/* * 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 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * Multipath driver interface (MDI) implementation; see mdi_impl.h for a more * detailed discussion of the overall mpxio architecture. * * Default locking order: * * _NOTE(LOCK_ORDER(mdi_mutex, mdi_vhci:vh_phci_mutex); * _NOTE(LOCK_ORDER(mdi_mutex, mdi_vhci:vh_client_mutex); * _NOTE(LOCK_ORDER(mdi_vhci:vh_phci_mutex, mdi_phci::ph_mutex); * _NOTE(LOCK_ORDER(mdi_vhci:vh_client_mutex, mdi_client::ct_mutex); * _NOTE(LOCK_ORDER(mdi_phci::ph_mutex mdi_pathinfo::pi_mutex)) * _NOTE(LOCK_ORDER(mdi_phci::ph_mutex mdi_client::ct_mutex)) * _NOTE(LOCK_ORDER(mdi_client::ct_mutex mdi_pathinfo::pi_mutex)) */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef DEBUG #include int mdi_debug = 1; int mdi_debug_logonly = 0; #define MDI_DEBUG(level, stmnt) \ if (mdi_debug >= (level)) i_mdi_log stmnt static void i_mdi_log(int, dev_info_t *, const char *fmt, ...); #else /* !DEBUG */ #define MDI_DEBUG(level, stmnt) #endif /* DEBUG */ extern pri_t minclsyspri; extern int modrootloaded; /* * Global mutex: * Protects vHCI list and structure members. */ kmutex_t mdi_mutex; /* * Registered vHCI class driver lists */ int mdi_vhci_count; mdi_vhci_t *mdi_vhci_head; mdi_vhci_t *mdi_vhci_tail; /* * Client Hash Table size */ static int mdi_client_table_size = CLIENT_HASH_TABLE_SIZE; /* * taskq interface definitions */ #define MDI_TASKQ_N_THREADS 8 #define MDI_TASKQ_PRI minclsyspri #define MDI_TASKQ_MINALLOC (4*mdi_taskq_n_threads) #define MDI_TASKQ_MAXALLOC (500*mdi_taskq_n_threads) taskq_t *mdi_taskq; static uint_t mdi_taskq_n_threads = MDI_TASKQ_N_THREADS; #define TICKS_PER_SECOND (drv_usectohz(1000000)) /* * The data should be "quiet" for this interval (in seconds) before the * vhci cached data is flushed to the disk. */ static int mdi_vhcache_flush_delay = 10; /* number of seconds the vhcache flush daemon will sleep idle before exiting */ static int mdi_vhcache_flush_daemon_idle_time = 60; /* * MDI falls back to discovery of all paths when a bus_config_one fails. * The following parameters can be used to tune this operation. * * mdi_path_discovery_boot * Number of times path discovery will be attempted during early boot. * Probably there is no reason to ever set this value to greater than one. * * mdi_path_discovery_postboot * Number of times path discovery will be attempted after early boot. * Set it to a minimum of two to allow for discovery of iscsi paths which * may happen very late during booting. * * mdi_path_discovery_interval * Minimum number of seconds MDI will wait between successive discovery * of all paths. Set it to -1 to disable discovery of all paths. */ static int mdi_path_discovery_boot = 1; static int mdi_path_discovery_postboot = 2; static int mdi_path_discovery_interval = 10; /* * number of seconds the asynchronous configuration thread will sleep idle * before exiting. */ static int mdi_async_config_idle_time = 600; static int mdi_bus_config_cache_hash_size = 256; /* turns off multithreaded configuration for certain operations */ static int mdi_mtc_off = 0; /* * The "path" to a pathinfo node is identical to the /devices path to a * devinfo node had the device been enumerated under a pHCI instead of * a vHCI. This pathinfo "path" is associated with a 'path_instance'. * This association persists across create/delete of the pathinfo nodes, * but not across reboot. */ static uint_t mdi_pathmap_instance = 1; /* 0 -> any path */ static int mdi_pathmap_hash_size = 256; static kmutex_t mdi_pathmap_mutex; static mod_hash_t *mdi_pathmap_bypath; /* "path"->instance */ static mod_hash_t *mdi_pathmap_byinstance; /* instance->"path" */ /* * MDI component property name/value string definitions */ const char *mdi_component_prop = "mpxio-component"; const char *mdi_component_prop_vhci = "vhci"; const char *mdi_component_prop_phci = "phci"; const char *mdi_component_prop_client = "client"; /* * MDI client global unique identifier property name */ const char *mdi_client_guid_prop = "client-guid"; /* * MDI client load balancing property name/value string definitions */ const char *mdi_load_balance = "load-balance"; const char *mdi_load_balance_none = "none"; const char *mdi_load_balance_rr = "round-robin"; const char *mdi_load_balance_lba = "logical-block"; /* * Obsolete vHCI class definition; to be removed after Leadville update */ const char *mdi_vhci_class_scsi = MDI_HCI_CLASS_SCSI; static char vhci_greeting[] = "\tThere already exists one vHCI driver for class %s\n" "\tOnly one vHCI driver for each class is allowed\n"; /* * Static function prototypes */ static int i_mdi_phci_offline(dev_info_t *, uint_t); static int i_mdi_client_offline(dev_info_t *, uint_t); static int i_mdi_phci_pre_detach(dev_info_t *, ddi_detach_cmd_t); static void i_mdi_phci_post_detach(dev_info_t *, ddi_detach_cmd_t, int); static int i_mdi_client_pre_detach(dev_info_t *, ddi_detach_cmd_t); static void i_mdi_client_post_detach(dev_info_t *, ddi_detach_cmd_t, int); static void i_mdi_pm_hold_pip(mdi_pathinfo_t *); static void i_mdi_pm_rele_pip(mdi_pathinfo_t *); static int i_mdi_lba_lb(mdi_client_t *ct, mdi_pathinfo_t **ret_pip, struct buf *buf); static void i_mdi_pm_hold_client(mdi_client_t *, int); static void i_mdi_pm_rele_client(mdi_client_t *, int); static void i_mdi_pm_reset_client(mdi_client_t *); static int i_mdi_power_all_phci(mdi_client_t *); static void i_mdi_log_sysevent(dev_info_t *, char *, char *); /* * Internal mdi_pathinfo node functions */ static void i_mdi_pi_kstat_destroy(mdi_pathinfo_t *); static mdi_vhci_t *i_mdi_vhci_class2vhci(char *); static mdi_vhci_t *i_devi_get_vhci(dev_info_t *); static mdi_phci_t *i_devi_get_phci(dev_info_t *); static void i_mdi_phci_lock(mdi_phci_t *, mdi_pathinfo_t *); static void i_mdi_phci_unlock(mdi_phci_t *); static mdi_pathinfo_t *i_mdi_pi_alloc(mdi_phci_t *, char *, mdi_client_t *); static void i_mdi_phci_add_path(mdi_phci_t *, mdi_pathinfo_t *); static void i_mdi_client_add_path(mdi_client_t *, mdi_pathinfo_t *); static void i_mdi_pi_free(mdi_phci_t *ph, mdi_pathinfo_t *, mdi_client_t *); static void i_mdi_phci_remove_path(mdi_phci_t *, mdi_pathinfo_t *); static void i_mdi_client_remove_path(mdi_client_t *, mdi_pathinfo_t *); static int i_mdi_pi_state_change(mdi_pathinfo_t *, mdi_pathinfo_state_t, int); static int i_mdi_pi_offline(mdi_pathinfo_t *, int); static dev_info_t *i_mdi_devinfo_create(mdi_vhci_t *, char *, char *, char **, int); static dev_info_t *i_mdi_devinfo_find(mdi_vhci_t *, char *, char *); static int i_mdi_devinfo_remove(dev_info_t *, dev_info_t *, int); static int i_mdi_is_child_present(dev_info_t *, dev_info_t *); static mdi_client_t *i_mdi_client_alloc(mdi_vhci_t *, char *, char *); static void i_mdi_client_enlist_table(mdi_vhci_t *, mdi_client_t *); static void i_mdi_client_delist_table(mdi_vhci_t *, mdi_client_t *); static mdi_client_t *i_mdi_client_find(mdi_vhci_t *, char *, char *); static void i_mdi_client_update_state(mdi_client_t *); static int i_mdi_client_compute_state(mdi_client_t *, mdi_phci_t *); static void i_mdi_client_lock(mdi_client_t *, mdi_pathinfo_t *); static void i_mdi_client_unlock(mdi_client_t *); static int i_mdi_client_free(mdi_vhci_t *, mdi_client_t *); static mdi_client_t *i_devi_get_client(dev_info_t *); /* * NOTE: this will be removed once the NWS files are changed to use the new * mdi_{enable,disable}_path interfaces */ static int i_mdi_pi_enable_disable(dev_info_t *, dev_info_t *, int, int); static mdi_pathinfo_t *i_mdi_enable_disable_path(mdi_pathinfo_t *pip, mdi_vhci_t *vh, int flags, int op); /* * Failover related function prototypes */ static int i_mdi_failover(void *); /* * misc internal functions */ static int i_mdi_get_hash_key(char *); static int i_map_nvlist_error_to_mdi(int); static void i_mdi_report_path_state(mdi_client_t *, mdi_pathinfo_t *); static void setup_vhci_cache(mdi_vhci_t *); static int destroy_vhci_cache(mdi_vhci_t *); static int stop_vhcache_async_threads(mdi_vhci_config_t *); static boolean_t stop_vhcache_flush_thread(void *, int); static void free_string_array(char **, int); static void free_vhcache_phci(mdi_vhcache_phci_t *); static void free_vhcache_pathinfo(mdi_vhcache_pathinfo_t *); static void free_vhcache_client(mdi_vhcache_client_t *); static int mainnvl_to_vhcache(mdi_vhci_cache_t *, nvlist_t *); static nvlist_t *vhcache_to_mainnvl(mdi_vhci_cache_t *); static void vhcache_phci_add(mdi_vhci_config_t *, mdi_phci_t *); static void vhcache_phci_remove(mdi_vhci_config_t *, mdi_phci_t *); static void vhcache_pi_add(mdi_vhci_config_t *, struct mdi_pathinfo *); static void vhcache_pi_remove(mdi_vhci_config_t *, struct mdi_pathinfo *); static void free_phclient_path_list(mdi_phys_path_t *); static void sort_vhcache_paths(mdi_vhcache_client_t *); static int flush_vhcache(mdi_vhci_config_t *, int); static void vhcache_dirty(mdi_vhci_config_t *); static void free_async_client_config(mdi_async_client_config_t *); static void single_threaded_vhconfig_enter(mdi_vhci_config_t *); static void single_threaded_vhconfig_exit(mdi_vhci_config_t *); static nvlist_t *read_on_disk_vhci_cache(char *); extern int fread_nvlist(char *, nvlist_t **); extern int fwrite_nvlist(char *, nvlist_t *); /* called once when first vhci registers with mdi */ static void i_mdi_init() { static int initialized = 0; if (initialized) return; initialized = 1; mutex_init(&mdi_mutex, NULL, MUTEX_DEFAULT, NULL); /* Create our taskq resources */ mdi_taskq = taskq_create("mdi_taskq", mdi_taskq_n_threads, MDI_TASKQ_PRI, MDI_TASKQ_MINALLOC, MDI_TASKQ_MAXALLOC, TASKQ_PREPOPULATE | TASKQ_CPR_SAFE); ASSERT(mdi_taskq != NULL); /* taskq_create never fails */ /* Allocate ['path_instance' <-> "path"] maps */ mutex_init(&mdi_pathmap_mutex, NULL, MUTEX_DRIVER, NULL); mdi_pathmap_bypath = mod_hash_create_strhash( "mdi_pathmap_bypath", mdi_pathmap_hash_size, mod_hash_null_valdtor); mdi_pathmap_byinstance = mod_hash_create_idhash( "mdi_pathmap_byinstance", mdi_pathmap_hash_size, mod_hash_null_valdtor); } /* * mdi_get_component_type(): * Return mpxio component type * Return Values: * MDI_COMPONENT_NONE * MDI_COMPONENT_VHCI * MDI_COMPONENT_PHCI * MDI_COMPONENT_CLIENT * XXX This doesn't work under multi-level MPxIO and should be * removed when clients migrate mdi_component_is_*() interfaces. */ int mdi_get_component_type(dev_info_t *dip) { return (DEVI(dip)->devi_mdi_component); } /* * mdi_vhci_register(): * Register a vHCI module with the mpxio framework * mdi_vhci_register() is called by vHCI drivers to register the * 'class_driver' vHCI driver and its MDI entrypoints with the * mpxio framework. The vHCI driver must call this interface as * part of its attach(9e) handler. * Competing threads may try to attach mdi_vhci_register() as * the vHCI drivers are loaded and attached as a result of pHCI * driver instance registration (mdi_phci_register()) with the * framework. * Return Values: * MDI_SUCCESS * MDI_FAILURE */ /*ARGSUSED*/ int mdi_vhci_register(char *class, dev_info_t *vdip, mdi_vhci_ops_t *vops, int flags) { mdi_vhci_t *vh = NULL; ASSERT(vops->vo_revision == MDI_VHCI_OPS_REV); ASSERT(DEVI_BUSY_OWNED(ddi_get_parent(vdip))); i_mdi_init(); mutex_enter(&mdi_mutex); /* * Scan for already registered vhci */ for (vh = mdi_vhci_head; vh != NULL; vh = vh->vh_next) { if (strcmp(vh->vh_class, class) == 0) { /* * vHCI has already been created. Check for valid * vHCI ops registration. We only support one vHCI * module per class */ if (vh->vh_ops != NULL) { mutex_exit(&mdi_mutex); cmn_err(CE_NOTE, vhci_greeting, class); return (MDI_FAILURE); } break; } } /* * if not yet created, create the vHCI component */ if (vh == NULL) { struct client_hash *hash = NULL; char *load_balance; /* * Allocate and initialize the mdi extensions */ vh = kmem_zalloc(sizeof (mdi_vhci_t), KM_SLEEP); hash = kmem_zalloc(mdi_client_table_size * sizeof (*hash), KM_SLEEP); vh->vh_client_table = hash; vh->vh_class = kmem_zalloc(strlen(class) + 1, KM_SLEEP); (void) strcpy(vh->vh_class, class); vh->vh_lb = LOAD_BALANCE_RR; if (ddi_prop_lookup_string(DDI_DEV_T_ANY, vdip, 0, LOAD_BALANCE_PROP, &load_balance) == DDI_SUCCESS) { if (strcmp(load_balance, LOAD_BALANCE_PROP_NONE) == 0) { vh->vh_lb = LOAD_BALANCE_NONE; } else if (strcmp(load_balance, LOAD_BALANCE_PROP_LBA) == 0) { vh->vh_lb = LOAD_BALANCE_LBA; } ddi_prop_free(load_balance); } mutex_init(&vh->vh_phci_mutex, NULL, MUTEX_DEFAULT, NULL); mutex_init(&vh->vh_client_mutex, NULL, MUTEX_DEFAULT, NULL); /* * Store the vHCI ops vectors */ vh->vh_dip = vdip; vh->vh_ops = vops; setup_vhci_cache(vh); if (mdi_vhci_head == NULL) { mdi_vhci_head = vh; } if (mdi_vhci_tail) { mdi_vhci_tail->vh_next = vh; } mdi_vhci_tail = vh; mdi_vhci_count++; } /* * Claim the devfs node as a vhci component */ DEVI(vdip)->devi_mdi_component |= MDI_COMPONENT_VHCI; /* * Initialize our back reference from dev_info node */ DEVI(vdip)->devi_mdi_xhci = (caddr_t)vh; mutex_exit(&mdi_mutex); return (MDI_SUCCESS); } /* * mdi_vhci_unregister(): * Unregister a vHCI module from mpxio framework * mdi_vhci_unregister() is called from the detach(9E) entrypoint * of a vhci to unregister it from the framework. * Return Values: * MDI_SUCCESS * MDI_FAILURE */ /*ARGSUSED*/ int mdi_vhci_unregister(dev_info_t *vdip, int flags) { mdi_vhci_t *found, *vh, *prev = NULL; ASSERT(DEVI_BUSY_OWNED(ddi_get_parent(vdip))); /* * Check for invalid VHCI */ if ((vh = i_devi_get_vhci(vdip)) == NULL) return (MDI_FAILURE); /* * Scan the list of registered vHCIs for a match */ mutex_enter(&mdi_mutex); for (found = mdi_vhci_head; found != NULL; found = found->vh_next) { if (found == vh) break; prev = found; } if (found == NULL) { mutex_exit(&mdi_mutex); return (MDI_FAILURE); } /* * Check the vHCI, pHCI and client count. All the pHCIs and clients * should have been unregistered, before a vHCI can be * unregistered. */ MDI_VHCI_PHCI_LOCK(vh); if (vh->vh_refcnt || vh->vh_phci_count || vh->vh_client_count) { MDI_VHCI_PHCI_UNLOCK(vh); mutex_exit(&mdi_mutex); return (MDI_FAILURE); } MDI_VHCI_PHCI_UNLOCK(vh); if (destroy_vhci_cache(vh) != MDI_SUCCESS) { mutex_exit(&mdi_mutex); return (MDI_FAILURE); } /* * Remove the vHCI from the global list */ if (vh == mdi_vhci_head) { mdi_vhci_head = vh->vh_next; } else { prev->vh_next = vh->vh_next; } if (vh == mdi_vhci_tail) { mdi_vhci_tail = prev; } mdi_vhci_count--; mutex_exit(&mdi_mutex); vh->vh_ops = NULL; DEVI(vdip)->devi_mdi_component &= ~MDI_COMPONENT_VHCI; DEVI(vdip)->devi_mdi_xhci = NULL; kmem_free(vh->vh_class, strlen(vh->vh_class)+1); kmem_free(vh->vh_client_table, mdi_client_table_size * sizeof (struct client_hash)); mutex_destroy(&vh->vh_phci_mutex); mutex_destroy(&vh->vh_client_mutex); kmem_free(vh, sizeof (mdi_vhci_t)); return (MDI_SUCCESS); } /* * i_mdi_vhci_class2vhci(): * Look for a matching vHCI module given a vHCI class name * Return Values: * Handle to a vHCI component * NULL */ static mdi_vhci_t * i_mdi_vhci_class2vhci(char *class) { mdi_vhci_t *vh = NULL; ASSERT(!MUTEX_HELD(&mdi_mutex)); mutex_enter(&mdi_mutex); for (vh = mdi_vhci_head; vh != NULL; vh = vh->vh_next) { if (strcmp(vh->vh_class, class) == 0) { break; } } mutex_exit(&mdi_mutex); return (vh); } /* * i_devi_get_vhci(): * Utility function to get the handle to a vHCI component * Return Values: * Handle to a vHCI component * NULL */ mdi_vhci_t * i_devi_get_vhci(dev_info_t *vdip) { mdi_vhci_t *vh = NULL; if (MDI_VHCI(vdip)) { vh = (mdi_vhci_t *)DEVI(vdip)->devi_mdi_xhci; } return (vh); } /* * mdi_phci_register(): * Register a pHCI module with mpxio framework * mdi_phci_register() is called by pHCI drivers to register with * the mpxio framework and a specific 'class_driver' vHCI. The * pHCI driver must call this interface as part of its attach(9e) * handler. * Return Values: * MDI_SUCCESS * MDI_FAILURE */ /*ARGSUSED*/ int mdi_phci_register(char *class, dev_info_t *pdip, int flags) { mdi_phci_t *ph; mdi_vhci_t *vh; char *data; char *pathname; /* * Some subsystems, like fcp, perform pHCI registration from a * different thread than the one doing the pHCI attach(9E) - the * driver attach code is waiting for this other thread to complete. * This means we can only ASSERT DEVI_BUSY_CHANGING of parent * (indicating that some thread has done an ndi_devi_enter of parent) * not DEVI_BUSY_OWNED (which would indicate that we did the enter). */ ASSERT(DEVI_BUSY_CHANGING(ddi_get_parent(pdip))); pathname = kmem_zalloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(pdip, pathname); /* * Check for mpxio-disable property. Enable mpxio if the property is * missing or not set to "yes". * If the property is set to "yes" then emit a brief message. */ if ((ddi_prop_lookup_string(DDI_DEV_T_ANY, pdip, 0, "mpxio-disable", &data) == DDI_SUCCESS)) { if (strcmp(data, "yes") == 0) { MDI_DEBUG(1, (CE_CONT, pdip, "?%s (%s%d) multipath capabilities " "disabled via %s.conf.\n", pathname, ddi_driver_name(pdip), ddi_get_instance(pdip), ddi_driver_name(pdip))); ddi_prop_free(data); kmem_free(pathname, MAXPATHLEN); return (MDI_FAILURE); } ddi_prop_free(data); } kmem_free(pathname, MAXPATHLEN); /* * Search for a matching vHCI */ vh = (mdi_vhci_t *)i_mdi_vhci_class2vhci(class); if (vh == NULL) { return (MDI_FAILURE); } ph = kmem_zalloc(sizeof (mdi_phci_t), KM_SLEEP); mutex_init(&ph->ph_mutex, NULL, MUTEX_DEFAULT, NULL); ph->ph_dip = pdip; ph->ph_vhci = vh; ph->ph_next = NULL; ph->ph_unstable = 0; ph->ph_vprivate = 0; cv_init(&ph->ph_unstable_cv, NULL, CV_DRIVER, NULL); MDI_PHCI_LOCK(ph); MDI_PHCI_SET_POWER_UP(ph); MDI_PHCI_UNLOCK(ph); DEVI(pdip)->devi_mdi_component |= MDI_COMPONENT_PHCI; DEVI(pdip)->devi_mdi_xhci = (caddr_t)ph; vhcache_phci_add(vh->vh_config, ph); MDI_VHCI_PHCI_LOCK(vh); if (vh->vh_phci_head == NULL) { vh->vh_phci_head = ph; } if (vh->vh_phci_tail) { vh->vh_phci_tail->ph_next = ph; } vh->vh_phci_tail = ph; vh->vh_phci_count++; MDI_VHCI_PHCI_UNLOCK(vh); i_mdi_log_sysevent(pdip, class, ESC_DDI_INITIATOR_REGISTER); return (MDI_SUCCESS); } /* * mdi_phci_unregister(): * Unregister a pHCI module from mpxio framework * mdi_phci_unregister() is called by the pHCI drivers from their * detach(9E) handler to unregister their instances from the * framework. * Return Values: * MDI_SUCCESS * MDI_FAILURE */ /*ARGSUSED*/ int mdi_phci_unregister(dev_info_t *pdip, int flags) { mdi_vhci_t *vh; mdi_phci_t *ph; mdi_phci_t *tmp; mdi_phci_t *prev = NULL; ASSERT(DEVI_BUSY_CHANGING(ddi_get_parent(pdip))); ph = i_devi_get_phci(pdip); if (ph == NULL) { MDI_DEBUG(1, (CE_WARN, pdip, "!pHCI unregister: Not a valid pHCI")); return (MDI_FAILURE); } vh = ph->ph_vhci; ASSERT(vh != NULL); if (vh == NULL) { MDI_DEBUG(1, (CE_WARN, pdip, "!pHCI unregister: Not a valid vHCI")); return (MDI_FAILURE); } MDI_VHCI_PHCI_LOCK(vh); tmp = vh->vh_phci_head; while (tmp) { if (tmp == ph) { break; } prev = tmp; tmp = tmp->ph_next; } if (ph == vh->vh_phci_head) { vh->vh_phci_head = ph->ph_next; } else { prev->ph_next = ph->ph_next; } if (ph == vh->vh_phci_tail) { vh->vh_phci_tail = prev; } vh->vh_phci_count--; MDI_VHCI_PHCI_UNLOCK(vh); i_mdi_log_sysevent(pdip, ph->ph_vhci->vh_class, ESC_DDI_INITIATOR_UNREGISTER); vhcache_phci_remove(vh->vh_config, ph); cv_destroy(&ph->ph_unstable_cv); mutex_destroy(&ph->ph_mutex); kmem_free(ph, sizeof (mdi_phci_t)); DEVI(pdip)->devi_mdi_component &= ~MDI_COMPONENT_PHCI; DEVI(pdip)->devi_mdi_xhci = NULL; return (MDI_SUCCESS); } /* * i_devi_get_phci(): * Utility function to return the phci extensions. */ static mdi_phci_t * i_devi_get_phci(dev_info_t *pdip) { mdi_phci_t *ph = NULL; if (MDI_PHCI(pdip)) { ph = (mdi_phci_t *)DEVI(pdip)->devi_mdi_xhci; } return (ph); } /* * Single thread mdi entry into devinfo node for modifying its children. * If necessary we perform an ndi_devi_enter of the vHCI before doing * an ndi_devi_enter of 'dip'. We maintain circular in two parts: one * for the vHCI and one for the pHCI. */ void mdi_devi_enter(dev_info_t *phci_dip, int *circular) { dev_info_t *vdip; int vcircular, pcircular; /* Verify calling context */ ASSERT(MDI_PHCI(phci_dip)); vdip = mdi_devi_get_vdip(phci_dip); ASSERT(vdip); /* A pHCI always has a vHCI */ /* * If pHCI is detaching then the framework has already entered the * vHCI on a threads that went down the code path leading to * detach_node(). This framework enter of the vHCI during pHCI * detach is done to avoid deadlock with vHCI power management * operations which enter the vHCI and the enter down the path * to the pHCI. If pHCI is detaching then we piggyback this calls * enter of the vHCI on frameworks vHCI enter that has already * occurred - this is OK because we know that the framework thread * doing detach is waiting for our completion. * * We should DEVI_IS_DETACHING under an enter of the parent to avoid * race with detach - but we can't do that because the framework has * already entered the parent, so we have some complexity instead. */ for (;;) { if (ndi_devi_tryenter(vdip, &vcircular)) { ASSERT(vcircular != -1); if (DEVI_IS_DETACHING(phci_dip)) { ndi_devi_exit(vdip, vcircular); vcircular = -1; } break; } else if (DEVI_IS_DETACHING(phci_dip)) { vcircular = -1; break; } else { delay(1); } } ndi_devi_enter(phci_dip, &pcircular); *circular = (vcircular << 16) | (pcircular & 0xFFFF); } /* * Release mdi_devi_enter or successful mdi_devi_tryenter. */ void mdi_devi_exit(dev_info_t *phci_dip, int circular) { dev_info_t *vdip; int vcircular, pcircular; /* Verify calling context */ ASSERT(MDI_PHCI(phci_dip)); vdip = mdi_devi_get_vdip(phci_dip); ASSERT(vdip); /* A pHCI always has a vHCI */ /* extract two circular recursion values from single int */ pcircular = (short)(circular & 0xFFFF); vcircular = (short)((circular >> 16) & 0xFFFF); ndi_devi_exit(phci_dip, pcircular); if (vcircular != -1) ndi_devi_exit(vdip, vcircular); } /* * The functions mdi_devi_exit_phci() and mdi_devi_enter_phci() are used * around a pHCI drivers calls to mdi_pi_online/offline, after holding * the pathinfo node via mdi_hold_path/mdi_rele_path, to avoid deadlock * with vHCI power management code during path online/offline. Each * mdi_devi_exit_phci must have a matching mdi_devi_enter_phci, and both must * occur within the scope of an active mdi_devi_enter that establishes the * circular value. */ void mdi_devi_exit_phci(dev_info_t *phci_dip, int circular) { int pcircular; /* Verify calling context */ ASSERT(MDI_PHCI(phci_dip)); pcircular = (short)(circular & 0xFFFF); ndi_devi_exit(phci_dip, pcircular); } void mdi_devi_enter_phci(dev_info_t *phci_dip, int *circular) { int pcircular; /* Verify calling context */ ASSERT(MDI_PHCI(phci_dip)); ndi_devi_enter(phci_dip, &pcircular); /* verify matching mdi_devi_exit_phci/mdi_devi_enter_phci use */ ASSERT(pcircular == ((short)(*circular & 0xFFFF))); } /* * mdi_devi_get_vdip(): * given a pHCI dip return vHCI dip */ dev_info_t * mdi_devi_get_vdip(dev_info_t *pdip) { mdi_phci_t *ph; ph = i_devi_get_phci(pdip); if (ph && ph->ph_vhci) return (ph->ph_vhci->vh_dip); return (NULL); } /* * mdi_devi_pdip_entered(): * Return 1 if we are vHCI and have done an ndi_devi_enter * of a pHCI */ int mdi_devi_pdip_entered(dev_info_t *vdip) { mdi_vhci_t *vh; mdi_phci_t *ph; vh = i_devi_get_vhci(vdip); if (vh == NULL) return (0); MDI_VHCI_PHCI_LOCK(vh); ph = vh->vh_phci_head; while (ph) { if (ph->ph_dip && DEVI_BUSY_OWNED(ph->ph_dip)) { MDI_VHCI_PHCI_UNLOCK(vh); return (1); } ph = ph->ph_next; } MDI_VHCI_PHCI_UNLOCK(vh); return (0); } /* * mdi_phci_path2devinfo(): * Utility function to search for a valid phci device given * the devfs pathname. */ dev_info_t * mdi_phci_path2devinfo(dev_info_t *vdip, caddr_t pathname) { char *temp_pathname; mdi_vhci_t *vh; mdi_phci_t *ph; dev_info_t *pdip = NULL; vh = i_devi_get_vhci(vdip); ASSERT(vh != NULL); if (vh == NULL) { /* * Invalid vHCI component, return failure */ return (NULL); } temp_pathname = kmem_zalloc(MAXPATHLEN, KM_SLEEP); MDI_VHCI_PHCI_LOCK(vh); ph = vh->vh_phci_head; while (ph != NULL) { pdip = ph->ph_dip; ASSERT(pdip != NULL); *temp_pathname = '\0'; (void) ddi_pathname(pdip, temp_pathname); if (strcmp(temp_pathname, pathname) == 0) { break; } ph = ph->ph_next; } if (ph == NULL) { pdip = NULL; } MDI_VHCI_PHCI_UNLOCK(vh); kmem_free(temp_pathname, MAXPATHLEN); return (pdip); } /* * mdi_phci_get_path_count(): * get number of path information nodes associated with a given * pHCI device. */ int mdi_phci_get_path_count(dev_info_t *pdip) { mdi_phci_t *ph; int count = 0; ph = i_devi_get_phci(pdip); if (ph != NULL) { count = ph->ph_path_count; } return (count); } /* * i_mdi_phci_lock(): * Lock a pHCI device * Return Values: * None * Note: * The default locking order is: * _NOTE(LOCK_ORDER(mdi_phci::ph_mutex mdi_pathinfo::pi_mutex)) * But there are number of situations where locks need to be * grabbed in reverse order. This routine implements try and lock * mechanism depending on the requested parameter option. */ static void i_mdi_phci_lock(mdi_phci_t *ph, mdi_pathinfo_t *pip) { if (pip) { /* Reverse locking is requested. */ while (MDI_PHCI_TRYLOCK(ph) == 0) { /* * tryenter failed. Try to grab again * after a small delay */ MDI_PI_HOLD(pip); MDI_PI_UNLOCK(pip); delay(1); MDI_PI_LOCK(pip); MDI_PI_RELE(pip); } } else { MDI_PHCI_LOCK(ph); } } /* * i_mdi_phci_unlock(): * Unlock the pHCI component */ static void i_mdi_phci_unlock(mdi_phci_t *ph) { MDI_PHCI_UNLOCK(ph); } /* * i_mdi_devinfo_create(): * create client device's devinfo node * Return Values: * dev_info * NULL * Notes: */ static dev_info_t * i_mdi_devinfo_create(mdi_vhci_t *vh, char *name, char *guid, char **compatible, int ncompatible) { dev_info_t *cdip = NULL; ASSERT(MDI_VHCI_CLIENT_LOCKED(vh)); /* Verify for duplicate entry */ cdip = i_mdi_devinfo_find(vh, name, guid); ASSERT(cdip == NULL); if (cdip) { cmn_err(CE_WARN, "i_mdi_devinfo_create: client dip %p already exists", (void *)cdip); } ndi_devi_alloc_sleep(vh->vh_dip, name, DEVI_SID_NODEID, &cdip); if (cdip == NULL) goto fail; /* * Create component type and Global unique identifier * properties */ if (ndi_prop_update_string(DDI_DEV_T_NONE, cdip, MDI_CLIENT_GUID_PROP, guid) != DDI_PROP_SUCCESS) { goto fail; } /* Decorate the node with compatible property */ if (compatible && (ndi_prop_update_string_array(DDI_DEV_T_NONE, cdip, "compatible", compatible, ncompatible) != DDI_PROP_SUCCESS)) { goto fail; } return (cdip); fail: if (cdip) { (void) ndi_prop_remove_all(cdip); (void) ndi_devi_free(cdip); } return (NULL); } /* * i_mdi_devinfo_find(): * Find a matching devinfo node for given client node name * and its guid. * Return Values: * Handle to a dev_info node or NULL */ static dev_info_t * i_mdi_devinfo_find(mdi_vhci_t *vh, caddr_t name, char *guid) { char *data; dev_info_t *cdip = NULL; dev_info_t *ndip = NULL; int circular; ndi_devi_enter(vh->vh_dip, &circular); ndip = (dev_info_t *)DEVI(vh->vh_dip)->devi_child; while ((cdip = ndip) != NULL) { ndip = (dev_info_t *)DEVI(cdip)->devi_sibling; if (strcmp(DEVI(cdip)->devi_node_name, name)) { continue; } if (ddi_prop_lookup_string(DDI_DEV_T_ANY, cdip, DDI_PROP_DONTPASS, MDI_CLIENT_GUID_PROP, &data) != DDI_PROP_SUCCESS) { continue; } if (strcmp(data, guid) != 0) { ddi_prop_free(data); continue; } ddi_prop_free(data); break; } ndi_devi_exit(vh->vh_dip, circular); return (cdip); } /* * i_mdi_devinfo_remove(): * Remove a client device node */ static int i_mdi_devinfo_remove(dev_info_t *vdip, dev_info_t *cdip, int flags) { int rv = MDI_SUCCESS; if (i_mdi_is_child_present(vdip, cdip) == MDI_SUCCESS || (flags & MDI_CLIENT_FLAGS_DEV_NOT_SUPPORTED)) { rv = ndi_devi_offline(cdip, NDI_DEVI_REMOVE); if (rv != NDI_SUCCESS) { MDI_DEBUG(1, (CE_NOTE, NULL, "!i_mdi_devinfo_remove:" " failed. cdip = %p\n", (void *)cdip)); } /* * Convert to MDI error code */ switch (rv) { case NDI_SUCCESS: rv = MDI_SUCCESS; break; case NDI_BUSY: rv = MDI_BUSY; break; default: rv = MDI_FAILURE; break; } } return (rv); } /* * i_devi_get_client() * Utility function to get mpxio component extensions */ static mdi_client_t * i_devi_get_client(dev_info_t *cdip) { mdi_client_t *ct = NULL; if (MDI_CLIENT(cdip)) { ct = (mdi_client_t *)DEVI(cdip)->devi_mdi_client; } return (ct); } /* * i_mdi_is_child_present(): * Search for the presence of client device dev_info node */ static int i_mdi_is_child_present(dev_info_t *vdip, dev_info_t *cdip) { int rv = MDI_FAILURE; struct dev_info *dip; int circular; ndi_devi_enter(vdip, &circular); dip = DEVI(vdip)->devi_child; while (dip) { if (dip == DEVI(cdip)) { rv = MDI_SUCCESS; break; } dip = dip->devi_sibling; } ndi_devi_exit(vdip, circular); return (rv); } /* * i_mdi_client_lock(): * Grab client component lock * Return Values: * None * Note: * The default locking order is: * _NOTE(LOCK_ORDER(mdi_client::ct_mutex mdi_pathinfo::pi_mutex)) * But there are number of situations where locks need to be * grabbed in reverse order. This routine implements try and lock * mechanism depending on the requested parameter option. */ static void i_mdi_client_lock(mdi_client_t *ct, mdi_pathinfo_t *pip) { if (pip) { /* * Reverse locking is requested. */ while (MDI_CLIENT_TRYLOCK(ct) == 0) { /* * tryenter failed. Try to grab again * after a small delay */ MDI_PI_HOLD(pip); MDI_PI_UNLOCK(pip); delay(1); MDI_PI_LOCK(pip); MDI_PI_RELE(pip); } } else { MDI_CLIENT_LOCK(ct); } } /* * i_mdi_client_unlock(): * Unlock a client component */ static void i_mdi_client_unlock(mdi_client_t *ct) { MDI_CLIENT_UNLOCK(ct); } /* * i_mdi_client_alloc(): * Allocate and initialize a client structure. Caller should * hold the vhci client lock. * Return Values: * Handle to a client component */ /*ARGSUSED*/ static mdi_client_t * i_mdi_client_alloc(mdi_vhci_t *vh, char *name, char *lguid) { mdi_client_t *ct; ASSERT(MDI_VHCI_CLIENT_LOCKED(vh)); /* * Allocate and initialize a component structure. */ ct = kmem_zalloc(sizeof (*ct), KM_SLEEP); mutex_init(&ct->ct_mutex, NULL, MUTEX_DEFAULT, NULL); ct->ct_hnext = NULL; ct->ct_hprev = NULL; ct->ct_dip = NULL; ct->ct_vhci = vh; ct->ct_drvname = kmem_alloc(strlen(name) + 1, KM_SLEEP); (void) strcpy(ct->ct_drvname, name); ct->ct_guid = kmem_alloc(strlen(lguid) + 1, KM_SLEEP); (void) strcpy(ct->ct_guid, lguid); ct->ct_cprivate = NULL; ct->ct_vprivate = NULL; ct->ct_flags = 0; ct->ct_state = MDI_CLIENT_STATE_FAILED; MDI_CLIENT_LOCK(ct); MDI_CLIENT_SET_OFFLINE(ct); MDI_CLIENT_SET_DETACH(ct); MDI_CLIENT_SET_POWER_UP(ct); MDI_CLIENT_UNLOCK(ct); ct->ct_failover_flags = 0; ct->ct_failover_status = 0; cv_init(&ct->ct_failover_cv, NULL, CV_DRIVER, NULL); ct->ct_unstable = 0; cv_init(&ct->ct_unstable_cv, NULL, CV_DRIVER, NULL); cv_init(&ct->ct_powerchange_cv, NULL, CV_DRIVER, NULL); ct->ct_lb = vh->vh_lb; ct->ct_lb_args = kmem_zalloc(sizeof (client_lb_args_t), KM_SLEEP); ct->ct_lb_args->region_size = LOAD_BALANCE_DEFAULT_REGION_SIZE; ct->ct_path_count = 0; ct->ct_path_head = NULL; ct->ct_path_tail = NULL; ct->ct_path_last = NULL; /* * Add this client component to our client hash queue */ i_mdi_client_enlist_table(vh, ct); return (ct); } /* * i_mdi_client_enlist_table(): * Attach the client device to the client hash table. Caller * should hold the vhci client lock. */ static void i_mdi_client_enlist_table(mdi_vhci_t *vh, mdi_client_t *ct) { int index; struct client_hash *head; ASSERT(MDI_VHCI_CLIENT_LOCKED(vh)); index = i_mdi_get_hash_key(ct->ct_guid); head = &vh->vh_client_table[index]; ct->ct_hnext = (mdi_client_t *)head->ct_hash_head; head->ct_hash_head = ct; head->ct_hash_count++; vh->vh_client_count++; } /* * i_mdi_client_delist_table(): * Attach the client device to the client hash table. * Caller should hold the vhci client lock. */ static void i_mdi_client_delist_table(mdi_vhci_t *vh, mdi_client_t *ct) { int index; char *guid; struct client_hash *head; mdi_client_t *next; mdi_client_t *last; ASSERT(MDI_VHCI_CLIENT_LOCKED(vh)); guid = ct->ct_guid; index = i_mdi_get_hash_key(guid); head = &vh->vh_client_table[index]; last = NULL; next = (mdi_client_t *)head->ct_hash_head; while (next != NULL) { if (next == ct) { break; } last = next; next = next->ct_hnext; } if (next) { head->ct_hash_count--; if (last == NULL) { head->ct_hash_head = ct->ct_hnext; } else { last->ct_hnext = ct->ct_hnext; } ct->ct_hnext = NULL; vh->vh_client_count--; } } /* * i_mdi_client_free(): * Free a client component */ static int i_mdi_client_free(mdi_vhci_t *vh, mdi_client_t *ct) { int rv = MDI_SUCCESS; int flags = ct->ct_flags; dev_info_t *cdip; dev_info_t *vdip; ASSERT(MDI_VHCI_CLIENT_LOCKED(vh)); vdip = vh->vh_dip; cdip = ct->ct_dip; (void) ndi_prop_remove(DDI_DEV_T_NONE, cdip, MDI_CLIENT_GUID_PROP); DEVI(cdip)->devi_mdi_component &= ~MDI_COMPONENT_CLIENT; DEVI(cdip)->devi_mdi_client = NULL; /* * Clear out back ref. to dev_info_t node */ ct->ct_dip = NULL; /* * Remove this client from our hash queue */ i_mdi_client_delist_table(vh, ct); /* * Uninitialize and free the component */ kmem_free(ct->ct_drvname, strlen(ct->ct_drvname) + 1); kmem_free(ct->ct_guid, strlen(ct->ct_guid) + 1); kmem_free(ct->ct_lb_args, sizeof (client_lb_args_t)); cv_destroy(&ct->ct_failover_cv); cv_destroy(&ct->ct_unstable_cv); cv_destroy(&ct->ct_powerchange_cv); mutex_destroy(&ct->ct_mutex); kmem_free(ct, sizeof (*ct)); if (cdip != NULL) { MDI_VHCI_CLIENT_UNLOCK(vh); (void) i_mdi_devinfo_remove(vdip, cdip, flags); MDI_VHCI_CLIENT_LOCK(vh); } return (rv); } /* * i_mdi_client_find(): * Find the client structure corresponding to a given guid * Caller should hold the vhci client lock. */ static mdi_client_t * i_mdi_client_find(mdi_vhci_t *vh, char *cname, char *guid) { int index; struct client_hash *head; mdi_client_t *ct; ASSERT(MDI_VHCI_CLIENT_LOCKED(vh)); index = i_mdi_get_hash_key(guid); head = &vh->vh_client_table[index]; ct = head->ct_hash_head; while (ct != NULL) { if (strcmp(ct->ct_guid, guid) == 0 && (cname == NULL || strcmp(ct->ct_drvname, cname) == 0)) { break; } ct = ct->ct_hnext; } return (ct); } /* * i_mdi_client_update_state(): * Compute and update client device state * Notes: * A client device can be in any of three possible states: * * MDI_CLIENT_STATE_OPTIMAL - Client in optimal state with more * one online/standby paths. Can tolerate failures. * MDI_CLIENT_STATE_DEGRADED - Client device in degraded state with * no alternate paths available as standby. A failure on the online * would result in loss of access to device data. * MDI_CLIENT_STATE_FAILED - Client device in failed state with * no paths available to access the device. */ static void i_mdi_client_update_state(mdi_client_t *ct) { int state; ASSERT(MDI_CLIENT_LOCKED(ct)); state = i_mdi_client_compute_state(ct, NULL); MDI_CLIENT_SET_STATE(ct, state); } /* * i_mdi_client_compute_state(): * Compute client device state * * mdi_phci_t * Pointer to pHCI structure which should * while computing the new value. Used by * i_mdi_phci_offline() to find the new * client state after DR of a pHCI. */ static int i_mdi_client_compute_state(mdi_client_t *ct, mdi_phci_t *ph) { int state; int online_count = 0; int standby_count = 0; mdi_pathinfo_t *pip, *next; ASSERT(MDI_CLIENT_LOCKED(ct)); pip = ct->ct_path_head; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; if (MDI_PI(pip)->pi_phci == ph) { MDI_PI_UNLOCK(pip); pip = next; continue; } if ((MDI_PI(pip)->pi_state & MDI_PATHINFO_STATE_MASK) == MDI_PATHINFO_STATE_ONLINE) online_count++; else if ((MDI_PI(pip)->pi_state & MDI_PATHINFO_STATE_MASK) == MDI_PATHINFO_STATE_STANDBY) standby_count++; MDI_PI_UNLOCK(pip); pip = next; } if (online_count == 0) { if (standby_count == 0) { state = MDI_CLIENT_STATE_FAILED; MDI_DEBUG(2, (CE_NOTE, NULL, "!client state: failed" " ct = %p\n", (void *)ct)); } else if (standby_count == 1) { state = MDI_CLIENT_STATE_DEGRADED; } else { state = MDI_CLIENT_STATE_OPTIMAL; } } else if (online_count == 1) { if (standby_count == 0) { state = MDI_CLIENT_STATE_DEGRADED; } else { state = MDI_CLIENT_STATE_OPTIMAL; } } else { state = MDI_CLIENT_STATE_OPTIMAL; } return (state); } /* * i_mdi_client2devinfo(): * Utility function */ dev_info_t * i_mdi_client2devinfo(mdi_client_t *ct) { return (ct->ct_dip); } /* * mdi_client_path2_devinfo(): * Given the parent devinfo and child devfs pathname, search for * a valid devfs node handle. */ dev_info_t * mdi_client_path2devinfo(dev_info_t *vdip, char *pathname) { dev_info_t *cdip = NULL; dev_info_t *ndip = NULL; char *temp_pathname; int circular; /* * Allocate temp buffer */ temp_pathname = kmem_zalloc(MAXPATHLEN, KM_SLEEP); /* * Lock parent against changes */ ndi_devi_enter(vdip, &circular); ndip = (dev_info_t *)DEVI(vdip)->devi_child; while ((cdip = ndip) != NULL) { ndip = (dev_info_t *)DEVI(cdip)->devi_sibling; *temp_pathname = '\0'; (void) ddi_pathname(cdip, temp_pathname); if (strcmp(temp_pathname, pathname) == 0) { break; } } /* * Release devinfo lock */ ndi_devi_exit(vdip, circular); /* * Free the temp buffer */ kmem_free(temp_pathname, MAXPATHLEN); return (cdip); } /* * mdi_client_get_path_count(): * Utility function to get number of path information nodes * associated with a given client device. */ int mdi_client_get_path_count(dev_info_t *cdip) { mdi_client_t *ct; int count = 0; ct = i_devi_get_client(cdip); if (ct != NULL) { count = ct->ct_path_count; } return (count); } /* * i_mdi_get_hash_key(): * Create a hash using strings as keys * */ static int i_mdi_get_hash_key(char *str) { uint32_t g, hash = 0; char *p; for (p = str; *p != '\0'; p++) { g = *p; hash += g; } return (hash % (CLIENT_HASH_TABLE_SIZE - 1)); } /* * mdi_get_lb_policy(): * Get current load balancing policy for a given client device */ client_lb_t mdi_get_lb_policy(dev_info_t *cdip) { client_lb_t lb = LOAD_BALANCE_NONE; mdi_client_t *ct; ct = i_devi_get_client(cdip); if (ct != NULL) { lb = ct->ct_lb; } return (lb); } /* * mdi_set_lb_region_size(): * Set current region size for the load-balance */ int mdi_set_lb_region_size(dev_info_t *cdip, int region_size) { mdi_client_t *ct; int rv = MDI_FAILURE; ct = i_devi_get_client(cdip); if (ct != NULL && ct->ct_lb_args != NULL) { ct->ct_lb_args->region_size = region_size; rv = MDI_SUCCESS; } return (rv); } /* * mdi_Set_lb_policy(): * Set current load balancing policy for a given client device */ int mdi_set_lb_policy(dev_info_t *cdip, client_lb_t lb) { mdi_client_t *ct; int rv = MDI_FAILURE; ct = i_devi_get_client(cdip); if (ct != NULL) { ct->ct_lb = lb; rv = MDI_SUCCESS; } return (rv); } /* * mdi_failover(): * failover function called by the vHCI drivers to initiate * a failover operation. This is typically due to non-availability * of online paths to route I/O requests. Failover can be * triggered through user application also. * * The vHCI driver calls mdi_failover() to initiate a failover * operation. mdi_failover() calls back into the vHCI driver's * vo_failover() entry point to perform the actual failover * operation. The reason for requiring the vHCI driver to * initiate failover by calling mdi_failover(), instead of directly * executing vo_failover() itself, is to ensure that the mdi * framework can keep track of the client state properly. * Additionally, mdi_failover() provides as a convenience the * option of performing the failover operation synchronously or * asynchronously * * Upon successful completion of the failover operation, the * paths that were previously ONLINE will be in the STANDBY state, * and the newly activated paths will be in the ONLINE state. * * The flags modifier determines whether the activation is done * synchronously: MDI_FAILOVER_SYNC * Return Values: * MDI_SUCCESS * MDI_FAILURE * MDI_BUSY */ /*ARGSUSED*/ int mdi_failover(dev_info_t *vdip, dev_info_t *cdip, int flags) { int rv; mdi_client_t *ct; ct = i_devi_get_client(cdip); ASSERT(ct != NULL); if (ct == NULL) { /* cdip is not a valid client device. Nothing more to do. */ return (MDI_FAILURE); } MDI_CLIENT_LOCK(ct); if (MDI_CLIENT_IS_PATH_FREE_IN_PROGRESS(ct)) { /* A path to the client is being freed */ MDI_CLIENT_UNLOCK(ct); return (MDI_BUSY); } if (MDI_CLIENT_IS_FAILED(ct)) { /* * Client is in failed state. Nothing more to do. */ MDI_CLIENT_UNLOCK(ct); return (MDI_FAILURE); } if (MDI_CLIENT_IS_FAILOVER_IN_PROGRESS(ct)) { /* * Failover is already in progress; return BUSY */ MDI_CLIENT_UNLOCK(ct); return (MDI_BUSY); } /* * Make sure that mdi_pathinfo node state changes are processed. * We do not allow failovers to progress while client path state * changes are in progress */ if (ct->ct_unstable) { if (flags == MDI_FAILOVER_ASYNC) { MDI_CLIENT_UNLOCK(ct); return (MDI_BUSY); } else { while (ct->ct_unstable) cv_wait(&ct->ct_unstable_cv, &ct->ct_mutex); } } /* * Client device is in stable state. Before proceeding, perform sanity * checks again. */ if ((MDI_CLIENT_IS_DETACHED(ct)) || (MDI_CLIENT_IS_FAILED(ct)) || (!i_ddi_devi_attached(ct->ct_dip))) { /* * Client is in failed state. Nothing more to do. */ MDI_CLIENT_UNLOCK(ct); return (MDI_FAILURE); } /* * Set the client state as failover in progress. */ MDI_CLIENT_SET_FAILOVER_IN_PROGRESS(ct); ct->ct_failover_flags = flags; MDI_CLIENT_UNLOCK(ct); if (flags == MDI_FAILOVER_ASYNC) { /* * Submit the initiate failover request via CPR safe * taskq threads. */ (void) taskq_dispatch(mdi_taskq, (task_func_t *)i_mdi_failover, ct, KM_SLEEP); return (MDI_ACCEPT); } else { /* * Synchronous failover mode. Typically invoked from the user * land. */ rv = i_mdi_failover(ct); } return (rv); } /* * i_mdi_failover(): * internal failover function. Invokes vHCI drivers failover * callback function and process the failover status * Return Values: * None * * Note: A client device in failover state can not be detached or freed. */ static int i_mdi_failover(void *arg) { int rv = MDI_SUCCESS; mdi_client_t *ct = (mdi_client_t *)arg; mdi_vhci_t *vh = ct->ct_vhci; ASSERT(!MDI_CLIENT_LOCKED(ct)); if (vh->vh_ops->vo_failover != NULL) { /* * Call vHCI drivers callback routine */ rv = (*vh->vh_ops->vo_failover)(vh->vh_dip, ct->ct_dip, ct->ct_failover_flags); } MDI_CLIENT_LOCK(ct); MDI_CLIENT_CLEAR_FAILOVER_IN_PROGRESS(ct); /* * Save the failover return status */ ct->ct_failover_status = rv; /* * As a result of failover, client status would have been changed. * Update the client state and wake up anyone waiting on this client * device. */ i_mdi_client_update_state(ct); cv_broadcast(&ct->ct_failover_cv); MDI_CLIENT_UNLOCK(ct); return (rv); } /* * Load balancing is logical block. * IOs within the range described by region_size * would go on the same path. This would improve the * performance by cache-hit on some of the RAID devices. * Search only for online paths(At some point we * may want to balance across target ports). * If no paths are found then default to round-robin. */ static int i_mdi_lba_lb(mdi_client_t *ct, mdi_pathinfo_t **ret_pip, struct buf *bp) { int path_index = -1; int online_path_count = 0; int online_nonpref_path_count = 0; int region_size = ct->ct_lb_args->region_size; mdi_pathinfo_t *pip; mdi_pathinfo_t *next; int preferred, path_cnt; pip = ct->ct_path_head; while (pip) { MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_ONLINE && MDI_PI(pip)->pi_preferred) { online_path_count++; } else if (MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_ONLINE && !MDI_PI(pip)->pi_preferred) { online_nonpref_path_count++; } next = (mdi_pathinfo_t *) MDI_PI(pip)->pi_client_link; MDI_PI_UNLOCK(pip); pip = next; } /* if found any online/preferred then use this type */ if (online_path_count > 0) { path_cnt = online_path_count; preferred = 1; } else if (online_nonpref_path_count > 0) { path_cnt = online_nonpref_path_count; preferred = 0; } else { path_cnt = 0; } if (path_cnt) { path_index = (bp->b_blkno >> region_size) % path_cnt; pip = ct->ct_path_head; while (pip && path_index != -1) { MDI_PI_LOCK(pip); if (path_index == 0 && (MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_ONLINE) && MDI_PI(pip)->pi_preferred == preferred) { MDI_PI_HOLD(pip); MDI_PI_UNLOCK(pip); *ret_pip = pip; return (MDI_SUCCESS); } path_index --; next = (mdi_pathinfo_t *) MDI_PI(pip)->pi_client_link; MDI_PI_UNLOCK(pip); pip = next; } if (pip == NULL) { MDI_DEBUG(4, (CE_NOTE, NULL, "!lba %llx, no pip !!\n", bp->b_lblkno)); } else { MDI_DEBUG(4, (CE_NOTE, NULL, "!lba %llx, no pip for path_index, " "pip %p\n", bp->b_lblkno, (void *)pip)); } } return (MDI_FAILURE); } /* * mdi_select_path(): * select a path to access a client device. * * mdi_select_path() function is called by the vHCI drivers to * select a path to route the I/O request to. The caller passes * the block I/O data transfer structure ("buf") as one of the * parameters. The mpxio framework uses the buf structure * contents to maintain per path statistics (total I/O size / * count pending). If more than one online paths are available to * select, the framework automatically selects a suitable path * for routing I/O request. If a failover operation is active for * this client device the call shall be failed with MDI_BUSY error * code. * * By default this function returns a suitable path in online * state based on the current load balancing policy. Currently * we support LOAD_BALANCE_NONE (Previously selected online path * will continue to be used till the path is usable) and * LOAD_BALANCE_RR (Online paths will be selected in a round * robin fashion), LOAD_BALANCE_LB(Online paths will be selected * based on the logical block). The load balancing * through vHCI drivers configuration file (driver.conf). * * vHCI drivers may override this default behavior by specifying * appropriate flags. The meaning of the thrid argument depends * on the flags specified. If MDI_SELECT_PATH_INSTANCE is set * then the argument is the "path instance" of the path to select. * If MDI_SELECT_PATH_INSTANCE is not set then the argument is * "start_pip". A non NULL "start_pip" is the starting point to * walk and find the next appropriate path. The following values * are currently defined: MDI_SELECT_ONLINE_PATH (to select an * ONLINE path) and/or MDI_SELECT_STANDBY_PATH (to select an * STANDBY path). * * The non-standard behavior is used by the scsi_vhci driver, * whenever it has to use a STANDBY/FAULTED path. Eg. during * attach of client devices (to avoid an unnecessary failover * when the STANDBY path comes up first), during failover * (to activate a STANDBY path as ONLINE). * * The selected path is returned in a a mdi_hold_path() state * (pi_ref_cnt). Caller should release the hold by calling * mdi_rele_path(). * * Return Values: * MDI_SUCCESS - Completed successfully * MDI_BUSY - Client device is busy failing over * MDI_NOPATH - Client device is online, but no valid path are * available to access this client device * MDI_FAILURE - Invalid client device or state * MDI_DEVI_ONLINING * - Client device (struct dev_info state) is in * onlining state. */ /*ARGSUSED*/ int mdi_select_path(dev_info_t *cdip, struct buf *bp, int flags, void *arg, mdi_pathinfo_t **ret_pip) { mdi_client_t *ct; mdi_pathinfo_t *pip; mdi_pathinfo_t *next; mdi_pathinfo_t *head; mdi_pathinfo_t *start; client_lb_t lbp; /* load balancing policy */ int sb = 1; /* standard behavior */ int preferred = 1; /* preferred path */ int cond, cont = 1; int retry = 0; mdi_pathinfo_t *start_pip; /* request starting pathinfo */ int path_instance; /* request specific path instance */ /* determine type of arg based on flags */ if (flags & MDI_SELECT_PATH_INSTANCE) { flags &= ~MDI_SELECT_PATH_INSTANCE; path_instance = (int)(intptr_t)arg; start_pip = NULL; } else { path_instance = 0; start_pip = (mdi_pathinfo_t *)arg; } if (flags != 0) { /* * disable default behavior */ sb = 0; } *ret_pip = NULL; ct = i_devi_get_client(cdip); if (ct == NULL) { /* mdi extensions are NULL, Nothing more to do */ return (MDI_FAILURE); } MDI_CLIENT_LOCK(ct); if (sb) { if (MDI_CLIENT_IS_FAILED(ct)) { /* * Client is not ready to accept any I/O requests. * Fail this request. */ MDI_DEBUG(2, (CE_NOTE, cdip, "!mdi_select_path: " "client state offline ct = %p\n", (void *)ct)); MDI_CLIENT_UNLOCK(ct); return (MDI_FAILURE); } if (MDI_CLIENT_IS_FAILOVER_IN_PROGRESS(ct)) { /* * Check for Failover is in progress. If so tell the * caller that this device is busy. */ MDI_DEBUG(2, (CE_NOTE, cdip, "!mdi_select_path: " "client failover in progress ct = %p\n", (void *)ct)); MDI_CLIENT_UNLOCK(ct); return (MDI_BUSY); } /* * Check to see whether the client device is attached. * If not so, let the vHCI driver manually select a path * (standby) and let the probe/attach process to continue. */ if (MDI_CLIENT_IS_DETACHED(ct) || !i_ddi_devi_attached(cdip)) { MDI_DEBUG(4, (CE_NOTE, cdip, "!Devi is onlining " "ct = %p\n", (void *)ct)); MDI_CLIENT_UNLOCK(ct); return (MDI_DEVI_ONLINING); } } /* * Cache in the client list head. If head of the list is NULL * return MDI_NOPATH */ head = ct->ct_path_head; if (head == NULL) { MDI_CLIENT_UNLOCK(ct); return (MDI_NOPATH); } /* Caller is specifying a specific pathinfo path by path_instance */ if (path_instance) { /* search for pathinfo with correct path_instance */ for (pip = head; pip && (mdi_pi_get_path_instance(pip) != path_instance); pip = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link) ; /* If path can't be selected then MDI_FAILURE is returned. */ if (pip == NULL) { MDI_CLIENT_UNLOCK(ct); return (MDI_FAILURE); } /* verify state of path */ MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_state != MDI_PATHINFO_STATE_ONLINE) { MDI_PI_UNLOCK(pip); MDI_CLIENT_UNLOCK(ct); return (MDI_FAILURE); } /* * Return the path in hold state. Caller should release the * lock by calling mdi_rele_path() */ MDI_PI_HOLD(pip); MDI_PI_UNLOCK(pip); ct->ct_path_last = pip; *ret_pip = pip; MDI_CLIENT_UNLOCK(ct); return (MDI_SUCCESS); } /* * for non default behavior, bypass current * load balancing policy and always use LOAD_BALANCE_RR * except that the start point will be adjusted based * on the provided start_pip */ lbp = sb ? ct->ct_lb : LOAD_BALANCE_RR; switch (lbp) { case LOAD_BALANCE_NONE: /* * Load balancing is None or Alternate path mode * Start looking for a online mdi_pathinfo node starting from * last known selected path */ preferred = 1; pip = (mdi_pathinfo_t *)ct->ct_path_last; if (pip == NULL) { pip = head; } start = pip; do { MDI_PI_LOCK(pip); /* * No need to explicitly check if the path is disabled. * Since we are checking for state == ONLINE and the * same veriable is used for DISABLE/ENABLE information. */ if ((MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_ONLINE) && preferred == MDI_PI(pip)->pi_preferred) { /* * Return the path in hold state. Caller should * release the lock by calling mdi_rele_path() */ MDI_PI_HOLD(pip); MDI_PI_UNLOCK(pip); ct->ct_path_last = pip; *ret_pip = pip; MDI_CLIENT_UNLOCK(ct); return (MDI_SUCCESS); } /* * Path is busy. */ if (MDI_PI_IS_DRV_DISABLE_TRANSIENT(pip) || MDI_PI_IS_TRANSIENT(pip)) retry = 1; /* * Keep looking for a next available online path */ next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; if (next == NULL) { next = head; } MDI_PI_UNLOCK(pip); pip = next; if (start == pip && preferred) { preferred = 0; } else if (start == pip && !preferred) { cont = 0; } } while (cont); break; case LOAD_BALANCE_LBA: /* * Make sure we are looking * for an online path. Otherwise, if it is for a STANDBY * path request, it will go through and fetch an ONLINE * path which is not desirable. */ if ((ct->ct_lb_args != NULL) && (ct->ct_lb_args->region_size) && bp && (sb || (flags == MDI_SELECT_ONLINE_PATH))) { if (i_mdi_lba_lb(ct, ret_pip, bp) == MDI_SUCCESS) { MDI_CLIENT_UNLOCK(ct); return (MDI_SUCCESS); } } /* FALLTHROUGH */ case LOAD_BALANCE_RR: /* * Load balancing is Round Robin. Start looking for a online * mdi_pathinfo node starting from last known selected path * as the start point. If override flags are specified, * process accordingly. * If the search is already in effect(start_pip not null), * then lets just use the same path preference to continue the * traversal. */ if (start_pip != NULL) { preferred = MDI_PI(start_pip)->pi_preferred; } else { preferred = 1; } start = sb ? (mdi_pathinfo_t *)ct->ct_path_last : start_pip; if (start == NULL) { pip = head; } else { pip = (mdi_pathinfo_t *)MDI_PI(start)->pi_client_link; if (pip == NULL) { if ( flags & MDI_SELECT_NO_PREFERRED) { /* * Return since we hit the end of list */ MDI_CLIENT_UNLOCK(ct); return (MDI_NOPATH); } if (!sb) { if (preferred == 0) { /* * Looks like we have completed * the traversal as preferred * value is 0. Time to bail out. */ *ret_pip = NULL; MDI_CLIENT_UNLOCK(ct); return (MDI_NOPATH); } else { /* * Looks like we reached the * end of the list. Lets enable * traversal of non preferred * paths. */ preferred = 0; } } pip = head; } } start = pip; do { MDI_PI_LOCK(pip); if (sb) { cond = ((MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_ONLINE && MDI_PI(pip)->pi_preferred == preferred) ? 