// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*- // vim: ts=8 sw=2 smarttab /* * Ceph - scalable distributed file system * * Copyright (C) 2004-2006 Sage Weil * * This is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License version 2.1, as published by the Free Software * Foundation. See file COPYING. * */ /* * This is the top level monitor. It runs on each machine in the Monitor * Cluster. The election of a leader for the paxos algorithm only happens * once per machine via the elector. There is a separate paxos instance (state) * kept for each of the system components: Object Store Device (OSD) Monitor, * Placement Group (PG) Monitor, Metadata Server (MDS) Monitor, and Client Monitor. */ #ifndef CEPH_MONITOR_H #define CEPH_MONITOR_H #include #include #include "include/types.h" #include "include/health.h" #include "msg/Messenger.h" #include "common/Timer.h" #include "health_check.h" #include "MonMap.h" #include "Elector.h" #include "Paxos.h" #include "Session.h" #include "PGStatService.h" #include "MonCommand.h" #include "common/LogClient.h" #include "auth/cephx/CephxKeyServer.h" #include "auth/AuthMethodList.h" #include "auth/KeyRing.h" #include "messages/MMonCommand.h" #include "mon/MonitorDBStore.h" #include "include/memory.h" #include "mgr/MgrClient.h" #include "mon/MonOpRequest.h" #include "common/WorkQueue.h" #define CEPH_MON_PROTOCOL 13 /* cluster internal */ enum { l_cluster_first = 555000, l_cluster_num_mon, l_cluster_num_mon_quorum, l_cluster_num_osd, l_cluster_num_osd_up, l_cluster_num_osd_in, l_cluster_osd_epoch, l_cluster_osd_bytes, l_cluster_osd_bytes_used, l_cluster_osd_bytes_avail, l_cluster_num_pool, l_cluster_num_pg, l_cluster_num_pg_active_clean, l_cluster_num_pg_active, l_cluster_num_pg_peering, l_cluster_num_object, l_cluster_num_object_degraded, l_cluster_num_object_misplaced, l_cluster_num_object_unfound, l_cluster_num_bytes, l_cluster_num_mds_up, l_cluster_num_mds_in, l_cluster_num_mds_failed, l_cluster_mds_epoch, l_cluster_last, }; enum { l_mon_first = 456000, l_mon_num_sessions, l_mon_session_add, l_mon_session_rm, l_mon_session_trim, l_mon_num_elections, l_mon_election_call, l_mon_election_win, l_mon_election_lose, l_mon_last, }; class QuorumService; class PaxosService; class PerfCounters; class AdminSocketHook; class MMonGetMap; class MMonGetVersion; class MMonMetadata; class MMonSync; class MMonScrub; class MMonProbe; struct MMonSubscribe; struct MRoute; struct MForward; struct MTimeCheck; struct MMonHealth; #define COMPAT_SET_LOC "feature_set" class C_MonContext final : public FunctionContext { const Monitor *mon; public: explicit C_MonContext(Monitor *m, boost::function&& callback) : FunctionContext(std::move(callback)), mon(m) {} void finish(int r) override; }; class Monitor : public Dispatcher, public md_config_obs_t { public: // me string name; int rank; Messenger *messenger; ConnectionRef con_self; Mutex lock; SafeTimer timer; Finisher finisher; ThreadPool cpu_tp; ///< threadpool for CPU intensive work /// true if we have ever joined a quorum. if false, we are either a /// new cluster, a newly joining monitor, or a just-upgraded /// monitor. bool has_ever_joined; PerfCounters *logger, *cluster_logger; bool cluster_logger_registered; void register_cluster_logger(); void unregister_cluster_logger(); MonMap *monmap; uuid_d fingerprint; set extra_probe_peers; LogClient log_client; LogChannelRef clog; LogChannelRef audit_clog; KeyRing keyring; KeyServer key_server; AuthMethodList auth_cluster_required; AuthMethodList auth_service_required; CompatSet features; vector leader_mon_commands; // quorum leader's commands vector local_mon_commands; // commands i support bufferlist local_mon_commands_bl; // encoded version of above // for upgrading mon cluster that still uses PGMonitor vector local_upgrading_mon_commands; // mixed mon cluster commands bufferlist