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samba-mirror/ctdb/server/ctdb_call.c
Amitay Isaacs c6d0e8dadc ctdb-readonly: Do not abort if revoke of readonly record fails on a node
Revoking readonly record involves first marking the record on dmaster as
RO_REVOKING_READONLY.  Then all the other nodes are sent update_record
control to get rid of RO_DELEGATION.  Once that succeeds, the record
is marked RO_REVOKING_COMPLETE.

Currently, revoking of readonly delegations on the nodes is tried only
once.  If a node goes in recovery, it can fail update_record control and
revoke code will abort ctdb.  Since database recovery would revoke all
readonly delegations anyway, there is no reason to abort.  Simply undo
the start of revoke process by resetting RO_REVOKING_READONLY flag.

Signed-off-by: Amitay Isaacs <amitay@gmail.com>
Reviewed-by: Martin Schwenke <martin@meltin.net>

Autobuild-User(master): Martin Schwenke <martins@samba.org>
Autobuild-Date(master): Wed Aug 13 11:24:09 CEST 2014 on sn-devel-104
2014-08-13 11:24:09 +02:00

1743 lines
50 KiB
C

/*
ctdb_call protocol code
Copyright (C) Andrew Tridgell 2006
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/>.
*/
/*
see http://wiki.samba.org/index.php/Samba_%26_Clustering for
protocol design and packet details
*/
#include "includes.h"
#include "tdb.h"
#include "lib/util/dlinklist.h"
#include "system/network.h"
#include "system/filesys.h"
#include "../include/ctdb_private.h"
#include "../common/rb_tree.h"
struct ctdb_sticky_record {
struct ctdb_context *ctdb;
struct ctdb_db_context *ctdb_db;
TDB_CONTEXT *pindown;
};
/*
find the ctdb_db from a db index
*/
struct ctdb_db_context *find_ctdb_db(struct ctdb_context *ctdb, uint32_t id)
{
struct ctdb_db_context *ctdb_db;
for (ctdb_db=ctdb->db_list; ctdb_db; ctdb_db=ctdb_db->next) {
if (ctdb_db->db_id == id) {
break;
}
}
return ctdb_db;
}
/*
a varient of input packet that can be used in lock requeue
*/
static void ctdb_call_input_pkt(void *p, struct ctdb_req_header *hdr)
{
struct ctdb_context *ctdb = talloc_get_type(p, struct ctdb_context);
ctdb_input_pkt(ctdb, hdr);
}
/*
send an error reply
*/
static void ctdb_send_error(struct ctdb_context *ctdb,
struct ctdb_req_header *hdr, uint32_t status,
const char *fmt, ...) PRINTF_ATTRIBUTE(4,5);
static void ctdb_send_error(struct ctdb_context *ctdb,
struct ctdb_req_header *hdr, uint32_t status,
const char *fmt, ...)
{
va_list ap;
struct ctdb_reply_error *r;
char *msg;
int msglen, len;
if (ctdb->methods == NULL) {
DEBUG(DEBUG_INFO,(__location__ " Failed to send error. Transport is DOWN\n"));
return;
}
va_start(ap, fmt);
msg = talloc_vasprintf(ctdb, fmt, ap);
if (msg == NULL) {
ctdb_fatal(ctdb, "Unable to allocate error in ctdb_send_error\n");
}
va_end(ap);
msglen = strlen(msg)+1;
len = offsetof(struct ctdb_reply_error, msg);
r = ctdb_transport_allocate(ctdb, msg, CTDB_REPLY_ERROR, len + msglen,
struct ctdb_reply_error);
CTDB_NO_MEMORY_FATAL(ctdb, r);
r->hdr.destnode = hdr->srcnode;
r->hdr.reqid = hdr->reqid;
r->status = status;
r->msglen = msglen;
memcpy(&r->msg[0], msg, msglen);
ctdb_queue_packet(ctdb, &r->hdr);
talloc_free(msg);
}
/**
* send a redirect reply
*
* The logic behind this function is this:
*
* A client wants to grab a record and sends a CTDB_REQ_CALL packet
* to its local ctdb (ctdb_request_call). If the node is not itself
* the record's DMASTER, it first redirects the packet to the
* record's LMASTER. The LMASTER then redirects the call packet to
* the current DMASTER. Note that this works because of this: When
* a record is migrated off a node, then the new DMASTER is stored
* in the record's copy on the former DMASTER.
*/
static void ctdb_call_send_redirect(struct ctdb_context *ctdb,
struct ctdb_db_context *ctdb_db,
TDB_DATA key,
struct ctdb_req_call *c,
struct ctdb_ltdb_header *header)
{
uint32_t lmaster = ctdb_lmaster(ctdb, &key);
c->hdr.destnode = lmaster;
if (ctdb->pnn == lmaster) {
c->hdr.destnode = header->dmaster;
}
c->hopcount++;
if (c->hopcount%100 > 95) {
DEBUG(DEBUG_WARNING,("High hopcount %d dbid:%s "
"key:0x%08x reqid=%08x pnn:%d src:%d lmaster:%d "
"header->dmaster:%d dst:%d\n",
c->hopcount, ctdb_db->db_name, ctdb_hash(&key),
c->hdr.reqid, ctdb->pnn, c->hdr.srcnode, lmaster,
header->dmaster, c->hdr.destnode));
}
ctdb_queue_packet(ctdb, &c->hdr);
}
/*
send a dmaster reply
caller must have the chainlock before calling this routine. Caller must be
the lmaster
*/
static void ctdb_send_dmaster_reply(struct ctdb_db_context *ctdb_db,
struct ctdb_ltdb_header *header,
TDB_DATA key, TDB_DATA data,
uint32_t new_dmaster,
uint32_t reqid)
{
struct ctdb_context *ctdb = ctdb_db->ctdb;
struct ctdb_reply_dmaster *r;
int ret, len;
TALLOC_CTX *tmp_ctx;
if (ctdb->pnn != ctdb_lmaster(ctdb, &key)) {
DEBUG(DEBUG_ALERT,(__location__ " Caller is not lmaster!\n"));
return;
}
header->dmaster = new_dmaster;
ret = ctdb_ltdb_store(ctdb_db, key, header, data);
if (ret != 0) {
ctdb_fatal(ctdb, "ctdb_send_dmaster_reply unable to update dmaster");
return;
}
if (ctdb->methods == NULL) {
ctdb_fatal(ctdb, "ctdb_send_dmaster_reply cant update dmaster since transport is down");
return;
}
/* put the packet on a temporary context, allowing us to safely free
it below even if ctdb_reply_dmaster() has freed it already */
tmp_ctx = talloc_new(ctdb);
/* send the CTDB_REPLY_DMASTER */
len = offsetof(struct ctdb_reply_dmaster, data) + key.dsize + data.dsize + sizeof(uint32_t);
r = ctdb_transport_allocate(ctdb, tmp_ctx, CTDB_REPLY_DMASTER, len,
struct ctdb_reply_dmaster);
CTDB_NO_MEMORY_FATAL(ctdb, r);
r->hdr.destnode = new_dmaster;
r->hdr.reqid = reqid;
r->rsn = header->rsn;
r->keylen = key.dsize;
r->datalen = data.dsize;
r->db_id = ctdb_db->db_id;
memcpy(&r->data[0], key.dptr, key.dsize);
memcpy(&r->data[key.dsize], data.dptr, data.dsize);
memcpy(&r->data[key.dsize+data.dsize], &header->flags, sizeof(uint32_t));
