ceph/src/osd/PrimaryLogPG.h

   1 // -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
   2 /*
   3  * Ceph - scalable distributed file system
   4  *
   5  * Copyright (C) 2004-2006 Sage Weil <sage@newdream.net>
   6  * Copyright (C) 2013 Cloudwatt <libre.licensing@cloudwatt.com>
   7  *
   8  * Author: Loic Dachary <loic@dachary.org>
   9  *
  10  * This is free software; you can redistribute it and/or
  11  * modify it under the terms of the GNU Lesser General Public
  12  * License version 2.1, as published by the Free Software
  13  * Foundation.  See file COPYING.
  14  *
  15  */
  16
  17 #ifndef CEPH_REPLICATEDPG_H
  18 #define CEPH_REPLICATEDPG_H
  19
  20 #include <boost/tuple/tuple.hpp>
  21 #include "include/ceph_assert.h"
  22 #include "DynamicPerfStats.h"
  23 #include "OSD.h"
  24 #include "PG.h"
  25 #include "Watch.h"
  26 #include "TierAgentState.h"
  27 #include "messages/MOSDOpReply.h"
  28 #include "common/Checksummer.h"
  29 #include "common/sharedptr_registry.hpp"
  30 #include "common/shared_cache.hpp"
  31 #include "ReplicatedBackend.h"
  32 #include "PGTransaction.h"
  33 #include "cls/cas/cls_cas_ops.h"
  34
  35 class CopyFromCallback;
  36 class PromoteCallback;
  37 struct RefCountCallback;
  38
  39 class PrimaryLogPG;
  40 class PGLSFilter;
  41 class HitSet;
  42 struct TierAgentState;
  43 class OSDService;
  44
  45 void intrusive_ptr_add_ref(PrimaryLogPG *pg);
  46 void intrusive_ptr_release(PrimaryLogPG *pg);
  47 uint64_t get_with_id(PrimaryLogPG *pg);
  48 void put_with_id(PrimaryLogPG *pg, uint64_t id);
  49
  50 #ifdef PG_DEBUG_REFS
  51   typedef TrackedIntPtr<PrimaryLogPG> PrimaryLogPGRef;
  52 #else
  53   typedef boost::intrusive_ptr<PrimaryLogPG> PrimaryLogPGRef;
  54 #endif
  55
  56 struct inconsistent_snapset_wrapper;
  57
  58 class PrimaryLogPG : public PG, public PGBackend::Listener {
  59   friend class OSD;
  60   friend class Watch;
  61   friend class PrimaryLogScrub;
  62
  63 public:
  64   MEMPOOL_CLASS_HELPERS();
  65
  66   /*
  67    * state associated with a copy operation
  68    */
  69   struct OpContext;
  70   class CopyCallback;
  71
  72   /**
  73    * CopyResults stores the object metadata of interest to a copy initiator.
  74    */
  75   struct CopyResults {
  76     ceph::real_time mtime; ///< the copy source's mtime
  77     uint64_t object_size; ///< the copied object's size
  78     bool started_temp_obj; ///< true if the callback needs to delete temp object
  79     hobject_t temp_oid;    ///< temp object (if any)
  80
  81     /**
  82      * Function to fill in transaction; if non-empty the callback
  83      * must execute it before any other accesses to the object
  84      * (in order to complete the copy).
  85      */
  86     std::function<void(PGTransaction *)> fill_in_final_tx;
  87
  88     version_t user_version; ///< The copy source's user version
  89     bool should_requeue;  ///< op should be requeued on cancel
  90     std::vector<snapid_t> snaps;  ///< src's snaps (if clone)
  91     snapid_t snap_seq;       ///< src's snap_seq (if head)
  92     librados::snap_set_t snapset; ///< src snapset (if head)
  93     bool mirror_snapset;
  94     bool has_omap;
  95     uint32_t flags;    // object_copy_data_t::FLAG_*
  96     uint32_t source_data_digest, source_omap_digest;
  97     uint32_t data_digest, omap_digest;
  98     mempool::osd_pglog::vector<std::pair<osd_reqid_t, version_t> > reqids; // [(reqid, user_version)]
  99     mempool::osd_pglog::map<uint32_t, int> reqid_return_codes; // std::map reqids by index to error code
 100     std::map<std::string, ceph::buffer::list, std::less<>> attrs; // xattrs
 101     uint64_t truncate_seq;
 102     uint64_t truncate_size;
 103     bool is_data_digest() {
 104       return flags & object_copy_data_t::FLAG_DATA_DIGEST;
 105     }
 106     bool is_omap_digest() {
 107       return flags & object_copy_data_t::FLAG_OMAP_DIGEST;
 108     }
 109     CopyResults()
 110       : object_size(0), started_temp_obj(false),
 111         user_version(0),
 112         should_requeue(false), mirror_snapset(false),
 113         has_omap(false),
 114         flags(0),
 115         source_data_digest(-1), source_omap_digest(-1),
 116         data_digest(-1), omap_digest(-1),
 117         truncate_seq(0), truncate_size(0)
 118     {}
 119   };
 120
 121   struct CopyOp;
 122   typedef std::shared_ptr<CopyOp> CopyOpRef;
 123
 124   struct CopyOp {
 125     CopyCallback *cb;
 126     ObjectContextRef obc;
 127     hobject_t src;
 128     object_locator_t oloc;
 129     unsigned flags;
 130     bool mirror_snapset;
 131
 132     CopyResults results;
 133
 134     ceph_tid_t objecter_tid;
 135     ceph_tid_t objecter_tid2;
 136
 137     object_copy_cursor_t cursor;
 138     std::map<std::string,ceph::buffer::list,std::less<>> attrs;
 139     ceph::buffer::list data;
 140     ceph::buffer::list omap_header;
 141     ceph::buffer::list omap_data;
 142     int rval;
 143
 144     object_copy_cursor_t temp_cursor;
 145
 146     /*
 147      * For CopyOp the process is:
 148      * step1: read the data(attr/omap/data) from the source object
 149      * step2: handle those data(w/ those data create a new object)
 150      * src_obj_fadvise_flags used in step1;
 151      * dest_obj_fadvise_flags used in step2
 152      */
 153     unsigned src_obj_fadvise_flags;
 154     unsigned dest_obj_fadvise_flags;
 155
 156     std::map<uint64_t, CopyOpRef> chunk_cops;
 157     int num_chunk;
 158     bool failed;
 159     uint64_t start_offset = 0;
 160     uint64_t last_offset = 0;
 161     std::vector<OSDOp> chunk_ops;
 162
 163     CopyOp(CopyCallback *cb_, ObjectContextRef _obc, hobject_t s,
 164            object_locator_t l,
 165            version_t v,
 166            unsigned f,
 167            bool ms,
 168            unsigned src_obj_fadvise_flags,
 169            unsigned dest_obj_fadvise_flags)
 170       : cb(cb_), obc(_obc), src(s), oloc(l), flags(f),
 171         mirror_snapset(ms),
 172         objecter_tid(0),
 173         objecter_tid2(0),
 174         rval(-1),
 175         src_obj_fadvise_flags(src_obj_fadvise_flags),
 176         dest_obj_fadvise_flags(dest_obj_fadvise_flags),
 177         num_chunk(0),
 178         failed(false)
 179     {
 180       results.user_version = v;
 181       results.mirror_snapset = mirror_snapset;
 182     }
 183   };
 184
 185   /**
 186    * The CopyCallback class defines an interface for completions to the
 187    * copy_start code. Users of the copy infrastructure must implement
 188    * one and give an instance of the class to start_copy.