local_upgrading_mon_commands_bl; // encoded version of above Messenger *mgr_messenger; MgrClient mgr_client; uint64_t mgr_proxy_bytes = 0; // in-flight proxied mgr command message bytes const MonPGStatService *pgservice; private: void new_tick(); // -- local storage -- public: MonitorDBStore *store; static const string MONITOR_NAME; static const string MONITOR_STORE_PREFIX; // -- monitor state -- private: enum { STATE_PROBING = 1, STATE_SYNCHRONIZING, STATE_ELECTING, STATE_LEADER, STATE_PEON, STATE_SHUTDOWN }; int state; public: static const char *get_state_name(int s) { switch (s) { case STATE_PROBING: return "probing"; case STATE_SYNCHRONIZING: return "synchronizing"; case STATE_ELECTING: return "electing"; case STATE_LEADER: return "leader"; case STATE_PEON: return "peon"; case STATE_SHUTDOWN: return "shutdown"; default: return "???"; } } const char *get_state_name() const { return get_state_name(state); } bool is_shutdown() const { return state == STATE_SHUTDOWN; } bool is_probing() const { return state == STATE_PROBING; } bool is_synchronizing() const { return state == STATE_SYNCHRONIZING; } bool is_electing() const { return state == STATE_ELECTING; } bool is_leader() const { return state == STATE_LEADER; } bool is_peon() const { return state == STATE_PEON; } const utime_t &get_leader_since() const; void prepare_new_fingerprint(MonitorDBStore::TransactionRef t); // -- elector -- private: Paxos *paxos; Elector elector; friend class Elector; /// features we require of peers (based on on-disk compatset) uint64_t required_features; int leader; // current leader (to best of knowledge) set quorum; // current active set of monitors (if !starting) utime_t leader_since; // when this monitor became the leader, if it is the leader utime_t exited_quorum; // time detected as not in quorum; 0 if in // map of counts of connected clients, by type and features, for // each quorum mon map quorum_feature_map; /** * Intersection of quorum member's connection feature bits. */ uint64_t quorum_con_features; /** * Intersection of quorum members mon-specific feature bits */ mon_feature_t quorum_mon_features; set outside_quorum; /** * @defgroup Monitor_h_scrub * @{ */ version_t scrub_version; ///< paxos version we are scrubbing map scrub_result; ///< results so far /** * trigger a cross-mon scrub * * Verify all mons are storing identical content */ int scrub_start(); int scrub(); void handle_scrub(MonOpRequestRef op); bool _scrub(ScrubResult *r, pair *start, int *num_keys); void scrub_check_results(); void scrub_timeout(); void scrub_finish(); void scrub_reset(); void scrub_update_interval(int secs); Context *scrub_event; ///< periodic event to trigger scrub (leader) Context *scrub_timeout_event; ///< scrub round timeout (leader) void scrub_event_start(); void scrub_event_cancel(); void scrub_reset_timeout(); void scrub_cancel_timeout(); struct ScrubState { pair last_key; ///< last scrubbed key bool finished; ScrubState() : finished(false) { } virtual ~ScrubState() { } }; ceph::shared_ptr scrub_state; ///< keeps track of current scrub /** * @defgroup Monitor_h_sync Synchronization * @{ */ /** * @} // provider state */ struct SyncProvider { entity_inst_t entity; ///< who uint64_t cookie; ///< unique cookie for this sync attempt utime_t timeout; ///< when we give up and expire this attempt version_t last_committed; ///< last paxos version on peer pair last_key; ///< last key sent to (or on) peer bool full; ///< full scan? MonitorDBStore::Synchronizer synchronizer; ///< iterator SyncProvider() : cookie(0), last_committed(0), full(false) {} void reset_timeout(CephContext *cct, int grace) { timeout = ceph_clock_now(); timeout += grace; } }; map sync_providers; ///< cookie -> SyncProvider for those syncing from us uint64_t sync_provider_count; ///< counter for issued cookies to keep them unique /** * @} // requester state */ entity_inst_t