ctdb_queue_packet(ctdb, &r->hdr);
talloc_free(tmp_ctx);
}
/*
send a dmaster request (give another node the dmaster for a record)
This is always sent to the lmaster, which ensures that the lmaster
always knows who the dmaster is. The lmaster will then send a
CTDB_REPLY_DMASTER to the new dmaster
*/
static void ctdb_call_send_dmaster(struct ctdb_db_context *ctdb_db,
struct ctdb_req_call *c,
struct ctdb_ltdb_header *header,
TDB_DATA *key, TDB_DATA *data)
{
struct ctdb_req_dmaster *r;
struct ctdb_context *ctdb = ctdb_db->ctdb;
int len;
uint32_t lmaster = ctdb_lmaster(ctdb, key);
if (ctdb->methods == NULL) {
ctdb_fatal(ctdb, "Failed ctdb_call_send_dmaster since transport is down");
return;
}
if (data->dsize != 0) {
header->flags |= CTDB_REC_FLAG_MIGRATED_WITH_DATA;
}
if (lmaster == ctdb->pnn) {
ctdb_send_dmaster_reply(ctdb_db, header, *key, *data,
c->hdr.srcnode, c->hdr.reqid);
return;
}
len = offsetof(struct ctdb_req_dmaster, data) + key->dsize + data->dsize
+ sizeof(uint32_t);
r = ctdb_transport_allocate(ctdb, ctdb, CTDB_REQ_DMASTER, len,
struct ctdb_req_dmaster);
CTDB_NO_MEMORY_FATAL(ctdb, r);
r->hdr.destnode = lmaster;
r->hdr.reqid = c->hdr.reqid;
r->db_id = c->db_id;
r->rsn = header->rsn;
r->dmaster = c->hdr.srcnode;
r->keylen = key->dsize;
r->datalen = data->dsize;
memcpy(&r->data[0], key->dptr, key->dsize);
memcpy(&r->data[key->dsize], data->dptr, data->dsize);
memcpy(&r->data[key->dsize + data->dsize], &header->flags, sizeof(uint32_t));
header->dmaster = c->hdr.srcnode;
if (ctdb_ltdb_store(ctdb_db, *key, header, *data) != 0) {
ctdb_fatal(ctdb, "Failed to store record in ctdb_call_send_dmaster");
}
ctdb_queue_packet(ctdb, &r->hdr);
talloc_free(r);
}
static void ctdb_sticky_pindown_timeout(struct event_context *ev, struct timed_event *te,
struct timeval t, void *private_data)
{
struct ctdb_sticky_record *sr = talloc_get_type(private_data,
struct ctdb_sticky_record);
DEBUG(DEBUG_ERR,("Pindown timeout db:%s unstick record\n", sr->ctdb_db->db_name));
if (sr->pindown != NULL) {
talloc_free(sr->pindown);
sr->pindown = NULL;
}
}
static int
ctdb_set_sticky_pindown(struct ctdb_context *ctdb, struct ctdb_db_context *ctdb_db, TDB_DATA key)
{
TALLOC_CTX *tmp_ctx = talloc_new(NULL);
uint32_t *k;
struct ctdb_sticky_record *sr;
k = talloc_zero_size(tmp_ctx, ((key.dsize + 3) & 0xfffffffc) + 4);
if (k == NULL) {
DEBUG(DEBUG_ERR,("Failed to allocate key for sticky record\n"));
talloc_free(tmp_ctx);
return -1;
}
k[0] = (key.dsize + 3) / 4 + 1;
memcpy(&k[1], key.dptr, key.dsize);
sr = trbt_lookuparray32(ctdb_db->sticky_records, k[0], &k[0]);
if (sr == NULL) {
talloc_free(tmp_ctx);
return 0;
}
talloc_free(tmp_ctx);
if (sr->pindown == NULL) {
DEBUG(DEBUG_ERR,("Pinning down record in %s for %d ms\n", ctdb_db->db_name, ctdb->tunable.sticky_pindown));
sr->pindown = talloc_new(sr);
if (sr->pindown == NULL) {
DEBUG(DEBUG_ERR,("Failed to allocate pindown context for sticky record\n"));
return -1;
}
event_add_timed(ctdb->ev, sr->pindown, timeval_current_ofs(ctdb->tunable.sticky_pindown / 1000, (ctdb->tunable.sticky_pindown * 1000) % 1000000), ctdb_sticky_pindown_timeout, sr);
}
return 0;
}
/*
called when a CTDB_REPLY_DMASTER packet comes in, or when the lmaster
gets a CTDB_REQUEST_DMASTER for itself. We become the dmaster.
must be called with the chainlock held. This function releases the chainlock
*/
static void ctdb_become_dmaster(struct ctdb_db_context *ctdb_db,
struct ctdb_req_header *hdr,
TDB_DATA key, TDB_DATA data,
uint64_t rsn, uint32_t record_flags)
{
struct ctdb_call_state *state;
struct ctdb_context *ctdb = ctdb_db->ctdb;
struct ctdb_ltdb_header header;
int ret;
DEBUG(DEBUG_DEBUG,("pnn %u dmaster response %08x\n", ctdb->pnn, ctdb_hash(&key)));
ZERO_STRUCT(header);
header.rsn = rsn;
header.dmaster = ctdb->pnn;
header.flags = record_flags;
state = ctdb_reqid_find(ctdb, hdr->reqid, struct ctdb_call_state);
if (state) {
if (state->call->flags & CTDB_CALL_FLAG_VACUUM_MIGRATION) {
/*
* We temporarily add the VACUUM_MIGRATED flag to
* the record flags, so that ctdb_ltdb_store can
* decide whether the record should be stored or
* deleted.
*/
header.flags |= CTDB_REC_FLAG_VACUUM_MIGRATED;
}
}
if (ctdb_ltdb_store(ctdb_db, key, &header, data) != 0) {
ctdb_fatal(ctdb, "ctdb_reply_dmaster store failed\n");
ret = ctdb_ltdb_unlock(ctdb_db, key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
return;
}
/* we just became DMASTER and this database is "sticky",
see if the record is flagged as "hot" and set up a pin-down
context to stop migrations for a little while if so
*/
if (ctdb_db->sticky) {
ctdb_set_sticky_pindown(ctdb, ctdb_db, key);
}
if (state == NULL) {
DEBUG(DEBUG_ERR,("pnn %u Invalid reqid %u in ctdb_become_dmaster from node %u\n",
ctdb->pnn, hdr->reqid, hdr->srcnode));
ret = ctdb_ltdb_unlock(ctdb_db, key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
return;
}
if (key.dsize != state->call->key.dsize || memcmp(key.dptr, state->call->key.dptr, key.dsize)) {
DEBUG(DEBUG_ERR, ("Got bogus DMASTER packet reqid:%u from node %u. Key does not match key held in matching idr.\n", hdr->reqid, hdr->srcnode));
ret = ctdb_ltdb_unlock(ctdb_db, key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
return;
}
if (hdr->reqid != state->reqid) {
/* we found a record but it was the wrong one */
DEBUG(DEBUG_ERR, ("Dropped orphan in ctdb_become_dmaster with reqid:%u\n from node %u", hdr->reqid, hdr->srcnode));
ret = ctdb_ltdb_unlock(ctdb_db, key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
return;
}
ctdb_call_local(ctdb_db, state->call, &header, state, &data, true);
ret = ctdb_ltdb_unlock(ctdb_db, state->call->key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
state->state = CTDB_CALL_DONE;
if (state->async.fn) {
state->async.fn(state);
}
}
/*
called when a CTDB_REQ_DMASTER packet comes in
this comes into the lmaster for a record when the current dmaster
