/*
* 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.
*/
#include <stdlib.h>
#include <unistd.h>
#include <wait.h>
#include <sys/time.h>
#include <syslog.h>
#include <meta.h>
#include <sys/lvm/mdio.h>
#include <sys/lvm/md_mddb.h>
#include <sys/lvm/md_mirror.h>
#define MAX_N_ARGS 64
#define MAX_ARG_LEN 1024
#define MAX_SLEEPS 99
#define SLEEP_MOD 5
/* we reserve 1024 bytes for stdout and the same for stderr */
#define MAX_OUT 1024
#define MAX_ERR 1024
#define JUNK 128 /* used to flush stdout and stderr */
/*ARGSUSED*/
void
mdmn_do_cmd(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
/*
* We are given one string containing all the arguments
* For execvp() we have to regenerate the arguments again
*/
int arg; /* argument that is currently been built */
int index; /* runs through arg above */
int i; /* helper for for loop */
char *argv[MAX_N_ARGS]; /* argument array for execvp */
char *cp; /* runs through the given command line string */
char *command = NULL; /* the command we call locally */
int pout[2]; /* pipe for stdout */
int perr[2]; /* pipe for stderr */
pid_t pid; /* process id */
cp = msg->msg_event_data;
arg = 0;
index = 0;
/* init the args array alloc the first one and null out the rest */
argv[0] = Malloc(MAX_ARG_LEN);
for (i = 1; i < MAX_N_ARGS; i++) {
argv[i] = NULL;
}
resp->mmr_comm_state = MDMNE_ACK; /* Ok state */;
while (*cp != '\0') {
if (arg == MAX_N_ARGS) {
(void) fprintf(stderr, dgettext(TEXT_DOMAIN,
"PANIC: too many arguments specified\n"));
resp->mmr_comm_state = MDMNE_HANDLER_FAILED;
goto out;
}
if (index == MAX_ARG_LEN) {
(void) fprintf(stderr, dgettext(TEXT_DOMAIN,
"PANIC: argument too long\n"));
resp->mmr_comm_state = MDMNE_HANDLER_FAILED;
goto out;
}
if ((*cp != ' ') && (*cp != '\t')) {
/*
* No space or tab: copy char into current
* argv and advance both pointers
*/
argv[arg][index] = *cp;
cp++; /* next char in command line */
index++; /* next char in argument */
} else {
/*
* space or tab: terminate current argv,
* advance arg, reset pointer into arg,
* advance pointer in command line
*/
argv[arg][index] = '\0';
arg++; /* next argument */
argv[arg] = Malloc(MAX_ARG_LEN);
cp++; /* next char in command line */
index = 0; /* starts at char 0 */
}
}
/* terminate the last real argument */
argv[arg][index] = '\0';
/* the last argument is an NULL pointer */
argv[++arg] = NULL;
if (pipe(pout) < 0) {
(void) fprintf(stderr, dgettext(TEXT_DOMAIN,
"PANIC: pipe failed\n"));
resp->mmr_comm_state = MDMNE_HANDLER_FAILED;
goto out;
}
if (pipe(perr) < 0) {
(void) fprintf(stderr, dgettext(TEXT_DOMAIN,
"PANIC: pipe failed\n"));
(void) close(pout[0]);
(void) close(pout[1]);
resp->mmr_comm_state = MDMNE_HANDLER_FAILED;
goto out;
}
command = Strdup(argv[0]);
(void) strcat(argv[0], ".rpc_call");
pid = fork1();
if (pid == (pid_t)-1) {
(void) fprintf(stderr, dgettext(TEXT_DOMAIN,
"PANIC: fork failed\n"));
resp->mmr_comm_state = MDMNE_HANDLER_FAILED;
(void) close(pout[0]);
(void) close(pout[1]);
(void) close(perr[0]);
(void) close(perr[1]);
goto out;
} else if (pid == (pid_t)0) {
/* child */
(void) close(0);
/* close the reading channels of pout and perr */
(void) close(pout[0]);
(void) close(perr[0]);
/* redirect stdout */
if (dup2(pout[1], 1) < 0) {
(void) fprintf(stderr, dgettext(TEXT_DOMAIN,
"PANIC: dup2 failed\n"));
resp->mmr_comm_state = MDMNE_HANDLER_FAILED;
return;
}
/* redirect stderr */
if (dup2(perr[1], 2) < 0) {
(void) fprintf(stderr, dgettext(TEXT_DOMAIN,
"PANIC: dup2 failed\n"));
resp->mmr_comm_state = MDMNE_HANDLER_FAILED;
return;
}
(void) execvp(command, (char *const *)argv);
perror("execvp");
_exit(1);
} else {
/* parent process */
int stat_loc;
char *out, *err; /* for stdout and stderr of child */
int i; /* index into the aboves */
char junk[JUNK];
int out_done = 0;
int err_done = 0;
int out_read = 0;
int err_read = 0;
int maxfd;
fd_set rset;
/* close the writing channels of pout and perr */
(void) close(pout[1]);
(void) close(perr[1]);
resp->mmr_out = Malloc(MAX_OUT);
resp->mmr_err = Malloc(MAX_ERR);
resp->mmr_out_size = MAX_OUT;
resp->mmr_err_size = MAX_ERR;
out = resp->mmr_out;
err = resp->mmr_err;
FD_ZERO(&rset);
while ((out_done == 0) || (err_done == 0)) {
FD_SET(pout[0], &rset);
FD_SET(perr[0], &rset);
maxfd = max(pout[0], perr[0]) + 1;
(void) select(maxfd, &rset, NULL, NULL, NULL);
/*
* Did the child produce some output to stdout?
* If so, read it until we either reach the end of the
* output or until we read MAX_OUT bytes.
* Whatever comes first.
* In case we already read MAX_OUT bytes we simply
* read away the output into a junk buffer.
* Just to make the child happy
*/
if (FD_ISSET(pout[0], &rset)) {
if (MAX_OUT - out_read - 1 > 0) {
i = read(pout[0], out,
MAX_OUT - out_read);
out_read += i;
out += i;
} else {
/* buffer full, empty stdout */
i = read(pout[0], junk, JUNK);
}
if (i == 0) {
/* stdout is closed by child */
out_done++;
}
}
/* same comment as above | sed -e 's/stdout/stderr/' */
if (FD_ISSET(perr[0], &rset)) {
if (MAX_ERR - err_read - 1 > 0) {
i = read(perr[0], err,
MAX_ERR - err_read);
err_read += i;
err += i;
} else {
/* buffer full, empty stderr */
i = read(perr[0], junk, JUNK);
}
if (i == 0) {
/* stderr is closed by child */
err_done++;
}
}
}
resp->mmr_out[out_read] = '\0';
resp->mmr_err[err_read] = '\0';
while (waitpid(pid, &stat_loc, 0) < 0) {
if (errno != EINTR) {
resp->mmr_comm_state = MDMNE_HANDLER_FAILED;
break;
}
}
if (errno == 0)
resp->mmr_exitval = WEXITSTATUS(stat_loc);
(void) close(pout[0]);
(void) close(perr[0]);
}
out:
for (i = 0; i < MAX_N_ARGS; i++) {
if (argv[i] != NULL) {
free(argv[i]);
}
}
if (command != NULL) {
Free(command);
}
}
/*
* This is for checking if a metadevice is opened, and for
* locking in case it is not and for
* unlocking a locked device
*/
/*ARGSUSED*/
void
mdmn_do_clu(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
if (msg->msg_type == MD_MN_MSG_CLU_CHECK) {
md_isopen_t *d;
int ret;
resp->mmr_comm_state = MDMNE_ACK; /* Ok state */;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
d = (md_isopen_t *)(void *)msg->msg_event_data;
ret = metaioctl(MD_IOCISOPEN, d, &(d->mde), NULL);
/*
* In case the ioctl succeeded, return the open state of
* the metadevice. Otherwise we return the error the ioctl
* produced. As this is not zero, no attempt is made to
* remove/rename the metadevice later
*/
if (ret == 0) {
resp->mmr_exitval = d->isopen;
} else {
/*
* When doing a metaclear, one node after the other
* does the two steps:
* - check on all nodes if this md is opened.
* - remove the md locally.
* When the 2nd node asks all nodes if the md is
* open it starts with the first node.