 189    *
 190    * The implementer is responsible for making sure that the CopyCallback
 191    * can associate itself with the correct copy operation.
 192    */
 193   typedef boost::tuple<int, CopyResults*> CopyCallbackResults;
 194
 195   friend class CopyFromCallback;
 196   friend struct CopyFromFinisher;
 197   friend class PromoteCallback;
 198   friend struct PromoteFinisher;
 199   friend struct C_gather;
 200
 201   struct ProxyReadOp {
 202     OpRequestRef op;
 203     hobject_t soid;
 204     ceph_tid_t objecter_tid;
 205     std::vector<OSDOp> &ops;
 206     version_t user_version;
 207     int data_offset;
 208     bool canceled;              ///< true if canceled
 209
 210     ProxyReadOp(OpRequestRef _op, hobject_t oid, std::vector<OSDOp>& _ops)
 211       : op(_op), soid(oid),
 212         objecter_tid(0), ops(_ops),
 213         user_version(0), data_offset(0),
 214         canceled(false) { }
 215   };
 216   typedef std::shared_ptr<ProxyReadOp> ProxyReadOpRef;
 217
 218   struct ProxyWriteOp {
 219     OpContext *ctx;
 220     OpRequestRef op;
 221     hobject_t soid;
 222     ceph_tid_t objecter_tid;
 223     std::vector<OSDOp> &ops;
 224     version_t user_version;
 225     bool sent_reply;
 226     utime_t mtime;
 227     bool canceled;
 228     osd_reqid_t reqid;
 229
 230     ProxyWriteOp(OpRequestRef _op, hobject_t oid, std::vector<OSDOp>& _ops, osd_reqid_t _reqid)
 231       : ctx(NULL), op(_op), soid(oid),
 232         objecter_tid(0), ops(_ops),
 233         user_version(0), sent_reply(false),
 234         canceled(false),
 235         reqid(_reqid) { }
 236   };
 237   typedef std::shared_ptr<ProxyWriteOp> ProxyWriteOpRef;
 238
 239   struct FlushOp {
 240     ObjectContextRef obc;       ///< obc we are flushing
 241     OpRequestRef op;            ///< initiating op
 242     std::list<OpRequestRef> dup_ops; ///< bandwagon jumpers
 243     version_t flushed_version;  ///< user version we are flushing
 244     ceph_tid_t objecter_tid;    ///< copy-from request tid
 245     int rval;                   ///< copy-from result
 246     bool blocking;              ///< whether we are blocking updates
 247     bool removal;               ///< we are removing the backend object
 248     std::optional<std::function<void()>> on_flush; ///< callback, may be null
 249     // for chunked object
 250     std::map<uint64_t, int> io_results;
 251     std::map<uint64_t, ceph_tid_t> io_tids;
 252     uint64_t chunks;
 253
 254     FlushOp()
 255       : flushed_version(0), objecter_tid(0), rval(0),
 256         blocking(false), removal(false), chunks(0) {}
 257     ~FlushOp() { ceph_assert(!on_flush); }
 258   };
 259   typedef std::shared_ptr<FlushOp> FlushOpRef;
 260
 261   struct CLSGatherOp {
 262     OpContext *ctx = nullptr;
 263     ObjectContextRef obc;
 264     OpRequestRef op;
 265     std::vector<ceph_tid_t> objecter_tids;
 266     int rval = 0;
 267
 268     CLSGatherOp(OpContext *ctx_, ObjectContextRef obc_, OpRequestRef op_)
 269       : ctx(ctx_), obc(obc_), op(op_)  {}
 270     CLSGatherOp() {}
 271     ~CLSGatherOp() {}
 272   };
 273
 274   friend struct RefCountCallback;
 275   struct ManifestOp {
 276     RefCountCallback *cb = nullptr;
 277     ceph_tid_t objecter_tid = 0;
 278     OpRequestRef op;
 279     std::map<uint64_t, int> results;
 280     std::map<uint64_t, ceph_tid_t> tids;
 281     std::map<hobject_t, std::pair<uint64_t, uint64_t>> chunks;
 282     uint64_t num_chunks = 0;
 283     object_manifest_t new_manifest;
 284
 285
 286     ManifestOp(RefCountCallback* cb)
 287       : cb(cb) {}
 288     ManifestOp() = default;
 289   };
 290   typedef std::shared_ptr<ManifestOp> ManifestOpRef;
 291   std::map<hobject_t, ManifestOpRef> manifest_ops;
 292
 293   boost::scoped_ptr<PGBackend> pgbackend;
 294   PGBackend *get_pgbackend() override {
 295     return pgbackend.get();
 296   }
 297
 298   const PGBackend *get_pgbackend() const override {
 299     return pgbackend.get();
 300   }
 301
 302   /// Listener methods
 303   DoutPrefixProvider *get_dpp() override {
 304     return this;
 305   }
 306
 307   void on_local_recover(
 308     const hobject_t &oid,
 309     const ObjectRecoveryInfo &recovery_info,
 310     ObjectContextRef obc,
 311     bool is_delete,
 312     ObjectStore::Transaction *t
 313     ) override;
 314   void on_peer_recover(
 315     pg_shard_t peer,
 316     const hobject_t &oid,
 317     const ObjectRecoveryInfo &recovery_info
 318     ) override {
 319     recovery_state.on_peer_recover(peer, oid, recovery_info.version);
 320   }
 321   void begin_peer_recover(
 322     pg_shard_t peer,
 323     const hobject_t oid) override {
 324     recovery_state.begin_peer_recover(peer, oid);
 325   }
 326   void on_global_recover(
 327     const hobject_t &oid,
 328     const object_stat_sum_t &stat_diff,
 329     bool is_delete) override;
 330   void on_failed_pull(
 331     const std::set<pg_shard_t> &from,
 332     const hobject_t &soid,
 333     const eversion_t &version) override;
 334   void cancel_pull(const hobject_t &soid) override;
 335   void apply_stats(
 336     const hobject_t &soid,
 337     const object_stat_sum_t &delta_stats) override;
 338
 339   bool primary_error(const hobject_t& soid, eversion_t v);
 340
 341   void remove_missing_object(const hobject_t &oid,
 342                              eversion_t v,
 343                              Context *on_complete) override;
 344
 345   template<class T> class BlessedGenContext;
 346   template<class T> class UnlockedBlessedGenContext;
 347   class BlessedContext;
 348   Context *bless_context(Context *c) override;
 349
 350   GenContext<ThreadPool::TPHandle&> *bless_gencontext(
 351     GenContext<ThreadPool::TPHandle&> *c) override;
 352   GenContext<ThreadPool::TPHandle&> *bless_unlocked_gencontext(
 353     GenContext<ThreadPool::TPHandle&> *c) override;
 354
 355   void send_message(int to_osd, Message *m) override {