sync_provider; ///< who we are syncing from uint64_t sync_cookie; ///< 0 if we are starting, non-zero otherwise bool sync_full; ///< true if we are a full sync, false for recent catch-up version_t sync_start_version; ///< last_committed at sync start Context *sync_timeout_event; ///< timeout event /** * floor for sync source * * When we sync we forget about our old last_committed value which * can be dangerous. For example, if we have a cluster of: * * mon.a: lc 100 * mon.b: lc 80 * mon.c: lc 100 (us) * * If something forces us to sync (say, corruption, or manual * intervention, or bug), we forget last_committed, and might abort. * If mon.a happens to be down when we come back, we will see: * * mon.b: lc 80 * mon.c: lc 0 (us) * * and sync from mon.b, at which point a+b will both have lc 80 and * come online with a majority holding out of date commits. * * Avoid this by preserving our old last_committed value prior to * sync and never going backwards. */ version_t sync_last_committed_floor; /** * Obtain the synchronization target prefixes in set form. * * We consider a target prefix all those that are relevant when * synchronizing two stores. That is, all those that hold paxos service's * versions, as well as paxos versions, or any control keys such as the * first or last committed version. * * Given the current design, this function should return the name of all and * any available paxos service, plus the paxos name. * * @returns a set of strings referring to the prefixes being synchronized */ set get_sync_targets_names(); /** * Reset the monitor's sync-related data structures for syncing *from* a peer */ void sync_reset_requester(); /** * Reset sync state related to allowing others to sync from us */ void sync_reset_provider(); /** * Caled when a sync attempt times out (requester-side) */ void sync_timeout(); /** * Get the latest monmap for backup purposes during sync */ void sync_obtain_latest_monmap(bufferlist &bl); /** * Start sync process * * Start pulling committed state from another monitor. * * @param entity where to pull committed state from * @param full whether to do a full sync or just catch up on recent paxos */ void sync_start(entity_inst_t &entity, bool full); public: /** * force a sync on next mon restart */ void sync_force(Formatter *f, ostream& ss); private: /** * store critical state for safekeeping during sync * * We store a few things on the side that we don't want to get clobbered by sync. This * includes the latest monmap and a lower bound on last_committed. */ void sync_stash_critical_state(MonitorDBStore::TransactionRef tx); /** * reset the sync timeout * * This is used on the client to restart if things aren't progressing */ void sync_reset_timeout(); /** * trim stale sync provider state * * If someone is syncing from us and hasn't talked to us recently, expire their state. */ void sync_trim_providers(); /** * Complete a sync * * Finish up a sync after we've gotten all of the chunks. * * @param last_committed final last_committed value from provider */ void sync_finish(version_t last_committed); /** * request the next chunk from the provider */ void sync_get_next_chunk(); /** * handle sync message * * @param m Sync message with operation type MMonSync::OP_START_CHUNKS */ void handle_sync(MonOpRequestRef op); void _sync_reply_no_cookie(MonOpRequestRef op); void handle_sync_get_cookie(MonOpRequestRef op); void handle_sync_get_chunk(MonOpRequestRef op); void handle_sync_finish(MonOpRequestRef op); void handle_sync_cookie(MonOpRequestRef op); void handle_sync_forward(MonOpRequestRef op); void handle_sync_chunk(MonOpRequestRef op); void handle_sync_no_cookie(MonOpRequestRef op); /** * @} // Synchronization */ list waitfor_quorum; list maybe_wait_for_quorum; /** * @defgroup Monitor_h_TimeCheck Monitor Clock Drift Early Warning System * @{ * * We use time checks to keep track of any clock drifting