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 (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved. 24 * Copyright 2012 Nexenta Systems, Inc. All rights reserved. 25 */ 26 27 #include <sys/param.h> 28 #include <sys/types.h> 29 #include <sys/tzfile.h> 30 #include <sys/atomic.h> 31 #include <sys/kidmap.h> 32 #include <sys/time.h> 33 #include <sys/spl.h> 34 #include <sys/cpuvar.h> 35 #include <sys/random.h> 36 #include <smbsrv/smb_kproto.h> 37 #include <smbsrv/smb_fsops.h> 38 #include <smbsrv/smbinfo.h> 39 #include <smbsrv/smb_xdr.h> 40 #include <smbsrv/smb_vops.h> 41 #include <smbsrv/smb_idmap.h> 42 43 #include <sys/sid.h> 44 #include <sys/priv_names.h> 45 46 static kmem_cache_t *smb_dtor_cache = NULL; 47 48 static boolean_t smb_thread_continue_timedwait_locked(smb_thread_t *, int); 49 50 static boolean_t smb_avl_hold(smb_avl_t *); 51 static void smb_avl_rele(smb_avl_t *); 52 53 time_t tzh_leapcnt = 0; 54 55 struct tm 56 *smb_gmtime_r(time_t *clock, struct tm *result); 57 58 time_t 59 smb_timegm(struct tm *tm); 60 61 struct tm { 62 int tm_sec; 63 int tm_min; 64 int tm_hour; 65 int tm_mday; 66 int tm_mon; 67 int tm_year; 68 int tm_wday; 69 int tm_yday; 70 int tm_isdst; 71 }; 72 73 static const int days_in_month[] = { 74 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 75 }; 76 77 int 78 smb_ascii_or_unicode_strlen(struct smb_request *sr, char *str) 79 { 80 if (sr->smb_flg2 & SMB_FLAGS2_UNICODE) 81 return (smb_wcequiv_strlen(str)); 82 return (strlen(str)); 83 } 84 85 int 86 smb_ascii_or_unicode_strlen_null(struct smb_request *sr, char *str) 87 { 88 if (sr->smb_flg2 & SMB_FLAGS2_UNICODE) 89 return (smb_wcequiv_strlen(str) + 2); 90 return (strlen(str) + 1); 91 } 92 93 int 94 smb_ascii_or_unicode_null_len(struct smb_request *sr) 95 { 96 if (sr->smb_flg2 & SMB_FLAGS2_UNICODE) 97 return (2); 98 return (1); 99 } 100 101 /* 102 * 103 * Convert old-style (DOS, LanMan) wildcard strings to NT style. 104 * This should ONLY happen to patterns that come from old clients, 105 * meaning dialect LANMAN2_1 etc. (dialect < NT_LM_0_12). 106 * 107 * ? is converted to > 108 * * is converted to < if it is followed by . 109 * . is converted to " if it is followed by ? or * or end of pattern 110 * 111 * Note: modifies pattern in place. 112 */ 113 void 114 smb_convert_wildcards(char *pattern) 115 { 116 char *p; 117 118 for (p = pattern; *p != '\0'; p++) { 119 switch (*p) { 120 case '?': 121 *p = '>'; 122 break; 123 case '*': 124 if (p[1] == '.') 125 *p = '<'; 126 break; 127 case '.': 128 if (p[1] == '?' || p[1] == '*' || p[1] == '\0') 129 *p = '\"'; 130 break; 131 } 132 } 133 } 134 135 /* 136 * smb_sattr_check 137 * 138 * Check file attributes against a search attribute (sattr) mask. 139 * 140 * Normal files, which includes READONLY and ARCHIVE, always pass 141 * this check. If the DIRECTORY, HIDDEN or SYSTEM special attributes 142 * are set then they must appear in the search mask. The special 143 * attributes are inclusive, i.e. all special attributes that appear 144 * in sattr must also appear in the file attributes for the check to 145 * pass. 146 * 147 * The following examples show how this works: 148 * 149 * fileA: READONLY 150 * fileB: 0 (no attributes = normal file) 151 * fileC: READONLY, ARCHIVE 152 * fileD: HIDDEN 153 * fileE: READONLY, HIDDEN, SYSTEM 154 * dirA: DIRECTORY 155 * 156 * search attribute: 0 157 * Returns: fileA, fileB and fileC. 158 * search attribute: HIDDEN 159 * Returns: fileA, fileB, fileC and fileD. 160 * search attribute: SYSTEM 161 * Returns: fileA, fileB and fileC. 162 * search attribute: DIRECTORY 163 * Returns: fileA, fileB, fileC and dirA. 164 * search attribute: HIDDEN and SYSTEM 165 * Returns: fileA, fileB, fileC, fileD and fileE. 166 * 167 * Returns true if the file and sattr match; otherwise, returns false. 168 */ 169 boolean_t 170 smb_sattr_check(uint16_t dosattr, uint16_t sattr) 171 { 172 if ((dosattr & FILE_ATTRIBUTE_DIRECTORY) && 173 !(sattr & FILE_ATTRIBUTE_DIRECTORY)) 174 return (B_FALSE); 175 176 if ((dosattr & FILE_ATTRIBUTE_HIDDEN) && 177 !(sattr & FILE_ATTRIBUTE_HIDDEN)) 178 return (B_FALSE); 179 180 if ((dosattr & FILE_ATTRIBUTE_SYSTEM) && 181 !(sattr & FILE_ATTRIBUTE_SYSTEM)) 182 return (B_FALSE); 183 184 return (B_TRUE); 185 } 186 187 int 188 microtime(timestruc_t *tvp) 189 { 190 tvp->tv_sec = gethrestime_sec(); 191 tvp->tv_nsec = 0; 192 return (0); 193 } 194 195 int32_t 196 clock_get_milli_uptime() 197 { 198 return (TICK_TO_MSEC(ddi_get_lbolt())); 199 } 200 201 /* 202 * smb_idpool_increment 203 * 204 * This function increments the ID pool by doubling the current size. This 205 * function assumes the caller entered the mutex of the pool. 206 */ 207 static int 208 smb_idpool_increment( 209 smb_idpool_t *pool) 210 { 211 uint8_t *new_pool; 212 uint32_t new_size; 213 214 ASSERT(pool->id_magic == SMB_IDPOOL_MAGIC); 215 216 new_size = pool->id_size * 2; 217 if (new_size <= SMB_IDPOOL_MAX_SIZE) { 218 new_pool = kmem_alloc(new_size / 8, KM_NOSLEEP); 219 if (new_pool) { 220 bzero(new_pool, new_size / 8); 221 bcopy(pool->id_pool, new_pool, pool->id_size / 8); 222 kmem_free(pool->id_pool, pool->id_size / 8); 223 pool->id_pool = new_pool; 224 pool->id_free_counter += new_size - pool->id_size; 225 pool->id_max_free_counter += new_size - pool->id_size; 226 pool->id_size = new_size; 227 pool->id_idx_msk = (new_size / 8) - 1; 228 if (new_size >= SMB_IDPOOL_MAX_SIZE) { 229 /* id -1 made unavailable */ 230 pool->id_pool[pool->id_idx_msk] = 0x80; 231 pool->id_free_counter--; 232 pool->id_max_free_counter--; 233 } 234 return (0); 235 } 236 } 237 return (-1); 238 } 239 240 /* 241 * smb_idpool_constructor 242 * 243 * This function initializes the pool structure provided. 244 */ 245 int 246 smb_idpool_constructor( 247 smb_idpool_t *pool) 248 { 249 250 ASSERT(pool->id_magic != SMB_IDPOOL_MAGIC); 251 252 pool->id_size = SMB_IDPOOL_MIN_SIZE; 253 pool->id_idx_msk = (SMB_IDPOOL_MIN_SIZE / 8) - 1; 254 pool->id_free_counter = SMB_IDPOOL_MIN_SIZE - 1; 255 pool->id_max_free_counter = SMB_IDPOOL_MIN_SIZE - 1; 256 pool->id_bit = 0x02; 257 pool->id_bit_idx = 1; 258 pool->id_idx = 0; 259 pool->id_pool = (uint8_t *)kmem_alloc((SMB_IDPOOL_MIN_SIZE / 8), 260 KM_SLEEP); 261 bzero(pool->id_pool, (SMB_IDPOOL_MIN_SIZE / 8)); 262 /* -1 id made unavailable */ 263 pool->id_pool[0] = 0x01; /* id 0 made unavailable */ 264 mutex_init(&pool->id_mutex, NULL, MUTEX_DEFAULT, NULL); 265 pool->id_magic = SMB_IDPOOL_MAGIC; 266 return (0); 267 } 268 269 /* 270 * smb_idpool_destructor 271 * 272 * This function tears down and frees the resources associated with the 273 * pool provided. 274 */ 275 void 276 smb_idpool_destructor( 277 smb_idpool_t *pool) 278 { 279 ASSERT(pool->id_magic == SMB_IDPOOL_MAGIC); 280 ASSERT(pool->id_free_counter == pool->id_max_free_counter); 281 pool->id_magic = (uint32_t)~SMB_IDPOOL_MAGIC; 282 mutex_destroy(&pool->id_mutex); 283 kmem_free(pool->id_pool, (size_t)(pool->id_size / 8)); 284 } 285 286 /* 287 * smb_idpool_alloc 288 * 289 * This function allocates an ID from the pool provided. 