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samba-mirror/ctdb/server/ctdb_recoverd.c
Martin Schwenke 44a0466ac1 ctdb-recoverd: Only respond to currently queued ipreallocated requests
Otherwise new requests can come in during the latter parts of the
takeover run when the IP allocation algorithm has already run, and the
new requests will be dequeued even though they haven't really be
processed.

Signed-off-by: Martin Schwenke <martin@meltin.net>
Pair-programmed-with: Amitay Isaacs <amitay@gmail.com>
Reviewed-by: Michael Adam <obnox@samba.org>
2013-11-27 18:46:16 +01:00

4335 lines
120 KiB
C

/*
ctdb recovery daemon
Copyright (C) Ronnie Sahlberg 2007
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#include "includes.h"
#include "system/filesys.h"
#include "system/time.h"
#include "system/network.h"
#include "system/wait.h"
#include "popt.h"
#include "cmdline.h"
#include "../include/ctdb_client.h"
#include "../include/ctdb_private.h"
#include "db_wrap.h"
#include "dlinklist.h"
/* List of SRVID requests that need to be processed */
struct srvid_list {
struct srvid_list *next, *prev;
struct srvid_request *request;
};
struct srvid_requests {
struct srvid_list *requests;
};
static void srvid_request_reply(struct ctdb_context *ctdb,
struct srvid_request *request,
TDB_DATA result)
{
/* Someone that sent srvid==0 does not want a reply */
if (request->srvid == 0) {
talloc_free(request);
return;
}
if (ctdb_client_send_message(ctdb, request->pnn, request->srvid,
result) == 0) {
DEBUG(DEBUG_INFO,("Sent SRVID reply to %u:%llu\n",
(unsigned)request->pnn,
(unsigned long long)request->srvid));
} else {
DEBUG(DEBUG_ERR,("Failed to send SRVID reply to %u:%llu\n",
(unsigned)request->pnn,
(unsigned long long)request->srvid));
}
talloc_free(request);
}
static void srvid_requests_reply(struct ctdb_context *ctdb,
struct srvid_requests **requests,
TDB_DATA result)
{
struct srvid_list *r;
for (r = (*requests)->requests; r != NULL; r = r->next) {
srvid_request_reply(ctdb, r->request, result);
}
/* Free the list structure... */
TALLOC_FREE(*requests);
}
static void srvid_request_add(struct ctdb_context *ctdb,
struct srvid_requests **requests,
struct srvid_request *request)
{
struct srvid_list *t;
int32_t ret;
TDB_DATA result;
if (*requests == NULL) {
*requests = talloc_zero(ctdb, struct srvid_requests);
if (*requests == NULL) {
goto nomem;
}
}
t = talloc_zero(*requests, struct srvid_list);
if (t == NULL) {
/* If *requests was just allocated above then free it */
if ((*requests)->requests == NULL) {
TALLOC_FREE(*requests);
}
goto nomem;
}
t->request = (struct srvid_request *)talloc_steal(t, request);
DLIST_ADD((*requests)->requests, t);
return;
nomem:
/* Failed to add the request to the list. Send a fail. */
DEBUG(DEBUG_ERR, (__location__
" Out of memory, failed to queue SRVID request\n"));
ret = -ENOMEM;
result.dsize = sizeof(ret);
result.dptr = (uint8_t *)&ret;
srvid_request_reply(ctdb, request, result);
}
struct ctdb_banning_state {
uint32_t count;
struct timeval last_reported_time;
};
/*
private state of recovery daemon
*/
struct ctdb_recoverd {
struct ctdb_context *ctdb;
uint32_t recmaster;
uint32_t num_active;
uint32_t num_lmasters;
uint32_t num_connected;
uint32_t last_culprit_node;
struct ctdb_node_map *nodemap;
struct timeval priority_time;
bool need_takeover_run;
bool need_recovery;
uint32_t node_flags;
struct timed_event *send_election_te;
struct timed_event *election_timeout;
struct vacuum_info *vacuum_info;
struct srvid_requests *reallocate_requests;
bool takeover_run_in_progress;
TALLOC_CTX *takeover_runs_disable_ctx;
struct ctdb_control_get_ifaces *ifaces;
uint32_t *force_rebalance_nodes;
};
#define CONTROL_TIMEOUT() timeval_current_ofs(ctdb->tunable.recover_timeout, 0)
#define MONITOR_TIMEOUT() timeval_current_ofs(ctdb->tunable.recover_interval, 0)
static void ctdb_restart_recd(struct event_context *ev, struct timed_event *te, struct timeval t, void *private_data);
/*
ban a node for a period of time
*/
static void ctdb_ban_node(struct ctdb_recoverd *rec, uint32_t pnn, uint32_t ban_time)
{
int ret;
struct ctdb_context *ctdb = rec->ctdb;
struct ctdb_ban_time bantime;
if (!ctdb_validate_pnn(ctdb, pnn)) {
DEBUG(DEBUG_ERR,("Bad pnn %u in ctdb_ban_node\n", pnn));
return;
}
DEBUG(DEBUG_NOTICE,("Banning node %u for %u seconds\n", pnn, ban_time));
bantime.pnn = pnn;
bantime.time = ban_time;
ret = ctdb_ctrl_set_ban(ctdb, CONTROL_TIMEOUT(), pnn, &bantime);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to ban node %d\n", pnn));
return;
}
}
enum monitor_result { MONITOR_OK, MONITOR_RECOVERY_NEEDED, MONITOR_ELECTION_NEEDED, MONITOR_FAILED};
/*
remember the trouble maker
*/
static void ctdb_set_culprit_count(struct ctdb_recoverd *rec, uint32_t culprit, uint32_t count)
{
struct ctdb_context *ctdb = talloc_get_type(rec->ctdb, struct ctdb_context);
struct ctdb_banning_state *ban_state;
if (culprit > ctdb->num_nodes) {
DEBUG(DEBUG_ERR,("Trying to set culprit %d but num_nodes is %d\n", culprit, ctdb->num_nodes));
return;
}
/* If we are banned or stopped, do not set other nodes as culprits */
if (rec->node_flags & NODE_FLAGS_INACTIVE) {
DEBUG(DEBUG_NOTICE, ("This node is INACTIVE, cannot set culprit node %d\n", culprit));
return;
}
if (ctdb->nodes[culprit]->ban_state == NULL) {
ctdb->nodes[culprit]->ban_state = talloc_zero(ctdb->nodes[culprit], struct ctdb_banning_state);
CTDB_NO_MEMORY_VOID(ctdb, ctdb->nodes[culprit]->ban_state);
}
ban_state = ctdb->nodes[culprit]->ban_state;
if (timeval_elapsed(&ban_state->last_reported_time) > ctdb->tunable.recovery_grace_period) {
/* this was the first time in a long while this node
misbehaved so we will forgive any old transgressions.
*/
ban_state->count = 0;
}
ban_state->count += count;
ban_state->last_reported_time = timeval_current();
rec->last_culprit_node = culprit;
}
/*
remember the trouble maker
*/
static void ctdb_set_culprit(struct ctdb_recoverd *rec, uint32_t culprit)
{
ctdb_set_culprit_count(rec, culprit, 1);
}
/* this callback is called for every node that failed to execute the
recovered event
*/
static void recovered_fail_callback(struct ctdb_context *ctdb, uint32_t node_pnn, int32_t res, TDB_DATA outdata, void *callback_data)
{
struct ctdb_recoverd *rec = talloc_get_type(callback_data, struct ctdb_recoverd);
DEBUG(DEBUG_ERR, (__location__ " Node %u failed the recovered event. Setting it as recovery fail culprit\n", node_pnn));
ctdb_set_culprit(rec, node_pnn);
}
/*
run the "recovered" eventscript on all nodes
*/
static int run_recovered_eventscript(struct ctdb_recoverd *rec, struct ctdb_node_map *nodemap, const char *caller)
{
TALLOC_CTX *tmp_ctx;
uint32_t *nodes;
struct ctdb_context *ctdb = rec->ctdb;
tmp_ctx = talloc_new(ctdb);
CTDB_NO_MEMORY(ctdb, tmp_ctx);
nodes = list_of_active_nodes(ctdb, nodemap, tmp_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_END_RECOVERY,
nodes, 0,
CONTROL_TIMEOUT(), false, tdb_null,
NULL, recovered_fail_callback,
rec) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to run the 'recovered' event when called from %s\n", caller));
talloc_free(tmp_ctx);
return -1;
}
talloc_free(tmp_ctx);
return 0;
}
/* this callback is called for every node that failed to execute the
start recovery event
*/
static void startrecovery_fail_callback(struct ctdb_context *ctdb, uint32_t node_pnn, int32_t res, TDB_DATA outdata, void *callback_data)
{
struct ctdb_recoverd *rec = talloc_get_type(callback_data, struct ctdb_recoverd);
DEBUG(DEBUG_ERR, (__location__ " Node %u failed the startrecovery event. Setting it as recovery fail culprit\n", node_pnn));
ctdb_set_culprit(rec, node_pnn);
}
/*
run the "startrecovery" eventscript on all nodes
*/
static int run_startrecovery_eventscript(struct ctdb_recoverd *rec, struct ctdb_node_map *nodemap)
{
TALLOC_CTX *tmp_ctx;
uint32_t *nodes;
struct ctdb_context *ctdb = rec->ctdb;
tmp_ctx = talloc_new(ctdb);
CTDB_NO_MEMORY(ctdb, tmp_ctx);
nodes = list_of_active_nodes(ctdb, nodemap, tmp_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_START_RECOVERY,
nodes, 0,
CONTROL_TIMEOUT(), false, tdb_null,
NULL,
startrecovery_fail_callback,
rec) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to run the 'startrecovery' event. Recovery failed.\n"));
talloc_free(tmp_ctx);
return -1;
}
talloc_free(tmp_ctx);
return 0;
}
static void async_getcap_callback(struct ctdb_context *ctdb, uint32_t node_pnn, int32_t res, TDB_DATA outdata, void *callback_data)
{
if ( (outdata.dsize != sizeof(uint32_t)) || (outdata.dptr == NULL) ) {
DEBUG(DEBUG_ERR, (__location__ " Invalid length/pointer for getcap callback : %u %p\n", (unsigned)outdata.dsize, outdata.dptr));
return;
}
if (node_pnn < ctdb->num_nodes) {
ctdb->nodes[node_pnn]->capabilities = *((uint32_t *)outdata.dptr);
}
if (node_pnn == ctdb->pnn) {
ctdb->capabilities = ctdb->nodes[node_pnn]->capabilities;
}
}
/*
update the node capabilities for all connected nodes
*/
static int update_capabilities(struct ctdb_context *ctdb, struct ctdb_node_map *nodemap)
{
uint32_t *nodes;
TALLOC_CTX *tmp_ctx;
tmp_ctx = talloc_new(ctdb);
CTDB_NO_MEMORY(ctdb, tmp_ctx);
nodes = list_of_connected_nodes(ctdb, nodemap, tmp_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_GET_CAPABILITIES,
nodes, 0,
CONTROL_TIMEOUT(),
false, tdb_null,
async_getcap_callback, NULL,
NULL) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Failed to read node capabilities.\n"));
talloc_free(tmp_ctx);
return -1;
}
talloc_free(tmp_ctx);
return 0;
}
static void set_recmode_fail_callback(struct ctdb_context *ctdb, uint32_t node_pnn, int32_t res, TDB_DATA outdata, void *callback_data)
{
struct ctdb_recoverd *rec = talloc_get_type(callback_data, struct ctdb_recoverd);
DEBUG(DEBUG_ERR,("Failed to freeze node %u during recovery. Set it as ban culprit for %d credits\n", node_pnn, rec->nodemap->num));
ctdb_set_culprit_count(rec, node_pnn, rec->nodemap->num);
}
static void transaction_start_fail_callback(struct ctdb_context *ctdb, uint32_t node_pnn, int32_t res, TDB_DATA outdata, void *callback_data)
{
struct ctdb_recoverd *rec = talloc_get_type(callback_data, struct ctdb_recoverd);
DEBUG(DEBUG_ERR,("Failed to start recovery transaction on node %u. Set it as ban culprit for %d credits\n", node_pnn, rec->nodemap->num));
ctdb_set_culprit_count(rec, node_pnn, rec->nodemap->num);
}
/*
change recovery mode on all nodes
*/
static int set_recovery_mode(struct ctdb_context *ctdb, struct ctdb_recoverd *rec, struct ctdb_node_map *nodemap, uint32_t rec_mode)
{
TDB_DATA data;
uint32_t *nodes;
TALLOC_CTX *tmp_ctx;
tmp_ctx = talloc_new(ctdb);
CTDB_NO_MEMORY(ctdb, tmp_ctx);
/* freeze all nodes */
nodes = list_of_active_nodes(ctdb, nodemap, tmp_ctx, true);
if (rec_mode == CTDB_RECOVERY_ACTIVE) {
int i;
for (i=1; i<=NUM_DB_PRIORITIES; i++) {
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_FREEZE,
nodes, i,
CONTROL_TIMEOUT(),
false, tdb_null,
NULL,
set_recmode_fail_callback,
rec) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to freeze nodes. Recovery failed.\n"));
talloc_free(tmp_ctx);
return -1;
}
}
}
data.dsize = sizeof(uint32_t);
data.dptr = (unsigned char *)&rec_mode;
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_SET_RECMODE,
nodes, 0,
CONTROL_TIMEOUT(),
false, data,
NULL, NULL,
NULL) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to set recovery mode. Recovery failed.\n"));
talloc_free(tmp_ctx);
return -1;
}
talloc_free(tmp_ctx);
return 0;
}
/*
change recovery master on all node
*/
static int set_recovery_master(struct ctdb_context *ctdb, struct ctdb_node_map *nodemap, uint32_t pnn)
{
TDB_DATA data;
TALLOC_CTX *tmp_ctx;
uint32_t *nodes;
tmp_ctx = talloc_new(ctdb);
CTDB_NO_MEMORY(ctdb, tmp_ctx);
data.dsize = sizeof(uint32_t);
data.dptr = (unsigned char *)&pnn;
nodes = list_of_active_nodes(ctdb, nodemap, tmp_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_SET_RECMASTER,
nodes, 0,
CONTROL_TIMEOUT(), false, data,
NULL, NULL,
NULL) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to set recmaster. Recovery failed.\n"));
talloc_free(tmp_ctx);
return -1;
}
talloc_free(tmp_ctx);
return 0;
}
/* update all remote nodes to use the same db priority that we have
this can fail if the remove node has not yet been upgraded to
support this function, so we always return success and never fail
a recovery if this call fails.