going on in the * cluster. This is accomplished by periodically ping each monitor in the * quorum and register its response time on a map, assessing how much its * clock has drifted. We also take this opportunity to assess the latency * on response. * * This mechanism works as follows: * * - Leader sends out a 'PING' message to each other monitor in the quorum. * The message is timestamped with the leader's current time. The leader's * current time is recorded in a map, associated with each peon's * instance. * - The peon replies to the leader with a timestamped 'PONG' message. * - The leader calculates a delta between the peon's timestamp and its * current time and stashes it. * - The leader also calculates the time it took to receive the 'PONG' * since the 'PING' was sent, and stashes an approximate latency estimate. * - Once all the quorum members have pong'ed, the leader will share the * clock skew and latency maps with all the monitors in the quorum. */ map timecheck_waiting; map timecheck_skews; map timecheck_latencies; // odd value means we are mid-round; even value means the round has // finished. version_t timecheck_round; unsigned int timecheck_acks; utime_t timecheck_round_start; friend class HealthMonitor; /* When we hit a skew we will start a new round based off of * 'mon_timecheck_skew_interval'. Each new round will be backed off * until we hit 'mon_timecheck_interval' -- which is the typical * interval when not in the presence of a skew. * * This variable tracks the number of rounds with skews since last clean * so that we can report to the user and properly adjust the backoff. */ uint64_t timecheck_rounds_since_clean; /** * Time Check event. */ Context *timecheck_event; void timecheck_start(); void timecheck_finish(); void timecheck_start_round(); void timecheck_finish_round(bool success = true); void timecheck_cancel_round(); void timecheck_cleanup(); void timecheck_reset_event(); void timecheck_check_skews(); void timecheck_report(); void timecheck(); health_status_t timecheck_status(ostringstream &ss, const double skew_bound, const double latency); void handle_timecheck_leader(MonOpRequestRef op); void handle_timecheck_peon(MonOpRequestRef op); void handle_timecheck(MonOpRequestRef op); /** * Returns 'true' if this is considered to be a skew; 'false' otherwise. */ bool timecheck_has_skew(const double skew_bound, double *abs) const { double abs_skew = std::fabs(skew_bound); if (abs) *abs = abs_skew; return (abs_skew > g_conf->mon_clock_drift_allowed); } /** * @} */ /** * Handle ping messages from others. */ void handle_ping(MonOpRequestRef op); Context *probe_timeout_event = nullptr; // for probing void reset_probe_timeout(); void cancel_probe_timeout(); void probe_timeout(int r); void _apply_compatset_features(CompatSet &new_features); public: epoch_t get_epoch(); int get_leader() const { return leader; } string get_leader_name() { return quorum.empty() ? string() : monmap->get_name(*quorum.begin()); } const set& get_quorum() const { return quorum; } list get_quorum_names() { list q; for (set::iterator p = quorum.begin(); p != quorum.end(); ++p) q.push_back(monmap->get_name(*p)); return q; } uint64_t get_quorum_con_features() const { return quorum_con_features; } mon_feature_t get_quorum_mon_features() const { return quorum_mon_features; } uint64_t get_required_features() const { return required_features; } mon_feature_t get_required_mon_features() const { return monmap->get_required_features(); } void apply_quorum_to_compatset_features(); void apply_monmap_to_compatset_features(); void calc_quorum_requirements(); void get_combined_feature_map(FeatureMap *fm); private: void _reset(); ///< called from bootstrap, start_, or join_election void wait_for_paxos_write(); void _finish_svc_election(); ///< called by {win,lose}_election public: void bootstrap(); void join_election(); void start_election(); void