wants to give up the dmaster role and give it to someone else
*/
void ctdb_request_dmaster(struct ctdb_context *ctdb, struct ctdb_req_header *hdr)
{
struct ctdb_req_dmaster *c = (struct ctdb_req_dmaster *)hdr;
TDB_DATA key, data, data2;
struct ctdb_ltdb_header header;
struct ctdb_db_context *ctdb_db;
uint32_t record_flags = 0;
size_t len;
int ret;
key.dptr = c->data;
key.dsize = c->keylen;
data.dptr = c->data + c->keylen;
data.dsize = c->datalen;
len = offsetof(struct ctdb_req_dmaster, data) + key.dsize + data.dsize
+ sizeof(uint32_t);
if (len <= c->hdr.length) {
record_flags = *(uint32_t *)&c->data[c->keylen + c->datalen];
}
ctdb_db = find_ctdb_db(ctdb, c->db_id);
if (!ctdb_db) {
ctdb_send_error(ctdb, hdr, -1,
"Unknown database in request. db_id==0x%08x",
c->db_id);
return;
}
/* fetch the current record */
ret = ctdb_ltdb_lock_fetch_requeue(ctdb_db, key, &header, hdr, &data2,
ctdb_call_input_pkt, ctdb, false);
if (ret == -1) {
ctdb_fatal(ctdb, "ctdb_req_dmaster failed to fetch record");
return;
}
if (ret == -2) {
DEBUG(DEBUG_INFO,(__location__ " deferring ctdb_request_dmaster\n"));
return;
}
if (ctdb_lmaster(ctdb, &key) != ctdb->pnn) {
DEBUG(DEBUG_ALERT,("pnn %u dmaster request to non-lmaster lmaster=%u gen=%u curgen=%u\n",
ctdb->pnn, ctdb_lmaster(ctdb, &key),
hdr->generation, ctdb->vnn_map->generation));
ctdb_fatal(ctdb, "ctdb_req_dmaster to non-lmaster");
}
DEBUG(DEBUG_DEBUG,("pnn %u dmaster request on %08x for %u from %u\n",
ctdb->pnn, ctdb_hash(&key), c->dmaster, c->hdr.srcnode));
/* its a protocol error if the sending node is not the current dmaster */
if (header.dmaster != hdr->srcnode) {
DEBUG(DEBUG_ALERT,("pnn %u dmaster request for new-dmaster %u from non-master %u real-dmaster=%u key %08x dbid 0x%08x gen=%u curgen=%u c->rsn=%llu header.rsn=%llu reqid=%u keyval=0x%08x\n",
ctdb->pnn, c->dmaster, hdr->srcnode, header.dmaster, ctdb_hash(&key),
ctdb_db->db_id, hdr->generation, ctdb->vnn_map->generation,
(unsigned long long)c->rsn, (unsigned long long)header.rsn, c->hdr.reqid,
(key.dsize >= 4)?(*(uint32_t *)key.dptr):0));
if (header.rsn != 0 || header.dmaster != ctdb->pnn) {
DEBUG(DEBUG_ERR,("ctdb_req_dmaster from non-master. Force a recovery.\n"));
ctdb->recovery_mode = CTDB_RECOVERY_ACTIVE;
ctdb_ltdb_unlock(ctdb_db, key);
return;
}
}
if (header.rsn > c->rsn) {
DEBUG(DEBUG_ALERT,("pnn %u dmaster request with older RSN new-dmaster %u from %u real-dmaster=%u key %08x dbid 0x%08x gen=%u curgen=%u c->rsn=%llu header.rsn=%llu reqid=%u\n",
ctdb->pnn, c->dmaster, hdr->srcnode, header.dmaster, ctdb_hash(&key),
ctdb_db->db_id, hdr->generation, ctdb->vnn_map->generation,
(unsigned long long)c->rsn, (unsigned long long)header.rsn, c->hdr.reqid));
}
/* use the rsn from the sending node */
header.rsn = c->rsn;
/* store the record flags from the sending node */
header.flags = record_flags;
/* check if the new dmaster is the lmaster, in which case we
skip the dmaster reply */
if (c->dmaster == ctdb->pnn) {
ctdb_become_dmaster(ctdb_db, hdr, key, data, c->rsn, record_flags);
} else {
ctdb_send_dmaster_reply(ctdb_db, &header, key, data, c->dmaster, hdr->reqid);
ret = ctdb_ltdb_unlock(ctdb_db, key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
}
}
static void ctdb_sticky_record_timeout(struct event_context *ev, struct timed_event *te,
struct timeval t, void *private_data)
{
struct ctdb_sticky_record *sr = talloc_get_type(private_data,
struct ctdb_sticky_record);
talloc_free(sr);
}
static void *ctdb_make_sticky_record_callback(void *parm, void *data)
{
if (data) {
DEBUG(DEBUG_ERR,("Already have sticky record registered. Free old %p and create new %p\n", data, parm));
talloc_free(data);
}
return parm;
}
static int
ctdb_make_record_sticky(struct ctdb_context *ctdb, struct ctdb_db_context *ctdb_db, TDB_DATA key)
{
TALLOC_CTX *tmp_ctx = talloc_new(NULL);
uint32_t *k;
struct ctdb_sticky_record *sr;
k = talloc_zero_size(tmp_ctx, ((key.dsize + 3) & 0xfffffffc) + 4);
if (k == NULL) {
DEBUG(DEBUG_ERR,("Failed to allocate key for sticky record\n"));
talloc_free(tmp_ctx);
return -1;
}
k[0] = (key.dsize + 3) / 4 + 1;
memcpy(&k[1], key.dptr, key.dsize);
sr = trbt_lookuparray32(ctdb_db->sticky_records, k[0], &k[0]);
if (sr != NULL) {
talloc_free(tmp_ctx);
return 0;
}
sr = talloc(ctdb_db->sticky_records, struct ctdb_sticky_record);
if (sr == NULL) {
talloc_free(tmp_ctx);
DEBUG(DEBUG_ERR,("Failed to allocate sticky record structure\n"));
return -1;
}
sr->ctdb = ctdb;
sr->ctdb_db = ctdb_db;
sr->pindown = NULL;
DEBUG(DEBUG_ERR,("Make record sticky for %d seconds in db %s key:0x%08x.\n",
ctdb->tunable.sticky_duration,
ctdb_db->db_name, ctdb_hash(&key)));
trbt_insertarray32_callback(ctdb_db->sticky_records, k[0], &k[0], ctdb_make_sticky_record_callback, sr);
event_add_timed(ctdb->ev, sr, timeval_current_ofs(ctdb->tunable.sticky_duration, 0), ctdb_sticky_record_timeout, sr);
talloc_free(tmp_ctx);
return 0;
}
struct pinned_down_requeue_handle {
struct ctdb_context *ctdb;
struct ctdb_req_header *hdr;
};
struct pinned_down_deferred_call {
struct ctdb_context *ctdb;
struct ctdb_req_header *hdr;
};
static void pinned_down_requeue(struct event_context *ev, struct timed_event *te,
struct timeval t, void *private_data)
{
struct pinned_down_requeue_handle *handle = talloc_get_type(private_data, struct pinned_down_requeue_handle);
struct ctdb_context *ctdb = handle->ctdb;
talloc_steal(ctdb, handle->hdr);
ctdb_call_input_pkt(ctdb, handle->hdr);
talloc_free(handle);
}
static int pinned_down_destructor(struct pinned_down_deferred_call *pinned_down)
{
struct ctdb_context *ctdb = pinned_down->ctdb;
struct pinned_down_requeue_handle *handle = talloc(ctdb, struct pinned_down_requeue_handle);
handle->ctdb = pinned_down->ctdb;
handle->hdr = pinned_down->hdr;
talloc_steal(handle, handle->hdr);
event_add_timed(ctdb->ev, handle, timeval_zero(), pinned_down_requeue, handle);
