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 * Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved. 23 * Copyright 2019 Nexenta by DDN, Inc. All rights reserved. 24 * Copyright (c) 2016 by Delphix. All rights reserved. 25 */ 26 27 /* 28 * General Structures Layout 29 * ------------------------- 30 * 31 * This is a simplified diagram showing the relationship between most of the 32 * main structures. 33 * 34 * +-------------------+ 35 * | SMB_INFO | 36 * +-------------------+ 37 * | 38 * | 39 * v 40 * +-------------------+ +-------------------+ +-------------------+ 41 * | SESSION |<----->| SESSION |......| SESSION | 42 * +-------------------+ +-------------------+ +-------------------+ 43 * | | 44 * | | 45 * | v 46 * | +-------------------+ +-------------------+ +-------------------+ 47 * | | USER |<--->| USER |...| USER | 48 * | +-------------------+ +-------------------+ +-------------------+ 49 * | 50 * | 51 * v 52 * +-------------------+ +-------------------+ +-------------------+ 53 * | TREE |<----->| TREE |......| TREE | 54 * +-------------------+ +-------------------+ +-------------------+ 55 * | | 56 * | | 57 * | v 58 * | +-------+ +-------+ +-------+ 59 * | | OFILE |<----->| OFILE |......| OFILE | 60 * | +-------+ +-------+ +-------+ 61 * | 62 * | 63 * v 64 * +-------+ +------+ +------+ 65 * | ODIR |<----->| ODIR |......| ODIR | 66 * +-------+ +------+ +------+ 67 * 68 * 69 * User State Machine 70 * ------------------ 71 * 72 * 73 * | T0: Creation/Allocation 74 * | (1st session setup) 75 * v 76 * +-----------------------------+ 77 * | SMB_USER_STATE_LOGGING_ON |<----------+ 78 * +-----------------------------+ addl. session setup 79 * | | (more proc. required) 80 * | T2 | ^ 81 * | | | T1: (cont.) 82 * | +------->-------? 83 * v | T3: (fail) 84 * +-----------------------------+ v 85 * | SMB_USER_STATE_LOGGED_ON | (logged off) 86 * +-----------------------------+ 87 * | 88 * | T4 89 * | 90 * v 91 * +-----------------------------+ 92 * | SMB_USER_STATE_LOGGING_OFF | 93 * +-----------------------------+ 94 * | 95 * | T5 96 * | 97 * v 98 * +-----------------------------+ T6 99 * | SMB_USER_STATE_LOGGED_OFF |----------> Deletion/Free 100 * +-----------------------------+ 101 * 102 * SMB_USER_STATE_LOGGING_ON 103 * 104 * While in this state: 105 * - The user is in the list of users for their session. 106 * - References will be given out ONLY for session setup. 107 * - This user can not access anything yet. 108 * 109 * SMB_USER_STATE_LOGGED_ON 110 * 111 * While in this state: 112 * - The user is in the list of users for their session. 113 * - References will be given out if the user is looked up. 114 * - The user can access files and pipes. 115 * 116 * SMB_USER_STATE_LOGGING_OFF 117 * 118 * While in this state: 119 * - The user is in the list of users for their session. 120 * - References will not be given out if the user is looked up. 121 * - The trees the user connected are being disconnected. 122 * - The resources associated with the user remain. 123 * 124 * SMB_USER_STATE_LOGGED_OFF 125 * 126 * While in this state: 127 * - The user is queued in the list of users of their session. 128 * - References will not be given out if the user is looked up. 129 * - The user has no more trees connected. 130 * - The resources associated with the user remain. 131 * 132 * Transition T0 133 * 134 * First request in an SMB Session Setup sequence creates a 135 * new user object and adds it to the list of users for 136 * this session. User UID is assigned and returned. 