svm_rcm.c revision 648495d6a097a39eaebc7e56d25f2463ff3bba65
/*
* 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.
*/
#pragma ident "%Z%%M% %I% %E% SMI"
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <sys/types.h>
#include <errno.h>
#include <meta.h>
#include <sys/lvm/mdio.h>
#include <sys/lvm/md_sp.h>
#include <sdssc.h>
#include "rcm_module.h"
/*
* This module is the RCM Module for SVM. The policy adopted by this module
* is to block offline requests for any SVM resource that is in use. A
* resource is considered to be in use if it contains a metadb or if it is
* a non-errored component of a metadevice that is open.
*
* The module uses the library libmeta to access the current state of the
* metadevices. On entry, and when svm_register() is called, the module
* builds a cache of all of the SVM resources and their dependencies. Each
* metadevice has an entry of type deventry_t which is accessed by a hash
* function. When the cache is built each SVM resource is registered with
* the RCM framework. The check_device code path uses meta_invalidate_name to
* ensure that the caching in libmeta will not conflict with the cache
* we build within this code.
*
* When an RCM operation occurs that affects a registered SVM resource, the RCM
* framework will call the appropriate routine in this module. The cache
* entry will be found and if the resource has dependants, a callback will
* be made into the RCM framework to pass the request on to the dependants,
* which may themselves by SVM resources.
*
* Locking:
* The cache is protected by a mutex
*/
/*
* Private constants
*/
/*
* Generic Messages
*/
#define MSG_UNRECOGNIZED gettext("SVM: \"%s\" is not a SVM resource")
#define MSG_NODEPS gettext("SVM: can't find dependents")
#define MSG_NORECACHE gettext("SVM: WARNING: couldn't re-cache.")
#define MSG_OPENERR gettext("SVM: can't open \"%s\"")
#define MSG_CACHEFAIL gettext("SVM: can't malloc cache")
#define ERR_UNRECOGNIZED gettext("unrecognized SVM resource")
#define ERR_NODEPS gettext("can't find SVM resource dependents")
/*
* Macros to produce a quoted string containing the value of a preprocessor
* macro. For example, if SIZE is defined to be 256, VAL2STR(SIZE) is "256".
* This is used to construct format strings for scanf-family functions below.
*/
#define QUOTE(x) #x
#define VAL2STR(x) QUOTE(x)
typedef enum {
SVM_SLICE = 0,
SVM_STRIPE,
SVM_CONCAT,
SVM_MIRROR,
SVM_RAID,
SVM_TRANS,
SVM_SOFTPART,
SVM_HS
} svm_type_t;
/* Hash table parameters */
#define HASH_DEFAULT 251
/* Hot spare pool users */
typedef struct hspuser {
struct hspuser *next; /* next user */
char *hspusername; /* name */
dev_t hspuserkey; /* key */
} hspuser_t;
/* Hot spare pool entry */
typedef struct hspentry {
struct hspentry *link; /* link through all hsp entries */
struct hspentry *next; /* next hsp entry for a slice */
char *hspname; /* name */
hspuser_t *hspuser; /* first hsp user */
} hspentry_t;
/* Hash table entry */
typedef struct deventry {
struct deventry *next; /* next entry with same hash */
svm_type_t devtype; /* device type */
dev_t devkey; /* key */
char *devname; /* name in /dev */
char *devicesname; /* name in /devices */
struct deventry *dependent; /* 1st dependent */
struct deventry *next_dep; /* next dependent */
struct deventry *antecedent; /* antecedent */
hspentry_t *hsp_list; /* list of hot spare pools */
int flags; /* flags */
} deventry_t;
/* flag values */
#define REMOVED 0x1
#define IN_HSP 0x2
#define TRANS_LOG 0x4
#define CONT_SOFTPART 0x8
#define CONT_METADB 0x10
/*
* Device redundancy flags. If the device can be removed from the
* metadevice configuration then it is considered a redundant device,
* otherwise not.
*/
#define NOTINDEVICE -1
#define NOTREDUNDANT 0
#define REDUNDANT 1
/* Cache */
typedef struct cache {
deventry_t **hashline; /* hash table */
int32_t size; /* sizer of hash table */
uint32_t registered; /* cache regsitered */
} cache_t;
/*
* Forward declarations of private functions
*/
static int svm_register(rcm_handle_t *hd);
static int svm_unregister(rcm_handle_t *hd);
static int svm_unregister_device(rcm_handle_t *hd, deventry_t *d);
static deventry_t *cache_dependent(cache_t *cache, char *devname, int devflags,
deventry_t *dependents);
static deventry_t *cache_device(cache_t *cache, char *devname,
svm_type_t devtype, md_dev64_t devkey, int devflags);
static hspentry_t *find_hsp(char *hspname);
static hspuser_t *add_hsp_user(char *hspname, deventry_t *deventry);
static hspentry_t *add_hsp(char *hspname, deventry_t *deventry);
static void free_names(mdnamelist_t *nlp);
static int cache_all_devices(cache_t *cache);
static int cache_hsp(cache_t *cache, mdhspnamelist_t *nlp, md_hsp_t *hsp);
static int cache_trans(cache_t *cache, mdnamelist_t *nlp, md_trans_t *trans);
static int cache_mirror(cache_t *cache, mdnamelist_t *nlp,
md_mirror_t *mirror);
static int cache_raid(cache_t *cache, mdnamelist_t *nlp, md_raid_t *raid);
static int cache_stripe(cache_t *cache, mdnamelist_t *nlp,
md_stripe_t *stripe);
static int cache_sp(cache_t *cache, mdnamelist_t *nlp, md_sp_t *soft_part);
static int cache_all_devices_in_set(cache_t *cache, mdsetname_t *sp);
static cache_t *create_cache();
static deventry_t *create_deventry(char *devname, svm_type_t devtype,
md_dev64_t devkey, int devflags);
static void cache_remove(cache_t *cache, deventry_t *deventry);
static deventry_t *cache_lookup(cache_t *cache, char *devname);
static void cache_sync(rcm_handle_t *hd, cache_t **cachep);
static char *cache_walk(cache_t *cache, uint32_t *i, deventry_t **hashline);
static void free_cache(cache_t **cache);
static void free_deventry(deventry_t **deventry);
static uint32_t hash(uint32_t h, char *s);
static void svm_register_device(rcm_handle_t *hd, char *devname);
static int add_dep(int *ndeps, char ***depsp, deventry_t *deventry);
static int get_dependents(deventry_t *deventry, char *** dependentsp);
char *add_to_usage(char ** usagep, char *string);
char *add_to_usage_fmt(char **usagep, char *fmt, char *string);
static int is_open(dev_t devkey);
static int svm_offline(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags,
char **errorp, rcm_info_t **infop);
static int svm_online(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags,
char **errorp, rcm_info_t **infop);
static int svm_get_info(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags,
char **usagep, char **errorp, nvlist_t *props, rcm_info_t **infop);
static int svm_suspend(rcm_handle_t *hd, char *rsrc, id_t id,
timespec_t *interval, uint_t flags, char **errorp,
rcm_info_t **infop);
static int svm_resume(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags,
char **errorp, rcm_info_t **infop);
static int svm_remove(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags,
char **errorp, rcm_info_t **infop);
static int check_device(deventry_t *deventry);
static int check_mirror(mdsetname_t *sp, mdname_t *np, md_error_t *ep);
/*
* Module-Private data
*/
static struct rcm_mod_ops svm_ops =
{
RCM_MOD_OPS_VERSION,
svm_register,
svm_unregister,
svm_get_info,
svm_suspend,
svm_resume,
svm_offline,
svm_online,
svm_remove,
NULL,
NULL,
NULL
};
static cache_t *svm_cache = NULL;
static mutex_t svm_cache_lock;
static hspentry_t *hsp_head = NULL;
/*
* Module Interface Routines
*/
/*
* rcm_mod_init()
*
* Create a cache, and return the ops structure.
* Input: None
* Return: rcm_mod_ops structure
*/
struct rcm_mod_ops *
rcm_mod_init()
{
/* initialize the lock mutex */
if (mutex_init(&svm_cache_lock, USYNC_THREAD, NULL)) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't init mutex"));
return (NULL);
}
/* need to initialize the cluster library to avoid seg faults */
if (sdssc_bind_library() == SDSSC_ERROR) {
rcm_log_message(RCM_ERROR,
gettext("SVM: Interface error with libsds_sc.so,"
" aborting."));
return (NULL);
}
/* Create a cache */
if ((svm_cache = create_cache()) == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: module can't function, aborting."));
return (NULL);
}
/* Return the ops vectors */
return (&svm_ops);
}
/*
* rcm_mod_info()
*
* Return a string describing this module.
* Input: None
* Return: String
* Locking: None
*/
const char *
rcm_mod_info()
{
return (gettext("Solaris Volume Manager module 1.9"));
}
/*
* rcm_mod_fini()
*
* Destroy the cache and mutex
* Input: None
* Return: RCM_SUCCESS
* Locking: None
*/
int
rcm_mod_fini()
{
(void) mutex_lock(&svm_cache_lock);
if (svm_cache) {
free_cache(&svm_cache);
}
(void) mutex_unlock(&svm_cache_lock);
(void) mutex_destroy(&svm_cache_lock);
return (RCM_SUCCESS);
}
/*
* svm_register()
*
* Make sure the cache is properly sync'ed, and its registrations are in
* order.
*
* Input:
* rcm_handle_t *hd
* Return:
* RCM_SUCCESS
* Locking: the cache is locked throughout the execution of this routine
* because it reads and possibly modifies cache links continuously.
*/
static int
svm_register(rcm_handle_t *hd)
{
uint32_t i = 0;
deventry_t *l = NULL;
char *devicename;
rcm_log_message(RCM_TRACE1, "SVM: register\n");
/* Guard against bad arguments */
assert(hd != NULL);
/* Lock the cache */
(void) mutex_lock(&svm_cache_lock);
/* If the cache has already been registered, then just sync it. */
if (svm_cache && svm_cache->registered) {
cache_sync(hd, &svm_cache);
(void) mutex_unlock(&svm_cache_lock);
return (RCM_SUCCESS);
}
/* If not, register the whole cache and mark it as registered. */
while ((devicename = cache_walk(svm_cache, &i, &l)) != NULL) {
svm_register_device(hd, devicename);
}
svm_cache->registered = 1;
/* Unlock the cache */
(void) mutex_unlock(&svm_cache_lock);
return (RCM_SUCCESS);
}
/*
* svm_unregister()
*
* Manually walk through the cache, unregistering all the special files and
* mount points.