win_standalone_election(); // end election (called by Elector) void win_election(epoch_t epoch, set& q, uint64_t features, const mon_feature_t& mon_features, const map& metadata); void lose_election(epoch_t epoch, set& q, int l, uint64_t features, const mon_feature_t& mon_features); // end election (called by Elector) void finish_election(); void update_logger(); /** * Vector holding the Services serviced by this Monitor. */ vector paxos_service; class PGMonitor *pgmon() { return (class PGMonitor *)paxos_service[PAXOS_PGMAP]; } class MDSMonitor *mdsmon() { return (class MDSMonitor *)paxos_service[PAXOS_MDSMAP]; } class MonmapMonitor *monmon() { return (class MonmapMonitor *)paxos_service[PAXOS_MONMAP]; } class OSDMonitor *osdmon() { return (class OSDMonitor *)paxos_service[PAXOS_OSDMAP]; } class AuthMonitor *authmon() { return (class AuthMonitor *)paxos_service[PAXOS_AUTH]; } class LogMonitor *logmon() { return (class LogMonitor*) paxos_service[PAXOS_LOG]; } class MgrMonitor *mgrmon() { return (class MgrMonitor*) paxos_service[PAXOS_MGR]; } class MgrStatMonitor *mgrstatmon() { return (class MgrStatMonitor*) paxos_service[PAXOS_MGRSTAT]; } class MgrStatMonitor *healthmon() { return (class MgrStatMonitor*) paxos_service[PAXOS_MGRSTAT]; } friend class Paxos; friend class OSDMonitor; friend class MDSMonitor; friend class MonmapMonitor; friend class PGMonitor; friend class LogMonitor; friend class ConfigKeyService; QuorumService *health_monitor; QuorumService *config_key_service; // -- sessions -- MonSessionMap session_map; Mutex session_map_lock{"Monitor::session_map_lock"}; AdminSocketHook *admin_hook; template void with_session_map(Func&& func) { Mutex::Locker l(session_map_lock); std::forward(func)(session_map); } void send_latest_monmap(Connection *con); // messages void handle_get_version(MonOpRequestRef op); void handle_subscribe(MonOpRequestRef op); void handle_mon_get_map(MonOpRequestRef op); static void _generate_command_map(map& cmdmap, map ¶m_str_map); static const MonCommand *_get_moncommand( const string &cmd_prefix, const vector& cmds); bool _allowed_command(MonSession *s, string &module, string &prefix, const map& cmdmap, const map& param_str_map, const MonCommand *this_cmd); void get_mon_status(Formatter *f, ostream& ss); void _quorum_status(Formatter *f, ostream& ss); bool _add_bootstrap_peer_hint(string cmd, cmdmap_t& cmdmap, ostream& ss); void handle_command(MonOpRequestRef op); void handle_route(MonOpRequestRef op); void handle_mon_metadata(MonOpRequestRef op); int get_mon_metadata(int mon, Formatter *f, ostream& err); int print_nodes(Formatter *f, ostream& err); // Accumulate metadata across calls to update_mon_metadata map mon_metadata; map pending_metadata; /** * */ struct health_cache_t { health_status_t overall; string summary; void reset() { // health_status_t doesn't really have a NONE value and we're not // okay with setting something else (say, HEALTH_ERR). so just // leave it be. summary.clear(); } } health_status_cache; Context *health_tick_event = nullptr; Context *health_interval_event = nullptr; void health_tick_start(); void health_tick_stop(); utime_t health_interval_calc_next_update(); void health_interval_start(); void health_interval_stop(); void health_events_cleanup(); void health_to_clog_update_conf(const std::set &changed); void do_health_to_clog_interval(); void do_health_to_clog(bool force = false); /** * Generate health report * * @param status one-line status summary * @param detailbl optional bufferlist* to fill with a detailed report * @returns health status */ health_status_t get_health(list& status, bufferlist *detailbl, Formatter *f); health_status_t get_health_status( bool want_detail, Formatter *f, std::string *plain, const char *sep1 = " ", const char *sep2 = "; "); void log_health( const health_check_map_t& updated, const