*/
static int update_db_priority_on_remote_nodes(struct ctdb_context *ctdb,
struct ctdb_node_map *nodemap,
uint32_t pnn, struct ctdb_dbid_map *dbmap, TALLOC_CTX *mem_ctx)
{
int db;
uint32_t *nodes;
nodes = list_of_active_nodes(ctdb, nodemap, mem_ctx, true);
/* step through all local databases */
for (db=0; db<dbmap->num;db++) {
TDB_DATA data;
struct ctdb_db_priority db_prio;
int ret;
db_prio.db_id = dbmap->dbs[db].dbid;
ret = ctdb_ctrl_get_db_priority(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, dbmap->dbs[db].dbid, &db_prio.priority);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to read database priority from local node for db 0x%08x\n", dbmap->dbs[db].dbid));
continue;
}
DEBUG(DEBUG_INFO,("Update DB priority for db 0x%08x to %u\n", dbmap->dbs[db].dbid, db_prio.priority));
data.dptr = (uint8_t *)&db_prio;
data.dsize = sizeof(db_prio);
if (ctdb_client_async_control(ctdb,
CTDB_CONTROL_SET_DB_PRIORITY,
nodes, 0,
CONTROL_TIMEOUT(), false, data,
NULL, NULL,
NULL) != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to set DB priority for 0x%08x\n", db_prio.db_id));
}
}
return 0;
}
/*
ensure all other nodes have attached to any databases that we have
*/
static int create_missing_remote_databases(struct ctdb_context *ctdb, struct ctdb_node_map *nodemap,
uint32_t pnn, struct ctdb_dbid_map *dbmap, TALLOC_CTX *mem_ctx)
{
int i, j, db, ret;
struct ctdb_dbid_map *remote_dbmap;
/* verify that all other nodes have all our databases */
for (j=0; j<nodemap->num; j++) {
/* we dont need to ourself ourselves */
if (nodemap->nodes[j].pnn == pnn) {
continue;
}
/* dont check nodes that are unavailable */
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
ret = ctdb_ctrl_getdbmap(ctdb, CONTROL_TIMEOUT(), nodemap->nodes[j].pnn,
mem_ctx, &remote_dbmap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get dbids from node %u\n", pnn));
return -1;
}
/* step through all local databases */
for (db=0; db<dbmap->num;db++) {
const char *name;
for (i=0;i<remote_dbmap->num;i++) {
if (dbmap->dbs[db].dbid == remote_dbmap->dbs[i].dbid) {
break;
}
}
/* the remote node already have this database */
if (i!=remote_dbmap->num) {
continue;
}
/* ok so we need to create this database */
ret = ctdb_ctrl_getdbname(ctdb, CONTROL_TIMEOUT(), pnn,
dbmap->dbs[db].dbid, mem_ctx,
&name);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get dbname from node %u\n", pnn));
return -1;
}
ret = ctdb_ctrl_createdb(ctdb, CONTROL_TIMEOUT(),
nodemap->nodes[j].pnn,
mem_ctx, name,
dbmap->dbs[db].flags & CTDB_DB_FLAGS_PERSISTENT);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to create remote db:%s\n", name));
return -1;
}
}
}
return 0;
}
/*
ensure we are attached to any databases that anyone else is attached to
*/
static int create_missing_local_databases(struct ctdb_context *ctdb, struct ctdb_node_map *nodemap,
uint32_t pnn, struct ctdb_dbid_map **dbmap, TALLOC_CTX *mem_ctx)
{
int i, j, db, ret;
struct ctdb_dbid_map *remote_dbmap;
/* verify that we have all database any other node has */
for (j=0; j<nodemap->num; j++) {
/* we dont need to ourself ourselves */
if (nodemap->nodes[j].pnn == pnn) {
continue;
}
/* dont check nodes that are unavailable */
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
ret = ctdb_ctrl_getdbmap(ctdb, CONTROL_TIMEOUT(), nodemap->nodes[j].pnn,
mem_ctx, &remote_dbmap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get dbids from node %u\n", pnn));
return -1;
}
/* step through all databases on the remote node */
for (db=0; db<remote_dbmap->num;db++) {
const char *name;
for (i=0;i<(*dbmap)->num;i++) {
if (remote_dbmap->dbs[db].dbid == (*dbmap)->dbs[i].dbid) {
break;
}
}
/* we already have this db locally */
if (i!=(*dbmap)->num) {
continue;
}
/* ok so we need to create this database and
rebuild dbmap
*/
ctdb_ctrl_getdbname(ctdb, CONTROL_TIMEOUT(), nodemap->nodes[j].pnn,
remote_dbmap->dbs[db].dbid, mem_ctx, &name);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get dbname from node %u\n",
nodemap->nodes[j].pnn));
return -1;
}
ctdb_ctrl_createdb(ctdb, CONTROL_TIMEOUT(), pnn, mem_ctx, name,
remote_dbmap->dbs[db].flags & CTDB_DB_FLAGS_PERSISTENT);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to create local db:%s\n", name));
return -1;
}
ret = ctdb_ctrl_getdbmap(ctdb, CONTROL_TIMEOUT(), pnn, mem_ctx, dbmap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to reread dbmap on node %u\n", pnn));
return -1;
}
}
}
return 0;
}
/*
pull the remote database contents from one node into the recdb
*/
static int pull_one_remote_database(struct ctdb_context *ctdb, uint32_t srcnode,
struct tdb_wrap *recdb, uint32_t dbid)
{
int ret;
TDB_DATA outdata;
struct ctdb_marshall_buffer *reply;
struct ctdb_rec_data *rec;
int i;
TALLOC_CTX *tmp_ctx = talloc_new(recdb);
ret = ctdb_ctrl_pulldb(ctdb, srcnode, dbid, CTDB_LMASTER_ANY, tmp_ctx,
CONTROL_TIMEOUT(), &outdata);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " Unable to copy db from node %u\n", srcnode));
talloc_free(tmp_ctx);
return -1;
}
reply = (struct ctdb_marshall_buffer *)outdata.dptr;
if (outdata.dsize < offsetof(struct ctdb_marshall_buffer, data)) {
DEBUG(DEBUG_ERR,(__location__ " invalid data in pulldb reply\n"));
talloc_free(tmp_ctx);
return -1;
}
rec = (struct ctdb_rec_data *)&reply->data[0];
for (i=0;
i<reply->count;
rec = (struct ctdb_rec_data *)(rec->length + (uint8_t *)rec), i++) {
TDB_DATA key, data;
struct ctdb_ltdb_header *hdr;
TDB_DATA existing;
key.dptr = &rec->data[0];
key.dsize = rec->keylen;
data.dptr = &rec->data[key.dsize];
data.dsize = rec->datalen;
hdr = (struct ctdb_ltdb_header *)data.dptr;
if (data.dsize < sizeof(struct ctdb_ltdb_header)) {
DEBUG(DEBUG_CRIT,(__location__ " bad ltdb record\n"));
talloc_free(tmp_ctx);
return -1;
}
/* fetch the existing record, if any */
existing = tdb_fetch(recdb->tdb, key);
if (existing.dptr != NULL) {
struct ctdb_ltdb_header header;
if (existing.dsize < sizeof(struct ctdb_ltdb_header)) {
DEBUG(DEBUG_CRIT,(__location__ " Bad record size %u from node %u\n",
(unsigned)existing.dsize, srcnode));
free(existing.dptr);
talloc_free(tmp_ctx);
return -1;
}
header = *(struct ctdb_ltdb_header *)existing.dptr;
free(existing.dptr);
if (!(header.rsn < hdr->rsn ||
(header.dmaster != ctdb->recovery_master && header.rsn == hdr->rsn))) {
continue;
}
}
if (tdb_store(recdb->tdb, key, data, TDB_REPLACE) != 0) {
DEBUG(DEBUG_CRIT,(__location__ " Failed to store record\n"));
talloc_free(tmp_ctx);
return -1;
}
}
talloc_free(tmp_ctx);
return 0;
}
struct pull_seqnum_cbdata {
int failed;
uint32_t pnn;
uint64_t seqnum;
};
static void pull_seqnum_cb(struct ctdb_context *ctdb, uint32_t node_pnn, int32_t res, TDB_DATA outdata, void *callback_data)
{
struct pull_seqnum_cbdata *cb_data = talloc_get_type(callback_data, struct pull_seqnum_cbdata);
uint64_t seqnum;
if (cb_data->failed != 0) {
DEBUG(DEBUG_ERR, ("Got seqnum from node %d but we have already failed the entire operation\n", node_pnn));
return;
}
if (res != 0) {
DEBUG(DEBUG_ERR, ("Error when pulling seqnum from node %d\n", node_pnn));
cb_data->failed = 1;
return;
}
if (outdata.dsize != sizeof(uint64_t)) {
DEBUG(DEBUG_ERR, ("Error when reading pull seqnum from node %d, got %d bytes but expected %d\n", node_pnn, (int)outdata.dsize, (int)sizeof(uint64_t)));
cb_data->failed = -1;
return;
}
seqnum = *((uint64_t *)outdata.dptr);
if (seqnum > cb_data->seqnum ||
(cb_data->pnn == -1 && seqnum == 0)) {
cb_data->seqnum = seqnum;
cb_data->pnn = node_pnn;
}
}
static void pull_seqnum_fail_cb(struct ctdb_context *ctdb, uint32_t node_pnn, int32_t res, TDB_DATA outdata, void *callback_data)
{
struct pull_seqnum_cbdata *cb_data = talloc_get_type(callback_data, struct pull_seqnum_cbdata);
DEBUG(DEBUG_ERR, ("Failed to pull db seqnum from node %d\n", node_pnn));
cb_data->failed = 1;
}
static int pull_highest_seqnum_pdb(struct ctdb_context *ctdb,
struct ctdb_recoverd *rec,
struct ctdb_node_map *nodemap,
struct tdb_wrap *recdb, uint32_t dbid)
{
TALLOC_CTX *tmp_ctx = talloc_new(NULL);
uint32_t *nodes;
TDB_DATA data;
uint32_t outdata[2];
struct pull_seqnum_cbdata *cb_data;
DEBUG(DEBUG_NOTICE, ("Scan for highest seqnum pdb for db:0x%08x\n", dbid));
outdata[0] = dbid;
outdata[1] = 0;
data.dsize = sizeof(outdata);
data.dptr = (uint8_t *)&outdata[0];
cb_data = talloc(tmp_ctx, struct pull_seqnum_cbdata);
if (cb_data == NULL) {
DEBUG(DEBUG_ERR, ("Failed to allocate pull highest seqnum cb_data structure\n"));
talloc_free(tmp_ctx);
return -1;
}
cb_data->failed = 0;
cb_data->pnn = -1;
cb_data->seqnum = 0;
nodes = list_of_active_nodes(ctdb, nodemap, tmp_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_GET_DB_SEQNUM,
nodes, 0,
CONTROL_TIMEOUT(), false, data,
pull_seqnum_cb,
pull_seqnum_fail_cb,
cb_data) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Failed to run async GET_DB_SEQNUM\n"));
talloc_free(tmp_ctx);
return -1;
}
if (cb_data->failed != 0) {
DEBUG(DEBUG_NOTICE, ("Failed to pull sequence numbers for DB 0x%08x\n", dbid));
talloc_free(tmp_ctx);
return -1;
}
if (cb_data->pnn == -1) {
DEBUG(DEBUG_NOTICE, ("Failed to find a node with highest sequence numbers for DB 0x%08x\n", dbid));
talloc_free(tmp_ctx);
return -1;
}
DEBUG(DEBUG_NOTICE, ("Pull persistent db:0x%08x from node %d with highest seqnum:%lld\n", dbid, cb_data->pnn, (long long)cb_data->seqnum));
if (pull_one_remote_database(ctdb, cb_data->pnn, recdb, dbid) != 0) {
DEBUG(DEBUG_ERR, ("Failed to pull higest seqnum database 0x%08x from node %d\n", dbid, cb_data->pnn));
talloc_free(tmp_ctx);
return -1;
}
talloc_free(tmp_ctx);
return 0;
}
/*
pull all the remote database contents into the recdb
*/
static int pull_remote_database(struct ctdb_context *ctdb,
struct ctdb_recoverd *rec,
struct ctdb_node_map *nodemap,
struct tdb_wrap *recdb, uint32_t dbid,
bool persistent)
{
int j;
if (persistent && ctdb->tunable.recover_pdb_by_seqnum != 0) {
int ret;
ret = pull_highest_seqnum_pdb(ctdb, rec, nodemap, recdb, dbid);
if (ret == 0) {
return 0;
}
}
/* pull all records from all other nodes across onto this node
(this merges based on rsn)
*/
for (j=0; j<nodemap->num; j++) {
/* dont merge from nodes that are unavailable */
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
if (pull_one_remote_database(ctdb, nodemap->nodes[j].pnn, recdb, dbid) != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to pull remote database from node %u\n",
nodemap->nodes[j].pnn));
ctdb_set_culprit_count(rec, nodemap->nodes[j].pnn, nodemap->num);
return -1;
}
}
return 0;
}
/*
update flags on all active nodes
*/
static int update_flags_on_all_nodes(struct ctdb_context *ctdb, struct ctdb_node_map *nodemap, uint32_t pnn, uint32_t flags)
{
int ret;
ret = ctdb_ctrl_modflags(ctdb, CONTROL_TIMEOUT(), pnn, flags, ~flags);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to update nodeflags on remote nodes\n"));
return -1;
}
return 0;
}
/*
ensure all nodes have the same vnnmap we do
*/
static int update_vnnmap_on_all_nodes(struct ctdb_context *ctdb, struct ctdb_node_map *nodemap,
uint32_t pnn, struct ctdb_vnn_map *vnnmap, TALLOC_CTX *mem_ctx)
{
int j, ret;
/* push the new vnn map out to all the nodes */
for (j=0; j<nodemap->num; j++) {
/* dont push to nodes that are unavailable */
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
ret = ctdb_ctrl_setvnnmap(ctdb, CONTROL_TIMEOUT(), nodemap->nodes[j].pnn, mem_ctx, vnnmap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to set vnnmap for node %u\n", pnn));
return -1;
}
}
return 0;
}
struct vacuum_info {
struct vacuum_info *next, *prev;
struct ctdb_recoverd *rec;
uint32_t srcnode;
struct ctdb_db_context *ctdb_db;
struct ctdb_marshall_buffer *recs;
struct ctdb_rec_data *r;
};
static void vacuum_fetch_next(struct vacuum_info *v);
/*
called when a vacuum fetch has completed - just free it and do the next one
*/
static void vacuum_fetch_callback(struct ctdb_client_call_state *state)
{
struct vacuum_info *v = talloc_get_type(state->async.private_data, struct vacuum_info);
talloc_free(state);
vacuum_fetch_next(v);
}
/*
process the next element from the vacuum list
*/
static void vacuum_fetch_next(struct vacuum_info *v)
{
struct ctdb_call call;
struct ctdb_rec_data *r;
while (v->recs->count) {
struct ctdb_client_call_state *state;
TDB_DATA data;
struct ctdb_ltdb_header *hdr;
ZERO_STRUCT(call);
call.call_id = CTDB_NULL_FUNC;
call.flags = CTDB_IMMEDIATE_MIGRATION;
call.flags |= CTDB_CALL_FLAG_VACUUM_MIGRATION;
r = v->r;
v->r = (struct ctdb_rec_data *)(r->length + (uint8_t *)r);
v->recs->count--;
call.key.dptr = &r->data[0];
call.key.dsize = r->keylen;
/* ensure we don't block this daemon - just skip a record if we can't get
the chainlock */
if (tdb_chainlock_nonblock(v->ctdb_db->ltdb->tdb, call.key) != 0) {
continue;
}
data = tdb_fetch(v->ctdb_db->ltdb->tdb, call.key);
if (data.dptr == NULL) {
tdb_chainunlock(v->ctdb_db->ltdb->tdb, call.key);
continue;
}
if (data.dsize < sizeof(struct ctdb_ltdb_header)) {
free(data.dptr);
tdb_chainunlock(v->ctdb_db->ltdb->tdb, call.key);
continue;
}
hdr = (struct ctdb_ltdb_header *)data.dptr;
if (hdr->dmaster == v->rec->ctdb->pnn) {
/* its already local */
free(data.dptr);
tdb_chainunlock(v->ctdb_db->ltdb->tdb, call.key);
continue;
}
free(data.dptr);
state = ctdb_call_send(v->ctdb_db, &call);
tdb_chainunlock(v->ctdb_db->ltdb->tdb, call.key);
if (state == NULL) {
DEBUG(DEBUG_ERR,(__location__ " Failed to setup vacuum fetch call\n"));
talloc_free(v);
return;
}
state->async.fn = vacuum_fetch_callback;
state->async.private_data = v;
return;
}
talloc_free(v);
}
/*
destroy a vacuum info structure
*/
static int vacuum_info_destructor(struct vacuum_info *v)
{
DLIST_REMOVE(v->rec->vacuum_info, v);
return 0;
}
/*
handler for vacuum fetch
*/
static void vacuum_fetch_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
struct ctdb_recoverd *rec = talloc_get_type(private_data, struct ctdb_recoverd);
struct ctdb_marshall_buffer *recs;
int ret, i;
TALLOC_CTX *tmp_ctx = talloc_new(ctdb);
const char *name;
struct ctdb_dbid_map *dbmap=NULL;
bool persistent = false;
struct ctdb_db_context *ctdb_db;
struct ctdb_rec_data *r;
uint32_t srcnode;
struct vacuum_info *v;
recs = (struct ctdb_marshall_buffer *)data.dptr;
r = (struct ctdb_rec_data *)&recs->data[0];
if (recs->count == 0) {
talloc_free(tmp_ctx);
return;
}
srcnode = r->reqid;
for (v=rec->vacuum_info;v;v=v->next) {
if (srcnode == v->srcnode && recs->db_id == v->ctdb_db->db_id) {
/* we're already working on records from this node */
talloc_free(tmp_ctx);
return;
}
}
/* work out if the database is persistent */
ret = ctdb_ctrl_getdbmap(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, tmp_ctx, &dbmap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get dbids from local node\n"));
talloc_free(tmp_ctx);
return;
}
for (i=0;i<dbmap->num;i++) {
if (dbmap->dbs[i].dbid == recs->db_id) {
persistent = dbmap->dbs[i].flags & CTDB_DB_FLAGS_PERSISTENT;
break;
}
}
if (i == dbmap->num) {
DEBUG(DEBUG_ERR, (__location__ " Unable to find db_id 0x%x on local node\n", recs->db_id));
talloc_free(tmp_ctx);
return;
}
/* find the name of this database */
if (ctdb_ctrl_getdbname(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, recs->db_id, tmp_ctx, &name) != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to get name of db 0x%x\n", recs->db_id));
talloc_free(tmp_ctx);
return;
}
/* attach to it */
ctdb_db = ctdb_attach(ctdb, CONTROL_TIMEOUT(), name, persistent, 0);
if (ctdb_db == NULL) {
DEBUG(DEBUG_ERR,(__location__ " Failed to attach to database '%s'\n", name));
talloc_free(tmp_ctx);
return;
}
v = talloc_zero(rec, struct vacuum_info);
if (v == NULL) {
DEBUG(DEBUG_CRIT,(__location__ " Out of memory\n"));
talloc_free(tmp_ctx);
return;
}
v->rec = rec;
v->srcnode = srcnode;
v->ctdb_db = ctdb_db;
v->recs = talloc_memdup(v, recs, data.dsize);
if (v->recs == NULL) {
DEBUG(DEBUG_CRIT,(__location__ " Out of memory\n"));
talloc_free(v);
talloc_free(tmp_ctx);
return;
}
v->r = (struct ctdb_rec_data *)&v->recs->data[0];
DLIST_ADD(rec->vacuum_info, v);
talloc_set_destructor(v, vacuum_info_destructor);
vacuum_fetch_next(v);
talloc_free(tmp_ctx);
}
/*
called when ctdb_wait_timeout should finish
*/
static void ctdb_wait_handler(struct event_context *ev, struct timed_event *te,
struct timeval yt, void *p)
{
uint32_t *timed_out = (uint32_t *)p;
(*timed_out) = 1;
}
/*
wait for a given number of seconds
*/
static void ctdb_wait_timeout(struct ctdb_context *ctdb, double secs)
{
uint32_t timed_out = 0;
time_t usecs = (secs - (time_t)secs) * 1000000;
event_add_timed(ctdb->ev, ctdb, timeval_current_ofs(secs, usecs), ctdb_wait_handler, &timed_out);
while (!timed_out) {
event_loop_once(ctdb->ev);
}
}
/*
called when an election times out (ends)
*/
static void ctdb_election_timeout(struct event_context *ev, struct timed_event *te,
struct timeval t, void *p)
{
struct ctdb_recoverd *rec = talloc_get_type(p, struct ctdb_recoverd);
rec->election_timeout = NULL;
fast_start = false;
DEBUG(DEBUG_WARNING,(__location__ " Election timed out\n"));
}
/*
wait for an election to finish. It finished election_timeout seconds after
the last election packet is received
*/
static void ctdb_wait_election(struct ctdb_recoverd *rec)
{
struct ctdb_context *ctdb = rec->ctdb;
while (rec->election_timeout) {
event_loop_once(ctdb->ev);
}
}
/*
Update our local flags from all remote connected nodes.