*
* Input:
* rcm_handle_t *hd
* Return:
* RCM_SUCCESS
* Locking: the cache is locked throughout the execution of this routine
* because it reads and modifies cache links continuously.
*/
static int
svm_unregister(rcm_handle_t *hd)
{
deventry_t *l = NULL;
uint32_t i = 0;
rcm_log_message(RCM_TRACE1, "SVM: unregister\n");
/* Guard against bad arguments */
assert(hd != NULL);
/* Walk the cache, unregistering everything */
(void) mutex_lock(&svm_cache_lock);
if (svm_cache != NULL) {
while (cache_walk(svm_cache, &i, &l) != NULL) {
(void) svm_unregister_device(hd, l);
}
svm_cache->registered = 0;
}
(void) mutex_unlock(&svm_cache_lock);
return (RCM_SUCCESS);
}
/*
* svm_offline()
*
* Determine dependents of the resource being offlined, and offline
* them all.
*
* Input:
* rcm_handle_t *hd handle
* char* *rsrc resource name
* id_t id 0
* char **errorp ptr to error message
* rcm_info_t **infop ptr to info string
* Output:
* char **errorp pass back error message
* Return:
* int RCM_SUCCESS or RCM_FAILURE
* Locking: the cache is locked for most of this routine, except while
* processing dependents.
*/
/*ARGSUSED*/
static int
svm_offline(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags,
char **errorp, rcm_info_t **infop)
{
int rv = RCM_SUCCESS;
int ret;
char **dependents;
deventry_t *deventry;
hspentry_t *hspentry;
hspuser_t *hspuser;
/* Guard against bad arguments */
assert(hd != NULL);
assert(rsrc != NULL);
assert(id == (id_t)0);
assert(errorp != NULL);
/* Trace */
rcm_log_message(RCM_TRACE1, "SVM: offline(%s), flags(%d)\n",
rsrc, flags);
/* Lock the cache */
(void) mutex_lock(&svm_cache_lock);
/* Lookup the resource in the cache. */
if ((deventry = cache_lookup(svm_cache, rsrc)) == NULL) {
rcm_log_message(RCM_ERROR, MSG_UNRECOGNIZED);
*errorp = strdup(ERR_UNRECOGNIZED);
(void) mutex_unlock(&svm_cache_lock);
rv = RCM_FAILURE;
rcm_log_message(RCM_TRACE1, "SVM: svm_offline(%s) exit %d\n",
rsrc, rv);
return (rv);
}
/* If it is a TRANS device, do not allow the offline */
if (deventry->devtype == SVM_TRANS) {
rv = RCM_FAILURE;
(void) mutex_unlock(&svm_cache_lock);
goto exit;
}
if (deventry->flags&IN_HSP) {
/*
* If this is in a hot spare pool, check to see
* if any of the hot spare pool users are open
*/
hspentry = deventry->hsp_list;
while (hspentry) {
hspuser = hspentry->hspuser;
while (hspuser) {
/* Check if open */
if (is_open(hspuser->hspuserkey)) {
rv = RCM_FAILURE;
(void) mutex_unlock(&svm_cache_lock);
goto exit;
}
hspuser = hspuser->next;
}
hspentry = hspentry->next;
}
}
/* Fail if the device contains a metadb replica */
if (deventry->flags&CONT_METADB) {
/*
* The user should delete the replica before continuing,
* so force the error.
*/
rcm_log_message(RCM_TRACE1, "SVM: %s has a replica\n",
deventry->devname);
rv = RCM_FAILURE;
(void) mutex_unlock(&svm_cache_lock);
goto exit;
}
/* Get dependents */
if (get_dependents(deventry, &dependents) != 0) {
rcm_log_message(RCM_ERROR, MSG_NODEPS);
rv = RCM_FAILURE;
(void) mutex_unlock(&svm_cache_lock);
goto exit;
}
if (dependents) {
/* Check if the device is broken (needs maintanence). */
if (check_device(deventry) == REDUNDANT) {
/*
* The device is broken, the offline request should
* succeed, so ignore any of the dependents.
*/
rcm_log_message(RCM_TRACE1,
"SVM: ignoring dependents\n");
(void) mutex_unlock(&svm_cache_lock);
free(dependents);
goto exit;
}
(void) mutex_unlock(&svm_cache_lock);
ret = rcm_request_offline_list(hd, dependents, flags, infop);
if (ret != RCM_SUCCESS) {
rv = ret;
}
free(dependents);
} else {
/* If no dependents, check if the metadevice is open */
if ((deventry->devkey) && (is_open(deventry->devkey))) {
rv = RCM_FAILURE;
(void) mutex_unlock(&svm_cache_lock);
goto exit;
}
(void) mutex_unlock(&svm_cache_lock);
}
exit:
rcm_log_message(RCM_TRACE1, "SVM: svm_offline(%s) exit %d\n", rsrc, rv);
if (rv != RCM_SUCCESS)
*errorp = strdup(gettext("unable to offline"));
return (rv);
}
/*
* svm_online()
*
* Just pass the online notification on to the dependents of this resource
*
* Input:
* rcm_handle_t *hd handle
* char* *rsrc resource name
* id_t id 0
* char **errorp ptr to error message
* rcm_info_t **infop ptr to info string
* Output:
* char **errorp pass back error message
* Return:
* int RCM_SUCCESS or RCM_FAILURE
* Locking: the cache is locked for most of this routine, except while
* processing dependents.
*/
/*ARGSUSED*/
static int
svm_online(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags, char **errorp,
rcm_info_t **infop)
{
int rv = RCM_SUCCESS;
char **dependents;
deventry_t *deventry;
/* Guard against bad arguments */
assert(hd != NULL);
assert(rsrc != NULL);
assert(id == (id_t)0);
/* Trace */
rcm_log_message(RCM_TRACE1, "SVM: online(%s)\n", rsrc);
/* Lookup this resource in the cache (cache gets locked) */
(void) mutex_lock(&svm_cache_lock);
deventry = cache_lookup(svm_cache, rsrc);
if (deventry == NULL) {
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_ERROR, MSG_UNRECOGNIZED, rsrc);
*errorp = strdup(ERR_UNRECOGNIZED);
return (RCM_FAILURE);
}
/* Get dependents */
if (get_dependents(deventry, &dependents) != 0) {
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_ERROR, MSG_NODEPS);
*errorp = strdup(ERR_NODEPS);
return (RCM_FAILURE);
}
(void) mutex_unlock(&svm_cache_lock);
if (dependents) {
rv = rcm_notify_online_list(hd, dependents, flags, infop);
if (rv != RCM_SUCCESS)
*errorp = strdup(gettext("unable to online"));
free(dependents);
}
return (rv);
}
/*
* svm_get_info()
*
* Gather usage information for this resource.
*
* Input:
* rcm_handle_t *hd handle
* char* *rsrc resource name
* id_t id 0
* char **errorp ptr to error message
* nvlist_t *props Not used
* rcm_info_t **infop ptr to info string
* Output:
* char **infop pass back info string
* Return:
* int RCM_SUCCESS or RCM_FAILURE
* Locking: the cache is locked throughout the whole function
*/
/*ARGSUSED*/
static int
svm_get_info(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags, char **usagep,
char **errorp, nvlist_t *props, rcm_info_t **infop)
{
int rv = RCM_SUCCESS;
deventry_t *deventry;
deventry_t *dependent;
hspentry_t *hspentry;
char **dependents;
/* Guard against bad arguments */
assert(hd != NULL);
assert(rsrc != NULL);
assert(id == (id_t)0);
assert(usagep != NULL);
assert(errorp != NULL);
/* Trace */
rcm_log_message(RCM_TRACE1, "SVM: get_info(%s)\n", rsrc);
/* Lookup this resource in the cache (cache gets locked) */
(void) mutex_lock(&svm_cache_lock);
deventry = cache_lookup(svm_cache, rsrc);
if (deventry == NULL) {
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_ERROR, MSG_UNRECOGNIZED, rsrc);
*errorp = strdup(ERR_UNRECOGNIZED);
return (RCM_FAILURE);
}
*usagep = NULL; /* Initialise usage string */
if (deventry->flags&CONT_METADB) {
*usagep = add_to_usage(usagep, gettext("contains metadb(s)"));
}
if (deventry->flags&CONT_SOFTPART) {
*usagep = add_to_usage(usagep,
gettext("contains soft partition(s)"));
}
if (deventry->devtype == SVM_SOFTPART) {
*usagep = add_to_usage_fmt(usagep,
gettext("soft partition based on \"%s\""),
deventry->antecedent->devname);
}
if (deventry->flags&IN_HSP) {
int hspflag = 0;
hspentry = deventry->hsp_list;
while (hspentry) {
if (hspflag == 0) {
*usagep = add_to_usage(usagep,
gettext("member of hot spare pool"));
hspflag = 1;
}
*usagep = add_to_usage_fmt(usagep, "\"%s\"",
hspentry->hspname);
hspentry = hspentry->next;
}
} else {
dependent = deventry->dependent;
while (dependent) {
/* Resource has dependents */
switch (dependent->devtype) {
case SVM_STRIPE:
*usagep = add_to_usage_fmt(usagep,
gettext("component of stripe \"%s\""),
dependent->devname);
break;
case SVM_CONCAT:
*usagep = add_to_usage_fmt(usagep,
gettext("component of concat \"%s\""),
dependent->devname);
break;
case SVM_MIRROR:
*usagep = add_to_usage_fmt(usagep,
gettext("submirror of \"%s\""),
dependent->devname);
break;
case SVM_RAID:
*usagep = add_to_usage_fmt(usagep,
gettext("component of RAID \"%s\""),
dependent->devname);
break;
case SVM_TRANS:
if (deventry->flags&TRANS_LOG) {
*usagep = add_to_usage_fmt(usagep,
gettext("trans log for \"%s\""),
dependent->devname);
} else {
*usagep = add_to_usage_fmt(usagep,
gettext("trans master for \"%s\""),
dependent->devname);
}
break;
case SVM_SOFTPART:
/* Contains soft parts, already processed */
break;
default:
rcm_log_message(RCM_ERROR,
gettext("Unknown type %d\n"),
dependent->devtype);
}
dependent = dependent->next_dep;
}
}
/* Get dependents and recurse if necessary */
if (get_dependents(deventry, &dependents) != 0) {
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_ERROR, MSG_NODEPS);
*errorp = strdup(ERR_NODEPS);
return (RCM_FAILURE);
}
(void) mutex_unlock(&svm_cache_lock);
if ((flags & RCM_INCLUDE_DEPENDENT) && (dependents != NULL)) {
rv = rcm_get_info_list(hd, dependents, flags, infop);
if (rv != RCM_SUCCESS)
*errorp = strdup(gettext("unable to get info"));
}
free(dependents);
if (*usagep != NULL)
rcm_log_message(RCM_TRACE1, "SVM: usage = %s\n", *usagep);
return (rv);
}
/*
* svm_suspend()
*
* Notify all dependents that the resource is being suspended.