* As this already removed the md, the check
* returns MDE_UNIT_NOT_SETUP.
* In order to not keep the 2nd node from proceeding,
* we map this to an Ok.
*/
if (mdismderror(&(d->mde), MDE_UNIT_NOT_SETUP)) {
mdclrerror(&(d->mde));
ret = 0;
}
resp->mmr_exitval = ret;
}
}
}
/* handler for MD_MN_MSG_REQUIRE_OWNER */
/*ARGSUSED*/
void
mdmn_do_req_owner(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_set_mmown_params_t setown;
md_mn_req_owner_t *d;
int ret, n = 0;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_req_owner_t *)(void *)msg->msg_event_data;
(void) memset(&setown, 0, sizeof (setown));
MD_SETDRIVERNAME(&setown, MD_MIRROR, MD_MIN2SET(d->mnum))
setown.d.mnum = d->mnum;
setown.d.owner = d->owner;
/* Retry ownership change if we get EAGAIN returned */
while ((ret = metaioctl(MD_MN_SET_MM_OWNER, &setown, &setown.mde, NULL))
!= 0) {
md_sys_error_t *ip =
&setown.mde.info.md_error_info_t_u.sys_error;
if (ip->errnum != EAGAIN) {
break;
}
if (n++ >= 10) {
break;
}
(void) sleep(1);
}
resp->mmr_exitval = ret;
}
/*
* handler for MD_MN_MSG_CHOOSE_OWNER
* This is called when a mirror resync has no owner. The master node generates
* this message which is not broadcast to the other nodes. The message is
* required as the kernel does not have access to the nodelist for the set.
*/
/*ARGSUSED*/
void
mdmn_do_choose_owner(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_chowner_t chownermsg;
md_mn_msg_chooseid_t *d;
int ret = 0;
int nodecnt;
int nodeno;
uint_t nodeid;
uint_t myflags;
set_t setno;
mdsetname_t *sp;
md_set_desc *sd;
md_mnnode_desc *nd;
md_error_t mde = mdnullerror;
md_mn_result_t *resp1 = NULL;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_chooseid_t *)(void *)msg->msg_event_data;
/*
* The node to be chosen will be the resync count for the set
* modulo the number of live nodes in the set
*/
setno = MD_MIN2SET(d->msg_chooseid_mnum);
if ((sp = metasetnosetname(setno, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_MSG_CHOOSE_OWNER: Invalid setno %d\n"), setno);
resp->mmr_exitval = 1;
return;
}
if ((sd = metaget_setdesc(sp, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_MSG_CHOOSE_OWNER: Invalid set pointer\n"));
resp->mmr_exitval = 1;
return;
}
/* Count the number of live nodes */
nodecnt = 0;
nd = sd->sd_nodelist;
while (nd) {
if (nd->nd_flags & MD_MN_NODE_ALIVE)
nodecnt++;
nd = nd->nd_next;
}
nodeno = (d->msg_chooseid_rcnt%nodecnt);
/*
* If we've been called with msg_chooseid_set_node set TRUE then we
* are simply re-setting the owner id to ensure consistency across
* the cluster.
* If the flag is reset (B_FALSE) we are requesting a new owner to be
* determined.
*/
if (d->msg_chooseid_set_node) {
nodeid = d->msg_chooseid_rcnt;
} else {
/* scan the nodelist looking for the required node */
nodecnt = 0;
nd = sd->sd_nodelist;
while (nd) {
if (nd->nd_flags & MD_MN_NODE_ALIVE) {
if (nodecnt == nodeno)
break;
nodecnt++;
}
nd = nd->nd_next;
}
nodeid = nd->nd_nodeid;
}
/* Send message to all nodes to make ownership change */
chownermsg.msg_chowner_mnum = d->msg_chooseid_mnum;
chownermsg.msg_chowner_nodeid = nodeid;
myflags = MD_MSGF_NO_LOG;
/* inherit some flags from the parent message */
myflags |= msg->msg_flags & MD_MSGF_INHERIT_BITS;
ret = mdmn_send_message(MD_MIN2SET(d->msg_chooseid_mnum),
MD_MN_MSG_CHANGE_OWNER, myflags, 0, (char *)&chownermsg,
sizeof (chownermsg), &resp1, &mde);
if (resp1 != NULL)
free_result(resp1);
resp->mmr_exitval = ret;
}
/*
* Handler for MD_MN_MSG_CHANGE_OWNER
* This is called when we are perfoming a resync and wish to change from
* no mirror owner to an owner chosen by the master.
* This mesage is only relevant for the new owner, the message will be
* ignored by all other nodes
*/
/*ARGSUSED*/
void
mdmn_do_change_owner(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_set_mmown_params_t setown;
md_mn_msg_chowner_t *d;
int ret = 0;
set_t setno;
mdsetname_t *sp;
md_set_desc *sd;
md_error_t mde = mdnullerror;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_chowner_t *)(void *)msg->msg_event_data;
setno = MD_MIN2SET(d->msg_chowner_mnum);
if ((sp = metasetnosetname(setno, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_MSG_CHANGE_OWNER: Invalid setno %d\n"), setno);
resp->mmr_exitval = 1;
return;
}
if ((sd = metaget_setdesc(sp, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_MSG_CHANGE_OWNER: Invalid set pointer\n"));
resp->mmr_exitval = 1;
return;
}
if (d->msg_chowner_nodeid == sd->sd_mn_mynode->nd_nodeid) {
/*
* If we are the chosen owner, issue ioctl to make the
* ownership change
*/
(void) memset(&setown, 0, sizeof (md_set_mmown_params_t));
setown.d.mnum = d->msg_chowner_mnum;
setown.d.owner = d->msg_chowner_nodeid;
setown.d.flags = MD_MN_MM_SPAWN_THREAD;
MD_SETDRIVERNAME(&setown, MD_MIRROR,
MD_MIN2SET(d->msg_chowner_mnum));
/*
* Single shot at changing the the owner, if it fails EAGAIN,
* another node must have become the owner while we are in the
* process of making this choice.
*/
ret = metaioctl(MD_MN_SET_MM_OWNER, &setown,
&(setown.mde), NULL);
if (ret == EAGAIN)
ret = 0;
}
resp->mmr_exitval = ret;
}
/* handler for MD_MN_MSG_SUSPEND_WRITES */
/*ARGSUSED*/
void
mdmn_do_susp_write(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
/* Suspend writes to a region of a mirror */
md_suspend_wr_params_t suspwr_ioc;
md_mn_msg_suspwr_t *d;
int ret;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_suspwr_t *)(void *)msg->msg_event_data;
(void) memset(&suspwr_ioc, 0, sizeof (md_suspend_wr_params_t));
MD_SETDRIVERNAME(&suspwr_ioc, MD_MIRROR,
MD_MIN2SET(d->msg_suspwr_mnum));
suspwr_ioc.mnum = d->msg_suspwr_mnum;
ret = metaioctl(MD_MN_SUSPEND_WRITES, &suspwr_ioc,
&(suspwr_ioc.mde), NULL);
resp->mmr_exitval = ret;
}
/*
* handler for MD_MN_MSG_STATE_UPDATE_RESWR
* This functions update a submirror component state and then resumes writes
* to the mirror
*/
/*ARGSUSED*/
void
mdmn_do_state_upd_reswr(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
/* Update the state of the component of a mirror */
md_set_state_params_t setstate_ioc;
md_mn_msg_stch_t *d;
int ret;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_stch_t *)(void *)msg->msg_event_data;
(void) memset(&setstate_ioc, 0, sizeof (md_set_state_params_t));
MD_SETDRIVERNAME(&setstate_ioc, MD_MIRROR,
MD_MIN2SET(d->msg_stch_mnum));
setstate_ioc.mnum = d->msg_stch_mnum;
setstate_ioc.sm = d->msg_stch_sm;
setstate_ioc.comp = d->msg_stch_comp;
setstate_ioc.state = d->msg_stch_new_state;
setstate_ioc.hs_id = d->msg_stch_hs_id;
ret = metaioctl(MD_MN_SET_STATE, &setstate_ioc,
&(setstate_ioc.mde), NULL);
resp->mmr_exitval = ret;
}
/*
* submessage generator for MD_MN_MSG_STATE_UPDATE and MD_MN_MSG_STATE_UPDATE2
* This generates 2 messages, the first is SUSPEND_WRITES and
* depending on the type of the original message the second one is
* either STATE_UPDATE_RESWR or STATE_UPDATE_RESWR2 which actually does
* the same, but runs on a higher class.