 356     osd->send_message_osd_cluster(to_osd, m, get_osdmap_epoch());
 357   }
 358   void queue_transaction(ObjectStore::Transaction&& t,
 359                          OpRequestRef op) override {
 360     osd->store->queue_transaction(ch, std::move(t), op);
 361   }
 362   void queue_transactions(std::vector<ObjectStore::Transaction>& tls,
 363                           OpRequestRef op) override {
 364     osd->store->queue_transactions(ch, tls, op, NULL);
 365   }
 366   epoch_t get_interval_start_epoch() const override {
 367     return info.history.same_interval_since;
 368   }
 369   epoch_t get_last_peering_reset_epoch() const override {
 370     return get_last_peering_reset();
 371   }
 372   const std::set<pg_shard_t> &get_acting_recovery_backfill_shards() const override {
 373     return get_acting_recovery_backfill();
 374   }
 375   const std::set<pg_shard_t> &get_acting_shards() const override {
 376     return recovery_state.get_actingset();
 377   }
 378   const std::set<pg_shard_t> &get_backfill_shards() const override {
 379     return get_backfill_targets();
 380   }
 381
 382   std::ostream& gen_dbg_prefix(std::ostream& out) const override {
 383     return gen_prefix(out);
 384   }
 385
 386   const HobjToShardSetMapping& get_missing_loc_shards() const override
 387   {
 388     return recovery_state.get_missing_loc().get_missing_locs();
 389   }
 390   const std::map<pg_shard_t, pg_missing_t> &get_shard_missing() const override {
 391     return recovery_state.get_peer_missing();
 392   }
 393   using PGBackend::Listener::get_shard_missing;
 394   const std::map<pg_shard_t, pg_info_t> &get_shard_info() const override {
 395     return recovery_state.get_peer_info();
 396   }
 397   using PGBackend::Listener::get_shard_info;
 398   const pg_missing_tracker_t &get_local_missing() const override {
 399     return recovery_state.get_pg_log().get_missing();
 400   }
 401   const PGLog &get_log() const override {
 402     return recovery_state.get_pg_log();
 403   }
 404   void add_local_next_event(const pg_log_entry_t& e) override {
 405     recovery_state.add_local_next_event(e);
 406   }
 407   bool pgb_is_primary() const override {
 408     return is_primary();
 409   }
 410   const OSDMapRef& pgb_get_osdmap() const override final {
 411     return get_osdmap();
 412   }
 413   epoch_t pgb_get_osdmap_epoch() const override final {
 414     return get_osdmap_epoch();
 415   }
 416   const pg_info_t &get_info() const override {
 417     return info;
 418   }
 419   const pg_pool_t &get_pool() const override {
 420     return pool.info;
 421   }
 422
 423   ObjectContextRef get_obc(
 424     const hobject_t &hoid,
 425     const std::map<std::string, ceph::buffer::list, std::less<>> &attrs) override {
 426     return get_object_context(hoid, true, &attrs);
 427   }
 428
 429   bool try_lock_for_read(
 430     const hobject_t &hoid,
 431     ObcLockManager &manager) override {
 432     if (is_missing_object(hoid))
 433       return false;
 434     auto obc = get_object_context(hoid, false, nullptr);
 435     if (!obc)
 436       return false;
 437     return manager.try_get_read_lock(hoid, obc);
 438   }
 439
 440   void release_locks(ObcLockManager &manager) override {
 441     release_object_locks(manager);
 442   }
 443
 444   bool pg_is_repair() override {
 445     return is_repair();
 446   }
 447   void inc_osd_stat_repaired() override {
 448     osd->inc_osd_stat_repaired();
 449   }
 450   bool pg_is_remote_backfilling() override {
 451     return is_remote_backfilling();
 452   }
 453   void pg_add_local_num_bytes(int64_t num_bytes) override {
 454     add_local_num_bytes(num_bytes);
 455   }
 456   void pg_sub_local_num_bytes(int64_t num_bytes) override {
 457     sub_local_num_bytes(num_bytes);
 458   }
 459   void pg_add_num_bytes(int64_t num_bytes) override {
 460     add_num_bytes(num_bytes);
 461   }
 462   void pg_sub_num_bytes(int64_t num_bytes) override {
 463     sub_num_bytes(num_bytes);
 464   }
 465
 466   void pgb_set_object_snap_mapping(
 467     const hobject_t &soid,
 468     const std::set<snapid_t> &snaps,
 469     ObjectStore::Transaction *t) override {
 470     return update_object_snap_mapping(t, soid, snaps);
 471   }
 472   void pgb_clear_object_snap_mapping(
 473     const hobject_t &soid,
 474     ObjectStore::Transaction *t) override {
 475     return clear_object_snap_mapping(t, soid);
 476   }
 477
 478   void log_operation(
 479     std::vector<pg_log_entry_t>&& logv,
 480     const std::optional<pg_hit_set_history_t> &hset_history,
 481     const eversion_t &trim_to,
 482     const eversion_t &roll_forward_to,
 483     const eversion_t &min_last_complete_ondisk,
 484     bool transaction_applied,
 485     ObjectStore::Transaction &t,
 486     bool async = false) override {
 487     if (is_primary()) {
 488       ceph_assert(trim_to <= recovery_state.get_last_update_ondisk());
 489     }
 490     if (hset_history) {
 491       recovery_state.update_hset(*hset_history);
 492     }
 493     if (transaction_applied) {
 494       update_snap_map(logv, t);
 495     }
 496     auto last = logv.rbegin();
 497     if (is_primary() && last != logv.rend()) {
 498       projected_log.skip_can_rollback_to_to_head();
 499       projected_log.trim(cct, last->version, nullptr, nullptr, nullptr);
 500     }
 501     if (!is_primary() && !is_ec_pg()) {
 502       replica_clear_repop_obc(logv, t);
 503     }
 504     recovery_state.append_log(
 505       std::move(logv), trim_to, roll_forward_to, min_last_complete_ondisk,
 506       t, transaction_applied, async);
 507   }
 508
 509   void replica_clear_repop_obc(
 510     const std::vector<pg_log_entry_t> &logv,
 511     ObjectStore::Transaction &t);
 512
 513   void op_applied(const eversion_t &applied_version) override;
 514
 515   bool should_send_op(
 516     pg_shard_t peer,
 517     const hobject_t &hoid) override;
 518
 519   bool pg_is_undersized() const override {