290 */ 291 int 292 smb_idpool_alloc( 293 smb_idpool_t *pool, 294 uint16_t *id) 295 { 296 uint32_t i; 297 uint8_t bit; 298 uint8_t bit_idx; 299 uint8_t byte; 300 301 ASSERT(pool->id_magic == SMB_IDPOOL_MAGIC); 302 303 mutex_enter(&pool->id_mutex); 304 if ((pool->id_free_counter == 0) && smb_idpool_increment(pool)) { 305 mutex_exit(&pool->id_mutex); 306 return (-1); 307 } 308 309 i = pool->id_size; 310 while (i) { 311 bit = pool->id_bit; 312 bit_idx = pool->id_bit_idx; 313 byte = pool->id_pool[pool->id_idx]; 314 while (bit) { 315 if (byte & bit) { 316 bit = bit << 1; 317 bit_idx++; 318 continue; 319 } 320 pool->id_pool[pool->id_idx] |= bit; 321 *id = (uint16_t)(pool->id_idx * 8 + (uint32_t)bit_idx); 322 pool->id_free_counter--; 323 pool->id_bit = bit; 324 pool->id_bit_idx = bit_idx; 325 mutex_exit(&pool->id_mutex); 326 return (0); 327 } 328 pool->id_bit = 1; 329 pool->id_bit_idx = 0; 330 pool->id_idx++; 331 pool->id_idx &= pool->id_idx_msk; 332 --i; 333 } 334 /* 335 * This section of code shouldn't be reached. If there are IDs 336 * available and none could be found there's a problem. 337 */ 338 ASSERT(0); 339 mutex_exit(&pool->id_mutex); 340 return (-1); 341 } 342 343 /* 344 * smb_idpool_free 345 * 346 * This function frees the ID provided. 347 */ 348 void 349 smb_idpool_free( 350 smb_idpool_t *pool, 351 uint16_t id) 352 { 353 ASSERT(pool->id_magic == SMB_IDPOOL_MAGIC); 354 ASSERT(id != 0); 355 ASSERT(id != 0xFFFF); 356 357 mutex_enter(&pool->id_mutex); 358 if (pool->id_pool[id >> 3] & (1 << (id & 7))) { 359 pool->id_pool[id >> 3] &= ~(1 << (id & 7)); 360 pool->id_free_counter++; 361 ASSERT(pool->id_free_counter <= pool->id_max_free_counter); 362 mutex_exit(&pool->id_mutex); 363 return; 364 } 365 /* Freeing a free ID. */ 366 ASSERT(0); 367 mutex_exit(&pool->id_mutex); 368 } 369 370 /* 371 * Initialize the llist delete queue object cache. 372 */ 373 void 374 smb_llist_init(void) 375 { 376 if (smb_dtor_cache != NULL) 377 return; 378 379 smb_dtor_cache = kmem_cache_create("smb_dtor_cache", 380 sizeof (smb_dtor_t), 8, NULL, NULL, NULL, NULL, NULL, 0); 381 } 382 383 /* 384 * Destroy the llist delete queue object cache. 385 */ 386 void 387 smb_llist_fini(void) 388 { 389 if (smb_dtor_cache != NULL) { 390 kmem_cache_destroy(smb_dtor_cache); 391 smb_dtor_cache = NULL; 392 } 393 } 394 395 /* 396 * smb_llist_constructor 397 * 398 * This function initializes a locked list. 399 */ 400 void 401 smb_llist_constructor( 402 smb_llist_t *ll, 403 size_t size, 404 size_t offset) 405 { 406 rw_init(&ll->ll_lock, NULL, RW_DEFAULT, NULL); 407 mutex_init(&ll->ll_mutex, NULL, MUTEX_DEFAULT, NULL); 408 list_create(&ll->ll_list, size, offset); 409 list_create(&ll->ll_deleteq, sizeof (smb_dtor_t), 410 offsetof(smb_dtor_t, dt_lnd)); 411 ll->ll_count = 0; 412 ll->ll_wrop = 0; 413 ll->ll_deleteq_count = 0; 414 ll->ll_flushing = B_FALSE; 415 } 416 417 /* 418 * Flush the delete queue and destroy a locked list. 419 */ 420 void 421 smb_llist_destructor( 422 smb_llist_t *ll) 423 { 424 smb_llist_flush(ll); 425 426 ASSERT(ll->ll_count == 0); 427 ASSERT(ll->ll_deleteq_count == 0); 428 429 rw_destroy(&ll->ll_lock); 430 list_destroy(&ll->ll_list); 431 list_destroy(&ll->ll_deleteq); 432 mutex_destroy(&ll->ll_mutex); 433 } 434 435 /* 436 * Post an object to the delete queue. The delete queue will be processed 437 * during list exit or list destruction. Objects are often posted for 438 * deletion during list iteration (while the list is locked) but that is 439 * not required, and an object can be posted at any time. 440 */ 441 void 442 smb_llist_post(smb_llist_t *ll, void *object, smb_dtorproc_t dtorproc) 443 { 444 smb_dtor_t *dtor; 445 446 ASSERT((object != NULL) && (dtorproc != NULL)); 447 448 dtor = kmem_cache_alloc(smb_dtor_cache, KM_SLEEP); 449 bzero(dtor, sizeof (smb_dtor_t)); 450 dtor->dt_magic = SMB_DTOR_MAGIC; 451 dtor->dt_object = object; 452 dtor->dt_proc = dtorproc; 453 454 mutex_enter(&ll->ll_mutex); 455 list_insert_tail(&ll->ll_deleteq, dtor); 456 ++ll->ll_deleteq_count; 457 mutex_exit(&ll->ll_mutex); 458 } 459 460 /* 461 * Exit the list lock and process the delete queue. 462 */ 463 void 464 smb_llist_exit(smb_llist_t *ll) 465 { 466 rw_exit(&ll->ll_lock); 467 smb_llist_flush(ll); 468 } 469 470 /* 471 * Flush the list delete queue. The mutex is dropped across the destructor 472 * call in case this leads to additional objects being posted to the delete 473 * queue. 474 */ 475 void 476 smb_llist_flush(smb_llist_t *ll) 477 { 478 smb_dtor_t *dtor; 479 480 mutex_enter(&ll->ll_mutex); 481 if (ll->ll_flushing) { 482 mutex_exit(&ll->ll_mutex); 483 return; 484 } 485 ll->ll_flushing = B_TRUE; 486 487 dtor = list_head(&ll->ll_deleteq); 488 while (dtor != NULL) { 489 SMB_DTOR_VALID(dtor); 490 ASSERT((dtor->dt_object != NULL) && (dtor->dt_proc != NULL)); 491 list_remove(&ll->ll_deleteq, dtor); 492 --ll->ll_deleteq_count; 493 mutex_exit(&ll->ll_mutex); 494 495 dtor->dt_proc(dtor->dt_object); 496 497 dtor->dt_magic = (uint32_t)~SMB_DTOR_MAGIC; 498 kmem_cache_free(smb_dtor_cache, dtor); 499 mutex_enter(&ll->ll_mutex); 500 dtor = list_head(&ll->ll_deleteq); 501 } 502 ll->ll_flushing = B_FALSE; 503 504 mutex_exit(&ll->ll_mutex); 505 } 506 507 /* 508 * smb_llist_upgrade 509 * 510 * This function tries to upgrade the lock of the locked list. It assumes the 511 * locked has already been entered in RW_READER mode. It first tries using the 512 * Solaris function rw_tryupgrade(). If that call fails the lock is released 513 * and reentered in RW_WRITER mode. In that last case a window is opened during 514 * which the contents of the list may have changed. The return code indicates 515 * whether or not the list was modified when the lock was exited. 516 */ 517 int smb_llist_upgrade( 518 smb_llist_t *ll) 519 { 520 uint64_t wrop; 521 522 if (rw_tryupgrade(&ll->ll_lock) != 0) { 523 return (0); 524 } 525 wrop = ll->ll_wrop; 526 rw_exit(&ll->ll_lock); 527 rw_enter(&ll->ll_lock, RW_WRITER); 528 return (wrop != ll->ll_wrop); 529 } 530 531 /* 532 * smb_llist_insert_head 533 * 534 * This function inserts the object passed a the beginning of the list. This 535 * function assumes the lock of the list has already been entered. 536 */ 537 void 538 smb_llist_insert_head( 539 smb_llist_t *ll, 540 void *obj) 541 { 542 list_insert_head(&ll->ll_list, obj); 543 ++ll->ll_wrop; 544 ++ll->ll_count; 545 } 546 547 /* 548 * smb_llist_insert_tail 549 * 550 * This function appends to the object passed to the list. This function assumes 551 * the lock of the list has already been entered. 552 * 553 */ 554 void 555 smb_llist_insert_tail( 556 smb_llist_t *ll, 557 void *obj) 558 { 559 list_insert_tail(&ll->ll_list, obj); 560 ++ll->ll_wrop; 561 ++ll->ll_count; 562 } 563 564 /* 565 * smb_llist_remove 566 * 567 * This function removes the object passed from the list. This function assumes 568 * the lock of the list has already been entered. 569 */ 570 void 571 smb_llist_remove( 572 smb_llist_t *ll, 573 void *obj) 574 { 575 list_remove(&ll->ll_list, obj); 576 ++ll->ll_wrop; 577 --ll->ll_count; 578 } 579 580 /* 581 * smb_llist_get_count 582 * 583 * This function returns the number of elements in the specified list. 584 */ 585 uint32_t 586 smb_llist_get_count( 587 smb_llist_t *ll) 588 { 589 return (ll->ll_count); 590 } 591 592 /* 593 * smb_slist_constructor 594 * 595 * Synchronized list constructor. 