* Since no real operation is involved, QUERY or not doesn't matter.
*
* Input:
* rcm_handle_t *hd handle
* char* *rsrc resource name
* id_t id 0
* char **errorp ptr to error message
* rcm_info_t **infop ptr to info string
* Output:
* char **errorp pass back error message
* Return:
* int RCM_SUCCESS or RCM_FAILURE
* Locking: the cache is locked for most of this routine, except while
* processing dependents.
*/
static int
svm_suspend(rcm_handle_t *hd, char *rsrc, id_t id, timespec_t *interval,
uint_t flags, char **errorp, rcm_info_t **infop)
{
int rv = RCM_SUCCESS;
deventry_t *deventry;
char **dependents;
/* Guard against bad arguments */
assert(hd != NULL);
assert(rsrc != NULL);
assert(id == (id_t)0);
assert(interval != NULL);
assert(errorp != NULL);
/* Trace */
rcm_log_message(RCM_TRACE1, "SVM: suspend(%s)\n", rsrc);
/* Lock the cache and extract information about this resource. */
(void) mutex_lock(&svm_cache_lock);
if ((deventry = cache_lookup(svm_cache, rsrc)) == NULL) {
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_ERROR, MSG_UNRECOGNIZED, rsrc);
*errorp = strdup(ERR_UNRECOGNIZED);
return (RCM_SUCCESS);
}
/* Get dependents */
if (get_dependents(deventry, &dependents) != 0) {
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_ERROR, MSG_NODEPS);
*errorp = strdup(ERR_NODEPS);
return (RCM_FAILURE);
}
(void) mutex_unlock(&svm_cache_lock);
if (dependents) {
rv = rcm_request_suspend_list(hd, dependents, flags,
interval, infop);
if (rv != RCM_SUCCESS)
*errorp = strdup(gettext("unable to suspend"));
free(dependents);
}
return (rv);
}
/*
* svm_resume()
*
* Notify all dependents that the resource is being resumed.
*
* Input:
* rcm_handle_t *hd handle
* char* *rsrc resource name
* id_t id 0
* char **errorp ptr to error message
* rcm_info_t **infop ptr to info string
* Output:
* char **errorp pass back error message
* Return:
* int RCM_SUCCESS or RCM_FAILURE
* Locking: the cache is locked for most of this routine, except while
* processing dependents.
*
*/
static int
svm_resume(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags, char **errorp,
rcm_info_t **infop)
{
int rv = RCM_SUCCESS;
deventry_t *deventry;
char **dependents;
/* Guard against bad arguments */
assert(hd != NULL);
assert(rsrc != NULL);
assert(id == (id_t)0);
assert(errorp != NULL);
/* Trace */
rcm_log_message(RCM_TRACE1, "SVM: resume(%s)\n", rsrc);
/*
* Lock the cache just long enough to extract information about this
* resource.
*/
(void) mutex_lock(&svm_cache_lock);
if ((deventry = cache_lookup(svm_cache, rsrc)) == NULL) {
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_ERROR, MSG_UNRECOGNIZED, rsrc);
*errorp = strdup(ERR_UNRECOGNIZED);
return (RCM_SUCCESS);
}
/* Get dependents */
if (get_dependents(deventry, &dependents) != 0) {
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_ERROR, MSG_NODEPS);
*errorp = strdup(ERR_NODEPS);
return (RCM_FAILURE);
}
(void) mutex_unlock(&svm_cache_lock);
if (dependents) {
rv = rcm_notify_resume_list(hd, dependents, flags, infop);
if (rv != RCM_SUCCESS)
*errorp = strdup(gettext("unable to resume"));
free(dependents);
}
return (rv);
}
/*
* svm_remove()
*
* Remove the resource from the cache and notify all dependents that
* the resource has been removed.
*
* Input:
* rcm_handle_t *hd handle
* char* *rsrc resource name
* id_t id 0
* char **errorp ptr to error message
* rcm_info_t **infop ptr to info string
* Output:
* char **errorp pass back error message
* Return:
* int RCM_SUCCESS or RCM_FAILURE
* Locking: the cache is locked for most of this routine, except while
* processing dependents.
*/
static int
svm_remove(rcm_handle_t *hd, char *rsrc, id_t id, uint_t flags, char **errorp,
rcm_info_t **infop)
{
int rv = RCM_SUCCESS;
char **dependents;
deventry_t *deventry;
/* Guard against bad arguments */
assert(hd != NULL);
assert(rsrc != NULL);
assert(id == (id_t)0);
/* Trace */
rcm_log_message(RCM_TRACE1, "SVM: svm_remove(%s)\n", rsrc);
/* Lock the cache while removing resource */
(void) mutex_lock(&svm_cache_lock);
if ((deventry = cache_lookup(svm_cache, rsrc)) == NULL) {
(void) mutex_unlock(&svm_cache_lock);
return (RCM_SUCCESS);
}
/* Get dependents */
if (get_dependents(deventry, &dependents) != 0) {
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_ERROR, MSG_NODEPS);
deventry->flags |= REMOVED;
*errorp = strdup(ERR_NODEPS);
return (RCM_FAILURE);
}
if (dependents) {
(void) mutex_unlock(&svm_cache_lock);
rv = rcm_notify_remove_list(hd, dependents, flags, infop);
(void) mutex_lock(&svm_cache_lock);
if (rv != RCM_SUCCESS)
*errorp = strdup(gettext("unable to remove"));
free(dependents);
}
/* Mark entry as removed */
deventry->flags |= REMOVED;
(void) mutex_unlock(&svm_cache_lock);
rcm_log_message(RCM_TRACE1, "SVM: exit svm_remove(%s)\n", rsrc);
/* Clean up and return success */
return (RCM_SUCCESS);
}
/*
* Definitions of private functions
*
*/
/*
* find_hsp()
*
* Find the hot spare entry from the linked list of all hotspare pools
*
* Input:
* char *hspname name of hot spare pool
* Return:
* hspentry_t hot spare entry
*/
static hspentry_t *
find_hsp(char *hspname)
{
hspentry_t *hspentry = hsp_head;
while (hspentry) {
if (strcmp(hspname, hspentry->hspname) == 0)
return (hspentry);
hspentry = hspentry->link;
}
return (NULL);
}
/*
* add_hsp_user()
*
* Add a hot spare pool user to the list for the hsp specfied by
* hspname. The memory allocated here will be freed by free_cache()
*
* Input:
* char *hspname hot spare pool name
* deventry_t *deventry specified hsp user
* Return:
* hspuser_t entry in hsp user list
*/
static hspuser_t *
add_hsp_user(char *hspname, deventry_t *deventry)
{
hspuser_t *newhspuser;
char *newhspusername;
hspuser_t *previous;
hspentry_t *hspentry;
hspentry = find_hsp(hspname);
if (hspentry == NULL)
return (NULL);
rcm_log_message(RCM_TRACE1, "SVM: Enter add_hsp_user %s, %x, %x\n",
hspname, hspentry, hspentry->hspuser);
newhspuser = (hspuser_t *)malloc(sizeof (*newhspuser));
if (newhspuser == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't malloc hspuser"));
return (NULL);
}
(void) memset((char *)newhspuser, 0, sizeof (*newhspuser));
newhspusername = strdup(deventry->devname);
if (newhspusername == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't malloc hspusername"));
free(newhspuser);
return (NULL);
}
newhspuser->hspusername = newhspusername;
newhspuser->hspuserkey = deventry->devkey;
if ((previous = hspentry->hspuser) == NULL) {
hspentry->hspuser = newhspuser;
} else {
hspuser_t *temp = previous->next;
previous->next = newhspuser;
newhspuser->next = temp;
}
rcm_log_message(RCM_TRACE1, "SVM: Added hsp_user %s (dev %x) to %s\n",
newhspusername, newhspuser->hspuserkey, hspname);
return (newhspuser);
}
/*
* add_hsp()
*
* Add a hot spare pool entry to the list for the slice, deventry.
* Also add to the linked list of all hsp pools
* The memory alllocated here will be freed by free_cache()
*
* Input:
* char *hspname name of hsp pool entry
* deventry_t *deventry device entry for the slice
* Return:
* hspentry_t end of hsp list
* Locking: None
*/
static hspentry_t *
add_hsp(char *hspname, deventry_t *deventry)
{
hspentry_t *newhspentry;
hspentry_t *previous;
char *newhspname;
rcm_log_message(RCM_TRACE1, "SVM: Enter add_hsp %s\n",
hspname);
newhspentry = (hspentry_t *)malloc(sizeof (*newhspentry));
if (newhspentry == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't malloc hspentry"));
return (NULL);
}
(void) memset((char *)newhspentry, 0, sizeof (*newhspentry));
newhspname = strdup(hspname);
if (newhspname == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't malloc hspname"));
free(newhspentry);
return (NULL);
}
newhspentry->hspname = newhspname;
/* Add to linked list of all hotspare pools */
newhspentry->link = hsp_head;
hsp_head = newhspentry;
/* Add to list of hotspare pools containing this slice */
if ((previous = deventry->hsp_list) == NULL) {
deventry->hsp_list = newhspentry;
} else {
hspentry_t *temp = previous->next;
previous->next = newhspentry;
newhspentry->next = temp;
}
rcm_log_message(RCM_TRACE1, "SVM: Exit add_hsp %s\n",
hspname);
return (newhspentry);
}
/*
* cache_dependent()
*
* Add a dependent for a deventry to the cache and return the cache entry
* If the name is not in the cache, we assume that it a SLICE. If it
* turns out to be any other type of metadevice, when it is processed
* in cache_all_devices_in_set(), cache_device() will be called to
* set the type to the actual value.