1 : 0); } else { if (flags == MDI_SELECT_ONLINE_PATH) { cond = ((MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_ONLINE && MDI_PI(pip)->pi_preferred == preferred) ? 1 : 0); } else if (flags == MDI_SELECT_STANDBY_PATH) { cond = ((MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_STANDBY && MDI_PI(pip)->pi_preferred == preferred) ? 1 : 0); } else if (flags == (MDI_SELECT_ONLINE_PATH | MDI_SELECT_STANDBY_PATH)) { cond = (((MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_ONLINE || (MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_STANDBY)) && MDI_PI(pip)->pi_preferred == preferred) ? 1 : 0); } else if (flags == (MDI_SELECT_STANDBY_PATH | MDI_SELECT_ONLINE_PATH | MDI_SELECT_USER_DISABLE_PATH)) { cond = (((MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_ONLINE || (MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_STANDBY) || (MDI_PI(pip)->pi_state == (MDI_PATHINFO_STATE_ONLINE| MDI_PATHINFO_STATE_USER_DISABLE)) || (MDI_PI(pip)->pi_state == (MDI_PATHINFO_STATE_STANDBY | MDI_PATHINFO_STATE_USER_DISABLE)))&& MDI_PI(pip)->pi_preferred == preferred) ? 1 : 0); } else if (flags == (MDI_SELECT_STANDBY_PATH | MDI_SELECT_ONLINE_PATH | MDI_SELECT_NO_PREFERRED)) { cond = (((MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_ONLINE) || (MDI_PI(pip)->pi_state == MDI_PATHINFO_STATE_STANDBY)) ? 1 : 0); } else { cond = 0; } } /* * No need to explicitly check if the path is disabled. * Since we are checking for state == ONLINE and the * same veriable is used for DISABLE/ENABLE information. */ if (cond) { /* * Return the path in hold state. Caller should * release the lock by calling mdi_rele_path() */ MDI_PI_HOLD(pip); MDI_PI_UNLOCK(pip); if (sb) ct->ct_path_last = pip; *ret_pip = pip; MDI_CLIENT_UNLOCK(ct); return (MDI_SUCCESS); } /* * Path is busy. */ if (MDI_PI_IS_DRV_DISABLE_TRANSIENT(pip) || MDI_PI_IS_TRANSIENT(pip)) retry = 1; /* * Keep looking for a next available online path */ do_again: next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; if (next == NULL) { if ( flags & MDI_SELECT_NO_PREFERRED) { /* * Bail out since we hit the end of list */ MDI_PI_UNLOCK(pip); break; } if (!sb) { if (preferred == 1) { /* * Looks like we reached the * end of the list. Lets enable * traversal of non preferred * paths. */ preferred = 0; next = head; } else { /* * We have done both the passes * Preferred as well as for * Non-preferred. Bail out now. */ cont = 0; } } else { /* * Standard behavior case. */ next = head; } } MDI_PI_UNLOCK(pip); if (cont == 0) { break; } pip = next; if (!sb) { /* * We need to handle the selection of * non-preferred path in the following * case: * * +------+ +------+ +------+ +-----+ * | A : 1| - | B : 1| - | C : 0| - |NULL | * +------+ +------+ +------+ +-----+ * * If we start the search with B, we need to * skip beyond B to pick C which is non - * preferred in the second pass. The following * test, if true, will allow us to skip over * the 'start'(B in the example) to select * other non preferred elements. */ if ((start_pip != NULL) && (start_pip == pip) && (MDI_PI(start_pip)->pi_preferred != preferred)) { /* * try again after going past the start * pip */ MDI_PI_LOCK(pip); goto do_again; } } else { /* * Standard behavior case */ if (start == pip && preferred) { /* look for nonpreferred paths */ preferred = 0; } else if (start == pip && !preferred) { /* * Exit condition */ cont = 0; } } } while (cont); break; } MDI_CLIENT_UNLOCK(ct); if (retry == 1) { return (MDI_BUSY); } else { return (MDI_NOPATH); } } /* * For a client, return the next available path to any phci * * Note: * Caller should hold the branch's devinfo node to get a consistent * snap shot of the mdi_pathinfo nodes. * * Please note that even the list is stable the mdi_pathinfo * node state and properties are volatile. The caller should lock * and unlock the nodes by calling mdi_pi_lock() and * mdi_pi_unlock() functions to get a stable properties. * * If there is a need to use the nodes beyond the hold of the * devinfo node period (For ex. I/O), then mdi_pathinfo node * need to be held against unexpected removal by calling * mdi_hold_path() and should be released by calling * mdi_rele_path() on completion. */ mdi_pathinfo_t * mdi_get_next_phci_path(dev_info_t *ct_dip, mdi_pathinfo_t *pip) { mdi_client_t *ct; if (!MDI_CLIENT(ct_dip)) return (NULL); /* * Walk through client link */ ct = (mdi_client_t *)DEVI(ct_dip)->devi_mdi_client; ASSERT(ct != NULL); if (pip == NULL) return ((mdi_pathinfo_t *)ct->ct_path_head); return ((mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link); } /* * For a phci, return the next available path to any client * Note: ditto mdi_get_next_phci_path() */ mdi_pathinfo_t * mdi_get_next_client_path(dev_info_t *ph_dip, mdi_pathinfo_t *pip) { mdi_phci_t *ph; if (!MDI_PHCI(ph_dip)) return (NULL); /* * Walk through pHCI link */ ph = (mdi_phci_t *)DEVI(ph_dip)->devi_mdi_xhci; ASSERT(ph != NULL); if (pip == NULL) return ((mdi_pathinfo_t *)ph->ph_path_head); return ((mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link); } /* * mdi_hold_path(): * Hold the mdi_pathinfo node against unwanted unexpected free. * Return Values: * None */ void mdi_hold_path(mdi_pathinfo_t *pip) { if (pip) { MDI_PI_LOCK(pip); MDI_PI_HOLD(pip); MDI_PI_UNLOCK(pip); } } /* * mdi_rele_path(): * Release the mdi_pathinfo node which was selected * through mdi_select_path() mechanism or manually held by * calling mdi_hold_path(). * Return Values: * None */ void mdi_rele_path(mdi_pathinfo_t *pip) { if (pip) { MDI_PI_LOCK(pip); MDI_PI_RELE(pip); if (MDI_PI(pip)->pi_ref_cnt == 0) { cv_broadcast(&MDI_PI(pip)->pi_ref_cv); } MDI_PI_UNLOCK(pip); } } /* * mdi_pi_lock(): * Lock the mdi_pathinfo node. * Note: * The caller should release the lock by calling mdi_pi_unlock() */ void mdi_pi_lock(mdi_pathinfo_t *pip) { ASSERT(pip != NULL); if (pip) { MDI_PI_LOCK(pip); } } /* * mdi_pi_unlock(): * Unlock the mdi_pathinfo node. * Note: * The mdi_pathinfo node should have been locked with mdi_pi_lock() */ void mdi_pi_unlock(mdi_pathinfo_t *pip) { ASSERT(pip != NULL); if (pip) { MDI_PI_UNLOCK(pip); } } /* * mdi_pi_find(): * Search the list of mdi_pathinfo nodes attached to the * pHCI/Client device node whose path address matches "paddr". * Returns a pointer to the mdi_pathinfo node if a matching node is * found. * Return Values: * mdi_pathinfo node handle * NULL * Notes: * Caller need not hold any locks to call this function. */ mdi_pathinfo_t * mdi_pi_find(dev_info_t *pdip, char *caddr, char *paddr) { mdi_phci_t *ph; mdi_vhci_t *vh; mdi_client_t *ct; mdi_pathinfo_t *pip = NULL; MDI_DEBUG(2, (CE_NOTE, pdip, "!mdi_pi_find: %s %s", caddr ? caddr : "NULL", paddr ? paddr : "NULL")); if ((pdip == NULL) || (paddr == NULL)) { return (NULL); } ph = i_devi_get_phci(pdip); if (ph == NULL) { /* * Invalid pHCI device, Nothing more to do. */ MDI_DEBUG(2, (CE_WARN, pdip, "!mdi_pi_find: invalid phci")); return (NULL); } vh = ph->ph_vhci; if (vh == NULL) { /* * Invalid vHCI device, Nothing more to do. */ MDI_DEBUG(2, (CE_WARN, pdip, "!mdi_pi_find: invalid vhci")); return (NULL); } /* * Look for pathinfo node identified by paddr. */ if (caddr == NULL) { /* * Find a mdi_pathinfo node under pHCI list for a matching * unit address. */ MDI_PHCI_LOCK(ph); if (MDI_PHCI_IS_OFFLINE(ph)) { MDI_DEBUG(2, (CE_WARN, pdip, "!mdi_pi_find: offline phci %p", (void *)ph)); MDI_PHCI_UNLOCK(ph); return (NULL); } pip = (mdi_pathinfo_t *)ph->ph_path_head; while (pip != NULL) { if (strcmp(MDI_PI(pip)->pi_addr, paddr) == 0) { break; } pip = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; } MDI_PHCI_UNLOCK(ph); MDI_DEBUG(2, (CE_NOTE, pdip, "!mdi_pi_find: found %p", (void *)pip)); return (pip); } /* * XXX - Is the rest of the code in this function really necessary? * The consumers of mdi_pi_find() can search for the desired pathinfo * node by calling mdi_pi_find(pdip, NULL, paddr). Irrespective of * whether the search is based on the pathinfo nodes attached to * the pHCI or the client node, the result will be the same. */ /* * Find the client device corresponding to 'caddr' */ MDI_VHCI_CLIENT_LOCK(vh); /* * XXX - Passing NULL to the following function works as long as the * the client addresses (caddr) are unique per vhci basis. */ ct = i_mdi_client_find(vh, NULL, caddr); if (ct == NULL) { /* * Client not found, Obviously mdi_pathinfo node has not been * created yet. */ MDI_VHCI_CLIENT_UNLOCK(vh); MDI_DEBUG(2, (CE_NOTE, pdip, "!mdi_pi_find: client not " "found for caddr %s", caddr ? caddr : "NULL")); return (NULL); } /* * Hold the client lock and look for a mdi_pathinfo node with matching * pHCI and paddr */ MDI_CLIENT_LOCK(ct); /* * Release the global mutex as it is no more needed. Note: We always * respect the locking order while acquiring. */ MDI_VHCI_CLIENT_UNLOCK(vh); pip = (mdi_pathinfo_t *)ct->ct_path_head; while (pip != NULL) { /* * Compare the unit address */ if ((MDI_PI(pip)->pi_phci == ph) && strcmp(MDI_PI(pip)->pi_addr, paddr) == 0) { break; } pip = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; } MDI_CLIENT_UNLOCK(ct); MDI_DEBUG(2, (CE_NOTE, pdip, "!mdi_pi_find: found:: %p", (void *)pip)); return (pip); } /* * mdi_pi_alloc(): * Allocate and initialize a new instance of a mdi_pathinfo node. * The mdi_pathinfo node returned by this function identifies a * unique device path is capable of having properties attached * and passed to mdi_pi_online() to fully attach and online the * path and client device node. * The mdi_pathinfo node returned by this function must be * destroyed using mdi_pi_free() if the path is no longer * operational or if the caller fails to attach a client device * node when calling mdi_pi_online(). The framework will not free * the resources allocated. * This function can be called from both interrupt and kernel * contexts. DDI_NOSLEEP flag should be used while calling * from interrupt contexts. * Return Values: * MDI_SUCCESS * MDI_FAILURE * MDI_NOMEM */ /*ARGSUSED*/ int mdi_pi_alloc_compatible(dev_info_t *pdip, char *cname, char *caddr, char *paddr, char **compatible, int ncompatible, int flags, mdi_pathinfo_t **ret_pip) { mdi_vhci_t *vh; mdi_phci_t *ph; mdi_client_t *ct; mdi_pathinfo_t *pip = NULL; dev_info_t *cdip; int rv = MDI_NOMEM; int path_allocated = 0; MDI_DEBUG(2, (CE_NOTE, pdip, "!mdi_pi_alloc_compatible: %s %s %s", cname ? cname : "NULL", caddr ? caddr : "NULL", paddr ? paddr : "NULL")); if (pdip == NULL || cname == NULL || caddr == NULL || paddr == NULL || ret_pip == NULL) { /* Nothing more to do */ return (MDI_FAILURE); } *ret_pip = NULL; /* No allocations on detaching pHCI */ if (DEVI_IS_DETACHING(pdip)) { /* Invalid pHCI device, return failure */ MDI_DEBUG(1, (CE_WARN, pdip, "!mdi_pi_alloc: detaching pHCI=%p", (void *)pdip)); return (MDI_FAILURE); } ph = i_devi_get_phci(pdip); ASSERT(ph != NULL); if (ph == NULL) { /* Invalid pHCI device, return failure */ MDI_DEBUG(1, (CE_WARN, pdip, "!mdi_pi_alloc: invalid pHCI=%p", (void *)pdip)); return (MDI_FAILURE); } MDI_PHCI_LOCK(ph); vh = ph->ph_vhci; if (vh == NULL) { /* Invalid vHCI device, return failure */ MDI_DEBUG(1, (CE_WARN, pdip, "!mdi_pi_alloc: invalid vHCI=%p", (void *)pdip)); MDI_PHCI_UNLOCK(ph); return (MDI_FAILURE); } if (MDI_PHCI_IS_READY(ph) == 0) { /* * Do not allow new node creation when pHCI is in * offline/suspended states */ MDI_DEBUG(1, (CE_WARN, pdip, "mdi_pi_alloc: pHCI=%p is not ready", (void *)ph)); MDI_PHCI_UNLOCK(ph); return (MDI_BUSY); } MDI_PHCI_UNSTABLE(ph); MDI_PHCI_UNLOCK(ph); /* look for a matching client, create one if not found */ MDI_VHCI_CLIENT_LOCK(vh); ct = i_mdi_client_find(vh, cname, caddr); if (ct == NULL) { ct = i_mdi_client_alloc(vh, cname, caddr); ASSERT(ct != NULL); } if (ct->ct_dip == NULL) { /* * Allocate a devinfo node */ ct->ct_dip = i_mdi_devinfo_create(vh, cname, caddr, compatible, ncompatible); if (ct->ct_dip == NULL) { (void) i_mdi_client_free(vh, ct); goto fail; } } cdip = ct->ct_dip; DEVI(cdip)->devi_mdi_component |= MDI_COMPONENT_CLIENT; DEVI(cdip)->devi_mdi_client = (caddr_t)ct; MDI_CLIENT_LOCK(ct); pip = (mdi_pathinfo_t *)ct->ct_path_head; while (pip != NULL) { /* * Compare the unit address */ if ((MDI_PI(pip)->pi_phci == ph) && strcmp(MDI_PI(pip)->pi_addr, paddr) == 0) { break; } pip = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; } MDI_CLIENT_UNLOCK(ct); if (pip == NULL) { /* * This is a new path for this client device. Allocate and * initialize a new pathinfo node */ pip = i_mdi_pi_alloc(ph, paddr, ct); ASSERT(pip != NULL); path_allocated = 1; } rv = MDI_SUCCESS; fail: /* * Release the global mutex. */ MDI_VHCI_CLIENT_UNLOCK(vh); /* * Mark the pHCI as stable */ MDI_PHCI_LOCK(ph); MDI_PHCI_STABLE(ph); MDI_PHCI_UNLOCK(ph); *ret_pip = pip; MDI_DEBUG(2, (CE_NOTE, pdip, "!mdi_pi_alloc_compatible: alloc %p", (void *)pip)); if (path_allocated) vhcache_pi_add(vh->vh_config, MDI_PI(pip)); return (rv); } /*ARGSUSED*/ int mdi_pi_alloc(dev_info_t *pdip, char *cname, char *caddr, char *paddr, int flags, mdi_pathinfo_t **ret_pip) { return (mdi_pi_alloc_compatible(pdip, cname, caddr, paddr, NULL, 0, flags, ret_pip)); } /* * i_mdi_pi_alloc(): * Allocate a mdi_pathinfo node and add to the pHCI path list * Return Values: * mdi_pathinfo */ /*ARGSUSED*/ static mdi_pathinfo_t * i_mdi_pi_alloc(mdi_phci_t *ph, char *paddr, mdi_client_t *ct) { mdi_pathinfo_t *pip; int ct_circular; int ph_circular; static char path[MAXPATHLEN]; char *path_persistent; int path_instance; mod_hash_val_t hv; ASSERT(MDI_VHCI_CLIENT_LOCKED(ph->ph_vhci)); pip = kmem_zalloc(sizeof (struct mdi_pathinfo), KM_SLEEP); mutex_init(&MDI_PI(pip)->pi_mutex, NULL, MUTEX_DEFAULT, NULL); MDI_PI(pip)->pi_state = MDI_PATHINFO_STATE_INIT | MDI_PATHINFO_STATE_TRANSIENT; if (MDI_PHCI_IS_USER_DISABLED(ph)) MDI_PI_SET_USER_DISABLE(pip); if (MDI_PHCI_IS_DRV_DISABLED_TRANSIENT(ph)) MDI_PI_SET_DRV_DISABLE_TRANS(pip); if (MDI_PHCI_IS_DRV_DISABLED(ph)) MDI_PI_SET_DRV_DISABLE(pip); MDI_PI(pip)->pi_old_state = MDI_PATHINFO_STATE_INIT; cv_init(&MDI_PI(pip)->pi_state_cv, NULL, CV_DEFAULT, NULL); MDI_PI(pip)->pi_client = ct; MDI_PI(pip)->pi_phci = ph; MDI_PI(pip)->pi_addr = kmem_alloc(strlen(paddr) + 1, KM_SLEEP); (void) strcpy(MDI_PI(pip)->pi_addr, paddr); /* * We form the "path" to the pathinfo node, and see if we have * already allocated a 'path_instance' for that "path". If so, * we use the already allocated 'path_instance'. If not, we * allocate a new 'path_instance' and associate it with a copy of * the "path" string (which is never freed). The association * between a 'path_instance' this "path" string persists until * reboot. */ mutex_enter(&mdi_pathmap_mutex); (void) ddi_pathname(ph->ph_dip, path); (void) sprintf(path + strlen(path), "/%s@%s", ddi_node_name(ct->ct_dip), MDI_PI(pip)->pi_addr); if (mod_hash_find(mdi_pathmap_bypath, (mod_hash_key_t)path, &hv) == 0) { path_instance = (uint_t)(intptr_t)hv; } else { /* allocate a new 'path_instance' and persistent "path" */ path_instance = mdi_pathmap_instance++; path_persistent = i_ddi_strdup(path, KM_SLEEP); (void) mod_hash_insert(mdi_pathmap_bypath, (mod_hash_key_t)path_persistent, (mod_hash_val_t)(intptr_t)path_instance); (void) mod_hash_insert(mdi_pathmap_byinstance, (mod_hash_key_t)(intptr_t)path_instance, (mod_hash_val_t)path_persistent); } mutex_exit(&mdi_pathmap_mutex); MDI_PI(pip)->pi_path_instance = path_instance; (void) nvlist_alloc(&MDI_PI(pip)->pi_prop, NV_UNIQUE_NAME, KM_SLEEP); ASSERT(MDI_PI(pip)->pi_prop != NULL); MDI_PI(pip)->pi_pprivate = NULL; MDI_PI(pip)->pi_cprivate = NULL; MDI_PI(pip)->pi_vprivate = NULL; MDI_PI(pip)->pi_client_link = NULL; MDI_PI(pip)->pi_phci_link = NULL; MDI_PI(pip)->pi_ref_cnt = 0; MDI_PI(pip)->pi_kstats = NULL; MDI_PI(pip)->pi_preferred = 1; cv_init(&MDI_PI(pip)->pi_ref_cv, NULL, CV_DEFAULT, NULL); /* * Lock both dev_info nodes against changes in parallel. * * The ndi_devi_enter(Client), is atypical since the client is a leaf. * This atypical operation is done to synchronize pathinfo nodes * during devinfo snapshot (see di_register_pip) by 'pretending' that * the pathinfo nodes are children of the Client. */ ndi_devi_enter(ct->ct_dip, &ct_circular); ndi_devi_enter(ph->ph_dip, &ph_circular); i_mdi_phci_add_path(ph, pip); i_mdi_client_add_path(ct, pip); ndi_devi_exit(ph->ph_dip, ph_circular); ndi_devi_exit(ct->ct_dip, ct_circular); return (pip); } /* * mdi_pi_pathname_by_instance(): * Lookup of "path" by 'path_instance'. Return "path". * NOTE: returned "path" remains valid forever (until reboot). */ char * mdi_pi_pathname_by_instance(int path_instance) { char *path; mod_hash_val_t hv; /* mdi_pathmap lookup of "path" by 'path_instance' */ mutex_enter(&mdi_pathmap_mutex); if (mod_hash_find(mdi_pathmap_byinstance, (mod_hash_key_t)(intptr_t)path_instance, &hv) == 0) path = (char *)hv; else path = NULL; mutex_exit(&mdi_pathmap_mutex); return (path); } /* * i_mdi_phci_add_path(): * Add a mdi_pathinfo node to pHCI list. * Notes: * Caller should per-pHCI mutex */ static void i_mdi_phci_add_path(mdi_phci_t *ph, mdi_pathinfo_t *pip) { ASSERT(DEVI_BUSY_OWNED(ph->ph_dip)); MDI_PHCI_LOCK(ph); if (ph->ph_path_head == NULL) { ph->ph_path_head = pip; } else { MDI_PI(ph->ph_path_tail)->pi_phci_link = MDI_PI(pip); } ph->ph_path_tail = pip; ph->ph_path_count++; MDI_PHCI_UNLOCK(ph); } /* * i_mdi_client_add_path(): * Add mdi_pathinfo node to client list */ static void i_mdi_client_add_path(mdi_client_t *ct, mdi_pathinfo_t *pip) { ASSERT(DEVI_BUSY_OWNED(ct->ct_dip)); MDI_CLIENT_LOCK(ct); if (ct->ct_path_head == NULL) { ct->ct_path_head = pip; } else { MDI_PI(ct->ct_path_tail)->pi_client_link = MDI_PI(pip); } ct->ct_path_tail = pip; ct->ct_path_count++; MDI_CLIENT_UNLOCK(ct); } /* * mdi_pi_free(): * Free the mdi_pathinfo node and also client device node if this * is the last path to the device * Return Values: * MDI_SUCCESS * MDI_FAILURE * MDI_BUSY */ /*ARGSUSED*/ int mdi_pi_free(mdi_pathinfo_t *pip, int flags) { int rv = MDI_FAILURE; mdi_vhci_t *vh; mdi_phci_t *ph; mdi_client_t *ct; int (*f)(); int client_held = 0; MDI_PI_LOCK(pip); ph = MDI_PI(pip)->pi_phci; ASSERT(ph != NULL); if (ph == NULL) { /* * Invalid pHCI device, return failure */ MDI_DEBUG(1, (CE_WARN, NULL, "!mdi_pi_free: invalid pHCI pip=%p", (void *)pip)); MDI_PI_UNLOCK(pip); return (MDI_FAILURE); } vh = ph->ph_vhci; ASSERT(vh != NULL); if (vh == NULL) { /* Invalid pHCI device, return failure */ MDI_DEBUG(1, (CE_WARN, NULL, "!mdi_pi_free: invalid vHCI pip=%p", (void *)pip)); MDI_PI_UNLOCK(pip); return (MDI_FAILURE); } ct = MDI_PI(pip)->pi_client; ASSERT(ct != NULL); if (ct == NULL) { /* * Invalid Client device, return failure */ MDI_DEBUG(1, (CE_WARN, NULL, "!mdi_pi_free: invalid client pip=%p", (void *)pip)); MDI_PI_UNLOCK(pip); return (MDI_FAILURE); } /* * Check to see for busy condition. A mdi_pathinfo can only be freed * if the node state is either offline or init and the reference count * is zero. */ if (!(MDI_PI_IS_OFFLINE(pip) || MDI_PI_IS_INIT(pip) || MDI_PI_IS_INITING(pip))) { /* * Node is busy */ MDI_DEBUG(1, (CE_WARN, ct->ct_dip, "!mdi_pi_free: pathinfo node is busy pip=%p", (void *)pip)); MDI_PI_UNLOCK(pip); return (MDI_BUSY); } while (MDI_PI(pip)->pi_ref_cnt != 0) { /* * Give a chance for pending I/Os to complete. */ MDI_DEBUG(1, (CE_NOTE, ct->ct_dip, "!mdi_pi_free: " "%d cmds still pending on path: %p\n", MDI_PI(pip)->pi_ref_cnt, (void *)pip)); if (cv_timedwait(&MDI_PI(pip)->pi_ref_cv, &MDI_PI(pip)->pi_mutex, ddi_get_lbolt() + drv_usectohz(60 * 1000000)) == -1) { /* * The timeout time reached without ref_cnt being zero * being signaled. */ MDI_DEBUG(1, (CE_NOTE, ct->ct_dip, "!mdi_pi_free: " "Timeout reached on path %p without the cond\n", (void *)pip)); MDI_DEBUG(1, (CE_NOTE, ct->ct_dip, "!mdi_pi_free: " "%d cmds still pending on path: %p\n", MDI_PI(pip)->pi_ref_cnt, (void *)pip)); MDI_PI_UNLOCK(pip); return (MDI_BUSY); } } if (MDI_PI(pip)->pi_pm_held) { client_held = 1; } MDI_PI_UNLOCK(pip); vhcache_pi_remove(vh->vh_config, MDI_PI(pip)); MDI_CLIENT_LOCK(ct); /* Prevent further failovers till MDI_VHCI_CLIENT_LOCK is held */ MDI_CLIENT_SET_PATH_FREE_IN_PROGRESS(ct); /* * Wait till failover is complete before removing this node. */ while (MDI_CLIENT_IS_FAILOVER_IN_PROGRESS(ct)) cv_wait(&ct->ct_failover_cv, &ct->ct_mutex); MDI_CLIENT_UNLOCK(ct); MDI_VHCI_CLIENT_LOCK(vh); MDI_CLIENT_LOCK(ct); MDI_CLIENT_CLEAR_PATH_FREE_IN_PROGRESS(ct); if (!MDI_PI_IS_INITING(pip)) { f = vh->vh_ops->vo_pi_uninit; if (f != NULL) { rv = (*f)(vh->vh_dip, pip, 0); } } /* * If vo_pi_uninit() completed successfully. */ if (rv == MDI_SUCCESS) { if (client_held) { MDI_DEBUG(4, (CE_NOTE, ct->ct_dip, "mdi_pi_free " "i_mdi_pm_rele_client\n")); i_mdi_pm_rele_client(ct, 1); } i_mdi_pi_free(ph, pip, ct); if (ct->ct_path_count == 0) { /* * Client lost its last path. * Clean up the client device */ MDI_CLIENT_UNLOCK(ct); (void) i_mdi_client_free(ct->ct_vhci, ct); MDI_VHCI_CLIENT_UNLOCK(vh); return (rv); } } MDI_CLIENT_UNLOCK(ct); MDI_VHCI_CLIENT_UNLOCK(vh); if (rv == MDI_FAILURE) vhcache_pi_add(vh->vh_config, MDI_PI(pip)); return (rv); } /* * i_mdi_pi_free(): * Free the mdi_pathinfo node */ static void i_mdi_pi_free(mdi_phci_t *ph, mdi_pathinfo_t *pip, mdi_client_t *ct) { int ct_circular; int ph_circular; ASSERT(MDI_CLIENT_LOCKED(ct)); /* * remove any per-path kstats */ i_mdi_pi_kstat_destroy(pip); /* See comments in i_mdi_pi_alloc() */ ndi_devi_enter(ct->ct_dip, &ct_circular); ndi_devi_enter(ph->ph_dip, &ph_circular); i_mdi_client_remove_path(ct, pip); i_mdi_phci_remove_path(ph, pip); ndi_devi_exit(ph->ph_dip, ph_circular); ndi_devi_exit(ct->ct_dip, ct_circular); mutex_destroy(&MDI_PI(pip)->pi_mutex); cv_destroy(&MDI_PI(pip)->pi_state_cv); cv_destroy(&MDI_PI(pip)->pi_ref_cv); if (MDI_PI(pip)->pi_addr) { kmem_free(MDI_PI(pip)->pi_addr, strlen(MDI_PI(pip)->pi_addr) + 1); MDI_PI(pip)->pi_addr = NULL; } if (MDI_PI(pip)->pi_prop) { (void) nvlist_free(MDI_PI(pip)->pi_prop); MDI_PI(pip)->pi_prop = NULL; } kmem_free(pip, sizeof (struct mdi_pathinfo)); } /* * i_mdi_phci_remove_path(): * Remove a mdi_pathinfo node from pHCI list. * Notes: * Caller should hold per-pHCI mutex */ static void i_mdi_phci_remove_path(mdi_phci_t *ph, mdi_pathinfo_t *pip) { mdi_pathinfo_t *prev = NULL; mdi_pathinfo_t *path = NULL; ASSERT(DEVI_BUSY_OWNED(ph->ph_dip)); MDI_PHCI_LOCK(ph); path = ph->ph_path_head; while (path != NULL) { if (path == pip) { break; } prev = path; path = (mdi_pathinfo_t *)MDI_PI(path)->pi_phci_link; } if (path) { ph->ph_path_count--; if (prev) { MDI_PI(prev)->pi_phci_link = MDI_PI(path)->pi_phci_link; } else { ph->ph_path_head = (mdi_pathinfo_t *)MDI_PI(path)->pi_phci_link; } if (ph->ph_path_tail == path) { ph->ph_path_tail = prev; } } /* * Clear the pHCI link */ MDI_PI(pip)->pi_phci_link = NULL; MDI_PI(pip)->pi_phci = NULL; MDI_PHCI_UNLOCK(ph); } /* * i_mdi_client_remove_path(): * Remove a mdi_pathinfo node from client path list. */ static void i_mdi_client_remove_path(mdi_client_t *ct, mdi_pathinfo_t *pip) { mdi_pathinfo_t *prev = NULL; mdi_pathinfo_t *path; ASSERT(DEVI_BUSY_OWNED(ct->ct_dip)); ASSERT(MDI_CLIENT_LOCKED(ct)); path = ct->ct_path_head; while (path != NULL) { if (path == pip) { break; } prev = path; path = (mdi_pathinfo_t *)MDI_PI(path)->pi_client_link; } if (path) { ct->ct_path_count--; if (prev) { MDI_PI(prev)->pi_client_link = MDI_PI(path)->pi_client_link; } else { ct->ct_path_head = (mdi_pathinfo_t *)MDI_PI(path)->pi_client_link; } if (ct->ct_path_tail == path) { ct->ct_path_tail = prev; } if (ct->ct_path_last == path) { ct->ct_path_last = ct->ct_path_head; } } MDI_PI(pip)->pi_client_link = NULL; MDI_PI(pip)->pi_client = NULL; } /* * i_mdi_pi_state_change(): * online a mdi_pathinfo node * * Return Values: * MDI_SUCCESS * MDI_FAILURE */ /*ARGSUSED*/ static int i_mdi_pi_state_change(mdi_pathinfo_t *pip, mdi_pathinfo_state_t state, int flag) { int rv = MDI_SUCCESS; mdi_vhci_t *vh; mdi_phci_t *ph; mdi_client_t *ct; int (*f)(); dev_info_t *cdip; MDI_PI_LOCK(pip); ph = MDI_PI(pip)->pi_phci; ASSERT(ph); if (ph == NULL) { /* * Invalid pHCI device, fail the request */ MDI_PI_UNLOCK(pip); MDI_DEBUG(1, (CE_WARN, NULL, "!mdi_pi_state_change: invalid phci pip=%p", (void *)pip)); return (MDI_FAILURE); } vh = ph->ph_vhci; ASSERT(vh); if (vh == NULL) { /* * Invalid vHCI device, fail the request */ MDI_PI_UNLOCK(pip); MDI_DEBUG(1, (CE_WARN, NULL, "!mdi_pi_state_change: invalid vhci pip=%p", (void *)pip)); return (MDI_FAILURE); } ct = MDI_PI(pip)->pi_client; ASSERT(ct != NULL); if (ct == NULL) { /* * Invalid client device, fail the request */ MDI_PI_UNLOCK(pip); MDI_DEBUG(1, (CE_WARN, NULL, "!mdi_pi_state_change: invalid client pip=%p", (void *)pip)); return (MDI_FAILURE); } /* * If this path has not been initialized yet, Callback vHCI driver's * pathinfo node initialize entry point */ if (MDI_PI_IS_INITING(pip)) { MDI_PI_UNLOCK(pip); f = vh->vh_ops->vo_pi_init; if (f != NULL) { rv = (*f)(vh->vh_dip, pip, 0); if (rv != MDI_SUCCESS) { MDI_DEBUG(1, (CE_WARN, ct->ct_dip, "!vo_pi_init: failed vHCI=0x%p, pip=0x%p", (void *)vh, (void *)pip)); return (MDI_FAILURE); } } MDI_PI_LOCK(pip); MDI_PI_CLEAR_TRANSIENT(pip); } /* * Do not allow state transition when pHCI is in offline/suspended * states */ i_mdi_phci_lock(ph, pip); if (MDI_PHCI_IS_READY(ph) == 0) { MDI_DEBUG(1, (CE_WARN, ct->ct_dip, "!mdi_pi_state_change: pHCI not ready, pHCI=%p", (void *)ph)); MDI_PI_UNLOCK(pip); i_mdi_phci_unlock(ph); return (MDI_BUSY); } MDI_PHCI_UNSTABLE(ph); i_mdi_phci_unlock(ph); /* * Check if mdi_pathinfo state is in transient state. * If yes, offlining is in progress and wait till transient state is * cleared. */ if (MDI_PI_IS_TRANSIENT(pip)) { while (MDI_PI_IS_TRANSIENT(pip)) { cv_wait(&MDI_PI(pip)->pi_state_cv, &MDI_PI(pip)->pi_mutex); } } /* * Grab the client lock in reverse order sequence and release the * mdi_pathinfo mutex. */ i_mdi_client_lock(ct, pip); MDI_PI_UNLOCK(pip); /* * Wait till failover state is cleared */ while (MDI_CLIENT_IS_FAILOVER_IN_PROGRESS(ct)) cv_wait(&ct->ct_failover_cv, &ct->ct_mutex); /* * Mark the mdi_pathinfo node state as transient */ MDI_PI_LOCK(pip); switch (state) { case MDI_PATHINFO_STATE_ONLINE: MDI_PI_SET_ONLINING(pip); break; case MDI_PATHINFO_STATE_STANDBY: MDI_PI_SET_STANDBYING(pip); break; case MDI_PATHINFO_STATE_FAULT: /* * Mark the pathinfo state as FAULTED */ MDI_PI_SET_FAULTING(pip); MDI_PI_ERRSTAT(pip, MDI_PI_HARDERR); break; case MDI_PATHINFO_STATE_OFFLINE: /* * ndi_devi_offline() cannot hold pip or ct locks. */ MDI_PI_UNLOCK(pip); /* * Don't offline the client dev_info node unless we have * no available paths left at all. */ cdip = ct->ct_dip; if ((flag & NDI_DEVI_REMOVE) && (ct->ct_path_count == 1)) { i_mdi_client_unlock(ct); rv = ndi_devi_offline(cdip, 0); if (rv != NDI_SUCCESS) { /* * Convert to MDI error code */ switch (rv) { case NDI_BUSY: rv = MDI_BUSY; break; default: rv = MDI_FAILURE; break; } goto state_change_exit; } else { i_mdi_client_lock(ct, NULL); } } /* * Mark the mdi_pathinfo node state as transient */ MDI_PI_LOCK(pip); MDI_PI_SET_OFFLINING(pip); break; } MDI_PI_UNLOCK(pip); MDI_CLIENT_UNSTABLE(ct); i_mdi_client_unlock(ct); f = vh->vh_ops->vo_pi_state_change; if (f != NULL) rv = (*f)(vh->vh_dip, pip, state, 0, flag); MDI_CLIENT_LOCK(ct); MDI_PI_LOCK(pip); if (rv == MDI_NOT_SUPPORTED) { MDI_CLIENT_SET_DEV_NOT_SUPPORTED(ct); } if (rv != MDI_SUCCESS) { MDI_DEBUG(2, (CE_WARN, ct->ct_dip, "!vo_pi_state_change: failed rv = %x", rv)); } if (MDI_PI_IS_TRANSIENT(pip)) { if (rv == MDI_SUCCESS) { MDI_PI_CLEAR_TRANSIENT(pip); } else { MDI_PI(pip)->pi_state = MDI_PI_OLD_STATE(pip); } } /* * Wake anyone waiting for this mdi_pathinfo node */ cv_broadcast(&MDI_PI(pip)->pi_state_cv); MDI_PI_UNLOCK(pip); /* * Mark the client device as stable */ MDI_CLIENT_STABLE(ct); if (rv == MDI_SUCCESS) { if (ct->ct_unstable == 0) { cdip = ct->ct_dip; /* * Onlining the mdi_pathinfo node will impact the * client state Update the client and dev_info node * state accordingly */ rv = NDI_SUCCESS; i_mdi_client_update_state(ct); switch (MDI_CLIENT_STATE(ct)) { case MDI_CLIENT_STATE_OPTIMAL: case MDI_CLIENT_STATE_DEGRADED: if (cdip && !i_ddi_devi_attached(cdip) && ((state == MDI_PATHINFO_STATE_ONLINE) || (state == MDI_PATHINFO_STATE_STANDBY))) { /* * Must do ndi_devi_online() through * hotplug thread for deferred * attach mechanism to work */ MDI_CLIENT_UNLOCK(ct); rv = ndi_devi_online(cdip, 0); MDI_CLIENT_LOCK(ct); if ((rv != NDI_SUCCESS) && (MDI_CLIENT_STATE(ct) == MDI_CLIENT_STATE_DEGRADED)) { /* * ndi_devi_online failed. * Reset client flags to * offline. */ MDI_DEBUG(1, (CE_WARN, cdip, "!ndi_devi_online: failed " " Error: %x", rv)); MDI_CLIENT_SET_OFFLINE(ct); } if (rv != NDI_SUCCESS) { /* Reset the path state */ MDI_PI_LOCK(pip); MDI_PI(pip)->pi_state = MDI_PI_OLD_STATE(pip); MDI_PI_UNLOCK(pip); } } break; case MDI_CLIENT_STATE_FAILED: /* * This is the last path case for * non-user initiated events. */ if (((flag & NDI_DEVI_REMOVE) == 0) && cdip && (i_ddi_node_state(cdip) >= DS_INITIALIZED)) { MDI_CLIENT_UNLOCK(ct); rv = ndi_devi_offline(cdip, 0); MDI_CLIENT_LOCK(ct); if (rv != NDI_SUCCESS) { /* * ndi_devi_offline failed. * Reset client flags to * online as the path could not * be offlined. */ MDI_DEBUG(1, (CE_WARN, cdip, "!ndi_devi_offline: failed " " Error: %x", rv)); MDI_CLIENT_SET_ONLINE(ct); } } break; } /* * Convert to MDI error code */ switch (rv) { case NDI_SUCCESS: MDI_CLIENT_SET_REPORT_DEV_NEEDED(ct); i_mdi_report_path_state(ct, pip); rv = MDI_SUCCESS; break; case NDI_BUSY: rv = MDI_BUSY; break; default: rv = MDI_FAILURE; break; } } } MDI_CLIENT_UNLOCK(ct); state_change_exit: /* * Mark the pHCI as stable again. */ MDI_PHCI_LOCK(ph); MDI_PHCI_STABLE(ph); MDI_PHCI_UNLOCK(ph); return (rv); } /* * mdi_pi_online(): * Place the path_info node in the online state. The path is * now available to be selected by mdi_select_path() for * transporting I/O requests to client devices. * Return Values: * MDI_SUCCESS * MDI_FAILURE */ int mdi_pi_online(mdi_pathinfo_t *pip, int flags) { mdi_client_t *ct = MDI_PI(pip)->pi_client; int client_held = 0; int rv; int se_flag; int kmem_flag; ASSERT(ct != NULL); rv = i_mdi_pi_state_change(pip, MDI_PATHINFO_STATE_ONLINE, flags); if (rv != MDI_SUCCESS) return (rv); MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_pm_held == 0) { MDI_DEBUG(4, (CE_NOTE, ct->ct_dip, "mdi_pi_online " "i_mdi_pm_hold_pip %p\n", (void *)pip)); i_mdi_pm_hold_pip(pip); client_held = 1; } MDI_PI_UNLOCK(pip); if (client_held) { MDI_CLIENT_LOCK(ct); if (ct->ct_power_cnt == 0) { rv = i_mdi_power_all_phci(ct); } MDI_DEBUG(4, (CE_NOTE, ct->ct_dip, "mdi_pi_online " "i_mdi_pm_hold_client %p\n", (void *)ct)); i_mdi_pm_hold_client(ct, 1); MDI_CLIENT_UNLOCK(ct); } /* determine interrupt context */ se_flag = (servicing_interrupt()) ? SE_NOSLEEP : SE_SLEEP; kmem_flag = (se_flag == SE_SLEEP) ? KM_SLEEP : KM_NOSLEEP; /* A new path is online. Invalidate DINFOCACHE snap shot. */ i_ddi_di_cache_invalidate(kmem_flag); return (rv); } /* * mdi_pi_standby(): * Place the mdi_pathinfo node in standby state * * Return Values: * MDI_SUCCESS * MDI_FAILURE */ int mdi_pi_standby(mdi_pathinfo_t *pip, int flags) { return (i_mdi_pi_state_change(pip, MDI_PATHINFO_STATE_STANDBY, flags)); } /* * mdi_pi_fault(): * Place the mdi_pathinfo node in fault'ed state * Return Values: * MDI_SUCCESS * MDI_FAILURE */ int mdi_pi_fault(mdi_pathinfo_t *pip, int flags) { return (i_mdi_pi_state_change(pip, MDI_PATHINFO_STATE_FAULT, flags)); } /* * mdi_pi_offline(): * Offline a mdi_pathinfo node. * Return Values: * MDI_SUCCESS * MDI_FAILURE */ int mdi_pi_offline(mdi_pathinfo_t *pip, int flags) { int ret, client_held = 0; mdi_client_t *ct; int se_flag; int kmem_flag; ret = i_mdi_pi_state_change(pip, MDI_PATHINFO_STATE_OFFLINE, flags); if (ret == MDI_SUCCESS) { MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_pm_held) { client_held = 1; } MDI_PI_UNLOCK(pip); if (client_held) { ct = MDI_PI(pip)->pi_client; MDI_CLIENT_LOCK(ct); MDI_DEBUG(4, (CE_NOTE, ct->ct_dip, "mdi_pi_offline i_mdi_pm_rele_client\n")); i_mdi_pm_rele_client(ct, 1); MDI_CLIENT_UNLOCK(ct); } /* determine interrupt context */ se_flag = (servicing_interrupt()) ? SE_NOSLEEP : SE_SLEEP; kmem_flag = (se_flag == SE_SLEEP) ? KM_SLEEP : KM_NOSLEEP; /* pathinfo is offlined. update DINFOCACHE. */ i_ddi_di_cache_invalidate(kmem_flag); } return (ret); } /* * i_mdi_pi_offline(): * Offline a mdi_pathinfo node and call the vHCI driver's callback */ static int i_mdi_pi_offline(mdi_pathinfo_t *pip, int flags) { dev_info_t *vdip = NULL; mdi_vhci_t *vh = NULL; mdi_client_t *ct = NULL; int (*f)(); int rv; MDI_PI_LOCK(pip); ct = MDI_PI(pip)->pi_client; ASSERT(ct != NULL); while (MDI_PI(pip)->pi_ref_cnt != 0) { /* * Give a chance for pending I/Os to complete. */ MDI_DEBUG(1, (CE_NOTE, ct->ct_dip, "!i_mdi_pi_offline: " "%d cmds still pending on path: %p\n", MDI_PI(pip)->pi_ref_cnt, (void *)pip)); if (cv_timedwait(&MDI_PI(pip)->pi_ref_cv, &MDI_PI(pip)->pi_mutex, ddi_get_lbolt() + drv_usectohz(60 * 1000000)) == -1) { /* * The timeout time reached without ref_cnt being zero * being signaled. */ MDI_DEBUG(1, (CE_NOTE, ct->ct_dip, "!i_mdi_pi_offline: " "Timeout reached on path %p without the cond\n", (void *)pip)); MDI_DEBUG(1, (CE_NOTE, ct->ct_dip, "!i_mdi_pi_offline: " "%d cmds still pending on path: %p\n", MDI_PI(pip)->pi_ref_cnt, (void *)pip)); } } vh = ct->ct_vhci; vdip = vh->vh_dip; /* * Notify vHCI that has registered this event */ ASSERT(vh->vh_ops); f = vh->vh_ops->vo_pi_state_change; if (f != NULL) { MDI_PI_UNLOCK(pip); if ((rv = (*f)(vdip, pip, MDI_PATHINFO_STATE_OFFLINE, 0, flags)) != MDI_SUCCESS) { MDI_DEBUG(1, (CE_WARN, ct->ct_dip, "!vo_path_offline failed " "vdip %p, pip %p", (void *)vdip, (void *)pip)); } MDI_PI_LOCK(pip); } /* * Set the mdi_pathinfo node state and clear the transient condition */ MDI_PI_SET_OFFLINE(pip); cv_broadcast(&MDI_PI(pip)->pi_state_cv); MDI_PI_UNLOCK(pip); MDI_CLIENT_LOCK(ct); if (rv == MDI_SUCCESS) { if (ct->ct_unstable == 0) { dev_info_t *cdip = ct->ct_dip; /* * Onlining the mdi_pathinfo node will impact the * client state Update the client and dev_info node * state accordingly */ i_mdi_client_update_state(ct); rv = NDI_SUCCESS; if (MDI_CLIENT_STATE(ct) == MDI_CLIENT_STATE_FAILED) { if (cdip && (i_ddi_node_state(cdip) >= DS_INITIALIZED)) { MDI_CLIENT_UNLOCK(ct); rv = ndi_devi_offline(cdip, 0); MDI_CLIENT_LOCK(ct); if (rv != NDI_SUCCESS) { /* * ndi_devi_offline failed. * Reset client flags to * online. */ MDI_DEBUG(4, (CE_WARN, cdip, "!ndi_devi_offline: failed " " Error: %x", rv)); MDI_CLIENT_SET_ONLINE(ct); } } } /* * Convert to MDI error code */ switch (rv) { case NDI_SUCCESS: rv = MDI_SUCCESS; break; case NDI_BUSY: rv = MDI_BUSY; break; default: rv = MDI_FAILURE; break; } } MDI_CLIENT_SET_REPORT_DEV_NEEDED(ct); i_mdi_report_path_state(ct, pip); } MDI_CLIENT_UNLOCK(ct); /* * Change in the mdi_pathinfo node state will impact the client state */ MDI_DEBUG(2, (CE_NOTE, NULL, "!i_mdi_pi_offline ct = %p pip = %p", (void *)ct, (void *)pip)); return (rv); } /* * mdi_pi_get_addr(): * Get the unit address associated with a mdi_pathinfo node * * Return Values: * char * */ char * mdi_pi_get_addr(mdi_pathinfo_t *pip) { if (pip == NULL) return (NULL); return (MDI_PI(pip)->pi_addr); } /* * mdi_pi_get_path_instance(): * Get the 'path_instance' of a mdi_pathinfo node * * Return Values: * path_instance */ int mdi_pi_get_path_instance(mdi_pathinfo_t *pip) { if (pip == NULL) return (0); return (MDI_PI(pip)->pi_path_instance); } /* * mdi_pi_pathname(): * Return pointer to path to pathinfo node. */ char * mdi_pi_pathname(mdi_pathinfo_t *pip) { if (pip == NULL) return (NULL); return (mdi_pi_pathname_by_instance(mdi_pi_get_path_instance(pip))); } char * mdi_pi_pathname_obp(mdi_pathinfo_t *pip, char *path) { char *obp_path = NULL; if ((pip == NULL) || (path == NULL)) return (NULL); if (mdi_prop_lookup_string(pip, "obp-path", &obp_path) == MDI_SUCCESS) { (void) strcpy(path, obp_path); (void) mdi_prop_free(obp_path); } else { path = NULL; } return (path); } int mdi_pi_pathname_obp_set(mdi_pathinfo_t *pip, char *component) { dev_info_t *pdip; char obp_path[MAXPATHLEN]; if (pip == NULL) return (MDI_FAILURE); bzero(obp_path, sizeof (obp_path)); pdip = mdi_pi_get_phci(pip); if (pdip == NULL) return (MDI_FAILURE); if (ddi_pathname_obp(pdip, obp_path) == NULL) { (void) ddi_pathname(pdip, obp_path); } if (component) { (void) strncat(obp_path, "/", sizeof (obp_path)); (void) strncat(obp_path, component, sizeof (obp_path)); } return (mdi_prop_update_string(pip, "obp-path", obp_path)); } /* * mdi_pi_get_client(): * Get the client devinfo associated with a mdi_pathinfo node * * Return Values: * Handle to client device dev_info node */ dev_info_t * mdi_pi_get_client(mdi_pathinfo_t *pip) { dev_info_t *dip = NULL; if (pip) { dip = MDI_PI(pip)->pi_client->ct_dip; } return (dip); } /* * mdi_pi_get_phci(): * Get the pHCI devinfo associated with the mdi_pathinfo node * Return Values: * Handle to dev_info node */ dev_info_t * mdi_pi_get_phci(mdi_pathinfo_t *pip) { dev_info_t *dip = NULL; if (pip) { dip = MDI_PI(pip)->pi_phci->ph_dip; } return (dip); } /* * mdi_pi_get_client_private(): * Get the client private information associated with the * mdi_pathinfo node */ void * mdi_pi_get_client_private(mdi_pathinfo_t *pip) { void *cprivate = NULL; if (pip) { cprivate = MDI_PI(pip)->pi_cprivate; } return (cprivate); } /* * mdi_pi_set_client_private(): * Set the client private information in the mdi_pathinfo node */ void mdi_pi_set_client_private(mdi_pathinfo_t *pip, void *priv) { if (pip) { MDI_PI(pip)->pi_cprivate = priv; } } /* * mdi_pi_get_phci_private(): * Get the pHCI private information associated with the * mdi_pathinfo node */ caddr_t mdi_pi_get_phci_private(mdi_pathinfo_t *pip) { caddr_t pprivate = NULL; if (pip) { pprivate = MDI_PI(pip)->pi_pprivate; } return (pprivate); } /* * mdi_pi_set_phci_private(): * Set the pHCI private information in the mdi_pathinfo node */ void mdi_pi_set_phci_private(mdi_pathinfo_t *pip, caddr_t priv) { if (pip) { MDI_PI(pip)->pi_pprivate = priv; } } /* * mdi_pi_get_state(): * Get the mdi_pathinfo node state. Transient states are internal * and not provided to the users */ mdi_pathinfo_state_t mdi_pi_get_state(mdi_pathinfo_t *pip) { mdi_pathinfo_state_t state = MDI_PATHINFO_STATE_INIT; if (pip) { if (MDI_PI_IS_TRANSIENT(pip)) { /* * mdi_pathinfo is in state transition. Return the * last good state. */ state = MDI_PI_OLD_STATE(pip); } else { state = MDI_PI_STATE(pip); } } return (state); } /* * Note that the following function needs to be the new interface for * mdi_pi_get_state when mpxio gets integrated to ON. */ int mdi_pi_get_state2(mdi_pathinfo_t *pip, mdi_pathinfo_state_t *state, uint32_t *ext_state) { *state = MDI_PATHINFO_STATE_INIT; if (pip) { if (MDI_PI_IS_TRANSIENT(pip)) { /* * mdi_pathinfo is in state transition. Return the * last good state. */ *state = MDI_PI_OLD_STATE(pip); *ext_state = MDI_PI_OLD_EXT_STATE(pip); } else { *state = MDI_PI_STATE(pip); *ext_state = MDI_PI_EXT_STATE(pip); } } return (MDI_SUCCESS); } /* * mdi_pi_get_preferred: * Get the preferred path flag */ int mdi_pi_get_preferred(mdi_pathinfo_t *pip) { if (pip) { return (MDI_PI(pip)->pi_preferred); } return (0); } /* * mdi_pi_set_preferred: * Set the preferred path flag */ void mdi_pi_set_preferred(mdi_pathinfo_t *pip, int preferred) { if (pip) { MDI_PI(pip)->pi_preferred = preferred; } } /* * mdi_pi_set_state(): * Set the mdi_pathinfo node state */ void mdi_pi_set_state(mdi_pathinfo_t *pip, mdi_pathinfo_state_t state) { uint32_t ext_state; if (pip) { ext_state = MDI_PI(pip)->pi_state & MDI_PATHINFO_EXT_STATE_MASK; MDI_PI(pip)->pi_state = state; MDI_PI(pip)->pi_state |= ext_state; } } /* * Property functions: */ int i_map_nvlist_error_to_mdi(int val) { int rv; switch (val) { case 0: rv = DDI_PROP_SUCCESS; break; case EINVAL: case ENOTSUP: rv = DDI_PROP_INVAL_ARG; break; case ENOMEM: rv = DDI_PROP_NO_MEMORY; break; default: rv = DDI_PROP_NOT_FOUND; break; } return (rv); } /* * mdi_pi_get_next_prop(): * Property walk function. The caller should hold mdi_pi_lock() * and release by calling mdi_pi_unlock() at the end of walk to * get a consistent value. */ nvpair_t * mdi_pi_get_next_prop(mdi_pathinfo_t *pip, nvpair_t *prev) { if ((pip == NULL) || (MDI_PI(pip)->pi_prop == NULL)) { return (NULL); } ASSERT(MDI_PI_LOCKED(pip)); return (nvlist_next_nvpair(MDI_PI(pip)->pi_prop, prev)); } /* * mdi_prop_remove(): * Remove the named property from the named list. */ int mdi_prop_remove(mdi_pathinfo_t *pip, char *name) { if (pip == NULL) { return (DDI_PROP_NOT_FOUND); } ASSERT(!MDI_PI_LOCKED(pip)); MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_prop == NULL) { MDI_PI_UNLOCK(pip); return (DDI_PROP_NOT_FOUND); } if (name) { (void) nvlist_remove_all(MDI_PI(pip)->pi_prop, name); } else { char nvp_name[MAXNAMELEN]; nvpair_t *nvp; nvp = nvlist_next_nvpair(MDI_PI(pip)->pi_prop, NULL); while (nvp) { nvpair_t *next; next = nvlist_next_nvpair(MDI_PI(pip)->pi_prop, nvp); (void) snprintf(nvp_name, MAXNAMELEN, "%s", nvpair_name(nvp)); (void) nvlist_remove_all(MDI_PI(pip)->pi_prop, nvp_name); nvp = next; } } MDI_PI_UNLOCK(pip); return (DDI_PROP_SUCCESS); } /* * mdi_prop_size(): * Get buffer size needed to pack the property data. * Caller should hold the mdi_pathinfo_t lock to get a consistent * buffer size. */ int mdi_prop_size(mdi_pathinfo_t *pip, size_t *buflenp) { int rv; size_t bufsize; *buflenp = 0; if ((pip == NULL) || (MDI_PI(pip)->pi_prop == NULL)) { return (DDI_PROP_NOT_FOUND); } ASSERT(MDI_PI_LOCKED(pip)); rv = nvlist_size(MDI_PI(pip)->pi_prop, &bufsize, NV_ENCODE_NATIVE); *buflenp = bufsize; return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_pack(): * pack the property list. The caller should hold the * mdi_pathinfo_t node to get a consistent data */ int mdi_prop_pack(mdi_pathinfo_t *pip, char **bufp, uint_t buflen) { int rv; size_t bufsize; if ((pip == NULL) || MDI_PI(pip)->pi_prop == NULL) { return (DDI_PROP_NOT_FOUND); } ASSERT(MDI_PI_LOCKED(pip)); bufsize = buflen; rv = nvlist_pack(MDI_PI(pip)->pi_prop, bufp, (size_t *)&bufsize, NV_ENCODE_NATIVE, KM_SLEEP); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_update_byte(): * Create/Update a byte property */ int mdi_prop_update_byte(mdi_pathinfo_t *pip, char *name, uchar_t data) { int rv; if (pip == NULL) { return (DDI_PROP_INVAL_ARG); } ASSERT(!MDI_PI_LOCKED(pip)); MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_prop == NULL) { MDI_PI_UNLOCK(pip); return (DDI_PROP_NOT_FOUND); } rv = nvlist_add_byte(MDI_PI(pip)->pi_prop, name, data); MDI_PI_UNLOCK(pip); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_update_byte_array(): * Create/Update a byte array property */ int mdi_prop_update_byte_array(mdi_pathinfo_t *pip, char *name, uchar_t *data, uint_t nelements) { int rv; if (pip == NULL) { return (DDI_PROP_INVAL_ARG); } ASSERT(!MDI_PI_LOCKED(pip)); MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_prop == NULL) { MDI_PI_UNLOCK(pip); return (DDI_PROP_NOT_FOUND); } rv = nvlist_add_byte_array(MDI_PI(pip)->pi_prop, name, data, nelements); MDI_PI_UNLOCK(pip); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_update_int(): * Create/Update a 32 bit integer property */ int mdi_prop_update_int(mdi_pathinfo_t *pip, char *name, int data) { int rv; if (pip == NULL) { return (DDI_PROP_INVAL_ARG); } ASSERT(!MDI_PI_LOCKED(pip)); MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_prop == NULL) { MDI_PI_UNLOCK(pip); return (DDI_PROP_NOT_FOUND); } rv = nvlist_add_int32(MDI_PI(pip)->pi_prop, name, (int32_t)data); MDI_PI_UNLOCK(pip); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_update_int64(): * Create/Update a 64 bit integer property */ int mdi_prop_update_int64(mdi_pathinfo_t *pip, char *name, int64_t data) { int rv; if (pip == NULL) { return (DDI_PROP_INVAL_ARG); } ASSERT(!MDI_PI_LOCKED(pip)); MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_prop == NULL) { MDI_PI_UNLOCK(pip); return (DDI_PROP_NOT_FOUND); } rv = nvlist_add_int64(MDI_PI(pip)->pi_prop, name, data); MDI_PI_UNLOCK(pip); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_update_int_array(): * Create/Update a int array property */ int mdi_prop_update_int_array(mdi_pathinfo_t *pip, char *name, int *data, uint_t nelements) { int rv; if (pip == NULL) { return (DDI_PROP_INVAL_ARG); } ASSERT(!MDI_PI_LOCKED(pip)); MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_prop == NULL) { MDI_PI_UNLOCK(pip); return (DDI_PROP_NOT_FOUND); } rv = nvlist_add_int32_array(MDI_PI(pip)->pi_prop, name, (int32_t *)data, nelements); MDI_PI_UNLOCK(pip); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_update_string(): * Create/Update a string property */ int mdi_prop_update_string(mdi_pathinfo_t *pip, char *name, char *data) { int rv; if (pip == NULL) { return (DDI_PROP_INVAL_ARG); } ASSERT(!MDI_PI_LOCKED(pip)); MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_prop == NULL) { MDI_PI_UNLOCK(pip); return (DDI_PROP_NOT_FOUND); } rv = nvlist_add_string(MDI_PI(pip)->pi_prop, name, data); MDI_PI_UNLOCK(pip); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_update_string_array(): * Create/Update a string array property */ int mdi_prop_update_string_array(mdi_pathinfo_t *pip, char *name, char **data, uint_t nelements) { int rv; if (pip == NULL) { return (DDI_PROP_INVAL_ARG); } ASSERT(!MDI_PI_LOCKED(pip)); MDI_PI_LOCK(pip); if (MDI_PI(pip)->pi_prop == NULL) { MDI_PI_UNLOCK(pip); return (DDI_PROP_NOT_FOUND); } rv = nvlist_add_string_array(MDI_PI(pip)->pi_prop, name, data, nelements); MDI_PI_UNLOCK(pip); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_lookup_byte(): * Look for byte property identified by name. The data returned * is the actual property and valid as long as mdi_pathinfo_t node * is alive. */ int mdi_prop_lookup_byte(mdi_pathinfo_t *pip, char *name, uchar_t *data) { int rv; if ((pip == NULL) || (MDI_PI(pip)->pi_prop == NULL)) { return (DDI_PROP_NOT_FOUND); } rv = nvlist_lookup_byte(MDI_PI(pip)->pi_prop, name, data); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_lookup_byte_array(): * Look for byte array property identified by name. The data * returned is the actual property and valid as long as * mdi_pathinfo_t node is alive. */ int mdi_prop_lookup_byte_array(mdi_pathinfo_t *pip, char *name, uchar_t **data, uint_t *nelements) { int rv; if ((pip == NULL) || (MDI_PI(pip)->pi_prop == NULL)) { return (DDI_PROP_NOT_FOUND); } rv = nvlist_lookup_byte_array(MDI_PI(pip)->pi_prop, name, data, nelements); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_lookup_int(): * Look for int property identified by name. The data returned * is the actual property and valid as long as mdi_pathinfo_t * node is alive. */ int mdi_prop_lookup_int(mdi_pathinfo_t *pip, char *name, int *data) { int rv; if ((pip == NULL) || (MDI_PI(pip)->pi_prop == NULL)) { return (DDI_PROP_NOT_FOUND); } rv = nvlist_lookup_int32(MDI_PI(pip)->pi_prop, name, (int32_t *)data); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_lookup_int64(): * Look for int64 property identified by name. The data returned * is the actual property and valid as long as mdi_pathinfo_t node * is alive. */ int mdi_prop_lookup_int64(mdi_pathinfo_t *pip, char *name, int64_t *data) { int rv; if ((pip == NULL) || (MDI_PI(pip)->pi_prop == NULL)) { return (DDI_PROP_NOT_FOUND); } rv = nvlist_lookup_int64(MDI_PI(pip)->pi_prop, name, data); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_lookup_int_array(): * Look for int array property identified by name. The data * returned is the actual property and valid as long as * mdi_pathinfo_t node is alive. */ int mdi_prop_lookup_int_array(mdi_pathinfo_t *pip, char *name, int **data, uint_t *nelements) { int rv; if ((pip == NULL) || (MDI_PI(pip)->pi_prop == NULL)) { return (DDI_PROP_NOT_FOUND); } rv = nvlist_lookup_int32_array(MDI_PI(pip)->pi_prop, name, (int32_t **)data, nelements); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_lookup_string(): * Look for string property identified by name. The data * returned is the actual property and valid as long as * mdi_pathinfo_t node is alive. */ int mdi_prop_lookup_string(mdi_pathinfo_t *pip, char *name, char **data) { int rv; if ((pip == NULL) || (MDI_PI(pip)->pi_prop == NULL)) { return (DDI_PROP_NOT_FOUND); } rv = nvlist_lookup_string(MDI_PI(pip)->pi_prop, name, data); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_lookup_string_array(): * Look for string array property identified by name. The data * returned is the actual property and valid as long as * mdi_pathinfo_t node is alive. */ int mdi_prop_lookup_string_array(mdi_pathinfo_t *pip, char *name, char ***data, uint_t *nelements) { int rv; if ((pip == NULL) || (MDI_PI(pip)->pi_prop == NULL)) { return (DDI_PROP_NOT_FOUND); } rv = nvlist_lookup_string_array(MDI_PI(pip)->pi_prop, name, data, nelements); return (i_map_nvlist_error_to_mdi(rv)); } /* * mdi_prop_free(): * Symmetrical function to ddi_prop_free(). nvlist_lookup_xx() * functions return the pointer to actual property data and not a * copy of it. So the data returned is valid as long as * mdi_pathinfo_t node is valid. */ /*ARGSUSED*/ int mdi_prop_free(void *data) { return (DDI_PROP_SUCCESS); } /*ARGSUSED*/ static void i_mdi_report_path_state(mdi_client_t *ct, mdi_pathinfo_t *pip) { char *phci_path, *ct_path; char *ct_status; char *status; dev_info_t *dip = ct->ct_dip; char lb_buf[64]; ASSERT(MDI_CLIENT_LOCKED(ct)); if ((dip == NULL) || (ddi_get_instance(dip) == -1) || (MDI_CLIENT_IS_REPORT_DEV_NEEDED(ct) == 0)) { return; } if (MDI_CLIENT_STATE(ct) == MDI_CLIENT_STATE_OPTIMAL) { ct_status = "optimal"; } else if (MDI_CLIENT_STATE(ct) == MDI_CLIENT_STATE_DEGRADED) { ct_status = "degraded"; } else if (MDI_CLIENT_STATE(ct) == MDI_CLIENT_STATE_FAILED) { ct_status = "failed"; } else { ct_status = "unknown"; } if (MDI_PI_IS_OFFLINE(pip)) { status = "offline"; } else if (MDI_PI_IS_ONLINE(pip)) { status = "online"; } else if (MDI_PI_IS_STANDBY(pip)) { status = "standby"; } else if (MDI_PI_IS_FAULT(pip)) { status = "faulted"; } else { status = "unknown"; } if (ct->ct_lb == LOAD_BALANCE_LBA) { (void) snprintf(lb_buf, sizeof (lb_buf), "%s, region-size: %d", mdi_load_balance_lba, ct->ct_lb_args->region_size); } else if (ct->ct_lb == LOAD_BALANCE_NONE) { (void) snprintf(lb_buf, sizeof (lb_buf), "%s", mdi_load_balance_none); } else { (void) snprintf(lb_buf, sizeof (lb_buf), "%s", mdi_load_balance_rr); } if (dip) { ct_path = kmem_alloc(MAXPATHLEN, KM_SLEEP); phci_path = kmem_alloc(MAXPATHLEN, KM_SLEEP); cmn_err(CE_CONT, "?