596 */ 597 void 598 smb_slist_constructor( 599 smb_slist_t *sl, 600 size_t size, 601 size_t offset) 602 { 603 mutex_init(&sl->sl_mutex, NULL, MUTEX_DEFAULT, NULL); 604 cv_init(&sl->sl_cv, NULL, CV_DEFAULT, NULL); 605 list_create(&sl->sl_list, size, offset); 606 sl->sl_count = 0; 607 sl->sl_waiting = B_FALSE; 608 } 609 610 /* 611 * smb_slist_destructor 612 * 613 * Synchronized list destructor. 614 */ 615 void 616 smb_slist_destructor( 617 smb_slist_t *sl) 618 { 619 VERIFY(sl->sl_count == 0); 620 621 mutex_destroy(&sl->sl_mutex); 622 cv_destroy(&sl->sl_cv); 623 list_destroy(&sl->sl_list); 624 } 625 626 /* 627 * smb_slist_insert_head 628 * 629 * This function inserts the object passed a the beginning of the list. 630 */ 631 void 632 smb_slist_insert_head( 633 smb_slist_t *sl, 634 void *obj) 635 { 636 mutex_enter(&sl->sl_mutex); 637 list_insert_head(&sl->sl_list, obj); 638 ++sl->sl_count; 639 mutex_exit(&sl->sl_mutex); 640 } 641 642 /* 643 * smb_slist_insert_tail 644 * 645 * This function appends the object passed to the list. 646 */ 647 void 648 smb_slist_insert_tail( 649 smb_slist_t *sl, 650 void *obj) 651 { 652 mutex_enter(&sl->sl_mutex); 653 list_insert_tail(&sl->sl_list, obj); 654 ++sl->sl_count; 655 mutex_exit(&sl->sl_mutex); 656 } 657 658 /* 659 * smb_llist_remove 660 * 661 * This function removes the object passed by the caller from the list. 662 */ 663 void 664 smb_slist_remove( 665 smb_slist_t *sl, 666 void *obj) 667 { 668 mutex_enter(&sl->sl_mutex); 669 list_remove(&sl->sl_list, obj); 670 if ((--sl->sl_count == 0) && (sl->sl_waiting)) { 671 sl->sl_waiting = B_FALSE; 672 cv_broadcast(&sl->sl_cv); 673 } 674 mutex_exit(&sl->sl_mutex); 675 } 676 677 /* 678 * smb_slist_move_tail 679 * 680 * This function transfers all the contents of the synchronized list to the 681 * list_t provided. It returns the number of objects transferred. 682 */ 683 uint32_t 684 smb_slist_move_tail( 685 list_t *lst, 686 smb_slist_t *sl) 687 { 688 uint32_t rv; 689 690 mutex_enter(&sl->sl_mutex); 691 rv = sl->sl_count; 692 if (sl->sl_count) { 693 list_move_tail(lst, &sl->sl_list); 694 sl->sl_count = 0; 695 if (sl->sl_waiting) { 696 sl->sl_waiting = B_FALSE; 697 cv_broadcast(&sl->sl_cv); 698 } 699 } 700 mutex_exit(&sl->sl_mutex); 701 return (rv); 702 } 703 704 /* 705 * smb_slist_obj_move 706 * 707 * This function moves an object from one list to the end of the other list. It 708 * assumes the mutex of each list has been entered. 709 */ 710 void 711 smb_slist_obj_move( 712 smb_slist_t *dst, 713 smb_slist_t *src, 714 void *obj) 715 { 716 ASSERT(dst->sl_list.list_offset == src->sl_list.list_offset); 717 ASSERT(dst->sl_list.list_size == src->sl_list.list_size); 718 719 list_remove(&src->sl_list, obj); 720 list_insert_tail(&dst->sl_list, obj); 721 dst->sl_count++; 722 src->sl_count--; 723 if ((src->sl_count == 0) && (src->sl_waiting)) { 724 src->sl_waiting = B_FALSE; 725 cv_broadcast(&src->sl_cv); 726 } 727 } 728 729 /* 730 * smb_slist_wait_for_empty 731 * 732 * This function waits for a list to be emptied. 733 */ 734 void 735 smb_slist_wait_for_empty( 736 smb_slist_t *sl) 737 { 738 mutex_enter(&sl->sl_mutex); 739 while (sl->sl_count) { 740 sl->sl_waiting = B_TRUE; 741 cv_wait(&sl->sl_cv, &sl->sl_mutex); 742 } 743 mutex_exit(&sl->sl_mutex); 744 } 745 746 /* 747 * smb_slist_exit 748 * 749 * This function exits the muetx of the list and signal the condition variable 750 * if the list is empty. 751 */ 752 void 753 smb_slist_exit(smb_slist_t *sl) 754 { 755 if ((sl->sl_count == 0) && (sl->sl_waiting)) { 756 sl->sl_waiting = B_FALSE; 757 cv_broadcast(&sl->sl_cv); 758 } 759 mutex_exit(&sl->sl_mutex); 760 } 761 762 /* 763 * smb_thread_entry_point 764 * 765 * Common entry point for all the threads created through smb_thread_start. 766 * The state of the thread is set to "running" at the beginning and moved to 767 * "exiting" just before calling thread_exit(). The condition variable is 768 * also signaled. 769 */ 770 static void 771 smb_thread_entry_point( 772 smb_thread_t *thread) 773 { 774 ASSERT(thread->sth_magic == SMB_THREAD_MAGIC); 775 mutex_enter(&thread->sth_mtx); 776 ASSERT(thread->sth_state == SMB_THREAD_STATE_STARTING); 777 thread->sth_th = curthread; 778 thread->sth_did = thread->sth_th->t_did; 779 780 if (!thread->sth_kill) { 781 thread->sth_state = SMB_THREAD_STATE_RUNNING; 782 cv_signal(&thread->sth_cv); 783 mutex_exit(&thread->sth_mtx); 784 thread->sth_ep(thread, thread->sth_ep_arg); 785 mutex_enter(&thread->sth_mtx); 786 } 787 thread->sth_th = NULL; 788 thread->sth_state = SMB_THREAD_STATE_EXITING; 789 cv_broadcast(&thread->sth_cv); 790 mutex_exit(&thread->sth_mtx); 791 zthread_exit(); 792 } 793 794 /* 795 * smb_thread_init 796 */ 797 void 798 smb_thread_init( 799 smb_thread_t *thread, 800 char *name, 801 smb_thread_ep_t ep, 802 void *ep_arg, 803 pri_t pri) 804 { 805 ASSERT(thread->sth_magic != SMB_THREAD_MAGIC); 806 807 bzero(thread, sizeof (*thread)); 808 809 (void) strlcpy(thread->sth_name, name, sizeof (thread->sth_name)); 810 thread->sth_ep = ep; 811 thread->sth_ep_arg = ep_arg; 812 thread->sth_state = SMB_THREAD_STATE_EXITED; 813 thread->sth_pri = pri; 814 mutex_init(&thread->sth_mtx, NULL, MUTEX_DEFAULT, NULL); 815 cv_init(&thread->sth_cv, NULL, CV_DEFAULT, NULL); 816 thread->sth_magic = SMB_THREAD_MAGIC; 817 } 818 819 /* 820 * smb_thread_destroy 821 */ 822 void 823 smb_thread_destroy( 824 smb_thread_t *thread) 825 { 826 ASSERT(thread->sth_magic == SMB_THREAD_MAGIC); 827 ASSERT(thread->sth_state == SMB_THREAD_STATE_EXITED); 828 thread->sth_magic = 0; 829 mutex_destroy(&thread->sth_mtx); 830 cv_destroy(&thread->sth_cv); 831 } 832 833 /* 834 * smb_thread_start 835 * 836 * This function starts a thread with the parameters provided. It waits until 837 * the state of the thread has been moved to running. 838 */ 839 /*ARGSUSED*/ 840 int 841 smb_thread_start( 842 smb_thread_t *thread) 843 { 844 int rc = 0; 845 kthread_t *tmpthread; 846 847 ASSERT(thread->sth_magic == SMB_THREAD_MAGIC); 848 849 mutex_enter(&thread->sth_mtx); 850 switch (thread->sth_state) { 851 case SMB_THREAD_STATE_EXITED: 852 thread->sth_state = SMB_THREAD_STATE_STARTING; 853 mutex_exit(&thread->sth_mtx); 854 tmpthread = zthread_create(NULL, 0, smb_thread_entry_point, 855 thread, 0, thread->sth_pri); 856 ASSERT(tmpthread != NULL); 857 mutex_enter(&thread->sth_mtx); 858 while (thread->sth_state == SMB_THREAD_STATE_STARTING) 859 cv_wait(&thread->sth_cv, &thread->sth_mtx); 860 if (thread->sth_state != SMB_THREAD_STATE_RUNNING) 861 rc = -1; 862 break; 863 default: 864 ASSERT(0); 865 rc = -1; 866 break; 867 } 868 mutex_exit(&thread->sth_mtx); 869 return (rc); 870 } 871 872 /* 873 * smb_thread_stop 874 * 875 * This function signals a thread to kill itself and waits until the "exiting" 876 * state has been reached. 