137 * 138 * Transition T1 139 * 140 * Subsequent SMB Session Setup requests (on the same UID 141 * assigned in T0) update the state of this user object, 142 * communicating with smbd for the crypto work. 143 * 144 * Transition T2 145 * 146 * If the SMB Session Setup sequence is successful, T2 147 * makes the new user object available for requests. 148 * 149 * Transition T3 150 * 151 * If an Session Setup request gets an error other than 152 * the expected "more processing required", then T3 153 * leads to state "LOGGED_OFF" and then tear-down of the 154 * partially constructed user. 155 * 156 * Transition T4 157 * 158 * Normal SMB User Logoff request, or session tear-down. 159 * 160 * Transition T5 161 * 162 * This transition occurs in smb_user_release(). The resources associated 163 * with the user are deleted as well as the user. For the transition to 164 * occur, the user must be in the SMB_USER_STATE_LOGGED_OFF state and the 165 * reference count be zero. 166 * 167 * Comments 168 * -------- 169 * 170 * The state machine of the user structures is controlled by 3 elements: 171 * - The list of users of the session they belong to. 172 * - The mutex embedded in the structure itself. 173 * - The reference count. 174 * 175 * There's a mutex embedded in the user structure used to protect its fields 176 * and there's a lock embedded in the list of users of a session. To 177 * increment or to decrement the reference count the mutex must be entered. 178 * To insert the user into the list of users of the session and to remove 179 * the user from it, the lock must be entered in RW_WRITER mode. 180 * 181 * Rules of access to a user structure: 182 * 183 * 1) In order to avoid deadlocks, when both (mutex and lock of the session 184 * list) have to be entered, the lock must be entered first. Additionally, 185 * one may NOT flush the deleteq of either the tree list or the ofile list 186 * while the user mutex is held. 187 * 188 * 2) All actions applied to a user require a reference count. 189 * 190 * 3) There are 2 ways of getting a reference count. One is when the user 191 * logs in. The other when the user is looked up. 192 * 193 * It should be noted that the reference count of a user registers the 194 * number of references to the user in other structures (such as an smb 195 * request). The reference count is not incremented in these 2 instances: 196 * 197 * 1) The user is logged in. An user is anchored by their state. If there's 198 * no activity involving a user currently logged in, the reference 199 * count of that user is zero. 200 * 201 * 2) The user is queued in the list of users of the session. The fact of 202 * being queued in that list is NOT registered by incrementing the 203 * reference count. 204 */ 205 #include <sys/types.h> 206 #include <sys/sid.h> 207 #include <sys/priv_names.h> 208 #include <sys/priv.h> 209 #include <sys/policy.h> 210 #include <smbsrv/smb_kproto.h> 211 #include <smbsrv/smb_door.h> 212 213 #define ADMINISTRATORS_SID "S-1-5-32-544" 214 215 /* Don't leak object addresses */ 216 #define SMB_USER_SSNID(u) \ 217 ((uintptr_t)&smb_cache_user ^ (uintptr_t)(u)) 218 219 static void smb_user_delete(void *); 220 static int smb_user_enum_private(smb_user_t *, smb_svcenum_t *); 221 static void smb_user_auth_logoff(smb_user_t *); 222 static void smb_user_logoff_tq(void *); 223 224 /* 225 * Create a new user. 226 * 227 * For SMB2 and later, session IDs (u_ssnid) need to be unique among all 228 * current and "recent" sessions. The session ID is derived from the 229 * address of the smb_user object (obscured by XOR with a constant). 