*
* Input:
* cache_t *cache cache
* char *devname metadevice name
* int devflags metadevice flags
* deventry_t *dependent dependent of this metadevice
* Return:
* deventry_t metadevice entry added to cache
* Locking: None
*/
static deventry_t *
cache_dependent(cache_t *cache, char *devname, int devflags,
deventry_t *dependent)
{
deventry_t *newdeventry = NULL;
deventry_t *hashprev = NULL;
deventry_t *deventry = NULL;
deventry_t *previous = NULL;
uint32_t hash_index;
int comp;
rcm_log_message(RCM_TRACE1, "SVM: Enter cache_dep %s, %x, %s\n",
devname, devflags, dependent->devname);
hash_index = hash(cache->size, devname);
if (hash_index >= cache->size) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't hash device."));
return (NULL);
}
deventry = cache->hashline[hash_index];
/* if the hash table slot is empty, then this is easy */
if (deventry == NULL) {
deventry = create_deventry(devname, SVM_SLICE, 0, devflags);
cache->hashline[hash_index] = deventry;
} else {
/* if the hash table slot isn't empty, find the immediate successor */
hashprev = NULL;
while ((comp = strcmp(deventry->devname, devname)) < 0 &&
deventry->next != NULL) {
hashprev = deventry;
deventry = deventry->next;
}
if (comp == 0) {
/* if already in cache, just update the flags */
deventry->flags |= devflags;
} else {
/* insert the entry if it's not already there */
if ((newdeventry = create_deventry(devname,
SVM_SLICE, 0, devflags)) == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't create hash line."));
return (NULL);
}
if (comp > 0) {
newdeventry->next = deventry;
if (hashprev)
hashprev->next = newdeventry;
else
cache->hashline[hash_index] =
newdeventry;
} else if (comp < 0) {
newdeventry->next = deventry->next;
deventry->next = newdeventry;
}
deventry = newdeventry;
}
}
/* complete deventry by linking the dependent to it */
dependent->antecedent = deventry;
if ((previous = deventry->dependent) != NULL) {
deventry_t *temp = previous->next_dep;
previous->next_dep = dependent;
dependent->next_dep = temp;
} else deventry->dependent = dependent;
return (deventry);
}
/*
* cache_device()
*
* Add an entry to the cache for devname
*
* Input:
* cache_t *cache cache
* char *devname metadevice named
* svm_type_t devtype metadevice type
* md_dev64_t devkey dev_t of device
* int devflags device flags
* Return:
* deventry_t metadevice added to cache
* Locking: None
*/
static deventry_t *
cache_device(cache_t *cache, char *devname, svm_type_t devtype,
md_dev64_t devkey, int devflags)
{
deventry_t *newdeventry = NULL;
deventry_t *previous = NULL;
deventry_t *deventry = NULL;
uint32_t hash_index;
int comp;
rcm_log_message(RCM_TRACE1, "SVM: Enter cache_device %s, %x, %lx, %x\n",
devname, devtype, devkey, devflags);
hash_index = hash(cache->size, devname);
if (hash_index >= cache->size) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't hash device."));
return (NULL);
}
deventry = cache->hashline[hash_index];
/* if the hash table slot is empty, then this is easy */
if (deventry == NULL) {
deventry = create_deventry(devname, devtype, devkey,
devflags);
cache->hashline[hash_index] = deventry;
} else {
/* if the hash table slot isn't empty, find the immediate successor */
previous = NULL;
while ((comp = strcmp(deventry->devname, devname)) < 0 &&
deventry->next != NULL) {
previous = deventry;
deventry = deventry->next;
}
if (comp == 0) {
/*
* If entry already exists, just set the type, key
* and flags
*/
deventry->devtype = devtype;
deventry->devkey = meta_cmpldev(devkey);
deventry->flags |= devflags;
} else {
/* insert the entry if it's not already there */
if ((newdeventry = create_deventry(devname, devtype,
devkey, devflags)) == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't create hash line."));
}
if (comp > 0) {
newdeventry->next = deventry;
if (previous)
previous->next = newdeventry;
else
cache->hashline[hash_index] =
newdeventry;
} else if (comp < 0) {
newdeventry->next = deventry->next;
deventry->next = newdeventry;
}
deventry = newdeventry;
}
}
return (deventry);
}
/*
* free_names()
*
* Free all name list entries
*
* Input:
* mdnamelist_t *np namelist pointer
* Return: None
*/
static void
free_names(mdnamelist_t *nlp)
{
mdnamelist_t *p;
for (p = nlp; p != NULL; p = p->next) {
meta_invalidate_name(p->namep);
p->namep = NULL;
}
metafreenamelist(nlp);
}
/*
* cache_hsp()
*
* Add an entry to the cache for each slice in the hot spare
* pool. Call add_hsp() to add the hot spare pool to the list
* of all hot spare pools.
*
* Input:
* cache_t *cache cache
* mdnamelist_t *nlp pointer to hsp name
* md_hsp_t *hsp
* Return:
* 0 if successful or error code
*/
static int
cache_hsp(cache_t *cache, mdhspnamelist_t *nlp, md_hsp_t *hsp)
{
int i;
deventry_t *deventry;
md_hs_t *hs;
for (i = 0; i < hsp->hotspares.hotspares_len; i++) {
hs = &hsp->hotspares.hotspares_val[i];
if ((deventry = cache_device(cache, hs->hsnamep->bname,
SVM_SLICE, hs->hsnamep->dev,
IN_HSP)) == NULL) {
return (ENOMEM);
}
if (add_hsp(nlp->hspnamep->hspname, deventry) == NULL) {
return (ENOMEM);
}
}
return (0);
}
/*
* cache_trans()
*
* Add an entry to the cache for trans metadevice, the master
* and the log. Call cache_dependent() to link that master and
* the log to the trans metadevice.
*
* Input:
* cache_t *cache cache
* mdnamelist_t *nlp pointer to trans name
* md_trans_t *trans
* Return:
* 0 if successful or error code
*
*/
static int
cache_trans(cache_t *cache, mdnamelist_t *nlp, md_trans_t *trans)
{
deventry_t *antecedent;
if ((antecedent = cache_device(cache, nlp->namep->bname, SVM_TRANS,
nlp->namep->dev, 0)) == NULL) {
return (ENOMEM);
}
if (cache_device(cache, trans->masternamep->bname, SVM_SLICE,
trans->masternamep->dev, 0) == NULL) {
return (ENOMEM);
}
if (cache_dependent(cache, trans->masternamep->bname, 0,
antecedent) == NULL) {
return (ENOMEM);
}
if (trans->lognamep != NULL) {
if (cache_device(cache, trans->lognamep->bname, SVM_SLICE,
trans->lognamep->dev, TRANS_LOG) == NULL) {
return (ENOMEM);
}
if (cache_dependent(cache, trans->lognamep->bname, 0,
antecedent) == NULL) {
return (ENOMEM);
}
}
return (0);
}
/*
* cache_mirror()
*
* Add an entry to the cache for the mirror. For each
* submirror, call cache_dependent() to add an entry to the
* cache and to link it to mirror entry.
*
* Input:
* cache_t *cache cache
* mdnamelist_t *nlp pointer to mirror name
* md_mirror_t *mirror
* Return:
* 0 if successful or error code
*
*/
static int
cache_mirror(cache_t *cache, mdnamelist_t *nlp, md_mirror_t *mirror)
{
int i;
deventry_t *antecedent;
if ((antecedent = cache_device(cache, nlp->namep->bname, SVM_MIRROR,
nlp->namep->dev, 0)) == NULL) {
return (ENOMEM);
}
for (i = 0; i < NMIRROR; i++) {
md_submirror_t *submirror;
submirror = &mirror->submirrors[i];
if (submirror->state == SMS_UNUSED)
continue;
if (!submirror->submirnamep)
continue;
if (cache_dependent(cache, submirror->submirnamep->bname,
0, antecedent) == NULL) {
return (ENOMEM);
}
}
return (0);
}
/*
* cache_raid()
*
* Add an entry to the cache for the RAID metadevice. For
* each component of the RAID call cache_dependent() to add
* add it to the cache and to link it to the RAID metadevice.
*
* Input:
* cache_t *cache cache
* mdnamelist_t *nlp pointer to raid name
* md_raid_t *raid mirror
* Return:
* 0 if successful or error code
*/
static int
cache_raid(cache_t *cache, mdnamelist_t *nlp, md_raid_t *raid)
{
int i;
deventry_t *antecedent;
if ((antecedent = cache_device(cache, nlp->namep->bname, SVM_RAID,
nlp->namep->dev, 0)) == NULL) {
return (ENOMEM);
}
if (raid->hspnamep) {
if (add_hsp_user(raid->hspnamep->hspname,
antecedent) == NULL) {
return (ENOMEM);
}
}
for (i = 0; i < raid->cols.cols_len; i++) {
if (cache_dependent(cache,
raid->cols.cols_val[i].colnamep->bname, 0,
antecedent) == NULL) {
return (ENOMEM);
}
}
return (0);
}
/*
* cache_stripe()
*
* Add a CONCAT or a STRIPE entry entry to the cache for the
* metadevice and call cache_dependent() to add each
* component to the cache.
*
* Input:
* cache_t *cache cache
* mdnamelist_t *nlp pointer to stripe name
* md_stripe_t *stripe
* Return:
* 0 if successful or error code
*
*/
static int
cache_stripe(cache_t *cache, mdnamelist_t *nlp, md_stripe_t *stripe)
{
int i;
deventry_t *antecedent;
if ((antecedent = cache_device(cache, nlp->namep->bname, SVM_CONCAT,
nlp->namep->dev, 0)) == NULL) {
return (ENOMEM);
}
if (stripe->hspnamep) {
if (add_hsp_user(stripe->hspnamep->hspname,
antecedent) == NULL) {
return (ENOMEM);
}
}
for (i = 0; i < stripe->rows.rows_len; i++) {
md_row_t *rowp;
int j;
rowp = &stripe->rows.rows_val[i];
if (stripe->rows.rows_len == 1 && rowp->comps.comps_len > 1) {
if ((void*) cache_device(cache, nlp->namep->bname,
SVM_STRIPE, nlp->namep->dev, 0) == NULL)
return (ENOMEM);
}
for (j = 0; j < rowp->comps.comps_len; j++) {
md_comp_t *component;
component = &rowp->comps.comps_val[j];
if (cache_dependent(cache,
component->compnamep->bname, 0,
antecedent) == NULL) {
return (ENOMEM);
}
}
}
return (0);
}
/*
* cache_sp()
*
* Add an entry to the cache for the softpart and also call
* cache_dependent() to set the CONT_SOFTPART flag in the
* cache entry for the metadevice that contains the softpart.