This is only run when we are or we belive we are the recovery master
*/
static int update_local_flags(struct ctdb_recoverd *rec, struct ctdb_node_map *nodemap)
{
int j;
struct ctdb_context *ctdb = rec->ctdb;
TALLOC_CTX *mem_ctx = talloc_new(ctdb);
/* get the nodemap for all active remote nodes and verify
they are the same as for this node
*/
for (j=0; j<nodemap->num; j++) {
struct ctdb_node_map *remote_nodemap=NULL;
int ret;
if (nodemap->nodes[j].flags & NODE_FLAGS_DISCONNECTED) {
continue;
}
if (nodemap->nodes[j].pnn == ctdb->pnn) {
continue;
}
ret = ctdb_ctrl_getnodemap(ctdb, CONTROL_TIMEOUT(), nodemap->nodes[j].pnn,
mem_ctx, &remote_nodemap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get nodemap from remote node %u\n",
nodemap->nodes[j].pnn));
ctdb_set_culprit(rec, nodemap->nodes[j].pnn);
talloc_free(mem_ctx);
return MONITOR_FAILED;
}
if (nodemap->nodes[j].flags != remote_nodemap->nodes[j].flags) {
/* We should tell our daemon about this so it
updates its flags or else we will log the same
message again in the next iteration of recovery.
Since we are the recovery master we can just as
well update the flags on all nodes.
*/
ret = ctdb_ctrl_modflags(ctdb, CONTROL_TIMEOUT(), nodemap->nodes[j].pnn, remote_nodemap->nodes[j].flags, ~remote_nodemap->nodes[j].flags);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to update nodeflags on remote nodes\n"));
return -1;
}
/* Update our local copy of the flags in the recovery
daemon.
*/
DEBUG(DEBUG_NOTICE,("Remote node %u had flags 0x%x, local had 0x%x - updating local\n",
nodemap->nodes[j].pnn, remote_nodemap->nodes[j].flags,
nodemap->nodes[j].flags));
nodemap->nodes[j].flags = remote_nodemap->nodes[j].flags;
}
talloc_free(remote_nodemap);
}
talloc_free(mem_ctx);
return MONITOR_OK;
}
/* Create a new random generation ip.
The generation id can not be the INVALID_GENERATION id
*/
static uint32_t new_generation(void)
{
uint32_t generation;
while (1) {
generation = random();
if (generation != INVALID_GENERATION) {
break;
}
}
return generation;
}
/*
create a temporary working database
*/
static struct tdb_wrap *create_recdb(struct ctdb_context *ctdb, TALLOC_CTX *mem_ctx)
{
char *name;
struct tdb_wrap *recdb;
unsigned tdb_flags;
/* open up the temporary recovery database */
name = talloc_asprintf(mem_ctx, "%s/recdb.tdb.%u",
ctdb->db_directory_state,
ctdb->pnn);
if (name == NULL) {
return NULL;
}
unlink(name);
tdb_flags = TDB_NOLOCK;
if (ctdb->valgrinding) {
tdb_flags |= TDB_NOMMAP;
}
tdb_flags |= (TDB_INCOMPATIBLE_HASH | TDB_DISALLOW_NESTING);
recdb = tdb_wrap_open(mem_ctx, name, ctdb->tunable.database_hash_size,
tdb_flags, O_RDWR|O_CREAT|O_EXCL, 0600);
if (recdb == NULL) {
DEBUG(DEBUG_CRIT,(__location__ " Failed to create temp recovery database '%s'\n", name));
}
talloc_free(name);
return recdb;
}
/*
a traverse function for pulling all relevant records from recdb
*/
struct recdb_data {
struct ctdb_context *ctdb;
struct ctdb_marshall_buffer *recdata;
uint32_t len;
uint32_t allocated_len;
bool failed;
bool persistent;
};
static int traverse_recdb(struct tdb_context *tdb, TDB_DATA key, TDB_DATA data, void *p)
{
struct recdb_data *params = (struct recdb_data *)p;
struct ctdb_rec_data *rec;
struct ctdb_ltdb_header *hdr;
/*
* skip empty records - but NOT for persistent databases:
*
* The record-by-record mode of recovery deletes empty records.
* For persistent databases, this can lead to data corruption
* by deleting records that should be there:
*
* - Assume the cluster has been running for a while.
*
* - A record R in a persistent database has been created and
* deleted a couple of times, the last operation being deletion,
* leaving an empty record with a high RSN, say 10.
*
* - Now a node N is turned off.
*
* - This leaves the local database copy of D on N with the empty
* copy of R and RSN 10. On all other nodes, the recovery has deleted
* the copy of record R.
*
* - Now the record is created again while node N is turned off.
* This creates R with RSN = 1 on all nodes except for N.
*
* - Now node N is turned on again. The following recovery will chose
* the older empty copy of R due to RSN 10 > RSN 1.
*
* ==> Hence the record is gone after the recovery.
*
* On databases like Samba's registry, this can damage the higher-level
* data structures built from the various tdb-level records.
*/
if (!params->persistent && data.dsize <= sizeof(struct ctdb_ltdb_header)) {
return 0;
}
/* update the dmaster field to point to us */
hdr = (struct ctdb_ltdb_header *)data.dptr;
if (!params->persistent) {
hdr->dmaster = params->ctdb->pnn;
hdr->flags |= CTDB_REC_FLAG_MIGRATED_WITH_DATA;
}
/* add the record to the blob ready to send to the nodes */
rec = ctdb_marshall_record(params->recdata, 0, key, NULL, data);
if (rec == NULL) {
params->failed = true;
return -1;
}
if (params->len + rec->length >= params->allocated_len) {
params->allocated_len = rec->length + params->len + params->ctdb->tunable.pulldb_preallocation_size;
params->recdata = talloc_realloc_size(NULL, params->recdata, params->allocated_len);
}
if (params->recdata == NULL) {
DEBUG(DEBUG_CRIT,(__location__ " Failed to expand recdata to %u\n",
rec->length + params->len));
params->failed = true;
return -1;
}
params->recdata->count++;
memcpy(params->len+(uint8_t *)params->recdata, rec, rec->length);
params->len += rec->length;
talloc_free(rec);
return 0;
}
/*
push the recdb database out to all nodes
*/
static int push_recdb_database(struct ctdb_context *ctdb, uint32_t dbid,
bool persistent,
struct tdb_wrap *recdb, struct ctdb_node_map *nodemap)
{
struct recdb_data params;
struct ctdb_marshall_buffer *recdata;
TDB_DATA outdata;
TALLOC_CTX *tmp_ctx;
uint32_t *nodes;
tmp_ctx = talloc_new(ctdb);
CTDB_NO_MEMORY(ctdb, tmp_ctx);
recdata = talloc_zero(recdb, struct ctdb_marshall_buffer);
CTDB_NO_MEMORY(ctdb, recdata);
recdata->db_id = dbid;
params.ctdb = ctdb;
params.recdata = recdata;
params.len = offsetof(struct ctdb_marshall_buffer, data);
params.allocated_len = params.len;
params.failed = false;
params.persistent = persistent;
if (tdb_traverse_read(recdb->tdb, traverse_recdb, &params) == -1) {
DEBUG(DEBUG_ERR,(__location__ " Failed to traverse recdb database\n"));
talloc_free(params.recdata);
talloc_free(tmp_ctx);
return -1;
}
if (params.failed) {
DEBUG(DEBUG_ERR,(__location__ " Failed to traverse recdb database\n"));
talloc_free(params.recdata);
talloc_free(tmp_ctx);
return -1;
}
recdata = params.recdata;
outdata.dptr = (void *)recdata;
outdata.dsize = params.len;
nodes = list_of_active_nodes(ctdb, nodemap, tmp_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_PUSH_DB,
nodes, 0,
CONTROL_TIMEOUT(), false, outdata,
NULL, NULL,
NULL) != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to push recdb records to nodes for db 0x%x\n", dbid));
talloc_free(recdata);
talloc_free(tmp_ctx);
return -1;
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - pushed remote database 0x%x of size %u\n",
dbid, recdata->count));
talloc_free(recdata);
talloc_free(tmp_ctx);
return 0;
}
/*
go through a full recovery on one database
*/
static int recover_database(struct ctdb_recoverd *rec,
TALLOC_CTX *mem_ctx,
uint32_t dbid,
bool persistent,
uint32_t pnn,
struct ctdb_node_map *nodemap,
uint32_t transaction_id)
{
struct tdb_wrap *recdb;
int ret;
struct ctdb_context *ctdb = rec->ctdb;
TDB_DATA data;
struct ctdb_control_wipe_database w;
uint32_t *nodes;
recdb = create_recdb(ctdb, mem_ctx);
if (recdb == NULL) {
return -1;
}
/* pull all remote databases onto the recdb */
ret = pull_remote_database(ctdb, rec, nodemap, recdb, dbid, persistent);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to pull remote database 0x%x\n", dbid));
return -1;
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - pulled remote database 0x%x\n", dbid));
/* wipe all the remote databases. This is safe as we are in a transaction */
w.db_id = dbid;
w.transaction_id = transaction_id;
data.dptr = (void *)&w;
data.dsize = sizeof(w);
nodes = list_of_active_nodes(ctdb, nodemap, recdb, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_WIPE_DATABASE,
nodes, 0,
CONTROL_TIMEOUT(), false, data,
NULL, NULL,
NULL) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to wipe database. Recovery failed.\n"));
talloc_free(recdb);
return -1;
}
/* push out the correct database. This sets the dmaster and skips
the empty records */
ret = push_recdb_database(ctdb, dbid, persistent, recdb, nodemap);
if (ret != 0) {
talloc_free(recdb);
return -1;
}
/* all done with this database */
talloc_free(recdb);
return 0;
}
static int ctdb_reload_remote_public_ips(struct ctdb_context *ctdb,
struct ctdb_recoverd *rec,
struct ctdb_node_map *nodemap,
uint32_t *culprit)
{
int j;
int ret;
if (ctdb->num_nodes != nodemap->num) {
DEBUG(DEBUG_ERR, (__location__ " ctdb->num_nodes (%d) != nodemap->num (%d) invalid param\n",
ctdb->num_nodes, nodemap->num));
if (culprit) {
*culprit = ctdb->pnn;
}
return -1;
}
for (j=0; j<nodemap->num; j++) {
/* For readability */
struct ctdb_node *node = ctdb->nodes[j];
/* release any existing data */
if (node->known_public_ips) {
talloc_free(node->known_public_ips);
node->known_public_ips = NULL;
}
if (node->available_public_ips) {
talloc_free(node->available_public_ips);
node->available_public_ips = NULL;
}
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
/* Retrieve the list of known public IPs from the node */
ret = ctdb_ctrl_get_public_ips_flags(ctdb,
CONTROL_TIMEOUT(),
node->pnn,
ctdb->nodes,
0,
&node->known_public_ips);
if (ret != 0) {
DEBUG(DEBUG_ERR,
("Failed to read known public IPs from node: %u\n",
node->pnn));
if (culprit) {
*culprit = node->pnn;
}
return -1;
}
if (ctdb->do_checkpublicip &&
rec->takeover_runs_disable_ctx == NULL &&
verify_remote_ip_allocation(ctdb,
node->known_public_ips,
node->pnn)) {
DEBUG(DEBUG_ERR,("Trigger IP reallocation\n"));
rec->need_takeover_run = true;
}
/* Retrieve the list of available public IPs from the node */
ret = ctdb_ctrl_get_public_ips_flags(ctdb,
CONTROL_TIMEOUT(),
node->pnn,
ctdb->nodes,
CTDB_PUBLIC_IP_FLAGS_ONLY_AVAILABLE,
&node->available_public_ips);
if (ret != 0) {
DEBUG(DEBUG_ERR,
("Failed to read available public IPs from node: %u\n",
node->pnn));
if (culprit) {
*culprit = node->pnn;
}
return -1;
}
}
return 0;
}
/* when we start a recovery, make sure all nodes use the same reclock file
setting
*/
static int sync_recovery_lock_file_across_cluster(struct ctdb_recoverd *rec)
{
struct ctdb_context *ctdb = rec->ctdb;
TALLOC_CTX *tmp_ctx = talloc_new(NULL);
TDB_DATA data;
uint32_t *nodes;
if (ctdb->recovery_lock_file == NULL) {
data.dptr = NULL;
data.dsize = 0;
} else {
data.dsize = strlen(ctdb->recovery_lock_file) + 1;
data.dptr = (uint8_t *)ctdb->recovery_lock_file;
}
nodes = list_of_active_nodes(ctdb, rec->nodemap, tmp_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_SET_RECLOCK_FILE,
nodes, 0,
CONTROL_TIMEOUT(),
false, data,
NULL, NULL,
rec) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Failed to sync reclock file settings\n"));
talloc_free(tmp_ctx);
return -1;
}
talloc_free(tmp_ctx);
return 0;
}
/*
* this callback is called for every node that failed to execute ctdb_takeover_run()
* and set flag to re-run takeover run.
*/
static void takeover_fail_callback(struct ctdb_context *ctdb, uint32_t node_pnn, int32_t res, TDB_DATA outdata, void *callback_data)
{
DEBUG(DEBUG_ERR, ("Node %u failed the takeover run\n", node_pnn));
if (callback_data != NULL) {
struct ctdb_recoverd *rec = talloc_get_type(callback_data, struct ctdb_recoverd);
DEBUG(DEBUG_ERR, ("Setting node %u as recovery fail culprit\n", node_pnn));
ctdb_set_culprit(rec, node_pnn);
}
}
static void ban_misbehaving_nodes(struct ctdb_recoverd *rec, bool *self_ban)
{
struct ctdb_context *ctdb = rec->ctdb;
int i;
struct ctdb_banning_state *ban_state;
*self_ban = false;
for (i=0; i<ctdb->num_nodes; i++) {
if (ctdb->nodes[i]->ban_state == NULL) {
continue;
}
ban_state = (struct ctdb_banning_state *)ctdb->nodes[i]->ban_state;
if (ban_state->count < 2*ctdb->num_nodes) {
continue;
}
DEBUG(DEBUG_NOTICE,("Node %u reached %u banning credits - banning it for %u seconds\n",
ctdb->nodes[i]->pnn, ban_state->count,
ctdb->tunable.recovery_ban_period));
ctdb_ban_node(rec, ctdb->nodes[i]->pnn, ctdb->tunable.recovery_ban_period);
ban_state->count = 0;
/* Banning ourself? */
if (ctdb->nodes[i]->pnn == rec->ctdb->pnn) {
*self_ban = true;
}
}
}
static bool do_takeover_run(struct ctdb_recoverd *rec,
struct ctdb_node_map *nodemap,
bool banning_credits_on_fail)
{
uint32_t *nodes = NULL;
struct srvid_request_data dtr;
TDB_DATA data;
int i;
uint32_t *rebalance_nodes = rec->force_rebalance_nodes;
int ret;
bool ok;
DEBUG(DEBUG_NOTICE, ("Takeover run starting\n"));
if (rec->takeover_run_in_progress) {
DEBUG(DEBUG_ERR, (__location__
" takeover run already in progress \n"));
ok = false;
goto done;
}
rec->takeover_run_in_progress = true;
/* If takeover runs are in disabled then fail... */
if (rec->takeover_runs_disable_ctx != NULL) {
DEBUG(DEBUG_ERR,
("Takeover runs are disabled so refusing to run one\n"));
ok = false;
goto done;
}
/* Disable IP checks (takeover runs, really) on other nodes
* while doing this takeover run. This will stop those other
* nodes from triggering takeover runs when think they should
* be hosting an IP but it isn't yet on an interface. Don't
* wait for replies since a failure here might cause some
* noise in the logs but will not actually cause a problem.