%s (%s%d) multipath status: %s, " "path %s (%s%d) to target address: %s is %s" " Load balancing: %s\n", ddi_pathname(dip, ct_path), ddi_driver_name(dip), ddi_get_instance(dip), ct_status, ddi_pathname(MDI_PI(pip)->pi_phci->ph_dip, phci_path), ddi_driver_name(MDI_PI(pip)->pi_phci->ph_dip), ddi_get_instance(MDI_PI(pip)->pi_phci->ph_dip), MDI_PI(pip)->pi_addr, status, lb_buf); kmem_free(phci_path, MAXPATHLEN); kmem_free(ct_path, MAXPATHLEN); MDI_CLIENT_CLEAR_REPORT_DEV_NEEDED(ct); } } #ifdef DEBUG /* * i_mdi_log(): * Utility function for error message management * */ /*PRINTFLIKE3*/ static void i_mdi_log(int level, dev_info_t *dip, const char *fmt, ...) { char name[MAXNAMELEN]; char buf[MAXNAMELEN]; char *bp; va_list ap; int log_only = 0; int boot_only = 0; int console_only = 0; if (dip) { (void) snprintf(name, MAXNAMELEN, "%s%d: ", ddi_node_name(dip), ddi_get_instance(dip)); } else { name[0] = 0; } va_start(ap, fmt); (void) vsnprintf(buf, MAXNAMELEN, fmt, ap); va_end(ap); switch (buf[0]) { case '!': bp = &buf[1]; log_only = 1; break; case '?': bp = &buf[1]; boot_only = 1; break; case '^': bp = &buf[1]; console_only = 1; break; default: bp = buf; break; } if (mdi_debug_logonly) { log_only = 1; boot_only = 0; console_only = 0; } switch (level) { case CE_NOTE: level = CE_CONT; /* FALLTHROUGH */ case CE_CONT: case CE_WARN: case CE_PANIC: if (boot_only) { cmn_err(level, "?mdi: %s%s", name, bp); } else if (console_only) { cmn_err(level, "^mdi: %s%s", name, bp); } else if (log_only) { cmn_err(level, "!mdi: %s%s", name, bp); } else { cmn_err(level, "mdi: %s%s", name, bp); } break; default: cmn_err(level, "mdi: %s%s", name, bp); break; } } #endif /* DEBUG */ void i_mdi_client_online(dev_info_t *ct_dip) { mdi_client_t *ct; /* * Client online notification. Mark client state as online * restore our binding with dev_info node */ ct = i_devi_get_client(ct_dip); ASSERT(ct != NULL); MDI_CLIENT_LOCK(ct); MDI_CLIENT_SET_ONLINE(ct); /* catch for any memory leaks */ ASSERT((ct->ct_dip == NULL) || (ct->ct_dip == ct_dip)); ct->ct_dip = ct_dip; if (ct->ct_power_cnt == 0) (void) i_mdi_power_all_phci(ct); MDI_DEBUG(4, (CE_NOTE, ct_dip, "i_mdi_client_online " "i_mdi_pm_hold_client %p\n", (void *)ct)); i_mdi_pm_hold_client(ct, 1); MDI_CLIENT_UNLOCK(ct); } void i_mdi_phci_online(dev_info_t *ph_dip) { mdi_phci_t *ph; /* pHCI online notification. Mark state accordingly */ ph = i_devi_get_phci(ph_dip); ASSERT(ph != NULL); MDI_PHCI_LOCK(ph); MDI_PHCI_SET_ONLINE(ph); MDI_PHCI_UNLOCK(ph); } /* * mdi_devi_online(): * Online notification from NDI framework on pHCI/client * device online. * Return Values: * NDI_SUCCESS * MDI_FAILURE */ /*ARGSUSED*/ int mdi_devi_online(dev_info_t *dip, uint_t flags) { if (MDI_PHCI(dip)) { i_mdi_phci_online(dip); } if (MDI_CLIENT(dip)) { i_mdi_client_online(dip); } return (NDI_SUCCESS); } /* * mdi_devi_offline(): * Offline notification from NDI framework on pHCI/Client device * offline. * * Return Values: * NDI_SUCCESS * NDI_FAILURE */ /*ARGSUSED*/ int mdi_devi_offline(dev_info_t *dip, uint_t flags) { int rv = NDI_SUCCESS; if (MDI_CLIENT(dip)) { rv = i_mdi_client_offline(dip, flags); if (rv != NDI_SUCCESS) return (rv); } if (MDI_PHCI(dip)) { rv = i_mdi_phci_offline(dip, flags); if ((rv != NDI_SUCCESS) && MDI_CLIENT(dip)) { /* set client back online */ i_mdi_client_online(dip); } } return (rv); } /*ARGSUSED*/ static int i_mdi_phci_offline(dev_info_t *dip, uint_t flags) { int rv = NDI_SUCCESS; mdi_phci_t *ph; mdi_client_t *ct; mdi_pathinfo_t *pip; mdi_pathinfo_t *next; mdi_pathinfo_t *failed_pip = NULL; dev_info_t *cdip; /* * pHCI component offline notification * Make sure that this pHCI instance is free to be offlined. * If it is OK to proceed, Offline and remove all the child * mdi_pathinfo nodes. This process automatically offlines * corresponding client devices, for which this pHCI provides * critical services. */ ph = i_devi_get_phci(dip); MDI_DEBUG(2, (CE_NOTE, dip, "!mdi_phci_offline called %p %p\n", (void *)dip, (void *)ph)); if (ph == NULL) { return (rv); } MDI_PHCI_LOCK(ph); if (MDI_PHCI_IS_OFFLINE(ph)) { MDI_DEBUG(1, (CE_WARN, dip, "!pHCI %p already offlined", (void *)ph)); MDI_PHCI_UNLOCK(ph); return (NDI_SUCCESS); } /* * Check to see if the pHCI can be offlined */ if (ph->ph_unstable) { MDI_DEBUG(1, (CE_WARN, dip, "!One or more target devices are in transient " "state. This device can not be removed at " "this moment. Please try again later.")); MDI_PHCI_UNLOCK(ph); return (NDI_BUSY); } pip = ph->ph_path_head; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; /* * The mdi_pathinfo state is OK. Check the client state. * If failover in progress fail the pHCI from offlining */ ct = MDI_PI(pip)->pi_client; i_mdi_client_lock(ct, pip); if ((MDI_CLIENT_IS_FAILOVER_IN_PROGRESS(ct)) || (ct->ct_unstable)) { /* * Failover is in progress, Fail the DR */ MDI_DEBUG(1, (CE_WARN, dip, "!pHCI device (%s%d) is Busy. %s", ddi_driver_name(dip), ddi_get_instance(dip), "This device can not be removed at " "this moment. Please try again later.")); MDI_PI_UNLOCK(pip); i_mdi_client_unlock(ct); MDI_PHCI_UNLOCK(ph); return (NDI_BUSY); } MDI_PI_UNLOCK(pip); /* * Check to see of we are removing the last path of this * client device... */ cdip = ct->ct_dip; if (cdip && (i_ddi_node_state(cdip) >= DS_INITIALIZED) && (i_mdi_client_compute_state(ct, ph) == MDI_CLIENT_STATE_FAILED)) { i_mdi_client_unlock(ct); MDI_PHCI_UNLOCK(ph); if (ndi_devi_offline(cdip, 0) != NDI_SUCCESS) { /* * ndi_devi_offline() failed. * This pHCI provides the critical path * to one or more client devices. * Return busy. */ MDI_PHCI_LOCK(ph); MDI_DEBUG(1, (CE_WARN, dip, "!pHCI device (%s%d) is Busy. %s", ddi_driver_name(dip), ddi_get_instance(dip), "This device can not be removed at " "this moment. Please try again later.")); failed_pip = pip; break; } else { MDI_PHCI_LOCK(ph); pip = next; } } else { i_mdi_client_unlock(ct); pip = next; } } if (failed_pip) { pip = ph->ph_path_head; while (pip != failed_pip) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; ct = MDI_PI(pip)->pi_client; i_mdi_client_lock(ct, pip); cdip = ct->ct_dip; switch (MDI_CLIENT_STATE(ct)) { case MDI_CLIENT_STATE_OPTIMAL: case MDI_CLIENT_STATE_DEGRADED: if (cdip) { MDI_PI_UNLOCK(pip); i_mdi_client_unlock(ct); MDI_PHCI_UNLOCK(ph); (void) ndi_devi_online(cdip, 0); MDI_PHCI_LOCK(ph); pip = next; continue; } break; case MDI_CLIENT_STATE_FAILED: if (cdip) { MDI_PI_UNLOCK(pip); i_mdi_client_unlock(ct); MDI_PHCI_UNLOCK(ph); (void) ndi_devi_offline(cdip, 0); MDI_PHCI_LOCK(ph); pip = next; continue; } break; } MDI_PI_UNLOCK(pip); i_mdi_client_unlock(ct); pip = next; } MDI_PHCI_UNLOCK(ph); return (NDI_BUSY); } /* * Mark the pHCI as offline */ MDI_PHCI_SET_OFFLINE(ph); /* * Mark the child mdi_pathinfo nodes as transient */ pip = ph->ph_path_head; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; MDI_PI_SET_OFFLINING(pip); MDI_PI_UNLOCK(pip); pip = next; } MDI_PHCI_UNLOCK(ph); /* * Give a chance for any pending commands to execute */ delay(1); MDI_PHCI_LOCK(ph); pip = ph->ph_path_head; while (pip != NULL) { next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; (void) i_mdi_pi_offline(pip, flags); MDI_PI_LOCK(pip); ct = MDI_PI(pip)->pi_client; if (!MDI_PI_IS_OFFLINE(pip)) { MDI_DEBUG(1, (CE_WARN, dip, "!pHCI device (%s%d) is Busy. %s", ddi_driver_name(dip), ddi_get_instance(dip), "This device can not be removed at " "this moment. Please try again later.")); MDI_PI_UNLOCK(pip); MDI_PHCI_SET_ONLINE(ph); MDI_PHCI_UNLOCK(ph); return (NDI_BUSY); } MDI_PI_UNLOCK(pip); pip = next; } MDI_PHCI_UNLOCK(ph); return (rv); } void mdi_phci_mark_retiring(dev_info_t *dip, char **cons_array) { mdi_phci_t *ph; mdi_client_t *ct; mdi_pathinfo_t *pip; mdi_pathinfo_t *next; dev_info_t *cdip; if (!MDI_PHCI(dip)) return; ph = i_devi_get_phci(dip); if (ph == NULL) { return; } MDI_PHCI_LOCK(ph); if (MDI_PHCI_IS_OFFLINE(ph)) { /* has no last path */ MDI_PHCI_UNLOCK(ph); return; } pip = ph->ph_path_head; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; ct = MDI_PI(pip)->pi_client; i_mdi_client_lock(ct, pip); MDI_PI_UNLOCK(pip); cdip = ct->ct_dip; if (cdip && (i_ddi_node_state(cdip) >= DS_INITIALIZED) && (i_mdi_client_compute_state(ct, ph) == MDI_CLIENT_STATE_FAILED)) { /* Last path. Mark client dip as retiring */ i_mdi_client_unlock(ct); MDI_PHCI_UNLOCK(ph); (void) e_ddi_mark_retiring(cdip, cons_array); MDI_PHCI_LOCK(ph); pip = next; } else { i_mdi_client_unlock(ct); pip = next; } } MDI_PHCI_UNLOCK(ph); return; } void mdi_phci_retire_notify(dev_info_t *dip, int *constraint) { mdi_phci_t *ph; mdi_client_t *ct; mdi_pathinfo_t *pip; mdi_pathinfo_t *next; dev_info_t *cdip; if (!MDI_PHCI(dip)) return; ph = i_devi_get_phci(dip); if (ph == NULL) return; MDI_PHCI_LOCK(ph); if (MDI_PHCI_IS_OFFLINE(ph)) { MDI_PHCI_UNLOCK(ph); /* not last path */ return; } if (ph->ph_unstable) { MDI_PHCI_UNLOCK(ph); /* can't check for constraints */ *constraint = 0; return; } pip = ph->ph_path_head; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; /* * The mdi_pathinfo state is OK. Check the client state. * If failover in progress fail the pHCI from offlining */ ct = MDI_PI(pip)->pi_client; i_mdi_client_lock(ct, pip); if ((MDI_CLIENT_IS_FAILOVER_IN_PROGRESS(ct)) || (ct->ct_unstable)) { /* * Failover is in progress, can't check for constraints */ MDI_PI_UNLOCK(pip); i_mdi_client_unlock(ct); MDI_PHCI_UNLOCK(ph); *constraint = 0; return; } MDI_PI_UNLOCK(pip); /* * Check to see of we are retiring the last path of this * client device... */ cdip = ct->ct_dip; if (cdip && (i_ddi_node_state(cdip) >= DS_INITIALIZED) && (i_mdi_client_compute_state(ct, ph) == MDI_CLIENT_STATE_FAILED)) { i_mdi_client_unlock(ct); MDI_PHCI_UNLOCK(ph); (void) e_ddi_retire_notify(cdip, constraint); MDI_PHCI_LOCK(ph); pip = next; } else { i_mdi_client_unlock(ct); pip = next; } } MDI_PHCI_UNLOCK(ph); return; } /* * offline the path(s) hanging off the PHCI. If the * last path to any client, check that constraints * have been applied. */ void mdi_phci_retire_finalize(dev_info_t *dip, int phci_only) { mdi_phci_t *ph; mdi_client_t *ct; mdi_pathinfo_t *pip; mdi_pathinfo_t *next; dev_info_t *cdip; int unstable = 0; int constraint; if (!MDI_PHCI(dip)) return; ph = i_devi_get_phci(dip); if (ph == NULL) { /* no last path and no pips */ return; } MDI_PHCI_LOCK(ph); if (MDI_PHCI_IS_OFFLINE(ph)) { MDI_PHCI_UNLOCK(ph); /* no last path and no pips */ return; } /* * Check to see if the pHCI can be offlined */ if (ph->ph_unstable) { unstable = 1; } pip = ph->ph_path_head; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; /* * if failover in progress fail the pHCI from offlining */ ct = MDI_PI(pip)->pi_client; i_mdi_client_lock(ct, pip); if ((MDI_CLIENT_IS_FAILOVER_IN_PROGRESS(ct)) || (ct->ct_unstable)) { unstable = 1; } MDI_PI_UNLOCK(pip); /* * Check to see of we are removing the last path of this * client device... */ cdip = ct->ct_dip; if (!phci_only && cdip && (i_ddi_node_state(cdip) >= DS_INITIALIZED) && (i_mdi_client_compute_state(ct, ph) == MDI_CLIENT_STATE_FAILED)) { i_mdi_client_unlock(ct); MDI_PHCI_UNLOCK(ph); /* * We don't retire clients we just retire the * path to a client. If it is the last path * to a client, constraints are checked and * if we pass the last path is offlined. MPXIO will * then fail all I/Os to the client. Since we don't * want to retire the client on a path error * set constraint = 0 so that the client dip * is not retired. */ constraint = 0; (void) e_ddi_retire_finalize(cdip, &constraint); MDI_PHCI_LOCK(ph); pip = next; } else { i_mdi_client_unlock(ct); pip = next; } } /* * Cannot offline pip(s) */ if (unstable) { cmn_err(CE_WARN, "PHCI in transient state, cannot " "retire, dip = %p", (void *)dip); MDI_PHCI_UNLOCK(ph); return; } /* * Mark the pHCI as offline */ MDI_PHCI_SET_OFFLINE(ph); /* * Mark the child mdi_pathinfo nodes as transient */ pip = ph->ph_path_head; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; MDI_PI_SET_OFFLINING(pip); MDI_PI_UNLOCK(pip); pip = next; } MDI_PHCI_UNLOCK(ph); /* * Give a chance for any pending commands to execute */ delay(1); MDI_PHCI_LOCK(ph); pip = ph->ph_path_head; while (pip != NULL) { next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; (void) i_mdi_pi_offline(pip, 0); MDI_PI_LOCK(pip); ct = MDI_PI(pip)->pi_client; if (!MDI_PI_IS_OFFLINE(pip)) { cmn_err(CE_WARN, "PHCI busy, cannot offline path: " "PHCI dip = %p", (void *)dip); MDI_PI_UNLOCK(pip); MDI_PHCI_SET_ONLINE(ph); MDI_PHCI_UNLOCK(ph); return; } MDI_PI_UNLOCK(pip); pip = next; } MDI_PHCI_UNLOCK(ph); return; } void mdi_phci_unretire(dev_info_t *dip) { ASSERT(MDI_PHCI(dip)); /* * Online the phci */ i_mdi_phci_online(dip); } /*ARGSUSED*/ static int i_mdi_client_offline(dev_info_t *dip, uint_t flags) { int rv = NDI_SUCCESS; mdi_client_t *ct; /* * Client component to go offline. Make sure that we are * not in failing over state and update client state * accordingly */ ct = i_devi_get_client(dip); MDI_DEBUG(2, (CE_NOTE, dip, "!i_mdi_client_offline called %p %p\n", (void *)dip, (void *)ct)); if (ct != NULL) { MDI_CLIENT_LOCK(ct); if (ct->ct_unstable) { /* * One or more paths are in transient state, * Dont allow offline of a client device */ MDI_DEBUG(1, (CE_WARN, dip, "!One or more paths to this device is " "in transient state. This device can not " "be removed at this moment. " "Please try again later.")); MDI_CLIENT_UNLOCK(ct); return (NDI_BUSY); } if (MDI_CLIENT_IS_FAILOVER_IN_PROGRESS(ct)) { /* * Failover is in progress, Dont allow DR of * a client device */ MDI_DEBUG(1, (CE_WARN, dip, "!Client device (%s%d) is Busy. %s", ddi_driver_name(dip), ddi_get_instance(dip), "This device can not be removed at " "this moment. Please try again later.")); MDI_CLIENT_UNLOCK(ct); return (NDI_BUSY); } MDI_CLIENT_SET_OFFLINE(ct); /* * Unbind our relationship with the dev_info node */ if (flags & NDI_DEVI_REMOVE) { ct->ct_dip = NULL; } MDI_CLIENT_UNLOCK(ct); } return (rv); } /* * mdi_pre_attach(): * Pre attach() notification handler */ /*ARGSUSED*/ int mdi_pre_attach(dev_info_t *dip, ddi_attach_cmd_t cmd) { /* don't support old DDI_PM_RESUME */ if ((DEVI(dip)->devi_mdi_component != MDI_COMPONENT_NONE) && (cmd == DDI_PM_RESUME)) return (DDI_FAILURE); return (DDI_SUCCESS); } /* * mdi_post_attach(): * Post attach() notification handler */ /*ARGSUSED*/ void mdi_post_attach(dev_info_t *dip, ddi_attach_cmd_t cmd, int error) { mdi_phci_t *ph; mdi_client_t *ct; mdi_vhci_t *vh; if (MDI_PHCI(dip)) { ph = i_devi_get_phci(dip); ASSERT(ph != NULL); MDI_PHCI_LOCK(ph); switch (cmd) { case DDI_ATTACH: MDI_DEBUG(2, (CE_NOTE, dip, "!pHCI post_attach: called %p\n", (void *)ph)); if (error == DDI_SUCCESS) { MDI_PHCI_SET_ATTACH(ph); } else { MDI_DEBUG(1, (CE_NOTE, dip, "!pHCI post_attach: failed error=%d\n", error)); MDI_PHCI_SET_DETACH(ph); } break; case DDI_RESUME: MDI_DEBUG(2, (CE_NOTE, dip, "!pHCI post_resume: called %p\n", (void *)ph)); if (error == DDI_SUCCESS) { MDI_PHCI_SET_RESUME(ph); } else { MDI_DEBUG(1, (CE_NOTE, dip, "!pHCI post_resume: failed error=%d\n", error)); MDI_PHCI_SET_SUSPEND(ph); } break; } MDI_PHCI_UNLOCK(ph); } if (MDI_CLIENT(dip)) { ct = i_devi_get_client(dip); ASSERT(ct != NULL); MDI_CLIENT_LOCK(ct); switch (cmd) { case DDI_ATTACH: MDI_DEBUG(2, (CE_NOTE, dip, "!Client post_attach: called %p\n", (void *)ct)); if (error != DDI_SUCCESS) { MDI_DEBUG(1, (CE_NOTE, dip, "!Client post_attach: failed error=%d\n", error)); MDI_CLIENT_SET_DETACH(ct); MDI_DEBUG(4, (CE_WARN, dip, "mdi_post_attach i_mdi_pm_reset_client\n")); i_mdi_pm_reset_client(ct); break; } /* * Client device has successfully attached, inform * the vhci. */ vh = ct->ct_vhci; if (vh->vh_ops->vo_client_attached) (*vh->vh_ops->vo_client_attached)(dip); MDI_CLIENT_SET_ATTACH(ct); break; case DDI_RESUME: MDI_DEBUG(2, (CE_NOTE, dip, "!Client post_attach: called %p\n", (void *)ct)); if (error == DDI_SUCCESS) { MDI_CLIENT_SET_RESUME(ct); } else { MDI_DEBUG(1, (CE_NOTE, dip, "!Client post_resume: failed error=%d\n", error)); MDI_CLIENT_SET_SUSPEND(ct); } break; } MDI_CLIENT_UNLOCK(ct); } } /* * mdi_pre_detach(): * Pre detach notification handler */ /*ARGSUSED*/ int mdi_pre_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { int rv = DDI_SUCCESS; if (MDI_CLIENT(dip)) { (void) i_mdi_client_pre_detach(dip, cmd); } if (MDI_PHCI(dip)) { rv = i_mdi_phci_pre_detach(dip, cmd); } return (rv); } /*ARGSUSED*/ static int i_mdi_phci_pre_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { int rv = DDI_SUCCESS; mdi_phci_t *ph; mdi_client_t *ct; mdi_pathinfo_t *pip; mdi_pathinfo_t *failed_pip = NULL; mdi_pathinfo_t *next; ph = i_devi_get_phci(dip); if (ph == NULL) { return (rv); } MDI_PHCI_LOCK(ph); switch (cmd) { case DDI_DETACH: MDI_DEBUG(2, (CE_NOTE, dip, "!pHCI pre_detach: called %p\n", (void *)ph)); if (!MDI_PHCI_IS_OFFLINE(ph)) { /* * mdi_pathinfo nodes are still attached to * this pHCI. Fail the detach for this pHCI. */ MDI_DEBUG(2, (CE_WARN, dip, "!pHCI pre_detach: " "mdi_pathinfo nodes are still attached " "%p\n", (void *)ph)); rv = DDI_FAILURE; break; } MDI_PHCI_SET_DETACH(ph); break; case DDI_SUSPEND: /* * pHCI is getting suspended. Since mpxio client * devices may not be suspended at this point, to avoid * a potential stack overflow, it is important to suspend * client devices before pHCI can be suspended. */ MDI_DEBUG(2, (CE_NOTE, dip, "!pHCI pre_suspend: called %p\n", (void *)ph)); /* * Suspend all the client devices accessible through this pHCI */ pip = ph->ph_path_head; while (pip != NULL && rv == DDI_SUCCESS) { dev_info_t *cdip; MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; ct = MDI_PI(pip)->pi_client; i_mdi_client_lock(ct, pip); cdip = ct->ct_dip; MDI_PI_UNLOCK(pip); if ((MDI_CLIENT_IS_DETACHED(ct) == 0) && MDI_CLIENT_IS_SUSPENDED(ct) == 0) { i_mdi_client_unlock(ct); if ((rv = devi_detach(cdip, DDI_SUSPEND)) != DDI_SUCCESS) { /* * Suspend of one of the client * device has failed. */ MDI_DEBUG(1, (CE_WARN, dip, "!Suspend of device (%s%d) failed.", ddi_driver_name(cdip), ddi_get_instance(cdip))); failed_pip = pip; break; } } else { i_mdi_client_unlock(ct); } pip = next; } if (rv == DDI_SUCCESS) { /* * Suspend of client devices is complete. Proceed * with pHCI suspend. */ MDI_PHCI_SET_SUSPEND(ph); } else { /* * Revert back all the suspended client device states * to converse. */ pip = ph->ph_path_head; while (pip != failed_pip) { dev_info_t *cdip; MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; ct = MDI_PI(pip)->pi_client; i_mdi_client_lock(ct, pip); cdip = ct->ct_dip; MDI_PI_UNLOCK(pip); if (MDI_CLIENT_IS_SUSPENDED(ct)) { i_mdi_client_unlock(ct); (void) devi_attach(cdip, DDI_RESUME); } else { i_mdi_client_unlock(ct); } pip = next; } } break; default: rv = DDI_FAILURE; break; } MDI_PHCI_UNLOCK(ph); return (rv); } /*ARGSUSED*/ static int i_mdi_client_pre_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { int rv = DDI_SUCCESS; mdi_client_t *ct; ct = i_devi_get_client(dip); if (ct == NULL) { return (rv); } MDI_CLIENT_LOCK(ct); switch (cmd) { case DDI_DETACH: MDI_DEBUG(2, (CE_NOTE, dip, "!Client pre_detach: called %p\n", (void *)ct)); MDI_CLIENT_SET_DETACH(ct); break; case DDI_SUSPEND: MDI_DEBUG(2, (CE_NOTE, dip, "!Client pre_suspend: called %p\n", (void *)ct)); MDI_CLIENT_SET_SUSPEND(ct); break; default: rv = DDI_FAILURE; break; } MDI_CLIENT_UNLOCK(ct); return (rv); } /* * mdi_post_detach(): * Post detach notification handler */ /*ARGSUSED*/ void mdi_post_detach(dev_info_t *dip, ddi_detach_cmd_t cmd, int error) { /* * Detach/Suspend of mpxio component failed. Update our state * too */ if (MDI_PHCI(dip)) i_mdi_phci_post_detach(dip, cmd, error); if (MDI_CLIENT(dip)) i_mdi_client_post_detach(dip, cmd, error); } /*ARGSUSED*/ static void i_mdi_phci_post_detach(dev_info_t *dip, ddi_detach_cmd_t cmd, int error) { mdi_phci_t *ph; /* * Detach/Suspend of phci component failed. Update our state * too */ ph = i_devi_get_phci(dip); if (ph == NULL) { return; } MDI_PHCI_LOCK(ph); /* * Detach of pHCI failed. Restore back converse * state */ switch (cmd) { case DDI_DETACH: MDI_DEBUG(2, (CE_NOTE, dip, "!pHCI post_detach: called %p\n", (void *)ph)); if (error != DDI_SUCCESS) MDI_PHCI_SET_ATTACH(ph); break; case DDI_SUSPEND: MDI_DEBUG(2, (CE_NOTE, dip, "!pHCI post_suspend: called %p\n", (void *)ph)); if (error != DDI_SUCCESS) MDI_PHCI_SET_RESUME(ph); break; } MDI_PHCI_UNLOCK(ph); } /*ARGSUSED*/ static void i_mdi_client_post_detach(dev_info_t *dip, ddi_detach_cmd_t cmd, int error) { mdi_client_t *ct; ct = i_devi_get_client(dip); if (ct == NULL) { return; } MDI_CLIENT_LOCK(ct); /* * Detach of Client failed. Restore back converse * state */ switch (cmd) { case DDI_DETACH: MDI_DEBUG(2, (CE_NOTE, dip, "!Client post_detach: called %p\n", (void *)ct)); if (DEVI_IS_ATTACHING(ct->ct_dip)) { MDI_DEBUG(4, (CE_NOTE, dip, "i_mdi_client_post_detach " "i_mdi_pm_rele_client\n")); i_mdi_pm_rele_client(ct, ct->ct_path_count); } else { MDI_DEBUG(4, (CE_NOTE, dip, "i_mdi_client_post_detach " "i_mdi_pm_reset_client\n")); i_mdi_pm_reset_client(ct); } if (error != DDI_SUCCESS) MDI_CLIENT_SET_ATTACH(ct); break; case DDI_SUSPEND: MDI_DEBUG(2, (CE_NOTE, dip, "!Client post_suspend: called %p\n", (void *)ct)); if (error != DDI_SUCCESS) MDI_CLIENT_SET_RESUME(ct); break; } MDI_CLIENT_UNLOCK(ct); } int mdi_pi_kstat_exists(mdi_pathinfo_t *pip) { return (MDI_PI(pip)->pi_kstats ? 1 : 0); } /* * create and install per-path (client - pHCI) statistics * I/O stats supported: nread, nwritten, reads, and writes * Error stats - hard errors, soft errors, & transport errors */ int mdi_pi_kstat_create(mdi_pathinfo_t *pip, char *ksname) { kstat_t *kiosp, *kerrsp; struct pi_errs *nsp; struct mdi_pi_kstats *mdi_statp; if (MDI_PI(pip)->pi_kstats != NULL) return (MDI_SUCCESS); if ((kiosp = kstat_create("mdi", 0, ksname, "iopath", KSTAT_TYPE_IO, 1, KSTAT_FLAG_PERSISTENT)) == NULL) { return (MDI_FAILURE); } (void) strcat(ksname, ",err"); kerrsp = kstat_create("mdi", 0, ksname, "iopath_errors", KSTAT_TYPE_NAMED, sizeof (struct pi_errs) / sizeof (kstat_named_t), 0); if (kerrsp == NULL) { kstat_delete(kiosp); return (MDI_FAILURE); } nsp = (struct pi_errs *)kerrsp->ks_data; kstat_named_init(&nsp->pi_softerrs, "Soft Errors", KSTAT_DATA_UINT32); kstat_named_init(&nsp->pi_harderrs, "Hard Errors", KSTAT_DATA_UINT32); kstat_named_init(&nsp->pi_transerrs, "Transport Errors", KSTAT_DATA_UINT32); kstat_named_init(&nsp->pi_icnt_busy, "Interconnect Busy", KSTAT_DATA_UINT32); kstat_named_init(&nsp->pi_icnt_errors, "Interconnect Errors", KSTAT_DATA_UINT32); kstat_named_init(&nsp->pi_phci_rsrc, "pHCI No Resources", KSTAT_DATA_UINT32); kstat_named_init(&nsp->pi_phci_localerr, "pHCI Local Errors", KSTAT_DATA_UINT32); kstat_named_init(&nsp->pi_phci_invstate, "pHCI Invalid State", KSTAT_DATA_UINT32); kstat_named_init(&nsp->pi_failedfrom, "Failed From", KSTAT_DATA_UINT32); kstat_named_init(&nsp->pi_failedto, "Failed To", KSTAT_DATA_UINT32); mdi_statp = kmem_alloc(sizeof (*mdi_statp), KM_SLEEP); mdi_statp->pi_kstat_ref = 1; mdi_statp->pi_kstat_iostats = kiosp; mdi_statp->pi_kstat_errstats = kerrsp; kstat_install(kiosp); kstat_install(kerrsp); MDI_PI(pip)->pi_kstats = mdi_statp; return (MDI_SUCCESS); } /* * destroy per-path properties */ static void i_mdi_pi_kstat_destroy(mdi_pathinfo_t *pip) { struct mdi_pi_kstats *mdi_statp; if (MDI_PI(pip)->pi_kstats == NULL) return; if ((mdi_statp = MDI_PI(pip)->pi_kstats) == NULL) return; MDI_PI(pip)->pi_kstats = NULL; /* * the kstat may be shared between multiple pathinfo nodes * decrement this pathinfo's usage, removing the kstats * themselves when the last pathinfo reference is removed. */ ASSERT(mdi_statp->pi_kstat_ref > 0); if (--mdi_statp->pi_kstat_ref != 0) return; kstat_delete(mdi_statp->pi_kstat_iostats); kstat_delete(mdi_statp->pi_kstat_errstats); kmem_free(mdi_statp, sizeof (*mdi_statp)); } /* * update I/O paths KSTATS */ void mdi_pi_kstat_iosupdate(mdi_pathinfo_t *pip, struct buf *bp) { kstat_t *iostatp; size_t xfer_cnt; ASSERT(pip != NULL); /* * I/O can be driven across a path prior to having path * statistics available, i.e. probe(9e). */ if (bp != NULL && MDI_PI(pip)->pi_kstats != NULL) { iostatp = MDI_PI(pip)->pi_kstats->pi_kstat_iostats; xfer_cnt = bp->b_bcount - bp->b_resid; if (bp->b_flags & B_READ) { KSTAT_IO_PTR(iostatp)->reads++; KSTAT_IO_PTR(iostatp)->nread += xfer_cnt; } else { KSTAT_IO_PTR(iostatp)->writes++; KSTAT_IO_PTR(iostatp)->nwritten += xfer_cnt; } } } /* * Enable the path(specific client/target/initiator) * Enabling a path means that MPxIO may select the enabled path for routing * future I/O requests, subject to other path state constraints. */ int mdi_pi_enable_path(mdi_pathinfo_t *pip, int flags) { mdi_phci_t *ph; ph = i_devi_get_phci(mdi_pi_get_phci(pip)); if (ph == NULL) { MDI_DEBUG(1, (CE_NOTE, NULL, "!mdi_pi_enable_path:" " failed. pip: %p ph = NULL\n", (void *)pip)); return (MDI_FAILURE); } (void) i_mdi_enable_disable_path(pip, ph->ph_vhci, flags, MDI_ENABLE_OP); MDI_DEBUG(5, (CE_NOTE, NULL, "!mdi_pi_enable_path:" " Returning success pip = %p. ph = %p\n", (void *)pip, (void *)ph)); return (MDI_SUCCESS); } /* * Disable the path (specific client/target/initiator) * Disabling a path means that MPxIO will not select the disabled path for * routing any new I/O requests. */ int mdi_pi_disable_path(mdi_pathinfo_t *pip, int flags) { mdi_phci_t *ph; ph = i_devi_get_phci(mdi_pi_get_phci(pip)); if (ph == NULL) { MDI_DEBUG(1, (CE_NOTE, NULL, "!mdi_pi_disable_path:" " failed. pip: %p ph = NULL\n", (void *)pip)); return (MDI_FAILURE); } (void) i_mdi_enable_disable_path(pip, ph->ph_vhci, flags, MDI_DISABLE_OP); MDI_DEBUG(5, (CE_NOTE, NULL, "!mdi_pi_disable_path:" "Returning success pip = %p. ph = %p", (void *)pip, (void *)ph)); return (MDI_SUCCESS); } /* * disable the path to a particular pHCI (pHCI specified in the phci_path * argument) for a particular client (specified in the client_path argument). * Disabling a path means that MPxIO will not select the disabled path for * routing any new I/O requests. * NOTE: this will be removed once the NWS files are changed to use the new * mdi_{enable,disable}_path interfaces */ int mdi_pi_disable(dev_info_t *cdip, dev_info_t *pdip, int flags) { return (i_mdi_pi_enable_disable(cdip, pdip, flags, MDI_DISABLE_OP)); } /* * Enable the path to a particular pHCI (pHCI specified in the phci_path * argument) for a particular client (specified in the client_path argument). * Enabling a path means that MPxIO may select the enabled path for routing * future I/O requests, subject to other path state constraints. * NOTE: this will be removed once the NWS files are changed to use the new * mdi_{enable,disable}_path interfaces */ int mdi_pi_enable(dev_info_t *cdip, dev_info_t *pdip, int flags) { return (i_mdi_pi_enable_disable(cdip, pdip, flags, MDI_ENABLE_OP)); } /* * Common routine for doing enable/disable. */ static mdi_pathinfo_t * i_mdi_enable_disable_path(mdi_pathinfo_t *pip, mdi_vhci_t *vh, int flags, int op) { int sync_flag = 0; int rv; mdi_pathinfo_t *next; int (*f)() = NULL; f = vh->vh_ops->vo_pi_state_change; sync_flag = (flags << 8) & 0xf00; /* * Do a callback into the mdi consumer to let it * know that path is about to get enabled/disabled. */ if (f != NULL) { rv = (*f)(vh->vh_dip, pip, 0, MDI_PI_EXT_STATE(pip), MDI_EXT_STATE_CHANGE | sync_flag | op | MDI_BEFORE_STATE_CHANGE); if (rv != MDI_SUCCESS) { MDI_DEBUG(2, (CE_WARN, vh->vh_dip, "!vo_pi_state_change: failed rv = %x", rv)); } } MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_phci_link; switch (flags) { case USER_DISABLE: if (op == MDI_DISABLE_OP) { MDI_PI_SET_USER_DISABLE(pip); } else { MDI_PI_SET_USER_ENABLE(pip); } break; case DRIVER_DISABLE: if (op == MDI_DISABLE_OP) { MDI_PI_SET_DRV_DISABLE(pip); } else { MDI_PI_SET_DRV_ENABLE(pip); } break; case DRIVER_DISABLE_TRANSIENT: if (op == MDI_DISABLE_OP && rv == MDI_SUCCESS) { MDI_PI_SET_DRV_DISABLE_TRANS(pip); } else { MDI_PI_SET_DRV_ENABLE_TRANS(pip); } break; } MDI_PI_UNLOCK(pip); /* * Do a callback into the mdi consumer to let it * know that path is now enabled/disabled. */ if (f != NULL) { rv = (*f)(vh->vh_dip, pip, 0, MDI_PI_EXT_STATE(pip), MDI_EXT_STATE_CHANGE | sync_flag | op | MDI_AFTER_STATE_CHANGE); if (rv != MDI_SUCCESS) { MDI_DEBUG(2, (CE_WARN, vh->vh_dip, "!vo_pi_state_change: failed rv = %x", rv)); } } return (next); } /* * Common routine for doing enable/disable. * NOTE: this will be removed once the NWS files are changed to use the new * mdi_{enable,disable}_path has been putback */ int i_mdi_pi_enable_disable(dev_info_t *cdip, dev_info_t *pdip, int flags, int op) { mdi_phci_t *ph; mdi_vhci_t *vh = NULL; mdi_client_t *ct; mdi_pathinfo_t *next, *pip; int found_it; ph = i_devi_get_phci(pdip); MDI_DEBUG(5, (CE_NOTE, NULL, "!i_mdi_pi_enable_disable: " "Op = %d pdip = %p cdip = %p\n", op, (void *)pdip, (void *)cdip)); if (ph == NULL) { MDI_DEBUG(1, (CE_NOTE, NULL, "!i_mdi_pi_enable_disable:" "Op %d failed. ph = NULL\n", op)); return (MDI_FAILURE); } if ((op != MDI_ENABLE_OP) && (op != MDI_DISABLE_OP)) { MDI_DEBUG(1, (CE_NOTE, NULL, "!i_mdi_pi_enable_disable: " "Op Invalid operation = %d\n", op)); return (MDI_FAILURE); } vh = ph->ph_vhci; if (cdip == NULL) { /* * Need to mark the Phci as enabled/disabled. */ MDI_DEBUG(3, (CE_NOTE, NULL, "!i_mdi_pi_enable_disable: " "Op %d for the phci\n", op)); MDI_PHCI_LOCK(ph); switch (flags) { case USER_DISABLE: if (op == MDI_DISABLE_OP) { MDI_PHCI_SET_USER_DISABLE(ph); } else { MDI_PHCI_SET_USER_ENABLE(ph); } break; case DRIVER_DISABLE: if (op == MDI_DISABLE_OP) { MDI_PHCI_SET_DRV_DISABLE(ph); } else { MDI_PHCI_SET_DRV_ENABLE(ph); } break; case DRIVER_DISABLE_TRANSIENT: if (op == MDI_DISABLE_OP) { MDI_PHCI_SET_DRV_DISABLE_TRANSIENT(ph); } else { MDI_PHCI_SET_DRV_ENABLE_TRANSIENT(ph); } break; default: MDI_PHCI_UNLOCK(ph); MDI_DEBUG(1, (CE_NOTE, NULL, "!i_mdi_pi_enable_disable:" " Invalid flag argument= %d\n", flags)); } /* * Phci has been disabled. Now try to enable/disable * path info's to each client. */ pip = ph->ph_path_head; while (pip != NULL) { pip = i_mdi_enable_disable_path(pip, vh, flags, op); } MDI_PHCI_UNLOCK(ph); } else { /* * Disable a specific client. */ ct = i_devi_get_client(cdip); if (ct == NULL) { MDI_DEBUG(1, (CE_NOTE, NULL, "!i_mdi_pi_enable_disable:" " failed. ct = NULL operation = %d\n", op)); return (MDI_FAILURE); } MDI_CLIENT_LOCK(ct); pip = ct->ct_path_head; found_it = 0; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; if (MDI_PI(pip)->pi_phci == ph) { MDI_PI_UNLOCK(pip); found_it = 1; break; } MDI_PI_UNLOCK(pip); pip = next; } MDI_CLIENT_UNLOCK(ct); if (found_it == 0) { MDI_DEBUG(1, (CE_NOTE, NULL, "!i_mdi_pi_enable_disable:" " failed. Could not find corresponding pip\n")); return (MDI_FAILURE); } (void) i_mdi_enable_disable_path(pip, vh, flags, op); } MDI_DEBUG(5, (CE_NOTE, NULL, "!i_mdi_pi_enable_disable: " "Op %d Returning success pdip = %p cdip = %p\n", op, (void *)pdip, (void *)cdip)); return (MDI_SUCCESS); } /* * Ensure phci powered up */ static void i_mdi_pm_hold_pip(mdi_pathinfo_t *pip) { dev_info_t *ph_dip; ASSERT(pip != NULL); ASSERT(MDI_PI_LOCKED(pip)); if (MDI_PI(pip)->pi_pm_held) { return; } ph_dip = mdi_pi_get_phci(pip); MDI_DEBUG(4, (CE_NOTE, ph_dip, "i_mdi_pm_hold_pip for %s%d %p\n", ddi_get_name(ph_dip), ddi_get_instance(ph_dip), (void *)pip)); if (ph_dip == NULL) { return; } MDI_PI_UNLOCK(pip); MDI_DEBUG(4, (CE_NOTE, ph_dip, "kidsupcnt was %d\n", DEVI(ph_dip)->devi_pm_kidsupcnt)); pm_hold_power(ph_dip); MDI_DEBUG(4, (CE_NOTE, ph_dip, "kidsupcnt is %d\n", DEVI(ph_dip)->devi_pm_kidsupcnt)); MDI_PI_LOCK(pip); /* If PM_GET_PM_INFO is NULL the pm_hold_power above was a noop */ if (DEVI(ph_dip)->devi_pm_info) MDI_PI(pip)->pi_pm_held = 1; } /* * Allow phci powered down */ static void i_mdi_pm_rele_pip(mdi_pathinfo_t *pip) { dev_info_t *ph_dip = NULL; ASSERT(pip != NULL); ASSERT(MDI_PI_LOCKED(pip)); if (MDI_PI(pip)->pi_pm_held == 0) { return; } ph_dip = mdi_pi_get_phci(pip); ASSERT(ph_dip != NULL); MDI_PI_UNLOCK(pip); MDI_DEBUG(4, (CE_NOTE, ph_dip, "i_mdi_pm_rele_pip for %s%d %p\n", ddi_get_name(ph_dip), ddi_get_instance(ph_dip), (void *)pip)); MDI_DEBUG(4, (CE_NOTE, ph_dip, "kidsupcnt was %d\n", DEVI(ph_dip)->devi_pm_kidsupcnt)); pm_rele_power(ph_dip); MDI_DEBUG(4, (CE_NOTE, ph_dip, "kidsupcnt is %d\n", DEVI(ph_dip)->devi_pm_kidsupcnt)); MDI_PI_LOCK(pip); MDI_PI(pip)->pi_pm_held = 0; } static void i_mdi_pm_hold_client(mdi_client_t *ct, int incr) { ASSERT(MDI_CLIENT_LOCKED(ct)); ct->ct_power_cnt += incr; MDI_DEBUG(4, (CE_NOTE, ct->ct_dip, "i_mdi_pm_hold_client %p " "ct_power_cnt = %d incr = %d\n", (void *)ct, ct->ct_power_cnt, incr)); ASSERT(ct->ct_power_cnt >= 0); } static void i_mdi_rele_all_phci(mdi_client_t *ct) { mdi_pathinfo_t *pip; ASSERT(MDI_CLIENT_LOCKED(ct)); pip = (mdi_pathinfo_t *)ct->ct_path_head; while (pip != NULL) { mdi_hold_path(pip); MDI_PI_LOCK(pip); i_mdi_pm_rele_pip(pip); MDI_PI_UNLOCK(pip); mdi_rele_path(pip); pip = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; } } static void i_mdi_pm_rele_client(mdi_client_t *ct, int decr) { ASSERT(MDI_CLIENT_LOCKED(ct)); if (i_ddi_devi_attached(ct->ct_dip)) { ct->ct_power_cnt -= decr; MDI_DEBUG(4, (CE_NOTE, ct->ct_dip, "i_mdi_pm_rele_client %p " "ct_power_cnt = %d decr = %d\n", (void *)ct, ct->ct_power_cnt, decr)); } ASSERT(ct->ct_power_cnt >= 0); if (ct->ct_power_cnt == 0) { i_mdi_rele_all_phci(ct); return; } } static void i_mdi_pm_reset_client(mdi_client_t *ct) { MDI_DEBUG(4, (CE_NOTE, ct->ct_dip, "i_mdi_pm_reset_client %p " "ct_power_cnt = %d\n", (void *)ct, ct->ct_power_cnt)); ASSERT(MDI_CLIENT_LOCKED(ct)); ct->ct_power_cnt = 0; i_mdi_rele_all_phci(ct); ct->ct_powercnt_config = 0; ct->ct_powercnt_unconfig = 0; ct->ct_powercnt_reset = 1; } static int i_mdi_power_one_phci(mdi_pathinfo_t *pip) { int ret; dev_info_t *ph_dip; MDI_PI_LOCK(pip); i_mdi_pm_hold_pip(pip); ph_dip = mdi_pi_get_phci(pip); MDI_PI_UNLOCK(pip); /* bring all components of phci to full power */ MDI_DEBUG(4, (CE_NOTE, ph_dip, "i_mdi_power_one_phci " "pm_powerup for %s%d %p\n", ddi_get_name(ph_dip), ddi_get_instance(ph_dip), (void *)pip)); ret = pm_powerup(ph_dip); if (ret == DDI_FAILURE) { MDI_DEBUG(4, (CE_NOTE, ph_dip, "i_mdi_power_one_phci " "pm_powerup FAILED for %s%d %p\n", ddi_get_name(ph_dip), ddi_get_instance(ph_dip), (void *)pip)); MDI_PI_LOCK(pip); i_mdi_pm_rele_pip(pip); MDI_PI_UNLOCK(pip); return (MDI_FAILURE); } return (MDI_SUCCESS); } static int i_mdi_power_all_phci(mdi_client_t *ct) { mdi_pathinfo_t *pip; int succeeded = 0; ASSERT(MDI_CLIENT_LOCKED(ct)); pip = (mdi_pathinfo_t *)ct->ct_path_head; while (pip != NULL) { /* * Don't power if MDI_PATHINFO_STATE_FAULT * or MDI_PATHINFO_STATE_OFFLINE. */ if (MDI_PI_IS_INIT(pip) || MDI_PI_IS_ONLINE(pip) || MDI_PI_IS_STANDBY(pip)) { mdi_hold_path(pip); MDI_CLIENT_UNLOCK(ct); if (i_mdi_power_one_phci(pip) == MDI_SUCCESS) succeeded = 1; ASSERT(ct == MDI_PI(pip)->pi_client); MDI_CLIENT_LOCK(ct); mdi_rele_path(pip); } pip = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; } return (succeeded ? MDI_SUCCESS : MDI_FAILURE); } /* * mdi_bus_power(): * 1. Place the phci(s) into powered up state so that * client can do power management * 2. Ensure phci powered up as client power managing * Return Values: * MDI_SUCCESS * MDI_FAILURE */ int mdi_bus_power(dev_info_t *parent, void *impl_arg, pm_bus_power_op_t op, void *arg, void *result) { int ret = MDI_SUCCESS; pm_bp_child_pwrchg_t *bpc; mdi_client_t *ct; dev_info_t *cdip; pm_bp_has_changed_t *bphc; /* * BUS_POWER_NOINVOL not supported */ if (op == BUS_POWER_NOINVOL) return (MDI_FAILURE); /* * ignore other OPs. * return quickly to save cou cycles on the ct processing */ switch (op) { case BUS_POWER_PRE_NOTIFICATION: case BUS_POWER_POST_NOTIFICATION: bpc = (pm_bp_child_pwrchg_t *)arg; cdip = bpc->bpc_dip; break; case BUS_POWER_HAS_CHANGED: bphc = (pm_bp_has_changed_t *)arg; cdip = bphc->bphc_dip; break; default: return (pm_busop_bus_power(parent, impl_arg, op, arg, result)); } ASSERT(MDI_CLIENT(cdip)); ct = i_devi_get_client(cdip); if (ct == NULL) return (MDI_FAILURE); /* * wait till the mdi_pathinfo node state change are processed */ MDI_CLIENT_LOCK(ct); switch (op) { case BUS_POWER_PRE_NOTIFICATION: MDI_DEBUG(4, (CE_NOTE, bpc->bpc_dip, "mdi_bus_power " "BUS_POWER_PRE_NOTIFICATION:" "%s@%s, olevel=%d, nlevel=%d, comp=%d\n", PM_NAME(bpc->bpc_dip), PM_ADDR(bpc->bpc_dip), bpc->bpc_olevel, bpc->bpc_nlevel, bpc->bpc_comp)); /* serialize power level change per client */ while (MDI_CLIENT_IS_POWER_TRANSITION(ct)) cv_wait(&ct->ct_powerchange_cv, &ct->ct_mutex); MDI_CLIENT_SET_POWER_TRANSITION(ct); if (ct->ct_power_cnt == 0) { ret = i_mdi_power_all_phci(ct); } /* * if new_level > 0: * - hold phci(s) * - power up phci(s) if not already * ignore power down */ if (bpc->bpc_nlevel > 0) { if (!DEVI_IS_ATTACHING(ct->ct_dip)) { MDI_DEBUG(4, (CE_NOTE, bpc->bpc_dip, "mdi_bus_power i_mdi_pm_hold_client\n")); i_mdi_pm_hold_client(ct, ct->ct_path_count); } } break; case BUS_POWER_POST_NOTIFICATION: MDI_DEBUG(4, (CE_NOTE, bpc->bpc_dip, "mdi_bus_power " "BUS_POWER_POST_NOTIFICATION:" "%s@%s, olevel=%d, nlevel=%d, comp=%d result=%d\n", PM_NAME(bpc->bpc_dip), PM_ADDR(bpc->bpc_dip), bpc->bpc_olevel, bpc->bpc_nlevel, bpc->bpc_comp, *(int *)result)); if (*(int *)result == DDI_SUCCESS) { if (bpc->bpc_nlevel > 0) { MDI_CLIENT_SET_POWER_UP(ct); } else { MDI_CLIENT_SET_POWER_DOWN(ct); } } /* release the hold we did in pre-notification */ if (bpc->bpc_nlevel > 0 && (*(int *)result != DDI_SUCCESS) && !DEVI_IS_ATTACHING(ct->ct_dip)) { MDI_DEBUG(4, (CE_NOTE, bpc->bpc_dip, "mdi_bus_power i_mdi_pm_rele_client\n")); i_mdi_pm_rele_client(ct, ct->ct_path_count); } if (bpc->bpc_nlevel == 0 && (*(int *)result == DDI_SUCCESS)) { /* another thread might started attaching */ if (DEVI_IS_ATTACHING(ct->ct_dip)) { MDI_DEBUG(4, (CE_NOTE, bpc->bpc_dip, "mdi_bus_power i_mdi_pm_rele_client\n")); i_mdi_pm_rele_client(ct, ct->ct_path_count); /* detaching has been taken care in pm_post_unconfig */ } else if (!DEVI_IS_DETACHING(ct->ct_dip)) { MDI_DEBUG(4, (CE_NOTE, bpc->bpc_dip, "mdi_bus_power i_mdi_pm_reset_client\n")); i_mdi_pm_reset_client(ct); } } MDI_CLIENT_CLEAR_POWER_TRANSITION(ct); cv_broadcast(&ct->ct_powerchange_cv); break; /* need to do more */ case BUS_POWER_HAS_CHANGED: MDI_DEBUG(4, (CE_NOTE, bphc->bphc_dip, "mdi_bus_power " "BUS_POWER_HAS_CHANGED:" "%s@%s, olevel=%d, nlevel=%d, comp=%d\n", PM_NAME(bphc->bphc_dip), PM_ADDR(bphc->bphc_dip), bphc->bphc_olevel, bphc->bphc_nlevel, bphc->bphc_comp)); if (bphc->bphc_nlevel > 0 && bphc->bphc_nlevel > bphc->bphc_olevel) { if (ct->ct_power_cnt == 0) { ret = i_mdi_power_all_phci(ct); } MDI_DEBUG(4, (CE_NOTE, bphc->bphc_dip, "mdi_bus_power i_mdi_pm_hold_client\n")); i_mdi_pm_hold_client(ct, ct->ct_path_count); } if (bphc->bphc_nlevel == 0 && bphc->bphc_olevel != -1) { MDI_DEBUG(4, (CE_NOTE, bphc->bphc_dip, "mdi_bus_power i_mdi_pm_rele_client\n")); i_mdi_pm_rele_client(ct, ct->ct_path_count); } break; } MDI_CLIENT_UNLOCK(ct); return (ret); } static int i_mdi_pm_pre_config_one(dev_info_t *child) { int ret = MDI_SUCCESS; mdi_client_t *ct; ct = i_devi_get_client(child); if (ct == NULL) return (MDI_FAILURE); MDI_CLIENT_LOCK(ct); while (MDI_CLIENT_IS_POWER_TRANSITION(ct)) cv_wait(&ct->ct_powerchange_cv, &ct->ct_mutex); if (!MDI_CLIENT_IS_FAILED(ct)) { MDI_CLIENT_UNLOCK(ct); MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_pre_config_one already configured\n")); return (MDI_SUCCESS); } if (ct->ct_powercnt_config) { MDI_CLIENT_UNLOCK(ct); MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_pre_config_one ALREADY held\n")); return (MDI_SUCCESS); } if (ct->ct_power_cnt == 0) { ret = i_mdi_power_all_phci(ct); } MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_pre_config_one i_mdi_pm_hold_client\n")); i_mdi_pm_hold_client(ct, ct->ct_path_count); ct->ct_powercnt_config = 1; ct->ct_powercnt_reset = 0; MDI_CLIENT_UNLOCK(ct); return (ret); } static int i_mdi_pm_pre_config(dev_info_t *vdip, dev_info_t *child) { int ret = MDI_SUCCESS; dev_info_t *cdip; int circ; ASSERT(MDI_VHCI(vdip)); /* ndi_devi_config_one */ if (child) { ASSERT(DEVI_BUSY_OWNED(vdip)); return (i_mdi_pm_pre_config_one(child)); } /* devi_config_common */ ndi_devi_enter(vdip, &circ); cdip = ddi_get_child(vdip); while (cdip) { dev_info_t *next = ddi_get_next_sibling(cdip); ret = i_mdi_pm_pre_config_one(cdip); if (ret != MDI_SUCCESS) break; cdip = next; } ndi_devi_exit(vdip, circ); return (ret); } static int i_mdi_pm_pre_unconfig_one(dev_info_t *child, int *held, int flags) { int ret = MDI_SUCCESS; mdi_client_t *ct; ct = i_devi_get_client(child); if (ct == NULL) return (MDI_FAILURE); MDI_CLIENT_LOCK(ct); while (MDI_CLIENT_IS_POWER_TRANSITION(ct)) cv_wait(&ct->ct_powerchange_cv, &ct->ct_mutex); if (!i_ddi_devi_attached(ct->ct_dip)) { MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_pre_unconfig node detached already\n")); MDI_CLIENT_UNLOCK(ct); return (MDI_SUCCESS); } if (MDI_CLIENT_IS_POWERED_DOWN(ct) && (flags & NDI_AUTODETACH)) { MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_pre_unconfig auto-modunload\n")); MDI_CLIENT_UNLOCK(ct); return (MDI_FAILURE); } if (ct->ct_powercnt_unconfig) { MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_pre_unconfig ct_powercnt_held\n")); MDI_CLIENT_UNLOCK(ct); *held = 1; return (MDI_SUCCESS); } if (ct->ct_power_cnt == 0) { ret = i_mdi_power_all_phci(ct); } MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_pre_unconfig i_mdi_pm_hold_client\n")); i_mdi_pm_hold_client(ct, ct->ct_path_count); ct->ct_powercnt_unconfig = 1; ct->ct_powercnt_reset = 0; MDI_CLIENT_UNLOCK(ct); if (ret == MDI_SUCCESS) *held = 1; return (ret); } static int i_mdi_pm_pre_unconfig(dev_info_t *vdip, dev_info_t *child, int *held, int flags) { int ret = MDI_SUCCESS; dev_info_t *cdip; int circ; ASSERT(MDI_VHCI(vdip)); *held = 0; /* ndi_devi_unconfig_one */ if (child) { ASSERT(DEVI_BUSY_OWNED(vdip)); return (i_mdi_pm_pre_unconfig_one(child, held, flags)); } /* devi_unconfig_common */ ndi_devi_enter(vdip, &circ); cdip = ddi_get_child(vdip); while (cdip) { dev_info_t *next = ddi_get_next_sibling(cdip); ret = i_mdi_pm_pre_unconfig_one(cdip, held, flags); cdip = next; } ndi_devi_exit(vdip, circ); if (*held) ret = MDI_SUCCESS; return (ret); } static void i_mdi_pm_post_config_one(dev_info_t *child) { mdi_client_t *ct; ct = i_devi_get_client(child); if (ct == NULL) return; MDI_CLIENT_LOCK(ct); while (MDI_CLIENT_IS_POWER_TRANSITION(ct)) cv_wait(&ct->ct_powerchange_cv, &ct->ct_mutex); if (ct->ct_powercnt_reset || !ct->ct_powercnt_config) { MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_post_config_one NOT configured\n")); MDI_CLIENT_UNLOCK(ct); return; } /* client has not been updated */ if (MDI_CLIENT_IS_FAILED(ct)) { MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_post_config_one NOT configured\n")); MDI_CLIENT_UNLOCK(ct); return; } /* another thread might have powered it down or detached it */ if ((MDI_CLIENT_IS_POWERED_DOWN(ct) && !DEVI_IS_ATTACHING(ct->ct_dip)) || (!i_ddi_devi_attached(ct->ct_dip) && !DEVI_IS_ATTACHING(ct->ct_dip))) { MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_post_config i_mdi_pm_reset_client\n")); i_mdi_pm_reset_client(ct); } else { mdi_pathinfo_t *pip, *next; int valid_path_count = 0; MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_post_config i_mdi_pm_rele_client\n")); pip = ct->ct_path_head; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; if (MDI_PI_IS_ONLINE(pip) || MDI_PI_IS_STANDBY(pip)) valid_path_count ++; MDI_PI_UNLOCK(pip); pip = next; } i_mdi_pm_rele_client(ct, valid_path_count); } ct->ct_powercnt_config = 0; MDI_CLIENT_UNLOCK(ct); } static void i_mdi_pm_post_config(dev_info_t *vdip, dev_info_t *child) { int circ; dev_info_t *cdip; ASSERT(MDI_VHCI(vdip)); /* ndi_devi_config_one */ if (child) { ASSERT(DEVI_BUSY_OWNED(vdip)); i_mdi_pm_post_config_one(child); return; } /* devi_config_common */ ndi_devi_enter(vdip, &circ); cdip = ddi_get_child(vdip); while (cdip) { dev_info_t *next = ddi_get_next_sibling(cdip); i_mdi_pm_post_config_one(cdip); cdip = next; } ndi_devi_exit(vdip, circ); } static void i_mdi_pm_post_unconfig_one(dev_info_t *child) { mdi_client_t *ct; ct = i_devi_get_client(child); if (ct == NULL) return; MDI_CLIENT_LOCK(ct); while (MDI_CLIENT_IS_POWER_TRANSITION(ct)) cv_wait(&ct->ct_powerchange_cv, &ct->ct_mutex); if (!ct->ct_powercnt_unconfig || ct->ct_powercnt_reset) { MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_post_unconfig NOT held\n")); MDI_CLIENT_UNLOCK(ct); return; } /* failure detaching or another thread just attached it */ if ((MDI_CLIENT_IS_POWERED_DOWN(ct) && i_ddi_devi_attached(ct->ct_dip)) || (!i_ddi_devi_attached(ct->ct_dip) && !DEVI_IS_ATTACHING(ct->ct_dip))) { MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_post_unconfig i_mdi_pm_reset_client\n")); i_mdi_pm_reset_client(ct); } else { mdi_pathinfo_t *pip, *next; int valid_path_count = 0; MDI_DEBUG(4, (CE_NOTE, child, "i_mdi_pm_post_unconfig i_mdi_pm_rele_client\n")); pip = ct->ct_path_head; while (pip != NULL) { MDI_PI_LOCK(pip); next = (mdi_pathinfo_t *)MDI_PI(pip)->pi_client_link; if (MDI_PI_IS_ONLINE(pip) || MDI_PI_IS_STANDBY(pip)) valid_path_count ++; MDI_PI_UNLOCK(pip); pip = next; } i_mdi_pm_rele_client(ct, valid_path_count); ct->ct_powercnt_unconfig = 0; } MDI_CLIENT_UNLOCK(ct); } static void i_mdi_pm_post_unconfig(dev_info_t *vdip, dev_info_t *child, int held) { int circ; dev_info_t *cdip; ASSERT(MDI_VHCI(vdip)); if (!held) { MDI_DEBUG(4, (CE_NOTE, vdip, "i_mdi_pm_post_unconfig held = %d\n", held)); return; } if (child) { ASSERT(DEVI_BUSY_OWNED(vdip)); i_mdi_pm_post_unconfig_one(child); return; } ndi_devi_enter(vdip, &circ); cdip = ddi_get_child(vdip); while (cdip) { dev_info_t *next = ddi_get_next_sibling(cdip); i_mdi_pm_post_unconfig_one(cdip); cdip = next; } ndi_devi_exit(vdip, circ); } int mdi_power(dev_info_t *vdip, mdi_pm_op_t op, void *args, char *devnm, int flags) { int circ, ret = MDI_SUCCESS; dev_info_t *client_dip = NULL; mdi_client_t *ct; /* * Handling ndi_devi_config_one and ndi_devi_unconfig_one. * Power up pHCI for the named client device. * Note: Before the client is enumerated under vhci by phci, * client_dip can be NULL. Then proceed to power up all the * pHCIs. */ if (devnm != NULL) { ndi_devi_enter(vdip, &circ); client_dip = ndi_devi_findchild(vdip, devnm); } MDI_DEBUG(4, (CE_NOTE, vdip, "mdi_power op = %d %s %p\n", op, devnm ? devnm : "NULL", (void *)client_dip)); switch (op) { case MDI_PM_PRE_CONFIG: ret = i_mdi_pm_pre_config(vdip, client_dip); break; case MDI_PM_PRE_UNCONFIG: ret = i_mdi_pm_pre_unconfig(vdip, client_dip, (int *)args, flags); break; case MDI_PM_POST_CONFIG: i_mdi_pm_post_config(vdip, client_dip); break; case MDI_PM_POST_UNCONFIG: i_mdi_pm_post_unconfig(vdip, client_dip, *(int *)args); break; case MDI_PM_HOLD_POWER: case MDI_PM_RELE_POWER: ASSERT(args); client_dip = (dev_info_t *)args; ASSERT(MDI_CLIENT(client_dip)); ct = i_devi_get_client(client_dip); MDI_CLIENT_LOCK(ct); if (op == MDI_PM_HOLD_POWER) { if (ct->ct_power_cnt == 0) { (void) i_mdi_power_all_phci(ct); MDI_DEBUG(4, (CE_NOTE, client_dip, "mdi_power i_mdi_pm_hold_client\n")); i_mdi_pm_hold_client(ct, ct->ct_path_count); } } else { if (DEVI_IS_ATTACHING(ct->ct_dip)) { MDI_DEBUG(4, (CE_NOTE, client_dip, "mdi_power i_mdi_pm_rele_client\n")); i_mdi_pm_rele_client(ct, ct->ct_path_count); } else { MDI_DEBUG(4, (CE_NOTE, client_dip, "mdi_power i_mdi_pm_reset_client\n")); i_mdi_pm_reset_client(ct); } } MDI_CLIENT_UNLOCK(ct); break; default: break; } if (devnm) ndi_devi_exit(vdip, circ); return (ret); } int mdi_component_is_vhci(dev_info_t *dip, const char **mdi_class) { mdi_vhci_t *vhci; if (!MDI_VHCI(dip)) return (MDI_FAILURE); if (mdi_class) { vhci = DEVI(dip)->devi_mdi_xhci; ASSERT(vhci); *mdi_class = vhci->vh_class; } return (MDI_SUCCESS); } int mdi_component_is_phci(dev_info_t *dip, const char **mdi_class) { mdi_phci_t *phci; if (!MDI_PHCI(dip)) return (MDI_FAILURE); if (mdi_class) { phci = DEVI(dip)->devi_mdi_xhci; ASSERT(phci); *mdi_class = phci->ph_vhci->vh_class; } return (MDI_SUCCESS); } int mdi_component_is_client(dev_info_t *dip, const char **mdi_class) { mdi_client_t *client; if (!MDI_CLIENT(dip)) return (MDI_FAILURE); if (mdi_class) { client = DEVI(dip)->devi_mdi_client; ASSERT(client); *mdi_class = client->ct_vhci->vh_class; } return (MDI_SUCCESS); } void * mdi_client_get_vhci_private(dev_info_t *dip) { ASSERT(mdi_component_is_client(dip, NULL) == MDI_SUCCESS); if (mdi_component_is_client(dip, NULL) == MDI_SUCCESS) { mdi_client_t *ct; ct = i_devi_get_client(dip); return (ct->ct_vprivate); } return (NULL); } void mdi_client_set_vhci_private(dev_info_t *dip, void *data) { ASSERT(mdi_component_is_client(dip, NULL) == MDI_SUCCESS); if (mdi_component_is_client(dip, NULL) == MDI_SUCCESS) { mdi_client_t *ct; ct = i_devi_get_client(dip); ct->ct_vprivate = data; } } /* * mdi_pi_get_vhci_private(): * Get the vhci private information associated with the * mdi_pathinfo node */ void * mdi_pi_get_vhci_private(mdi_pathinfo_t *pip) { caddr_t vprivate = NULL; if (pip) { vprivate = MDI_PI(pip)->pi_vprivate; } return (vprivate); } /* * mdi_pi_set_vhci_private(): * Set the vhci private information in the mdi_pathinfo node */ void mdi_pi_set_vhci_private(mdi_pathinfo_t *pip, void *priv) { if (pip) { MDI_PI(pip)->pi_vprivate = priv; } } /* * mdi_phci_get_vhci_private(): * Get the vhci private information associated with the * mdi_phci node */ void * mdi_phci_get_vhci_private(dev_info_t *dip) { ASSERT(mdi_component_is_phci(dip, NULL) == MDI_SUCCESS); if (mdi_component_is_phci(dip, NULL) == MDI_SUCCESS) { mdi_phci_t *ph; ph = i_devi_get_phci(dip); return (ph->ph_vprivate); } return (NULL); } /* * mdi_phci_set_vhci_private(): * Set the vhci private information in the mdi_phci node */ void mdi_phci_set_vhci_private(dev_info_t *dip, void *priv) { ASSERT(mdi_component_is_phci(dip, NULL) == MDI_SUCCESS); if (mdi_component_is_phci(dip, NULL) == MDI_SUCCESS) { mdi_phci_t *ph; ph = i_devi_get_phci(dip); ph->ph_vprivate = priv; } } /* * List of vhci class names: * A vhci class name must be in this list only if the corresponding vhci * driver intends to use the mdi provided bus config implementation * (i.e., mdi_vhci_bus_config()). */ static char *vhci_class_list[] = { MDI_HCI_CLASS_SCSI, MDI_HCI_CLASS_IB }; #define N_VHCI_CLASSES (sizeof (vhci_class_list) / sizeof (char *)) /* * During boot time, the on-disk vhci cache for every vhci class is read * in the form of an nvlist and stored here. */ static nvlist_t *vhcache_nvl[N_VHCI_CLASSES]; /* nvpair names in vhci cache nvlist */ #define MDI_VHCI_CACHE_VERSION 1 #define MDI_NVPNAME_VERSION "version" #define MDI_NVPNAME_PHCIS "phcis" #define MDI_NVPNAME_CTADDRMAP "clientaddrmap" /* * Given vhci class name, return its on-disk vhci cache filename. * Memory for the returned filename which includes the full path is allocated * by this function. */ static char * vhclass2vhcache_filename(char *vhclass) { char *filename; int len; static char *fmt = "/etc/devices/mdi_%s_cache"; /* * fmt contains the on-disk vhci cache file name format; * for scsi_vhci the filename is "/etc/devices/mdi_scsi_vhci_cache". */ /* the -1 below is to account for "%s" in the format string */ len = strlen(fmt) + strlen(vhclass) - 1; filename = kmem_alloc(len, KM_SLEEP); (void) snprintf(filename, len, fmt, vhclass); ASSERT(len == (strlen(filename) + 1)); return (filename); } /* * initialize the vhci cache related data structures and read the on-disk * vhci cached data into memory. */ static void setup_vhci_cache(mdi_vhci_t *vh) { mdi_vhci_config_t *vhc; mdi_vhci_cache_t *vhcache; int i; nvlist_t *nvl = NULL; vhc = kmem_zalloc(sizeof (mdi_vhci_config_t), KM_SLEEP); vh->vh_config = vhc; vhcache = &vhc->vhc_vhcache; vhc->vhc_vhcache_filename = vhclass2vhcache_filename(vh->vh_class); mutex_init(&vhc->vhc_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&vhc->vhc_cv, NULL, CV_DRIVER, NULL); rw_init(&vhcache->vhcache_lock, NULL, RW_DRIVER, NULL); /* * Create string hash; same as mod_hash_create_strhash() except that * we use NULL key destructor. */ vhcache->vhcache_client_hash = mod_hash_create_extended(vh->vh_class, mdi_bus_config_cache_hash_size, mod_hash_null_keydtor, mod_hash_null_valdtor, mod_hash_bystr, NULL, mod_hash_strkey_cmp, KM_SLEEP); /* * The on-disk vhci cache is read during booting prior to the * lights-out period by mdi_read_devices_files(). */ for (i = 0; i < N_VHCI_CLASSES; i++) { if (strcmp(vhci_class_list[i], vh->vh_class) == 0) { nvl = vhcache_nvl[i]; vhcache_nvl[i] = NULL; break; } } /* * this is to cover the case of some one manually causing unloading * (or detaching) and reloading (or attaching) of a vhci driver. */ if (nvl == NULL && modrootloaded) nvl = read_on_disk_vhci_cache(vh->vh_class); if (nvl != NULL) { rw_enter(&vhcache->vhcache_lock, RW_WRITER); if (mainnvl_to_vhcache(vhcache, nvl) == MDI_SUCCESS) vhcache->vhcache_flags |= MDI_VHCI_CACHE_SETUP_DONE; else { cmn_err(CE_WARN, "%s: data file corrupted, will recreate\n", vhc->vhc_vhcache_filename); } rw_exit(&vhcache->vhcache_lock); nvlist_free(nvl); } vhc->vhc_cbid = callb_add(stop_vhcache_flush_thread, vhc, CB_CL_UADMIN_PRE_VFS, "mdi_vhcache_flush"); vhc->vhc_path_discovery_boot = mdi_path_discovery_boot; vhc->vhc_path_discovery_postboot = mdi_path_discovery_postboot; } /* * free all vhci cache related resources */ static int destroy_vhci_cache(mdi_vhci_t *vh) { mdi_vhci_config_t *vhc = vh->vh_config; mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; mdi_vhcache_phci_t *cphci, *cphci_next; mdi_vhcache_client_t *cct, *cct_next; mdi_vhcache_pathinfo_t *cpi, *cpi_next; if (stop_vhcache_async_threads(vhc) != MDI_SUCCESS) return (MDI_FAILURE); kmem_free(vhc->vhc_vhcache_filename, strlen(vhc->vhc_vhcache_filename) + 1); mod_hash_destroy_strhash(vhcache->vhcache_client_hash); for (cphci = vhcache->vhcache_phci_head; cphci != NULL; cphci = cphci_next) { cphci_next = cphci->cphci_next; free_vhcache_phci(cphci); } for (cct = vhcache->vhcache_client_head; cct != NULL; cct = cct_next) { cct_next = cct->cct_next; for (cpi = cct->cct_cpi_head; cpi != NULL; cpi = cpi_next) { cpi_next = cpi->cpi_next; free_vhcache_pathinfo(cpi); } free_vhcache_client(cct); } rw_destroy(&vhcache->vhcache_lock); mutex_destroy(&vhc->vhc_lock); cv_destroy(&vhc->vhc_cv); kmem_free(vhc, sizeof (mdi_vhci_config_t)); return (MDI_SUCCESS); } /* * Stop all vhci cache related async threads and free their resources. */ static int stop_vhcache_async_threads(mdi_vhci_config_t *vhc) { mdi_async_client_config_t *acc, *acc_next; mutex_enter(&vhc->vhc_lock); vhc->vhc_flags |= MDI_VHC_EXIT; ASSERT(vhc->vhc_acc_thrcount >= 0); cv_broadcast(&vhc->vhc_cv); while ((vhc->vhc_flags & MDI_VHC_VHCACHE_FLUSH_THREAD) || vhc->vhc_acc_thrcount != 0) { mutex_exit(&vhc->vhc_lock); delay(1); mutex_enter(&vhc->vhc_lock); } vhc->vhc_flags &= ~MDI_VHC_EXIT; for (acc = vhc->vhc_acc_list_head; acc != NULL; acc = acc_next) { acc_next = acc->acc_next; free_async_client_config(acc); } vhc->vhc_acc_list_head = NULL; vhc->vhc_acc_list_tail = NULL; vhc->vhc_acc_count = 0; if (vhc->vhc_flags & MDI_VHC_VHCACHE_DIRTY) { vhc->vhc_flags &= ~MDI_VHC_VHCACHE_DIRTY; mutex_exit(&vhc->vhc_lock); if (flush_vhcache(vhc, 0) != MDI_SUCCESS) { vhcache_dirty(vhc); return (MDI_FAILURE); } } else mutex_exit(&vhc->vhc_lock); if (callb_delete(vhc->vhc_cbid) != 0) return (MDI_FAILURE); return (MDI_SUCCESS); } /* * Stop vhci cache flush thread */ /* ARGSUSED */ static boolean_t stop_vhcache_flush_thread(void *arg, int code) { mdi_vhci_config_t *vhc = (mdi_vhci_config_t *)arg; mutex_enter(&vhc->vhc_lock); vhc->vhc_flags |= MDI_VHC_EXIT; cv_broadcast(&vhc->vhc_cv); while (vhc->vhc_flags & MDI_VHC_VHCACHE_FLUSH_THREAD) { mutex_exit(&vhc->vhc_lock); delay(1); mutex_enter(&vhc->vhc_lock); } if (vhc->vhc_flags & MDI_VHC_VHCACHE_DIRTY) { vhc->vhc_flags &= ~MDI_VHC_VHCACHE_DIRTY; mutex_exit(&vhc->vhc_lock); (void) flush_vhcache(vhc, 1); } else mutex_exit(&vhc->vhc_lock); return (B_TRUE); } /* * Enqueue the vhcache phci (cphci) at the tail of the list */ static void enqueue_vhcache_phci(mdi_vhci_cache_t *vhcache, mdi_vhcache_phci_t *cphci) { cphci->cphci_next = NULL; if (vhcache->vhcache_phci_head == NULL) vhcache->vhcache_phci_head = cphci; else vhcache->vhcache_phci_tail->cphci_next = cphci; vhcache->vhcache_phci_tail = cphci; } /* * Enqueue the vhcache pathinfo (cpi) at the tail of the list */ static void enqueue_tail_vhcache_pathinfo(mdi_vhcache_client_t *cct, mdi_vhcache_pathinfo_t *cpi) { cpi->cpi_next = NULL; if (cct->cct_cpi_head == NULL) cct->cct_cpi_head = cpi; else cct->cct_cpi_tail->cpi_next = cpi; cct->cct_cpi_tail = cpi; } /* * Enqueue the vhcache pathinfo (cpi) at the correct location in the * ordered list. All cpis which do not have MDI_CPI_HINT_PATH_DOES_NOT_EXIST * flag set come at the beginning of the list. All cpis which have this * flag set come at the end of the list. */ static void enqueue_vhcache_pathinfo(mdi_vhcache_client_t *cct, mdi_vhcache_pathinfo_t *newcpi) { mdi_vhcache_pathinfo_t *cpi, *prev_cpi; if (cct->cct_cpi_head == NULL || (newcpi->cpi_flags & MDI_CPI_HINT_PATH_DOES_NOT_EXIST)) enqueue_tail_vhcache_pathinfo(cct, newcpi); else { for (cpi = cct->cct_cpi_head, prev_cpi = NULL; cpi != NULL && !