 520     return is_undersized();
 521   }
 522
 523   bool pg_is_repair() const override {
 524     return is_repair();
 525   }
 526
 527   void update_peer_last_complete_ondisk(
 528     pg_shard_t fromosd,
 529     eversion_t lcod) override {
 530     recovery_state.update_peer_last_complete_ondisk(fromosd, lcod);
 531   }
 532
 533   void update_last_complete_ondisk(
 534     eversion_t lcod) override {
 535     recovery_state.update_last_complete_ondisk(lcod);
 536   }
 537
 538   void update_stats(
 539     const pg_stat_t &stat) override {
 540     recovery_state.update_stats(
 541       [&stat](auto &history, auto &stats) {
 542         stats = stat;
 543         return false;
 544       });
 545   }
 546
 547   void schedule_recovery_work(
 548     GenContext<ThreadPool::TPHandle&> *c) override;
 549
 550   pg_shard_t whoami_shard() const override {
 551     return pg_whoami;
 552   }
 553   spg_t primary_spg_t() const override {
 554     return spg_t(info.pgid.pgid, get_primary().shard);
 555   }
 556   pg_shard_t primary_shard() const override {
 557     return get_primary();
 558   }
 559   uint64_t min_peer_features() const override {
 560     return recovery_state.get_min_peer_features();
 561   }
 562   uint64_t min_upacting_features() const override {
 563     return recovery_state.get_min_upacting_features();
 564   }
 565   void send_message_osd_cluster(
 566     int peer, Message *m, epoch_t from_epoch) override {
 567     osd->send_message_osd_cluster(peer, m, from_epoch);
 568   }
 569   void send_message_osd_cluster(
 570     std::vector<std::pair<int, Message*>>& messages, epoch_t from_epoch) override {
 571     osd->send_message_osd_cluster(messages, from_epoch);
 572   }
 573   void send_message_osd_cluster(
 574     MessageRef m, Connection *con) override {
 575     osd->send_message_osd_cluster(m, con);
 576   }
 577   void send_message_osd_cluster(
 578     Message *m, const ConnectionRef& con) override {
 579     osd->send_message_osd_cluster(m, con);
 580   }
 581   ConnectionRef get_con_osd_cluster(int peer, epoch_t from_epoch) override;
 582   entity_name_t get_cluster_msgr_name() override {
 583     return osd->get_cluster_msgr_name();
 584   }
 585
 586   PerfCounters *get_logger() override;
 587
 588   ceph_tid_t get_tid() override { return osd->get_tid(); }
 589
 590   OstreamTemp clog_error() override { return osd->clog->error(); }
 591   OstreamTemp clog_warn() override { return osd->clog->warn(); }
 592
 593   /**
 594    * a scrub-map arrived from a replica
 595    */
 596   void do_replica_scrub_map(OpRequestRef op);
 597
 598   struct watch_disconnect_t {
 599     uint64_t cookie;
 600     entity_name_t name;
 601     bool send_disconnect;
 602     watch_disconnect_t(uint64_t c, entity_name_t n, bool sd)
 603       : cookie(c), name(n), send_disconnect(sd) {}
 604   };
 605   void complete_disconnect_watches(
 606     ObjectContextRef obc,
 607     const std::list<watch_disconnect_t> &to_disconnect);
 608
 609   struct OpFinisher {
 610     virtual ~OpFinisher() {
 611     }
 612
 613     virtual int execute() = 0;
 614   };
 615
 616   /*
 617    * Capture all object state associated with an in-progress read or write.
 618    */
 619   struct OpContext {
 620     OpRequestRef op;
 621     osd_reqid_t reqid;
 622     std::vector<OSDOp> *ops;
 623
 624     const ObjectState *obs; // Old objectstate
 625     const SnapSet *snapset; // Old snapset
 626
 627     ObjectState new_obs;  // resulting ObjectState
 628     SnapSet new_snapset;  // resulting SnapSet (in case of a write)
 629     //pg_stat_t new_stats;  // resulting Stats
 630     object_stat_sum_t delta_stats;
 631
 632     bool modify;          // (force) modification (even if op_t is empty)
 633     bool user_modify;     // user-visible modification
 634     bool undirty;         // user explicitly un-dirtying this object
 635     bool cache_operation;     ///< true if this is a cache eviction
 636     bool ignore_cache;    ///< true if IGNORE_CACHE flag is std::set
 637     bool ignore_log_op_stats;  // don't log op stats
 638     bool update_log_only; ///< this is a write that returned an error - just record in pg log for dup detection
 639     ObjectCleanRegions clean_regions;
 640
 641     // side effects
 642     std::list<std::pair<watch_info_t,bool> > watch_connects; ///< new watch + will_ping flag
 643     std::list<watch_disconnect_t> watch_disconnects; ///< old watch + send_discon
 644     std::list<notify_info_t> notifies;
 645     struct NotifyAck {
 646       std::optional<uint64_t> watch_cookie;
 647       uint64_t notify_id;
 648       ceph::buffer::list reply_bl;
 649       explicit NotifyAck(uint64_t notify_id) : notify_id(notify_id) {}
 650       NotifyAck(uint64_t notify_id, uint64_t cookie, ceph::buffer::list& rbl)
 651         : watch_cookie(cookie), notify_id(notify_id) {
 652         reply_bl = std::move(rbl);
 653       }
 654     };
 655     std::list<NotifyAck> notify_acks;
 656
 657     uint64_t bytes_written, bytes_read;
 658
 659     utime_t mtime;
 660     SnapContext snapc;           // writer snap context
 661     eversion_t at_version;       // pg's current version pointer
 662     version_t user_at_version;   // pg's current user version pointer
 663
 664     /// index of the current subop - only valid inside of do_osd_ops()
 665     int current_osd_subop_num;
 666     /// total number of subops processed in this context for cls_cxx_subop_version()
 667     int processed_subop_count = 0;
 668
 669     PGTransactionUPtr op_t;
 670     std::vector<pg_log_entry_t> log;
 671     std::optional<pg_hit_set_history_t> updated_hset_history;
 672
 673     interval_set<uint64_t> modified_ranges;
 674     ObjectContextRef obc;
 675     ObjectContextRef clone_obc;    // if we created a clone
 676     ObjectContextRef head_obc;     // if we also update snapset (see trim_object)
 677
 678     // FIXME: we may want to kill this msgr hint off at some point!