877 */ 878 void 879 smb_thread_stop(smb_thread_t *thread) 880 { 881 ASSERT(thread->sth_magic == SMB_THREAD_MAGIC); 882 883 mutex_enter(&thread->sth_mtx); 884 switch (thread->sth_state) { 885 case SMB_THREAD_STATE_RUNNING: 886 case SMB_THREAD_STATE_STARTING: 887 if (!thread->sth_kill) { 888 thread->sth_kill = B_TRUE; 889 cv_broadcast(&thread->sth_cv); 890 while (thread->sth_state != SMB_THREAD_STATE_EXITING) 891 cv_wait(&thread->sth_cv, &thread->sth_mtx); 892 mutex_exit(&thread->sth_mtx); 893 thread_join(thread->sth_did); 894 mutex_enter(&thread->sth_mtx); 895 thread->sth_state = SMB_THREAD_STATE_EXITED; 896 thread->sth_did = 0; 897 thread->sth_kill = B_FALSE; 898 cv_broadcast(&thread->sth_cv); 899 break; 900 } 901 /*FALLTHRU*/ 902 903 case SMB_THREAD_STATE_EXITING: 904 if (thread->sth_kill) { 905 while (thread->sth_state != SMB_THREAD_STATE_EXITED) 906 cv_wait(&thread->sth_cv, &thread->sth_mtx); 907 } else { 908 thread->sth_state = SMB_THREAD_STATE_EXITED; 909 thread->sth_did = 0; 910 } 911 break; 912 913 case SMB_THREAD_STATE_EXITED: 914 break; 915 916 default: 917 ASSERT(0); 918 break; 919 } 920 mutex_exit(&thread->sth_mtx); 921 } 922 923 /* 924 * smb_thread_signal 925 * 926 * This function signals a thread. 927 */ 928 void 929 smb_thread_signal(smb_thread_t *thread) 930 { 931 ASSERT(thread->sth_magic == SMB_THREAD_MAGIC); 932 933 mutex_enter(&thread->sth_mtx); 934 switch (thread->sth_state) { 935 case SMB_THREAD_STATE_RUNNING: 936 cv_signal(&thread->sth_cv); 937 break; 938 939 default: 940 break; 941 } 942 mutex_exit(&thread->sth_mtx); 943 } 944 945 boolean_t 946 smb_thread_continue(smb_thread_t *thread) 947 { 948 boolean_t result; 949 950 ASSERT(thread->sth_magic == SMB_THREAD_MAGIC); 951 952 mutex_enter(&thread->sth_mtx); 953 result = smb_thread_continue_timedwait_locked(thread, 0); 954 mutex_exit(&thread->sth_mtx); 955 956 return (result); 957 } 958 959 boolean_t 960 smb_thread_continue_nowait(smb_thread_t *thread) 961 { 962 boolean_t result; 963 964 ASSERT(thread->sth_magic == SMB_THREAD_MAGIC); 965 966 mutex_enter(&thread->sth_mtx); 967 /* 968 * Setting ticks=-1 requests a non-blocking check. We will 969 * still block if the thread is in "suspend" state. 970 */ 971 result = smb_thread_continue_timedwait_locked(thread, -1); 972 mutex_exit(&thread->sth_mtx); 973 974 return (result); 975 } 976 977 boolean_t 978 smb_thread_continue_timedwait(smb_thread_t *thread, int seconds) 979 { 980 boolean_t result; 981 982 ASSERT(thread->sth_magic == SMB_THREAD_MAGIC); 983 984 mutex_enter(&thread->sth_mtx); 985 result = smb_thread_continue_timedwait_locked(thread, 986 SEC_TO_TICK(seconds)); 987 mutex_exit(&thread->sth_mtx); 988 989 return (result); 990 } 991 992 /* 993 * smb_thread_continue_timedwait_locked 994 * 995 * Internal only. Ticks==-1 means don't block, Ticks == 0 means wait 996 * indefinitely 997 */ 998 static boolean_t 999 smb_thread_continue_timedwait_locked(smb_thread_t *thread, int ticks) 1000 { 1001 boolean_t result; 1002 1003 /* -1 means don't block */ 1004 if (ticks != -1 && !thread->sth_kill) { 1005 if (ticks == 0) { 1006 cv_wait(&thread->sth_cv, &thread->sth_mtx); 1007 } else { 1008 (void) cv_reltimedwait(&thread->sth_cv, 1009 &thread->sth_mtx, (clock_t)ticks, TR_CLOCK_TICK); 1010 } 1011 } 1012 result = (thread->sth_kill == 0); 1013 1014 return (result); 1015 } 1016 1017 /* 1018 * smb_rwx_init 1019 */ 1020 void 1021 smb_rwx_init( 1022 smb_rwx_t *rwx) 1023 { 1024 bzero(rwx, sizeof (smb_rwx_t)); 1025 cv_init(&rwx->rwx_cv, NULL, CV_DEFAULT, NULL); 1026 mutex_init(&rwx->rwx_mutex, NULL, MUTEX_DEFAULT, NULL); 1027 rw_init(&rwx->rwx_lock, NULL, RW_DEFAULT, NULL); 1028 } 1029 1030 /* 1031 * smb_rwx_destroy 1032 */ 1033 void 1034 smb_rwx_destroy( 1035 smb_rwx_t *rwx) 1036 { 1037 mutex_destroy(&rwx->rwx_mutex); 1038 cv_destroy(&rwx->rwx_cv); 1039 rw_destroy(&rwx->rwx_lock); 1040 } 1041 1042 /* 1043 * smb_rwx_rwexit 1044 */ 1045 void 1046 smb_rwx_rwexit( 1047 smb_rwx_t *rwx) 1048 { 1049 if (rw_write_held(&rwx->rwx_lock)) { 1050 ASSERT(rw_owner(&rwx->rwx_lock) == curthread); 1051 mutex_enter(&rwx->rwx_mutex); 1052 if (rwx->rwx_waiting) { 1053 rwx->rwx_waiting = B_FALSE; 1054 cv_broadcast(&rwx->rwx_cv); 1055 } 1056 mutex_exit(&rwx->rwx_mutex); 1057 } 1058 rw_exit(&rwx->rwx_lock); 1059 } 1060 1061 /* 1062 * smb_rwx_rwupgrade 1063 */ 1064 krw_t 1065 smb_rwx_rwupgrade( 1066 smb_rwx_t *rwx) 1067 { 1068 if (rw_write_held(&rwx->rwx_lock)) { 1069 ASSERT(rw_owner(&rwx->rwx_lock) == curthread); 1070 return (RW_WRITER); 1071 } 1072 if (!rw_tryupgrade(&rwx->rwx_lock)) { 1073 rw_exit(&rwx->rwx_lock); 1074 rw_enter(&rwx->rwx_lock, RW_WRITER); 1075 } 1076 return (RW_READER); 1077 } 1078 1079 /* 1080 * smb_rwx_rwrestore 1081 */ 1082 void 1083 smb_rwx_rwdowngrade( 1084 smb_rwx_t *rwx, 1085 krw_t mode) 1086 { 1087 ASSERT(rw_write_held(&rwx->rwx_lock)); 1088 ASSERT(rw_owner(&rwx->rwx_lock) == curthread); 1089 1090 if (mode == RW_WRITER) { 1091 return; 1092 } 1093 ASSERT(mode == RW_READER); 1094 mutex_enter(&rwx->rwx_mutex); 1095 if (rwx->rwx_waiting) { 1096 rwx->rwx_waiting = B_FALSE; 1097 cv_broadcast(&rwx->rwx_cv); 1098 } 1099 mutex_exit(&rwx->rwx_mutex); 1100 rw_downgrade(&rwx->rwx_lock); 1101 } 1102 1103 /* 1104 * smb_rwx_wait 1105 * 1106 * This function assumes the smb_rwx lock was enter in RW_READER or RW_WRITER 1107 * mode. It will: 1108 * 1109 * 1) release the lock and save its current mode. 1110 * 2) wait until the condition variable is signaled. This can happen for 1111 * 2 reasons: When a writer releases the lock or when the time out (if 1112 * provided) expires. 1113 * 3) re-acquire the lock in the mode saved in (1). 1114 */ 1115 int 1116 smb_rwx_rwwait( 1117 smb_rwx_t *rwx, 1118 clock_t timeout) 1119 { 1120 int rc; 1121 krw_t mode; 1122 1123 mutex_enter(&rwx->rwx_mutex); 1124 rwx->rwx_waiting = B_TRUE; 1125 mutex_exit(&rwx->rwx_mutex); 1126 1127 if (rw_write_held(&rwx->rwx_lock)) { 1128 ASSERT(rw_owner(&rwx->rwx_lock) == curthread); 1129 mode = RW_WRITER; 1130 } else { 1131 ASSERT(rw_read_held(&rwx->rwx_lock)); 1132 mode = RW_READER; 1133 } 1134 rw_exit(&rwx->rwx_lock); 1135 1136 mutex_enter(&rwx->rwx_mutex); 1137 if (rwx->rwx_waiting) { 1138 if (timeout == -1) { 1139 rc = 1; 1140 cv_wait(&rwx->rwx_cv, &rwx->rwx_mutex); 1141 } else { 1142 rc = cv_reltimedwait(&rwx->rwx_cv, &rwx->rwx_mutex, 1143 timeout, TR_CLOCK_TICK); 1144 } 1145 } 1146 mutex_exit(&rwx->rwx_mutex); 1147 1148 rw_enter(&rwx->rwx_lock, mode); 1149 return (rc); 1150 } 1151 1152 /* 1153 * SMB ID mapping 1154 * 1155 * Solaris ID mapping service (aka Winchester) works with domain SIDs 1156 * and RIDs where domain SIDs are in string format. CIFS service works 1157 * with binary SIDs understandable by CIFS clients. A layer of SMB ID 1158 * mapping functions are implemeted to hide the SID conversion details 1159 * and also hide the handling of array of batch mapping requests. 1160 * 1161 * IMPORTANT NOTE The Winchester API requires a zone. Because CIFS server 1162 * currently only runs in the global zone the global zone is specified. 1163 * This needs to be fixed when the CIFS server supports zones. 