/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved. */ /* * General Structures Layout * ------------------------- * * This is a simplified diagram showing the relationship between most of the * main structures. * * +-------------------+ * | SMB_INFO | * +-------------------+ * | * | * v * +-------------------+ +-------------------+ +-------------------+ * | SESSION |<----->| SESSION |......| SESSION | * +-------------------+ +-------------------+ +-------------------+ * | * | * v * +-------------------+ +-------------------+ +-------------------+ * | USER |<----->| USER |......| USER | * +-------------------+ +-------------------+ +-------------------+ * | * | * v * +-------------------+ +-------------------+ +-------------------+ * | TREE |<----->| TREE |......| TREE | * +-------------------+ +-------------------+ +-------------------+ * | | * | | * | v * | +-------+ +-------+ +-------+ * | | OFILE |<----->| OFILE |......| OFILE | * | +-------+ +-------+ +-------+ * | * | * v * +-------+ +------+ +------+ * | ODIR |<----->| ODIR |......| ODIR | * +-------+ +------+ +------+ * * * User State Machine * ------------------ * * +-----------------------------+ T0 * | SMB_USER_STATE_LOGGED_IN |<----------- Creation/Allocation * +-----------------------------+ * | * | T1 * | * v * +-----------------------------+ * | SMB_USER_STATE_LOGGING_OFF | * +-----------------------------+ * | * | T2 * | * v * +-----------------------------+ T3 * | SMB_USER_STATE_LOGGED_OFF |----------> Deletion/Free * +-----------------------------+ * * SMB_USER_STATE_LOGGED_IN * * While in this state: * - The user is queued in the list of users of his session. * - References will be given out if the user is looked up. * - The user can access files and pipes. * * SMB_USER_STATE_LOGGING_OFF * * While in this state: * - The user is queued in the list of users of his session. * - References will not be given out if the user is looked up. * - The trees the user connected are being disconnected. * - The resources associated with the user remain. * * SMB_USER_STATE_LOGGING_OFF * * While in this state: * - The user is queued in the list of users of his session. * - References will not be given out if the user is looked up. * - The user has no more trees connected. * - The resources associated with the user remain. * * Transition T0 * * This transition occurs in smb_user_login(). A new user is created and * added to the list of users of a session. * * Transition T1 * * This transition occurs in smb_user_logoff(). * * Transition T2 * * This transition occurs in smb_user_release(). The resources associated * with the user are deleted as well as the user. For the transition to * occur, the user must be in the SMB_USER_STATE_LOGGED_OFF state and the * reference count be zero. * * Comments * -------- * * The state machine of the user structures is controlled by 3 elements: * - The list of users of the session he belongs to. * - The mutex embedded in the structure itself. * - The reference count. * * There's a mutex embedded in the user structure used to protect its fields * and there's a lock embedded in the list of users of a session. To * increment or to decrement the reference count the mutex must be entered. * To insert the user into the list of users of the session and to remove * the user from it, the lock must be entered in RW_WRITER mode. * * Rules of access to a user structure: * * 1) In order to avoid deadlocks, when both (mutex and lock of the session * list) have