health_check_map_t& previous, MonitorDBStore::TransactionRef t); protected: class HealthCheckLogStatus { public: health_status_t severity; std::string last_message; utime_t updated_at = 0; HealthCheckLogStatus(health_status_t severity_, const std::string &last_message_, utime_t updated_at_) : severity(severity_), last_message(last_message_), updated_at(updated_at_) {} }; std::map health_check_log_times; public: void get_cluster_status(stringstream &ss, Formatter *f); void reply_command(MonOpRequestRef op, int rc, const string &rs, version_t version); void reply_command(MonOpRequestRef op, int rc, const string &rs, bufferlist& rdata, version_t version); void handle_probe(MonOpRequestRef op); /** * Handle a Probe Operation, replying with our name, quorum and known versions. * * We use the MMonProbe message class for anything and everything related with * Monitor probing. One of the operations relates directly with the probing * itself, in which we receive a probe request and to which we reply with * our name, our quorum and the known versions for each Paxos service. Thus the * redundant function name. This reply will obviously be sent to the one * probing/requesting these infos. * * @todo Add @pre and @post * * @param m A Probe message, with an operation of type Probe. */ void handle_probe_probe(MonOpRequestRef op); void handle_probe_reply(MonOpRequestRef op); // request routing struct RoutedRequest { uint64_t tid; bufferlist request_bl; MonSession *session; ConnectionRef con; uint64_t con_features; entity_inst_t client_inst; MonOpRequestRef op; RoutedRequest() : tid(0), session(NULL), con_features(0) {} ~RoutedRequest() { if (session) session->put(); } }; uint64_t routed_request_tid; map routed_requests; void forward_request_leader(MonOpRequestRef op); void handle_forward(MonOpRequestRef op); void try_send_message(Message *m, const entity_inst_t& to); void send_reply(MonOpRequestRef op, Message *reply); void no_reply(MonOpRequestRef op); void resend_routed_requests(); void remove_session(MonSession *s); void remove_all_sessions(); void waitlist_or_zap_client(MonOpRequestRef op); void send_command(const entity_inst_t& inst, const vector& com); public: struct C_Command : public C_MonOp { Monitor *mon; int rc; string rs; bufferlist rdata; version_t version; C_Command(Monitor *_mm, MonOpRequestRef _op, int r, string s, version_t v) : C_MonOp(_op), mon(_mm), rc(r), rs(s), version(v){} C_Command(Monitor *_mm, MonOpRequestRef _op, int r, string s, bufferlist rd, version_t v) : C_MonOp(_op), mon(_mm), rc(r), rs(s), rdata(rd), version(v){} void _finish(int r) override { MMonCommand *m = static_cast(op->get_req()); if (r >= 0) { ostringstream ss; if (!op->get_req()->get_connection()) { ss << "connection dropped for command "; } else { MonSession *s = op->get_session(); // if client drops we may not have a session to draw information from. if (s) { ss << "from='" << s->inst << "' " << "entity='" << s->entity_name << "' "; } else { ss << "session dropped for command "; } } ss << "cmd='" << m->cmd << "': finished"; mon->audit_clog->info() << ss.str(); mon->reply_command(op, rc, rs, rdata, version); } else if (r == -ECANCELED) return; else if (r == -EAGAIN) mon->dispatch_op(op); else assert(0 == "bad C_Command return value"); } }; private: class C_RetryMessage : public C_MonOp { Monitor *mon; public: C_RetryMessage(Monitor *m, MonOpRequestRef op) : C_MonOp(op), mon(m) { } void _finish(int r) override { if (r == -EAGAIN || r >= 0) mon->dispatch_op(op); else if (r == -ECANCELED) return; else assert(0 == "bad C_RetryMessage return value"); } }; //ms_dispatch handles a lot of logic and we want to reuse it //on forwarded messages, so we create a non-locking version for this class void _ms_dispatch(Message *m); bool ms_dispatch(Message *m) override { lock.Lock(); _ms_dispatch(m); lock.Unlock(); return true; } void dispatch_op(MonOpRequestRef op); //mon_caps is