230 * This adds a 3-bit generation number in the low bits, incremented 231 * when we allocate an smb_user_t from its kmem cache, so it can't 232 * be confused with a (recent) previous incarnation of this object. 233 */ 234 smb_user_t * 235 smb_user_new(smb_session_t *session) 236 { 237 smb_user_t *user; 238 uint_t gen; // generation (low 3 bits of ssnid) 239 uint32_t ucount; 240 241 ASSERT(session); 242 ASSERT(session->s_magic == SMB_SESSION_MAGIC); 243 244 user = kmem_cache_alloc(smb_cache_user, KM_SLEEP); 245 gen = (user->u_ssnid + 1) & 7; 246 bzero(user, sizeof (smb_user_t)); 247 248 user->u_refcnt = 1; 249 user->u_session = session; 250 user->u_server = session->s_server; 251 user->u_logon_time = gethrestime_sec(); 252 253 if (smb_idpool_alloc(&session->s_uid_pool, &user->u_uid)) 254 goto errout; 255 user->u_ssnid = SMB_USER_SSNID(user) + gen; 256 257 mutex_init(&user->u_mutex, NULL, MUTEX_DEFAULT, NULL); 258 user->u_state = SMB_USER_STATE_LOGGING_ON; 259 user->u_magic = SMB_USER_MAGIC; 260 261 smb_llist_enter(&session->s_user_list, RW_WRITER); 262 ucount = smb_llist_get_count(&session->s_user_list); 263 smb_llist_insert_tail(&session->s_user_list, user); 264 smb_llist_exit(&session->s_user_list); 265 smb_server_inc_users(session->s_server); 266 267 /* 268 * If we added the first user to the session, cancel the 269 * timeout that was started in smb_session_receiver(). 270 */ 271 if (ucount == 0) { 272 timeout_id_t tmo = NULL; 273 274 smb_rwx_rwenter(&session->s_lock, RW_WRITER); 275 tmo = session->s_auth_tmo; 276 session->s_auth_tmo = NULL; 277 smb_rwx_rwexit(&session->s_lock); 278 279 if (tmo != NULL) 280 (void) untimeout(tmo); 281 } 282 283 return (user); 284 285 errout: 286 if (user->u_uid != 0) 287 smb_idpool_free(&session->s_uid_pool, user->u_uid); 288 kmem_cache_free(smb_cache_user, user); 289 return (NULL); 290 } 291 292 /* 293 * Fill in the details of a user, meaning a transition 294 * from state LOGGING_ON to state LOGGED_ON. 295 */ 296 int 297 smb_user_logon( 298 smb_user_t *user, 299 cred_t *cr, 300 char *domain_name, 301 char *account_name, 302 uint32_t flags, 303 uint32_t privileges, 304 uint32_t audit_sid) 305 { 306 ksocket_t authsock = NULL; 307 timeout_id_t tmo = NULL; 308 309 ASSERT(user->u_magic == SMB_USER_MAGIC); 310 ASSERT(cr); 311 ASSERT(account_name); 312 ASSERT(domain_name); 313 314 mutex_enter(&user->u_mutex); 315 316 if (user->u_state != SMB_USER_STATE_LOGGING_ON) { 317 mutex_exit(&user->u_mutex); 318 return (-1); 319 } 320 321 /* 322 * In the transition from LOGGING_ON to LOGGED_ON, 323 * we always have an auth. socket to close. 324 */ 325 authsock = user->u_authsock; 326 user->u_authsock = NULL; 327 tmo = user->u_auth_tmo; 328 user->u_auth_tmo = NULL; 329 330 user->u_state = SMB_USER_STATE_LOGGED_ON; 331 user->u_flags = flags; 332 user->u_name_len = strlen(account_name) + 1; 333 user->u_domain_len = strlen(domain_name) + 1; 334 user->u_name = smb_mem_strdup(account_name); 335 user->u_domain = smb_mem_strdup(domain_name); 336 user->u_audit_sid = audit_sid; 337 338 smb_user_setcred(user, cr, privileges); 339 340 mutex_exit(&user->u_mutex); 341 342 /* Timeout callback takes u_mutex. See untimeout(9f) */ 343 if (tmo != NULL) 344 (void) untimeout(tmo); 345 346 /* This close can block, so not under the mutex. */ 347 if (authsock != NULL) 348 smb_authsock_close(user, authsock); 349 350 return (0); 351 } 352 353 /* 354 * smb_user_logoff 355 * 356 * Change the user state to "logging off" and disconnect trees. 