*/
dtr.srvid = 0; /* No reply */
dtr.pnn = -1;
data.dptr = (uint8_t*)&dtr;
data.dsize = sizeof(dtr);
nodes = list_of_connected_nodes(rec->ctdb, nodemap, rec, false);
/* Disable for 60 seconds. This can be a tunable later if
* necessary.
*/
dtr.data = 60;
for (i = 0; i < talloc_array_length(nodes); i++) {
if (ctdb_client_send_message(rec->ctdb, nodes[i],
CTDB_SRVID_DISABLE_TAKEOVER_RUNS,
data) != 0) {
DEBUG(DEBUG_INFO,("Failed to disable takeover runs\n"));
}
}
ret = ctdb_takeover_run(rec->ctdb, nodemap,
rec->force_rebalance_nodes,
takeover_fail_callback,
banning_credits_on_fail ? rec : NULL);
/* Reenable takeover runs and IP checks on other nodes */
dtr.data = 0;
for (i = 0; i < talloc_array_length(nodes); i++) {
if (ctdb_client_send_message(rec->ctdb, nodes[i],
CTDB_SRVID_DISABLE_TAKEOVER_RUNS,
data) != 0) {
DEBUG(DEBUG_INFO,("Failed to reenable takeover runs\n"));
}
}
if (ret != 0) {
DEBUG(DEBUG_ERR, ("ctdb_takeover_run() failed\n"));
ok = false;
goto done;
}
ok = true;
/* Takeover run was successful so clear force rebalance targets */
if (rebalance_nodes == rec->force_rebalance_nodes) {
TALLOC_FREE(rec->force_rebalance_nodes);
} else {
DEBUG(DEBUG_WARNING,
("Rebalance target nodes changed during takeover run - not clearing\n"));
}
done:
rec->need_takeover_run = !ok;
talloc_free(nodes);
rec->takeover_run_in_progress = false;
DEBUG(DEBUG_NOTICE, ("Takeover run %s\n", ok ? "completed successfully" : "unsuccessful"));
return ok;
}
/*
we are the recmaster, and recovery is needed - start a recovery run
*/
static int do_recovery(struct ctdb_recoverd *rec,
TALLOC_CTX *mem_ctx, uint32_t pnn,
struct ctdb_node_map *nodemap, struct ctdb_vnn_map *vnnmap)
{
struct ctdb_context *ctdb = rec->ctdb;
int i, j, ret;
uint32_t generation;
struct ctdb_dbid_map *dbmap;
TDB_DATA data;
uint32_t *nodes;
struct timeval start_time;
uint32_t culprit = (uint32_t)-1;
bool self_ban;
DEBUG(DEBUG_NOTICE, (__location__ " Starting do_recovery\n"));
/* if recovery fails, force it again */
rec->need_recovery = true;
ban_misbehaving_nodes(rec, &self_ban);
if (self_ban) {
DEBUG(DEBUG_NOTICE, ("This node was banned, aborting recovery\n"));
return -1;
}
if (ctdb->tunable.verify_recovery_lock != 0) {
DEBUG(DEBUG_ERR,("Taking out recovery lock from recovery daemon\n"));
start_time = timeval_current();
if (!ctdb_recovery_lock(ctdb, true)) {
DEBUG(DEBUG_ERR,("Unable to get recovery lock - aborting recovery "
"and ban ourself for %u seconds\n",
ctdb->tunable.recovery_ban_period));
ctdb_ban_node(rec, pnn, ctdb->tunable.recovery_ban_period);
return -1;
}
ctdb_ctrl_report_recd_lock_latency(ctdb, CONTROL_TIMEOUT(), timeval_elapsed(&start_time));
DEBUG(DEBUG_NOTICE,("Recovery lock taken successfully by recovery daemon\n"));
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery initiated due to problem with node %u\n", rec->last_culprit_node));
/* get a list of all databases */
ret = ctdb_ctrl_getdbmap(ctdb, CONTROL_TIMEOUT(), pnn, mem_ctx, &dbmap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get dbids from node :%u\n", pnn));
return -1;
}
/* we do the db creation before we set the recovery mode, so the freeze happens
on all databases we will be dealing with. */
/* verify that we have all the databases any other node has */
ret = create_missing_local_databases(ctdb, nodemap, pnn, &dbmap, mem_ctx);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to create missing local databases\n"));
return -1;
}
/* verify that all other nodes have all our databases */
ret = create_missing_remote_databases(ctdb, nodemap, pnn, dbmap, mem_ctx);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to create missing remote databases\n"));
return -1;
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - created remote databases\n"));
/* update the database priority for all remote databases */
ret = update_db_priority_on_remote_nodes(ctdb, nodemap, pnn, dbmap, mem_ctx);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to set db priority on remote nodes\n"));
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - updated db priority for all databases\n"));
/* update all other nodes to use the same setting for reclock files
as the local recovery master.
*/
sync_recovery_lock_file_across_cluster(rec);
/* set recovery mode to active on all nodes */
ret = set_recovery_mode(ctdb, rec, nodemap, CTDB_RECOVERY_ACTIVE);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to set recovery mode to active on cluster\n"));
return -1;
}
/* execute the "startrecovery" event script on all nodes */
ret = run_startrecovery_eventscript(rec, nodemap);
if (ret!=0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to run the 'startrecovery' event on cluster\n"));
return -1;
}
/*
update all nodes to have the same flags that we have
*/
for (i=0;i<nodemap->num;i++) {
if (nodemap->nodes[i].flags & NODE_FLAGS_DISCONNECTED) {
continue;
}
ret = update_flags_on_all_nodes(ctdb, nodemap, i, nodemap->nodes[i].flags);
if (ret != 0) {
if (nodemap->nodes[i].flags & NODE_FLAGS_INACTIVE) {
DEBUG(DEBUG_WARNING, (__location__ "Unable to update flags on inactive node %d\n", i));
} else {
DEBUG(DEBUG_ERR, (__location__ " Unable to update flags on all nodes for node %d\n", i));
return -1;
}
}
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - updated flags\n"));
/* pick a new generation number */
generation = new_generation();
/* change the vnnmap on this node to use the new generation
number but not on any other nodes.
this guarantees that if we abort the recovery prematurely
for some reason (a node stops responding?)
that we can just return immediately and we will reenter
recovery shortly again.
I.e. we deliberately leave the cluster with an inconsistent
generation id to allow us to abort recovery at any stage and
just restart it from scratch.
*/
vnnmap->generation = generation;
ret = ctdb_ctrl_setvnnmap(ctdb, CONTROL_TIMEOUT(), pnn, mem_ctx, vnnmap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to set vnnmap for node %u\n", pnn));
return -1;
}
data.dptr = (void *)&generation;
data.dsize = sizeof(uint32_t);
nodes = list_of_active_nodes(ctdb, nodemap, mem_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_TRANSACTION_START,
nodes, 0,
CONTROL_TIMEOUT(), false, data,
NULL,
transaction_start_fail_callback,
rec) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to start transactions. Recovery failed.\n"));
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_TRANSACTION_CANCEL,
nodes, 0,
CONTROL_TIMEOUT(), false, tdb_null,
NULL,
NULL,
NULL) != 0) {
DEBUG(DEBUG_ERR,("Failed to cancel recovery transaction\n"));
}
return -1;
}
DEBUG(DEBUG_NOTICE,(__location__ " started transactions on all nodes\n"));
for (i=0;i<dbmap->num;i++) {
ret = recover_database(rec, mem_ctx,
dbmap->dbs[i].dbid,
dbmap->dbs[i].flags & CTDB_DB_FLAGS_PERSISTENT,
pnn, nodemap, generation);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Failed to recover database 0x%x\n", dbmap->dbs[i].dbid));
return -1;
}
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - starting database commits\n"));
/* commit all the changes */
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_TRANSACTION_COMMIT,
nodes, 0,
CONTROL_TIMEOUT(), false, data,
NULL, NULL,
NULL) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to commit recovery changes. Recovery failed.\n"));
return -1;
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - committed databases\n"));
/* update the capabilities for all nodes */
ret = update_capabilities(ctdb, nodemap);
if (ret!=0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to update node capabilities.\n"));
return -1;
}
/* build a new vnn map with all the currently active and
unbanned nodes */
generation = new_generation();
vnnmap = talloc(mem_ctx, struct ctdb_vnn_map);
CTDB_NO_MEMORY(ctdb, vnnmap);
vnnmap->generation = generation;
vnnmap->size = 0;
vnnmap->map = talloc_zero_array(vnnmap, uint32_t, vnnmap->size);
CTDB_NO_MEMORY(ctdb, vnnmap->map);
for (i=j=0;i<nodemap->num;i++) {
if (nodemap->nodes[i].flags & NODE_FLAGS_INACTIVE) {
continue;
}
if (!(ctdb->nodes[i]->capabilities & CTDB_CAP_LMASTER)) {
/* this node can not be an lmaster */
DEBUG(DEBUG_DEBUG, ("Node %d cant be a LMASTER, skipping it\n", i));
continue;
}
vnnmap->size++;
vnnmap->map = talloc_realloc(vnnmap, vnnmap->map, uint32_t, vnnmap->size);
CTDB_NO_MEMORY(ctdb, vnnmap->map);
vnnmap->map[j++] = nodemap->nodes[i].pnn;
}
if (vnnmap->size == 0) {
DEBUG(DEBUG_NOTICE, ("No suitable lmasters found. Adding local node (recmaster) anyway.\n"));
vnnmap->size++;
vnnmap->map = talloc_realloc(vnnmap, vnnmap->map, uint32_t, vnnmap->size);
CTDB_NO_MEMORY(ctdb, vnnmap->map);
vnnmap->map[0] = pnn;
}
/* update to the new vnnmap on all nodes */
ret = update_vnnmap_on_all_nodes(ctdb, nodemap, pnn, vnnmap, mem_ctx);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to update vnnmap on all nodes\n"));
return -1;
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - updated vnnmap\n"));
/* update recmaster to point to us for all nodes */
ret = set_recovery_master(ctdb, nodemap, pnn);
if (ret!=0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to set recovery master\n"));
return -1;
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - updated recmaster\n"));
/* disable recovery mode */
ret = set_recovery_mode(ctdb, rec, nodemap, CTDB_RECOVERY_NORMAL);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to set recovery mode to normal on cluster\n"));
return -1;
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - disabled recovery mode\n"));
/* Fetch known/available public IPs from each active node */
ret = ctdb_reload_remote_public_ips(ctdb, rec, nodemap, &culprit);
if (ret != 0) {
DEBUG(DEBUG_ERR,("Failed to read public ips from remote node %d\n",
culprit));
rec->need_takeover_run = true;
return -1;
}
do_takeover_run(rec, nodemap, false);
/* execute the "recovered" event script on all nodes */
ret = run_recovered_eventscript(rec, nodemap, "do_recovery");
if (ret!=0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to run the 'recovered' event on cluster. Recovery process failed.\n"));
return -1;
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery - finished the recovered event\n"));
/* send a message to all clients telling them that the cluster
has been reconfigured */
ret = ctdb_client_send_message(ctdb, CTDB_BROADCAST_CONNECTED,
CTDB_SRVID_RECONFIGURE, tdb_null);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Failed to send reconfigure message\n"));
return -1;
}
DEBUG(DEBUG_NOTICE, (__location__ " Recovery complete\n"));
rec->need_recovery = false;
/* we managed to complete a full recovery, make sure to forgive
any past sins by the nodes that could now participate in the
recovery.
*/
DEBUG(DEBUG_ERR,("Resetting ban count to 0 for all nodes\n"));
for (i=0;i<nodemap->num;i++) {
struct ctdb_banning_state *ban_state;
if (nodemap->nodes[i].flags & NODE_FLAGS_DISCONNECTED) {
continue;
}
ban_state = (struct ctdb_banning_state *)ctdb->nodes[nodemap->nodes[i].pnn]->ban_state;
if (ban_state == NULL) {
continue;
}
ban_state->count = 0;
}
/* We just finished a recovery successfully.
We now wait for rerecovery_timeout before we allow
another recovery to take place.