used for un-connected messages from monitors MonCap * mon_caps; bool ms_get_authorizer(int dest_type, AuthAuthorizer **authorizer, bool force_new) override; bool ms_verify_authorizer(Connection *con, int peer_type, int protocol, bufferlist& authorizer_data, bufferlist& authorizer_reply, bool& isvalid, CryptoKey& session_key) override; bool ms_handle_reset(Connection *con) override; void ms_handle_remote_reset(Connection *con) override {} bool ms_handle_refused(Connection *con) override; int write_default_keyring(bufferlist& bl); void extract_save_mon_key(KeyRing& keyring); void collect_metadata(Metadata *m); void update_mon_metadata(int from, Metadata&& m); int load_metadata(); void count_metadata(const string& field, Formatter *f); void count_metadata(const string& field, map *out); // features static CompatSet get_initial_supported_features(); static CompatSet get_supported_features(); static CompatSet get_legacy_features(); /// read the ondisk features into the CompatSet pointed to by read_features static void read_features_off_disk(MonitorDBStore *store, CompatSet *read_features); void read_features(); void write_features(MonitorDBStore::TransactionRef t); OpTracker op_tracker; public: Monitor(CephContext *cct_, string nm, MonitorDBStore *s, Messenger *m, Messenger *mgr_m, MonMap *map); ~Monitor() override; static int check_features(MonitorDBStore *store); // config observer const char** get_tracked_conf_keys() const override; void handle_conf_change(const struct md_config_t *conf, const std::set &changed) override; void update_log_clients(); int sanitize_options(); int preinit(); int init(); void init_paxos(); void refresh_from_paxos(bool *need_bootstrap); void shutdown(); void tick(); void handle_signal(int sig); int mkfs(bufferlist& osdmapbl); /** * check cluster_fsid file * * @return EEXIST if file exists and doesn't match, 0 on match, or negative error code */ int check_fsid(); /** * write cluster_fsid file * * @return 0 on success, or negative error code */ int write_fsid(); int write_fsid(MonitorDBStore::TransactionRef t); void do_admin_command(std::string command, cmdmap_t& cmdmap, std::string format, ostream& ss); private: // don't allow copying Monitor(const Monitor& rhs); Monitor& operator=(const Monitor &rhs); public: static void format_command_descriptions(const std::vector &commands, Formatter *f, bufferlist *rdata, bool hide_mgr_flag=false); const std::vector &get_local_commands(mon_feature_t f) { if (f.contains_all(ceph::features::mon::FEATURE_LUMINOUS)) return local_mon_commands; else return local_upgrading_mon_commands; } const bufferlist& get_local_commands_bl(mon_feature_t f) { if (f.contains_all(ceph::features::mon::FEATURE_LUMINOUS)) return local_mon_commands_bl; else return local_upgrading_mon_commands_bl; } void set_leader_commands(const std::vector& cmds) { leader_mon_commands = cmds; } static bool is_keyring_required(); }; #define CEPH_MON_FEATURE_INCOMPAT_BASE CompatSet::Feature (1, "initial feature set (~v.18)") #define CEPH_MON_FEATURE_INCOMPAT_GV CompatSet::Feature (2, "global version sequencing (v0.52)") #define CEPH_MON_FEATURE_INCOMPAT_SINGLE_PAXOS CompatSet::Feature (3, "single paxos with k/v store (v0.\?)") #define CEPH_MON_FEATURE_INCOMPAT_OSD_ERASURE_CODES CompatSet::Feature(4, "support erasure code pools") #define CEPH_MON_FEATURE_INCOMPAT_OSDMAP_ENC CompatSet::Feature(5, "new-style osdmap encoding") #define CEPH_MON_FEATURE_INCOMPAT_ERASURE_CODE_PLUGINS_V2 CompatSet::Feature(6, "support isa/lrc erasure code") #define CEPH_MON_FEATURE_INCOMPAT_ERASURE_CODE_PLUGINS_V3 CompatSet::Feature(7, "support shec erasure code") #define CEPH_MON_FEATURE_INCOMPAT_KRAKEN CompatSet::Feature(8, "support monmap features") #define CEPH_MON_FEATURE_INCOMPAT_LUMINOUS CompatSet::Feature(9, "luminous ondisk layout") // make sure you add your feature to Monitor::get_supported_features #endif