357 * The user list must not be entered or modified here. 358 * 359 * We remain in state "logging off" until the last ref. is gone, 360 * then smb_user_release takes us to state "logged off". 361 */ 362 void 363 smb_user_logoff( 364 smb_user_t *user) 365 { 366 ksocket_t authsock = NULL; 367 timeout_id_t tmo = NULL; 368 369 ASSERT(user->u_magic == SMB_USER_MAGIC); 370 371 mutex_enter(&user->u_mutex); 372 ASSERT(user->u_refcnt); 373 switch (user->u_state) { 374 case SMB_USER_STATE_LOGGING_ON: 375 authsock = user->u_authsock; 376 user->u_authsock = NULL; 377 tmo = user->u_auth_tmo; 378 user->u_auth_tmo = NULL; 379 user->u_state = SMB_USER_STATE_LOGGING_OFF; 380 mutex_exit(&user->u_mutex); 381 382 /* Timeout callback takes u_mutex. See untimeout(9f) */ 383 if (tmo != NULL) 384 (void) untimeout(tmo); 385 /* This close can block, so not under the mutex. */ 386 if (authsock != NULL) 387 smb_authsock_close(user, authsock); 388 break; 389 390 case SMB_USER_STATE_LOGGED_ON: 391 /* 392 * The user is moved into a state indicating that the log off 393 * process has started. 394 */ 395 user->u_state = SMB_USER_STATE_LOGGING_OFF; 396 mutex_exit(&user->u_mutex); 397 smb_session_disconnect_owned_trees(user->u_session, user); 398 smb_user_auth_logoff(user); 399 break; 400 401 case SMB_USER_STATE_LOGGED_OFF: 402 case SMB_USER_STATE_LOGGING_OFF: 403 mutex_exit(&user->u_mutex); 404 break; 405 406 default: 407 ASSERT(0); 408 mutex_exit(&user->u_mutex); 409 break; 410 } 411 } 412 413 /* 414 * Take a reference on a user. Do not return a reference unless the user is in 415 * the logged-in state. 416 */ 417 boolean_t 418 smb_user_hold(smb_user_t *user) 419 { 420 SMB_USER_VALID(user); 421 422 mutex_enter(&user->u_mutex); 423 424 if (user->u_state == SMB_USER_STATE_LOGGED_ON) { 425 user->u_refcnt++; 426 mutex_exit(&user->u_mutex); 427 return (B_TRUE); 428 } 429 430 mutex_exit(&user->u_mutex); 431 return (B_FALSE); 432 } 433 434 /* 435 * Unconditionally take a reference on a user. 436 */ 437 void 438 smb_user_hold_internal(smb_user_t *user) 439 { 440 SMB_USER_VALID(user); 441 442 mutex_enter(&user->u_mutex); 443 user->u_refcnt++; 444 mutex_exit(&user->u_mutex); 445 } 446 447 /* 448 * Release a reference on a user. If the reference count falls to 449 * zero and the user has logged off, post the object for deletion. 450 * Object deletion is deferred to avoid modifying a list while an 451 * iteration may be in progress. 452 */ 453 void 454 smb_user_release( 455 smb_user_t *user) 456 { 457 smb_session_t *ssn = user->u_session; 458 459 SMB_USER_VALID(user); 460 461 /* flush the tree list delete queue */ 462 smb_llist_flush(&ssn->s_tree_list); 463 464 mutex_enter(&user->u_mutex); 465 ASSERT(user->u_refcnt); 466 user->u_refcnt--; 467 468 switch (user->u_state) { 469 case SMB_USER_STATE_LOGGING_OFF: 470 if (user->u_refcnt == 0) { 471 smb_session_t *ssn = user->u_session; 472 user->u_state = SMB_USER_STATE_LOGGED_OFF; 473 smb_llist_post(&ssn->s_user_list, user, 474 smb_user_delete); 475 } 476 break; 477 478 case SMB_USER_STATE_LOGGING_ON: 479 case SMB_USER_STATE_LOGGED_ON: 480 break; 481 482 case SMB_USER_STATE_LOGGED_OFF: 483 default: 484 ASSERT(0); 485 break; 486 } 487 mutex_exit(&user->u_mutex); 488 } 489 490 /* 491 * Timeout handler for user logons that stay too long in 492 * state SMB_USER_STATE_LOGGING_ON. This is setup by a 493 * timeout call in smb_authsock_open, and called in a 494 * callout thread, so schedule a taskq job to do the 495 * real work of logging off this user. 496 */ 497 void 498 smb_user_auth_tmo(void *arg) 499 { 500 smb_user_t *user = arg; 501 smb_request_t *sr; 502 503 SMB_USER_VALID(user); 504 505 /* 506 * If we can't allocate a request, it means the 507 * session is being torn down, so nothing to do. 508 */ 509 sr = smb_request_alloc(user->u_session, 0); 510 if (sr == NULL) 511 return; 512 513 /* 514 * Check user state, and take a hold if it's 515 * still logging on. If not, we're done. 516 */ 517 mutex_enter(&user->u_mutex); 518 if (user->u_state != SMB_USER_STATE_LOGGING_ON) { 519 mutex_exit(&user->u_mutex); 520 smb_request_free(sr); 521 return; 522 } 523 /* smb_user_hold_internal */ 524 user->u_refcnt++; 525 mutex_exit(&user->u_mutex); 526 527 /* 528 * The user hold is given to the SR, and released in 529 * smb_user_logoff_tq / smb_request_free 530 */ 531 sr->uid_user = user; 532 sr->user_cr = user->u_cred; 533 sr->sr_state = SMB_REQ_STATE_SUBMITTED; 534 535 (void) taskq_dispatch( 536 user->u_server->sv_worker_pool, 537 smb_user_logoff_tq, sr, TQ_SLEEP); 538 } 539 540 /* 541 * Helper for smb_user_auth_tmo() 542 */ 543 static void 544 smb_user_logoff_tq(void *arg) 545 { 546 smb_request_t *sr = arg; 547 548 SMB_REQ_VALID(sr); 549 550 mutex_enter(&sr->sr_mutex); 551 sr->sr_worker = curthread; 552 sr->sr_state = SMB_REQ_STATE_ACTIVE; 553 mutex_exit(&sr->sr_mutex); 554 555 smb_user_logoff(sr->uid_user); 556 557 sr->sr_state = SMB_REQ_STATE_COMPLETED; 558 smb_request_free(sr); 559 } 560 561 /* 562 * Determine whether or not the user is an administrator. 563 * Members of the administrators group have administrative rights. 564 */ 565 boolean_t 566 smb_user_is_admin(smb_user_t *user) 567 { 568 #ifdef _KERNEL 569 char sidstr[SMB_SID_STRSZ]; 570 ksidlist_t *ksidlist; 571 ksid_t ksid1; 572 ksid_t *ksid2; 573 int i; 574 #endif /* _KERNEL */ 575 boolean_t rc = B_FALSE; 576 577 ASSERT(user); 578 ASSERT(user->u_cred); 579 580 if (SMB_USER_IS_ADMIN(user)) 581 return (B_TRUE); 582 583 #ifdef _KERNEL 584 bzero(&ksid1, sizeof (ksid_t)); 585 (void) strlcpy(sidstr, ADMINISTRATORS_SID, SMB_SID_STRSZ); 586 ASSERT(smb_sid_splitstr(sidstr, &ksid1.ks_rid) == 0); 587 ksid1.ks_domain = ksid_lookupdomain(sidstr); 588 589 ksidlist = crgetsidlist(user->u_cred); 590 ASSERT(ksidlist); 591 ASSERT(ksid1.ks_domain); 592 ASSERT(ksid1.ks_domain->kd_name); 593 594 i = 0; 595 ksid2 = crgetsid(user->u_cred, KSID_USER); 596 do { 597 ASSERT(ksid2->ks_domain); 598 ASSERT(ksid2->ks_domain->kd_name); 599 600 if (strcmp(ksid1.ks_domain->kd_name, 601 ksid2->ks_domain->kd_name) == 0 && 602 ksid1.ks_rid == ksid2->ks_rid) { 603 user->u_flags |= SMB_USER_FLAG_ADMIN; 604 rc = B_TRUE; 605 break; 606 } 607 608 ksid2 = &ksidlist->ksl_sids[i]; 609 } while (i++ < ksidlist->ksl_nsid); 610 611 ksid_rele(&ksid1); 612 #endif /* _KERNEL */ 613 return (rc); 614 } 615 616 /* 617 * This function should be called with a hold on the user. 618 */ 619 boolean_t 620 smb_user_namecmp(smb_user_t *user, const char *name) 621 { 622 char *fq_name; 623 boolean_t match; 624 625 if (smb_strcasecmp(name, user->u_name, 0) == 0) 626 return (B_TRUE); 627 628 fq_name = kmem_alloc(MAXNAMELEN, KM_SLEEP); 629 630 (void) snprintf(fq_name, MAXNAMELEN, "%s\\%s", 631 user->u_domain, user->u_name); 632 633 match = (smb_strcasecmp(name, fq_name, 0) == 0); 634 if (!match) { 635 (void) snprintf(fq_name, MAXNAMELEN, "%s@%s", 636 user->u_name, user->u_domain); 637 638 match = (smb_strcasecmp(name, fq_name, 0) == 0); 639 } 640 641 kmem_free(fq_name, MAXNAMELEN); 642 return (match); 643 } 644 645 /* 646 * If the enumeration request is for user data, handle the request 647 * here. Otherwise, pass it on to the trees. 