*/
DEBUG(DEBUG_NOTICE, ("Just finished a recovery. New recoveries will now be supressed for the rerecovery timeout (%d seconds)\n", ctdb->tunable.rerecovery_timeout));
ctdb_wait_timeout(ctdb, ctdb->tunable.rerecovery_timeout);
DEBUG(DEBUG_NOTICE, ("The rerecovery timeout has elapsed. We now allow recoveries to trigger again.\n"));
return 0;
}
/*
elections are won by first checking the number of connected nodes, then
the priority time, then the pnn
*/
struct election_message {
uint32_t num_connected;
struct timeval priority_time;
uint32_t pnn;
uint32_t node_flags;
};
/*
form this nodes election data
*/
static void ctdb_election_data(struct ctdb_recoverd *rec, struct election_message *em)
{
int ret, i;
struct ctdb_node_map *nodemap;
struct ctdb_context *ctdb = rec->ctdb;
ZERO_STRUCTP(em);
em->pnn = rec->ctdb->pnn;
em->priority_time = rec->priority_time;
ret = ctdb_ctrl_getnodemap(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, rec, &nodemap);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " unable to get node map\n"));
return;
}
rec->node_flags = nodemap->nodes[ctdb->pnn].flags;
em->node_flags = rec->node_flags;
for (i=0;i<nodemap->num;i++) {
if (!(nodemap->nodes[i].flags & NODE_FLAGS_DISCONNECTED)) {
em->num_connected++;
}
}
/* we shouldnt try to win this election if we cant be a recmaster */
if ((ctdb->capabilities & CTDB_CAP_RECMASTER) == 0) {
em->num_connected = 0;
em->priority_time = timeval_current();
}
talloc_free(nodemap);
}
/*
see if the given election data wins
*/
static bool ctdb_election_win(struct ctdb_recoverd *rec, struct election_message *em)
{
struct election_message myem;
int cmp = 0;
ctdb_election_data(rec, &myem);
/* we cant win if we dont have the recmaster capability */
if ((rec->ctdb->capabilities & CTDB_CAP_RECMASTER) == 0) {
return false;
}
/* we cant win if we are banned */
if (rec->node_flags & NODE_FLAGS_BANNED) {
return false;
}
/* we cant win if we are stopped */
if (rec->node_flags & NODE_FLAGS_STOPPED) {
return false;
}
/* we will automatically win if the other node is banned */
if (em->node_flags & NODE_FLAGS_BANNED) {
return true;
}
/* we will automatically win if the other node is banned */
if (em->node_flags & NODE_FLAGS_STOPPED) {
return true;
}
/* try to use the most connected node */
if (cmp == 0) {
cmp = (int)myem.num_connected - (int)em->num_connected;
}
/* then the longest running node */
if (cmp == 0) {
cmp = timeval_compare(&em->priority_time, &myem.priority_time);
}
if (cmp == 0) {
cmp = (int)myem.pnn - (int)em->pnn;
}
return cmp > 0;
}
/*
send out an election request
*/
static int send_election_request(struct ctdb_recoverd *rec, uint32_t pnn)
{
int ret;
TDB_DATA election_data;
struct election_message emsg;
uint64_t srvid;
struct ctdb_context *ctdb = rec->ctdb;
srvid = CTDB_SRVID_RECOVERY;
ctdb_election_data(rec, &emsg);
election_data.dsize = sizeof(struct election_message);
election_data.dptr = (unsigned char *)&emsg;
/* first we assume we will win the election and set
recoverymaster to be ourself on the current node
*/
ret = ctdb_ctrl_setrecmaster(ctdb, CONTROL_TIMEOUT(), pnn, pnn);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " failed to send recmaster election request\n"));
return -1;
}
/* send an election message to all active nodes */
DEBUG(DEBUG_INFO,(__location__ " Send election request to all active nodes\n"));
return ctdb_client_send_message(ctdb, CTDB_BROADCAST_ALL, srvid, election_data);
}
/*
this function will unban all nodes in the cluster
*/
static void unban_all_nodes(struct ctdb_context *ctdb)
{
int ret, i;
struct ctdb_node_map *nodemap;
TALLOC_CTX *tmp_ctx = talloc_new(ctdb);
ret = ctdb_ctrl_getnodemap(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, tmp_ctx, &nodemap);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " failed to get nodemap to unban all nodes\n"));
return;
}
for (i=0;i<nodemap->num;i++) {
if ( (!(nodemap->nodes[i].flags & NODE_FLAGS_DISCONNECTED))
&& (nodemap->nodes[i].flags & NODE_FLAGS_BANNED) ) {
ret = ctdb_ctrl_modflags(ctdb, CONTROL_TIMEOUT(),
nodemap->nodes[i].pnn, 0,
NODE_FLAGS_BANNED);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " failed to reset ban state\n"));
}
}
}
talloc_free(tmp_ctx);
}
/*
we think we are winning the election - send a broadcast election request
*/
static void election_send_request(struct event_context *ev, struct timed_event *te, struct timeval t, void *p)
{
struct ctdb_recoverd *rec = talloc_get_type(p, struct ctdb_recoverd);
int ret;
ret = send_election_request(rec, ctdb_get_pnn(rec->ctdb));
if (ret != 0) {
DEBUG(DEBUG_ERR,("Failed to send election request!\n"));
}
talloc_free(rec->send_election_te);
rec->send_election_te = NULL;
}
/*
handler for memory dumps
*/
static void mem_dump_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
TALLOC_CTX *tmp_ctx = talloc_new(ctdb);
TDB_DATA *dump;
int ret;
struct srvid_request *rd;
if (data.dsize != sizeof(struct srvid_request)) {
DEBUG(DEBUG_ERR, (__location__ " Wrong size of return address.\n"));
talloc_free(tmp_ctx);
return;
}
rd = (struct srvid_request *)data.dptr;
dump = talloc_zero(tmp_ctx, TDB_DATA);
if (dump == NULL) {
DEBUG(DEBUG_ERR, (__location__ " Failed to allocate memory for memdump\n"));
talloc_free(tmp_ctx);
return;
}
ret = ctdb_dump_memory(ctdb, dump);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " ctdb_dump_memory() failed\n"));
talloc_free(tmp_ctx);
return;
}
DEBUG(DEBUG_ERR, ("recovery master memory dump\n"));
ret = ctdb_client_send_message(ctdb, rd->pnn, rd->srvid, *dump);
if (ret != 0) {
DEBUG(DEBUG_ERR,("Failed to send rd memdump reply message\n"));
talloc_free(tmp_ctx);
return;
}
talloc_free(tmp_ctx);
}
/*
handler for getlog
*/
static void getlog_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
struct ctdb_get_log_addr *log_addr;
pid_t child;
if (data.dsize != sizeof(struct ctdb_get_log_addr)) {
DEBUG(DEBUG_ERR, (__location__ " Wrong size of return address.\n"));
return;
}
log_addr = (struct ctdb_get_log_addr *)data.dptr;
child = ctdb_fork_no_free_ringbuffer(ctdb);
if (child == (pid_t)-1) {
DEBUG(DEBUG_ERR,("Failed to fork a log collector child\n"));
return;
}
if (child == 0) {
ctdb_set_process_name("ctdb_rec_log_collector");
if (switch_from_server_to_client(ctdb, "recoverd-log-collector") != 0) {
DEBUG(DEBUG_CRIT, (__location__ "ERROR: failed to switch log collector child into client mode.\n"));
_exit(1);
}
ctdb_collect_log(ctdb, log_addr);
_exit(0);
}
}
/*
handler for clearlog
*/
static void clearlog_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
ctdb_clear_log(ctdb);
}
/*
handler for reload_nodes
*/
static void reload_nodes_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
struct ctdb_recoverd *rec = talloc_get_type(private_data, struct ctdb_recoverd);
DEBUG(DEBUG_ERR, (__location__ " Reload nodes file from recovery daemon\n"));
ctdb_load_nodes_file(rec->ctdb);
}
static void ctdb_rebalance_timeout(struct event_context *ev,
struct timed_event *te,
struct timeval t, void *p)
{
struct ctdb_recoverd *rec = talloc_get_type(p, struct ctdb_recoverd);
if (rec->force_rebalance_nodes == NULL) {
DEBUG(DEBUG_ERR,
("Rebalance timeout occurred - no nodes to rebalance\n"));
return;
}
DEBUG(DEBUG_NOTICE,
("Rebalance timeout occurred - do takeover run\n"));
do_takeover_run(rec, rec->nodemap, false);
}
static void recd_node_rebalance_handler(struct ctdb_context *ctdb,
uint64_t srvid,
TDB_DATA data, void *private_data)
{
uint32_t pnn;
uint32_t *t;
int len;
uint32_t deferred_rebalance;
struct ctdb_recoverd *rec = talloc_get_type(private_data, struct ctdb_recoverd);
if (rec->recmaster != ctdb_get_pnn(ctdb)) {
return;
}
if (data.dsize != sizeof(uint32_t)) {
DEBUG(DEBUG_ERR,(__location__ " Incorrect size of node rebalance message. Was %zd but expected %zd bytes\n", data.dsize, sizeof(uint32_t)));
return;
}
pnn = *(uint32_t *)&data.dptr[0];
DEBUG(DEBUG_NOTICE,("Setting up rebalance of IPs to node %u\n", pnn));
/* Copy any existing list of nodes. There's probably some
* sort of realloc variant that will do this but we need to
* make sure that freeing the old array also cancels the timer
* event for the timeout... not sure if realloc will do that.
*/
len = (rec->force_rebalance_nodes != NULL) ?
talloc_array_length(rec->force_rebalance_nodes) :
0;
/* This allows duplicates to be added but they don't cause
* harm. A call to add a duplicate PNN arguably means that
* the timeout should be reset, so this is the simplest
* solution.
*/
t = talloc_zero_array(rec, uint32_t, len+1);
CTDB_NO_MEMORY_VOID(ctdb, t);
if (len > 0) {
memcpy(t, rec->force_rebalance_nodes, sizeof(uint32_t) * len);
}
t[len] = pnn;
talloc_free(rec->force_rebalance_nodes);
rec->force_rebalance_nodes = t;
/* If configured, setup a deferred takeover run to make sure
* that certain nodes get IPs rebalanced to them. This will
* be cancelled if a successful takeover run happens before
* the timeout. Assign tunable value to variable for
* readability.
*/
deferred_rebalance = ctdb->tunable.deferred_rebalance_on_node_add;
if (deferred_rebalance != 0) {
event_add_timed(ctdb->ev, rec->force_rebalance_nodes,
timeval_current_ofs(deferred_rebalance, 0),
ctdb_rebalance_timeout, rec);
}
}
static void recd_update_ip_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
struct ctdb_recoverd *rec = talloc_get_type(private_data, struct ctdb_recoverd);
struct ctdb_public_ip *ip;
if (rec->recmaster != rec->ctdb->pnn) {
DEBUG(DEBUG_INFO,("Not recmaster, ignore update ip message\n"));
return;
}
if (data.dsize != sizeof(struct ctdb_public_ip)) {
DEBUG(DEBUG_ERR,(__location__ " Incorrect size of recd update ip message. Was %zd but expected %zd bytes\n", data.dsize, sizeof(struct ctdb_public_ip)));
return;
}
ip = (struct ctdb_public_ip *)data.dptr;
update_ip_assignment_tree(rec->ctdb, ip);
}
static void clear_takeover_runs_disable(struct ctdb_recoverd *rec)
{
TALLOC_FREE(rec->takeover_runs_disable_ctx);
}
static void reenable_takeover_runs(struct event_context *ev,
struct timed_event *te,
struct timeval yt, void *p)
{
struct ctdb_recoverd *rec = talloc_get_type(p, struct ctdb_recoverd);
DEBUG(DEBUG_NOTICE,("Reenabling takeover runs after timeout\n"));
clear_takeover_runs_disable(rec);
}
static void disable_takeover_runs_handler(struct ctdb_context *ctdb,
uint64_t srvid, TDB_DATA data,
void *private_data)
{
struct ctdb_recoverd *rec = talloc_get_type(private_data,
struct ctdb_recoverd);
struct srvid_request_data *r;
uint32_t timeout;
TDB_DATA result;
int32_t ret = 0;
/* Validate input data */
if (data.dsize != sizeof(struct srvid_request_data)) {
DEBUG(DEBUG_ERR,(__location__ " Wrong size for data :%lu "
"expecting %lu\n", (long unsigned)data.dsize,
(long unsigned)sizeof(struct srvid_request)));
return;
}
if (data.dptr == NULL) {
DEBUG(DEBUG_ERR,(__location__ " No data received\n"));
return;
}
r = (struct srvid_request_data *)data.dptr;
timeout = r->data;
if (timeout == 0) {
DEBUG(DEBUG_NOTICE,("Reenabling takeover runs\n"));
clear_takeover_runs_disable(rec);
ret = ctdb_get_pnn(ctdb);
goto done;
}
if (rec->node_flags & NODE_FLAGS_INACTIVE) {
DEBUG(DEBUG_ERR,
("Refusing to disable takeover runs on inactive node\n"));
ret = -EHOSTDOWN;
goto done;
}
if (rec->takeover_run_in_progress) {
DEBUG(DEBUG_ERR,
("Unable to disable takeover runs - in progress\n"));
ret = -EAGAIN;
goto done;
}
DEBUG(DEBUG_NOTICE,("Disabling takeover runs for %u seconds\n", timeout));
/* Clear any old timers */
clear_takeover_runs_disable(rec);
/* When this is non-NULL it indicates that takeover runs are
* disabled. This context also holds the timeout timer.
*/
rec->takeover_runs_disable_ctx = talloc_new(rec);
if (rec->takeover_runs_disable_ctx == NULL) {
DEBUG(DEBUG_ERR,(__location__ " Unable to allocate memory\n"));
ret = -ENOMEM;
goto done;
}
/* Arrange for the timeout to occur */
event_add_timed(ctdb->ev, rec->takeover_runs_disable_ctx,
timeval_current_ofs(timeout, 0),
reenable_takeover_runs,
rec);
/* Returning our PNN tells the caller that we succeeded */
ret = ctdb_get_pnn(ctdb);
done:
result.dsize = sizeof(int32_t);
result.dptr = (uint8_t *)&ret;
srvid_request_reply(ctdb, (struct srvid_request *)r, result);
}
/* Backward compatibility for this SRVID - call
* disable_takeover_runs_handler() instead
*/
static void disable_ip_check_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
struct ctdb_recoverd *rec = talloc_get_type(private_data,
struct ctdb_recoverd);
TDB_DATA data2;
struct srvid_request_data *req;
if (data.dsize != sizeof(uint32_t)) {
DEBUG(DEBUG_ERR,(__location__ " Wrong size for data :%lu "
"expecting %lu\n", (long unsigned)data.dsize,
(long unsigned)sizeof(uint32_t)));
return;
}
if (data.dptr == NULL) {
DEBUG(DEBUG_ERR,(__location__ " No data received\n"));
return;
}
req = talloc(ctdb, struct srvid_request_data);
CTDB_NO_MEMORY_VOID(ctdb, req);
req->srvid = 0; /* No reply */
req->pnn = -1;
req->data = *((uint32_t *)data.dptr); /* Timeout */
data2.dsize = sizeof(*req);
data2.dptr = (uint8_t *)req;
disable_takeover_runs_handler(rec->ctdb,
CTDB_SRVID_DISABLE_TAKEOVER_RUNS,
data2, rec);
}
/*
handler for ip reallocate, just add it to the list of requests and
handle this later in the monitor_cluster loop so we do not recurse
with other requests to takeover_run()
*/
static void ip_reallocate_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
struct srvid_request *request;
struct ctdb_recoverd *rec = talloc_get_type(private_data,
struct ctdb_recoverd);
if (data.dsize != sizeof(struct srvid_request)) {
DEBUG(DEBUG_ERR, (__location__ " Wrong size of return address.\n"));
return;
}
request = (struct srvid_request *)data.dptr;
srvid_request_add(ctdb, &rec->reallocate_requests, request);
}
static void process_ipreallocate_requests(struct ctdb_context *ctdb,
struct ctdb_recoverd *rec)
{
TDB_DATA result;
int32_t ret;
uint32_t culprit;
struct srvid_requests *current;
DEBUG(DEBUG_INFO, ("recovery master forced ip reallocation\n"));
/* Only process requests that are currently pending. More
* might come in while the takeover run is in progress and
* they will need to be processed later since they might
* be in response flag changes.
*/
current = rec->reallocate_requests;
rec->reallocate_requests = NULL;
/* update the list of public ips that a node can handle for
all connected nodes
*/
ret = ctdb_reload_remote_public_ips(ctdb, rec, rec->nodemap, &culprit);
if (ret != 0) {
DEBUG(DEBUG_ERR,("Failed to read public ips from remote node %d\n",
culprit));
rec->need_takeover_run = true;
}
if (ret == 0) {
if (do_takeover_run(rec, rec->nodemap, false)) {
ret = ctdb_get_pnn(ctdb);
} else {
ret = -1;
}
}
result.dsize = sizeof(int32_t);
result.dptr = (uint8_t *)&ret;
srvid_requests_reply(ctdb, &current, result);
}
/*
handler for recovery master elections
*/
static void election_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
struct ctdb_recoverd *rec = talloc_get_type(private_data, struct ctdb_recoverd);
int ret;
struct election_message *em = (struct election_message *)data.dptr;
TALLOC_CTX *mem_ctx;
/* Ignore election packets from ourself */
if (ctdb->pnn == em->pnn) {
return;
}
/* we got an election packet - update the timeout for the election */
talloc_free(rec->election_timeout);
rec->election_timeout = event_add_timed(ctdb->ev, ctdb,
fast_start ?
timeval_current_ofs(0, 500000) :
timeval_current_ofs(ctdb->tunable.election_timeout, 0),
ctdb_election_timeout, rec);
mem_ctx = talloc_new(ctdb);
/* someone called an election. check their election data
and if we disagree and we would rather be the elected node,
send a new election message to all other nodes
*/
if (ctdb_election_win(rec, em)) {
if (!rec->send_election_te) {
rec->send_election_te = event_add_timed(ctdb->ev, rec,
timeval_current_ofs(0, 500000),
election_send_request, rec);
}
talloc_free(mem_ctx);
/*unban_all_nodes(ctdb);*/
return;
}
/* we didn't win */
talloc_free(rec->send_election_te);
rec->send_election_te = NULL;
if (ctdb->tunable.verify_recovery_lock != 0) {
/* release the recmaster lock */
if (em->pnn != ctdb->pnn &&
ctdb->recovery_lock_fd != -1) {
close(ctdb->recovery_lock_fd);
ctdb->recovery_lock_fd = -1;
unban_all_nodes(ctdb);
}
}
/* ok, let that guy become recmaster then */
ret = ctdb_ctrl_setrecmaster(ctdb, CONTROL_TIMEOUT(), ctdb_get_pnn(ctdb), em->pnn);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " failed to send recmaster election request"));
talloc_free(mem_ctx);
return;
}
talloc_free(mem_ctx);
return;
}
/*
force the start of the election process
*/
static void force_election(struct ctdb_recoverd *rec, uint32_t pnn,
struct ctdb_node_map *nodemap)
{
int ret;
struct ctdb_context *ctdb = rec->ctdb;
DEBUG(DEBUG_INFO,(__location__ " Force an election\n"));
/* set all nodes to recovery mode to stop all internode traffic */
ret = set_recovery_mode(ctdb, rec, nodemap, CTDB_RECOVERY_ACTIVE);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to set recovery mode to active on cluster\n"));
return;
}
talloc_free(rec->election_timeout);
rec->election_timeout = event_add_timed(ctdb->ev, ctdb,
fast_start ?
timeval_current_ofs(0, 500000) :
timeval_current_ofs(ctdb->tunable.election_timeout, 0),
ctdb_election_timeout, rec);
ret = send_election_request(rec, pnn);
if (ret!=0) {
DEBUG(DEBUG_ERR, (__location__ " failed to initiate recmaster election"));
return;
}
/* wait for a few seconds to collect all responses */
ctdb_wait_election(rec);
}
/*
handler for when a node changes its flags
*/
static void monitor_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
int ret;
struct ctdb_node_flag_change *c = (struct ctdb_node_flag_change *)data.dptr;
struct ctdb_node_map *nodemap=NULL;
TALLOC_CTX *tmp_ctx;
int i;
struct ctdb_recoverd *rec = talloc_get_type(private_data, struct ctdb_recoverd);
int disabled_flag_changed;
if (data.dsize != sizeof(*c)) {
DEBUG(DEBUG_ERR,(__location__ "Invalid data in ctdb_node_flag_change\n"));
return;
}
tmp_ctx = talloc_new(ctdb);
CTDB_NO_MEMORY_VOID(ctdb, tmp_ctx);
ret = ctdb_ctrl_getnodemap(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, tmp_ctx, &nodemap);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ "ctdb_ctrl_getnodemap failed in monitor_handler\n"));
talloc_free(tmp_ctx);
return;
}
for (i=0;i<nodemap->num;i++) {
if (nodemap->nodes[i].pnn == c->pnn) break;
}
if (i == nodemap->num) {
DEBUG(DEBUG_CRIT,(__location__ "Flag change for non-existant node %u\n", c->pnn));
talloc_free(tmp_ctx);
return;
}
if (c->old_flags != c->new_flags) {
DEBUG(DEBUG_NOTICE,("Node %u has changed flags - now 0x%x was 0x%x\n", c->pnn, c->new_flags, c->old_flags));
}
disabled_flag_changed = (nodemap->nodes[i].flags ^ c->new_flags) & NODE_FLAGS_DISABLED;
nodemap->nodes[i].flags = c->new_flags;
ret = ctdb_ctrl_getrecmaster(ctdb, tmp_ctx, CONTROL_TIMEOUT(),
CTDB_CURRENT_NODE, &ctdb->recovery_master);
if (ret == 0) {
ret = ctdb_ctrl_getrecmode(ctdb, tmp_ctx, CONTROL_TIMEOUT(),
CTDB_CURRENT_NODE, &ctdb->recovery_mode);
}
if (ret == 0 &&
ctdb->recovery_master == ctdb->pnn &&
ctdb->recovery_mode == CTDB_RECOVERY_NORMAL) {
/* Only do the takeover run if the perm disabled or unhealthy
flags changed since these will cause an ip failover but not
a recovery.