return 0;
}
static int
ctdb_defer_pinned_down_request(struct ctdb_context *ctdb, struct ctdb_db_context *ctdb_db, TDB_DATA key, struct ctdb_req_header *hdr)
{
TALLOC_CTX *tmp_ctx = talloc_new(NULL);
uint32_t *k;
struct ctdb_sticky_record *sr;
struct pinned_down_deferred_call *pinned_down;
k = talloc_zero_size(tmp_ctx, ((key.dsize + 3) & 0xfffffffc) + 4);
if (k == NULL) {
DEBUG(DEBUG_ERR,("Failed to allocate key for sticky record\n"));
talloc_free(tmp_ctx);
return -1;
}
k[0] = (key.dsize + 3) / 4 + 1;
memcpy(&k[1], key.dptr, key.dsize);
sr = trbt_lookuparray32(ctdb_db->sticky_records, k[0], &k[0]);
if (sr == NULL) {
talloc_free(tmp_ctx);
return -1;
}
talloc_free(tmp_ctx);
if (sr->pindown == NULL) {
return -1;
}
pinned_down = talloc(sr->pindown, struct pinned_down_deferred_call);
if (pinned_down == NULL) {
DEBUG(DEBUG_ERR,("Failed to allocate structure for deferred pinned down request\n"));
return -1;
}
pinned_down->ctdb = ctdb;
pinned_down->hdr = hdr;
talloc_set_destructor(pinned_down, pinned_down_destructor);
talloc_steal(pinned_down, hdr);
return 0;
}
static void
ctdb_update_db_stat_hot_keys(struct ctdb_db_context *ctdb_db, TDB_DATA key, int hopcount)
{
int i, id;
/* smallest value is always at index 0 */
if (hopcount <= ctdb_db->statistics.hot_keys[0].count) {
return;
}
/* see if we already know this key */
for (i = 0; i < MAX_HOT_KEYS; i++) {
if (key.dsize != ctdb_db->statistics.hot_keys[i].key.dsize) {
continue;
}
if (memcmp(key.dptr, ctdb_db->statistics.hot_keys[i].key.dptr, key.dsize)) {
continue;
}
/* found an entry for this key */
if (hopcount <= ctdb_db->statistics.hot_keys[i].count) {
return;
}
ctdb_db->statistics.hot_keys[i].count = hopcount;
goto sort_keys;
}
if (ctdb_db->statistics.num_hot_keys < MAX_HOT_KEYS) {
id = ctdb_db->statistics.num_hot_keys;
ctdb_db->statistics.num_hot_keys++;
} else {
id = 0;
}
if (ctdb_db->statistics.hot_keys[id].key.dptr != NULL) {
talloc_free(ctdb_db->statistics.hot_keys[id].key.dptr);
}
ctdb_db->statistics.hot_keys[id].key.dsize = key.dsize;
ctdb_db->statistics.hot_keys[id].key.dptr = talloc_memdup(ctdb_db, key.dptr, key.dsize);
ctdb_db->statistics.hot_keys[id].count = hopcount;
DEBUG(DEBUG_NOTICE,("Updated hot key database=%s key=0x%08x id=%d hop_count=%d\n",
ctdb_db->db_name, ctdb_hash(&key), id, hopcount));
sort_keys:
for (i = 1; i < MAX_HOT_KEYS; i++) {
if (ctdb_db->statistics.hot_keys[i].count == 0) {
continue;
}
if (ctdb_db->statistics.hot_keys[i].count < ctdb_db->statistics.hot_keys[0].count) {
hopcount = ctdb_db->statistics.hot_keys[i].count;
ctdb_db->statistics.hot_keys[i].count = ctdb_db->statistics.hot_keys[0].count;
ctdb_db->statistics.hot_keys[0].count = hopcount;
key = ctdb_db->statistics.hot_keys[i].key;
ctdb_db->statistics.hot_keys[i].key = ctdb_db->statistics.hot_keys[0].key;
ctdb_db->statistics.hot_keys[0].key = key;
}
}
}
/*
called when a CTDB_REQ_CALL packet comes in
*/
void ctdb_request_call(struct ctdb_context *ctdb, struct ctdb_req_header *hdr)
{
struct ctdb_req_call *c = (struct ctdb_req_call *)hdr;
TDB_DATA data;
struct ctdb_reply_call *r;
int ret, len;
struct ctdb_ltdb_header header;
struct ctdb_call *call;
struct ctdb_db_context *ctdb_db;
int tmp_count, bucket;
if (ctdb->methods == NULL) {
DEBUG(DEBUG_INFO,(__location__ " Failed ctdb_request_call. Transport is DOWN\n"));
return;
}
ctdb_db = find_ctdb_db(ctdb, c->db_id);
if (!ctdb_db) {
ctdb_send_error(ctdb, hdr, -1,
"Unknown database in request. db_id==0x%08x",
c->db_id);
return;
}
call = talloc(hdr, struct ctdb_call);
CTDB_NO_MEMORY_FATAL(ctdb, call);
call->call_id = c->callid;
call->key.dptr = c->data;
call->key.dsize = c->keylen;
call->call_data.dptr = c->data + c->keylen;
call->call_data.dsize = c->calldatalen;
call->reply_data.dptr = NULL;
call->reply_data.dsize = 0;
/* If this record is pinned down we should defer the
request until the pindown times out
*/
if (ctdb_db->sticky) {
if (ctdb_defer_pinned_down_request(ctdb, ctdb_db, call->key, hdr) == 0) {
DEBUG(DEBUG_WARNING,
("Defer request for pinned down record in %s\n", ctdb_db->db_name));
talloc_free(call);
return;
}
}
/* determine if we are the dmaster for this key. This also
fetches the record data (if any), thus avoiding a 2nd fetch of the data
if the call will be answered locally */
ret = ctdb_ltdb_lock_fetch_requeue(ctdb_db, call->key, &header, hdr, &data,
ctdb_call_input_pkt, ctdb, false);
if (ret == -1) {
ctdb_send_error(ctdb, hdr, ret, "ltdb fetch failed in ctdb_request_call");
talloc_free(call);
return;
}
if (ret == -2) {
DEBUG(DEBUG_INFO,(__location__ " deferred ctdb_request_call\n"));
talloc_free(call);
return;
}
/* Dont do READONLY if we dont have a tracking database */
if ((c->flags & CTDB_WANT_READONLY) && !ctdb_db->readonly) {
c->flags &= ~CTDB_WANT_READONLY;
}
if (header.flags & CTDB_REC_RO_REVOKE_COMPLETE) {
header.flags &= ~CTDB_REC_RO_FLAGS;
CTDB_INCREMENT_STAT(ctdb, total_ro_revokes);
CTDB_INCREMENT_DB_STAT(ctdb_db, db_ro_revokes);
if (ctdb_ltdb_store(ctdb_db, call->key, &header, data) != 0) {
ctdb_fatal(ctdb, "Failed to write header with cleared REVOKE flag");
}
/* and clear out the tracking data */
if (tdb_delete(ctdb_db->rottdb, call->key) != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to clear out trackingdb record\n"));
}
}
/* if we are revoking, we must defer all other calls until the revoke
* had completed.
*/
if (header.flags & CTDB_REC_RO_REVOKING_READONLY) {
talloc_free(data.dptr);
ret = ctdb_ltdb_unlock(ctdb_db, call->key);
if (ctdb_add_revoke_deferred_call(ctdb, ctdb_db, call->key, hdr, ctdb_call_input_pkt, ctdb) != 0) {
ctdb_fatal(ctdb, "Failed to add deferred call for revoke child");
}
talloc_free(call);
return;
}
/*
* If we are not the dmaster and are not hosting any delegations,
* then we redirect the request to the node than can answer it
* (the lmaster or the dmaster).