to be entered, the lock must be entered first. * * 2) All actions applied to a user require a reference count. * * 3) There are 2 ways of getting a reference count. One is when the user * logs in. The other when the user is looked up. * * It should be noted that the reference count of a user registers the * number of references to the user in other structures (such as an smb * request). The reference count is not incremented in these 2 instances: * * 1) The user is logged in. An user is anchored by his state. If there's * no activity involving a user currently logged in, the reference * count of that user is zero. * * 2) The user is queued in the list of users of the session. The fact of * being queued in that list is NOT registered by incrementing the * reference count. */ #include #include #define ADMINISTRATORS_SID "S-1-5-32-544" static smb_sid_t *smb_admins_sid = NULL; static boolean_t smb_user_is_logged_in(smb_user_t *); static int smb_user_enum_private(smb_user_t *, smb_svcenum_t *); static smb_tree_t *smb_user_get_tree(smb_llist_t *, smb_tree_t *); static void smb_user_nonauth_logon(uint32_t); static void smb_user_auth_logoff(uint32_t); int smb_user_init(void) { if (smb_admins_sid != NULL) return (0); if ((smb_admins_sid = smb_sid_fromstr(ADMINISTRATORS_SID)) == NULL) return (-1); return (0); } void smb_user_fini(void) { if (smb_admins_sid != NULL) { smb_sid_free(smb_admins_sid); smb_admins_sid = NULL; } } /* * smb_user_login * * */ smb_user_t * smb_user_login( smb_session_t *session, cred_t *cr, char *domain_name, char *account_name, uint32_t flags, uint32_t privileges, uint32_t audit_sid) { smb_user_t *user; ASSERT(session); ASSERT(session->s_magic == SMB_SESSION_MAGIC); ASSERT(cr); ASSERT(account_name); ASSERT(domain_name); user = kmem_cache_alloc(session->s_server->si_cache_user, KM_SLEEP); bzero(user, sizeof (smb_user_t)); user->u_refcnt = 1; user->u_session = session; user->u_server = session->s_server; user->u_logon_time = gethrestime_sec(); user->u_flags = flags; user->u_privileges = privileges; user->u_name_len = strlen(account_name) + 1; user->u_domain_len = strlen(domain_name) + 1; user->u_name = smb_mem_strdup(account_name); user->u_domain = smb_mem_strdup(domain_name); user->u_cred = cr; user->u_privcred = smb_cred_create_privs(cr, privileges); user->u_audit_sid = audit_sid; if (!smb_idpool_alloc(&session->s_uid_pool, &user->u_uid)) { if (!smb_idpool_constructor(&user->u_tid_pool)) { smb_llist_constructor(&user->u_tree_list, sizeof (smb_tree_t), offsetof(smb_tree_t, t_lnd)); mutex_init(&user->u_mutex, NULL, MUTEX_DEFAULT, NULL); crhold(user->u_cred); if (user->u_privcred) crhold(user->u_privcred); user->u_state = SMB_USER_STATE_LOGGED_IN; user->u_magic = SMB_USER_MAGIC; smb_llist_enter(&session->s_user_list, RW_WRITER); smb_llist_insert_tail(&session->s_user_list, user); smb_llist_exit(&session->s_user_list); atomic_inc_32(&session->s_server->sv_open_users); return (user); } smb_idpool_free(&session->s_uid_pool, user->u_uid); } smb_mem_free(user->u_name); smb_mem_free(user->u_domain); kmem_cache_free(session->s_server->si_cache_user, user); return (NULL); } /* * Create a new user based on an existing user, used to support * additional SessionSetupX requests for a user on a session. * * Assumes the caller has a reference on the original user from * a user_lookup_by_x call. */ smb_user_t * smb_user_dup( smb_user_t *orig_user) { smb_user_t *user; ASSERT(orig_user->u_magic == SMB_USER_MAGIC); ASSERT(orig_user->u_refcnt); user = smb_user_login(orig_user->u_session, orig_user->u_cred, orig_user->u_domain, orig_user->u_name, orig_user->u_flags, orig_user->u_privileges, orig_user->u_audit_sid); if (user) smb_user_nonauth_logon(orig_user->u_audit_sid); return (user); } /* * smb_user_logoff * * Change the user state and disconnect trees. * The user list must not be entered or modified here. */ void smb_user_logoff( smb_user_t *user) { ASSERT(user->u_magic == SMB_USER_MAGIC); mutex_enter(&user->u_mutex); ASSERT(user->u_refcnt); switch (user->u_state) { case SMB_USER_STATE_LOGGED_IN: { /* * The user is moved into a state indicating that the log off * process has started. */ user->u_state = SMB_USER_STATE_LOGGING_OFF; mutex_exit(&user->u_mutex); atomic_dec_32(&user->u_server->sv_open_users); /* * All the trees hanging off of this user are disconnected. */ smb_user_disconnect_trees(user); smb_user_auth_logoff(user->u_audit_sid); mutex_enter(&user->u_mutex); user->u_state = SMB_USER_STATE_LOGGED_OFF; break; } case SMB_USER_STATE_LOGGED_OFF: case SMB_USER_STATE_LOGGING_OFF: break; default: ASSERT(0); break; } mutex_exit(&user->u_mutex); } /* * Take a reference on a user. */ boolean_t smb_user_hold(smb_user_t *user) { ASSERT(user); ASSERT(user->u_magic == SMB_USER_MAGIC); mutex_enter(&user->u_mutex); if (smb_user_is_logged_in(user)) { user->u_refcnt++; mutex_exit(&user->u_mutex); return (B_TRUE); } mutex_exit(&user->u_mutex); return (B_FALSE); } /* * Release a reference on a user. If the reference count falls to * zero and the user has logged off, post the object for deletion. * Object deletion is deferred to avoid modifying a list while an * iteration may be in progress. */ void smb_user_release( smb_user_t *user) { ASSERT(user->u_magic == SMB_USER_MAGIC); mutex_enter(&user->u_mutex); ASSERT(user->u_refcnt); user->u_refcnt--; /* flush the tree list's delete queue */ smb_llist_flush(&user->u_tree_list); switch (user->u_state) { case SMB_USER_STATE_LOGGED_OFF: if (user->u_refcnt == 0) smb_session_post_user(user->u_session, user); break; case SMB_USER_STATE_LOGGED_IN: case SMB_USER_STATE_LOGGING_OFF: break; default: ASSERT(0); break; } mutex_exit(&user->u_mutex); } void smb_user_post_tree(smb_user_t *user, smb_tree_t *tree) { SMB_USER_VALID(user); SMB_TREE_VALID(tree); ASSERT(tree->t_refcnt == 0); ASSERT(tree->t_state == SMB_TREE_STATE_DISCONNECTED); ASSERT(tree->t_user == user); smb_llist_post(&user->u_tree_list, tree, smb_tree_dealloc); } /* * Find a tree by tree-id. */ smb_tree_t * smb_user_lookup_tree( smb_user_t *user, uint16_t tid) { smb_tree_t *tree; ASSERT(user); ASSERT(user->u_magic == SMB_USER_MAGIC); smb_llist_enter(&user->u_tree_list, RW_READER); tree = smb_llist_head(&user->u_tree_list); while (tree) { ASSERT(tree->t_magic == SMB_TREE_MAGIC); ASSERT(tree->t_user == user); if (tree->t_tid == tid) { if (smb_tree_hold(tree)) { smb_llist_exit(&user->u_tree_list); return (tree); } else { smb_llist_exit(&user->u_tree_list); return (NULL); } } tree = smb_llist_next(&user->u_tree_list, tree); } smb_llist_exit(&user->u_tree_list); return (NULL); } /* * Find the first connected tree that matches the specified sharename. * If the specified tree is NULL the search starts from the beginning of * the user's tree list. If a tree is provided the search starts just * after that tree. */ smb_tree_t * smb_user_lookup_share( smb_user_t *user, const char *sharename, smb_tree_t *tree) { ASSERT(user); ASSERT(user->u_magic == SMB_USER_MAGIC); ASSERT(sharename); smb_llist_enter(&user->u_tree_list, RW_READER); if (tree) { ASSERT(tree->t_magic == SMB_TREE_MAGIC); ASSERT(tree->t_user == user); tree = smb_llist_next(&user->u_tree_list, tree); } else { tree = smb_llist_head(&user->u_tree_list); } while (tree) { ASSERT(tree->t_magic == SMB_TREE_MAGIC); ASSERT(tree->t_user == user); if (smb_strcasecmp(tree->t_sharename, sharename, 0) == 0) { if (smb_tree_hold(tree)) { smb_llist_exit(&user->u_tree_list); return (tree); } } tree = smb_llist_next(&user->u_tree_list, tree); } smb_llist_exit(&user->u_tree_list); return (NULL); } /* * Find the first connected tree that matches the specified volume name. * If the specified tree is NULL the search starts from the beginning of * the user's tree list. If a tree is provided the search starts just * after that tree. */ smb_tree_t * smb_user_lookup_volume( smb_user_t *user, const char *name, smb_tree_t *tree) { ASSERT(user); ASSERT(user->u_magic == SMB_USER_MAGIC); ASSERT(name); smb_llist_enter(&user->u_tree_list, RW_READER); if (tree) { ASSERT(tree->t_magic == SMB_TREE_MAGIC); ASSERT(tree->t_user == user); tree = smb_llist_next(&user->u_tree_list, tree); } else { tree = smb_llist_head(&user->u_tree_list); } while (tree) { ASSERT(tree->t_magic == SMB_TREE_MAGIC); ASSERT(tree->t_user == user); if (smb_strcasecmp(tree->t_volume, name, 0) == 0) { if (smb_tree_hold(tree)) { smb_llist_exit(&user->u_tree_list); return (tree); } } tree = smb_llist_next(&user->u_tree_list, tree); } smb_llist_exit(&user->u_tree_list); return (NULL); } /* * Disconnect all trees that match the specified client process-id. */ void smb_user_close_pid( smb_user_t *user, uint16_t pid) { smb_tree_t *tree; ASSERT(user); ASSERT(user->u_magic == SMB_USER_MAGIC); tree = smb_user_get_tree(&user->u_tree_list, NULL); while (tree) { smb_tree_t *next; ASSERT(tree->t_user == user); smb_tree_close_pid(tree, pid); next = smb_user_get_tree(&user->u_tree_list, tree); smb_tree_release(tree); tree = next; } } /* * Disconnect all trees that this user has connected. */ void smb_user_disconnect_trees( smb_user_t *user) { smb_tree_t *tree; ASSERT(user); ASSERT(user->u_magic == SMB_USER_MAGIC); tree = smb_user_get_tree(&user->u_tree_list, NULL); while (tree) { ASSERT(tree->t_user == user); smb_tree_disconnect(tree, B_TRUE); smb_tree_release(tree); tree = smb_user_get_tree(&user->u_tree_list, NULL); } } /* * Disconnect all trees that match the specified share name. */ void smb_user_disconnect_share( smb_user_t *user, const char *sharename) { smb_tree_t *tree; smb_tree_t *next; ASSERT(user); ASSERT(user->u_magic == SMB_USER_MAGIC); ASSERT(user->u_refcnt); tree = smb_user_lookup_share(user, sharename, NULL); while (tree) { ASSERT(tree->t_magic == SMB_TREE_MAGIC); smb_session_cancel_requests(user->u_session, tree, NULL); smb_tree_disconnect(tree, B_TRUE); next = smb_user_lookup_share(user, sharename, tree); smb_tree_release(tree); tree = next; } } /* * Close a file by its unique id. */ int smb_user_fclose(smb_user_t *user, uint32_t uniqid) { smb_llist_t *tree_list; smb_tree_t *tree; int rc = ENOENT; ASSERT(user); ASSERT(user->u_magic == SMB_USER_MAGIC); tree_list = &user->u_tree_list; ASSERT(tree_list); smb_llist_enter(tree_list, RW_READER); tree = smb_llist_head(tree_list); while ((tree != NULL) && (rc == ENOENT)) { ASSERT(tree->t_user == user); if (smb_tree_hold(tree)) { rc = smb_tree_fclose(tree, uniqid); smb_tree_release(tree); } tree = smb_llist_next(tree_list, tree); } smb_llist_exit(tree_list); return (rc); } /* * Determine