1164 */ 1165 1166 static int smb_idmap_batch_binsid(smb_idmap_batch_t *sib); 1167 1168 /* 1169 * smb_idmap_getid 1170 * 1171 * Maps the given Windows SID to a Solaris ID using the 1172 * simple mapping API. 1173 */ 1174 idmap_stat 1175 smb_idmap_getid(smb_sid_t *sid, uid_t *id, int *idtype) 1176 { 1177 smb_idmap_t sim; 1178 char sidstr[SMB_SID_STRSZ]; 1179 1180 smb_sid_tostr(sid, sidstr); 1181 if (smb_sid_splitstr(sidstr, &sim.sim_rid) != 0) 1182 return (IDMAP_ERR_SID); 1183 sim.sim_domsid = sidstr; 1184 sim.sim_id = id; 1185 1186 switch (*idtype) { 1187 case SMB_IDMAP_USER: 1188 sim.sim_stat = kidmap_getuidbysid(global_zone, sim.sim_domsid, 1189 sim.sim_rid, sim.sim_id); 1190 break; 1191 1192 case SMB_IDMAP_GROUP: 1193 sim.sim_stat = kidmap_getgidbysid(global_zone, sim.sim_domsid, 1194 sim.sim_rid, sim.sim_id); 1195 break; 1196 1197 case SMB_IDMAP_UNKNOWN: 1198 sim.sim_stat = kidmap_getpidbysid(global_zone, sim.sim_domsid, 1199 sim.sim_rid, sim.sim_id, &sim.sim_idtype); 1200 break; 1201 1202 default: 1203 ASSERT(0); 1204 return (IDMAP_ERR_ARG); 1205 } 1206 1207 *idtype = sim.sim_idtype; 1208 1209 return (sim.sim_stat); 1210 } 1211 1212 /* 1213 * smb_idmap_getsid 1214 * 1215 * Maps the given Solaris ID to a Windows SID using the 1216 * simple mapping API. 1217 */ 1218 idmap_stat 1219 smb_idmap_getsid(uid_t id, int idtype, smb_sid_t **sid) 1220 { 1221 smb_idmap_t sim; 1222 1223 switch (idtype) { 1224 case SMB_IDMAP_USER: 1225 sim.sim_stat = kidmap_getsidbyuid(global_zone, id, 1226 (const char **)&sim.sim_domsid, &sim.sim_rid); 1227 break; 1228 1229 case SMB_IDMAP_GROUP: 1230 sim.sim_stat = kidmap_getsidbygid(global_zone, id, 1231 (const char **)&sim.sim_domsid, &sim.sim_rid); 1232 break; 1233 1234 case SMB_IDMAP_EVERYONE: 1235 /* Everyone S-1-1-0 */ 1236 sim.sim_domsid = "S-1-1"; 1237 sim.sim_rid = 0; 1238 sim.sim_stat = IDMAP_SUCCESS; 1239 break; 1240 1241 default: 1242 ASSERT(0); 1243 return (IDMAP_ERR_ARG); 1244 } 1245 1246 if (sim.sim_stat != IDMAP_SUCCESS) 1247 return (sim.sim_stat); 1248 1249 if (sim.sim_domsid == NULL) 1250 return (IDMAP_ERR_NOMAPPING); 1251 1252 sim.sim_sid = smb_sid_fromstr(sim.sim_domsid); 1253 if (sim.sim_sid == NULL) 1254 return (IDMAP_ERR_INTERNAL); 1255 1256 *sid = smb_sid_splice(sim.sim_sid, sim.sim_rid); 1257 smb_sid_free(sim.sim_sid); 1258 if (*sid == NULL) 1259 sim.sim_stat = IDMAP_ERR_INTERNAL; 1260 1261 return (sim.sim_stat); 1262 } 1263 1264 /* 1265 * smb_idmap_batch_create 1266 * 1267 * Creates and initializes the context for batch ID mapping. 1268 */ 1269 idmap_stat 1270 smb_idmap_batch_create(smb_idmap_batch_t *sib, uint16_t nmap, int flags) 1271 { 1272 ASSERT(sib); 1273 1274 bzero(sib, sizeof (smb_idmap_batch_t)); 1275 1276 sib->sib_idmaph = kidmap_get_create(global_zone); 1277 1278 sib->sib_flags = flags; 1279 sib->sib_nmap = nmap; 1280 sib->sib_size = nmap * sizeof (smb_idmap_t); 1281 sib->sib_maps = kmem_zalloc(sib->sib_size, KM_SLEEP); 1282 1283 return (IDMAP_SUCCESS); 1284 } 1285 1286 /* 1287 * smb_idmap_batch_destroy 1288 * 1289 * Frees the batch ID mapping context. 1290 * If ID mapping is Solaris -> Windows it frees memories 1291 * allocated for binary SIDs. 1292 */ 1293 void 1294 smb_idmap_batch_destroy(smb_idmap_batch_t *sib) 1295 { 1296 char *domsid; 1297 int i; 1298 1299 ASSERT(sib); 1300 ASSERT(sib->sib_maps); 1301 1302 if (sib->sib_idmaph) 1303 kidmap_get_destroy(sib->sib_idmaph); 1304 1305 if (sib->sib_flags & SMB_IDMAP_ID2SID) { 1306 /* 1307 * SIDs are allocated only when mapping 1308 * UID/GID to SIDs 1309 */ 1310 for (i = 0; i < sib->sib_nmap; i++) 1311 smb_sid_free(sib->sib_maps[i].sim_sid); 1312 } else if (sib->sib_flags & SMB_IDMAP_SID2ID) { 1313 /* 1314 * SID prefixes are allocated only when mapping 1315 * SIDs to UID/GID 1316 */ 1317 for (i = 0; i < sib->sib_nmap; i++) { 1318 domsid = sib->sib_maps[i].sim_domsid; 1319 if (domsid) 1320 smb_mem_free(domsid); 1321 } 1322 } 1323 1324 if (sib->sib_size && sib->sib_maps) 1325 kmem_free(sib->sib_maps, sib->sib_size); 1326 } 1327 1328 /* 1329 * smb_idmap_batch_getid 1330 * 1331 * Queue a request to map the given SID to a UID or GID. 1332 * 1333 * sim->sim_id should point to variable that's supposed to 1334 * hold the returned UID/GID. This needs to be setup by caller 1335 * of this function. 1336 * 1337 * If requested ID type is known, it's passed as 'idtype', 1338 * if it's unknown it'll be returned in sim->sim_idtype. 1339 */ 1340 idmap_stat 1341 smb_idmap_batch_getid(idmap_get_handle_t *idmaph, smb_idmap_t *sim, 1342 smb_sid_t *sid, int idtype) 1343 { 1344 char strsid[SMB_SID_STRSZ]; 1345 idmap_stat idm_stat; 1346 1347 ASSERT(idmaph); 1348 ASSERT(sim); 1349 ASSERT(sid); 1350 1351 smb_sid_tostr(sid, strsid); 1352 if (smb_sid_splitstr(strsid, &sim->sim_rid) != 0) 1353 return (IDMAP_ERR_SID); 1354 sim->sim_domsid = smb_mem_strdup(strsid); 1355 1356 switch (idtype) { 1357 case SMB_IDMAP_USER: 1358 idm_stat = kidmap_batch_getuidbysid(idmaph, sim->sim_domsid, 1359 sim->sim_rid, sim->sim_id, &sim->sim_stat); 1360 break; 1361 1362 case SMB_IDMAP_GROUP: 1363 idm_stat = kidmap_batch_getgidbysid(idmaph, sim->sim_domsid, 1364 sim->sim_rid, sim->sim_id, &sim->sim_stat); 1365 break; 1366 1367 case SMB_IDMAP_UNKNOWN: 1368 idm_stat = kidmap_batch_getpidbysid(idmaph, sim->sim_domsid, 1369 sim->sim_rid, sim->sim_id, &sim->sim_idtype, 1370 &sim->sim_stat); 1371 break; 1372 1373 default: 1374 ASSERT(0); 1375 return (IDMAP_ERR_ARG); 1376 } 1377 1378 return (idm_stat); 1379 } 1380 1381 /* 1382 * smb_idmap_batch_getsid 1383 * 1384 * Queue a request to map the given UID/GID to a SID. 1385 * 1386 * sim->sim_domsid and sim->sim_rid will contain the mapping 1387 * result upon successful process of the batched request. 1388 */ 1389 idmap_stat 1390 smb_idmap_batch_getsid(idmap_get_handle_t *idmaph, smb_idmap_t *sim, 1391 uid_t id, int idtype) 1392 { 1393 idmap_stat idm_stat; 1394 1395 switch (idtype) { 1396 case SMB_IDMAP_USER: 1397 idm_stat = kidmap_batch_getsidbyuid(idmaph, id, 1398 (const char **)&sim->sim_domsid, &sim->sim_rid, 1399 &sim->sim_stat); 1400 break; 1401 1402 case SMB_IDMAP_GROUP: 1403 idm_stat = kidmap_batch_getsidbygid(idmaph, id, 1404 (const char **)&sim->sim_domsid, &sim->sim_rid, 1405 &sim->sim_stat); 1406 break; 1407 1408 case SMB_IDMAP_OWNERAT: 1409 /* Current Owner S-1-5-32-766 */ 1410 sim->sim_domsid = NT_BUILTIN_DOMAIN_SIDSTR; 1411 sim->sim_rid = SECURITY_CURRENT_OWNER_RID; 1412 sim->sim_stat = IDMAP_SUCCESS; 1413 idm_stat = IDMAP_SUCCESS; 1414 break; 1415 1416 case SMB_IDMAP_GROUPAT: 1417 /* Current Group S-1-5-32-767 */ 1418 sim->sim_domsid = NT_BUILTIN_DOMAIN_SIDSTR; 1419 sim->sim_rid = SECURITY_CURRENT_GROUP_RID; 1420 sim->sim_stat = IDMAP_SUCCESS; 1421 idm_stat = IDMAP_SUCCESS; 1422 break; 1423 1424 case SMB_IDMAP_EVERYONE: 1425 /* Everyone S-1-1-0 */ 1426 sim->sim_domsid = NT_WORLD_AUTH_SIDSTR; 1427 sim->sim_rid = 0; 1428 sim->sim_stat = IDMAP_SUCCESS; 1429 idm_stat = IDMAP_SUCCESS; 1430 break; 1431 1432 default: 1433 ASSERT(0); 1434 return (IDMAP_ERR_ARG); 1435 } 1436 1437 return (idm_stat); 1438 } 1439 1440 /* 1441 * smb_idmap_batch_binsid 1442 * 1443 * Convert sidrids to binary sids 1444 * 1445 * Returns 0 if successful and non-zero upon failure. 1446 */ 1447 static int 1448 smb_idmap_batch_binsid(smb_idmap_batch_t *sib) 1449 { 1450 smb_sid_t *sid; 1451 smb_idmap_t *sim; 1452 int i; 1453 1454 if (sib->sib_flags & SMB_IDMAP_SID2ID) 1455 /* This operation is not required */ 1456 return (0); 1457 1458 sim = sib->sib_maps; 1459 for (i = 0; i < sib->sib_nmap; sim++, i++) { 1460 ASSERT(sim->sim_domsid); 1461 if (sim->sim_domsid == NULL) 1462 return (1); 1463 1464 if ((sid = smb_sid_fromstr(sim->sim_domsid)) == NULL) 1465 return (1); 1466 1467 sim->sim_sid = smb_sid_splice(sid, sim->sim_rid); 1468 smb_sid_free(sid); 1469 } 1470 1471 return (0); 1472 } 1473 1474 /* 1475 * smb_idmap_batch_getmappings 1476 * 1477 * trigger ID mapping service to get the mappings for queued 1478 * requests. 