*/
if ((header.dmaster != ctdb->pnn)
&& (!(header.flags & CTDB_REC_RO_HAVE_DELEGATIONS)) ) {
talloc_free(data.dptr);
ctdb_call_send_redirect(ctdb, ctdb_db, call->key, c, &header);
ret = ctdb_ltdb_unlock(ctdb_db, call->key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
talloc_free(call);
return;
}
if ( (!(c->flags & CTDB_WANT_READONLY))
&& (header.flags & (CTDB_REC_RO_HAVE_DELEGATIONS|CTDB_REC_RO_HAVE_READONLY)) ) {
header.flags |= CTDB_REC_RO_REVOKING_READONLY;
if (ctdb_ltdb_store(ctdb_db, call->key, &header, data) != 0) {
ctdb_fatal(ctdb, "Failed to store record with HAVE_DELEGATIONS set");
}
ret = ctdb_ltdb_unlock(ctdb_db, call->key);
if (ctdb_start_revoke_ro_record(ctdb, ctdb_db, call->key, &header, data) != 0) {
ctdb_fatal(ctdb, "Failed to start record revoke");
}
talloc_free(data.dptr);
if (ctdb_add_revoke_deferred_call(ctdb, ctdb_db, call->key, hdr, ctdb_call_input_pkt, ctdb) != 0) {
ctdb_fatal(ctdb, "Failed to add deferred call for revoke child");
}
talloc_free(call);
return;
}
/* If this is the first request for delegation. bump rsn and set
* the delegations flag
*/
if ((c->flags & CTDB_WANT_READONLY)
&& (c->callid == CTDB_FETCH_WITH_HEADER_FUNC)
&& (!(header.flags & CTDB_REC_RO_HAVE_DELEGATIONS))) {
header.rsn += 3;
header.flags |= CTDB_REC_RO_HAVE_DELEGATIONS;
if (ctdb_ltdb_store(ctdb_db, call->key, &header, data) != 0) {
ctdb_fatal(ctdb, "Failed to store record with HAVE_DELEGATIONS set");
}
}
if ((c->flags & CTDB_WANT_READONLY)
&& (call->call_id == CTDB_FETCH_WITH_HEADER_FUNC)) {
TDB_DATA tdata;
tdata = tdb_fetch(ctdb_db->rottdb, call->key);
if (ctdb_trackingdb_add_pnn(ctdb, &tdata, c->hdr.srcnode) != 0) {
ctdb_fatal(ctdb, "Failed to add node to trackingdb");
}
if (tdb_store(ctdb_db->rottdb, call->key, tdata, TDB_REPLACE) != 0) {
ctdb_fatal(ctdb, "Failed to store trackingdb data");
}
free(tdata.dptr);
ret = ctdb_ltdb_unlock(ctdb_db, call->key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
len = offsetof(struct ctdb_reply_call, data) + data.dsize + sizeof(struct ctdb_ltdb_header);
r = ctdb_transport_allocate(ctdb, ctdb, CTDB_REPLY_CALL, len,
struct ctdb_reply_call);
CTDB_NO_MEMORY_FATAL(ctdb, r);
r->hdr.destnode = c->hdr.srcnode;
r->hdr.reqid = c->hdr.reqid;
r->status = 0;
r->datalen = data.dsize + sizeof(struct ctdb_ltdb_header);
header.rsn -= 2;
header.flags |= CTDB_REC_RO_HAVE_READONLY;
header.flags &= ~CTDB_REC_RO_HAVE_DELEGATIONS;
memcpy(&r->data[0], &header, sizeof(struct ctdb_ltdb_header));
if (data.dsize) {
memcpy(&r->data[sizeof(struct ctdb_ltdb_header)], data.dptr, data.dsize);
}
ctdb_queue_packet(ctdb, &r->hdr);
CTDB_INCREMENT_STAT(ctdb, total_ro_delegations);
CTDB_INCREMENT_DB_STAT(ctdb_db, db_ro_delegations);
talloc_free(r);
talloc_free(call);
return;
}
CTDB_UPDATE_STAT(ctdb, max_hop_count, c->hopcount);
tmp_count = c->hopcount;
bucket = 0;
while (tmp_count) {
tmp_count >>= 2;
bucket++;
}
if (bucket >= MAX_COUNT_BUCKETS) {
bucket = MAX_COUNT_BUCKETS - 1;
}
CTDB_INCREMENT_STAT(ctdb, hop_count_bucket[bucket]);
CTDB_INCREMENT_DB_STAT(ctdb_db, hop_count_bucket[bucket]);
ctdb_update_db_stat_hot_keys(ctdb_db, call->key, c->hopcount);
/* If this database supports sticky records, then check if the
hopcount is big. If it is it means the record is hot and we
should make it sticky.
*/
if (ctdb_db->sticky && c->hopcount >= ctdb->tunable.hopcount_make_sticky) {
ctdb_make_record_sticky(ctdb, ctdb_db, call->key);
}
/* Try if possible to migrate the record off to the caller node.
* From the clients perspective a fetch of the data is just as
* expensive as a migration.
*/
if (c->hdr.srcnode != ctdb->pnn) {
if (ctdb_db->persistent_state) {
DEBUG(DEBUG_INFO, (__location__ " refusing migration"
" of key %s while transaction is active\n",
(char *)call->key.dptr));
} else {
DEBUG(DEBUG_DEBUG,("pnn %u starting migration of %08x to %u\n",
ctdb->pnn, ctdb_hash(&(call->key)), c->hdr.srcnode));
ctdb_call_send_dmaster(ctdb_db, c, &header, &(call->key), &data);
talloc_free(data.dptr);
ret = ctdb_ltdb_unlock(ctdb_db, call->key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
}
talloc_free(call);
return;
}
ret = ctdb_call_local(ctdb_db, call, &header, hdr, &data, true);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_call_local failed\n"));
call->status = -1;
}
ret = ctdb_ltdb_unlock(ctdb_db, call->key);
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " ctdb_ltdb_unlock() failed with error %d\n", ret));
}
len = offsetof(struct ctdb_reply_call, data) + call->reply_data.dsize;
r = ctdb_transport_allocate(ctdb, ctdb, CTDB_REPLY_CALL, len,
struct ctdb_reply_call);
CTDB_NO_MEMORY_FATAL(ctdb, r);
r->hdr.destnode = hdr->srcnode;
r->hdr.reqid = hdr->reqid;
r->status = call->status;
r->datalen = call->reply_data.dsize;
if (call->reply_data.dsize) {
memcpy(&r->data[0], call->reply_data.dptr, call->reply_data.dsize);
}
ctdb_queue_packet(ctdb, &r->hdr);
talloc_free(r);
talloc_free(call);
}
/**
* called when a CTDB_REPLY_CALL packet comes in
*
* This packet comes in response to a CTDB_REQ_CALL request packet. It
* contains any reply data from the call
*/
void ctdb_reply_call(struct ctdb_context *ctdb, struct ctdb_req_header *hdr)
{
struct ctdb_reply_call *c = (struct ctdb_reply_call *)hdr;
struct ctdb_call_state *state;
state = ctdb_reqid_find(ctdb, hdr->reqid, struct ctdb_call_state);
if (state == NULL) {
DEBUG(DEBUG_ERR, (__location__ " reqid %u not found\n", hdr->reqid));
return;
}
if (hdr->reqid != state->reqid) {
/* we found a record but it was the wrong one */
DEBUG(DEBUG_ERR, ("Dropped orphaned call reply with reqid:%u\n",hdr->reqid));
return;
}
/* read only delegation processing */
/* If we got a FETCH_WITH_HEADER we should check if this is a ro
* delegation since we may need to update the record header
*/
if (state->c->callid == CTDB_FETCH_WITH_HEADER_FUNC) {
struct ctdb_db_context *ctdb_db = state->ctdb_db;
struct ctdb_ltdb_header *header = (struct ctdb_ltdb_header *)&c->data[0];
struct ctdb_ltdb_header oldheader;
TDB_DATA key, data, olddata;
int ret;
if (!(header->flags & CTDB_REC_RO_HAVE_READONLY)) {
goto finished_ro;
return;
}
key.dsize = state->c->keylen;
key.dptr = state->c->data;
ret = ctdb_ltdb_lock_requeue(ctdb_db, key, hdr,
ctdb_call_input_pkt, ctdb, false);
if (ret == -2) {
return;
}
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to get lock in ctdb_reply_call\n"));
return;
}
ret = ctdb_ltdb_fetch(ctdb_db, key, &oldheader, state, &olddata);
if (ret != 0) {
DEBUG(DEBUG_ERR, ("Failed to fetch old record in ctdb_reply_call\n"));
ctdb_ltdb_unlock(ctdb_db, key);
goto finished_ro;
}
if (header->rsn <= oldheader.rsn) {
ctdb_ltdb_unlock(ctdb_db, key);
goto finished_ro;
}
if (c->datalen < sizeof(struct ctdb_ltdb_header)) {
DEBUG(DEBUG_ERR,(__location__ " Got FETCH_WITH_HEADER reply with too little data: %d bytes\n", c->datalen));
ctdb_ltdb_unlock(ctdb_db, key);
goto finished_ro;
}
data.dsize = c->datalen - sizeof(struct ctdb_ltdb_header);
data.dptr = &c->data[sizeof(struct ctdb_ltdb_header)];
ret = ctdb_ltdb_store(ctdb_db, key, header, data);
if (ret != 0) {
DEBUG(DEBUG_ERR, ("Failed to store new record in ctdb_reply_call\n"));
ctdb_ltdb_unlock(ctdb_db, key);
goto finished_ro;
}
ctdb_ltdb_unlock(ctdb_db, key);
}
finished_ro:
state->call->reply_data.dptr = c->data;
state->call->reply_data.dsize = c->datalen;
state->call->status = c->status;
talloc_steal(state, c);
state->state = CTDB_CALL_DONE;
if (state->async.fn) {
state->async.fn(state);
}
}
/**
* called when a CTDB_REPLY_DMASTER packet comes in
*
* This packet comes in from the lmaster in response to a CTDB_REQ_CALL
* request packet. It means that the current dmaster wants to give us
* the dmaster role.