whether or not the user is an administrator. * Members of the administrators group have administrative rights. */ boolean_t smb_user_is_admin( smb_user_t *user) { cred_t *u_cred; ASSERT(user); u_cred = user->u_cred; ASSERT(u_cred); if (smb_admins_sid == NULL) return (B_FALSE); if (smb_cred_is_member(u_cred, smb_admins_sid)) return (B_TRUE); return (B_FALSE); } /* * This function should be called with a hold on the user. */ boolean_t smb_user_namecmp(smb_user_t *user, const char *name) { char *fq_name; boolean_t match; if (smb_strcasecmp(name, user->u_name, 0) == 0) return (B_TRUE); fq_name = kmem_alloc(MAXNAMELEN, KM_SLEEP); (void) snprintf(fq_name, MAXNAMELEN, "%s\\%s", user->u_domain, user->u_name); match = (smb_strcasecmp(name, fq_name, 0) == 0); if (!match) { (void) snprintf(fq_name, MAXNAMELEN, "%s@%s", user->u_name, user->u_domain); match = (smb_strcasecmp(name, fq_name, 0) == 0); } kmem_free(fq_name, MAXNAMELEN); return (match); } /* * If the enumeration request is for user data, handle the request * here. Otherwise, pass it on to the trees. * * This function should be called with a hold on the user. */ int smb_user_enum(smb_user_t *user, smb_svcenum_t *svcenum) { smb_tree_t *tree; smb_tree_t *next; int rc; ASSERT(user); ASSERT(user->u_magic == SMB_USER_MAGIC); if (svcenum->se_type == SMB_SVCENUM_TYPE_USER) return (smb_user_enum_private(user, svcenum)); tree = smb_user_get_tree(&user->u_tree_list, NULL); while (tree) { ASSERT(tree->t_user == user); rc = smb_tree_enum(tree, svcenum); if (rc != 0) { smb_tree_release(tree); break; } next = smb_user_get_tree(&user->u_tree_list, tree); smb_tree_release(tree); tree = next; } return (rc); } /* *************************** Static Functions ***************************** */ /* * Determine whether or not a user is logged in. * Typically, a reference can only be taken on a logged-in user. * * This is a private function and must be called with the user * mutex held. */ static boolean_t smb_user_is_logged_in(smb_user_t *user) { switch (user->u_state) { case SMB_USER_STATE_LOGGED_IN: return (B_TRUE); case SMB_USER_STATE_LOGGING_OFF: case SMB_USER_STATE_LOGGED_OFF: return (B_FALSE); default: ASSERT(0); return (B_FALSE); } } /* * Delete a user. The tree list should be empty. * * Remove the user from the session's user list before freeing resources * associated with the user. */ void smb_user_delete(void *arg) { smb_session_t *session; smb_user_t *user = (smb_user_t *)arg; SMB_USER_VALID(user); ASSERT(user->u_refcnt == 0); ASSERT(user->u_state == SMB_USER_STATE_LOGGED_OFF); session = user->u_session; smb_llist_enter(&session->s_user_list, RW_WRITER); smb_llist_remove(&session->s_user_list, user); smb_idpool_free(&session->s_uid_pool, user->u_uid); smb_llist_exit(&session->s_user_list); mutex_enter(&user->u_mutex); mutex_exit(&user->u_mutex); user->u_magic = (uint32_t)~SMB_USER_MAGIC; mutex_destroy(&user->u_mutex); smb_llist_destructor(&user->u_tree_list); smb_idpool_destructor(&user->u_tid_pool); crfree(user->u_cred); if (user->u_privcred) crfree(user->u_privcred); smb_mem_free(user->u_name); smb_mem_free(user->u_domain); kmem_cache_free(user->u_server->si_cache_user, user); } /* * Get the next connected tree in the list. A reference is taken on * the tree, which can be released later with smb_tree_release(). * * If the specified tree is NULL the search starts from the beginning of * the tree list. If a tree is provided the search starts just after * that tree. * * Returns NULL if there are no connected