*/
int
mdmn_smgen_state_upd(md_mn_msg_t *msg, md_mn_msg_t *msglist[])
{
md_mn_msg_t *nmsg;
md_mn_msg_stch_t *d;
md_mn_msg_stch_t *stch_data;
md_mn_msg_suspwr_t *suspwr_data;
d = (md_mn_msg_stch_t *)(void *)msg->msg_event_data;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = MD_MSGF_NO_LOG; /* Don't log submessages */
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_SUSPEND_WRITES;
nmsg->msg_event_size = sizeof (md_mn_msg_suspwr_t);
nmsg->msg_event_data = Zalloc(sizeof (md_mn_msg_suspwr_t));
suspwr_data = (md_mn_msg_suspwr_t *)(void *)nmsg->msg_event_data;
suspwr_data->msg_suspwr_mnum = d->msg_stch_mnum;
msglist[0] = nmsg;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = MD_MSGF_NO_LOG; /* Don't log submessages */
nmsg->msg_setno = msg->msg_setno;
if (msg->msg_type == MD_MN_MSG_STATE_UPDATE2) {
nmsg->msg_type = MD_MN_MSG_STATE_UPDATE_RESWR2;
} else {
nmsg->msg_type = MD_MN_MSG_STATE_UPDATE_RESWR;
}
nmsg->msg_event_size = sizeof (md_mn_msg_stch_t);
nmsg->msg_event_data = Zalloc(sizeof (md_mn_msg_stch_t));
stch_data = (md_mn_msg_stch_t *)(void *)nmsg->msg_event_data;
stch_data->msg_stch_mnum = d->msg_stch_mnum;
stch_data->msg_stch_sm = d->msg_stch_sm;
stch_data->msg_stch_comp = d->msg_stch_comp;
stch_data->msg_stch_new_state = d->msg_stch_new_state;
stch_data->msg_stch_hs_id = d->msg_stch_hs_id;
msglist[1] = nmsg;
return (2); /* Return the number of submessages generated */
}
/*
* handler for MD_MN_MSG_ALLOCATE_HOTSPARE and MD_MN_MSG_ALLOCATE_HOTSPARE2
* This sends a message to all nodes requesting them to allocate a hotspare
* for the specified component. The component is specified by the mnum of
* the mirror, the submirror index and the component index.
*/
/*ARGSUSED*/
void
mdmn_do_allocate_hotspare(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
/* Allocate a hotspare for a mirror component */
md_alloc_hotsp_params_t allochsp_ioc;
md_mn_msg_allochsp_t *d;
int ret;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_allochsp_t *)((void *)(msg->msg_event_data));
(void) memset(&allochsp_ioc, 0,
sizeof (md_alloc_hotsp_params_t));
MD_SETDRIVERNAME(&allochsp_ioc, MD_MIRROR,
MD_MIN2SET(d->msg_allochsp_mnum));
allochsp_ioc.mnum = d->msg_allochsp_mnum;
allochsp_ioc.sm = d->msg_allochsp_sm;
allochsp_ioc.comp = d->msg_allochsp_comp;
allochsp_ioc.hs_id = d->msg_allochsp_hs_id;
ret = metaioctl(MD_MN_ALLOCATE_HOTSPARE, &allochsp_ioc,
&(allochsp_ioc.mde), NULL);
resp->mmr_exitval = ret;
}
/*
* handler for MD_MN_MSG_RESYNC_STARTING,MD_MN_MSG_RESYNC_FIRST,
* MD_MN_MSG_RESYNC_NEXT, MD_MN_MSG_RESYNC_FINISH, MD_MN_MSG_RESYNC_PHASE_DONE
*/
/*ARGSUSED*/
void
mdmn_do_resync(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_resync_t *d;
md_mn_rs_params_t respar;
mddb_setflags_config_t sf;
md_error_t ep = mdnullerror;
mdsetname_t *sp;
int ret;
int smi;
int start_flag = 1;
int sleep_count = 0;
unsigned int sleep_time = 2;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_resync_t *)((void *)(msg->msg_event_data));
(void) memset(&respar, 0, sizeof (respar));
MD_SETDRIVERNAME(&respar, MD_MIRROR,
MD_MIN2SET(d->msg_resync_mnum))
respar.msg_type = (int)msg->msg_type;
respar.mnum = d->msg_resync_mnum;
respar.rs_type = d->msg_resync_type;
respar.rs_start = d->msg_resync_start;
respar.rs_size = d->msg_resync_rsize;
respar.rs_done = d->msg_resync_done;
respar.rs_2_do = d->msg_resync_2_do;
respar.rs_originator = d->msg_originator;
respar.rs_flags = d->msg_resync_flags;
for (smi = 0; smi < NMIRROR; smi++) {
respar.rs_sm_state[smi] = d->msg_sm_state[smi];
respar.rs_sm_flags[smi] = d->msg_sm_flags[smi];
}
/*
* Prior to running the resync thread first check that the start_step
* flag (MD_SET_MN_START_RC) added by metaclust's MC_START step has been
* removed from the set record flags. Ordinarily, this would be removed
* at MC_STEP4 in metaclust - need to ensure this has happened on all
* nodes.
*/
(void) memset(&sf, 0, sizeof (sf));
sf.sf_setno = MD_MIN2SET(d->msg_resync_mnum);
sf.sf_flags = MDDB_NM_GET;
/* Use magic to help protect ioctl against attack. */
sf.sf_magic = MDDB_SETFLAGS_MAGIC;
if ((sp = metasetnosetname(sf.sf_setno, &ep)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MDMN_DO_RESYNC: Invalid setno = %d\n"),
sf.sf_setno);
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
/* start_flag always true initially */
while (start_flag) {
if (metaioctl(MD_MN_GET_SETFLAGS, &sf, &sf.sf_mde, NULL) != 0) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MDMN_DO_RESYNC: Could not get start_step "
"flag for set %s - returning\n"),
sp->setname);
(void) mdstealerror(&(resp->mmr_ep), &sf.sf_mde);
resp->mmr_exitval = -1;
return;
}
/* metaioctl returns successfully - is start flag cleared? */
if (sf.sf_setflags & MD_SET_MN_START_RC) {
start_flag = 1;
(void) sleep(sleep_time);
sleep_count++;
if ((sleep_count == 1) ||
(sleep_count % SLEEP_MOD) == 0) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MDMN_DO_RESYNC: Waiting for start_step "
"flag for set %s to be cleared\n"),
sp->setname);
}
if (sleep_count == MAX_SLEEPS) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MDMN_DO_RESYNC: Could not clear "
"start_step flag for set %s "
"- returning\n"), sp->setname);
resp->mmr_exitval = -1;
return;
}
} else {
start_flag = 0;
}
}
ret = metaioctl(MD_MN_RESYNC, &respar, &respar.mde, NULL);
if (ret) {
(void) mdstealerror(&(resp->mmr_ep), &respar.mde);
}
resp->mmr_exitval = ret;
}
/*
* handler for MD_MN_MSG_SETSYNC
*/
/*ARGSUSED*/
void
mdmn_do_setsync(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_setsync_t *d;
md_resync_ioctl_t ri;
int ret;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_setsync_t *)((void *)(msg->msg_event_data));
(void) memset(&ri, 0, sizeof (ri));
MD_SETDRIVERNAME(&ri, MD_MIRROR, MD_MIN2SET(d->setsync_mnum))
ri.ri_mnum = d->setsync_mnum;
ri.ri_copysize = d->setsync_copysize;
ri.ri_flags = d->setsync_flags;
ret = metaioctl(MD_MN_SETSYNC, &ri, &ri.mde, NULL);
resp->mmr_exitval = ret;
}
/*
* handler for MD_MN_MSG_SET_CAP. As this handler can deal with both mirrors
* and soft partitions, the driver name that is required for the ioctl call
* is included in the message.