 679     std::optional<int> data_off = std::nullopt;
 680
 681     MOSDOpReply *reply;
 682
 683     PrimaryLogPG *pg;
 684
 685     int num_read;    ///< count read ops
 686     int num_write;   ///< count update ops
 687
 688     mempool::osd_pglog::vector<std::pair<osd_reqid_t, version_t> > extra_reqids;
 689     mempool::osd_pglog::map<uint32_t, int> extra_reqid_return_codes;
 690
 691     hobject_t new_temp_oid, discard_temp_oid;  ///< temp objects we should start/stop tracking
 692
 693     std::list<std::function<void()>> on_applied;
 694     std::list<std::function<void()>> on_committed;
 695     std::list<std::function<void()>> on_finish;
 696     std::list<std::function<void()>> on_success;
 697     template <typename F>
 698     void register_on_finish(F &&f) {
 699       on_finish.emplace_back(std::forward<F>(f));
 700     }
 701     template <typename F>
 702     void register_on_success(F &&f) {
 703       on_success.emplace_back(std::forward<F>(f));
 704     }
 705     template <typename F>
 706     void register_on_applied(F &&f) {
 707       on_applied.emplace_back(std::forward<F>(f));
 708     }
 709     template <typename F>
 710     void register_on_commit(F &&f) {
 711       on_committed.emplace_back(std::forward<F>(f));
 712     }
 713
 714     bool sent_reply = false;
 715
 716     // pending async reads <off, len, op_flags> -> <outbl, outr>
 717     std::list<std::pair<boost::tuple<uint64_t, uint64_t, unsigned>,
 718               std::pair<ceph::buffer::list*, Context*> > > pending_async_reads;
 719     int inflightreads;
 720     friend struct OnReadComplete;
 721     void start_async_reads(PrimaryLogPG *pg);
 722     void finish_read(PrimaryLogPG *pg);
 723     bool async_reads_complete() {
 724       return inflightreads == 0;
 725     }
 726
 727     RWState::State lock_type;
 728     ObcLockManager lock_manager;
 729
 730     std::map<int, std::unique_ptr<OpFinisher>> op_finishers;
 731
 732     OpContext(const OpContext& other);
 733     const OpContext& operator=(const OpContext& other);
 734
 735     OpContext(OpRequestRef _op, osd_reqid_t _reqid, std::vector<OSDOp>* _ops,
 736               ObjectContextRef& obc,
 737               PrimaryLogPG *_pg) :
 738       op(_op), reqid(_reqid), ops(_ops),
 739       obs(&obc->obs),
 740       snapset(0),
 741       new_obs(obs->oi, obs->exists),
 742       modify(false), user_modify(false), undirty(false), cache_operation(false),
 743       ignore_cache(false), ignore_log_op_stats(false), update_log_only(false),
 744       bytes_written(0), bytes_read(0), user_at_version(0),
 745       current_osd_subop_num(0),
 746       obc(obc),
 747       reply(NULL), pg(_pg),
 748       num_read(0),
 749       num_write(0),
 750       sent_reply(false),
 751       inflightreads(0),
 752       lock_type(RWState::RWNONE) {
 753       if (obc->ssc) {
 754         new_snapset = obc->ssc->snapset;
 755         snapset = &obc->ssc->snapset;
 756       }
 757     }
 758     OpContext(OpRequestRef _op, osd_reqid_t _reqid,
 759               std::vector<OSDOp>* _ops, PrimaryLogPG *_pg) :
 760       op(_op), reqid(_reqid), ops(_ops), obs(NULL), snapset(0),
 761       modify(false), user_modify(false), undirty(false), cache_operation(false),
 762       ignore_cache(false), ignore_log_op_stats(false), update_log_only(false),
 763       bytes_written(0), bytes_read(0), user_at_version(0),
 764       current_osd_subop_num(0),
 765       reply(NULL), pg(_pg),
 766       num_read(0),
 767       num_write(0),
 768       inflightreads(0),
 769       lock_type(RWState::RWNONE) {}
 770     void reset_obs(ObjectContextRef obc) {
 771       new_obs = ObjectState(obc->obs.oi, obc->obs.exists);
 772       if (obc->ssc) {
 773         new_snapset = obc->ssc->snapset;
 774         snapset = &obc->ssc->snapset;
 775       }
 776     }
 777     ~OpContext() {
 778       ceph_assert(!op_t);
 779       if (reply)
 780         reply->put();
 781       for (std::list<std::pair<boost::tuple<uint64_t, uint64_t, unsigned>,
 782                      std::pair<ceph::buffer::list*, Context*> > >::iterator i =
 783              pending_async_reads.begin();
 784            i != pending_async_reads.end();
 785            pending_async_reads.erase(i++)) {
 786         delete i->second.second;
 787       }
 788     }
 789     uint64_t get_features() {
 790       if (op && op->get_req()) {
 791         return op->get_req()->get_connection()->get_features();
 792       }
 793       return -1ull;
 794     }
 795   };
 796   using OpContextUPtr = std::unique_ptr<OpContext>;
 797   friend struct OpContext;
 798
 799   /*
 800    * State on the PG primary associated with the replicated mutation
 801    */
 802   class RepGather {
 803   public:
 804     hobject_t hoid;
 805     OpRequestRef op;
 806     xlist<RepGather*>::item queue_item;
 807     int nref;
 808
 809     eversion_t v;
 810     int r = 0;
 811
 812     ceph_tid_t rep_tid;
 813
 814     bool rep_aborted;
 815     bool all_committed;
 816
 817     utime_t   start;
 818
 819     eversion_t          pg_local_last_complete;
 820
 821     ObcLockManager lock_manager;
 822
 823     std::list<std::function<void()>> on_committed;
 824     std::list<std::function<void()>> on_success;
 825     std::list<std::function<void()>> on_finish;
 826
 827     RepGather(
 828       OpContext *c, ceph_tid_t rt,
 829       eversion_t lc) :
 830       hoid(c->obc->obs.oi.soid),
 831       op(c->op),
 832       queue_item(this),
 833       nref(1),
 834       rep_tid(rt),
 835       rep_aborted(false),
 836       all_committed(false),
 837       pg_local_last_complete(lc),
 838       lock_manager(std::move(c->lock_manager)),
 839       on_committed(std::move(c->on_committed)),
 840       on_success(std::move(c->on_success)),
 841       on_finish(std::move(c->on_finish)) {}
 842
 843     RepGather(
 844       ObcLockManager &&manager,
 845       OpRequestRef &&o,