trees in the list. */ static smb_tree_t * smb_user_get_tree( smb_llist_t *tree_list, smb_tree_t *tree) { ASSERT(tree_list); smb_llist_enter(tree_list, RW_READER); if (tree) { ASSERT(tree->t_magic == SMB_TREE_MAGIC); tree = smb_llist_next(tree_list, tree); } else { tree = smb_llist_head(tree_list); } while (tree) { if (smb_tree_hold(tree)) break; tree = smb_llist_next(tree_list, tree); } smb_llist_exit(tree_list); return (tree); } cred_t * smb_user_getcred(smb_user_t *user) { return (user->u_cred); } cred_t * smb_user_getprivcred(smb_user_t *user) { return ((user->u_privcred)? user->u_privcred : user->u_cred); } /* * Private function to support smb_user_enum. */ static int smb_user_enum_private(smb_user_t *user, smb_svcenum_t *svcenum) { uint8_t *pb; uint_t nbytes; int rc; if (svcenum->se_nskip > 0) { svcenum->se_nskip--; return (0); } if (svcenum->se_nitems >= svcenum->se_nlimit) { svcenum->se_nitems = svcenum->se_nlimit; return (0); } pb = &svcenum->se_buf[svcenum->se_bused]; rc = smb_user_netinfo_encode(user, pb, svcenum->se_bavail, &nbytes); if (rc == 0) { svcenum->se_bavail -= nbytes; svcenum->se_bused += nbytes; svcenum->se_nitems++; } return (rc); } /* * Encode the NetInfo for a user into a buffer. NetInfo contains * information that is often needed in user space to support RPC * requests. */ int smb_user_netinfo_encode(smb_user_t *user, uint8_t *buf, size_t buflen, uint32_t *nbytes) { smb_netuserinfo_t info; int rc; smb_user_netinfo_init(user, &info); rc = smb_netuserinfo_encode(&info, buf, buflen, nbytes); smb_user_netinfo_fini(&info); return (rc); } void smb_user_netinfo_init(smb_user_t *user, smb_netuserinfo_t *info) { smb_session_t *session; char *buf; ASSERT(user); ASSERT(user->u_domain); ASSERT(user->u_name); session = user->u_session; ASSERT(session); ASSERT(session->workstation); info->ui_session_id = session->s_kid; info->ui_native_os = session->native_os; info->ui_ipaddr = session->ipaddr; info->ui_numopens = session->s_file_cnt; info->ui_smb_uid = user->u_uid; info->ui_logon_time = user->u_logon_time; info->ui_flags = user->u_flags; info->ui_posix_uid = crgetuid(user->u_cred); info->ui_domain_len = user->u_domain_len; info->ui_domain = smb_mem_strdup(user->u_domain); info->ui_account_len = user->u_name_len; info->ui_account = smb_mem_strdup(user->u_name); buf = kmem_alloc(MAXNAMELEN, KM_SLEEP); smb_session_getclient(session, buf, MAXNAMELEN); info->ui_workstation_len = strlen(buf) + 1; info->ui_workstation = smb_mem_strdup(buf); kmem_free(buf, MAXNAMELEN); } void smb_user_netinfo_fini(smb_netuserinfo_t *info) { if (info == NULL) return; if (info->ui_domain) smb_mem_free(info->ui_domain); if (info->ui_account) smb_mem_free(info->ui_account); if (info->ui_workstation) smb_mem_free(info->ui_workstation); bzero(info, sizeof (smb_netuserinfo_t)); } static void smb_user_nonauth_logon(uint32_t audit_sid) { (void) smb_kdoor_upcall(SMB_DR_USER_NONAUTH_LOGON, &audit_sid, xdr_uint32_t, NULL, NULL); } static void smb_user_auth_logoff(uint32_t audit_sid) { (void) smb_kdoor_upcall(SMB_DR_USER_AUTH_LOGOFF, &audit_sid, xdr_uint32_t, NULL, NULL); } smb_token_t * smb_get_token(smb_logon_t *user_info) { smb_token_t *token; int rc; token = kmem_zalloc(sizeof (smb_token_t), KM_SLEEP); rc = smb_kdoor_upcall(SMB_DR_USER_AUTH_LOGON, user_info, smb_logon_xdr, token, smb_token_xdr); if (rc != 0) { kmem_free(token, sizeof (smb_token_t)); return (NULL); } if (!smb_token_valid(token)) { smb_token_free(token); return (NULL); } return (token); }