*/
/*ARGSUSED*/
void
mdmn_do_set_cap(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_setcap_t *d;
md_mn_setcap_params_t setcap_ioc;
minor_t mnum;
int ret;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_setcap_t *)((void *)(msg->msg_event_data));
mnum = d->msg_setcap_mnum;
(void) memset(&setcap_ioc, 0, sizeof (setcap_ioc));
MD_SETDRIVERNAME(&setcap_ioc, d->msg_setcap_driver, MD_MIN2SET(mnum));
setcap_ioc.mnum = mnum;
setcap_ioc.sc_set = d->msg_setcap_set;
ret = metaioctl(MD_MN_SET_CAP, &setcap_ioc, &setcap_ioc.mde, NULL);
resp->mmr_exitval = ret;
}
/*
* Dummy handler for various CLASS0 messages like
* MD_MN_MSG_VERBOSITY / MD_MN_MSG_RESUME / MD_MN_MSG_SUSPEND ...
*/
/*ARGSUSED*/
void
mdmn_do_dummy(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_exitval = 0;
resp->mmr_comm_state = MDMNE_ACK;
}
/*
* Overall description of mdcommd support that keeps all nodes in-sync
* with the ondisk diskset mddbs.
*
* All configuration changes to the mddb - addition/deletion of metadevices
* or replicas must use a CLASS1 message to block out these changes.
* Changes to the state of existing replicas do not need to block CLASS1
* since there is no conflict when just updating the state of a replica.
*
* Error encountered when master writes to mddbs:
* As the master updates parts of the mddbs, flags are updated describing
* what has been written. When all locks are dropped (either in
* mddb_setexit or mdioctl), a PARSE message will be generated to all
* nodes with an index list of known good mddbs and the parse flags.
* The master node ignore the parse message since it sent it.
* The slave nodes re-read in the changed part of the mddb using the list
* of known good replicas that was passed.
* PARSE message does not block CLASS1.
* The PARSE message must be the highest class message. Since this
* message could be sent on any ioctl, this PARSE message class must
* be higher than any other class message that could issue an ioctl.
*
* Master Slave1 Slave2
* Handles_error
* PARSE PARSE PARSE
*
*
* Add/Delete mddbs can occur from the following commands:
* metadb -s set_name -a/-d
* metaset -s set_name -a/-d disk
* metaset -s set_name -b
*
* The metadb/metaset command is run on the node executing the command
* and sends an ATTACH/DETACH message to the master node blocking CLASS1
* messages on all nodes until this message is finished. The master
* node generates 3 submessages of BLOCK, SM_ATTACH/SM_DETACH, UNBLOCK.
* The BLOCK message is only run on the master node and will BLOCK
* the PARSE messages from being sent to the nodes.
* The SM_ATTACH/SM_DETACH message is run on all nodes and actually adds or
* removes the replica(s) from the given disk slice.
* The UNBLOCK message is only run on the master node and allows the
* sending of PARSE messages.
*
* Master Slave1 Slave2
* Add mddb cmd
* ATTACH msg to master
* BLOCK
* ATTACH ATTACH ATTACH
* UNBLOCK
* PARSE PARSE PARSE
* ATTACH msg finished
*
* Add/Delete host side information from the following commands:
* metaset -s set_name -a/-d -h
*
* The metaset command is run on the node executing the command and
* sends a DB_NEWSIDE/DB_DELSIDE message and a MD_NEWSIDE/MD_DELSIDE
* message whenever a host is added to or deleted from the diskset.
*
* The side information contains the major name and minor number
* associated with a disk slice from a certain node's perspective
* in an (failed) effort to support clustered systems that don't have the
* same device name for a physical device. (The original designers of
* SVM eventually took the shortcut of assuming that all device names
* are the same on all systems, but left the side information in the
* mddb and namespace.) The side information is used for disk slices
* that contain mddbs and/or are components for metadevices.
*
* The DB_NEWSIDE/DELSIDE command adds or deletes the side information
* for each mddb for the host being added or deleted.
* The MD_ADDSIDE/MD_DELSIDE command adds or deletes the side information
* for all disk slice components that are in the namespace records for
* the host being added or deleted.
*
* The DB_NEWSIDE/DB_DELSIDE message does not change any mddb records
* and only needs to be executed on the master node since the slave
* nodes will be brought up to date by the PARSE message that is
* generated as a result of a change to the mddb.
* The MD_ADDSIDE/MD_DELSIDE message does modify the records in the mddb
* and needs to be run on all nodes. The message must block class1
* messages so that record changing commands don't interfere.
*
* Master Slave1 Slave2
* Add host
* DB_NEWSIDE msg to master
* DB_NEWSIDE
* PARSE PARSE PARSE
* DB_NEWSIDE msg finished
* MD_NEWSIDE msg to master
* MD_NEWSIDE MD_NEWSIDE MD_NEWSIDE
* MD_NEWSIDE msg finished
*
*
* Optimized resync record failure:
* When any node sees a failure to write an optimized resync record
* that node notifies the master node of the replica that failed.
* The master node handles the error and updates the rest of the
* nodes using a PARSE message. The PARSE message also calls
* fixoptrecord on each slave node causing each node to fix up
* the optimized resync records that are owned by that node (the mirror
* owner code also sets the optimized resync record owner). The master
* node will fix up all optimized resync records that have no owner or
* are owned by the master node.
*
* Master Slave1 Slave2
* Optimized Record Failure
* OPTRECERR msg to master
* Master handles opt rec failure
* PARSE PARSE PARSE
* OPTRECERR msg finished
* Slave rewrites optimized record
*
*/
/*
* Handler for MD_MN_MSG_MDDB_PARSE which send parse messages to the
* slave nodes in order to keep the incore view of the mddbs the
* same on all nodes.
*
* Since master node generated the mddb parse message, do nothing
* if this is the master node.
*
* If this is a slave node, send the parse message down to the kernel
* where this node will re-read in parts of the mddbs.
*
*/
void
mdmn_do_mddb_parse(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_mddb_parse_t *d;
mddb_parse_parm_t mpp;
int ret = 0;
int i;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_mddb_parse_t *)((void *)(msg->msg_event_data));
if (flags & MD_MSGF_ON_MASTER)
return;
(void) memset(&mpp, 0, sizeof (mpp));
mpp.c_setno = msg->msg_setno;
mpp.c_parse_flags = d->msg_parse_flags;
for (i = 0; i < MDDB_NLB; i++) {
mpp.c_lb_flags[i] = d->msg_lb_flags[i];
}
ret = metaioctl(MD_MN_MDDB_PARSE, &mpp, &mpp.c_mde, NULL);
if (ret)
(void) mdstealerror(&(resp->mmr_ep), &mpp.c_mde);
resp->mmr_exitval = ret;
}
/*
* Handler for MD_MN_MSG_MDDB_BLOCK which blocks the generation
* of parse messages from this node.
*
* This is needed when attaching/detaching mddbs on the master and the
* slave node is unable to handle a parse message until the slave node
* has done the attach/detach of the mddbs. So, master node will block
* the parse messages, execute the attach/detach on all nodes and
* then unblock the parse messages which causes the parse message to
* be sent to all nodes.
*/
/*ARGSUSED*/
void
mdmn_do_mddb_block(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_mddb_block_t *d;
mddb_block_parm_t mbp;
int ret;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_mddb_block_t *)((void *)(msg->msg_event_data));
(void) memset(&mbp, 0, sizeof (mbp));
mbp.c_setno = msg->msg_setno;
mbp.c_blk_flags = d->msg_block_flags;
ret = metaioctl(MD_MN_MDDB_BLOCK, &mbp, &mbp.c_mde, NULL);
if (ret)
(void) mdstealerror(&(resp->mmr_ep), &mbp.c_mde);
resp->mmr_exitval = ret;
}
/*
* Submessage generator for MD_MN_MSG_META_DB_ATTACH which generates
* a BLOCK message on the master node only, a MD_MN_MSG_SM_MDDB_ATTACH
* message on all nodes and then an UNBLOCK message on the master only.