*
* Input:
* cache_t *cache cache
* mdnamelist_t *nlp pointer to soft part name
* md_sp_t *soft_part
* Return:
* 0 if successful or error code
*
*/
static int
cache_sp(cache_t *cache, mdnamelist_t *nlp, md_sp_t *soft_part)
{
deventry_t *antecedent;
if ((antecedent = cache_device(cache, nlp->namep->bname,
SVM_SOFTPART, nlp->namep->dev, 0)) == NULL) {
return (ENOMEM);
}
if (cache_dependent(cache, soft_part->compnamep->bname,
CONT_SOFTPART, antecedent) == NULL) {
return (ENOMEM);
}
return (0);
}
/*
* cache_all_devices_in_set()
*
* Add all of the metadevices and mddb replicas in the set to the
* cache
*
* Input:
* cache_t *cache cache
* mdsetname_t *sp setname
* Return:
* 0 if successful or error code
*/
static int
cache_all_devices_in_set(cache_t *cache, mdsetname_t *sp)
{
md_error_t error = mdnullerror;
md_replicalist_t *replica_list = NULL;
md_replicalist_t *mdbp;
mdnamelist_t *nlp;
mdnamelist_t *trans_list = NULL;
mdnamelist_t *mirror_list = NULL;
mdnamelist_t *raid_list = NULL;
mdnamelist_t *stripe_list = NULL;
mdnamelist_t *sp_list = NULL;
mdhspnamelist_t *hsp_list = NULL;
rcm_log_message(RCM_TRACE1, "SVM: cache_all_devices_in_set\n");
/* Add each mddb replica to the cache */
if (metareplicalist(sp, MD_BASICNAME_OK, &replica_list, &error) < 0) {
/* there are no metadb's; that is ok, no need to check the rest */
mdclrerror(&error);
return (0);
}
for (mdbp = replica_list; mdbp != NULL; mdbp = mdbp->rl_next) {
if (cache_device(cache, mdbp->rl_repp->r_namep->bname,
SVM_SLICE, mdbp->rl_repp->r_namep->dev,
CONT_METADB) == NULL) {
metafreereplicalist(replica_list);
return (ENOMEM);
}
}
metafreereplicalist(replica_list);
/* Process Hot Spare pools */
if (meta_get_hsp_names(sp, &hsp_list, 0, &error) >= 0) {
mdhspnamelist_t *nlp;
for (nlp = hsp_list; nlp != NULL; nlp = nlp->next) {
md_hsp_t *hsp;
hsp = meta_get_hsp(sp, nlp->hspnamep, &error);
if (hsp != NULL) {
if (cache_hsp(cache, nlp, hsp) != 0) {
metafreehspnamelist(hsp_list);
return (ENOMEM);
}
}
meta_invalidate_hsp(nlp->hspnamep);
}
metafreehspnamelist(hsp_list);
}
/* Process Trans devices */
if (meta_get_trans_names(sp, &trans_list, 0, &error) >= 0) {
for (nlp = trans_list; nlp != NULL; nlp = nlp->next) {
mdname_t *mdn;
md_trans_t *trans;
mdn = metaname(&sp, nlp->namep->cname, META_DEVICE,
&error);
if (mdn == NULL) {
continue;
}
trans = meta_get_trans(sp, mdn, &error);
if (trans != NULL && trans->masternamep != NULL) {
if (cache_trans(cache, nlp, trans) != NULL) {
free_names(trans_list);
return (ENOMEM);
}
}
}
free_names(trans_list);
}
/* Process Mirrors */
if (meta_get_mirror_names(sp, &mirror_list, 0, &error) >= 0) {
for (nlp = mirror_list; nlp != NULL; nlp = nlp->next) {
mdname_t *mdn;
md_mirror_t *mirror;
mdn = metaname(&sp, nlp->namep->cname, META_DEVICE,
&error);
if (mdn == NULL) {
continue;
}
mirror = meta_get_mirror(sp, mdn, &error);
if (mirror != NULL) {
if (cache_mirror(cache, nlp, mirror) != 0) {
free_names(mirror_list);
return (ENOMEM);
}
}
}
free_names(mirror_list);
}
/* Process Raid devices */
if (meta_get_raid_names(sp, &raid_list, 0, &error) >= 0) {
for (nlp = raid_list; nlp != NULL; nlp = nlp->next) {
mdname_t *mdn;
md_raid_t *raid;
mdn = metaname(&sp, nlp->namep->cname, META_DEVICE,
&error);
if (mdn == NULL) {
continue;
}
raid = meta_get_raid(sp, mdn, &error);
if (raid != NULL) {
if (cache_raid(cache, nlp, raid) != 0) {
free_names(raid_list);
return (ENOMEM);
}
}
}
free_names(raid_list);
}
/* Process Slices */
if (meta_get_stripe_names(sp, &stripe_list, 0, &error) >= 0) {
for (nlp = stripe_list; nlp != NULL; nlp = nlp->next) {
mdname_t *mdn;
md_stripe_t *stripe;
mdn = metaname(&sp, nlp->namep->cname, META_DEVICE,
&error);
if (mdn == NULL) {
continue;
}
stripe = meta_get_stripe(sp, mdn, &error);
if (stripe != NULL) {
if (cache_stripe(cache, nlp, stripe) != 0) {
free_names(stripe_list);
return (ENOMEM);
}
}
}
free_names(stripe_list);
}
/* Process Soft partitions */
if (meta_get_sp_names(sp, &sp_list, 0, &error) >= 0) {
for (nlp = sp_list; nlp != NULL; nlp = nlp->next) {
mdname_t *mdn;
md_sp_t *soft_part;
mdn = metaname(&sp, nlp->namep->cname, META_DEVICE,
&error);
if (mdn == NULL) {
continue;
}
soft_part = meta_get_sp(sp, mdn, &error);
if (soft_part != NULL) {
if (cache_sp(cache, nlp, soft_part) != 0) {
free_names(sp_list);
return (ENOMEM);
}
}
}
free_names(sp_list);
}
mdclrerror(&error);
return (0);
}
/*
* create_all_devices()
*
* Cache all devices in all sets
*
* Input:
* cache_t cache
* Return:
* 0 if successful, error code if not
* Locking: None
*/
static int
cache_all_devices(cache_t *cache)
{
int max_sets;
md_error_t error = mdnullerror;
int i;
if ((max_sets = get_max_sets(&error)) == 0) {
return (0);
}
if (!mdisok(&error)) {
mdclrerror(&error);
return (0);
}
rcm_log_message(RCM_TRACE1,
"SVM: cache_all_devices,max sets = %d\n", max_sets);
/* for each possible set number, see if we really have a diskset */
for (i = 0; i < max_sets; i++) {
mdsetname_t *sp;
if ((sp = metasetnosetname(i, &error)) == NULL) {
rcm_log_message(RCM_TRACE1,
"SVM: cache_all_devices no set: setno %d\n", i);
if (!mdisok(&error) &&
((error.info.errclass == MDEC_RPC) ||
(mdiserror(&error, MDE_SMF_NO_SERVICE)))) {
/*
* metad rpc program not available
* - no metasets. metad rpc not available
* is indicated either by an RPC error or
* the fact that the service is not
* enabled.
*/
break;
}
continue;
}
if (cache_all_devices_in_set(cache, sp)) {
metaflushsetname(sp);
return (ENOMEM);
}
metaflushsetname(sp);
}
mdclrerror(&error);
rcm_log_message(RCM_TRACE1, "SVM: exit cache_all_devices\n");
return (0);
}
/*
* create_cache()
*
* Create an empty cache
* If the function fails free_cache() will be called to free any
* allocated memory.
*
* Input: None
* Return:
* cache_t cache created
* Locking: None
*/
static cache_t *
create_cache()
{
cache_t *cache;
uint32_t size;
int ret;
size = HASH_DEFAULT;
/* try allocating storage for a new, empty cache */
if ((cache = (cache_t *)malloc(sizeof (cache_t))) == NULL) {
rcm_log_message(RCM_ERROR, MSG_CACHEFAIL);
return (NULL);
}
(void) memset((char *)cache, 0, sizeof (*cache));
cache->hashline = (deventry_t **)calloc(size, sizeof (deventry_t *));
if (cache->hashline == NULL) {
rcm_log_message(RCM_ERROR, MSG_CACHEFAIL);
free(cache);
return (NULL);
}
cache->size = size;
/* Initialise linked list of hsp entries */
hsp_head = NULL;
/* add entries to cache */
ret = cache_all_devices(cache);
if (ret != 0) {
free_cache(&cache);
return (NULL);
}
/* Mark the cache as new */
cache->registered = 0;
/* Finished - return the new cache */
return (cache);
}
/*
* create_deventry()
*
* Create a new deventry entry for device with name devname
* The memory alllocated here will be freed by free_cache()
*
* Input:
* char *devname device name
* svm_type_t devtype metadevice type
* md_dev64_t devkey device key
* int devflags device flags
* Return:
* deventry_t New deventry
* Locking: None
*/
static deventry_t *
create_deventry(char *devname, svm_type_t devtype, md_dev64_t devkey,
int devflags)
{
const char *devprefix = "/dev/";
deventry_t *newdeventry = NULL;
char *newdevname = NULL;
char *devicesname = NULL;
newdeventry = (deventry_t *)malloc(sizeof (*newdeventry));
if (newdeventry == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't malloc deventrys"));
goto errout;
}
(void) memset((char *)newdeventry, 0, sizeof (*newdeventry));
newdevname = strdup(devname);
if (newdevname == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't malloc devname"));
goto errout;
}
/*
* When we register interest in a name starting with /dev/, RCM
* will use realpath to convert the name to a /devices name before
* storing it. metaclear removes both the /dev and the /devices
* form of the name of a metadevice from the file system. Thus,
* when we later call rcm_unregister_interest to get rid of a
* metacleared device, RCM will not be able to derive the /devices
* name for the /dev name. Thus, to unregister we will need to use
* the /devices name. We will save it now, so that we have it when
* it comes time to unregister.
*/
if (strncmp(devname, devprefix, strlen(devprefix)) == 0) {
devicesname = (char *)malloc(PATH_MAX);
if (devicesname == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't malloc PATH_MAX bytes"));
goto errout;
}
if (realpath(devname, devicesname) == NULL) {
free(devicesname);
devicesname = NULL;
}
}
newdeventry->devname = newdevname;
newdeventry->devicesname = devicesname;
newdeventry->devtype = devtype;
newdeventry->devkey = meta_cmpldev(devkey);
newdeventry->flags = devflags;
if (newdeventry->devicesname == NULL) {
rcm_log_message(RCM_TRACE1,
"SVM created deventry for %s\n", newdeventry->devname);
} else {
rcm_log_message(RCM_TRACE1,
"SVM created deventry for %s (%s)\n",
newdeventry->devname, newdeventry->devicesname);
}
return (newdeventry);
errout:
if (devicesname != NULL)
free(devicesname);
if (newdevname != NULL)
free(newdevname);
if (newdeventry != NULL)
free(newdeventry);
return (NULL);
}
/*
* cache_remove()
*
* Given a cache and a deventry, the deventry is
* removed from the cache's tables and memory for the deventry is
* free'ed.