 846       std::optional<std::function<void(void)> > &&on_complete,
 847       ceph_tid_t rt,
 848       eversion_t lc,
 849       int r) :
 850       op(o),
 851       queue_item(this),
 852       nref(1),
 853       r(r),
 854       rep_tid(rt),
 855       rep_aborted(false),
 856       all_committed(false),
 857       pg_local_last_complete(lc),
 858       lock_manager(std::move(manager)) {
 859       if (on_complete) {
 860         on_success.push_back(std::move(*on_complete));
 861       }
 862     }
 863
 864     RepGather *get() {
 865       nref++;
 866       return this;
 867     }
 868     void put() {
 869       ceph_assert(nref > 0);
 870       if (--nref == 0) {
 871         delete this;
 872         //generic_dout(0) << "deleting " << this << dendl;
 873       }
 874     }
 875   };
 876
 877
 878 protected:
 879
 880   /**
 881    * Grabs locks for OpContext, should be cleaned up in close_op_ctx
 882    *
 883    * @param ctx [in,out] ctx to get locks for
 884    * @return true on success, false if we are queued
 885    */
 886   bool get_rw_locks(bool write_ordered, OpContext *ctx);
 887
 888   /**
 889    * Cleans up OpContext
 890    *
 891    * @param ctx [in] ctx to clean up
 892    */
 893   void close_op_ctx(OpContext *ctx);
 894
 895   /**
 896    * Releases locks
 897    *
 898    * @param manager [in] manager with locks to release
 899    *
 900    * (moved to .cc due to scrubber access)
 901    */
 902   void release_object_locks(ObcLockManager &lock_manager);
 903
 904   // replica ops
 905   // [primary|tail]
 906   xlist<RepGather*> repop_queue;
 907
 908   friend class C_OSD_RepopCommit;
 909   void repop_all_committed(RepGather *repop);
 910   void eval_repop(RepGather*);
 911   void issue_repop(RepGather *repop, OpContext *ctx);
 912   RepGather *new_repop(
 913     OpContext *ctx,
 914     ceph_tid_t rep_tid);
 915   boost::intrusive_ptr<RepGather> new_repop(
 916     eversion_t version,
 917     int r,
 918     ObcLockManager &&manager,
 919     OpRequestRef &&op,
 920     std::optional<std::function<void(void)> > &&on_complete);
 921   void remove_repop(RepGather *repop);
 922
 923   OpContextUPtr simple_opc_create(ObjectContextRef obc);
 924   void simple_opc_submit(OpContextUPtr ctx);
 925
 926   /**
 927    * Merge entries atomically into all acting_recovery_backfill osds
 928    * adjusting missing and recovery state as necessary.
 929    *
 930    * Also used to store error log entries for dup detection.
 931    */
 932   void submit_log_entries(
 933     const mempool::osd_pglog::list<pg_log_entry_t> &entries,
 934     ObcLockManager &&manager,
 935     std::optional<std::function<void(void)> > &&on_complete,
 936     OpRequestRef op = OpRequestRef(),
 937     int r = 0);
 938   struct LogUpdateCtx {
 939     boost::intrusive_ptr<RepGather> repop;
 940     std::set<pg_shard_t> waiting_on;
 941   };
 942   void cancel_log_updates();
 943   std::map<ceph_tid_t, LogUpdateCtx> log_entry_update_waiting_on;
 944
 945
 946   // hot/cold tracking
 947   HitSetRef hit_set;        ///< currently accumulating HitSet
 948   utime_t hit_set_start_stamp;    ///< time the current HitSet started recording
 949
 950
 951   void hit_set_clear();     ///< discard any HitSet state
 952   void hit_set_setup();     ///< initialize HitSet state
 953   void hit_set_create();    ///< create a new HitSet
 954   void hit_set_persist();   ///< persist hit info
 955   bool hit_set_apply_log(); ///< apply log entries to update in-memory HitSet
 956   void hit_set_trim(OpContextUPtr &ctx, unsigned max); ///< discard old HitSets
 957   void hit_set_in_memory_trim(uint32_t max_in_memory); ///< discard old in memory HitSets
 958   void hit_set_remove_all();
 959
 960   hobject_t get_hit_set_current_object(utime_t stamp);
 961   hobject_t get_hit_set_archive_object(utime_t start,
 962                                        utime_t end,
 963                                        bool using_gmt);
 964
 965   // agent
 966   boost::scoped_ptr<TierAgentState> agent_state;
 967
 968   void agent_setup();       ///< initialize agent state
 969   bool agent_work(int max) override ///< entry point to do some agent work
 970   {
 971     return agent_work(max, max);
 972   }
 973   bool agent_work(int max, int agent_flush_quota) override;
 974   bool agent_maybe_flush(ObjectContextRef& obc);  ///< maybe flush
 975   bool agent_maybe_evict(ObjectContextRef& obc, bool after_flush);  ///< maybe evict
 976
 977   void agent_load_hit_sets();  ///< load HitSets, if needed
 978
 979   /// estimate object atime and temperature
 980   ///
 981   /// @param oid [in] object name
 982   /// @param temperature [out] relative temperature (# consider both access time and frequency)
 983   void agent_estimate_temp(const hobject_t& oid, int *temperature);
 984
 985   /// stop the agent
 986   void agent_stop() override;
 987   void agent_delay() override;
 988
 989   /// clear agent state
 990   void agent_clear() override;
 991
 992   /// choose (new) agent mode(s), returns true if op is requeued
 993   bool agent_choose_mode(bool restart = false, OpRequestRef op = OpRequestRef());
 994   void agent_choose_mode_restart() override;
 995
 996   /// true if we can send an ondisk/commit for v
 997   bool already_complete(eversion_t v);
 998
 999   // projected object info
1000   SharedLRU<hobject_t, ObjectContext> object_contexts;
1001   // std::map from oid.snapdir() to SnapSetContext *
1002   std::map<hobject_t, SnapSetContext*> snapset_contexts;
1003   ceph::mutex snapset_contexts_lock =
1004     ceph::make_mutex("PrimaryLogPG::snapset_contexts_lock");
1005
1006   // debug order that client ops are applied
1007   std::map<hobject_t, std::map<client_t, ceph_tid_t>> debug_op_order;
1008
1009   void populate_obc_watchers(ObjectContextRef obc);
1010   void check_blocklisted_obc_watchers(ObjectContextRef obc);
1011   void check_blocklisted_watchers() override;