*/
int
mdmn_smgen_mddb_attach(md_mn_msg_t *msg, md_mn_msg_t *msglist[])
{
md_mn_msg_t *nmsg;
md_mn_msg_meta_db_attach_t *d;
md_mn_msg_meta_db_attach_t *attach_d;
md_mn_msg_mddb_block_t *block_d;
d = (md_mn_msg_meta_db_attach_t *)(void *)msg->msg_event_data;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = (MD_MSGF_NO_LOG | MD_MSGF_NO_BCAST);
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_MDDB_BLOCK;
nmsg->msg_event_size = sizeof (md_mn_msg_mddb_block_t);
nmsg->msg_event_data = Zalloc(sizeof (md_mn_msg_mddb_block_t));
block_d = (md_mn_msg_mddb_block_t *)(void *)nmsg->msg_event_data;
block_d->msg_block_flags = MDDB_BLOCK_PARSE;
msglist[0] = nmsg;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
/* Don't log submessages and panic on inconsistent results */
nmsg->msg_flags = MD_MSGF_NO_LOG |
MD_MSGF_PANIC_WHEN_INCONSISTENT;
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_SM_MDDB_ATTACH;
nmsg->msg_event_size = sizeof (md_mn_msg_meta_db_attach_t);
nmsg->msg_event_data = Zalloc(sizeof (md_mn_msg_meta_db_attach_t));
attach_d = (md_mn_msg_meta_db_attach_t *)
(void *)nmsg->msg_event_data;
attach_d->msg_l_dev = d->msg_l_dev;
attach_d->msg_cnt = d->msg_cnt;
attach_d->msg_dbsize = d->msg_dbsize;
(void) strncpy(attach_d->msg_dname, d->msg_dname, 16);
attach_d->msg_splitname = d->msg_splitname;
attach_d->msg_options = d->msg_options;
msglist[1] = nmsg;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = (MD_MSGF_NO_LOG | MD_MSGF_NO_BCAST);
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_MDDB_BLOCK;
nmsg->msg_event_size = sizeof (md_mn_msg_mddb_block_t);
nmsg->msg_event_data = Zalloc(sizeof (md_mn_msg_mddb_block_t));
block_d = (md_mn_msg_mddb_block_t *)(void *)nmsg->msg_event_data;
block_d->msg_block_flags = MDDB_UNBLOCK_PARSE;
msglist[2] = nmsg;
return (3); /* Return the number of submessages generated */
}
/*
* Submessage generator for MD_MN_MSG_META_DB_DETACH which generates
* a BLOCK message on the master node only, a MD_MN_MSG_SM_MDDB_DETACH
* message on all nodes and then an UNBLOCK message on the master only.
*/
int
mdmn_smgen_mddb_detach(md_mn_msg_t *msg, md_mn_msg_t *msglist[])
{
md_mn_msg_t *nmsg;
md_mn_msg_meta_db_detach_t *d;
md_mn_msg_meta_db_detach_t *detach_d;
md_mn_msg_mddb_block_t *block_d;
d = (md_mn_msg_meta_db_detach_t *)(void *)msg->msg_event_data;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = (MD_MSGF_NO_LOG | MD_MSGF_NO_BCAST);
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_MDDB_BLOCK;
nmsg->msg_event_size = sizeof (md_mn_msg_mddb_block_t);
nmsg->msg_event_data = Zalloc(sizeof (md_mn_msg_mddb_block_t));
block_d = (md_mn_msg_mddb_block_t *)(void *)nmsg->msg_event_data;
block_d->msg_block_flags = MDDB_BLOCK_PARSE;
msglist[0] = nmsg;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
/* Don't log submessages and panic on inconsistent results */
nmsg->msg_flags = MD_MSGF_NO_LOG |
MD_MSGF_PANIC_WHEN_INCONSISTENT;
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_SM_MDDB_DETACH;
nmsg->msg_event_size = sizeof (md_mn_msg_meta_db_detach_t);
nmsg->msg_event_data = Zalloc(sizeof (md_mn_msg_meta_db_detach_t));
detach_d = (md_mn_msg_meta_db_detach_t *)
(void *)nmsg->msg_event_data;
detach_d->msg_splitname = d->msg_splitname;
msglist[1] = nmsg;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = (MD_MSGF_NO_LOG | MD_MSGF_NO_BCAST);
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_MDDB_BLOCK;
nmsg->msg_event_size = sizeof (md_mn_msg_mddb_block_t);
nmsg->msg_event_data = Zalloc(sizeof (md_mn_msg_mddb_block_t));
block_d = (md_mn_msg_mddb_block_t *)(void *)nmsg->msg_event_data;
block_d->msg_block_flags = MDDB_UNBLOCK_PARSE;
msglist[2] = nmsg;
return (3); /* Return the number of submessages generated */
}
/*
* Handler for MD_MN_MSG_SM_MDDB_ATTACH which is used to attach mddbs.
*
* Used when running:
* metadb -s set_name -a
* metaset -s set_name -a/-d disk
* metaset -s set_name -b
*/
/*ARGSUSED*/
void
mdmn_do_sm_mddb_attach(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_meta_db_attach_t *d;
struct mddb_config c;
int i;
int ret = 0;
md_error_t ep = mdnullerror;
char *name, *add_name;
mdname_t *np;
mdsetname_t *sp;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_meta_db_attach_t *)((void *)(msg->msg_event_data));
(void) memset(&c, 0, sizeof (c));
c.c_setno = msg->msg_setno;
c.c_locator.l_dev = meta_cmpldev(d->msg_l_dev);
(void) strncpy(c.c_locator.l_driver, d->msg_dname,
sizeof (c.c_locator.l_driver));
c.c_devname = d->msg_splitname;
c.c_locator.l_mnum = meta_getminor(d->msg_l_dev);
c.c_multi_node = 1;
if ((sp = metasetnosetname(c.c_setno, &ep)) == NULL) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
(void) strcpy(c.c_setname, sp->setname);
c.c_sideno = getmyside(sp, &ep);
if (c.c_sideno == MD_SIDEWILD) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
name = splicename(&d->msg_splitname);
np = metaname(&sp, name, LOGICAL_DEVICE, &ep);
Free(name);
if (np == NULL) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
/*
* All nodes in MN diskset must do meta_check_replica
* since this causes the shared namespace to be
* populated by the md driver names while checking
* to see if this device is already in use as a
* metadevice.
*/
if (meta_check_replica(sp, np, d->msg_options, 0,
(d->msg_cnt * d->msg_dbsize), &ep)) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
for (i = 0; i < d->msg_cnt; i++) {
c.c_locator.l_blkno = i * d->msg_dbsize + 16;
if (setup_med_cfg(sp, &c,
(d->msg_options & MDCHK_SET_FORCE), &ep)) {
ret = -1;
(void) mdstealerror(&(resp->mmr_ep), &ep);
break;
}
ret = metaioctl(MD_DB_NEWDEV, &c, &c.c_mde, NULL);
/* If newdev was successful, continue with attach */
if (ret == 0) {
if (meta_db_addsidenms(sp, np, c.c_locator.l_blkno,
DB_ADDSIDENMS_NO_BCAST, &ep)) {
ret = -1;
(void) mdstealerror(&(resp->mmr_ep), &ep);
break;
}
} else {
(void) mdstealerror(&(resp->mmr_ep), &c.c_mde);
break;
}
}
add_name = splicename(&d->msg_splitname);
if ((np = metaname(&sp, add_name, LOGICAL_DEVICE, &ep)) != NULL) {
meta_invalidate_name(np);
} else {
ret = -1;
(void) mdstealerror(&(resp->mmr_ep), &ep);
}
Free(add_name);
resp->mmr_exitval = ret;
}
/*
* Handler for MD_MN_MSG_SM_MDDB_DETACH which is used to detach mddbs.