648 * 649 * This function should be called with a hold on the user. 650 */ 651 int 652 smb_user_enum(smb_user_t *user, smb_svcenum_t *svcenum) 653 { 654 int rc = 0; 655 656 ASSERT(user); 657 ASSERT(user->u_magic == SMB_USER_MAGIC); 658 659 if (svcenum->se_type == SMB_SVCENUM_TYPE_USER) 660 return (smb_user_enum_private(user, svcenum)); 661 662 return (rc); 663 } 664 665 /* *************************** Static Functions ***************************** */ 666 667 /* 668 * Delete a user. The tree list should be empty. 669 * 670 * Remove the user from the session's user list before freeing resources 671 * associated with the user. 672 */ 673 static void 674 smb_user_delete(void *arg) 675 { 676 smb_session_t *session; 677 smb_user_t *user = (smb_user_t *)arg; 678 uint32_t ucount; 679 680 SMB_USER_VALID(user); 681 ASSERT(user->u_refcnt == 0); 682 ASSERT(user->u_state == SMB_USER_STATE_LOGGED_OFF); 683 ASSERT(user->u_authsock == NULL); 684 ASSERT(user->u_auth_tmo == NULL); 685 686 session = user->u_session; 687 688 smb_server_dec_users(session->s_server); 689 smb_llist_enter(&session->s_user_list, RW_WRITER); 690 smb_llist_remove(&session->s_user_list, user); 691 smb_idpool_free(&session->s_uid_pool, user->u_uid); 692 ucount = smb_llist_get_count(&session->s_user_list); 693 smb_llist_exit(&session->s_user_list); 694 695 /* 696 * When the last smb_user_t object goes away, schedule a timeout 697 * after which we'll terminate this session if the client hasn't 698 * authenticated another smb_user_t on this session by then. 699 */ 700 if (ucount == 0) { 701 smb_rwx_rwenter(&session->s_lock, RW_WRITER); 702 if (session->s_state == SMB_SESSION_STATE_NEGOTIATED && 703 session->s_auth_tmo == NULL) { 704 session->s_auth_tmo = 705 timeout((tmo_func_t)smb_session_disconnect, 706 session, SEC_TO_TICK(smb_session_auth_tmo)); 707 } 708 smb_rwx_cvbcast(&session->s_lock); 709 smb_rwx_rwexit(&session->s_lock); 710 } 711 712 /* 713 * This user is no longer on s_user_list, however... 714 * 715 * This is called via smb_llist_post, which means it may run 716 * BEFORE smb_user_release drops u_mutex (if another thread 717 * flushes the delete queue before we do). Synchronize. 718 */ 719 mutex_enter(&user->u_mutex); 720 mutex_exit(&user->u_mutex); 721 722 user->u_magic = (uint32_t)~SMB_USER_MAGIC; 723 mutex_destroy(&user->u_mutex); 724 if (user->u_cred) 725 crfree(user->u_cred); 726 if (user->u_privcred) 727 crfree(user->u_privcred); 728 smb_mem_free(user->u_name); 729 smb_mem_free(user->u_domain); 730 kmem_cache_free(smb_cache_user, user); 731 } 732 733 cred_t * 734 smb_user_getcred(smb_user_t *user) 735 { 736 return (user->u_cred); 737 } 738 739 cred_t * 740 smb_user_getprivcred(smb_user_t *user) 741 { 742 return ((user->u_privcred)? user->u_privcred : user->u_cred); 743 } 744 745 #ifdef _KERNEL 746 /* 747 * Assign the user cred and privileges. 748 * 749 * If the user has backup and/or restore privleges, dup the cred 750 * and add those privileges to this new privileged cred. 751 */ 752 void 753 smb_user_setcred(smb_user_t *user, cred_t *cr, uint32_t privileges) 754 { 755 cred_t *privcred = NULL; 756 757 ASSERT(cr); 758 crhold(cr); 759 760 /* 761 * See smb.4 bypass_traverse_checking 762 * 763 * For historical reasons, the Windows privilege is named 764 * SeChangeNotifyPrivilege, though the description is 765 * "Bypass traverse checking". 