(cpi->cpi_flags & MDI_CPI_HINT_PATH_DOES_NOT_EXIST); prev_cpi = cpi, cpi = cpi->cpi_next) ; if (prev_cpi == NULL) cct->cct_cpi_head = newcpi; else prev_cpi->cpi_next = newcpi; newcpi->cpi_next = cpi; if (cpi == NULL) cct->cct_cpi_tail = newcpi; } } /* * Enqueue the vhcache client (cct) at the tail of the list */ static void enqueue_vhcache_client(mdi_vhci_cache_t *vhcache, mdi_vhcache_client_t *cct) { cct->cct_next = NULL; if (vhcache->vhcache_client_head == NULL) vhcache->vhcache_client_head = cct; else vhcache->vhcache_client_tail->cct_next = cct; vhcache->vhcache_client_tail = cct; } static void free_string_array(char **str, int nelem) { int i; if (str) { for (i = 0; i < nelem; i++) { if (str[i]) kmem_free(str[i], strlen(str[i]) + 1); } kmem_free(str, sizeof (char *) * nelem); } } static void free_vhcache_phci(mdi_vhcache_phci_t *cphci) { kmem_free(cphci->cphci_path, strlen(cphci->cphci_path) + 1); kmem_free(cphci, sizeof (*cphci)); } static void free_vhcache_pathinfo(mdi_vhcache_pathinfo_t *cpi) { kmem_free(cpi->cpi_addr, strlen(cpi->cpi_addr) + 1); kmem_free(cpi, sizeof (*cpi)); } static void free_vhcache_client(mdi_vhcache_client_t *cct) { kmem_free(cct->cct_name_addr, strlen(cct->cct_name_addr) + 1); kmem_free(cct, sizeof (*cct)); } static char * vhcache_mknameaddr(char *ct_name, char *ct_addr, int *ret_len) { char *name_addr; int len; len = strlen(ct_name) + strlen(ct_addr) + 2; name_addr = kmem_alloc(len, KM_SLEEP); (void) snprintf(name_addr, len, "%s@%s", ct_name, ct_addr); if (ret_len) *ret_len = len; return (name_addr); } /* * Copy the contents of paddrnvl to vhci cache. * paddrnvl nvlist contains path information for a vhci client. * See the comment in mainnvl_to_vhcache() for the format of this nvlist. */ static void paddrnvl_to_vhcache(nvlist_t *nvl, mdi_vhcache_phci_t *cphci_list[], mdi_vhcache_client_t *cct) { nvpair_t *nvp = NULL; mdi_vhcache_pathinfo_t *cpi; uint_t nelem; uint32_t *val; while ((nvp = nvlist_next_nvpair(nvl, nvp)) != NULL) { ASSERT(nvpair_type(nvp) == DATA_TYPE_UINT32_ARRAY); cpi = kmem_zalloc(sizeof (*cpi), KM_SLEEP); cpi->cpi_addr = i_ddi_strdup(nvpair_name(nvp), KM_SLEEP); (void) nvpair_value_uint32_array(nvp, &val, &nelem); ASSERT(nelem == 2); cpi->cpi_cphci = cphci_list[val[0]]; cpi->cpi_flags = val[1]; enqueue_tail_vhcache_pathinfo(cct, cpi); } } /* * Copy the contents of caddrmapnvl to vhci cache. * caddrmapnvl nvlist contains vhci client address to phci client address * mappings. See the comment in mainnvl_to_vhcache() for the format of * this nvlist. */ static void caddrmapnvl_to_vhcache(mdi_vhci_cache_t *vhcache, nvlist_t *nvl, mdi_vhcache_phci_t *cphci_list[]) { nvpair_t *nvp = NULL; nvlist_t *paddrnvl; mdi_vhcache_client_t *cct; while ((nvp = nvlist_next_nvpair(nvl, nvp)) != NULL) { ASSERT(nvpair_type(nvp) == DATA_TYPE_NVLIST); cct = kmem_zalloc(sizeof (*cct), KM_SLEEP); cct->cct_name_addr = i_ddi_strdup(nvpair_name(nvp), KM_SLEEP); (void) nvpair_value_nvlist(nvp, &paddrnvl); paddrnvl_to_vhcache(paddrnvl, cphci_list, cct); /* the client must contain at least one path */ ASSERT(cct->cct_cpi_head != NULL); enqueue_vhcache_client(vhcache, cct); (void) mod_hash_insert(vhcache->vhcache_client_hash, (mod_hash_key_t)cct->cct_name_addr, (mod_hash_val_t)cct); } } /* * Copy the contents of the main nvlist to vhci cache. * * VHCI busconfig cached data is stored in the form of a nvlist on the disk. * The nvlist contains the mappings between the vhci client addresses and * their corresponding phci client addresses. * * The structure of the nvlist is as follows: * * Main nvlist: * NAME TYPE DATA * version int32 version number * phcis string array array of phci paths * clientaddrmap nvlist_t c2paddrs_nvl (see below) * * structure of c2paddrs_nvl: * NAME TYPE DATA * caddr1 nvlist_t paddrs_nvl1 * caddr2 nvlist_t paddrs_nvl2 * ... * where caddr1, caddr2, ... are vhci client name and addresses in the * form of "@". * (for example: "ssd@2000002037cd9f72"); * paddrs_nvl1, paddrs_nvl2, .. are nvlists that contain path information. * * structure of paddrs_nvl: * NAME TYPE DATA * pi_addr1 uint32_array (phci-id, cpi_flags) * pi_addr2 uint32_array (phci-id, cpi_flags) * ... * where pi_addr1, pi_addr2, ... are bus specific addresses of pathinfo nodes * (so called pi_addrs, for example: "w2100002037cd9f72,0"); * phci-ids are integers that identify PHCIs to which the * the bus specific address belongs to. These integers are used as an index * into to the phcis string array in the main nvlist to get the PHCI path. */ static int mainnvl_to_vhcache(mdi_vhci_cache_t *vhcache, nvlist_t *nvl) { char **phcis, **phci_namep; uint_t nphcis; mdi_vhcache_phci_t *cphci, **cphci_list; nvlist_t *caddrmapnvl; int32_t ver; int i; size_t cphci_list_size; ASSERT(RW_WRITE_HELD(&vhcache->vhcache_lock)); if (nvlist_lookup_int32(nvl, MDI_NVPNAME_VERSION, &ver) != 0 || ver != MDI_VHCI_CACHE_VERSION) return (MDI_FAILURE); if (nvlist_lookup_string_array(nvl, MDI_NVPNAME_PHCIS, &phcis, &nphcis) != 0) return (MDI_SUCCESS); ASSERT(nphcis > 0); cphci_list_size = sizeof (mdi_vhcache_phci_t *) * nphcis; cphci_list = kmem_alloc(cphci_list_size, KM_SLEEP); for (i = 0, phci_namep = phcis; i < nphcis; i++, phci_namep++) { cphci = kmem_zalloc(sizeof (mdi_vhcache_phci_t), KM_SLEEP); cphci->cphci_path = i_ddi_strdup(*phci_namep, KM_SLEEP); enqueue_vhcache_phci(vhcache, cphci); cphci_list[i] = cphci; } ASSERT(vhcache->vhcache_phci_head != NULL); if (nvlist_lookup_nvlist(nvl, MDI_NVPNAME_CTADDRMAP, &caddrmapnvl) == 0) caddrmapnvl_to_vhcache(vhcache, caddrmapnvl, cphci_list); kmem_free(cphci_list, cphci_list_size); return (MDI_SUCCESS); } /* * Build paddrnvl for the specified client using the information in the * vhci cache and add it to the caddrmapnnvl. * Returns 0 on success, errno on failure. */ static int vhcache_to_paddrnvl(mdi_vhci_cache_t *vhcache, mdi_vhcache_client_t *cct, nvlist_t *caddrmapnvl) { mdi_vhcache_pathinfo_t *cpi; nvlist_t *nvl; int err; uint32_t val[2]; ASSERT(RW_LOCK_HELD(&vhcache->vhcache_lock)); if ((err = nvlist_alloc(&nvl, 0, KM_SLEEP)) != 0) return (err); for (cpi = cct->cct_cpi_head; cpi != NULL; cpi = cpi->cpi_next) { val[0] = cpi->cpi_cphci->cphci_id; val[1] = cpi->cpi_flags; if ((err = nvlist_add_uint32_array(nvl, cpi->cpi_addr, val, 2)) != 0) goto out; } err = nvlist_add_nvlist(caddrmapnvl, cct->cct_name_addr, nvl); out: nvlist_free(nvl); return (err); } /* * Build caddrmapnvl using the information in the vhci cache * and add it to the mainnvl. * Returns 0 on success, errno on failure. */ static int vhcache_to_caddrmapnvl(mdi_vhci_cache_t *vhcache, nvlist_t *mainnvl) { mdi_vhcache_client_t *cct; nvlist_t *nvl; int err; ASSERT(RW_LOCK_HELD(&vhcache->vhcache_lock)); if ((err = nvlist_alloc(&nvl, NV_UNIQUE_NAME, KM_SLEEP)) != 0) return (err); for (cct = vhcache->vhcache_client_head; cct != NULL; cct = cct->cct_next) { if ((err = vhcache_to_paddrnvl(vhcache, cct, nvl)) != 0) goto out; } err = nvlist_add_nvlist(mainnvl, MDI_NVPNAME_CTADDRMAP, nvl); out: nvlist_free(nvl); return (err); } /* * Build nvlist using the information in the vhci cache. * See the comment in mainnvl_to_vhcache() for the format of the nvlist. * Returns nvl on success, NULL on failure. */ static nvlist_t * vhcache_to_mainnvl(mdi_vhci_cache_t *vhcache) { mdi_vhcache_phci_t *cphci; uint_t phci_count; char **phcis; nvlist_t *nvl; int err, i; if ((err = nvlist_alloc(&nvl, NV_UNIQUE_NAME, KM_SLEEP)) != 0) { nvl = NULL; goto out; } if ((err = nvlist_add_int32(nvl, MDI_NVPNAME_VERSION, MDI_VHCI_CACHE_VERSION)) != 0) goto out; rw_enter(&vhcache->vhcache_lock, RW_READER); if (vhcache->vhcache_phci_head == NULL) { rw_exit(&vhcache->vhcache_lock); return (nvl); } phci_count = 0; for (cphci = vhcache->vhcache_phci_head; cphci != NULL; cphci = cphci->cphci_next) cphci->cphci_id = phci_count++; /* build phci pathname list */ phcis = kmem_alloc(sizeof (char *) * phci_count, KM_SLEEP); for (cphci = vhcache->vhcache_phci_head, i = 0; cphci != NULL; cphci = cphci->cphci_next, i++) phcis[i] = i_ddi_strdup(cphci->cphci_path, KM_SLEEP); err = nvlist_add_string_array(nvl, MDI_NVPNAME_PHCIS, phcis, phci_count); free_string_array(phcis, phci_count); if (err == 0 && (err = vhcache_to_caddrmapnvl(vhcache, nvl)) == 0) { rw_exit(&vhcache->vhcache_lock); return (nvl); } rw_exit(&vhcache->vhcache_lock); out: if (nvl) nvlist_free(nvl); return (NULL); } /* * Lookup vhcache phci structure for the specified phci path. */ static mdi_vhcache_phci_t * lookup_vhcache_phci_by_name(mdi_vhci_cache_t *vhcache, char *phci_path) { mdi_vhcache_phci_t *cphci; ASSERT(RW_LOCK_HELD(&vhcache->vhcache_lock)); for (cphci = vhcache->vhcache_phci_head; cphci != NULL; cphci = cphci->cphci_next) { if (strcmp(cphci->cphci_path, phci_path) == 0) return (cphci); } return (NULL); } /* * Lookup vhcache phci structure for the specified phci. */ static mdi_vhcache_phci_t * lookup_vhcache_phci_by_addr(mdi_vhci_cache_t *vhcache, mdi_phci_t *ph) { mdi_vhcache_phci_t *cphci; ASSERT(RW_LOCK_HELD(&vhcache->vhcache_lock)); for (cphci = vhcache->vhcache_phci_head; cphci != NULL; cphci = cphci->cphci_next) { if (cphci->cphci_phci == ph) return (cphci); } return (NULL); } /* * Add the specified phci to the vhci cache if not already present. */ static void vhcache_phci_add(mdi_vhci_config_t *vhc, mdi_phci_t *ph) { mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; mdi_vhcache_phci_t *cphci; char *pathname; int cache_updated; rw_enter(&vhcache->vhcache_lock, RW_WRITER); pathname = kmem_alloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(ph->ph_dip, pathname); if ((cphci = lookup_vhcache_phci_by_name(vhcache, pathname)) != NULL) { cphci->cphci_phci = ph; cache_updated = 0; } else { cphci = kmem_zalloc(sizeof (*cphci), KM_SLEEP); cphci->cphci_path = i_ddi_strdup(pathname, KM_SLEEP); cphci->cphci_phci = ph; enqueue_vhcache_phci(vhcache, cphci); cache_updated = 1; } rw_exit(&vhcache->vhcache_lock); /* * Since a new phci has been added, reset * vhc_path_discovery_cutoff_time to allow for discovery of paths * during next vhcache_discover_paths(). */ mutex_enter(&vhc->vhc_lock); vhc->vhc_path_discovery_cutoff_time = 0; mutex_exit(&vhc->vhc_lock); kmem_free(pathname, MAXPATHLEN); if (cache_updated) vhcache_dirty(vhc); } /* * Remove the reference to the specified phci from the vhci cache. */ static void vhcache_phci_remove(mdi_vhci_config_t *vhc, mdi_phci_t *ph) { mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; mdi_vhcache_phci_t *cphci; rw_enter(&vhcache->vhcache_lock, RW_WRITER); if ((cphci = lookup_vhcache_phci_by_addr(vhcache, ph)) != NULL) { /* do not remove the actual mdi_vhcache_phci structure */ cphci->cphci_phci = NULL; } rw_exit(&vhcache->vhcache_lock); } static void init_vhcache_lookup_token(mdi_vhcache_lookup_token_t *dst, mdi_vhcache_lookup_token_t *src) { if (src == NULL) { dst->lt_cct = NULL; dst->lt_cct_lookup_time = 0; } else { dst->lt_cct = src->lt_cct; dst->lt_cct_lookup_time = src->lt_cct_lookup_time; } } /* * Look up vhcache client for the specified client. */ static mdi_vhcache_client_t * lookup_vhcache_client(mdi_vhci_cache_t *vhcache, char *ct_name, char *ct_addr, mdi_vhcache_lookup_token_t *token) { mod_hash_val_t hv; char *name_addr; int len; ASSERT(RW_LOCK_HELD(&vhcache->vhcache_lock)); /* * If no vhcache clean occurred since the last lookup, we can * simply return the cct from the last lookup operation. * It works because ccts are never freed except during the vhcache * cleanup operation. */ if (token != NULL && vhcache->vhcache_clean_time < token->lt_cct_lookup_time) return (token->lt_cct); name_addr = vhcache_mknameaddr(ct_name, ct_addr, &len); if (mod_hash_find(vhcache->vhcache_client_hash, (mod_hash_key_t)name_addr, &hv) == 0) { if (token) { token->lt_cct = (mdi_vhcache_client_t *)hv; token->lt_cct_lookup_time = lbolt64; } } else { if (token) { token->lt_cct = NULL; token->lt_cct_lookup_time = 0; } hv = NULL; } kmem_free(name_addr, len); return ((mdi_vhcache_client_t *)hv); } /* * Add the specified path to the vhci cache if not already present. * Also add the vhcache client for the client corresponding to this path * if it doesn't already exist. */ static void vhcache_pi_add(mdi_vhci_config_t *vhc, struct mdi_pathinfo *pip) { mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; mdi_vhcache_client_t *cct; mdi_vhcache_pathinfo_t *cpi; mdi_phci_t *ph = pip->pi_phci; mdi_client_t *ct = pip->pi_client; int cache_updated = 0; rw_enter(&vhcache->vhcache_lock, RW_WRITER); /* if vhcache client for this pip doesn't already exist, add it */ if ((cct = lookup_vhcache_client(vhcache, ct->ct_drvname, ct->ct_guid, NULL)) == NULL) { cct = kmem_zalloc(sizeof (*cct), KM_SLEEP); cct->cct_name_addr = vhcache_mknameaddr(ct->ct_drvname, ct->ct_guid, NULL); enqueue_vhcache_client(vhcache, cct); (void) mod_hash_insert(vhcache->vhcache_client_hash, (mod_hash_key_t)cct->cct_name_addr, (mod_hash_val_t)cct); cache_updated = 1; } for (cpi = cct->cct_cpi_head; cpi != NULL; cpi = cpi->cpi_next) { if (cpi->cpi_cphci->cphci_phci == ph && strcmp(cpi->cpi_addr, pip->pi_addr) == 0) { cpi->cpi_pip = pip; if (cpi->cpi_flags & MDI_CPI_HINT_PATH_DOES_NOT_EXIST) { cpi->cpi_flags &= ~MDI_CPI_HINT_PATH_DOES_NOT_EXIST; sort_vhcache_paths(cct); cache_updated = 1; } break; } } if (cpi == NULL) { cpi = kmem_zalloc(sizeof (*cpi), KM_SLEEP); cpi->cpi_addr = i_ddi_strdup(pip->pi_addr, KM_SLEEP); cpi->cpi_cphci = lookup_vhcache_phci_by_addr(vhcache, ph); ASSERT(cpi->cpi_cphci != NULL); cpi->cpi_pip = pip; enqueue_vhcache_pathinfo(cct, cpi); cache_updated = 1; } rw_exit(&vhcache->vhcache_lock); if (cache_updated) vhcache_dirty(vhc); } /* * Remove the reference to the specified path from the vhci cache. */ static void vhcache_pi_remove(mdi_vhci_config_t *vhc, struct mdi_pathinfo *pip) { mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; mdi_client_t *ct = pip->pi_client; mdi_vhcache_client_t *cct; mdi_vhcache_pathinfo_t *cpi; rw_enter(&vhcache->vhcache_lock, RW_WRITER); if ((cct = lookup_vhcache_client(vhcache, ct->ct_drvname, ct->ct_guid, NULL)) != NULL) { for (cpi = cct->cct_cpi_head; cpi != NULL; cpi = cpi->cpi_next) { if (cpi->cpi_pip == pip) { cpi->cpi_pip = NULL; break; } } } rw_exit(&vhcache->vhcache_lock); } /* * Flush the vhci cache to disk. * Returns MDI_SUCCESS on success, MDI_FAILURE on failure. */ static int flush_vhcache(mdi_vhci_config_t *vhc, int force_flag) { nvlist_t *nvl; int err; int rv; /* * It is possible that the system may shutdown before * i_ddi_io_initialized (during stmsboot for example). To allow for * flushing the cache in this case do not check for * i_ddi_io_initialized when force flag is set. */ if (force_flag == 0 && !i_ddi_io_initialized()) return (MDI_FAILURE); if ((nvl = vhcache_to_mainnvl(&vhc->vhc_vhcache)) != NULL) { err = fwrite_nvlist(vhc->vhc_vhcache_filename, nvl); nvlist_free(nvl); } else err = EFAULT; rv = MDI_SUCCESS; mutex_enter(&vhc->vhc_lock); if (err != 0) { if (err == EROFS) { vhc->vhc_flags |= MDI_VHC_READONLY_FS; vhc->vhc_flags &= ~(MDI_VHC_VHCACHE_FLUSH_ERROR | MDI_VHC_VHCACHE_DIRTY); } else { if (!(vhc->vhc_flags & MDI_VHC_VHCACHE_FLUSH_ERROR)) { cmn_err(CE_CONT, "%s: update failed\n", vhc->vhc_vhcache_filename); vhc->vhc_flags |= MDI_VHC_VHCACHE_FLUSH_ERROR; } rv = MDI_FAILURE; } } else if (vhc->vhc_flags & MDI_VHC_VHCACHE_FLUSH_ERROR) { cmn_err(CE_CONT, "%s: update now ok\n", vhc->vhc_vhcache_filename); vhc->vhc_flags &= ~MDI_VHC_VHCACHE_FLUSH_ERROR; } mutex_exit(&vhc->vhc_lock); return (rv); } /* * Call flush_vhcache() to flush the vhci cache at the scheduled time. * Exits itself if left idle for the idle timeout period. */ static void vhcache_flush_thread(void *arg) { mdi_vhci_config_t *vhc = (mdi_vhci_config_t *)arg; clock_t idle_time, quit_at_ticks; callb_cpr_t cprinfo; /* number of seconds to sleep idle before exiting */ idle_time = mdi_vhcache_flush_daemon_idle_time * TICKS_PER_SECOND; CALLB_CPR_INIT(&cprinfo, &vhc->vhc_lock, callb_generic_cpr, "mdi_vhcache_flush"); mutex_enter(&vhc->vhc_lock); for (; ; ) { while (!(vhc->vhc_flags & MDI_VHC_EXIT) && (vhc->vhc_flags & MDI_VHC_VHCACHE_DIRTY)) { if (ddi_get_lbolt() < vhc->vhc_flush_at_ticks) { CALLB_CPR_SAFE_BEGIN(&cprinfo); (void) cv_timedwait(&vhc->vhc_cv, &vhc->vhc_lock, vhc->vhc_flush_at_ticks); CALLB_CPR_SAFE_END(&cprinfo, &vhc->vhc_lock); } else { vhc->vhc_flags &= ~MDI_VHC_VHCACHE_DIRTY; mutex_exit(&vhc->vhc_lock); if (flush_vhcache(vhc, 0) != MDI_SUCCESS) vhcache_dirty(vhc); mutex_enter(&vhc->vhc_lock); } } quit_at_ticks = ddi_get_lbolt() + idle_time; while (!(vhc->vhc_flags & MDI_VHC_EXIT) && !(vhc->vhc_flags & MDI_VHC_VHCACHE_DIRTY) && ddi_get_lbolt() < quit_at_ticks) { CALLB_CPR_SAFE_BEGIN(&cprinfo); (void) cv_timedwait(&vhc->vhc_cv, &vhc->vhc_lock, quit_at_ticks); CALLB_CPR_SAFE_END(&cprinfo, &vhc->vhc_lock); } if ((vhc->vhc_flags & MDI_VHC_EXIT) || !(vhc->vhc_flags & MDI_VHC_VHCACHE_DIRTY)) goto out; } out: vhc->vhc_flags &= ~MDI_VHC_VHCACHE_FLUSH_THREAD; /* CALLB_CPR_EXIT releases the vhc->vhc_lock */ CALLB_CPR_EXIT(&cprinfo); } /* * Make vhci cache dirty and schedule flushing by vhcache flush thread. */ static void vhcache_dirty(mdi_vhci_config_t *vhc) { mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; int create_thread; rw_enter(&vhcache->vhcache_lock, RW_READER); /* do not flush cache until the cache is fully built */ if (!(vhcache->vhcache_flags & MDI_VHCI_CACHE_SETUP_DONE)) { rw_exit(&vhcache->vhcache_lock); return; } rw_exit(&vhcache->vhcache_lock); mutex_enter(&vhc->vhc_lock); if (vhc->vhc_flags & MDI_VHC_READONLY_FS) { mutex_exit(&vhc->vhc_lock); return; } vhc->vhc_flags |= MDI_VHC_VHCACHE_DIRTY; vhc->vhc_flush_at_ticks = ddi_get_lbolt() + mdi_vhcache_flush_delay * TICKS_PER_SECOND; if (vhc->vhc_flags & MDI_VHC_VHCACHE_FLUSH_THREAD) { cv_broadcast(&vhc->vhc_cv); create_thread = 0; } else { vhc->vhc_flags |= MDI_VHC_VHCACHE_FLUSH_THREAD; create_thread = 1; } mutex_exit(&vhc->vhc_lock); if (create_thread) (void) thread_create(NULL, 0, vhcache_flush_thread, vhc, 0, &p0, TS_RUN, minclsyspri); } /* * phci bus config structure - one for for each phci bus config operation that * we initiate on behalf of a vhci. */ typedef struct mdi_phci_bus_config_s { char *phbc_phci_path; struct mdi_vhci_bus_config_s *phbc_vhbusconfig; /* vhci bus config */ struct mdi_phci_bus_config_s *phbc_next; } mdi_phci_bus_config_t; /* vhci bus config structure - one for each vhci bus config operation */ typedef struct mdi_vhci_bus_config_s { ddi_bus_config_op_t vhbc_op; /* bus config op */ major_t vhbc_op_major; /* bus config op major */ uint_t vhbc_op_flags; /* bus config op flags */ kmutex_t vhbc_lock; kcondvar_t vhbc_cv; int vhbc_thr_count; } mdi_vhci_bus_config_t; /* * bus config the specified phci */ static void bus_config_phci(void *arg) { mdi_phci_bus_config_t *phbc = (mdi_phci_bus_config_t *)arg; mdi_vhci_bus_config_t *vhbc = phbc->phbc_vhbusconfig; dev_info_t *ph_dip; /* * first configure all path components upto phci and then configure * the phci children. */ if ((ph_dip = e_ddi_hold_devi_by_path(phbc->phbc_phci_path, 0)) != NULL) { if (vhbc->vhbc_op == BUS_CONFIG_DRIVER || vhbc->vhbc_op == BUS_UNCONFIG_DRIVER) { (void) ndi_devi_config_driver(ph_dip, vhbc->vhbc_op_flags, vhbc->vhbc_op_major); } else (void) ndi_devi_config(ph_dip, vhbc->vhbc_op_flags); /* release the hold that e_ddi_hold_devi_by_path() placed */ ndi_rele_devi(ph_dip); } kmem_free(phbc->phbc_phci_path, strlen(phbc->phbc_phci_path) + 1); kmem_free(phbc, sizeof (*phbc)); mutex_enter(&vhbc->vhbc_lock); vhbc->vhbc_thr_count--; if (vhbc->vhbc_thr_count == 0) cv_broadcast(&vhbc->vhbc_cv); mutex_exit(&vhbc->vhbc_lock); } /* * Bus config all phcis associated with the vhci in parallel. * op must be BUS_CONFIG_DRIVER or BUS_CONFIG_ALL. */ static void bus_config_all_phcis(mdi_vhci_cache_t *vhcache, uint_t flags, ddi_bus_config_op_t op, major_t maj) { mdi_phci_bus_config_t *phbc_head = NULL, *phbc, *phbc_next; mdi_vhci_bus_config_t *vhbc; mdi_vhcache_phci_t *cphci; rw_enter(&vhcache->vhcache_lock, RW_READER); if (vhcache->vhcache_phci_head == NULL) { rw_exit(&vhcache->vhcache_lock); return; } vhbc = kmem_zalloc(sizeof (*vhbc), KM_SLEEP); for (cphci = vhcache->vhcache_phci_head; cphci != NULL; cphci = cphci->cphci_next) { /* skip phcis that haven't attached before root is available */ if (!modrootloaded && (cphci->cphci_phci == NULL)) continue; phbc = kmem_zalloc(sizeof (*phbc), KM_SLEEP); phbc->phbc_phci_path = i_ddi_strdup(cphci->cphci_path, KM_SLEEP); phbc->phbc_vhbusconfig = vhbc; phbc->phbc_next = phbc_head; phbc_head = phbc; vhbc->vhbc_thr_count++; } rw_exit(&vhcache->vhcache_lock); vhbc->vhbc_op = op; vhbc->vhbc_op_major = maj; vhbc->vhbc_op_flags = NDI_NO_EVENT | (flags & (NDI_CONFIG_REPROBE | NDI_DRV_CONF_REPROBE)); mutex_init(&vhbc->vhbc_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&vhbc->vhbc_cv, NULL, CV_DRIVER, NULL); /* now create threads to initiate bus config on all phcis in parallel */ for (phbc = phbc_head; phbc != NULL; phbc = phbc_next) { phbc_next = phbc->phbc_next; if (mdi_mtc_off) bus_config_phci((void *)phbc); else (void) thread_create(NULL, 0, bus_config_phci, phbc, 0, &p0, TS_RUN, minclsyspri); } mutex_enter(&vhbc->vhbc_lock); /* wait until all threads exit */ while (vhbc->vhbc_thr_count > 0) cv_wait(&vhbc->vhbc_cv, &vhbc->vhbc_lock); mutex_exit(&vhbc->vhbc_lock); mutex_destroy(&vhbc->vhbc_lock); cv_destroy(&vhbc->vhbc_cv); kmem_free(vhbc, sizeof (*vhbc)); } /* * Single threaded version of bus_config_all_phcis() */ static void st_bus_config_all_phcis(mdi_vhci_config_t *vhc, uint_t flags, ddi_bus_config_op_t op, major_t maj) { mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; single_threaded_vhconfig_enter(vhc); bus_config_all_phcis(vhcache, flags, op, maj); single_threaded_vhconfig_exit(vhc); } /* * Perform BUS_CONFIG_ONE on the specified child of the phci. * The path includes the child component in addition to the phci path. */ static int bus_config_one_phci_child(char *path) { dev_info_t *ph_dip, *child; char *devnm; int rv = MDI_FAILURE; /* extract the child component of the phci */ devnm = strrchr(path, '/'); *devnm++ = '\0'; /* * first configure all path components upto phci and then * configure the phci child. */ if ((ph_dip = e_ddi_hold_devi_by_path(path, 0)) != NULL) { if (ndi_devi_config_one(ph_dip, devnm, &child, NDI_NO_EVENT) == NDI_SUCCESS) { /* * release the hold that ndi_devi_config_one() placed */ ndi_rele_devi(child); rv = MDI_SUCCESS; } /* release the hold that e_ddi_hold_devi_by_path() placed */ ndi_rele_devi(ph_dip); } devnm--; *devnm = '/'; return (rv); } /* * Build a list of phci client paths for the specified vhci client. * The list includes only those phci client paths which aren't configured yet. */ static mdi_phys_path_t * build_phclient_path_list(mdi_vhcache_client_t *cct, char *ct_name) { mdi_vhcache_pathinfo_t *cpi; mdi_phys_path_t *pp_head = NULL, *pp_tail = NULL, *pp; int config_path, len; for (cpi = cct->cct_cpi_head; cpi != NULL; cpi = cpi->cpi_next) { /* * include only those paths that aren't configured. */ config_path = 0; if (cpi->cpi_pip == NULL) config_path = 1; else { MDI_PI_LOCK(cpi->cpi_pip); if (MDI_PI_IS_INIT(cpi->cpi_pip)) config_path = 1; MDI_PI_UNLOCK(cpi->cpi_pip); } if (config_path) { pp = kmem_alloc(sizeof (*pp), KM_SLEEP); len = strlen(cpi->cpi_cphci->cphci_path) + strlen(ct_name) + strlen(cpi->cpi_addr) + 3; pp->phys_path = kmem_alloc(len, KM_SLEEP); (void) snprintf(pp->phys_path, len, "%s/%s@%s", cpi->cpi_cphci->cphci_path, ct_name, cpi->cpi_addr); pp->phys_path_next = NULL; if (pp_head == NULL) pp_head = pp; else pp_tail->phys_path_next = pp; pp_tail = pp; } } return (pp_head); } /* * Free the memory allocated for phci client path list. */ static void free_phclient_path_list(mdi_phys_path_t *pp_head) { mdi_phys_path_t *pp, *pp_next; for (pp = pp_head; pp != NULL; pp = pp_next) { pp_next = pp->phys_path_next; kmem_free(pp->phys_path, strlen(pp->phys_path) + 1); kmem_free(pp, sizeof (*pp)); } } /* * Allocated async client structure and initialize with the specified values. */ static mdi_async_client_config_t * alloc_async_client_config(char *ct_name, char *ct_addr, mdi_phys_path_t *pp_head, mdi_vhcache_lookup_token_t *tok) { mdi_async_client_config_t *acc; acc = kmem_alloc(sizeof (*acc), KM_SLEEP); acc->acc_ct_name = i_ddi_strdup(ct_name, KM_SLEEP); acc->acc_ct_addr = i_ddi_strdup(ct_addr, KM_SLEEP); acc->acc_phclient_path_list_head = pp_head; init_vhcache_lookup_token(&acc->acc_token, tok); acc->acc_next = NULL; return (acc); } /* * Free the memory allocated for the async client structure and their members. */ static void free_async_client_config(mdi_async_client_config_t *acc) { if (acc->acc_phclient_path_list_head) free_phclient_path_list(acc->acc_phclient_path_list_head); kmem_free(acc->acc_ct_name, strlen(acc->acc_ct_name) + 1); kmem_free(acc->acc_ct_addr, strlen(acc->acc_ct_addr) + 1); kmem_free(acc, sizeof (*acc)); } /* * Sort vhcache pathinfos (cpis) of the specified client. * All cpis which do not have MDI_CPI_HINT_PATH_DOES_NOT_EXIST * flag set come at the beginning of the list. All cpis which have this * flag set come at the end of the list. */ static void sort_vhcache_paths(mdi_vhcache_client_t *cct) { mdi_vhcache_pathinfo_t *cpi, *cpi_next, *cpi_head; cpi_head = cct->cct_cpi_head; cct->cct_cpi_head = cct->cct_cpi_tail = NULL; for (cpi = cpi_head; cpi != NULL; cpi = cpi_next) { cpi_next = cpi->cpi_next; enqueue_vhcache_pathinfo(cct, cpi); } } /* * Verify whether MDI_CPI_HINT_PATH_DOES_NOT_EXIST flag setting is correct for * every vhcache pathinfo of the specified client. If not adjust the flag * setting appropriately. * * Note that MDI_CPI_HINT_PATH_DOES_NOT_EXIST flag is persisted in the * on-disk vhci cache. So every time this flag is updated the cache must be * flushed. */ static void adjust_sort_vhcache_paths(mdi_vhci_config_t *vhc, char *ct_name, char *ct_addr, mdi_vhcache_lookup_token_t *tok) { mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; mdi_vhcache_client_t *cct; mdi_vhcache_pathinfo_t *cpi; rw_enter(&vhcache->vhcache_lock, RW_READER); if ((cct = lookup_vhcache_client(vhcache, ct_name, ct_addr, tok)) == NULL) { rw_exit(&vhcache->vhcache_lock); return; } /* * to avoid unnecessary on-disk cache updates, first check if an * update is really needed. If no update is needed simply return. */ for (cpi = cct->cct_cpi_head; cpi != NULL; cpi = cpi->cpi_next) { if ((cpi->cpi_pip != NULL && (cpi->cpi_flags & MDI_CPI_HINT_PATH_DOES_NOT_EXIST)) || (cpi->cpi_pip == NULL && !