*
* Used when running:
* metadb -s set_name -d
* metaset -s set_name -a/-d disk
* metaset -s set_name -b
*/
/*ARGSUSED*/
void
mdmn_do_sm_mddb_detach(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_meta_db_detach_t *d;
struct mddb_config c;
int i;
int ret = 0;
md_error_t ep = mdnullerror;
char *name, *del_name;
mdname_t *np;
mdsetname_t *sp;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_meta_db_detach_t *)((void *)(msg->msg_event_data));
if ((sp = metasetnosetname(msg->msg_setno, &ep)) == NULL) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
(void) memset(&c, 0, sizeof (c));
c.c_setno = msg->msg_setno;
if (metaioctl(MD_DB_GETDEV, &c, &c.c_mde, NULL) != 0) {
resp->mmr_exitval = -1;
(void) mdstealerror(&(resp->mmr_ep), &c.c_mde);
return;
}
i = 0;
del_name = splicename(&d->msg_splitname);
while (i < c.c_dbcnt) {
c.c_id = i;
if (metaioctl(MD_DB_GETDEV, &c, &c.c_mde, NULL) != 0) {
ret = -1;
(void) mdstealerror(&(resp->mmr_ep), &c.c_mde);
break;
}
name = splicename(&c.c_devname);
if (strcmp(name, del_name) != 0) {
Free(name);
i++;
continue;
}
Free(name);
/* Found a match - delete mddb */
if (metaioctl(MD_DB_DELDEV, &c, &c.c_mde, NULL) != 0) {
ret = -1;
(void) mdstealerror(&(resp->mmr_ep), &c.c_mde);
break;
}
/* Not incrementing "i" intentionally (dbcnt is changed) */
}
if ((np = metaname(&sp, del_name, LOGICAL_DEVICE, &ep)) != NULL) {
meta_invalidate_name(np);
} else {
ret = -1;
(void) mdstealerror(&(resp->mmr_ep), &ep);
}
Free(del_name);
resp->mmr_exitval = ret;
}
/*
* Handler for MD_MN_MSG_META_DB_NEWSIDE which is used to update the
* side information for each diskset mddb when a new host has been
* added to the diskset. The side information is the /dev/dsk/ctds name
* that the new node would use to access each mddb.
*
* Since this routine makes no changes to the records in the diskset mddb,
* this routine only needs to be run on the master node. The master node's
* kernel code will detect that portions of the mddb have changed and
* will send a parse message to all nodes to re-parse parts of the mddb.
*
* Used when running:
* metaset -s set_name -a -h new_hostname
*/
/*ARGSUSED*/
void
mdmn_do_meta_db_newside(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_meta_db_newside_t *d;
struct mddb_config c;
int ret = 0;
mdsetname_t *sp;
md_error_t ep = mdnullerror;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_meta_db_newside_t *)((void *)(msg->msg_event_data));
(void) memset(&c, 0, sizeof (c));
c.c_setno = msg->msg_setno;
c.c_locator.l_dev = meta_cmpldev(d->msg_l_dev);
c.c_locator.l_blkno = d->msg_blkno;
(void) strncpy(c.c_locator.l_driver, d->msg_dname,
sizeof (c.c_locator.l_driver));
c.c_devname = d->msg_splitname;
c.c_locator.l_mnum = d->msg_mnum;
c.c_multi_node = 1;
if ((sp = metasetnosetname(c.c_setno, &ep)) == NULL) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
(void) strcpy(c.c_setname, sp->setname);
c.c_sideno = d->msg_sideno;
if ((ret = metaioctl(MD_DB_NEWSIDE, &c, &c.c_mde, NULL)) != 0) {
(void) mdstealerror(&(resp->mmr_ep), &c.c_mde);
}
resp->mmr_exitval = ret;
}
/*
* Handler for MD_MN_MSG_META_DB_DELSIDE which is used to remove the
* side information for each diskset mddb when a host has been
* deleted from the diskset. The side information is the /dev/dsk/ctds name
* that the node would use to access each mddb.
*
* Since this routine makes no changes to the records in the diskset mddb,
* this routine only needs to be run on the master node. The master node's
* kernel code will detect that portions of the mddb have changed and
* will send a parse message to all nodes to re-parse parts of the mddb.
*
* Used when running:
* metaset -s set_name -d -h hostname
*/
/*ARGSUSED*/
void
mdmn_do_meta_db_delside(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_meta_db_delside_t *d;
mddb_config_t c;
int ret = 0;
mdsetname_t *sp;
md_error_t ep = mdnullerror;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_meta_db_delside_t *)((void *)(msg->msg_event_data));
(void) memset(&c, 0, sizeof (c));
c.c_setno = msg->msg_setno;
c.c_locator.l_dev = meta_cmpldev(d->msg_l_dev);
c.c_locator.l_blkno = d->msg_blkno;
c.c_multi_node = 1;
if ((sp = metasetnosetname(c.c_setno, &ep)) == NULL) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
(void) strcpy(c.c_setname, sp->setname);
c.c_sideno = d->msg_sideno;
if ((ret = metaioctl(MD_DB_DELSIDE, &c, &c.c_mde, NULL)) != 0) {
(void) mdstealerror(&(resp->mmr_ep), &c.c_mde);
}
resp->mmr_exitval = ret;
}
/*
* Handler for MD_MN_MSG_META_MD_ADDSIDE which is used to add the
* side information for each diskset metadevice component (if that
* component is a disk) when a host has been added to the diskset.
* The side information is the /dev/dsk/ctds name that the node would
* use to access the metadevice component.
*
* This routine makes changes to the mddb records and must be run
* on all nodes.
*
* Used when running:
* metaset -s set_name -a -h new_hostname
*/
/*ARGSUSED*/
void
mdmn_do_meta_md_addside(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_meta_md_addside_t *d;
mdnm_params_t nm;
mdsetname_t *sp;
char *cname, *dname;
minor_t mnum;
int done, i;
md_error_t ep = mdnullerror;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_meta_md_addside_t *)((void *)(msg->msg_event_data));
(void) memset(&nm, 0, sizeof (nm));
if ((sp = metasetnosetname(msg->msg_setno, &ep)) == NULL) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
/* While loop continues until IOCNXTKEY_NM gives nm.key of KEYWILD */
/*CONSTCOND*/
while (1) {
char *drvnm = NULL;
nm.mde = mdnullerror;
nm.setno = msg->msg_setno;
nm.side = d->msg_otherside;
if (metaioctl(MD_IOCNXTKEY_NM, &nm, &nm.mde, NULL) != 0) {
(void) mdstealerror(&(resp->mmr_ep), &nm.mde);
resp->mmr_exitval = -1;
return;
}
/* Normal exit path is to eventually get a KEYWILD */
if (nm.key == MD_KEYWILD) {
resp->mmr_exitval = 0;
return;
}
/*
* Okay we have a valid key
* Let's see if it is hsp or not
*/
nm.devname = (uintptr_t)meta_getnmentbykey(msg->msg_setno,
d->msg_otherside, nm.key, &drvnm, NULL, NULL, &ep);
if (nm.devname == NULL || drvnm == NULL) {
if (nm.devname)
Free((void *)(uintptr_t)nm.devname);
if (drvnm)
Free((void *)(uintptr_t)drvnm);
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
/*
* If it is hsp add here
*/
if (strcmp(drvnm, MD_HOTSPARES) == 0) {
if (add_name(sp, d->msg_sideno, nm.key, MD_HOTSPARES,
minor(NODEV), (char *)(uintptr_t)nm.devname,
NULL, NULL, &ep) == -1) {
Free((void *)(uintptr_t)nm.devname);
Free((void *)(uintptr_t)drvnm);
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
} else {
Free((void *)(uintptr_t)nm.devname);
Free((void *)(uintptr_t)drvnm);
continue;
}
}
nm.side = d->msg_sideno;
if ((done = meta_getside_devinfo(sp,
(char *)(uintptr_t)nm.devname,
d->msg_sideno, &cname, &dname, &mnum, &ep)) == -1) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
Free((void *)(uintptr_t)nm.devname);
resp->mmr_exitval = -1;
return;
}
Free((void *)(uintptr_t)nm.devname);
Free((void *)(uintptr_t)drvnm);
if (done != 1) {
Free(cname);
Free(dname);
resp->mmr_exitval = -1;
return;
}
/*
* The device reference count can be greater than 1 if
* more than one softpart is configured on top of the
* same device. If this is the case then we want to
* increment the count to sync up with the other sides.
*/
for (i = 0; i < nm.ref_count; i++) {
if (add_name(sp, d->msg_sideno, nm.key, dname, mnum,
cname, NULL, NULL, &ep) == -1) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
Free(cname);
Free(dname);
resp->mmr_exitval = -1;
return;
}
}
Free(cname);
Free(dname);
}
/*NOTREACHED*/
}
/*
* Handler for MD_MN_MSG_META_MD_DELSIDE which is used to delete the
* side information for each diskset metadevice component (if that
* component is a disk) when a host has been removed from the diskset.
* The side information is the /dev/dsk/ctds name that the node would
* use to access the metadevice component.
*
* This routine makes changes to the mddb records and must be run
* on all nodes.