1012   void get_watchers(std::list<obj_watch_item_t> *ls) override;
1013   void get_obc_watchers(ObjectContextRef obc, std::list<obj_watch_item_t> &pg_watchers);
1014 public:
1015   void handle_watch_timeout(WatchRef watch);
1016 protected:
1017
1018   ObjectContextRef create_object_context(const object_info_t& oi, SnapSetContext *ssc);
1019   ObjectContextRef get_object_context(
1020     const hobject_t& soid,
1021     bool can_create,
1022     const std::map<std::string, ceph::buffer::list, std::less<>> *attrs = 0
1023     );
1024
1025   void context_registry_on_change();
1026   void object_context_destructor_callback(ObjectContext *obc);
1027   class C_PG_ObjectContext;
1028
1029   int find_object_context(const hobject_t& oid,
1030                           ObjectContextRef *pobc,
1031                           bool can_create,
1032                           bool map_snapid_to_clone=false,
1033                           hobject_t *missing_oid=NULL);
1034
1035   void add_object_context_to_pg_stat(ObjectContextRef obc, pg_stat_t *stat);
1036
1037   void get_src_oloc(const object_t& oid, const object_locator_t& oloc, object_locator_t& src_oloc);
1038
1039   SnapSetContext *get_snapset_context(
1040     const hobject_t& oid,
1041     bool can_create,
1042     const std::map<std::string, ceph::buffer::list, std::less<>> *attrs = 0,
1043     bool oid_existed = true //indicate this oid whether exsited in backend
1044     );
1045   void register_snapset_context(SnapSetContext *ssc) {
1046     std::lock_guard l(snapset_contexts_lock);
1047     _register_snapset_context(ssc);
1048   }
1049   void _register_snapset_context(SnapSetContext *ssc) {
1050     ceph_assert(ceph_mutex_is_locked(snapset_contexts_lock));
1051     if (!ssc->registered) {
1052       ceph_assert(snapset_contexts.count(ssc->oid) == 0);
1053       ssc->registered = true;
1054       snapset_contexts[ssc->oid] = ssc;
1055     }
1056   }
1057   void put_snapset_context(SnapSetContext *ssc);
1058
1059   std::map<hobject_t, ObjectContextRef> recovering;
1060
1061   /*
1062    * Backfill
1063    *
1064    * peer_info[backfill_target].last_backfill == info.last_backfill on the peer.
1065    *
1066    * objects prior to peer_info[backfill_target].last_backfill
1067    *   - are on the peer
1068    *   - are included in the peer stats
1069    *
1070    * objects \in (last_backfill, last_backfill_started]
1071    *   - are on the peer or are in backfills_in_flight
1072    *   - are not included in pg stats (yet)
1073    *   - have their stats in pending_backfill_updates on the primary
1074    */
1075   std::set<hobject_t> backfills_in_flight;
1076   std::map<hobject_t, pg_stat_t> pending_backfill_updates;
1077
1078   void dump_recovery_info(ceph::Formatter *f) const override {
1079     f->open_array_section("waiting_on_backfill");
1080     for (std::set<pg_shard_t>::const_iterator p = waiting_on_backfill.begin();
1081         p != waiting_on_backfill.end(); ++p)
1082       f->dump_stream("osd") << *p;
1083     f->close_section();
1084     f->dump_stream("last_backfill_started") << last_backfill_started;
1085     {
1086       f->open_object_section("backfill_info");
1087       backfill_info.dump(f);
1088       f->close_section();
1089     }
1090     {
1091       f->open_array_section("peer_backfill_info");
1092       for (std::map<pg_shard_t, BackfillInterval>::const_iterator pbi =
1093              peer_backfill_info.begin();
1094           pbi != peer_backfill_info.end(); ++pbi) {
1095         f->dump_stream("osd") << pbi->first;
1096         f->open_object_section("BackfillInterval");
1097           pbi->second.dump(f);
1098         f->close_section();
1099       }
1100       f->close_section();
1101     }
1102     {
1103       f->open_array_section("backfills_in_flight");
1104       for (std::set<hobject_t>::const_iterator i = backfills_in_flight.begin();
1105            i != backfills_in_flight.end();
1106            ++i) {
1107         f->dump_stream("object") << *i;
1108       }
1109       f->close_section();
1110     }
1111     {
1112       f->open_array_section("recovering");
1113       for (std::map<hobject_t, ObjectContextRef>::const_iterator i = recovering.begin();
1114            i != recovering.end();
1115            ++i) {
1116         f->dump_stream("object") << i->first;
1117       }
1118       f->close_section();
1119     }
1120     {
1121       f->open_object_section("pg_backend");
1122       pgbackend->dump_recovery_info(f);
1123       f->close_section();
1124     }
1125   }
1126
1127   /// last backfill operation started
1128   hobject_t last_backfill_started;
1129   bool new_backfill;
1130
1131   int prep_object_replica_pushes(const hobject_t& soid, eversion_t v,
1132                                  PGBackend::RecoveryHandle *h,
1133                                  bool *work_started);
1134   int prep_object_replica_deletes(const hobject_t& soid, eversion_t v,
1135                                   PGBackend::RecoveryHandle *h,
1136                                   bool *work_started);
1137
1138   void finish_degraded_object(const hobject_t oid);
1139
1140   // Cancels/resets pulls from peer
1141   void check_recovery_sources(const OSDMapRef& map) override ;
1142
1143   int recover_missing(
1144     const hobject_t& oid,
1145     eversion_t v,
1146     int priority,
1147     PGBackend::RecoveryHandle *h);
1148
1149   // low level ops
1150
1151   void _make_clone(
1152     OpContext *ctx,
1153     PGTransaction* t,
1154     ObjectContextRef obc,
1155     const hobject_t& head, const hobject_t& coid,
1156     object_info_t *poi);
1157   void execute_ctx(OpContext *ctx);
1158   void finish_ctx(OpContext *ctx, int log_op_type, int result=0);
1159   void reply_ctx(OpContext *ctx, int err);
1160   void make_writeable(OpContext *ctx);
1161   void log_op_stats(const OpRequest& op, uint64_t inb, uint64_t outb);
1162