*
* Input:
* cache_t *cache cache
* deventry_t *deventry deventry to be removed
* Return: None
* Locking: The cache must be locked by the caller prior to calling
* this routine.
*/
static void
cache_remove(cache_t *cache, deventry_t *deventry)
{
deventry_t *olddeventry;
deventry_t *previous;
hspentry_t *hspentry;
hspentry_t *oldhspentry;
hspuser_t *hspuser;
hspuser_t *oldhspuser;
uint32_t hash_index;
/* sanity check */
if (cache == NULL || deventry == NULL || deventry->devname == NULL)
return;
/* If this is in the hash table, remove it from there */
hash_index = hash(cache->size, deventry->devname);
if (hash_index >= cache->size) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't hash device."));
return;
}
olddeventry = cache->hashline[hash_index];
previous = NULL;
while (olddeventry) {
if (olddeventry->devname &&
strcmp(olddeventry->devname, deventry->devname) == 0) {
break;
}
previous = olddeventry;
olddeventry = olddeventry->next;
}
if (olddeventry) {
if (previous)
previous->next = olddeventry->next;
else
cache->hashline[hash_index] = olddeventry->next;
if (olddeventry->flags&IN_HSP) {
/*
* If this is in a hot spare pool, remove the list
* of hot spare pools that it is in along with
* all of the volumes that are users of the pool
*/
hspentry = olddeventry->hsp_list;
while (hspentry) {
oldhspentry = hspentry;
hspuser = hspentry->hspuser;
while (hspuser) {
oldhspuser = hspuser;
free(hspuser->hspusername);
hspuser = hspuser->next;
free(oldhspuser);
}
free(hspentry->hspname);
hspentry = hspentry->next;
free(oldhspentry);
}
}
free(olddeventry->devname);
free(olddeventry);
}
}
/*
* cache_lookup()
*
* Return the deventry corresponding to devname from the cache
* Input:
* cache_t cache cache
* char *devname name to lookup in cache
* Return:
* deventry_t deventry of name, NULL if not found
* Locking: cache lock held on entry and on exit
*/
static deventry_t *
cache_lookup(cache_t *cache, char *devname)
{
int comp;
uint32_t hash_index;
deventry_t *deventry;
hash_index = hash(cache->size, devname);
if (hash_index >= cache->size) {
rcm_log_message(RCM_ERROR,
gettext("SVM: can't hash resource."));
return (NULL);
}
deventry = cache->hashline[hash_index];
while (deventry) {
comp = strcmp(deventry->devname, devname);
if (comp == 0)
return (deventry);
if (comp > 0)
return (NULL);
deventry = deventry->next;
}
return (NULL);
}
/*
* cache_sync()
*
* Resync cache with the svm database. First a new cache is created
* that represents the current state of the SVM database. The
* function walks the new cache to look for new entries that must be
* registered. The new entries are kept in a list, because we cannot
* register them at this point. Entries that appear in both caches
* are removed from the old cache. Because of this at the end of the
* walk, the old cache will only contain devices that have been
* removed and need to be unregistered.
*
* Next the old cache is walked, so that we can unregister the devices
* that are no longer present.
*
* Finally, we process the list of new devices that must be
* registered. There is a reason why we must unregister the removed
* (metacleared) devices before registering the new ones. It has to
* do with the fact that rcm_register_interest calls realpath(3C) to
* convert a /dev name to a /devices name. It uses the /devices name
* for storing the device information.
*
* It can happen that between cache_syncs that the administrator
* metaclears one metadevice and metacreates a new one. For example,
*
* metaclear acct
* metainit engr 1 1 c1t12d0s0
*
* The metaclear operation frees up the minor number that was being
* used by acct. The metainit operation can then reuse the minor
* number. This means that both metadevices would have the same
* /devices name even though they had different /dev names. Since
* rcm_register_interest uses /devices names for storing records, we
* need to unregister acct before registering engr. Otherwise we
* would get an EALREADY errno and a failed registration. This is why
* cache_sync creates a list of devices to be registered after all the
* removed devices have been unregistered.
*
* Input:
* rcm_handle_t *hd rcm handle
* cache_t **cachep pointer to cache
* Return:
* cache_t **cachep pointer to new cache
* Return: None
* Locking: The cache must be locked prior to entry
*/
static void
cache_sync(rcm_handle_t *hd, cache_t **cachep)
{
char *devicename;
deventry_t *deventry;
cache_t *new_cache;
cache_t *old_cache = *cachep;
deventry_t *hashline = NULL;
deventry_t **register_list = NULL;
deventry_t *register_this;
uint32_t register_count = 0; /* # entrys in register_list */
uint32_t allocated = 0; /* # entrys allocated in */
/* register_list */
uint32_t allocate_incr = 16;
uint32_t i = 0;
/* Get a new cache */
if ((new_cache = create_cache()) == NULL) {
rcm_log_message(RCM_WARNING, MSG_NORECACHE);
return;
}
/* For every entry in the new cache... */
while ((devicename = cache_walk(new_cache, &i, &hashline)) != NULL) {
register_this = NULL;
/* Look for this entry in the old cache */
deventry = cache_lookup(old_cache, devicename);
/*
* If no entry in old cache, register the resource. If there
* is an entry, but it is marked as removed, register it
* again and remove it from the old cache
*/
if (deventry == NULL) {
register_this = hashline;
} else {
if (deventry->flags&REMOVED)
register_this = hashline;
cache_remove(old_cache, deventry);
}
/* Save this entry if we need to register it later. */
if (register_this) {
if (register_count >= allocated) {
/* Need to extend our array */
allocated += allocate_incr;
register_list =
(deventry_t **)realloc(register_list,
allocated * sizeof (*register_list));
if (register_list == NULL) {
/* Out of memory. Give up. */
rcm_log_message(RCM_WARNING,
MSG_NORECACHE);
free(new_cache);
return;
}
}
*(register_list + register_count) = register_this;
register_count++;
}
}
/*
* For every device left in the old cache, just unregister if
* it has not already been removed
*/
i = 0;
hashline = NULL;
while ((devicename = cache_walk(old_cache, &i, &hashline)) != NULL) {
if (!(hashline->flags&REMOVED)) {
(void) svm_unregister_device(hd, hashline);
}
}
/* Register the new devices. */
for (i = 0; i < register_count; i++) {
deventry = *(register_list + i);
svm_register_device(hd, deventry->devname);
}
if (register_list)
free(register_list);
/* Swap pointers */
*cachep = new_cache;
/* Destroy old cache */
free_cache(&old_cache);
/* Mark the new cache as registered */
new_cache-> registered = 1;
}
/*
* cache_walk()
*
* Perform one step of a walk through the cache. The i and hashline
* parameters are updated to store progress of the walk for future steps.
* They must all be initialized for the beginning of the walk
* (i = 0, line = NULL). Initialize variables to these values for these
* parameters, and then pass in the address of each of the variables
* along with the cache. A NULL return value will be given to indicate
* when there are no more cached items to be returned.
*
* Input:
* cache_t *cache cache
* uint32_t *i hash table index of prev entry
* deventry_t **line ptr to previous device entry
* Output:
* uint32_t *i updated hash table index
* deventry_t **line ptr to device entry
* Return:
* char* device name (NULL for end of cache)
* Locking: The cache must be locked prior to calling this routine.
*/
static char *
cache_walk(cache_t *cache, uint32_t *i, deventry_t **line)
{
uint32_t j;
/* sanity check */
if (cache == NULL || i == NULL || line == NULL ||
*i >= cache->size)
return (NULL);
/* if initial values were given, look for the first entry */
if (*i == 0 && *line == NULL) {
for (j = 0; j < cache->size; j++) {
if (cache->hashline[j]) {
*i = j;
*line = cache->hashline[j];
return ((*line)->devname);
}
}
} else {
/* otherwise, look for the next entry for this hash value */
if (*line && (*line)->next) {
*line = (*line)->next;
return ((*line)->devname);
} else {
/* next look further down in the hash table */
for (j = (*i) + 1; j < cache->size; j++) {
if (cache->hashline[j]) {
*i = j;
*line = cache->hashline[j];
return ((*line)->devname);
}
}
}
}
/*
* We would have returned somewhere above if there were any more
* entries. So set the sentinel values and return a NULL.
*/
*i = cache->size;
*line = NULL;
return (NULL);
}
/*
* free_cache()
*
* Given a pointer to a cache structure, this routine will free all
* of the memory allocated within the cache.
*
* Input:
* cache_t **cache ptr to cache
* Return: None
* Locking: cache lock held on entry
*/
static void
free_cache(cache_t **cache)
{
uint32_t index;
cache_t *realcache;
/* sanity check */
if (cache == NULL || *cache == NULL)
return;
/* de-reference the cache pointer */
realcache = *cache;
/* free the hash table */
for (index = 0; index < realcache->size; index++) {
free_deventry(&realcache->hashline[index]);
}
free(realcache->hashline);
realcache->hashline = NULL;
free(realcache);
*cache = NULL;
}
/*
* free_deventry()
*
* This routine frees all of the memory allocated within a node of a
* deventry.
*
* Input:
* deventry_t **deventry ptr to deventry
* Return: None
* Locking: cache lock held on entry
*/
static void
free_deventry(deventry_t **deventry)
{
deventry_t *olddeventry;
hspentry_t *hspentry;
hspentry_t *oldhspentry;
hspuser_t *hspuser;
hspuser_t *oldhspuser;
if (deventry != NULL) {
while (*deventry != NULL) {
olddeventry = (*deventry)->next;
if ((*deventry)->flags&IN_HSP) {
/*
* If this is in a hot spare pool, remove the
* memory allocated to hot spare pools and
* the users of the pool
*/
hspentry = (*deventry)->hsp_list;
while (hspentry) {
oldhspentry = hspentry;
hspuser = hspentry->hspuser;
while (hspuser) {
oldhspuser = hspuser;
free(hspuser->hspusername);
hspuser = hspuser->next;
free(oldhspuser);
}
free(hspentry->hspname);
hspentry = hspentry->next;
free(oldhspentry);
}
}
if ((*deventry)->devicesname)
free((*deventry)->devicesname);
free((*deventry)->devname);
free (*deventry);
*deventry = olddeventry;
}
}
}
/*
* hash()
*
* A rotating hashing function that converts a string 's' to an index
* in a hash table of size 'h'.