*/
void ctdb_reply_dmaster(struct ctdb_context *ctdb, struct ctdb_req_header *hdr)
{
struct ctdb_reply_dmaster *c = (struct ctdb_reply_dmaster *)hdr;
struct ctdb_db_context *ctdb_db;
TDB_DATA key, data;
uint32_t record_flags = 0;
size_t len;
int ret;
ctdb_db = find_ctdb_db(ctdb, c->db_id);
if (ctdb_db == NULL) {
DEBUG(DEBUG_ERR,("Unknown db_id 0x%x in ctdb_reply_dmaster\n", c->db_id));
return;
}
key.dptr = c->data;
key.dsize = c->keylen;
data.dptr = &c->data[key.dsize];
data.dsize = c->datalen;
len = offsetof(struct ctdb_reply_dmaster, data) + key.dsize + data.dsize
+ sizeof(uint32_t);
if (len <= c->hdr.length) {
record_flags = *(uint32_t *)&c->data[c->keylen + c->datalen];
}
ret = ctdb_ltdb_lock_requeue(ctdb_db, key, hdr,
ctdb_call_input_pkt, ctdb, false);
if (ret == -2) {
return;
}
if (ret != 0) {
DEBUG(DEBUG_ERR,(__location__ " Failed to get lock in ctdb_reply_dmaster\n"));
return;
}
ctdb_become_dmaster(ctdb_db, hdr, key, data, c->rsn, record_flags);
}
/*
called when a CTDB_REPLY_ERROR packet comes in
*/
void ctdb_reply_error(struct ctdb_context *ctdb, struct ctdb_req_header *hdr)
{
struct ctdb_reply_error *c = (struct ctdb_reply_error *)hdr;
struct ctdb_call_state *state;
state = ctdb_reqid_find(ctdb, hdr->reqid, struct ctdb_call_state);
if (state == NULL) {
DEBUG(DEBUG_ERR,("pnn %u Invalid reqid %u in ctdb_reply_error\n",
ctdb->pnn, hdr->reqid));
return;
}
if (hdr->reqid != state->reqid) {
/* we found a record but it was the wrong one */
DEBUG(DEBUG_ERR, ("Dropped orphaned error reply with reqid:%u\n",hdr->reqid));
return;
}
talloc_steal(state, c);
state->state = CTDB_CALL_ERROR;
state->errmsg = (char *)c->msg;
if (state->async.fn) {
state->async.fn(state);
}
}
/*
destroy a ctdb_call
*/
static int ctdb_call_destructor(struct ctdb_call_state *state)
{
DLIST_REMOVE(state->ctdb_db->ctdb->pending_calls, state);
ctdb_reqid_remove(state->ctdb_db->ctdb, state->reqid);
return 0;
}
/*
called when a ctdb_call needs to be resent after a reconfigure event
*/
static void ctdb_call_resend(struct ctdb_call_state *state)
{
struct ctdb_context *ctdb = state->ctdb_db->ctdb;
state->generation = ctdb->vnn_map->generation;
/* use a new reqid, in case the old reply does eventually come in */
ctdb_reqid_remove(ctdb, state->reqid);
state->reqid = ctdb_reqid_new(ctdb, state);
state->c->hdr.reqid = state->reqid;
/* update the generation count for this request, so its valid with the new vnn_map */
state->c->hdr.generation = state->generation;
/* send the packet to ourselves, it will be redirected appropriately */
state->c->hdr.destnode = ctdb->pnn;
ctdb_queue_packet(ctdb, &state->c->hdr);
DEBUG(DEBUG_NOTICE,("resent ctdb_call\n"));
}
/*
resend all pending calls on recovery
*/
void ctdb_call_resend_all(struct ctdb_context *ctdb)
{
struct ctdb_call_state *state, *next;
for (state=ctdb->pending_calls;state;state=next) {
next = state->next;
ctdb_call_resend(state);
}
}
/*
this allows the caller to setup a async.fn
*/
static void call_local_trigger(struct event_context *ev, struct timed_event *te,
struct timeval t, void *private_data)
{
struct ctdb_call_state *state = talloc_get_type(private_data, struct ctdb_call_state);
if (state->async.fn) {
state->async.fn(state);
}
}
/*
construct an event driven local ctdb_call
this is used so that locally processed ctdb_call requests are processed
in an event driven manner
*/
struct ctdb_call_state *ctdb_call_local_send(struct ctdb_db_context *ctdb_db,
struct ctdb_call *call,
struct ctdb_ltdb_header *header,
TDB_DATA *data)
{
struct ctdb_call_state *state;
struct ctdb_context *ctdb = ctdb_db->ctdb;
int ret;
state = talloc_zero(ctdb_db, struct ctdb_call_state);
CTDB_NO_MEMORY_NULL(ctdb, state);
talloc_steal(state, data->dptr);
state->state = CTDB_CALL_DONE;
state->call = talloc(state, struct ctdb_call);
CTDB_NO_MEMORY_NULL(ctdb, state->call);
*(state->call) = *call;
state->ctdb_db = ctdb_db;
ret = ctdb_call_local(ctdb_db, state->call, header, state, data, true);
if (ret != 0) {
DEBUG(DEBUG_DEBUG,("ctdb_call_local() failed, ignoring return code %d\n", ret));
}
event_add_timed(ctdb->ev, state, timeval_zero(), call_local_trigger, state);
return state;
}
/*
make a remote ctdb call - async send. Called in daemon context.
This constructs a ctdb_call request and queues it for processing.
This call never blocks.