766 */ 767 if ((privileges & SMB_USER_PRIV_CHANGE_NOTIFY) != 0) { 768 (void) crsetpriv(cr, PRIV_FILE_DAC_SEARCH, NULL); 769 } 770 771 /* 772 * Window's "take ownership privilege" is similar to our 773 * PRIV_FILE_CHOWN privilege. It's normally given to members of the 774 * "Administrators" group, which normally includes the the local 775 * Administrator (like root) and when joined to a domain, 776 * "Domain Admins". 777 */ 778 if ((privileges & SMB_USER_PRIV_TAKE_OWNERSHIP) != 0) { 779 (void) crsetpriv(cr, 780 PRIV_FILE_CHOWN, 781 PRIV_FILE_CHOWN_SELF, 782 NULL); 783 } 784 785 /* 786 * Bypass ACL for READ accesses. 787 */ 788 if ((privileges & SMB_USER_PRIV_READ_FILE) != 0) { 789 (void) crsetpriv(cr, PRIV_FILE_DAC_READ, NULL); 790 } 791 792 /* 793 * Bypass ACL for WRITE accesses. 794 * Include FILE_OWNER, as it covers WRITE_ACL and DELETE. 795 */ 796 if ((privileges & SMB_USER_PRIV_WRITE_FILE) != 0) { 797 (void) crsetpriv(cr, 798 PRIV_FILE_DAC_WRITE, 799 PRIV_FILE_OWNER, 800 NULL); 801 } 802 803 /* 804 * These privileges are used only when a file is opened with 805 * 'backup intent'. These allow users to bypass certain access 806 * controls. Administrators typically have these privileges, 807 * and they are used during recursive take-ownership operations. 808 * Some commonly used tools use 'backup intent' to administrate 809 * files that do not grant explicit permissions to Administrators. 810 */ 811 if (privileges & (SMB_USER_PRIV_BACKUP | SMB_USER_PRIV_RESTORE)) 812 privcred = crdup(cr); 813 814 if (privcred != NULL) { 815 if (privileges & SMB_USER_PRIV_BACKUP) { 816 (void) crsetpriv(privcred, PRIV_FILE_DAC_READ, 817 PRIV_FILE_DAC_SEARCH, PRIV_SYS_MOUNT, NULL); 818 } 819 820 if (privileges & SMB_USER_PRIV_RESTORE) { 821 (void) crsetpriv(privcred, PRIV_FILE_DAC_WRITE, 822 PRIV_FILE_CHOWN, PRIV_FILE_CHOWN_SELF, 823 PRIV_FILE_DAC_SEARCH, PRIV_FILE_LINK_ANY, 824 PRIV_FILE_OWNER, PRIV_FILE_SETID, 825 PRIV_SYS_LINKDIR, PRIV_SYS_MOUNT, NULL); 826 } 827 } 828 829 user->u_cred = cr; 830 user->u_privcred = privcred; 831 user->u_privileges = privileges; 832 } 833 #endif /* _KERNEL */ 834 835 /* 836 * Determines whether a user can be granted ACCESS_SYSTEM_SECURITY 837 */ 838 boolean_t 839 smb_user_has_security_priv(smb_user_t *user, cred_t *cr) 840 { 841 /* Need SeSecurityPrivilege to get/set SACL */ 842 if ((user->u_privileges & SMB_USER_PRIV_SECURITY) != 0) 843 return (B_TRUE); 844 845 #ifdef _KERNEL 846 /* 847 * ACCESS_SYSTEM_SECURITY is also granted if the file is opened with 848 * BACKUP/RESTORE intent by a user with BACKUP/RESTORE privilege, 849 * which means we'll be using u_privcred. 850 * 851 * We translate BACKUP as DAC_READ and RESTORE as DAC_WRITE, 852 * to account for our various SMB_USER_* privileges. 853 */ 854 if (PRIV_POLICY_ONLY(cr, 855 priv_getbyname(PRIV_FILE_DAC_READ, 0), B_FALSE) || 856 PRIV_POLICY_ONLY(cr, 857 priv_getbyname(PRIV_FILE_DAC_WRITE, 0), B_FALSE)) 858 return (B_TRUE); 859 #else 860 /* 861 * No "real" privileges in fksmbsrv, so use the SMB privs instead. 