*
* Used when running:
* metaset -s set_name -d -h hostname
*/
/*ARGSUSED*/
void
mdmn_do_meta_md_delside(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_meta_md_delside_t *d;
mdnm_params_t nm;
mdsetname_t *sp;
md_error_t ep = mdnullerror;
int i;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_meta_md_delside_t *)((void *)(msg->msg_event_data));
if ((sp = metasetnosetname(msg->msg_setno, &ep)) == NULL) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
(void) memset(&nm, 0, sizeof (nm));
nm.key = MD_KEYWILD;
/*CONSTCOND*/
while (1) {
nm.mde = mdnullerror;
nm.setno = msg->msg_setno;
nm.side = MD_SIDEWILD;
if (metaioctl(MD_IOCNXTKEY_NM, &nm, &nm.mde, NULL) != 0) {
(void) mdstealerror(&(resp->mmr_ep), &nm.mde);
resp->mmr_exitval = -1;
return;
}
/* Normal exit path is to eventually get a KEYWILD */
if (nm.key == MD_KEYWILD) {
resp->mmr_exitval = 0;
return;
}
/*
* The device reference count can be greater than 1 if
* more than one softpart is configured on top of the
* same device. If this is the case then we want to
* decrement the count to zero so the entry can be
* actually removed.
*/
for (i = 0; i < nm.ref_count; i++) {
if (del_name(sp, d->msg_sideno, nm.key, &ep) == -1) {
(void) mdstealerror(&(resp->mmr_ep), &ep);
resp->mmr_exitval = -1;
return;
}
}
}
/*NOTREACHED*/
}
/*
* Handler for MD_MN_MSG_MDDB_OPTRECERR which is used to notify
* the master node that a node has seen an error when attempting to
* write to the optimized resync records that reside on 2 of the diskset
* mddbs. Master node will mark the failed replica in error and this
* will send a parse message to all nodes to re-read parts of the mddb
* and to fix their optimized resync records based on this information.
*/
/*ARGSUSED*/
void
mdmn_do_mddb_optrecerr(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_mddb_optrecerr_t *d;
mddb_optrec_parm_t mop;
int ret;
int i;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_mddb_optrecerr_t *)((void *)(msg->msg_event_data));
(void) memset(&mop, 0, sizeof (mop));
mop.c_setno = msg->msg_setno;
for (i = 0; i < 2; i++) {
mop.c_recerr[i] = d->msg_recerr[i];
}
ret = metaioctl(MD_MN_MDDB_OPTRECFIX, &mop, &mop.c_mde, NULL);
if (ret)
(void) mdstealerror(&(resp->mmr_ep), &mop.c_mde);
resp->mmr_exitval = ret;
}
int
mdmn_smgen_test6(md_mn_msg_t *msg, md_mn_msg_t **msglist)
{
md_mn_msg_t *nmsg;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = MD_MSGF_NO_LOG; /* Don't log submessages */
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_TEST2;
nmsg->msg_event_size = sizeof ("test2");
nmsg->msg_event_data = Strdup("test2");
msglist[0] = nmsg;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = MD_MSGF_NO_LOG; /* Don't log submessages */
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_TEST2;
nmsg->msg_event_size = sizeof ("test2");
nmsg->msg_event_data = Strdup("test2");
msglist[1] = nmsg;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = MD_MSGF_NO_LOG; /* Don't log submessages */
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_TEST3;
nmsg->msg_event_size = sizeof ("test3");
nmsg->msg_event_data = Strdup("test3");
msglist[2] = nmsg;
nmsg = Zalloc(sizeof (md_mn_msg_t));
MSGID_COPY(&(msg->msg_msgid), &(nmsg->msg_msgid));
nmsg->msg_flags = MD_MSGF_NO_LOG; /* Don't log submessages */
nmsg->msg_setno = msg->msg_setno;
nmsg->msg_type = MD_MN_MSG_TEST4;
nmsg->msg_event_size = sizeof ("test4");
nmsg->msg_event_data = Strdup("test4");
msglist[3] = nmsg;
return (4); /* Return the number of submessages generated */
}
/*
* This is to send an MD_IOCSET ioctl to all nodes to create a soft
* partition.
*/
/*ARGSUSED*/
void
mdmn_do_iocset(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_iocset_t *d;
int ret;
set_t setno;
mdsetname_t *sp;
mdname_t *np;
md_error_t mde = mdnullerror;
resp->mmr_comm_state = MDMNE_ACK; /* Ok state */;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
d = (md_mn_msg_iocset_t *)(void *)msg->msg_event_data;
setno = MD_MIN2SET(d->iocset_params.mnum);
if ((sp = metasetnosetname(setno, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_MSG_IOCSET: Invalid setno %d\n"), setno);
resp->mmr_exitval = 1;
return;
}
/*
* Device should be in the namespace already
*/
if ((np = metamnumname(&sp, d->iocset_params.mnum, 1, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_MSG_IOCSET: Invalid mnum %d\n"),
d->iocset_params.mnum);
resp->mmr_exitval = 1;
return;
}
/*
* Create unit structure
*/
d->iocset_params.mdp = (uintptr_t)&d->unit; /* set pointer to unit */
ret = metaioctl(MD_IOCSET, &(d->iocset_params), &mde, np->cname);
resp->mmr_exitval = ret;
}
/*
* This is to update the status of a softpart
*/
/*ARGSUSED*/
void
mdmn_do_sp_setstat(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_sp_setstat_t *d;
int ret;
set_t setno;
mdsetname_t *sp;
minor_t mnum;
md_error_t mde = mdnullerror;
resp->mmr_comm_state = MDMNE_ACK; /* Ok state */;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
d = (md_mn_msg_sp_setstat_t *)(void *)msg->msg_event_data;
mnum = d->sp_setstat_mnum;
setno = MD_MIN2SET(mnum);
if ((sp = metasetnosetname(setno, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_MSG_IOCSET: Invalid setno %d\n"), setno);
resp->mmr_exitval = 1;
return;
}
ret = meta_sp_setstatus(sp, &mnum, 1, d->sp_setstat_status, &mde);
resp->mmr_exitval = ret;
}
/*
* This is to add a key to the namespace
*/
/*ARGSUSED*/
void
mdmn_do_addkeyname(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_addkeyname_t *d;
int ret;
set_t setno;
mdsetname_t *sp;
md_error_t mde = mdnullerror;
mdname_t *compnp;
resp->mmr_comm_state = MDMNE_ACK; /* Ok state */;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
d = (md_mn_msg_addkeyname_t *)(void *)msg->msg_event_data;
setno = d->addkeyname_setno;
if ((sp = metasetnosetname(setno, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_ADDKEYNAME: Invalid setno %d\n"), setno);
resp->mmr_exitval = -1;
return;
}
compnp = metaname(&sp, d->addkeyname_name, UNKNOWN, &mde);
if (compnp != NULL) {
ret = add_key_name(sp, compnp, NULL, &mde);
if (ret < 0)
resp->mmr_exitval = -1;
else
resp->mmr_exitval = compnp->key;
} else {
resp->mmr_exitval = -1;
}
}
/*
* This is to delete a key from the namespace
*/
/*ARGSUSED*/
void
mdmn_do_delkeyname(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_delkeyname_t *d;
int ret;
set_t setno;
mdsetname_t *sp;
md_error_t mde = mdnullerror;
mdname_t *compnp;
resp->mmr_comm_state = MDMNE_ACK; /* Ok state */;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
d = (md_mn_msg_delkeyname_t *)(void *)msg->msg_event_data;
setno = d->delkeyname_setno;
if ((sp = metasetnosetname(setno, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_DELKEYNAME: Invalid setno %d\n"), setno);
resp->mmr_exitval = -1;
return;
}
compnp = metadevname(&sp, d->delkeyname_dev, &mde);
if (compnp != NULL) {
/*
* Reset the key value for the name. This is required because
* any previous call of del_key_name for the same component
* will have resulted in the key value being reset to MD_KEYBAD
* even though there may still be references to this component.
*/
compnp->key = d->delkeyname_key;
ret = del_key_name(sp, compnp, &mde);
resp->mmr_exitval = ret;
} else {
resp->mmr_exitval = -1;
}
}
/*
* This is to get the value of tstate from the master node. We use this
* to get the ABR state of a metadevice from the master.