If the node became disconnected or banned this will also
lead to an ip address failover but that is handled
during recovery
*/
if (disabled_flag_changed) {
rec->need_takeover_run = true;
}
}
talloc_free(tmp_ctx);
}
/*
handler for when we need to push out flag changes ot all other nodes
*/
static void push_flags_handler(struct ctdb_context *ctdb, uint64_t srvid,
TDB_DATA data, void *private_data)
{
int ret;
struct ctdb_node_flag_change *c = (struct ctdb_node_flag_change *)data.dptr;
struct ctdb_node_map *nodemap=NULL;
TALLOC_CTX *tmp_ctx = talloc_new(ctdb);
uint32_t recmaster;
uint32_t *nodes;
/* find the recovery master */
ret = ctdb_ctrl_getrecmaster(ctdb, tmp_ctx, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, &recmaster);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get recmaster from local node\n"));
talloc_free(tmp_ctx);
return;
}
/* read the node flags from the recmaster */
ret = ctdb_ctrl_getnodemap(ctdb, CONTROL_TIMEOUT(), recmaster, tmp_ctx, &nodemap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get nodemap from node %u\n", c->pnn));
talloc_free(tmp_ctx);
return;
}
if (c->pnn >= nodemap->num) {
DEBUG(DEBUG_ERR,(__location__ " Nodemap from recmaster does not contain node %d\n", c->pnn));
talloc_free(tmp_ctx);
return;
}
/* send the flags update to all connected nodes */
nodes = list_of_connected_nodes(ctdb, nodemap, tmp_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_MODIFY_FLAGS,
nodes, 0, CONTROL_TIMEOUT(),
false, data,
NULL, NULL,
NULL) != 0) {
DEBUG(DEBUG_ERR, (__location__ " ctdb_control to modify node flags failed\n"));
talloc_free(tmp_ctx);
return;
}
talloc_free(tmp_ctx);
}
struct verify_recmode_normal_data {
uint32_t count;
enum monitor_result status;
};
static void verify_recmode_normal_callback(struct ctdb_client_control_state *state)
{
struct verify_recmode_normal_data *rmdata = talloc_get_type(state->async.private_data, struct verify_recmode_normal_data);
/* one more node has responded with recmode data*/
rmdata->count--;
/* if we failed to get the recmode, then return an error and let
the main loop try again.
*/
if (state->state != CTDB_CONTROL_DONE) {
if (rmdata->status == MONITOR_OK) {
rmdata->status = MONITOR_FAILED;
}
return;
}
/* if we got a response, then the recmode will be stored in the
status field
*/
if (state->status != CTDB_RECOVERY_NORMAL) {
DEBUG(DEBUG_NOTICE, ("Node:%u was in recovery mode. Start recovery process\n", state->c->hdr.destnode));
rmdata->status = MONITOR_RECOVERY_NEEDED;
}
return;
}
/* verify that all nodes are in normal recovery mode */
static enum monitor_result verify_recmode(struct ctdb_context *ctdb, struct ctdb_node_map *nodemap)
{
struct verify_recmode_normal_data *rmdata;
TALLOC_CTX *mem_ctx = talloc_new(ctdb);
struct ctdb_client_control_state *state;
enum monitor_result status;
int j;
rmdata = talloc(mem_ctx, struct verify_recmode_normal_data);
CTDB_NO_MEMORY_FATAL(ctdb, rmdata);
rmdata->count = 0;
rmdata->status = MONITOR_OK;
/* loop over all active nodes and send an async getrecmode call to
them*/
for (j=0; j<nodemap->num; j++) {
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
state = ctdb_ctrl_getrecmode_send(ctdb, mem_ctx,
CONTROL_TIMEOUT(),
nodemap->nodes[j].pnn);
if (state == NULL) {
/* we failed to send the control, treat this as
an error and try again next iteration
*/
DEBUG(DEBUG_ERR,("Failed to call ctdb_ctrl_getrecmode_send during monitoring\n"));
talloc_free(mem_ctx);
return MONITOR_FAILED;
}
/* set up the callback functions */
state->async.fn = verify_recmode_normal_callback;
state->async.private_data = rmdata;
/* one more control to wait for to complete */
rmdata->count++;
}
/* now wait for up to the maximum number of seconds allowed
or until all nodes we expect a response from has replied
*/
while (rmdata->count > 0) {
event_loop_once(ctdb->ev);
}
status = rmdata->status;
talloc_free(mem_ctx);
return status;
}
struct verify_recmaster_data {
struct ctdb_recoverd *rec;
uint32_t count;
uint32_t pnn;
enum monitor_result status;
};
static void verify_recmaster_callback(struct ctdb_client_control_state *state)
{
struct verify_recmaster_data *rmdata = talloc_get_type(state->async.private_data, struct verify_recmaster_data);
/* one more node has responded with recmaster data*/
rmdata->count--;
/* if we failed to get the recmaster, then return an error and let
the main loop try again.
*/
if (state->state != CTDB_CONTROL_DONE) {
if (rmdata->status == MONITOR_OK) {
rmdata->status = MONITOR_FAILED;
}
return;
}
/* if we got a response, then the recmaster will be stored in the
status field
*/
if (state->status != rmdata->pnn) {
DEBUG(DEBUG_ERR,("Node %d thinks node %d is recmaster. Need a new recmaster election\n", state->c->hdr.destnode, state->status));
ctdb_set_culprit(rmdata->rec, state->c->hdr.destnode);
rmdata->status = MONITOR_ELECTION_NEEDED;
}
return;
}
/* verify that all nodes agree that we are the recmaster */
static enum monitor_result verify_recmaster(struct ctdb_recoverd *rec, struct ctdb_node_map *nodemap, uint32_t pnn)
{
struct ctdb_context *ctdb = rec->ctdb;
struct verify_recmaster_data *rmdata;
TALLOC_CTX *mem_ctx = talloc_new(ctdb);
struct ctdb_client_control_state *state;
enum monitor_result status;
int j;
rmdata = talloc(mem_ctx, struct verify_recmaster_data);
CTDB_NO_MEMORY_FATAL(ctdb, rmdata);
rmdata->rec = rec;
rmdata->count = 0;
rmdata->pnn = pnn;
rmdata->status = MONITOR_OK;
/* loop over all active nodes and send an async getrecmaster call to
them*/
for (j=0; j<nodemap->num; j++) {
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
state = ctdb_ctrl_getrecmaster_send(ctdb, mem_ctx,
CONTROL_TIMEOUT(),
nodemap->nodes[j].pnn);
if (state == NULL) {
/* we failed to send the control, treat this as
an error and try again next iteration
*/
DEBUG(DEBUG_ERR,("Failed to call ctdb_ctrl_getrecmaster_send during monitoring\n"));
talloc_free(mem_ctx);
return MONITOR_FAILED;
}
/* set up the callback functions */
state->async.fn = verify_recmaster_callback;
state->async.private_data = rmdata;
/* one more control to wait for to complete */
rmdata->count++;
}
/* now wait for up to the maximum number of seconds allowed
or until all nodes we expect a response from has replied
*/
while (rmdata->count > 0) {
event_loop_once(ctdb->ev);
}
status = rmdata->status;
talloc_free(mem_ctx);
return status;
}
static bool interfaces_have_changed(struct ctdb_context *ctdb,
struct ctdb_recoverd *rec)
{
struct ctdb_control_get_ifaces *ifaces = NULL;
TALLOC_CTX *mem_ctx;
bool ret = false;
mem_ctx = talloc_new(NULL);
/* Read the interfaces from the local node */
if (ctdb_ctrl_get_ifaces(ctdb, CONTROL_TIMEOUT(),
CTDB_CURRENT_NODE, mem_ctx, &ifaces) != 0) {
DEBUG(DEBUG_ERR, ("Unable to get interfaces from local node %u\n", ctdb->pnn));
/* We could return an error. However, this will be
* rare so we'll decide that the interfaces have
* actually changed, just in case.
*/
talloc_free(mem_ctx);
return true;
}
if (!rec->ifaces) {
/* We haven't been here before so things have changed */
DEBUG(DEBUG_NOTICE, ("Initial interface fetched\n"));
ret = true;
} else if (rec->ifaces->num != ifaces->num) {
/* Number of interfaces has changed */
DEBUG(DEBUG_NOTICE, ("Interface count changed from %d to %d\n",
rec->ifaces->num, ifaces->num));
ret = true;
} else {
/* See if interface names or link states have changed */
int i;
for (i = 0; i < rec->ifaces->num; i++) {
struct ctdb_control_iface_info * iface = &rec->ifaces->ifaces[i];
if (strcmp(iface->name, ifaces->ifaces[i].name) != 0) {
DEBUG(DEBUG_NOTICE,
("Interface in slot %d changed: %s => %s\n",
i, iface->name, ifaces->ifaces[i].name));
ret = true;
break;
}
if (iface->link_state != ifaces->ifaces[i].link_state) {
DEBUG(DEBUG_NOTICE,
("Interface %s changed state: %d => %d\n",
iface->name, iface->link_state,
ifaces->ifaces[i].link_state));
ret = true;
break;
}
}
}
talloc_free(rec->ifaces);
rec->ifaces = talloc_steal(rec, ifaces);
talloc_free(mem_ctx);
return ret;
}
/* called to check that the local allocation of public ip addresses is ok.
*/
static int verify_local_ip_allocation(struct ctdb_context *ctdb, struct ctdb_recoverd *rec, uint32_t pnn, struct ctdb_node_map *nodemap)
{
TALLOC_CTX *mem_ctx = talloc_new(NULL);
struct ctdb_uptime *uptime1 = NULL;
struct ctdb_uptime *uptime2 = NULL;
int ret, j;
bool need_takeover_run = false;
ret = ctdb_ctrl_uptime(ctdb, mem_ctx, CONTROL_TIMEOUT(),
CTDB_CURRENT_NODE, &uptime1);
if (ret != 0) {
DEBUG(DEBUG_ERR, ("Unable to get uptime from local node %u\n", pnn));
talloc_free(mem_ctx);
return -1;
}
if (interfaces_have_changed(ctdb, rec)) {
DEBUG(DEBUG_NOTICE, ("The interfaces status has changed on "
"local node %u - force takeover run\n",
pnn));
need_takeover_run = true;
}
ret = ctdb_ctrl_uptime(ctdb, mem_ctx, CONTROL_TIMEOUT(),
CTDB_CURRENT_NODE, &uptime2);
if (ret != 0) {
DEBUG(DEBUG_ERR, ("Unable to get uptime from local node %u\n", pnn));
talloc_free(mem_ctx);
return -1;
}
/* skip the check if the startrecovery time has changed */
if (timeval_compare(&uptime1->last_recovery_started,
&uptime2->last_recovery_started) != 0) {
DEBUG(DEBUG_NOTICE, (__location__ " last recovery time changed while we read the public ip list. skipping public ip address check\n"));
talloc_free(mem_ctx);
return 0;
}
/* skip the check if the endrecovery time has changed */
if (timeval_compare(&uptime1->last_recovery_finished,
&uptime2->last_recovery_finished) != 0) {
DEBUG(DEBUG_NOTICE, (__location__ " last recovery time changed while we read the public ip list. skipping public ip address check\n"));
talloc_free(mem_ctx);
return 0;
}
/* skip the check if we have started but not finished recovery */
if (timeval_compare(&uptime1->last_recovery_finished,
&uptime1->last_recovery_started) != 1) {
DEBUG(DEBUG_INFO, (__location__ " in the middle of recovery or ip reallocation. skipping public ip address check\n"));
talloc_free(mem_ctx);
return 0;
}
/* verify that we have the ip addresses we should have
and we dont have ones we shouldnt have.
if we find an inconsistency we set recmode to
active on the local node and wait for the recmaster
to do a full blown recovery.
also if the pnn is -1 and we are healthy and can host the ip
we also request a ip reallocation.
*/
if (ctdb->tunable.disable_ip_failover == 0) {
struct ctdb_all_public_ips *ips = NULL;
/* read the *available* IPs from the local node */
ret = ctdb_ctrl_get_public_ips_flags(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, mem_ctx, CTDB_PUBLIC_IP_FLAGS_ONLY_AVAILABLE, &ips);
if (ret != 0) {
DEBUG(DEBUG_ERR, ("Unable to get available public IPs from local node %u\n", pnn));
talloc_free(mem_ctx);
return -1;
}
for (j=0; j<ips->num; j++) {
if (ips->ips[j].pnn == -1 &&
nodemap->nodes[pnn].flags == 0) {
DEBUG(DEBUG_CRIT,("Public IP '%s' is not assigned and we could serve it\n",
ctdb_addr_to_str(&ips->ips[j].addr)));
need_takeover_run = true;
}
}
talloc_free(ips);
/* read the *known* IPs from the local node */
ret = ctdb_ctrl_get_public_ips_flags(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, mem_ctx, 0, &ips);
if (ret != 0) {
DEBUG(DEBUG_ERR, ("Unable to get known public IPs from local node %u\n", pnn));
talloc_free(mem_ctx);
return -1;
}
for (j=0; j<ips->num; j++) {
if (ips->ips[j].pnn == pnn) {
if (ctdb->do_checkpublicip && !ctdb_sys_have_ip(&ips->ips[j].addr)) {
DEBUG(DEBUG_CRIT,("Public IP '%s' is assigned to us but not on an interface\n",
ctdb_addr_to_str(&ips->ips[j].addr)));
need_takeover_run = true;
}
} else {
if (ctdb->do_checkpublicip &&
ctdb_sys_have_ip(&ips->ips[j].addr)) {
DEBUG(DEBUG_CRIT,("We are still serving a public IP '%s' that we should not be serving. Removing it\n",
ctdb_addr_to_str(&ips->ips[j].addr)));
if (ctdb_ctrl_release_ip(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, &ips->ips[j]) != 0) {
DEBUG(DEBUG_ERR,("Failed to release local IP address\n"));
}
}
}
}
}
if (need_takeover_run) {
struct srvid_request rd;
TDB_DATA data;
DEBUG(DEBUG_CRIT,("Trigger takeoverrun\n"));
rd.pnn = ctdb->pnn;
rd.srvid = 0;
data.dptr = (uint8_t *)&rd;
data.dsize = sizeof(rd);
ret = ctdb_client_send_message(ctdb, rec->recmaster, CTDB_SRVID_TAKEOVER_RUN, data);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to send ipreallocate to recmaster :%d\n", (int)rec->recmaster));
}
}
talloc_free(mem_ctx);
return 0;
}
static void async_getnodemap_callback(struct ctdb_context *ctdb, uint32_t node_pnn, int32_t res, TDB_DATA outdata, void *callback_data)
{
struct ctdb_node_map **remote_nodemaps = callback_data;
if (node_pnn >= ctdb->num_nodes) {
DEBUG(DEBUG_ERR,(__location__ " pnn from invalid node\n"));
return;
}
remote_nodemaps[node_pnn] = (struct ctdb_node_map *)talloc_steal(remote_nodemaps, outdata.dptr);
}
static int get_remote_nodemaps(struct ctdb_context *ctdb, TALLOC_CTX *mem_ctx,
struct ctdb_node_map *nodemap,
struct ctdb_node_map **remote_nodemaps)
{
uint32_t *nodes;
nodes = list_of_active_nodes(ctdb, nodemap, mem_ctx, true);
if (ctdb_client_async_control(ctdb, CTDB_CONTROL_GET_NODEMAP,
nodes, 0,
CONTROL_TIMEOUT(), false, tdb_null,
async_getnodemap_callback,
NULL,
remote_nodemaps) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to pull all remote nodemaps\n"));
return -1;
}
return 0;
}
enum reclock_child_status { RECLOCK_CHECKING, RECLOCK_OK, RECLOCK_FAILED, RECLOCK_TIMEOUT};
struct ctdb_check_reclock_state {
struct ctdb_context *ctdb;
struct timeval start_time;
int fd[2];
pid_t child;
struct timed_event *te;
struct fd_event *fde;
enum reclock_child_status status;
};
/* when we free the reclock state we must kill any child process.
