALSE; 1100 for (nsp = &netstack_head; *nsp != NULL; 1101 nsp = &(*nsp)->netstack_next) { 1102 if (*nsp == ns) { 1103 *nsp = ns->netstack_next; 1104 ns->netstack_next = NULL; 1105 found = B_TRUE; 1106 break; 1107 } 1108 } 1109 ASSERT(found); 1110 mutex_exit(&netstack_g_lock); 1111 1112 /* Make sure nothing increased the references */ 1113 ASSERT(ns->netstack_refcnt == 0); 1114 ASSERT(ns->netstack_numzones == 0); 1115 1116 ASSERT(ns->netstack_flags & NSF_CLOSING); 1117 1118 for (i = 0; i < NS_MAX; i++) { 1119 nm_state_t *nms = &ns->netstack_m_state[i]; 1120 1121 cv_destroy(&nms->nms_cv); 1122 } 1123 mutex_destroy(&ns->netstack_lock); 1124 cv_destroy(&ns->netstack_cv); 1125 kmem_free(ns, sizeof (*ns)); 1126 } 1127 } 1128 1129 void 1130 netstack_hold(netstack_t *ns) 1131 { 1132 mutex_enter(&ns->netstack_lock); 1133 ns->netstack_refcnt++; 1134 ASSERT(ns->netstack_refcnt > 0); 1135 mutex_exit(&ns->netstack_lock); 1136 DTRACE_PROBE1(netstack__inc__ref, netstack_t *, ns); 1137 } 1138 1139 /* 1140 * To support kstat_create_netstack() using kstat_zone_add we need 1141 * to track both 1142 * - all zoneids that use the global/shared stack 1143 * - all kstats that have been added for the shared stack 1144 */ 1145 kstat_t * 1146 kstat_create_netstack(char *ks_module, int ks_instance, char *ks_name, 1147 char *ks_class, uchar_t ks_type, uint_t ks_ndata, uchar_t ks_flags, 1148 netstackid_t ks_netstackid) 1149 { 1150 kstat_t *ks; 1151 1152 if (ks_netstackid == GLOBAL_NETSTACKID) { 1153 ks = kstat_create_zone(ks_module, ks_instance, ks_name, 1154 ks_class, ks_type, ks_ndata, ks_flags, GLOBAL_ZONEID); 1155 if (ks != NULL) 1156 netstack_shared_kstat_add(ks); 1157 return (ks); 1158 } else { 1159 zoneid_t zoneid = ks_netstackid; 1160 1161 return (kstat_create_zone(ks_module, ks_instance, ks_name, 1162 ks_class, ks_type, ks_ndata, ks_flags, zoneid)); 1163 } 1164 } 1165 1166 void 1167 kstat_delete_netstack(kstat_t *ks, netstackid_t ks_netstackid) 1168 { 1169 if (ks_netstackid == GLOBAL_NETSTACKID) { 1170 netstack_shared_kstat_remove(ks); 1171 } 1172 kstat_delete(ks); 1173 } 1174 1175 static void 1176 netstack_shared_zone_add(zoneid_t zoneid) 1177 { 1178 struct shared_zone_list *sz; 1179 struct shared_kstat_list *sk; 1180 1181 sz = (struct shared_zone_list *)kmem_zalloc(sizeof (*sz), KM_SLEEP); 1182 sz->sz_zoneid = zoneid; 1183 1184 /* Insert in list */ 1185 mutex_enter(&netstack_shared_lock); 1186 sz->sz_next = netstack_shared_zones; 1187 netstack_shared_zones = sz; 1188 1189 /* 1190 * Perform kstat_zone_add for each existing shared stack kstat. 1191 * Note: Holds netstack_shared_lock lock across kstat_zone_add. 1192 */ 1193 for (sk = netstack_shared_kstats; sk != NULL; sk = sk->sk_next) { 1194 kstat_zone_add(sk->sk_kstat, zoneid); 1195 } 1196 mutex_exit(&netstack_shared_lock); 1197 } 1198 1199 static void 1200 netstack_shared_zone_remove(zoneid_t zoneid) 1201 { 1202 struct shared_zone_list **szp, *sz; 1203 struct shared_kstat_list *sk; 1204 1205 /* Find in list */ 1206 mutex_enter(&netstack_shared_lock); 1207 sz = NULL; 1208 for (szp = &netstack_shared_zones; *szp != NULL; 1209 szp = &((*szp)->sz_next)) { 1210 if ((*szp)->sz_zoneid == zoneid) { 1211 sz = *szp; 1212 break; 1213 } 1214 } 1215 /* We must find it */ 1216 ASSERT(sz != NULL); 1217 *szp = sz->sz_next; 1218 sz->sz_next = NULL; 1219 1220 /* 1221 * Perform kstat_zone_remove for each existing shared stack kstat. 1222 * Note: Holds netstack_shared_lock lock across kstat_zone_remove. 