(cpi->cpi_flags & MDI_CPI_HINT_PATH_DOES_NOT_EXIST))) { break; } } if (cpi == NULL) { rw_exit(&vhcache->vhcache_lock); return; } if (rw_tryupgrade(&vhcache->vhcache_lock) == 0) { rw_exit(&vhcache->vhcache_lock); rw_enter(&vhcache->vhcache_lock, RW_WRITER); if ((cct = lookup_vhcache_client(vhcache, ct_name, ct_addr, tok)) == NULL) { rw_exit(&vhcache->vhcache_lock); return; } } for (cpi = cct->cct_cpi_head; cpi != NULL; cpi = cpi->cpi_next) { if (cpi->cpi_pip != NULL) cpi->cpi_flags &= ~MDI_CPI_HINT_PATH_DOES_NOT_EXIST; else cpi->cpi_flags |= MDI_CPI_HINT_PATH_DOES_NOT_EXIST; } sort_vhcache_paths(cct); rw_exit(&vhcache->vhcache_lock); vhcache_dirty(vhc); } /* * Configure all specified paths of the client. */ static void config_client_paths_sync(mdi_vhci_config_t *vhc, char *ct_name, char *ct_addr, mdi_phys_path_t *pp_head, mdi_vhcache_lookup_token_t *tok) { mdi_phys_path_t *pp; for (pp = pp_head; pp != NULL; pp = pp->phys_path_next) (void) bus_config_one_phci_child(pp->phys_path); adjust_sort_vhcache_paths(vhc, ct_name, ct_addr, tok); } /* * Dequeue elements from vhci async client config list and bus configure * their corresponding phci clients. */ static void config_client_paths_thread(void *arg) { mdi_vhci_config_t *vhc = (mdi_vhci_config_t *)arg; mdi_async_client_config_t *acc; clock_t quit_at_ticks; clock_t idle_time = mdi_async_config_idle_time * TICKS_PER_SECOND; callb_cpr_t cprinfo; CALLB_CPR_INIT(&cprinfo, &vhc->vhc_lock, callb_generic_cpr, "mdi_config_client_paths"); for (; ; ) { quit_at_ticks = ddi_get_lbolt() + idle_time; mutex_enter(&vhc->vhc_lock); while (!(vhc->vhc_flags & MDI_VHC_EXIT) && vhc->vhc_acc_list_head == NULL && ddi_get_lbolt() < quit_at_ticks) { CALLB_CPR_SAFE_BEGIN(&cprinfo); (void) cv_timedwait(&vhc->vhc_cv, &vhc->vhc_lock, quit_at_ticks); CALLB_CPR_SAFE_END(&cprinfo, &vhc->vhc_lock); } if ((vhc->vhc_flags & MDI_VHC_EXIT) || vhc->vhc_acc_list_head == NULL) goto out; acc = vhc->vhc_acc_list_head; vhc->vhc_acc_list_head = acc->acc_next; if (vhc->vhc_acc_list_head == NULL) vhc->vhc_acc_list_tail = NULL; vhc->vhc_acc_count--; mutex_exit(&vhc->vhc_lock); config_client_paths_sync(vhc, acc->acc_ct_name, acc->acc_ct_addr, acc->acc_phclient_path_list_head, &acc->acc_token); free_async_client_config(acc); } out: vhc->vhc_acc_thrcount--; /* CALLB_CPR_EXIT releases the vhc->vhc_lock */ CALLB_CPR_EXIT(&cprinfo); } /* * Arrange for all the phci client paths (pp_head) for the specified client * to be bus configured asynchronously by a thread. */ static void config_client_paths_async(mdi_vhci_config_t *vhc, char *ct_name, char *ct_addr, mdi_phys_path_t *pp_head, mdi_vhcache_lookup_token_t *tok) { mdi_async_client_config_t *acc, *newacc; int create_thread; if (pp_head == NULL) return; if (mdi_mtc_off) { config_client_paths_sync(vhc, ct_name, ct_addr, pp_head, tok); free_phclient_path_list(pp_head); return; } newacc = alloc_async_client_config(ct_name, ct_addr, pp_head, tok); ASSERT(newacc); mutex_enter(&vhc->vhc_lock); for (acc = vhc->vhc_acc_list_head; acc != NULL; acc = acc->acc_next) { if (strcmp(ct_name, acc->acc_ct_name) == 0 && strcmp(ct_addr, acc->acc_ct_addr) == 0) { free_async_client_config(newacc); mutex_exit(&vhc->vhc_lock); return; } } if (vhc->vhc_acc_list_head == NULL) vhc->vhc_acc_list_head = newacc; else vhc->vhc_acc_list_tail->acc_next = newacc; vhc->vhc_acc_list_tail = newacc; vhc->vhc_acc_count++; if (vhc->vhc_acc_count <= vhc->vhc_acc_thrcount) { cv_broadcast(&vhc->vhc_cv); create_thread = 0; } else { vhc->vhc_acc_thrcount++; create_thread = 1; } mutex_exit(&vhc->vhc_lock); if (create_thread) (void) thread_create(NULL, 0, config_client_paths_thread, vhc, 0, &p0, TS_RUN, minclsyspri); } /* * Return number of online paths for the specified client. */ static int nonline_paths(mdi_vhcache_client_t *cct) { mdi_vhcache_pathinfo_t *cpi; int online_count = 0; for (cpi = cct->cct_cpi_head; cpi != NULL; cpi = cpi->cpi_next) { if (cpi->cpi_pip != NULL) { MDI_PI_LOCK(cpi->cpi_pip); if (cpi->cpi_pip->pi_state == MDI_PATHINFO_STATE_ONLINE) online_count++; MDI_PI_UNLOCK(cpi->cpi_pip); } } return (online_count); } /* * Bus configure all paths for the specified vhci client. * If at least one path for the client is already online, the remaining paths * will be configured asynchronously. Otherwise, it synchronously configures * the paths until at least one path is online and then rest of the paths * will be configured asynchronously. */ static void config_client_paths(mdi_vhci_config_t *vhc, char *ct_name, char *ct_addr) { mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; mdi_phys_path_t *pp_head, *pp; mdi_vhcache_client_t *cct; mdi_vhcache_lookup_token_t tok; ASSERT(RW_LOCK_HELD(&vhcache->vhcache_lock)); init_vhcache_lookup_token(&tok, NULL); if (ct_name == NULL || ct_addr == NULL || (cct = lookup_vhcache_client(vhcache, ct_name, ct_addr, &tok)) == NULL || (pp_head = build_phclient_path_list(cct, ct_name)) == NULL) { rw_exit(&vhcache->vhcache_lock); return; } /* if at least one path is online, configure the rest asynchronously */ if (nonline_paths(cct) > 0) { rw_exit(&vhcache->vhcache_lock); config_client_paths_async(vhc, ct_name, ct_addr, pp_head, &tok); return; } rw_exit(&vhcache->vhcache_lock); for (pp = pp_head; pp != NULL; pp = pp->phys_path_next) { if (bus_config_one_phci_child(pp->phys_path) == MDI_SUCCESS) { rw_enter(&vhcache->vhcache_lock, RW_READER); if ((cct = lookup_vhcache_client(vhcache, ct_name, ct_addr, &tok)) == NULL) { rw_exit(&vhcache->vhcache_lock); goto out; } if (nonline_paths(cct) > 0 && pp->phys_path_next != NULL) { rw_exit(&vhcache->vhcache_lock); config_client_paths_async(vhc, ct_name, ct_addr, pp->phys_path_next, &tok); pp->phys_path_next = NULL; goto out; } rw_exit(&vhcache->vhcache_lock); } } adjust_sort_vhcache_paths(vhc, ct_name, ct_addr, &tok); out: free_phclient_path_list(pp_head); } static void single_threaded_vhconfig_enter(mdi_vhci_config_t *vhc) { mutex_enter(&vhc->vhc_lock); while (vhc->vhc_flags & MDI_VHC_SINGLE_THREADED) cv_wait(&vhc->vhc_cv, &vhc->vhc_lock); vhc->vhc_flags |= MDI_VHC_SINGLE_THREADED; mutex_exit(&vhc->vhc_lock); } static void single_threaded_vhconfig_exit(mdi_vhci_config_t *vhc) { mutex_enter(&vhc->vhc_lock); vhc->vhc_flags &= ~MDI_VHC_SINGLE_THREADED; cv_broadcast(&vhc->vhc_cv); mutex_exit(&vhc->vhc_lock); } typedef struct mdi_phci_driver_info { char *phdriver_name; /* name of the phci driver */ /* set to non zero if the phci driver supports root device */ int phdriver_root_support; } mdi_phci_driver_info_t; /* * vhci class and root support capability of a phci driver can be * specified using ddi-vhci-class and ddi-no-root-support properties in the * phci driver.conf file. The built-in tables below contain this information * for those phci drivers whose driver.conf files don't yet contain this info. * * All phci drivers expect iscsi have root device support. */ static mdi_phci_driver_info_t scsi_phci_driver_list[] = { { "fp", 1 }, { "iscsi", 0 }, { "ibsrp", 1 } }; static mdi_phci_driver_info_t ib_phci_driver_list[] = { "tavor", 1 }; static void * mdi_realloc(void *old_ptr, size_t old_size, size_t new_size) { void *new_ptr; new_ptr = kmem_zalloc(new_size, KM_SLEEP); if (old_ptr) { bcopy(old_ptr, new_ptr, MIN(old_size, new_size)); kmem_free(old_ptr, old_size); } return (new_ptr); } static void add_to_phci_list(char ***driver_list, int **root_support_list, int *cur_elements, int *max_elements, char *driver_name, int root_support) { ASSERT(*cur_elements <= *max_elements); if (*cur_elements == *max_elements) { *max_elements += 10; *driver_list = mdi_realloc(*driver_list, sizeof (char *) * (*cur_elements), sizeof (char *) * (*max_elements)); *root_support_list = mdi_realloc(*root_support_list, sizeof (int) * (*cur_elements), sizeof (int) * (*max_elements)); } (*driver_list)[*cur_elements] = i_ddi_strdup(driver_name, KM_SLEEP); (*root_support_list)[*cur_elements] = root_support; (*cur_elements)++; } static void get_phci_driver_list(char *vhci_class, char ***driver_list, int **root_support_list, int *cur_elements, int *max_elements) { mdi_phci_driver_info_t *st_driver_list, *p; int st_ndrivers, root_support, i, j, driver_conf_count; major_t m; struct devnames *dnp; ddi_prop_t *propp; *driver_list = NULL; *root_support_list = NULL; *cur_elements = 0; *max_elements = 0; /* add the phci drivers derived from the phci driver.conf files */ for (m = 0; m < devcnt; m++) { dnp = &devnamesp[m]; if (dnp->dn_flags & DN_PHCI_DRIVER) { LOCK_DEV_OPS(&dnp->dn_lock); if (dnp->dn_global_prop_ptr != NULL && (propp = i_ddi_prop_search(DDI_DEV_T_ANY, DDI_VHCI_CLASS, DDI_PROP_TYPE_STRING, &dnp->dn_global_prop_ptr->prop_list)) != NULL && strcmp(propp->prop_val, vhci_class) == 0) { root_support = (i_ddi_prop_search(DDI_DEV_T_ANY, DDI_NO_ROOT_SUPPORT, DDI_PROP_TYPE_INT, &dnp->dn_global_prop_ptr->prop_list) == NULL) ? 1 : 0; add_to_phci_list(driver_list, root_support_list, cur_elements, max_elements, dnp->dn_name, root_support); UNLOCK_DEV_OPS(&dnp->dn_lock); } else UNLOCK_DEV_OPS(&dnp->dn_lock); } } driver_conf_count = *cur_elements; /* add the phci drivers specified in the built-in tables */ if (strcmp(vhci_class, MDI_HCI_CLASS_SCSI) == 0) { st_driver_list = scsi_phci_driver_list; st_ndrivers = sizeof (scsi_phci_driver_list) / sizeof (mdi_phci_driver_info_t); } else if (strcmp(vhci_class, MDI_HCI_CLASS_IB) == 0) { st_driver_list = ib_phci_driver_list; st_ndrivers = sizeof (ib_phci_driver_list) / sizeof (mdi_phci_driver_info_t); } else { st_driver_list = NULL; st_ndrivers = 0; } for (i = 0, p = st_driver_list; i < st_ndrivers; i++, p++) { /* add this phci driver if not already added before */ for (j = 0; j < driver_conf_count; j++) { if (strcmp((*driver_list)[j], p->phdriver_name) == 0) break; } if (j == driver_conf_count) { add_to_phci_list(driver_list, root_support_list, cur_elements, max_elements, p->phdriver_name, p->phdriver_root_support); } } } /* * Attach the phci driver instances associated with the specified vhci class. * If root is mounted attach all phci driver instances. * If root is not mounted, attach the instances of only those phci * drivers that have the root support. */ static void attach_phci_drivers(char *vhci_class) { char **driver_list, **p; int *root_support_list; int cur_elements, max_elements, i; major_t m; get_phci_driver_list(vhci_class, &driver_list, &root_support_list, &cur_elements, &max_elements); for (i = 0; i < cur_elements; i++) { if (modrootloaded || root_support_list[i]) { m = ddi_name_to_major(driver_list[i]); if (m != DDI_MAJOR_T_NONE && ddi_hold_installed_driver(m)) ddi_rele_driver(m); } } if (driver_list) { for (i = 0, p = driver_list; i < cur_elements; i++, p++) kmem_free(*p, strlen(*p) + 1); kmem_free(driver_list, sizeof (char *) * max_elements); kmem_free(root_support_list, sizeof (int) * max_elements); } } /* * Build vhci cache: * * Attach phci driver instances and then drive BUS_CONFIG_ALL on * the phci driver instances. During this process the cache gets built. * * Cache is built fully if the root is mounted. * If the root is not mounted, phci drivers that do not have root support * are not attached. As a result the cache is built partially. The entries * in the cache reflect only those phci drivers that have root support. */ static int build_vhci_cache(mdi_vhci_t *vh) { mdi_vhci_config_t *vhc = vh->vh_config; mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; single_threaded_vhconfig_enter(vhc); rw_enter(&vhcache->vhcache_lock, RW_READER); if (vhcache->vhcache_flags & MDI_VHCI_CACHE_SETUP_DONE) { rw_exit(&vhcache->vhcache_lock); single_threaded_vhconfig_exit(vhc); return (0); } rw_exit(&vhcache->vhcache_lock); attach_phci_drivers(vh->vh_class); bus_config_all_phcis(vhcache, NDI_DRV_CONF_REPROBE | NDI_NO_EVENT, BUS_CONFIG_ALL, DDI_MAJOR_T_NONE); rw_enter(&vhcache->vhcache_lock, RW_WRITER); vhcache->vhcache_flags |= MDI_VHCI_CACHE_SETUP_DONE; rw_exit(&vhcache->vhcache_lock); single_threaded_vhconfig_exit(vhc); vhcache_dirty(vhc); return (1); } /* * Determine if discovery of paths is needed. */ static int vhcache_do_discovery(mdi_vhci_config_t *vhc) { int rv = 1; mutex_enter(&vhc->vhc_lock); if (i_ddi_io_initialized() == 0) { if (vhc->vhc_path_discovery_boot > 0) { vhc->vhc_path_discovery_boot--; goto out; } } else { if (vhc->vhc_path_discovery_postboot > 0) { vhc->vhc_path_discovery_postboot--; goto out; } } /* * Do full path discovery at most once per mdi_path_discovery_interval. * This is to avoid a series of full path discoveries when opening * stale /dev/[r]dsk links. */ if (mdi_path_discovery_interval != -1 && lbolt64 >= vhc->vhc_path_discovery_cutoff_time) goto out; rv = 0; out: mutex_exit(&vhc->vhc_lock); return (rv); } /* * Discover all paths: * * Attach phci driver instances and then drive BUS_CONFIG_ALL on all the phci * driver instances. During this process all paths will be discovered. */ static int vhcache_discover_paths(mdi_vhci_t *vh) { mdi_vhci_config_t *vhc = vh->vh_config; mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; int rv = 0; single_threaded_vhconfig_enter(vhc); if (vhcache_do_discovery(vhc)) { attach_phci_drivers(vh->vh_class); bus_config_all_phcis(vhcache, NDI_DRV_CONF_REPROBE | NDI_NO_EVENT, BUS_CONFIG_ALL, DDI_MAJOR_T_NONE); mutex_enter(&vhc->vhc_lock); vhc->vhc_path_discovery_cutoff_time = lbolt64 + mdi_path_discovery_interval * TICKS_PER_SECOND; mutex_exit(&vhc->vhc_lock); rv = 1; } single_threaded_vhconfig_exit(vhc); return (rv); } /* * Generic vhci bus config implementation: * * Parameters * vdip vhci dip * flags bus config flags * op bus config operation * The remaining parameters are bus config operation specific * * for BUS_CONFIG_ONE * arg pointer to name@addr * child upon successful return from this function, *child will be * set to the configured and held devinfo child node of vdip. * ct_addr pointer to client address (i.e. GUID) * * for BUS_CONFIG_DRIVER * arg major number of the driver * child and ct_addr parameters are ignored * * for BUS_CONFIG_ALL * arg, child, and ct_addr parameters are ignored * * Note that for the rest of the bus config operations, this function simply * calls the framework provided default bus config routine. */ int mdi_vhci_bus_config(dev_info_t *vdip, uint_t flags, ddi_bus_config_op_t op, void *arg, dev_info_t **child, char *ct_addr) { mdi_vhci_t *vh = i_devi_get_vhci(vdip); mdi_vhci_config_t *vhc = vh->vh_config; mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; int rv = 0; int params_valid = 0; char *cp; /* * To bus config vhcis we relay operation, possibly using another * thread, to phcis. The phci driver then interacts with MDI to cause * vhci child nodes to be enumerated under the vhci node. Adding a * vhci child requires an ndi_devi_enter of the vhci. Since another * thread may be adding the child, to avoid deadlock we can't wait * for the relayed operations to complete if we have already entered * the vhci node. */ if (DEVI_BUSY_OWNED(vdip)) { MDI_DEBUG(2, (CE_NOTE, vdip, "!MDI: vhci bus config: " "vhci dip is busy owned %p\n", (void *)vdip)); goto default_bus_config; } rw_enter(&vhcache->vhcache_lock, RW_READER); if (!(vhcache->vhcache_flags & MDI_VHCI_CACHE_SETUP_DONE)) { rw_exit(&vhcache->vhcache_lock); rv = build_vhci_cache(vh); rw_enter(&vhcache->vhcache_lock, RW_READER); } switch (op) { case BUS_CONFIG_ONE: if (arg != NULL && ct_addr != NULL) { /* extract node name */ cp = (char *)arg; while (*cp != '\0' && *cp != '@') cp++; if (*cp == '@') { params_valid = 1; *cp = '\0'; config_client_paths(vhc, (char *)arg, ct_addr); /* config_client_paths() releases cache_lock */ *cp = '@'; break; } } rw_exit(&vhcache->vhcache_lock); break; case BUS_CONFIG_DRIVER: rw_exit(&vhcache->vhcache_lock); if (rv == 0) st_bus_config_all_phcis(vhc, flags, op, (major_t)(uintptr_t)arg); break; case BUS_CONFIG_ALL: rw_exit(&vhcache->vhcache_lock); if (rv == 0) st_bus_config_all_phcis(vhc, flags, op, -1); break; default: rw_exit(&vhcache->vhcache_lock); break; } default_bus_config: /* * All requested child nodes are enumerated under the vhci. * Now configure them. */ if (ndi_busop_bus_config(vdip, flags, op, arg, child, 0) == NDI_SUCCESS) { return (MDI_SUCCESS); } else if (op == BUS_CONFIG_ONE && rv == 0 && params_valid) { /* discover all paths and try configuring again */ if (vhcache_discover_paths(vh) && ndi_busop_bus_config(vdip, flags, op, arg, child, 0) == NDI_SUCCESS) return (MDI_SUCCESS); } return (MDI_FAILURE); } /* * Read the on-disk vhci cache into an nvlist for the specified vhci class. */ static nvlist_t * read_on_disk_vhci_cache(char *vhci_class) { nvlist_t *nvl; int err; char *filename; filename = vhclass2vhcache_filename(vhci_class); if ((err = fread_nvlist(filename, &nvl)) == 0) { kmem_free(filename, strlen(filename) + 1); return (nvl); } else if (err == EIO) cmn_err(CE_WARN, "%s: I/O error, will recreate\n", filename); else if (err == EINVAL) cmn_err(CE_WARN, "%s: data file corrupted, will recreate\n", filename); kmem_free(filename, strlen(filename) + 1); return (NULL); } /* * Read on-disk vhci cache into nvlists for all vhci classes. * Called during booting by i_ddi_read_devices_files(). */ void mdi_read_devices_files(void) { int i; for (i = 0; i < N_VHCI_CLASSES; i++) vhcache_nvl[i] = read_on_disk_vhci_cache(vhci_class_list[i]); } /* * Remove all stale entries from vhci cache. */ static void clean_vhcache(mdi_vhci_config_t *vhc) { mdi_vhci_cache_t *vhcache = &vhc->vhc_vhcache; mdi_vhcache_phci_t *cphci, *cphci_head, *cphci_next; mdi_vhcache_client_t *cct, *cct_head, *cct_next; mdi_vhcache_pathinfo_t *cpi, *cpi_head, *cpi_next; rw_enter(&vhcache->vhcache_lock, RW_WRITER); cct_head = vhcache->vhcache_client_head; vhcache->vhcache_client_head = vhcache->vhcache_client_tail = NULL; for (cct = cct_head; cct != NULL; cct = cct_next) { cct_next = cct->cct_next; cpi_head = cct->cct_cpi_head; cct->cct_cpi_head = cct->cct_cpi_tail = NULL; for (cpi = cpi_head; cpi != NULL; cpi = cpi_next) { cpi_next = cpi->cpi_next; if (cpi->cpi_pip != NULL) { ASSERT(cpi->cpi_cphci->cphci_phci != NULL); enqueue_tail_vhcache_pathinfo(cct, cpi); } else free_vhcache_pathinfo(cpi); } if (cct->cct_cpi_head != NULL) enqueue_vhcache_client(vhcache, cct); else { (void) mod_hash_destroy(vhcache->vhcache_client_hash, (mod_hash_key_t)cct->cct_name_addr); free_vhcache_client(cct); } } cphci_head = vhcache->vhcache_phci_head; vhcache->vhcache_phci_head = vhcache->vhcache_phci_tail = NULL; for (cphci = cphci_head; cphci != NULL; cphci = cphci_next) { cphci_next = cphci->cphci_next; if (cphci->cphci_phci != NULL) enqueue_vhcache_phci(vhcache, cphci); else free_vhcache_phci(cphci); } vhcache->vhcache_clean_time = lbolt64; rw_exit(&vhcache->vhcache_lock); vhcache_dirty(vhc); } /* * Remove all stale entries from vhci cache. * Called by i_ddi_clean_devices_files() during the execution of devfsadm -C */ void mdi_clean_vhcache(void) { mdi_vhci_t *vh; mutex_enter(&mdi_mutex); for (vh = mdi_vhci_head; vh != NULL; vh = vh->vh_next) { vh->vh_refcnt++; mutex_exit(&mdi_mutex); clean_vhcache(vh->vh_config); mutex_enter(&mdi_mutex); vh->vh_refcnt--; } mutex_exit(&mdi_mutex); } /* * mdi_vhci_walk_clients(): * Walker routine to traverse client dev_info nodes * ddi_walk_devs(ddi_get_child(vdip), f, arg) returns the entire tree * below the client, including nexus devices, which we dont want. * So we just traverse the immediate siblings, starting from 1st client. */ void mdi_vhci_walk_clients(dev_info_t *vdip, int (*f)(dev_info_t *, void *), void *arg) { mdi_vhci_t *vh = i_devi_get_vhci(vdip); dev_info_t *cdip; mdi_client_t *ct; MDI_VHCI_CLIENT_LOCK(vh); cdip = ddi_get_child(vdip); while (cdip) { ct = i_devi_get_client(cdip); MDI_CLIENT_LOCK(ct); if (((*f)(cdip, arg)) == DDI_WALK_CONTINUE) cdip = ddi_get_next_sibling(cdip); else cdip = NULL; MDI_CLIENT_UNLOCK(ct); } MDI_VHCI_CLIENT_UNLOCK(vh); } /* * mdi_vhci_walk_phcis(): * Walker routine to traverse phci dev_info nodes */ void mdi_vhci_walk_phcis(dev_info_t *vdip, int (*f)(dev_info_t *, void *), void *arg) { mdi_vhci_t *vh = i_devi_get_vhci(vdip); mdi_phci_t *ph, *next; MDI_VHCI_PHCI_LOCK(vh); ph = vh->vh_phci_head; while (ph) { MDI_PHCI_LOCK(ph); if (((*f)(ph->ph_dip, arg)) == DDI_WALK_CONTINUE) next = ph->ph_next; else next = NULL; MDI_PHCI_UNLOCK(ph); ph = next; } MDI_VHCI_PHCI_UNLOCK(vh); } /* * mdi_walk_vhcis(): * Walker routine to traverse vhci dev_info nodes */ void mdi_walk_vhcis(int (*f)(dev_info_t *, void *), void *arg) { mdi_vhci_t *vh = NULL; mutex_enter(&mdi_mutex); /* * Scan for already registered vhci */ for (vh = mdi_vhci_head; vh != NULL; vh = vh->vh_next) { vh->vh_refcnt++; mutex_exit(&mdi_mutex); if (((*f)(vh->vh_dip, arg)) != DDI_WALK_CONTINUE) { mutex_enter(&mdi_mutex); vh->vh_refcnt--; break; } else { mutex_enter(&mdi_mutex); vh->vh_refcnt--; } } mutex_exit(&mdi_mutex); } /* * i_mdi_log_sysevent(): * Logs events for pickup by syseventd */ static void i_mdi_log_sysevent(dev_info_t *dip, char *ph_vh_class, char *subclass) { char *path_name; nvlist_t *attr_list; if (nvlist_alloc(&attr_list, NV_UNIQUE_NAME_TYPE, KM_SLEEP) != DDI_SUCCESS) { goto alloc_failed; } path_name = kmem_zalloc(MAXPATHLEN, KM_SLEEP); (void) ddi_pathname(dip, path_name); if (nvlist_add_string(attr_list, DDI_DRIVER_NAME, ddi_driver_name(dip)) != DDI_SUCCESS) { goto error; } if (nvlist_add_int32(attr_list, DDI_DRIVER_MAJOR, (int32_t)ddi_driver_major(dip)) != DDI_SUCCESS) { goto error; } if (nvlist_add_int32(attr_list, DDI_INSTANCE, (int32_t)ddi_get_instance(dip)) != DDI_SUCCESS) { goto error; } if (nvlist_add_string(attr_list, DDI_PATHNAME, path_name) != DDI_SUCCESS) { goto error; } if (nvlist_add_string(attr_list, DDI_CLASS, ph_vh_class) != DDI_SUCCESS) { goto error; } (void) ddi_log_sysevent(dip, DDI_VENDOR_SUNW, EC_DDI, subclass, attr_list, NULL, DDI_SLEEP); error: kmem_free(path_name, MAXPATHLEN); nvlist_free(attr_list); return; alloc_failed: MDI_DEBUG(1, (CE_WARN, dip, "!i_mdi_log_sysevent: Unable to send sysevent")); } char ** mdi_get_phci_driver_list(char *vhci_class, int *ndrivers) { char **driver_list, **ret_driver_list = NULL; int *root_support_list; int cur_elements, max_elements; get_phci_driver_list(vhci_class, &driver_list, &root_support_list, &cur_elements, &max_elements); if (driver_list) { kmem_free(root_support_list, sizeof (int) * max_elements); ret_driver_list = mdi_realloc(driver_list, sizeof (char *) * max_elements, sizeof (char *) * cur_elements); } *ndrivers = cur_elements; return (ret_driver_list); } void mdi_free_phci_driver_list(char **driver_list, int ndrivers) { char **p; int i; if (driver_list) { for (i = 0, p = driver_list; i < ndrivers; i++, p++) kmem_free(*p, strlen(*p) + 1); kmem_free(driver_list, sizeof (char *) * ndrivers); } }