*/
static int check_reclock_destructor(struct ctdb_check_reclock_state *state)
{
struct ctdb_context *ctdb = state->ctdb;
ctdb_ctrl_report_recd_lock_latency(ctdb, CONTROL_TIMEOUT(), timeval_elapsed(&state->start_time));
if (state->fd[0] != -1) {
close(state->fd[0]);
state->fd[0] = -1;
}
if (state->fd[1] != -1) {
close(state->fd[1]);
state->fd[1] = -1;
}
ctdb_kill(ctdb, state->child, SIGKILL);
return 0;
}
/*
called if our check_reclock child times out. this would happen if
i/o to the reclock file blocks.
*/
static void ctdb_check_reclock_timeout(struct event_context *ev, struct timed_event *te,
struct timeval t, void *private_data)
{
struct ctdb_check_reclock_state *state = talloc_get_type(private_data,
struct ctdb_check_reclock_state);
DEBUG(DEBUG_ERR,(__location__ " check_reclock child process hung/timedout CFS slow to grant locks?\n"));
state->status = RECLOCK_TIMEOUT;
}
/* this is called when the child process has completed checking the reclock
file and has written data back to us through the pipe.
*/
static void reclock_child_handler(struct event_context *ev, struct fd_event *fde,
uint16_t flags, void *private_data)
{
struct ctdb_check_reclock_state *state= talloc_get_type(private_data,
struct ctdb_check_reclock_state);
char c = 0;
int ret;
/* we got a response from our child process so we can abort the
timeout.
*/
talloc_free(state->te);
state->te = NULL;
ret = read(state->fd[0], &c, 1);
if (ret != 1 || c != RECLOCK_OK) {
DEBUG(DEBUG_ERR,(__location__ " reclock child process returned error %d\n", c));
state->status = RECLOCK_FAILED;
return;
}
state->status = RECLOCK_OK;
return;
}
static int check_recovery_lock(struct ctdb_context *ctdb)
{
int ret;
struct ctdb_check_reclock_state *state;
pid_t parent = getpid();
if (ctdb->recovery_lock_fd == -1) {
DEBUG(DEBUG_CRIT,("recovery master doesn't have the recovery lock\n"));
return -1;
}
state = talloc(ctdb, struct ctdb_check_reclock_state);
CTDB_NO_MEMORY(ctdb, state);
state->ctdb = ctdb;
state->start_time = timeval_current();
state->status = RECLOCK_CHECKING;
state->fd[0] = -1;
state->fd[1] = -1;
ret = pipe(state->fd);
if (ret != 0) {
talloc_free(state);
DEBUG(DEBUG_CRIT,(__location__ " Failed to open pipe for check_reclock child\n"));
return -1;
}
state->child = ctdb_fork(ctdb);
if (state->child == (pid_t)-1) {
DEBUG(DEBUG_CRIT,(__location__ " fork() failed in check_reclock child\n"));
close(state->fd[0]);
state->fd[0] = -1;
close(state->fd[1]);
state->fd[1] = -1;
talloc_free(state);
return -1;
}
if (state->child == 0) {
char cc = RECLOCK_OK;
close(state->fd[0]);
state->fd[0] = -1;
ctdb_set_process_name("ctdb_rec_reclock");
debug_extra = talloc_asprintf(NULL, "recovery-lock:");
if (pread(ctdb->recovery_lock_fd, &cc, 1, 0) == -1) {
DEBUG(DEBUG_CRIT,("failed read from recovery_lock_fd - %s\n", strerror(errno)));
cc = RECLOCK_FAILED;
}
write(state->fd[1], &cc, 1);
/* make sure we die when our parent dies */
while (ctdb_kill(ctdb, parent, 0) == 0 || errno != ESRCH) {
sleep(5);
}
_exit(0);
}
close(state->fd[1]);
state->fd[1] = -1;
set_close_on_exec(state->fd[0]);
DEBUG(DEBUG_DEBUG, (__location__ " Created PIPE FD:%d for check_recovery_lock\n", state->fd[0]));
talloc_set_destructor(state, check_reclock_destructor);
state->te = event_add_timed(ctdb->ev, state, timeval_current_ofs(15, 0),
ctdb_check_reclock_timeout, state);
if (state->te == NULL) {
DEBUG(DEBUG_CRIT,(__location__ " Failed to create a timed event for reclock child\n"));
talloc_free(state);
return -1;
}
state->fde = event_add_fd(ctdb->ev, state, state->fd[0],
EVENT_FD_READ,
reclock_child_handler,
(void *)state);
if (state->fde == NULL) {
DEBUG(DEBUG_CRIT,(__location__ " Failed to create an fd event for reclock child\n"));
talloc_free(state);
return -1;
}
tevent_fd_set_auto_close(state->fde);
while (state->status == RECLOCK_CHECKING) {
event_loop_once(ctdb->ev);
}
if (state->status == RECLOCK_FAILED) {
DEBUG(DEBUG_ERR,(__location__ " reclock child failed when checking file\n"));
close(ctdb->recovery_lock_fd);
ctdb->recovery_lock_fd = -1;
talloc_free(state);
return -1;
}
talloc_free(state);
return 0;
}
static int update_recovery_lock_file(struct ctdb_context *ctdb)
{
TALLOC_CTX *tmp_ctx = talloc_new(NULL);
const char *reclockfile;
if (ctdb_ctrl_getreclock(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, tmp_ctx, &reclockfile) != 0) {
DEBUG(DEBUG_ERR,("Failed to read reclock file from daemon\n"));
talloc_free(tmp_ctx);
return -1;
}
if (reclockfile == NULL) {
if (ctdb->recovery_lock_file != NULL) {
DEBUG(DEBUG_ERR,("Reclock file disabled\n"));
talloc_free(ctdb->recovery_lock_file);
ctdb->recovery_lock_file = NULL;
if (ctdb->recovery_lock_fd != -1) {
close(ctdb->recovery_lock_fd);
ctdb->recovery_lock_fd = -1;
}
}
ctdb->tunable.verify_recovery_lock = 0;
talloc_free(tmp_ctx);
return 0;
}
if (ctdb->recovery_lock_file == NULL) {
ctdb->recovery_lock_file = talloc_strdup(ctdb, reclockfile);
if (ctdb->recovery_lock_fd != -1) {
close(ctdb->recovery_lock_fd);
ctdb->recovery_lock_fd = -1;
}
talloc_free(tmp_ctx);
return 0;
}
if (!strcmp(reclockfile, ctdb->recovery_lock_file)) {
talloc_free(tmp_ctx);
return 0;
}
talloc_free(ctdb->recovery_lock_file);
ctdb->recovery_lock_file = talloc_strdup(ctdb, reclockfile);
ctdb->tunable.verify_recovery_lock = 0;
if (ctdb->recovery_lock_fd != -1) {
close(ctdb->recovery_lock_fd);
ctdb->recovery_lock_fd = -1;
}
talloc_free(tmp_ctx);
return 0;
}
static void main_loop(struct ctdb_context *ctdb, struct ctdb_recoverd *rec,
TALLOC_CTX *mem_ctx)
{
uint32_t pnn;
struct ctdb_node_map *nodemap=NULL;
struct ctdb_node_map *recmaster_nodemap=NULL;
struct ctdb_node_map **remote_nodemaps=NULL;
struct ctdb_vnn_map *vnnmap=NULL;
struct ctdb_vnn_map *remote_vnnmap=NULL;
int32_t debug_level;
int i, j, ret;
bool self_ban;
/* verify that the main daemon is still running */
if (ctdb_kill(ctdb, ctdb->ctdbd_pid, 0) != 0) {
DEBUG(DEBUG_CRIT,("CTDB daemon is no longer available. Shutting down recovery daemon\n"));
exit(-1);
}
/* ping the local daemon to tell it we are alive */
ctdb_ctrl_recd_ping(ctdb);
if (rec->election_timeout) {
/* an election is in progress */
return;
}
/* read the debug level from the parent and update locally */
ret = ctdb_ctrl_get_debuglevel(ctdb, CTDB_CURRENT_NODE, &debug_level);
if (ret !=0) {
DEBUG(DEBUG_ERR, (__location__ " Failed to read debuglevel from parent\n"));
return;
}
LogLevel = debug_level;
/* get relevant tunables */
ret = ctdb_ctrl_get_all_tunables(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, &ctdb->tunable);
if (ret != 0) {
DEBUG(DEBUG_ERR,("Failed to get tunables - retrying\n"));
return;
}
/* get the current recovery lock file from the server */
if (update_recovery_lock_file(ctdb) != 0) {
DEBUG(DEBUG_ERR,("Failed to update the recovery lock file\n"));
return;
}
/* Make sure that if recovery lock verification becomes disabled when
we close the file
*/
if (ctdb->tunable.verify_recovery_lock == 0) {
if (ctdb->recovery_lock_fd != -1) {
close(ctdb->recovery_lock_fd);
ctdb->recovery_lock_fd = -1;
}
}
pnn = ctdb_get_pnn(ctdb);
/* get the vnnmap */
ret = ctdb_ctrl_getvnnmap(ctdb, CONTROL_TIMEOUT(), pnn, mem_ctx, &vnnmap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get vnnmap from node %u\n", pnn));
return;
}
/* get number of nodes */
if (rec->nodemap) {
talloc_free(rec->nodemap);
rec->nodemap = NULL;
nodemap=NULL;
}
ret = ctdb_ctrl_getnodemap(ctdb, CONTROL_TIMEOUT(), pnn, rec, &rec->nodemap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get nodemap from node %u\n", pnn));
return;
}
nodemap = rec->nodemap;
/* remember our own node flags */
rec->node_flags = nodemap->nodes[pnn].flags;
ban_misbehaving_nodes(rec, &self_ban);
if (self_ban) {
DEBUG(DEBUG_NOTICE, ("This node was banned, restart main_loop\n"));
return;
}
/* if the local daemon is STOPPED or BANNED, we verify that the databases are
also frozen and that the recmode is set to active.
*/
if (rec->node_flags & (NODE_FLAGS_STOPPED | NODE_FLAGS_BANNED)) {
/* If this node has become inactive then we want to
* reduce the chances of it taking over the recovery
* master role when it becomes active again. This
* helps to stabilise the recovery master role so that
* it stays on the most stable node.
*/
rec->priority_time = timeval_current();
ret = ctdb_ctrl_getrecmode(ctdb, mem_ctx, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, &ctdb->recovery_mode);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to read recmode from local node\n"));
}
if (ctdb->recovery_mode == CTDB_RECOVERY_NORMAL) {
DEBUG(DEBUG_ERR,("Node is stopped or banned but recovery mode is not active. Activate recovery mode and lock databases\n"));
ret = ctdb_ctrl_freeze_priority(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, 1);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to freeze node in STOPPED or BANNED state\n"));
return;
}
ret = ctdb_ctrl_setrecmode(ctdb, CONTROL_TIMEOUT(), CTDB_CURRENT_NODE, CTDB_RECOVERY_ACTIVE);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to activate recovery mode in STOPPED or BANNED state\n"));
return;
}
}
/* If this node is stopped or banned then it is not the recovery
* master, so don't do anything. This prevents stopped or banned
* node from starting election and sending unnecessary controls.
*/
return;
}
/* check which node is the recovery master */
ret = ctdb_ctrl_getrecmaster(ctdb, mem_ctx, CONTROL_TIMEOUT(), pnn, &rec->recmaster);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get recmaster from node %u\n", pnn));
return;
}
/* If we are not the recmaster then do some housekeeping */
if (rec->recmaster != pnn) {
/* Ignore any IP reallocate requests - only recmaster
* processes them
*/
TALLOC_FREE(rec->reallocate_requests);
/* Clear any nodes that should be force rebalanced in
* the next takeover run. If the recovery master role
* has moved then we don't want to process these some
* time in the future.
*/
TALLOC_FREE(rec->force_rebalance_nodes);
}
/* This is a special case. When recovery daemon is started, recmaster
* is set to -1. If a node is not started in stopped state, then
* start election to decide recovery master
*/
if (rec->recmaster == (uint32_t)-1) {
DEBUG(DEBUG_NOTICE,(__location__ " Initial recovery master set - forcing election\n"));
force_election(rec, pnn, nodemap);
return;
}
/* update the capabilities for all nodes */
ret = update_capabilities(ctdb, nodemap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to update node capabilities.\n"));
return;
}
/*
* If the current recmaster does not have CTDB_CAP_RECMASTER,
* but we have, then force an election and try to become the new
* recmaster.
*/
if ((rec->ctdb->nodes[rec->recmaster]->capabilities & CTDB_CAP_RECMASTER) == 0 &&
(rec->ctdb->capabilities & CTDB_CAP_RECMASTER) &&
!(nodemap->nodes[pnn].flags & NODE_FLAGS_INACTIVE)) {
DEBUG(DEBUG_ERR, (__location__ " Current recmaster node %u does not have CAP_RECMASTER,"
" but we (node %u) have - force an election\n",
rec->recmaster, pnn));
force_election(rec, pnn, nodemap);
return;
}
/* count how many active nodes there are */
rec->num_active = 0;
rec->num_lmasters = 0;
rec->num_connected = 0;
for (i=0; i<nodemap->num; i++) {
if (!(nodemap->nodes[i].flags & NODE_FLAGS_INACTIVE)) {
rec->num_active++;
if (rec->ctdb->nodes[i]->capabilities & CTDB_CAP_LMASTER) {
rec->num_lmasters++;
}
}
if (!(nodemap->nodes[i].flags & NODE_FLAGS_DISCONNECTED)) {
rec->num_connected++;
}
}
/* verify that the recmaster node is still active */
for (j=0; j<nodemap->num; j++) {
if (nodemap->nodes[j].pnn==rec->recmaster) {
break;
}
}
if (j == nodemap->num) {
DEBUG(DEBUG_ERR, ("Recmaster node %u not in list. Force reelection\n", rec->recmaster));
force_election(rec, pnn, nodemap);
return;
}
/* if recovery master is disconnected we must elect a new recmaster */
if (nodemap->nodes[j].flags & NODE_FLAGS_DISCONNECTED) {
DEBUG(DEBUG_NOTICE, ("Recmaster node %u is disconnected. Force reelection\n", nodemap->nodes[j].pnn));
force_election(rec, pnn, nodemap);
return;
}
/* get nodemap from the recovery master to check if it is inactive */
ret = ctdb_ctrl_getnodemap(ctdb, CONTROL_TIMEOUT(), nodemap->nodes[j].pnn,
mem_ctx, &recmaster_nodemap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get nodemap from recovery master %u\n",
nodemap->nodes[j].pnn));
return;
}
if ((recmaster_nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) &&
(rec->node_flags & NODE_FLAGS_INACTIVE) == 0) {
DEBUG(DEBUG_NOTICE, ("Recmaster node %u no longer available. Force reelection\n", nodemap->nodes[j].pnn));
/*
* update our nodemap to carry the recmaster's notion of
* its own flags, so that we don't keep freezing the
* inactive recmaster node...
*/
nodemap->nodes[j].flags = recmaster_nodemap->nodes[j].flags;
force_election(rec, pnn, nodemap);
return;
}
/* verify that we have all ip addresses we should have and we dont
* have addresses we shouldnt have.