*
* Input:
* uint32_t h hash table size
* char *s string to be hashed
* Return:
* uint32_t hash value
* Locking: None
*/
static uint32_t
hash(uint32_t h, char *s)
{
int len;
int hash, i;
len = strlen(s);
for (hash = len, i = 0; i < len; ++i) {
hash = (hash<<4)^(hash>>28)^s[i];
}
return (hash % h);
}
/*
* svm_register_device()
*
* Register a device
*
* Input:
* rcm_handle_t *hd rcm handle
* char *devname device name
* Return: None
* Locking: None
*/
static void
svm_register_device(rcm_handle_t *hd, char *devname)
{
/* Sanity check */
if (devname == NULL)
return;
rcm_log_message(RCM_TRACE1, "SVM: Registering %s(%d)\n", devname,
devname);
if (rcm_register_interest(hd, devname, 0, NULL) != RCM_SUCCESS) {
rcm_log_message(RCM_ERROR,
gettext("SVM: failed to register \"%s\"\n"), devname);
}
}
/*
* add_dep()
*
* Add an entry to an array of dependent names for a device. Used to
* build an array to call the rcm framework with when passing on a
* DR request.
*
* Input:
* int *ndeps ptr to current number of deps
* char ***depsp ptr to current dependent array
* deventry_t *deventry deventry of device to be added
* Output:
* int *ndeps ptr to updated no of deps
* char ***depsp ptr to new dependant array
* Return:
* int 0, of ok, -1 if failed to allocate memory
* Locking: None
*/
static int
add_dep(int *ndeps, char ***depsp, deventry_t *deventry)
{
char **deps_new;
*ndeps += 1;
deps_new = realloc(*depsp, ((*ndeps) + 1) * sizeof (char *));
if (deps_new == NULL) {
rcm_log_message(RCM_ERROR,
gettext("SVM: cannot allocate dependent array (%s).\n"),
strerror(errno));
return (-1);
}
deps_new[(*ndeps-1)] = deventry->devname;
deps_new[(*ndeps)] = NULL;
*depsp = deps_new;
return (0);
}
/*
* get_dependent()
*
* Create a list of all dependents of a device
* Do not add dependent if it is marked as removed
*
* Input:
* deventry_t *deventry device entry
* Output:
* char ***dependentsp pty to dependent list
* Return:
* int 0, if ok, -1 if failed
* Locking: None
*/
static int
get_dependents(deventry_t *deventry, char *** dependentsp)
{
int ndeps = 0;
deventry_t *dependent;
char **deps = NULL;
dependent = deventry->dependent;
if (dependent == NULL) {
*dependentsp = NULL;
return (0);
}
while (dependent != NULL) {
/*
* do not add dependent if we have
* already received a remove notifification
*/
if (!(dependent->flags&REMOVED))
if (add_dep(&ndeps, &deps, dependent) < 0)
return (-1);
dependent = dependent->next_dep;
}
if (ndeps == 0) {
*dependentsp = NULL;
} else {
*dependentsp = deps;
}
return (0);
}
/*
* add_to_usage()
* Add string to the usage string pointed at by usagep. Allocate memory
* for the new usage string and free the memory used by the original
* usage string
*
* Input:
* char **usagep ptr to usage string
* char *string string to be added to usage
* Return:
* char ptr to new usage string
* Locking: None
*/
char *
add_to_usage(char ** usagep, char *string)
{
int len;
char *new_usage = NULL;
if (*usagep == NULL) {
len = 0;
} else {
len = strlen(*usagep) + 2; /* allow space for comma */
}
len += strlen(string) + 1;
if (new_usage = calloc(1, len)) {
if (*usagep) {
(void) strcpy(new_usage, *usagep);
free(*usagep);
(void) strcat(new_usage, ", ");
}
(void) strcat(new_usage, string);
}
return (new_usage);
}
/*
* add_to_usage_fmt()
*
* Add a formatted string , of the form "blah %s" to the usage string
* pointed at by usagep. Allocate memory for the new usage string and free
* the memory used by the original usage string.
*
* Input:
* char **usagep ptr to current usage string
* char *fmt format string
* char *string string to be added
* Return:
* char* new usage string
* Locking: None
*/
/*PRINTFLIKE2*/
char *
add_to_usage_fmt(char **usagep, char *fmt, char *string)
{
int len;
char *usage;
char *new_usage = NULL;
len = strlen(fmt)
+ strlen(string) + 1;
if (usage = calloc(1, len)) {
(void) sprintf(usage, fmt, string);
new_usage = add_to_usage(usagep, usage);
free(usage);
}
return (new_usage);
}
/*
* is_open()
*
* Make ioctl call to find if a device is open
*
* Input:
* dev_t devkey dev_t for device
* Return:
* int 0 if not open, !=0 if open
* Locking: None
*/
static int
is_open(dev_t devkey)
{
int fd;
md_isopen_t isopen_ioc;
/* Open admin device */
if ((fd = open(ADMSPECIAL, O_RDONLY, 0)) < 0) {
rcm_log_message(RCM_ERROR, MSG_OPENERR, ADMSPECIAL);
return (0);
}
(void) memset(&isopen_ioc, 0, sizeof (isopen_ioc));
isopen_ioc.dev = devkey;
if (ioctl(fd, MD_IOCISOPEN, &isopen_ioc) < 0) {
(void) close(fd);
return (0);
}
(void) close(fd);
return (isopen_ioc.isopen);
}
/*
* check_softpart()
*
* Check the status of the passed in device within the softpartition.
*
* Input:
* mdsetname_t * the name of the set
* mdname_t * the softpartition device that is being examined
* char * the device which needs to be checked
* md_error_t * error pointer (not used)
* Return:
* int REDUNDANT - device is redundant and can be
* removed
* NOTREDUNDANT - device cannot be removed
* NOTINDEVICE - device is not part of this
* component
*/
static int
check_softpart(mdsetname_t *sp, mdname_t *np, char *uname, md_error_t *ep)
{
md_sp_t *softp = NULL;
rcm_log_message(RCM_TRACE1, "SVM: softpart checking %s %s\n",
np->bname, uname);
softp = meta_get_sp(sp, np, ep);
/* softp cannot be NULL, if it is then the RCM cache is corrupt */
assert(softp != NULL);
/*
* if the softpartition is not a parent then nothing can be done, user
* must close the device and then fix the under lying devices.
*/
if (!(MD_HAS_PARENT(softp->common.parent))) {
rcm_log_message(RCM_TRACE1,
"SVM: softpart is a top level device\n");
return (NOTREDUNDANT);
}
if (strcmp(softp->compnamep->bname, uname) != 0) {
/*
* This can occur if this function has been called by the
* check_raid5 code as it is cycling through each column
* in turn.
*/
rcm_log_message(RCM_TRACE1,
"SVM: %s is not in softpart (%s)\n",
uname, softp->compnamep->bname);
return (NOTINDEVICE);
}
/*
* Check the status of the soft partition this only moves from
* an okay state if the underlying devices fails while the soft
* partition is open.
*/
if (softp->status != MD_SP_OK) {
rcm_log_message(RCM_TRACE1,
"SVM: softpart is broken (state: 0x%x)\n",
softp->status);
return (REDUNDANT);
}
return (NOTREDUNDANT);
}
/*
* check_raid5()
*
* Check the status of the passed in device within the raid5 in question.
*
* Input:
* mdsetname_t * the name of the set
* mdname_t * the raid5 device that is being examined
* char * the device which needs to be checked
* md_error_t * error pointer (not used)
* Return:
* int REDUNDANT - device is redundant and can be
* removed
* NOTREDUNDANT - device cannot be removed
*/
static int
check_raid5(mdsetname_t *sp, mdname_t *np, char *uname, md_error_t *ep)
{
md_raid_t *raidp = NULL;
md_raidcol_t *colp = NULL;
int i;
int rval = 0;
rcm_log_message(RCM_TRACE1, "SVM: raid5 checking %s %s\n",
np->bname, uname);
raidp = meta_get_raid(sp, np, ep);
/* raidp cannot be NULL, if it is then the RCM cache is corrupt */
assert(raidp != NULL);
/*
* Now check each column in the device. We cannot rely upon the state
* of the device because if a hotspare is in use all the states are
* set to Okay, both at the metadevice layer and the column layer.
*/
for (i = 0; (i < raidp->cols.cols_len); i++) {
colp = &raidp->cols.cols_val[i];
np = colp->colnamep;
rcm_log_message(RCM_TRACE1,
"SVM: raid5 checking %s state %s 0x%x\n",
np->bname, raid_col_state_to_name(colp, NULL, 0),
colp->state);
/*
* It is possible for the column to be a softpartition,
* so need to check the softpartiton if this is the
* case. It is *not* valid for the column to be a
* stripe/concat/mirror, and so no check to see what
* type of metadevice is being used.
*/
if (metaismeta(np)) {
/* this is a metadevice ie a softpartiton */
rval = check_softpart(sp, np, uname, ep);
if (rval == REDUNDANT) {
rcm_log_message(RCM_TRACE1,
"SVM: raid5 %s is broken\n", uname);
meta_invalidate_name(np);
return (REDUNDANT);
} else if (rval == NOTREDUNDANT &&
colp->hsnamep != NULL) {
rcm_log_message(RCM_TRACE1,
"SVM: raid5 device is broken, hotspared\n");
meta_invalidate_name(np);
return (REDUNDANT);
}
meta_invalidate_name(np);
continue;
}
meta_invalidate_name(np);
if (strcmp(uname, np->bname) != 0)
continue;
/*
* Found the device. Check if it is broken or hotspared.
*/
if (colp->state & RUS_ERRED) {
rcm_log_message(RCM_TRACE1,
"SVM: raid5 column device is broken\n");
return (REDUNDANT);
}
if (colp->hsnamep != NULL) {
rcm_log_message(RCM_TRACE1,
"SVM: raid5 column device is broken, hotspared\n");
return (REDUNDANT);
}
}
return (NOTREDUNDANT);
}
/*
* check_stripe()
*
* Check the status of the passed in device within the stripe in question.
*
* Input:
* mdsetname_t * the name of the set
* mdname_t * the stripe that is being examined
* char * the device which needs to be checked
* md_error_t * error pointer (not used)
* Return:
* int REDUNDANT - device is redundant and can be
* removed
* NOTREDUNDANT - device cannot be removed
* NOTINDEVICE - device is not part of this
* component
*/
static int
check_stripe(mdsetname_t *sp, mdname_t *np, char *uname, md_error_t *ep)
{
md_stripe_t *stripep = NULL;
md_row_t *mrp = NULL;
md_comp_t *mcp;
mdname_t *pnp;
char *miscname;
int row;
int col;
rcm_log_message(RCM_TRACE1, "SVM: concat/stripe checking %s %s\n",
np->bname, uname);
stripep = meta_get_stripe(sp, np, ep);
/* stripep cannot be NULL, if it is then the RCM cache is corrupt */
assert(stripep != NULL);
/*
* If the stripe is not a parent then nothing can be done, user
* must close the device and then fix the devices.