1223 */ 1224 for (sk = netstack_shared_kstats; sk != NULL; sk = sk->sk_next) { 1225 kstat_zone_remove(sk->sk_kstat, zoneid); 1226 } 1227 mutex_exit(&netstack_shared_lock); 1228 1229 kmem_free(sz, sizeof (*sz)); 1230 } 1231 1232 static void 1233 netstack_shared_kstat_add(kstat_t *ks) 1234 { 1235 struct shared_zone_list *sz; 1236 struct shared_kstat_list *sk; 1237 1238 sk = (struct shared_kstat_list *)kmem_zalloc(sizeof (*sk), KM_SLEEP); 1239 sk->sk_kstat = ks; 1240 1241 /* Insert in list */ 1242 mutex_enter(&netstack_shared_lock); 1243 sk->sk_next = netstack_shared_kstats; 1244 netstack_shared_kstats = sk; 1245 1246 /* 1247 * Perform kstat_zone_add for each existing shared stack zone. 1248 * Note: Holds netstack_shared_lock lock across kstat_zone_add. 1249 */ 1250 for (sz = netstack_shared_zones; sz != NULL; sz = sz->sz_next) { 1251 kstat_zone_add(ks, sz->sz_zoneid); 1252 } 1253 mutex_exit(&netstack_shared_lock); 1254 } 1255 1256 static void 1257 netstack_shared_kstat_remove(kstat_t *ks) 1258 { 1259 struct shared_zone_list *sz; 1260 struct shared_kstat_list **skp, *sk; 1261 1262 /* Find in list */ 1263 mutex_enter(&netstack_shared_lock); 1264 sk = NULL; 1265 for (skp = &netstack_shared_kstats; *skp != NULL; 1266 skp = &((*skp)->sk_next)) { 1267 if ((*skp)->sk_kstat == ks) { 1268 sk = *skp; 1269 break; 1270 } 1271 } 1272 /* Must find it */ 1273 ASSERT(sk != NULL); 1274 *skp = sk->sk_next; 1275 sk->sk_next = NULL; 1276 1277 /* 1278 * Perform kstat_zone_remove for each existing shared stack kstat. 1279 * Note: Holds netstack_shared_lock lock across kstat_zone_remove. 1280 */ 1281 for (sz = netstack_shared_zones; sz != NULL; sz = sz->sz_next) { 1282 kstat_zone_remove(ks, sz->sz_zoneid); 1283 } 1284 mutex_exit(&netstack_shared_lock); 1285 kmem_free(sk, sizeof (*sk)); 1286 } 1287 1288 /* 1289 * If a zoneid is part of the shared zone, return true 1290 */ 1291 static boolean_t 1292 netstack_find_shared_zoneid(zoneid_t zoneid) 1293 { 1294 struct shared_zone_list *sz; 1295 1296 mutex_enter(&netstack_shared_lock); 1297 for (sz = netstack_shared_zones; sz != NULL; sz = sz->sz_next) { 1298 if (sz->sz_zoneid == zoneid) { 1299 mutex_exit(&netstack_shared_lock); 1300 return (B_TRUE); 1301 } 1302 } 1303 mutex_exit(&netstack_shared_lock); 1304 return (B_FALSE); 1305 } 1306 1307 /* 1308 * Hide the fact that zoneids and netstackids are allocated from 1309 * the same space in the current implementation. 1310 * We currently do not check that the stackid/zoneids are valid, since there 1311 * is no need for that. But this should only be done for ids that are 1312 * valid. 1313 */ 1314 zoneid_t 1315 netstackid_to_zoneid(netstackid_t stackid) 1316 { 1317 return (stackid); 1318 } 1319 1320 netstackid_t 1321 zoneid_to_netstackid(zoneid_t zoneid) 1322 { 1323 if (netstack_find_shared_zoneid(zoneid)) 1324 return (GLOBAL_ZONEID); 1325 else 1326 return (zoneid); 1327 } 1328 1329 zoneid_t 1330 netstack_get_zoneid(netstack_t *ns) 1331 { 1332 return (netstackid_to_zoneid(ns->netstack_stackid)); 1333 } 1334 1335 /* 1336 * Simplistic support for walking all the handles. 1337 * Example usage: 1338 * netstack_handle_t nh; 1339 * netstack_t *ns; 1340 * 1341 * netstack_next_init(&nh); 1342 * while ((ns = netstack_next(&nh)) != NULL) { 1343 * do something; 1344 * netstack_rele(ns); 1345 * } 1346 * netstack_next_fini(&nh); 1347 */ 1348 void 1349 netstack_next_init(netstack_handle_t *handle) 1350 { 1351 *handle = 0; 1352 } 1353 1354 /* ARGSUSED */ 1355 void 1356 netstack_next_fini(netstack_handle_t *handle) 1357 { 1358 } 1359 1360 netstack_t * 1361 netstack_next(netstack_handle_t *handle) 1362 { 1363 netstack_t *ns; 1364 int i, end; 1365 1366 end = *handle; 1367 /* Walk skipping *handle number of instances */ 1368 1369 /* Look if there is a matching stack instance */ 1370 mutex_enter(&netstack_g_lock); 1371 ns = netstack_head; 1372 for (i = 0; i < end; i++) { 1373 if (ns == NULL) 1374 break; 1375 ns = ns->netstack_next; 1376 } 1377 /* skip those with that aren't really here */ 1378 while (ns != NULL) { 1379 mutex_enter(&ns->netstack_lock); 1380 if ((ns->netstack_flags & (NSF_UNINIT|NSF_CLOSING)) == 0) { 1381 mutex_exit(&ns->netstack_lock); 1382 break; 1383 } 1384 mutex_exit(&ns->netstack_lock); 1385 end++; 1386 ns = ns->netstack_next; 1387 } 1388 if (ns != NULL) { 1389 *handle = end + 1; 1390 netstack_hold(ns); 1391 } 1392 mutex_exit(&netstack_g_lock); 1393 return (ns); 1394 } 1395