*/
struct ctdb_call_state *ctdb_daemon_call_send_remote(struct ctdb_db_context *ctdb_db,
struct ctdb_call *call,
struct ctdb_ltdb_header *header)
{
uint32_t len;
struct ctdb_call_state *state;
struct ctdb_context *ctdb = ctdb_db->ctdb;
if (ctdb->methods == NULL) {
DEBUG(DEBUG_INFO,(__location__ " Failed send packet. Transport is down\n"));
return NULL;
}
state = talloc_zero(ctdb_db, struct ctdb_call_state);
CTDB_NO_MEMORY_NULL(ctdb, state);
state->call = talloc(state, struct ctdb_call);
CTDB_NO_MEMORY_NULL(ctdb, state->call);
state->reqid = ctdb_reqid_new(ctdb, state);
state->ctdb_db = ctdb_db;
talloc_set_destructor(state, ctdb_call_destructor);
len = offsetof(struct ctdb_req_call, data) + call->key.dsize + call->call_data.dsize;
state->c = ctdb_transport_allocate(ctdb, state, CTDB_REQ_CALL, len,
struct ctdb_req_call);
CTDB_NO_MEMORY_NULL(ctdb, state->c);
state->c->hdr.destnode = header->dmaster;
/* this limits us to 16k outstanding messages - not unreasonable */
state->c->hdr.reqid = state->reqid;
state->c->flags = call->flags;
state->c->db_id = ctdb_db->db_id;
state->c->callid = call->call_id;
state->c->hopcount = 0;
state->c->keylen = call->key.dsize;
state->c->calldatalen = call->call_data.dsize;
memcpy(&state->c->data[0], call->key.dptr, call->key.dsize);
memcpy(&state->c->data[call->key.dsize],
call->call_data.dptr, call->call_data.dsize);
*(state->call) = *call;
state->call->call_data.dptr = &state->c->data[call->key.dsize];
state->call->key.dptr = &state->c->data[0];
state->state = CTDB_CALL_WAIT;
state->generation = ctdb->vnn_map->generation;
DLIST_ADD(ctdb->pending_calls, state);
ctdb_queue_packet(ctdb, &state->c->hdr);
return state;
}
/*
make a remote ctdb call - async recv - called in daemon context
This is called when the program wants to wait for a ctdb_call to complete and get the
results. This call will block unless the call has already completed.
*/
int ctdb_daemon_call_recv(struct ctdb_call_state *state, struct ctdb_call *call)
{
while (state->state < CTDB_CALL_DONE) {
event_loop_once(state->ctdb_db->ctdb->ev);
}
if (state->state != CTDB_CALL_DONE) {
ctdb_set_error(state->ctdb_db->ctdb, "%s", state->errmsg);
talloc_free(state);
return -1;
}
if (state->call->reply_data.dsize) {
call->reply_data.dptr = talloc_memdup(call,
state->call->reply_data.dptr,
state->call->reply_data.dsize);
call->reply_data.dsize = state->call->reply_data.dsize;
} else {
call->reply_data.dptr = NULL;
call->reply_data.dsize = 0;
}
call->status = state->call->status;
talloc_free(state);
return 0;
}
/*
send a keepalive packet to the other node
*/
void ctdb_send_keepalive(struct ctdb_context *ctdb, uint32_t destnode)
{
struct ctdb_req_keepalive *r;
if (ctdb->methods == NULL) {
DEBUG(DEBUG_INFO,(__location__ " Failed to send keepalive. Transport is DOWN\n"));
return;
}
r = ctdb_transport_allocate(ctdb, ctdb, CTDB_REQ_KEEPALIVE,
sizeof(struct ctdb_req_keepalive),
struct ctdb_req_keepalive);
CTDB_NO_MEMORY_FATAL(ctdb, r);
r->hdr.destnode = destnode;
r->hdr.reqid = 0;
CTDB_INCREMENT_STAT(ctdb, keepalive_packets_sent);
ctdb_queue_packet(ctdb, &r->hdr);
talloc_free(r);
}
struct revokechild_deferred_call {
struct ctdb_context *ctdb;
struct ctdb_req_header *hdr;
deferred_requeue_fn fn;
void *ctx;
};
struct revokechild_handle {
struct revokechild_handle *next, *prev;
struct ctdb_context *ctdb;
struct ctdb_db_context *ctdb_db;
struct fd_event *fde;
int status;
int fd[2];
pid_t child;
TDB_DATA key;
};
struct revokechild_requeue_handle {
struct ctdb_context *ctdb;
struct ctdb_req_header *hdr;
deferred_requeue_fn fn;
void *ctx;
};
static void deferred_call_requeue(struct event_context *ev, struct timed_event *te,
struct timeval t, void *private_data)
{
struct revokechild_requeue_handle *requeue_handle = talloc_get_type(private_data, struct revokechild_requeue_handle);
requeue_handle->fn(requeue_handle->ctx, requeue_handle->hdr);
talloc_free(requeue_handle);
}
static int deferred_call_destructor(struct revokechild_deferred_call *deferred_call)
{
struct ctdb_context *ctdb = deferred_call->ctdb;
struct revokechild_requeue_handle *requeue_handle = talloc(ctdb, struct revokechild_requeue_handle);
struct ctdb_req_call *c = (struct ctdb_req_call *)deferred_call->hdr;
requeue_handle->ctdb = ctdb;
requeue_handle->hdr = deferred_call->hdr;
requeue_handle->fn = deferred_call->fn;
requeue_handle->ctx = deferred_call->ctx;
talloc_steal(requeue_handle, requeue_handle->hdr);
/* when revoking, any READONLY requests have 1 second grace to let read/write finish first */
event_add_timed(ctdb->ev, requeue_handle, timeval_current_ofs(c->flags & CTDB_WANT_READONLY ? 1 : 0, 0), deferred_call_requeue, requeue_handle);
return 0;
}
static int revokechild_destructor(struct revokechild_handle *rc)
{
if (rc->fde != NULL) {
talloc_free(rc->fde);
}
if (rc->fd[0] != -1) {
close(rc->fd[0]);
}
if (rc->fd[1] != -1) {
close(rc->fd[1]);
}
ctdb_kill(rc->ctdb, rc->child, SIGKILL);
DLIST_REMOVE(rc->ctdb_db->revokechild_active, rc);
return 0;
}
static void revokechild_handler(struct event_context *ev, struct fd_event *fde,
uint16_t flags, void *private_data)
{
struct revokechild_handle *rc = talloc_get_type(private_data,
struct revokechild_handle);
int ret;
char c;
ret = read(rc->fd[0], &c, 1);
if (ret != 1) {
DEBUG(DEBUG_ERR,("Failed to read status from revokechild. errno:%d\n", errno));
rc->status = -1;
talloc_free(rc);
return;
}
if (c != 0) {
DEBUG(DEBUG_ERR,("revokechild returned failure. status:%d\n", c));
rc->status = -1;
talloc_free(rc);
return;
}
talloc_free(rc);
}
struct ctdb_revoke_state {
struct ctdb_db_context *ctdb_db;
TDB_DATA key;
struct ctdb_ltdb_header *header;
TDB_DATA data;
int count;
int status;
int finished;
};
static void update_record_cb(struct ctdb_client_control_state *state)
{
struct ctdb_revoke_state *revoke_state;
int ret;
int32_t res;
if (state == NULL) {
return;
}
revoke_state = state->async.private_data;
state->async.fn = NULL;
ret = ctdb_control_recv(state->ctdb, state, state, NULL, &res, NULL);
if ((ret != 0) || (res != 0)) {
DEBUG(DEBUG_ERR,("Recv for revoke update record failed ret:%d res:%d\n", ret, res));
revoke_state->status = -1;
}
revoke_state->count--;
if (revoke_state->count <= 0) {
revoke_state->finished = 1;
}
}
static void revoke_send_cb(struct ctdb_context *ctdb, uint32_t pnn, void *private_data)
{