1479 * 1480 * Checks the result of all the queued requests. 1481 * If this is a Solaris -> Windows mapping it generates 1482 * binary SIDs from returned (domsid, rid) pairs. 1483 */ 1484 idmap_stat 1485 smb_idmap_batch_getmappings(smb_idmap_batch_t *sib) 1486 { 1487 idmap_stat idm_stat = IDMAP_SUCCESS; 1488 int i; 1489 1490 idm_stat = kidmap_get_mappings(sib->sib_idmaph); 1491 if (idm_stat != IDMAP_SUCCESS) 1492 return (idm_stat); 1493 1494 /* 1495 * Check the status for all the queued requests 1496 */ 1497 for (i = 0; i < sib->sib_nmap; i++) { 1498 if (sib->sib_maps[i].sim_stat != IDMAP_SUCCESS) 1499 return (sib->sib_maps[i].sim_stat); 1500 } 1501 1502 if (smb_idmap_batch_binsid(sib) != 0) 1503 idm_stat = IDMAP_ERR_OTHER; 1504 1505 return (idm_stat); 1506 } 1507 1508 uint64_t 1509 smb_time_unix_to_nt(timestruc_t *unix_time) 1510 { 1511 uint64_t nt_time; 1512 1513 if ((unix_time->tv_sec == 0) && (unix_time->tv_nsec == 0)) 1514 return (0); 1515 1516 nt_time = unix_time->tv_sec; 1517 nt_time *= 10000000; /* seconds to 100ns */ 1518 nt_time += unix_time->tv_nsec / 100; 1519 return (nt_time + NT_TIME_BIAS); 1520 } 1521 1522 void 1523 smb_time_nt_to_unix(uint64_t nt_time, timestruc_t *unix_time) 1524 { 1525 uint32_t seconds; 1526 1527 ASSERT(unix_time); 1528 1529 if ((nt_time == 0) || (nt_time == -1)) { 1530 unix_time->tv_sec = 0; 1531 unix_time->tv_nsec = 0; 1532 return; 1533 } 1534 1535 nt_time -= NT_TIME_BIAS; 1536 seconds = nt_time / 10000000; 1537 unix_time->tv_sec = seconds; 1538 unix_time->tv_nsec = (nt_time % 10000000) * 100; 1539 } 1540 1541 /* 1542 * smb_time_gmt_to_local, smb_time_local_to_gmt 1543 * 1544 * Apply the gmt offset to convert between local time and gmt 1545 */ 1546 int32_t 1547 smb_time_gmt_to_local(smb_request_t *sr, int32_t gmt) 1548 { 1549 if ((gmt == 0) || (gmt == -1)) 1550 return (0); 1551 1552 return (gmt - sr->sr_gmtoff); 1553 } 1554 1555 int32_t 1556 smb_time_local_to_gmt(smb_request_t *sr, int32_t local) 1557 { 1558 if ((local == 0) || (local == -1)) 1559 return (0); 1560 1561 return (local + sr->sr_gmtoff); 1562 } 1563 1564 1565 /* 1566 * smb_time_dos_to_unix 1567 * 1568 * Convert SMB_DATE & SMB_TIME values to a unix timestamp. 1569 * 1570 * A date/time field of 0 means that that server file system 1571 * assigned value need not be changed. The behaviour when the 1572 * date/time field is set to -1 is not documented but is 1573 * generally treated like 0. 1574 * If date or time is 0 or -1 the unix time is returned as 0 1575 * so that the caller can identify and handle this special case. 1576 */ 1577 int32_t 1578 smb_time_dos_to_unix(int16_t date, int16_t time) 1579 { 1580 struct tm atm; 1581 1582 if (((date == 0) || (time == 0)) || 1583 ((date == -1) || (time == -1))) { 1584 return (0); 1585 } 1586 1587 atm.tm_year = ((date >> 9) & 0x3F) + 80; 1588 atm.tm_mon = ((date >> 5) & 0x0F) - 1; 1589 atm.tm_mday = ((date >> 0) & 0x1F); 1590 atm.tm_hour = ((time >> 11) & 0x1F); 1591 atm.tm_min = ((time >> 5) & 0x3F); 1592 atm.tm_sec = ((time >> 0) & 0x1F) << 1; 1593 1594 return (smb_timegm(&atm)); 1595 } 1596 1597 void 1598 smb_time_unix_to_dos(int32_t ux_time, int16_t *date_p, int16_t *time_p) 1599 { 1600 struct tm atm; 1601 int i; 1602 time_t tmp_time; 1603 1604 if (ux_time == 0) { 1605 *date_p = 0; 1606 *time_p = 0; 1607 return; 1608 } 1609 1610 tmp_time = (time_t)ux_time; 1611 (void) smb_gmtime_r(&tmp_time, &atm); 1612 1613 if (date_p) { 1614 i = 0; 1615 i += atm.tm_year - 80; 1616 i <<= 4; 1617 i += atm.tm_mon + 1; 1618 i <<= 5; 1619 i += atm.tm_mday; 1620 1621 *date_p = (short)i; 1622 } 1623 if (time_p) { 1624 i = 0; 1625 i += atm.tm_hour; 1626 i <<= 6; 1627 i += atm.tm_min; 1628 i <<= 5; 1629 i += atm.tm_sec >> 1; 1630 1631 *time_p = (short)i; 1632 } 1633 } 1634 1635 1636 /* 1637 * smb_gmtime_r 1638 * 1639 * Thread-safe version of smb_gmtime. Returns a null pointer if either 1640 * input parameter is a null pointer. Otherwise returns a pointer 1641 * to result. 1642 * 1643 * Day of the week calculation: the Epoch was a thursday. 1644 * 1645 * There are no timezone corrections so tm_isdst and tm_gmtoff are 1646 * always zero, and the zone is always WET. 1647 */ 1648 struct tm * 1649 smb_gmtime_r(time_t *clock, struct tm *result) 1650 { 1651 time_t tsec; 1652 int year; 1653 int month; 1654 int sec_per_month; 1655 1656 if (clock == 0 || result == 0) 1657 return (0); 1658 1659 bzero(result, sizeof (struct tm)); 1660 tsec = *clock; 1661 tsec -= tzh_leapcnt; 1662 1663 result->tm_wday = tsec / SECSPERDAY; 1664 result->tm_wday = (result->tm_wday + TM_THURSDAY) % DAYSPERWEEK; 1665 1666 year = EPOCH_YEAR; 1667 while (tsec >= (isleap(year) ? (SECSPERDAY * DAYSPERLYEAR) : 1668 (SECSPERDAY * DAYSPERNYEAR))) { 1669 if (isleap(year)) 1670 tsec -= SECSPERDAY * DAYSPERLYEAR; 1671 else 1672 tsec -= SECSPERDAY * DAYSPERNYEAR; 1673 1674 ++year; 1675 } 1676 1677 result->tm_year = year - TM_YEAR_BASE; 1678 result->tm_yday = tsec / SECSPERDAY; 1679 1680 for (month = TM_JANUARY; month <= TM_DECEMBER; ++month) { 1681 sec_per_month = days_in_month[month] * SECSPERDAY; 1682 1683 if (month == TM_FEBRUARY && isleap(year)) 1684 sec_per_month += SECSPERDAY; 1685 1686 if (tsec < sec_per_month) 1687 break; 1688 1689 tsec -= sec_per_month; 1690 } 1691 1692 result->tm_mon = month; 1693 result->tm_mday = (tsec / SECSPERDAY) + 1; 1694 tsec %= SECSPERDAY; 1695 result->tm_sec = tsec % 60; 1696 tsec /= 60; 1697 result->tm_min = tsec % 60; 1698 tsec /= 60; 1699 result->tm_hour = (int)tsec; 1700 1701 return (result); 1702 } 1703 1704 1705 /* 1706 * smb_timegm 1707 * 1708 * Converts the broken-down time in tm to a time value, i.e. the number 1709 * of seconds since the Epoch (00:00:00 UTC, January 1, 1970). This is 1710 * not a POSIX or ANSI function. Per the man page, the input values of 1711 * tm_wday and tm_yday are ignored and, as the input data is assumed to 1712 * represent GMT, we force tm_isdst and tm_gmtoff to 0. 1713 * 1714 * Before returning the clock time, we use smb_gmtime_r to set up tm_wday 1715 * and tm_yday, and bring the other fields within normal range. I don't 1716 * think this is really how it should be done but it's convenient for 1717 * now. 1718 */ 1719 time_t 1720 smb_timegm(struct tm *tm) 1721 { 1722 time_t tsec; 1723 int dd; 1724 int mm; 1725 int yy; 1726 int year; 1727 1728 if (tm == 0) 1729 return (-1); 1730 1731 year = tm->tm_year + TM_YEAR_BASE; 1732 tsec = tzh_leapcnt; 1733 1734 for (yy = EPOCH_YEAR; yy < year; ++yy) { 1735 if (isleap(yy)) 1736 tsec += SECSPERDAY * DAYSPERLYEAR; 1737 else 1738 tsec += SECSPERDAY * DAYSPERNYEAR; 1739 } 1740 1741 for (mm = TM_JANUARY; mm < tm->tm_mon; ++mm) { 1742 dd = days_in_month[mm] * SECSPERDAY; 1743 1744 if (mm == TM_FEBRUARY && isleap(year)) 1745 dd += SECSPERDAY; 1746 1747 tsec += dd; 1748 } 1749 1750 tsec += (tm->tm_mday - 1) * SECSPERDAY; 1751 tsec += tm->tm_sec; 1752 tsec += tm->tm_min * SECSPERMIN; 1753 tsec += tm->tm_hour * SECSPERHOUR; 1754 1755 tm->tm_isdst = 0; 1756 (void) smb_gmtime_r(&tsec, tm); 1757 return (tsec); 1758 } 1759 1760 /* 1761 * smb_pad_align 1762 * 1763 * Returns the number of bytes required to pad an offset to the 1764 * specified alignment. 