*/
if (ctdb->tunable.disable_ip_failover == 0 &&
rec->takeover_runs_disable_ctx == NULL) {
if (verify_local_ip_allocation(ctdb, rec, pnn, nodemap) != 0) {
DEBUG(DEBUG_ERR, (__location__ " Public IPs were inconsistent.\n"));
}
}
/* if we are not the recmaster then we do not need to check
if recovery is needed
*/
if (pnn != rec->recmaster) {
return;
}
/* ensure our local copies of flags are right */
ret = update_local_flags(rec, nodemap);
if (ret == MONITOR_ELECTION_NEEDED) {
DEBUG(DEBUG_NOTICE,("update_local_flags() called for a re-election.\n"));
force_election(rec, pnn, nodemap);
return;
}
if (ret != MONITOR_OK) {
DEBUG(DEBUG_ERR,("Unable to update local flags\n"));
return;
}
if (ctdb->num_nodes != nodemap->num) {
DEBUG(DEBUG_ERR, (__location__ " ctdb->num_nodes (%d) != nodemap->num (%d) reloading nodes file\n", ctdb->num_nodes, nodemap->num));
ctdb_load_nodes_file(ctdb);
return;
}
/* verify that all active nodes agree that we are the recmaster */
switch (verify_recmaster(rec, nodemap, pnn)) {
case MONITOR_RECOVERY_NEEDED:
/* can not happen */
return;
case MONITOR_ELECTION_NEEDED:
force_election(rec, pnn, nodemap);
return;
case MONITOR_OK:
break;
case MONITOR_FAILED:
return;
}
if (rec->need_recovery) {
/* a previous recovery didn't finish */
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
return;
}
/* verify that all active nodes are in normal mode
and not in recovery mode
*/
switch (verify_recmode(ctdb, nodemap)) {
case MONITOR_RECOVERY_NEEDED:
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
return;
case MONITOR_FAILED:
return;
case MONITOR_ELECTION_NEEDED:
/* can not happen */
case MONITOR_OK:
break;
}
if (ctdb->tunable.verify_recovery_lock != 0) {
/* we should have the reclock - check its not stale */
ret = check_recovery_lock(ctdb);
if (ret != 0) {
DEBUG(DEBUG_ERR,("Failed check_recovery_lock. Force a recovery\n"));
ctdb_set_culprit(rec, ctdb->pnn);
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
return;
}
}
/* if there are takeovers requested, perform it and notify the waiters */
if (rec->takeover_runs_disable_ctx == NULL &&
rec->reallocate_requests) {
process_ipreallocate_requests(ctdb, rec);
}
/* get the nodemap for all active remote nodes
*/
remote_nodemaps = talloc_array(mem_ctx, struct ctdb_node_map *, nodemap->num);
if (remote_nodemaps == NULL) {
DEBUG(DEBUG_ERR, (__location__ " failed to allocate remote nodemap array\n"));
return;
}
for(i=0; i<nodemap->num; i++) {
remote_nodemaps[i] = NULL;
}
if (get_remote_nodemaps(ctdb, mem_ctx, nodemap, remote_nodemaps) != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to read remote nodemaps\n"));
return;
}
/* verify that all other nodes have the same nodemap as we have
*/
for (j=0; j<nodemap->num; j++) {
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
if (remote_nodemaps[j] == NULL) {
DEBUG(DEBUG_ERR,(__location__ " Did not get a remote nodemap for node %d, restarting monitoring\n", j));
ctdb_set_culprit(rec, j);
return;
}
/* if the nodes disagree on how many nodes there are
then this is a good reason to try recovery
*/
if (remote_nodemaps[j]->num != nodemap->num) {
DEBUG(DEBUG_ERR, (__location__ " Remote node:%u has different node count. %u vs %u of the local node\n",
nodemap->nodes[j].pnn, remote_nodemaps[j]->num, nodemap->num));
ctdb_set_culprit(rec, nodemap->nodes[j].pnn);
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
return;
}
/* if the nodes disagree on which nodes exist and are
active, then that is also a good reason to do recovery
*/
for (i=0;i<nodemap->num;i++) {
if (remote_nodemaps[j]->nodes[i].pnn != nodemap->nodes[i].pnn) {
DEBUG(DEBUG_ERR, (__location__ " Remote node:%u has different nodemap pnn for %d (%u vs %u).\n",
nodemap->nodes[j].pnn, i,
remote_nodemaps[j]->nodes[i].pnn, nodemap->nodes[i].pnn));
ctdb_set_culprit(rec, nodemap->nodes[j].pnn);
do_recovery(rec, mem_ctx, pnn, nodemap,
vnnmap);
return;
}
}
}
/*
* Update node flags obtained from each active node. This ensure we have
* up-to-date information for all the nodes.
*/
for (j=0; j<nodemap->num; j++) {
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
nodemap->nodes[j].flags = remote_nodemaps[j]->nodes[j].flags;
}
for (j=0; j<nodemap->num; j++) {
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
/* verify the flags are consistent
*/
for (i=0; i<nodemap->num; i++) {
if (nodemap->nodes[i].flags & NODE_FLAGS_DISCONNECTED) {
continue;
}
if (nodemap->nodes[i].flags != remote_nodemaps[j]->nodes[i].flags) {
DEBUG(DEBUG_ERR, (__location__ " Remote node:%u has different flags for node %u. It has 0x%02x vs our 0x%02x\n",
nodemap->nodes[j].pnn,
nodemap->nodes[i].pnn,
remote_nodemaps[j]->nodes[i].flags,
nodemap->nodes[i].flags));
if (i == j) {
DEBUG(DEBUG_ERR,("Use flags 0x%02x from remote node %d for cluster update of its own flags\n", remote_nodemaps[j]->nodes[i].flags, j));
update_flags_on_all_nodes(ctdb, nodemap, nodemap->nodes[i].pnn, remote_nodemaps[j]->nodes[i].flags);
ctdb_set_culprit(rec, nodemap->nodes[j].pnn);
do_recovery(rec, mem_ctx, pnn, nodemap,
vnnmap);
return;
} else {
DEBUG(DEBUG_ERR,("Use flags 0x%02x from local recmaster node for cluster update of node %d flags\n", nodemap->nodes[i].flags, i));
update_flags_on_all_nodes(ctdb, nodemap, nodemap->nodes[i].pnn, nodemap->nodes[i].flags);
ctdb_set_culprit(rec, nodemap->nodes[j].pnn);
do_recovery(rec, mem_ctx, pnn, nodemap,
vnnmap);
return;
}
}
}
}
/* There must be the same number of lmasters in the vnn map as
* there are active nodes with the lmaster capability... or
* do a recovery.
*/
if (vnnmap->size != rec->num_lmasters) {
DEBUG(DEBUG_ERR, (__location__ " The vnnmap count is different from the number of active lmaster nodes: %u vs %u\n",
vnnmap->size, rec->num_lmasters));
ctdb_set_culprit(rec, ctdb->pnn);
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
return;
}
/* verify that all active nodes in the nodemap also exist in
the vnnmap.
*/
for (j=0; j<nodemap->num; j++) {
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
if (nodemap->nodes[j].pnn == pnn) {
continue;
}
for (i=0; i<vnnmap->size; i++) {
if (vnnmap->map[i] == nodemap->nodes[j].pnn) {
break;
}
}
if (i == vnnmap->size) {
DEBUG(DEBUG_ERR, (__location__ " Node %u is active in the nodemap but did not exist in the vnnmap\n",
nodemap->nodes[j].pnn));
ctdb_set_culprit(rec, nodemap->nodes[j].pnn);
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
return;
}
}
/* verify that all other nodes have the same vnnmap
and are from the same generation
*/
for (j=0; j<nodemap->num; j++) {
if (nodemap->nodes[j].flags & NODE_FLAGS_INACTIVE) {
continue;
}
if (nodemap->nodes[j].pnn == pnn) {
continue;
}
ret = ctdb_ctrl_getvnnmap(ctdb, CONTROL_TIMEOUT(), nodemap->nodes[j].pnn,
mem_ctx, &remote_vnnmap);
if (ret != 0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to get vnnmap from remote node %u\n",
nodemap->nodes[j].pnn));
return;
}
/* verify the vnnmap generation is the same */
if (vnnmap->generation != remote_vnnmap->generation) {
DEBUG(DEBUG_ERR, (__location__ " Remote node %u has different generation of vnnmap. %u vs %u (ours)\n",
nodemap->nodes[j].pnn, remote_vnnmap->generation, vnnmap->generation));
ctdb_set_culprit(rec, nodemap->nodes[j].pnn);
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
return;
}
/* verify the vnnmap size is the same */
if (vnnmap->size != remote_vnnmap->size) {
DEBUG(DEBUG_ERR, (__location__ " Remote node %u has different size of vnnmap. %u vs %u (ours)\n",
nodemap->nodes[j].pnn, remote_vnnmap->size, vnnmap->size));
ctdb_set_culprit(rec, nodemap->nodes[j].pnn);
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
return;
}
/* verify the vnnmap is the same */
for (i=0;i<vnnmap->size;i++) {
if (remote_vnnmap->map[i] != vnnmap->map[i]) {
DEBUG(DEBUG_ERR, (__location__ " Remote node %u has different vnnmap.\n",
nodemap->nodes[j].pnn));
ctdb_set_culprit(rec, nodemap->nodes[j].pnn);
do_recovery(rec, mem_ctx, pnn, nodemap,
vnnmap);
return;
}
}
}
/* we might need to change who has what IP assigned */
if (rec->need_takeover_run) {
uint32_t culprit = (uint32_t)-1;
rec->need_takeover_run = false;
/* update the list of public ips that a node can handle for
all connected nodes
*/
ret = ctdb_reload_remote_public_ips(ctdb, rec, nodemap, &culprit);
if (ret != 0) {
DEBUG(DEBUG_ERR,("Failed to read public ips from remote node %d\n",
culprit));
rec->need_takeover_run = true;
return;
}
/* execute the "startrecovery" event script on all nodes */
ret = run_startrecovery_eventscript(rec, nodemap);
if (ret!=0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to run the 'startrecovery' event on cluster\n"));
ctdb_set_culprit(rec, ctdb->pnn);
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
return;
}
/* If takeover run fails, then the offending nodes are
* assigned ban culprit counts. And we re-try takeover.
* If takeover run fails repeatedly, the node would get
* banned.
*
* If rec->need_takeover_run is not set to true at this
* failure, monitoring is disabled cluster-wide (via
* startrecovery eventscript) and will not get enabled.
*/
if (!do_takeover_run(rec, nodemap, true)) {
return;
}
/* execute the "recovered" event script on all nodes */
ret = run_recovered_eventscript(rec, nodemap, "monitor_cluster");
#if 0
// we cant check whether the event completed successfully
// since this script WILL fail if the node is in recovery mode
// and if that race happens, the code here would just cause a second
// cascading recovery.
if (ret!=0) {
DEBUG(DEBUG_ERR, (__location__ " Unable to run the 'recovered' event on cluster. Update of public ips failed.\n"));
ctdb_set_culprit(rec, ctdb->pnn);
do_recovery(rec, mem_ctx, pnn, nodemap, vnnmap);
}
#endif
}
}
/*
the main monitoring loop
*/
static void monitor_cluster(struct ctdb_context *ctdb)
{
struct ctdb_recoverd *rec;
DEBUG(DEBUG_NOTICE,("monitor_cluster starting\n"));
rec = talloc_zero(ctdb, struct ctdb_recoverd);
CTDB_NO_MEMORY_FATAL(ctdb, rec);
rec->ctdb = ctdb;
rec->takeover_run_in_progress = false;
rec->priority_time = timeval_current();
/* register a message port for sending memory dumps */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_MEM_DUMP, mem_dump_handler, rec);
/* register a message port for requesting logs */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_GETLOG, getlog_handler, rec);
/* register a message port for clearing logs */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_CLEARLOG, clearlog_handler, rec);
/* register a message port for recovery elections */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_RECOVERY, election_handler, rec);
/* when nodes are disabled/enabled */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_SET_NODE_FLAGS, monitor_handler, rec);
/* when we are asked to puch out a flag change */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_PUSH_NODE_FLAGS, push_flags_handler, rec);
/* register a message port for vacuum fetch */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_VACUUM_FETCH, vacuum_fetch_handler, rec);
/* register a message port for reloadnodes */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_RELOAD_NODES, reload_nodes_handler, rec);
/* register a message port for performing a takeover run */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_TAKEOVER_RUN, ip_reallocate_handler, rec);
/* register a message port for disabling the ip check for a short while */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_DISABLE_IP_CHECK, disable_ip_check_handler, rec);
/* register a message port for updating the recovery daemons node assignment for an ip */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_RECD_UPDATE_IP, recd_update_ip_handler, rec);
/* register a message port for forcing a rebalance of a node next
reallocation */
ctdb_client_set_message_handler(ctdb, CTDB_SRVID_REBALANCE_NODE, recd_node_rebalance_handler, rec);
/* Register a message port for disabling takeover runs */
ctdb_client_set_message_handler(ctdb,
CTDB_SRVID_DISABLE_TAKEOVER_RUNS,
disable_takeover_runs_handler, rec);
for (;;) {
TALLOC_CTX *mem_ctx = talloc_new(ctdb);
struct timeval start;
double elapsed;
if (!mem_ctx) {
DEBUG(DEBUG_CRIT,(__location__
" Failed to create temp context\n"));
exit(-1);
}
start = timeval_current();
main_loop(ctdb, rec, mem_ctx);
talloc_free(mem_ctx);
/* we only check for recovery once every second */
elapsed = timeval_elapsed(&start);
if (elapsed < ctdb->tunable.recover_interval) {
ctdb_wait_timeout(ctdb, ctdb->tunable.recover_interval
- elapsed);
}
}
}
/*
event handler for when the main ctdbd dies
*/
static void ctdb_recoverd_parent(struct event_context *ev, struct fd_event *fde,
uint16_t flags, void *private_data)
{
DEBUG(DEBUG_ALERT,("recovery daemon parent died - exiting\n"));
_exit(1);
}
/*
called regularly to verify that the recovery daemon is still running
*/
static void ctdb_check_recd(struct event_context *ev, struct timed_event *te,
struct timeval yt, void *p)
{
struct ctdb_context *ctdb = talloc_get_type(p, struct ctdb_context);
if (ctdb_kill(ctdb, ctdb->recoverd_pid, 0) != 0) {
DEBUG(DEBUG_ERR,("Recovery daemon (pid:%d) is no longer running. Trying to restart recovery daemon.\n", (int)ctdb->recoverd_pid));
event_add_timed(ctdb->ev, ctdb, timeval_zero(),
ctdb_restart_recd, ctdb);
return;
}
event_add_timed(ctdb->ev, ctdb->recd_ctx,
timeval_current_ofs(30, 0),
ctdb_check_recd, ctdb);
}
static void recd_sig_child_handler(struct event_context *ev,
struct signal_event *se, int signum, int count,
void *dont_care,
void *private_data)
{
// struct ctdb_context *ctdb = talloc_get_type(private_data, struct ctdb_context);
int status;
pid_t pid = -1;
while (pid != 0) {
pid = waitpid(-1, &status, WNOHANG);
if (pid == -1) {
if (errno != ECHILD) {
DEBUG(DEBUG_ERR, (__location__ " waitpid() returned error. errno:%s(%d)\n", strerror(errno),errno));
}
return;
}
if (pid > 0) {
DEBUG(DEBUG_DEBUG, ("RECD SIGCHLD from %d\n", (int)pid));
}
}
}
/*
startup the recovery daemon as a child of the main ctdb daemon
*/
int ctdb_start_recoverd(struct ctdb_context *ctdb)
{
int fd[2];
struct signal_event *se;
struct tevent_fd *fde;
if (pipe(fd) != 0) {
return -1;
}
ctdb->ctdbd_pid = getpid();
ctdb->recoverd_pid = ctdb_fork_no_free_ringbuffer(ctdb);
if (ctdb->recoverd_pid == -1) {
return -1;
}
if (ctdb->recoverd_pid != 0) {
talloc_free(ctdb->recd_ctx);
ctdb->recd_ctx = talloc_new(ctdb);
CTDB_NO_MEMORY(ctdb, ctdb->recd_ctx);
close(fd[0]);
event_add_timed(ctdb->ev, ctdb->recd_ctx,
timeval_current_ofs(30, 0),
ctdb_check_recd, ctdb);
return 0;
}
close(fd[1]);
srandom(getpid() ^ time(NULL));
/* Clear the log ringbuffer */
ctdb_clear_log(ctdb);
ctdb_set_process_name("ctdb_recovered");
if (switch_from_server_to_client(ctdb, "recoverd") != 0) {
DEBUG(DEBUG_CRIT, (__location__ "ERROR: failed to switch recovery daemon into client mode. shutting down.\n"));
exit(1);
}
DEBUG(DEBUG_DEBUG, (__location__ " Created PIPE FD:%d to recovery daemon\n", fd[0]));
fde = event_add_fd(ctdb->ev, ctdb, fd[0], EVENT_FD_READ,
ctdb_recoverd_parent, &fd[0]);
tevent_fd_set_auto_close(fde);
/* set up a handler to pick up sigchld */
se = event_add_signal(ctdb->ev, ctdb,
SIGCHLD, 0,
recd_sig_child_handler,
ctdb);
if (se == NULL) {
DEBUG(DEBUG_CRIT,("Failed to set up signal handler for SIGCHLD in recovery daemon\n"));
exit(1);
}
monitor_cluster(ctdb);
DEBUG(DEBUG_ALERT,("ERROR: ctdb_recoverd finished!?\n"));
return -1;
}
/*
shutdown the recovery daemon
*/
void ctdb_stop_recoverd(struct ctdb_context *ctdb)
{
if (ctdb->recoverd_pid == 0) {
return;
}
DEBUG(DEBUG_NOTICE,("Shutting down recovery daemon\n"));
ctdb_kill(ctdb, ctdb->recoverd_pid, SIGTERM);
TALLOC_FREE(ctdb->recd_ctx);
TALLOC_FREE(ctdb->recd_ping_count);
}
static void ctdb_restart_recd(struct event_context *ev, struct timed_event *te,
struct timeval t, void *private_data)
{
struct ctdb_context *ctdb = talloc_get_type(private_data, struct ctdb_context);
DEBUG(DEBUG_ERR,("Restarting recovery daemon\n"));
ctdb_stop_recoverd(ctdb);
ctdb_start_recoverd(ctdb);
}