struct ctdb_revoke_state *revoke_state = private_data;
struct ctdb_client_control_state *state;
state = ctdb_ctrl_updaterecord_send(ctdb, revoke_state, timeval_current_ofs(ctdb->tunable.control_timeout,0), pnn, revoke_state->ctdb_db, revoke_state->key, revoke_state->header, revoke_state->data);
if (state == NULL) {
DEBUG(DEBUG_ERR,("Failure to send update record to revoke readonly delegation\n"));
revoke_state->status = -1;
return;
}
state->async.fn = update_record_cb;
state->async.private_data = revoke_state;
revoke_state->count++;
}
static void ctdb_revoke_timeout_handler(struct event_context *ev, struct timed_event *te,
struct timeval yt, void *private_data)
{
struct ctdb_revoke_state *state = private_data;
DEBUG(DEBUG_ERR,("Timed out waiting for revoke to finish\n"));
state->finished = 1;
state->status = -1;
}
static int ctdb_revoke_all_delegations(struct ctdb_context *ctdb, struct ctdb_db_context *ctdb_db, TDB_DATA tdata, TDB_DATA key, struct ctdb_ltdb_header *header, TDB_DATA data)
{
struct ctdb_revoke_state *state = talloc_zero(ctdb, struct ctdb_revoke_state);
struct ctdb_ltdb_header new_header;
TDB_DATA new_data;
state->ctdb_db = ctdb_db;
state->key = key;
state->header = header;
state->data = data;
ctdb_trackingdb_traverse(ctdb, tdata, revoke_send_cb, state);
event_add_timed(ctdb->ev, state, timeval_current_ofs(ctdb->tunable.control_timeout, 0), ctdb_revoke_timeout_handler, state);
while (state->finished == 0) {
event_loop_once(ctdb->ev);
}
if (ctdb_ltdb_lock(ctdb_db, key) != 0) {
DEBUG(DEBUG_ERR,("Failed to chainlock the database in revokechild\n"));
talloc_free(state);
return -1;
}
if (ctdb_ltdb_fetch(ctdb_db, key, &new_header, state, &new_data) != 0) {
ctdb_ltdb_unlock(ctdb_db, key);
DEBUG(DEBUG_ERR,("Failed for fetch tdb record in revokechild\n"));
talloc_free(state);
return -1;
}
header->rsn++;
if (new_header.rsn > header->rsn) {
ctdb_ltdb_unlock(ctdb_db, key);
DEBUG(DEBUG_ERR,("RSN too high in tdb record in revokechild\n"));
talloc_free(state);
return -1;
}
if ( (new_header.flags & (CTDB_REC_RO_REVOKING_READONLY|CTDB_REC_RO_HAVE_DELEGATIONS)) != (CTDB_REC_RO_REVOKING_READONLY|CTDB_REC_RO_HAVE_DELEGATIONS) ) {
ctdb_ltdb_unlock(ctdb_db, key);
DEBUG(DEBUG_ERR,("Flags are wrong in tdb record in revokechild\n"));
talloc_free(state);
return -1;
}
/*
* If revoke on all nodes succeed, revoke is complete. Otherwise,
* remove CTDB_REC_RO_REVOKING_READONLY flag and retry.
*/
if (state->status == 0) {
new_header.rsn++;
new_header.flags |= CTDB_REC_RO_REVOKE_COMPLETE;
} else {
DEBUG(DEBUG_NOTICE, ("Revoke all delegations failed, retrying.\n"));
new_header.flags &= ~CTDB_REC_RO_REVOKING_READONLY;
}
if (ctdb_ltdb_store(ctdb_db, key, &new_header, new_data) != 0) {
ctdb_ltdb_unlock(ctdb_db, key);
DEBUG(DEBUG_ERR,("Failed to write new record in revokechild\n"));
talloc_free(state);
return -1;
}
ctdb_ltdb_unlock(ctdb_db, key);
talloc_free(state);
return 0;
}
int ctdb_start_revoke_ro_record(struct ctdb_context *ctdb, struct ctdb_db_context *ctdb_db, TDB_DATA key, struct ctdb_ltdb_header *header, TDB_DATA data)
{
TDB_DATA tdata;
struct revokechild_handle *rc;
pid_t parent = getpid();
int ret;
header->flags &= ~(CTDB_REC_RO_REVOKING_READONLY|CTDB_REC_RO_HAVE_DELEGATIONS|CTDB_REC_RO_HAVE_READONLY);
header->flags |= CTDB_REC_FLAG_MIGRATED_WITH_DATA;
header->rsn -= 1;
if ((rc = talloc_zero(ctdb_db, struct revokechild_handle)) == NULL) {
DEBUG(DEBUG_ERR,("Failed to allocate revokechild_handle\n"));
return -1;
}
tdata = tdb_fetch(ctdb_db->rottdb, key);
if (tdata.dsize > 0) {
uint8_t *tmp;
tmp = tdata.dptr;
tdata.dptr = talloc_memdup(rc, tdata.dptr, tdata.dsize);
free(tmp);
}
rc->status = 0;
rc->ctdb = ctdb;
rc->ctdb_db = ctdb_db;
rc->fd[0] = -1;
rc->fd[1] = -1;
talloc_set_destructor(rc, revokechild_destructor);
rc->key.dsize = key.dsize;
rc->key.dptr = talloc_memdup(rc, key.dptr, key.dsize);
if (rc->key.dptr == NULL) {
DEBUG(DEBUG_ERR,("Failed to allocate key for revokechild_handle\n"));
talloc_free(rc);
return -1;
}
ret = pipe(rc->fd);
if (ret != 0) {
DEBUG(DEBUG_ERR,("Failed to allocate key for revokechild_handle\n"));
talloc_free(rc);
return -1;
}
rc->child = ctdb_fork(ctdb);
if (rc->child == (pid_t)-1) {
DEBUG(DEBUG_ERR,("Failed to fork child for revokechild\n"));
talloc_free(rc);
return -1;
}
if (rc->child == 0) {
char c = 0;
close(rc->fd[0]);
debug_extra = talloc_asprintf(NULL, "revokechild-%s:", ctdb_db->db_name);
ctdb_set_process_name("ctdb_revokechild");
if (switch_from_server_to_client(ctdb, "revokechild-%s", ctdb_db->db_name) != 0) {
DEBUG(DEBUG_ERR,("Failed to switch from server to client for revokechild process\n"));
c = 1;
goto child_finished;
}
c = ctdb_revoke_all_delegations(ctdb, ctdb_db, tdata, key, header, data);
child_finished:
write(rc->fd[1], &c, 1);
/* make sure we die when our parent dies */
while (ctdb_kill(ctdb, parent, 0) == 0 || errno != ESRCH) {
sleep(5);
}
_exit(0);
}
close(rc->fd[1]);
rc->fd[1] = -1;
set_close_on_exec(rc->fd[0]);
/* This is an active revokechild child process */
DLIST_ADD_END(ctdb_db->revokechild_active, rc, NULL);
rc->fde = event_add_fd(ctdb->ev, rc, rc->fd[0],
EVENT_FD_READ, revokechild_handler,
(void *)rc);
if (rc->fde == NULL) {
DEBUG(DEBUG_ERR,("Failed to set up fd event for revokechild process\n"));
talloc_free(rc);
}
tevent_fd_set_auto_close(rc->fde);
return 0;
}
int ctdb_add_revoke_deferred_call(struct ctdb_context *ctdb, struct ctdb_db_context *ctdb_db, TDB_DATA key, struct ctdb_req_header *hdr, deferred_requeue_fn fn, void *call_context)
{
struct revokechild_handle *rc;
struct revokechild_deferred_call *deferred_call;
for (rc = ctdb_db->revokechild_active; rc; rc = rc->next) {
if (rc->key.dsize == 0) {
continue;
}
if (rc->key.dsize != key.dsize) {
continue;
}
if (!memcmp(rc->key.dptr, key.dptr, key.dsize)) {
break;
}
}
if (rc == NULL) {
DEBUG(DEBUG_ERR,("Failed to add deferred call to revoke list. revoke structure not found\n"));
return -1;
}
deferred_call = talloc(rc, struct revokechild_deferred_call);
if (deferred_call == NULL) {
DEBUG(DEBUG_ERR,("Failed to allocate deferred call structure for revoking record\n"));
return -1;
}
deferred_call->ctdb = ctdb;
deferred_call->hdr = hdr;
deferred_call->fn = fn;
deferred_call->ctx = call_context;
talloc_set_destructor(deferred_call, deferred_call_destructor);
talloc_steal(deferred_call, hdr);
return 0;
}