862 */ 863 if ((user->u_privileges & 864 (SMB_USER_PRIV_BACKUP | 865 SMB_USER_PRIV_RESTORE | 866 SMB_USER_PRIV_READ_FILE | 867 SMB_USER_PRIV_WRITE_FILE)) != 0) 868 return (B_TRUE); 869 #endif 870 871 return (B_FALSE); 872 } 873 874 /* 875 * Private function to support smb_user_enum. 876 */ 877 static int 878 smb_user_enum_private(smb_user_t *user, smb_svcenum_t *svcenum) 879 { 880 uint8_t *pb; 881 uint_t nbytes; 882 int rc; 883 884 if (svcenum->se_nskip > 0) { 885 svcenum->se_nskip--; 886 return (0); 887 } 888 889 if (svcenum->se_nitems >= svcenum->se_nlimit) { 890 svcenum->se_nitems = svcenum->se_nlimit; 891 return (0); 892 } 893 894 pb = &svcenum->se_buf[svcenum->se_bused]; 895 rc = smb_user_netinfo_encode(user, pb, svcenum->se_bavail, &nbytes); 896 if (rc == 0) { 897 svcenum->se_bavail -= nbytes; 898 svcenum->se_bused += nbytes; 899 svcenum->se_nitems++; 900 } 901 902 return (rc); 903 } 904 905 /* 906 * Encode the NetInfo for a user into a buffer. NetInfo contains 907 * information that is often needed in user space to support RPC 908 * requests. 909 */ 910 int 911 smb_user_netinfo_encode(smb_user_t *user, uint8_t *buf, size_t buflen, 912 uint32_t *nbytes) 913 { 914 smb_netuserinfo_t info; 915 int rc; 916 917 smb_user_netinfo_init(user, &info); 918 rc = smb_netuserinfo_encode(&info, buf, buflen, nbytes); 919 smb_user_netinfo_fini(&info); 920 921 return (rc); 922 } 923 924 void 925 smb_user_netinfo_init(smb_user_t *user, smb_netuserinfo_t *info) 926 { 927 smb_session_t *session; 928 char *buf; 929 930 ASSERT(user); 931 ASSERT(user->u_domain); 932 ASSERT(user->u_name); 933 934 session = user->u_session; 935 ASSERT(session); 936 ASSERT(session->workstation); 937 938 info->ui_session_id = session->s_kid; 939 info->ui_native_os = session->native_os; 940 info->ui_ipaddr = session->ipaddr; 941 info->ui_numopens = session->s_file_cnt; 942 info->ui_logon_time = user->u_logon_time; 943 info->ui_flags = user->u_flags; 944 info->ui_posix_uid = crgetuid(user->u_cred); 945 946 info->ui_domain_len = user->u_domain_len; 947 info->ui_domain = smb_mem_strdup(user->u_domain); 948 949 info->ui_account_len = user->u_name_len; 950 info->ui_account = smb_mem_strdup(user->u_name); 951 952 buf = kmem_alloc(MAXNAMELEN, KM_SLEEP); 953 smb_session_getclient(session, buf, MAXNAMELEN); 954 info->ui_workstation_len = strlen(buf) + 1; 955 info->ui_workstation = smb_mem_strdup(buf); 956 kmem_free(buf, MAXNAMELEN); 957 } 958 959 void 960 smb_user_netinfo_fini(smb_netuserinfo_t *info) 961 { 962 if (info == NULL) 963 return; 964 965 if (info->ui_domain) 966 smb_mem_free(info->ui_domain); 967 if (info->ui_account) 968 smb_mem_free(info->ui_account); 969 if (info->ui_workstation) 970 smb_mem_free(info->ui_workstation); 971 972 bzero(info, sizeof (smb_netuserinfo_t)); 973 } 974 975 /* 976 * Tell smbd this user is going away so it can clean up their 977 * audit session, autohome dir, etc. 978 * 979 * Note that when we're shutting down, smbd will already have set 980 * smbd.s_shutting_down and therefore will ignore door calls. 981 * Skip this during shutdown to reduce upcall noise. 982 */ 983 static void 984 smb_user_auth_logoff(smb_user_t *user) 985 { 986 smb_server_t *sv = user->u_server; 987 uint32_t audit_sid; 988 989 if (sv->sv_state != SMB_SERVER_STATE_RUNNING) 990 return; 991 992 audit_sid = user->u_audit_sid; 993 (void) smb_kdoor_upcall(sv, SMB_DR_USER_AUTH_LOGOFF, 994 &audit_sid, xdr_uint32_t, NULL, NULL); 995 } 996 997 boolean_t 998 smb_is_same_user(cred_t *cr1, cred_t *cr2) 999 { 1000 ksid_t *ks1 = crgetsid(cr1, KSID_USER); 1001 ksid_t *ks2 = crgetsid(cr2, KSID_USER); 1002 1003 if (ks1 == NULL || ks2 == NULL) { 1004 return (B_FALSE); 1005 } 1006 return (ks1->ks_rid == ks2->ks_rid && 1007 strcmp(ks1->ks_domain->kd_name, ks2->ks_domain->kd_name) == 0); 1008 } 1009