1765 */ 1766 uint32_t 1767 smb_pad_align(uint32_t offset, uint32_t align) 1768 { 1769 uint32_t pad = offset % align; 1770 1771 if (pad != 0) 1772 pad = align - pad; 1773 1774 return (pad); 1775 } 1776 1777 /* 1778 * smb_panic 1779 * 1780 * Logs the file name, function name and line number passed in and panics the 1781 * system. 1782 */ 1783 void 1784 smb_panic(char *file, const char *func, int line) 1785 { 1786 cmn_err(CE_PANIC, "%s:%s:%d\n", file, func, line); 1787 } 1788 1789 /* 1790 * Creates an AVL tree and initializes the given smb_avl_t 1791 * structure using the passed args 1792 */ 1793 void 1794 smb_avl_create(smb_avl_t *avl, size_t size, size_t offset, 1795 const smb_avl_nops_t *ops) 1796 { 1797 ASSERT(avl); 1798 ASSERT(ops); 1799 1800 rw_init(&avl->avl_lock, NULL, RW_DEFAULT, NULL); 1801 mutex_init(&avl->avl_mutex, NULL, MUTEX_DEFAULT, NULL); 1802 1803 avl->avl_nops = ops; 1804 avl->avl_state = SMB_AVL_STATE_READY; 1805 avl->avl_refcnt = 0; 1806 (void) random_get_pseudo_bytes((uint8_t *)&avl->avl_sequence, 1807 sizeof (uint32_t)); 1808 1809 avl_create(&avl->avl_tree, ops->avln_cmp, size, offset); 1810 } 1811 1812 /* 1813 * Destroys the specified AVL tree. 1814 * It waits for all the in-flight operations to finish 1815 * before destroying the AVL. 1816 */ 1817 void 1818 smb_avl_destroy(smb_avl_t *avl) 1819 { 1820 void *cookie = NULL; 1821 void *node; 1822 1823 ASSERT(avl); 1824 1825 mutex_enter(&avl->avl_mutex); 1826 if (avl->avl_state != SMB_AVL_STATE_READY) { 1827 mutex_exit(&avl->avl_mutex); 1828 return; 1829 } 1830 1831 avl->avl_state = SMB_AVL_STATE_DESTROYING; 1832 1833 while (avl->avl_refcnt > 0) 1834 (void) cv_wait(&avl->avl_cv, &avl->avl_mutex); 1835 mutex_exit(&avl->avl_mutex); 1836 1837 rw_enter(&avl->avl_lock, RW_WRITER); 1838 while ((node = avl_destroy_nodes(&avl->avl_tree, &cookie)) != NULL) 1839 avl->avl_nops->avln_destroy(node); 1840 1841 avl_destroy(&avl->avl_tree); 1842 rw_exit(&avl->avl_lock); 1843 1844 rw_destroy(&avl->avl_lock); 1845 1846 mutex_destroy(&avl->avl_mutex); 1847 bzero(avl, sizeof (smb_avl_t)); 1848 } 1849 1850 /* 1851 * Adds the given item to the AVL if it's 1852 * not already there. 1853 * 1854 * Returns: 1855 * 1856 * ENOTACTIVE AVL is not in READY state 1857 * EEXIST The item is already in AVL 1858 */ 1859 int 1860 smb_avl_add(smb_avl_t *avl, void *item) 1861 { 1862 avl_index_t where; 1863 1864 ASSERT(avl); 1865 ASSERT(item); 1866 1867 if (!smb_avl_hold(avl)) 1868 return (ENOTACTIVE); 1869 1870 rw_enter(&avl->avl_lock, RW_WRITER); 1871 if (avl_find(&avl->avl_tree, item, &where) != NULL) { 1872 rw_exit(&avl->avl_lock); 1873 smb_avl_rele(avl); 1874 return (EEXIST); 1875 } 1876 1877 avl_insert(&avl->avl_tree, item, where); 1878 avl->avl_sequence++; 1879 rw_exit(&avl->avl_lock); 1880 1881 smb_avl_rele(avl); 1882 return (0); 1883 } 1884 1885 /* 1886 * Removes the given item from the AVL. 1887 * If no reference is left on the item 1888 * it will also be destroyed by calling the 1889 * registered destroy operation. 1890 */ 1891 void 1892 smb_avl_remove(smb_avl_t *avl, void *item) 1893 { 1894 avl_index_t where; 1895 void *rm_item; 1896 1897 ASSERT(avl); 1898 ASSERT(item); 1899 1900 if (!smb_avl_hold(avl)) 1901 return; 1902 1903 rw_enter(&avl->avl_lock, RW_WRITER); 1904 if ((rm_item = avl_find(&avl->avl_tree, item, &where)) == NULL) { 1905 rw_exit(&avl->avl_lock); 1906 smb_avl_rele(avl); 1907 return; 1908 } 1909 1910 avl_remove(&avl->avl_tree, rm_item); 1911 if (avl->avl_nops->avln_rele(rm_item)) 1912 avl->avl_nops->avln_destroy(rm_item); 1913 avl->avl_sequence++; 1914 rw_exit(&avl->avl_lock); 1915 1916 smb_avl_rele(avl); 1917 } 1918 1919 /* 1920 * Looks up the AVL for the given item. 1921 * If the item is found a hold on the object 1922 * is taken before the pointer to it is 1923 * returned to the caller. The caller MUST 1924 * always call smb_avl_release() after it's done 1925 * using the returned object to release the hold 1926 * taken on the object. 1927 */ 1928 void * 1929 smb_avl_lookup(smb_avl_t *avl, void *item) 1930 { 1931 void *node = NULL; 1932 1933 ASSERT(avl); 1934 ASSERT(item); 1935 1936 if (!smb_avl_hold(avl)) 1937 return (NULL); 1938 1939 rw_enter(&avl->avl_lock, RW_READER); 1940 node = avl_find(&avl->avl_tree, item, NULL); 1941 if (node != NULL) 1942 avl->avl_nops->avln_hold(node); 1943 rw_exit(&avl->avl_lock); 1944 1945 if (node == NULL) 1946 smb_avl_rele(avl); 1947 1948 return (node); 1949 } 1950 1951 /* 1952 * The hold on the given object is released. 1953 * This function MUST always be called after 1954 * smb_avl_lookup() and smb_avl_iterate() for 1955 * the returned object. 1956 * 1957 * If AVL is in DESTROYING state, the destroying 1958 * thread will be notified. 1959 */ 1960 void 1961 smb_avl_release(smb_avl_t *avl, void *item) 1962 { 1963 ASSERT(avl); 1964 ASSERT(item); 1965 1966 if (avl->avl_nops->avln_rele(item)) 1967 avl->avl_nops->avln_destroy(item); 1968 1969 smb_avl_rele(avl); 1970 } 1971 1972 /* 1973 * Initializes the given cursor for the AVL. 1974 * The cursor will be used to iterate through the AVL 1975 */ 1976 void 1977 smb_avl_iterinit(smb_avl_t *avl, smb_avl_cursor_t *cursor) 1978 { 1979 ASSERT(avl); 1980 ASSERT(cursor); 1981 1982 cursor->avlc_next = NULL; 1983 cursor->avlc_sequence = avl->avl_sequence; 1984 } 1985 1986 /* 1987 * Iterates through the AVL using the given cursor. 1988 * It always starts at the beginning and then returns 1989 * a pointer to the next object on each subsequent call. 1990 * 1991 * If a new object is added to or removed from the AVL 1992 * between two calls to this function, the iteration 1993 * will terminate prematurely. 1994 * 1995 * The caller MUST always call smb_avl_release() after it's 1996 * done using the returned object to release the hold taken 1997 * on the object. 1998 */ 1999 void * 2000 smb_avl_iterate(smb_avl_t *avl, smb_avl_cursor_t *cursor) 2001 { 2002 void *node; 2003 2004 ASSERT(avl); 2005 ASSERT(cursor); 2006 2007 if (!smb_avl_hold(avl)) 2008 return (NULL); 2009 2010 rw_enter(&avl->avl_lock, RW_READER); 2011 if (cursor->avlc_sequence != avl->avl_sequence) { 2012 rw_exit(&avl->avl_lock); 2013 smb_avl_rele(avl); 2014 return (NULL); 2015 } 2016 2017 if (cursor->avlc_next == NULL) 2018 node = avl_first(&avl->avl_tree); 2019 else 2020 node = AVL_NEXT(&avl->avl_tree, cursor->avlc_next); 2021 2022 if (node != NULL) 2023 avl->avl_nops->avln_hold(node); 2024 2025 cursor->avlc_next = node; 2026 rw_exit(&avl->avl_lock); 2027 2028 if (node == NULL) 2029 smb_avl_rele(avl); 2030 2031 return (node); 2032 } 2033 2034 /* 2035 * Increments the AVL reference count in order to 2036 * prevent the avl from being destroyed while it's 2037 * being accessed. 