*/
/*ARGSUSED*/
void
mdmn_do_get_tstate(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_gettstate_t *d;
int ret;
uint_t tstate;
md_error_t mde = mdnullerror;
resp->mmr_comm_state = MDMNE_ACK; /* Ok state */;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
d = (md_mn_msg_gettstate_t *)(void *)msg->msg_event_data;
ret = meta_get_tstate(d->gettstate_dev, &tstate, &mde);
if (ret != 0) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_GET_TSTATE: Invalid dev %llx\n"), d->gettstate_dev);
tstate = 0;
}
resp->mmr_exitval = tstate;
}
/*
* This is to get the mirror ABR state and the state of its submirrors from
* the master node. We need this to ensure consistent output from metastat
* when a new node joins the cluster during a resync. Without this the
* submirror status will be incorrect until the whole resync is complete which
* may take days for very large metadevices.
*/
/*ARGSUSED*/
void
mdmn_do_get_mirstate(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_mir_state_t *d;
md_mn_msg_mir_state_res_t *res; /* Results */
set_t setno;
mdsetname_t *sp; /* Set name */
mdname_t *mirnp; /* Mirror name */
md_error_t mde = mdnullerror;
mm_unit_t *mm; /* Mirror */
int smi;
uint_t tstate;
resp->mmr_comm_state = MDMNE_ACK;
resp->mmr_out_size = sizeof (md_mn_msg_mir_state_res_t);
resp->mmr_err_size = 0;
resp->mmr_out = Malloc(resp->mmr_out_size);
resp->mmr_err = NULL;
d = (md_mn_msg_mir_state_t *)(void *)msg->msg_event_data;
res = (md_mn_msg_mir_state_res_t *)(void *)resp->mmr_out;
/* Validate set information from minor number */
setno = MD_MIN2SET(d->mir_state_mnum);
sp = metasetnosetname(setno, &mde);
if (sp == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_GET_MIRROR_STATE: Invalid set %d\n"), setno);
resp->mmr_exitval = 1; /* Failure */
Free(resp->mmr_out);
resp->mmr_out_size = 0;
return;
}
/* Construct mirror name from minor number */
mirnp = metamnumname(&sp, d->mir_state_mnum, 0, &mde);
if (mirnp == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_GET_MIRROR_STATE: Invalid minor %lx\n"),
d->mir_state_mnum);
resp->mmr_exitval = 2; /* Failure */
Free(resp->mmr_out);
resp->mmr_out_size = 0;
return;
}
/* Get common mirror structure */
mm = (mm_unit_t *)meta_get_mdunit(sp, mirnp, &mde);
if (mm == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_GET_MIRROR_STATE: Invalid mirror minor %x\n"),
d->mir_state_mnum);
resp->mmr_exitval = 3; /* Failure */
Free(resp->mmr_out);
resp->mmr_out_size = 0;
return;
}
if (meta_get_tstate(d->mir_state_mnum, &tstate, &mde) != 0) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_GET_MIRROR_STATE: Invalid minor %lx\n"),
d->mir_state_mnum);
resp->mmr_exitval = 4; /* Failure */
Free(resp->mmr_out);
resp->mmr_out_size = 0;
return;
}
/*
* Fill in the sm_state/sm_flags value in the results structure which
* gets passed back to the message originator
*/
resp->mmr_exitval = 0;
for (smi = 0; (smi < NMIRROR); smi++) {
mm_submirror_t *mmsp = &mm->un_sm[smi];
res->sm_state[smi] = mmsp->sm_state;
res->sm_flags[smi] = mmsp->sm_flags;
}
/* Returm value of tstate for mirror */
res->mir_tstate = tstate;
}
/*
* This is to issue an ioctl to call poke_hotspares
*/
/*ARGSUSED*/
void
mdmn_do_poke_hotspares(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_poke_hotspares_t pokehsp;
md_mn_msg_pokehsp_t *d;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_pokehsp_t *)(void *)msg->msg_event_data;
(void) memset(&pokehsp, 0, sizeof (pokehsp));
MD_SETDRIVERNAME(&pokehsp, MD_MIRROR, d->pokehsp_setno);
resp->mmr_exitval = metaioctl(MD_MN_POKE_HOTSPARES, &pokehsp,
&pokehsp.mde, NULL);
}
/*
* Called to create a softpart during a metarecover operation
*/
/*ARGSUSED*/
void
mdmn_do_addmdname(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_addmdname_t *d;
md_error_t mde = mdnullerror;
mdsetname_t *sp;
int init = 0;
mdkey_t key;
minor_t mnum;
resp->mmr_comm_state = MDMNE_ACK; /* Ok state */;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
d = (md_mn_msg_addmdname_t *)(void *)msg->msg_event_data;
if ((sp = metasetnosetname(d->addmdname_setno, &mde)) == NULL) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_MSG_ADDMDNAME: Invalid setno %d\n"),
d->addmdname_setno);
resp->mmr_exitval = 1;
return;
}
/*
* If device node does not exist then init it
*/
if (!is_existing_meta_hsp(sp, d->addmdname_name)) {
if ((key = meta_init_make_device(&sp, d->addmdname_name,
&mde)) <= 0) {
syslog(LOG_ERR, dgettext(TEXT_DOMAIN,
"MD_MN_MSG_ADDMDNAME: Invalid name %s\n"),
d->addmdname_name);
resp->mmr_exitval = 1;
return;
}
init = 1;
}
/*
* We should have it
*/
if (metaname(&sp, d->addmdname_name, META_DEVICE, &mde) == NULL) {
if (init) {
if (meta_getnmentbykey(sp->setno, MD_SIDEWILD,
key, NULL, &mnum, NULL, &mde) != NULL) {
(void) metaioctl(
MD_IOCREM_DEV, &mnum, &mde, NULL);
}
(void) del_self_name(sp, key, &mde);
}
resp->mmr_exitval = 1;
return;
}
resp->mmr_exitval = 0;
}
/*
* This is used to issue a MD_MN_RR_DIRTY ioctl to the mirror.
*/
/*ARGSUSED*/
void
mdmn_do_mark_dirty(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_rr_dirty_t *d;
md_mn_rr_dirty_params_t rp;
int ret;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_rr_dirty_t *)((void *)(msg->msg_event_data));
(void) memset(&rp, 0, sizeof (rp));
MD_SETDRIVERNAME(&rp, MD_MIRROR, MD_MIN2SET(d->rr_mnum))
rp.rr_mnum = d->rr_mnum;
rp.rr_nodeid = d->rr_nodeid;
rp.rr_start = (ushort_t)((d->rr_range >> 16) & 0xffff);
rp.rr_end = (ushort_t)(d->rr_range & 0xffff);
ret = metaioctl(MD_MN_RR_DIRTY, &rp, &rp.mde, NULL);
resp->mmr_exitval = ret;
}
/*
* This is used to issue a MD_MN_RR_CLEAN ioctl to the mirror.
*/
/*ARGSUSED*/
void
mdmn_do_mark_clean(md_mn_msg_t *msg, uint_t flags, md_mn_result_t *resp)
{
md_mn_msg_rr_clean_t *d;
md_mn_rr_clean_params_t *rcp;
int ret;
resp->mmr_out_size = 0;
resp->mmr_err_size = 0;
resp->mmr_out = NULL;
resp->mmr_err = NULL;
resp->mmr_comm_state = MDMNE_ACK;
d = (md_mn_msg_rr_clean_t *)((void *)(msg->msg_event_data));
rcp = Zalloc(sizeof (struct md_mn_rr_clean_params) +
MDMN_MSG_RR_CLEAN_DATA_BYTES(d));
MD_SETDRIVERNAME(rcp, MD_MIRROR, MD_MIN2SET(d->rr_mnum))
rcp->rr_mnum = d->rr_mnum;
rcp->rr_nodeid = d->rr_nodeid;
rcp->rr_start_size = d->rr_start_size;
(void) memcpy(MDMN_RR_CLEAN_PARAMS_DATA(rcp), MDMN_MSG_RR_CLEAN_DATA(d),
MDMN_MSG_RR_CLEAN_DATA_BYTES(d));
ret = metaioctl(MD_MN_RR_CLEAN, rcp, &rcp->mde, NULL);
Free(rcp);
resp->mmr_exitval = ret;
}