*/
if (!(MD_HAS_PARENT(stripep->common.parent))) {
rcm_log_message(RCM_TRACE1,
"SVM: stripe is a top level device\n");
return (NOTREDUNDANT);
}
pnp = metamnumname(&sp, stripep->common.parent, 0, ep);
if (pnp == NULL) {
/*
* Only NULL when the replicas are in an inconsistant state
* ie the device says it is the parent of X but X does not
* exist.
*/
rcm_log_message(RCM_TRACE1, "SVM: parent is not configured\n");
return (NOTREDUNDANT);
}
/*
* Get the type of the parent and make sure that it is a mirror,
* if it is then need to find out the number of submirrors, and
* if it is not a mirror then this is not a REDUNDANT device.
*/
if ((miscname = metagetmiscname(pnp, ep)) == NULL) {
/*
* Again something is wrong with the configuration.
*/
rcm_log_message(RCM_TRACE1,
"SVM: unable to find the type of %s\n", pnp->cname);
meta_invalidate_name(pnp);
return (NOTREDUNDANT);
}
if (!(strcmp(miscname, MD_MIRROR) == 0 &&
check_mirror(sp, pnp, ep) == REDUNDANT)) {
rcm_log_message(RCM_TRACE1,
"SVM: %s is a %s and not redundant\n",
pnp->cname, miscname);
meta_invalidate_name(pnp);
return (NOTREDUNDANT);
}
meta_invalidate_name(pnp);
for (row = 0; row < stripep->rows.rows_len; row++) {
mrp = &stripep->rows.rows_val[row];
/* now the components in the row */
for (col = 0; col < mrp->comps.comps_len; col++) {
mcp = &mrp->comps.comps_val[col];
rcm_log_message(RCM_TRACE1,
"SVM: stripe comp %s check\n",
mcp->compnamep->bname);
if (strcmp(mcp->compnamep->bname, uname) != 0)
continue;
rcm_log_message(RCM_TRACE1,
"SVM: component state: %s\n",
comp_state_to_name(mcp, NULL, 0));
if (mcp->hsnamep != NULL) {
/* device is broken and hotspared */
rcm_log_message(RCM_TRACE1,
"SVM: stripe %s broken, hotspare active\n",
uname);
return (REDUNDANT);
}
/*
* LAST_ERRED is a special case. If the state of a
* component is CS_LAST_ERRED then this is the last
* copy of the data and we need to keep using it, even
* though we had errors. Thus, we must block the DR
* request. If you follow the documented procedure for
* fixing each component (fix devs in maintenance
* before last erred) then the mirror will
* automatically transition Last Erred components to
* the Erred state after which they can be DRed out.
*/
if (mcp->state == CS_ERRED) {
/* device is broken */
rcm_log_message(RCM_TRACE1,
"SVM: stripe %s is broken\n", uname);
return (REDUNDANT);
}
/*
* Short circuit - if here the component has been
* found in the column so no further processing is
* required here.
*/
return (NOTREDUNDANT);
}
}
/*
* Only get to this point if the device (uname) has not been
* found in the stripe. This means that there is something
* wrong with the device dependency list.
*/
rcm_log_message(RCM_TRACE1,
"SVM: component %s is not part of %s\n",
uname, np->bname);
return (NOTINDEVICE);
}
/*
* check_mirror()
*
* Make sure that the mirror > 1 submirror.
*
* Input:
* mdsetname_t * the name of the set
* mdname_t * the stripe that is being examined
* Return:
* int REDUNDANT - mirror > 1 submirrors
* NOTREDUNDANT - mirror has 1 submirror
*/
static int
check_mirror(mdsetname_t *sp, mdname_t *np, md_error_t *ep)
{
uint_t nsm = 0; /* number of submirrors */
uint_t smi = 0; /* index into submirror array */
md_mirror_t *mirrorp = NULL;
rcm_log_message(RCM_TRACE1, "SVM: mirror checking %s\n", np->bname);
mirrorp = meta_get_mirror(sp, np, ep);
/* mirrorp cannot be NULL, if it is then the RCM cache is corrupt */
assert(mirrorp != NULL);
/*
* Need to check how many submirrors that the mirror has.
*/
for (smi = 0, nsm = 0; (smi < NMIRROR); ++smi) {
md_submirror_t *mdsp = &mirrorp->submirrors[smi];
mdname_t *submirnamep = mdsp->submirnamep;
/* Is this submirror being used ? No, then continue */
if (submirnamep == NULL)
continue;
nsm++;
}
/*
* If there is only one submirror then there is no redundancy
* in the configuration and the user needs to take some other
* action before using cfgadm on the device ie close the metadevice.
*/
if (nsm == 1) {
rcm_log_message(RCM_TRACE1,
"SVM: only one submirror unable to allow action\n");
return (NOTREDUNDANT);
}
return (REDUNDANT);
}
/*
* check_device()
*
* Check the current status of the underlying device.
*
* Input:
* deventry_t * the device that is being checked
* Return:
* int REDUNDANT - device is redundant and can be
* removed
* NOTREDUNDANT - device cannot be removed
* Locking:
* None
*
* The check_device code path (the functions called by check_device) use
* libmeta calls directly to determine if the specified device is
* redundant or not. The can lead to conflicts between data cached in
* libmeta and data that is being cached by this rcm module. Since the
* rcm cache is our primary source of information here, we need to make
* sure that we are not getting stale data from the libmeta caches.
* We use meta_invalidate_name throughout this code path to clear the
* cached data in libmeta in order to ensure that we are not using stale data.
*/
static int
check_device(deventry_t *deventry)
{
mdsetname_t *sp;
md_error_t error = mdnullerror;
char sname[BUFSIZ+1];
mdname_t *np;
deventry_t *dependent;
int rval = NOTREDUNDANT;
int ret;
dependent = deventry->dependent;
rcm_log_message(RCM_TRACE1, "SVM: check_device(%s)\n",
deventry->devname);
/*
* should not be null because the caller has already figured out
* there are dependent devices.
*/
assert(dependent != NULL);
do {
rcm_log_message(RCM_TRACE1, "SVM: check dependent: %s\n",
dependent->devname);
if (dependent->flags & REMOVED) {
dependent = dependent->next_dep;
continue;
}
/*
* The device *should* be a metadevice and so need to see if
* it contains a setname.
*/
ret = sscanf(dependent->devname,
"/dev/md/%" VAL2STR(BUFSIZ) "[^/]/dsk/",
sname);
if (ret != 1)
(void) strcpy(sname, MD_LOCAL_NAME);
if ((sp = metasetname(sname, &error)) == NULL) {
rcm_log_message(RCM_TRACE1,
"SVM: unable to get setname for \"%s\", error %s\n",
sname, mde_sperror(&error, ""));
break;
}
rcm_log_message(RCM_TRACE1, "SVM: processing: %s\n",
dependent->devname);
np = metaname(&sp, dependent->devname, META_DEVICE, &error);
switch (dependent->devtype) {
case SVM_TRANS:
/*
* No code to check trans devices because ufs logging
* should be being used.
*/
rcm_log_message(RCM_TRACE1,
"SVM: Use UFS logging instead of trans devices\n");
break;
case SVM_SLICE:
case SVM_STRIPE:
case SVM_CONCAT:
rval = check_stripe(sp, np, deventry->devname, &error);
break;
case SVM_MIRROR:
/*
* No check here as this is performed by the one
* above when the submirror is checked.
*/
rcm_log_message(RCM_TRACE1,
"SVM: Mirror check is done by the stripe check\n");
break;
case SVM_RAID:
/*
* Raid5 devices can be built on soft partitions or
* slices and so the check here is for the raid5
* device built on top of slices. Note, a raid5 cannot
* be built on a stripe/concat.
*/
rval = check_raid5(sp, np, deventry->devname, &error);
break;
case SVM_SOFTPART:
/*
* Raid5 devices can be built on top of soft partitions
* and so they have to be checked.
*/
rval = check_softpart(sp, np, deventry->devname,
&error);
break;
default:
rcm_log_message(RCM_TRACE1,
"SVM: unknown devtype: %d\n", dependent->devtype);
break;
}
meta_invalidate_name(np);
if (rval == REDUNDANT)
break;
} while ((dependent = dependent->next_dep) != NULL);
rcm_log_message(RCM_TRACE1, "SVM: check_device return %d\n", rval);
return (rval);
}
/*
* svm_unregister_device
*
* Unregister the device specified by the deventry
*
* Input:
* rcm_handle_t * information for RCM
* deventry_t * description of the device to be
* unregistered
*
* Return:
* int 0 - successfully unregistered
* != 0 - failed to unregister
*
* Locking:
* None
*
* If the deventry_t has a devicesname, we will first attempt to unregister
* using that name. If that fails then we'll attempt to unregister using
* devname. The reason for this strategy has to do with the way that
* rcm_register_interest works. If passed a /dev/ name,
* rcm_register_interest uses realpath() to convert it to a /devices name.
* Thus, we are more likely to succeed if we use devicesname first.
*/
static int
svm_unregister_device(rcm_handle_t *hd, deventry_t *d)
{
int deleted;
if (d->devicesname) {
rcm_log_message(RCM_TRACE1, "SVM: unregister_device %s (%s)\n",
d->devname, d->devicesname);
} else {
rcm_log_message(RCM_TRACE1, "SVM: unregister_device %s\n",
d->devname);
}
deleted = -1;
if (d->devicesname != NULL) {
/*
* Try to unregister via the /devices entry first. RCM
* converts /dev/ entries to /devices entries before
* storing them. Thus, if this item has a /devices name
* available, we should use it for unregistering.
*/
deleted = rcm_unregister_interest(hd,
d->devicesname, 0);
}
if (deleted != 0) {
/*
* Either we did not have a /devices name or the attempt to
* unregister using the /devices name failed. Either way
* we'll now try to unregister using the conventional name.
*/
deleted = rcm_unregister_interest(hd, d->devname, 0);
}
if (deleted != 0) {
rcm_log_message(RCM_TRACE1, "SVM: unregister_device failed "
"for %s\n", d->devname);
}
return (deleted);
}