2038 */ 2039 static boolean_t 2040 smb_avl_hold(smb_avl_t *avl) 2041 { 2042 mutex_enter(&avl->avl_mutex); 2043 if (avl->avl_state != SMB_AVL_STATE_READY) { 2044 mutex_exit(&avl->avl_mutex); 2045 return (B_FALSE); 2046 } 2047 avl->avl_refcnt++; 2048 mutex_exit(&avl->avl_mutex); 2049 2050 return (B_TRUE); 2051 } 2052 2053 /* 2054 * Decrements the AVL reference count to release the 2055 * hold. If another thread is trying to destroy the 2056 * AVL and is waiting for the reference count to become 2057 * 0, it is signaled to wake up. 2058 */ 2059 static void 2060 smb_avl_rele(smb_avl_t *avl) 2061 { 2062 mutex_enter(&avl->avl_mutex); 2063 ASSERT(avl->avl_refcnt > 0); 2064 avl->avl_refcnt--; 2065 if (avl->avl_state == SMB_AVL_STATE_DESTROYING) 2066 cv_broadcast(&avl->avl_cv); 2067 mutex_exit(&avl->avl_mutex); 2068 } 2069 2070 /* 2071 * smb_latency_init 2072 */ 2073 void 2074 smb_latency_init(smb_latency_t *lat) 2075 { 2076 bzero(lat, sizeof (*lat)); 2077 mutex_init(&lat->ly_mutex, NULL, MUTEX_SPIN, (void *)ipltospl(SPL7)); 2078 } 2079 2080 /* 2081 * smb_latency_destroy 2082 */ 2083 void 2084 smb_latency_destroy(smb_latency_t *lat) 2085 { 2086 mutex_destroy(&lat->ly_mutex); 2087 } 2088 2089 /* 2090 * smb_latency_add_sample 2091 * 2092 * Uses the new sample to calculate the new mean and standard deviation. The 2093 * sample must be a scaled value. 2094 */ 2095 void 2096 smb_latency_add_sample(smb_latency_t *lat, hrtime_t sample) 2097 { 2098 hrtime_t a_mean; 2099 hrtime_t d_mean; 2100 2101 mutex_enter(&lat->ly_mutex); 2102 lat->ly_a_nreq++; 2103 lat->ly_a_sum += sample; 2104 if (lat->ly_a_nreq != 0) { 2105 a_mean = lat->ly_a_sum / lat->ly_a_nreq; 2106 lat->ly_a_stddev = 2107 (sample - a_mean) * (sample - lat->ly_a_mean); 2108 lat->ly_a_mean = a_mean; 2109 } 2110 lat->ly_d_nreq++; 2111 lat->ly_d_sum += sample; 2112 if (lat->ly_d_nreq != 0) { 2113 d_mean = lat->ly_d_sum / lat->ly_d_nreq; 2114 lat->ly_d_stddev = 2115 (sample - d_mean) * (sample - lat->ly_d_mean); 2116 lat->ly_d_mean = d_mean; 2117 } 2118 mutex_exit(&lat->ly_mutex); 2119 } 2120 2121 /* 2122 * smb_srqueue_init 2123 */ 2124 void 2125 smb_srqueue_init(smb_srqueue_t *srq) 2126 { 2127 bzero(srq, sizeof (*srq)); 2128 mutex_init(&srq->srq_mutex, NULL, MUTEX_SPIN, (void *)ipltospl(SPL7)); 2129 srq->srq_wlastupdate = srq->srq_rlastupdate = gethrtime_unscaled(); 2130 } 2131 2132 /* 2133 * smb_srqueue_destroy 2134 */ 2135 void 2136 smb_srqueue_destroy(smb_srqueue_t *srq) 2137 { 2138 mutex_destroy(&srq->srq_mutex); 2139 } 2140 2141 /* 2142 * smb_srqueue_waitq_enter 2143 */ 2144 void 2145 smb_srqueue_waitq_enter(smb_srqueue_t *srq) 2146 { 2147 hrtime_t new; 2148 hrtime_t delta; 2149 uint32_t wcnt; 2150 2151 mutex_enter(&srq->srq_mutex); 2152 new = gethrtime_unscaled(); 2153 delta = new - srq->srq_wlastupdate; 2154 srq->srq_wlastupdate = new; 2155 wcnt = srq->srq_wcnt++; 2156 if (wcnt != 0) { 2157 srq->srq_wlentime += delta * wcnt; 2158 srq->srq_wtime += delta; 2159 } 2160 mutex_exit(&srq->srq_mutex); 2161 } 2162 2163 /* 2164 * smb_srqueue_runq_exit 2165 */ 2166 void 2167 smb_srqueue_runq_exit(smb_srqueue_t *srq) 2168 { 2169 hrtime_t new; 2170 hrtime_t delta; 2171 uint32_t rcnt; 2172 2173 mutex_enter(&srq->srq_mutex); 2174 new = gethrtime_unscaled(); 2175 delta = new - srq->srq_rlastupdate; 2176 srq->srq_rlastupdate = new; 2177 rcnt = srq->srq_rcnt--; 2178 ASSERT(rcnt > 0); 2179 srq->srq_rlentime += delta * rcnt; 2180 srq->srq_rtime += delta; 2181 mutex_exit(&srq->srq_mutex); 2182 } 2183 2184 /* 2185 * smb_srqueue_waitq_to_runq 2186 */ 2187 void 2188 smb_srqueue_waitq_to_runq(smb_srqueue_t *srq) 2189 { 2190 hrtime_t new; 2191 hrtime_t delta; 2192 uint32_t wcnt; 2193 uint32_t rcnt; 2194 2195 mutex_enter(&srq->srq_mutex); 2196 new = gethrtime_unscaled(); 2197 delta = new - srq->srq_wlastupdate; 2198 srq->srq_wlastupdate = new; 2199 wcnt = srq->srq_wcnt--; 2200 ASSERT(wcnt > 0); 2201 srq->srq_wlentime += delta * wcnt; 2202 srq->srq_wtime += delta; 2203 delta = new - srq->srq_rlastupdate; 2204 srq->srq_rlastupdate = new; 2205 rcnt = srq->srq_rcnt++; 2206 if (rcnt != 0) { 2207 srq->srq_rlentime += delta * rcnt; 2208 srq->srq_rtime += delta; 2209 } 2210 mutex_exit(&srq->srq_mutex); 2211 } 2212 2213 /* 2214 * smb_srqueue_update 2215 * 2216 * Takes a snapshot of the smb_sr_stat_t structure passed in. 2217 */ 2218 void 2219 smb_srqueue_update(smb_srqueue_t *srq, smb_kstat_utilization_t *kd) 2220 { 2221 hrtime_t delta; 2222 hrtime_t snaptime; 2223 2224 mutex_enter(&srq->srq_mutex); 2225 snaptime = gethrtime_unscaled(); 2226 delta = snaptime - srq->srq_wlastupdate; 2227 srq->srq_wlastupdate = snaptime; 2228 if (srq->srq_wcnt != 0) { 2229 srq->srq_wlentime += delta * srq->srq_wcnt; 2230 srq->srq_wtime += delta; 2231 } 2232 delta = snaptime - srq->srq_rlastupdate; 2233 srq->srq_rlastupdate = snaptime; 2234 if (srq->srq_rcnt != 0) { 2235 srq->srq_rlentime += delta * srq->srq_rcnt; 2236 srq->srq_rtime += delta; 2237 } 2238 kd->ku_rlentime = srq->srq_rlentime; 2239 kd->ku_rtime = srq->srq_rtime; 2240 kd->ku_wlentime = srq->srq_wlentime; 2241 kd->ku_wtime = srq->srq_wtime; 2242 mutex_exit(&srq->srq_mutex); 2243 scalehrtime(&kd->ku_rlentime); 2244 scalehrtime(&kd->ku_rtime); 2245 scalehrtime(&kd->ku_wlentime); 2246 scalehrtime(&kd->ku_wtime); 2247 } 2248 2249 void 2250 smb_threshold_init(smb_cmd_threshold_t *ct, char *cmd, 2251 uint_t threshold, uint_t timeout) 2252 { 2253 bzero(ct, sizeof (smb_cmd_threshold_t)); 2254 mutex_init(&ct->ct_mutex, NULL, MUTEX_DEFAULT, NULL); 2255 cv_init(&ct->ct_cond, NULL, CV_DEFAULT, NULL); 2256 2257 ct->ct_cmd = cmd; 2258 ct->ct_threshold = threshold; 2259 ct->ct_timeout = timeout; 2260 } 2261 2262 void 2263 smb_threshold_fini(smb_cmd_threshold_t *ct) 2264 { 2265 cv_destroy(&ct->ct_cond); 2266 mutex_destroy(&ct->ct_mutex); 2267 } 2268 2269 /* 2270 * This threshold mechanism is used to limit the number of simultaneous 2271 * named pipe connections, concurrent authentication conversations, etc. 2272 * Requests that would take us over the threshold wait until either the 2273 * resources are available (return zero) or timeout (return error). 2274 */ 2275 int 2276 smb_threshold_enter(smb_cmd_threshold_t *ct) 2277 { 2278 clock_t time, rem; 2279 2280 time = MSEC_TO_TICK(ct->ct_timeout) + ddi_get_lbolt(); 2281 mutex_enter(&ct->ct_mutex); 2282 2283 while (ct->ct_threshold != 0 && 2284 ct->ct_threshold <= ct->ct_active_cnt) { 2285 ct->ct_blocked_cnt++; 2286 rem = cv_timedwait(&ct->ct_cond, &ct->ct_mutex, time); 2287 ct->ct_blocked_cnt--; 2288 if (rem < 0) { 2289 mutex_exit(&ct->ct_mutex); 2290 return (ETIME); 2291 } 2292 } 2293 if (ct->ct_threshold == 0) { 2294 mutex_exit(&ct->ct_mutex); 2295 return (ECANCELED); 2296 } 2297 2298 ASSERT3U(ct->ct_active_cnt, <, ct->ct_threshold); 2299 ct->ct_active_cnt++; 2300 2301 mutex_exit(&ct->ct_mutex); 2302 return (0); 2303 } 2304 2305 void 2306 smb_threshold_exit(smb_cmd_threshold_t *ct) 2307 { 2308 mutex_enter(&ct->ct_mutex); 2309 ASSERT3U(ct->ct_active_cnt, >, 0); 2310 ct->ct_active_cnt--; 2311 if (ct->ct_blocked_cnt) 2312 cv_signal(&ct->ct_cond); 2313 mutex_exit(&ct->ct_mutex); 2314 } 2315 2316 void 2317 smb_threshold_wake_all(smb_cmd_threshold_t *ct) 2318 { 2319 mutex_enter(&ct->ct_mutex); 2320 ct->ct_threshold = 0; 2321 cv_broadcast(&ct->ct_cond); 2322 mutex_exit(&ct->ct_mutex); 2323 } 2324