1163   void write_update_size_and_usage(object_stat_sum_t& stats, object_info_t& oi,
1164                                    interval_set<uint64_t>& modified, uint64_t offset,
1165                                    uint64_t length, bool write_full=false);
1166   inline void truncate_update_size_and_usage(
1167     object_stat_sum_t& delta_stats,
1168     object_info_t& oi,
1169     uint64_t truncate_size);
1170
1171   enum class cache_result_t {
1172     NOOP,
1173     BLOCKED_FULL,
1174     BLOCKED_PROMOTE,
1175     HANDLED_PROXY,
1176     HANDLED_REDIRECT,
1177     REPLIED_WITH_EAGAIN,
1178     BLOCKED_RECOVERY,
1179   };
1180   cache_result_t maybe_handle_cache_detail(OpRequestRef op,
1181                                            bool write_ordered,
1182                                            ObjectContextRef obc, int r,
1183                                            hobject_t missing_oid,
1184                                            bool must_promote,
1185                                            bool in_hit_set,
1186                                            ObjectContextRef *promote_obc);
1187   cache_result_t maybe_handle_manifest_detail(OpRequestRef op,
1188                                                      bool write_ordered,
1189                                                      ObjectContextRef obc);
1190   bool maybe_handle_manifest(OpRequestRef op,
1191                               bool write_ordered,
1192                               ObjectContextRef obc) {
1193     return cache_result_t::NOOP != maybe_handle_manifest_detail(
1194       op,
1195       write_ordered,
1196       obc);
1197   }
1198
1199   /**
1200    * This helper function is called from do_op if the ObjectContext lookup fails.
1201    * @returns true if the caching code is handling the Op, false otherwise.
1202    */
1203   bool maybe_handle_cache(OpRequestRef op,
1204                           bool write_ordered,
1205                           ObjectContextRef obc, int r,
1206                           const hobject_t& missing_oid,
1207                           bool must_promote,
1208                           bool in_hit_set = false) {
1209     return cache_result_t::NOOP != maybe_handle_cache_detail(
1210       op,
1211       write_ordered,
1212       obc,
1213       r,
1214       missing_oid,
1215       must_promote,
1216       in_hit_set,
1217       nullptr);
1218   }
1219
1220   /**
1221    * This helper function checks if a promotion is needed.
1222    */
1223   bool maybe_promote(ObjectContextRef obc,
1224                      const hobject_t& missing_oid,
1225                      const object_locator_t& oloc,
1226                      bool in_hit_set,
1227                      uint32_t recency,
1228                      OpRequestRef promote_op,
1229                      ObjectContextRef *promote_obc = nullptr);
1230   /**
1231    * This helper function tells the client to redirect their request elsewhere.
1232    */
1233   void do_cache_redirect(OpRequestRef op);
1234   /**
1235    * This function attempts to start a promote.  Either it succeeds,
1236    * or places op on a wait std::list.  If op is null, failure means that
1237    * this is a noop.  If a future user wants to be able to distinguish
1238    * these cases, a return value should be added.
1239    */
1240   void promote_object(
1241     ObjectContextRef obc,            ///< [optional] obc
1242     const hobject_t& missing_object, ///< oid (if !obc)
1243     const object_locator_t& oloc,    ///< locator for obc|oid
1244     OpRequestRef op,                 ///< [optional] client op
1245     ObjectContextRef *promote_obc = nullptr ///< [optional] new obc for object
1246     );
1247
1248   int prepare_transaction(OpContext *ctx);
1249   std::list<std::pair<OpRequestRef, OpContext*> > in_progress_async_reads;
1250   void complete_read_ctx(int result, OpContext *ctx);
1251
1252   // pg on-disk content
1253   void check_local() override;
1254
1255   void _clear_recovery_state() override;
1256
1257   bool start_recovery_ops(
1258     uint64_t max,
1259     ThreadPool::TPHandle &handle, uint64_t *started) override;
1260
1261   uint64_t recover_primary(uint64_t max, ThreadPool::TPHandle &handle);
1262   uint64_t recover_replicas(uint64_t max, ThreadPool::TPHandle &handle,
1263                             bool *recovery_started);
1264   hobject_t earliest_peer_backfill() const;
1265   bool all_peer_done() const;
1266   /**
1267    * @param work_started will be std::set to true if recover_backfill got anywhere
1268    * @returns the number of operations started
1269    */
1270   uint64_t recover_backfill(uint64_t max, ThreadPool::TPHandle &handle,
1271                             bool *work_started);
1272
1273   /**
1274    * scan a (hash) range of objects in the current pg
1275    *
1276    * @min return at least this many items, unless we are done
1277    * @max return no more than this many items
1278    * @bi.begin first item should be >= this value
1279    * @bi [out] resulting std::map of objects to eversion_t's
1280    */
1281   void scan_range(
1282     int min, int max, BackfillInterval *bi,
1283     ThreadPool::TPHandle &handle
1284     );
1285
1286   /// Update a hash range to reflect changes since the last scan
1287   void update_range(
1288     BackfillInterval *bi,        ///< [in,out] interval to update
1289     ThreadPool::TPHandle &handle ///< [in] tp handle
1290     );
1291
1292   int prep_backfill_object_push(
1293     hobject_t oid, eversion_t v, ObjectContextRef obc,
1294     std::vector<pg_shard_t> peers,
1295     PGBackend::RecoveryHandle *h);
1296   void send_remove_op(const hobject_t& oid, eversion_t v, pg_shard_t peer);
1297
1298
1299   class C_OSD_AppliedRecoveredObject;
1300   class C_OSD_CommittedPushedObject;
1301   class C_OSD_AppliedRecoveredObjectReplica;
1302
1303   void _applied_recovered_object(ObjectContextRef obc);
1304   void _applied_recovered_object_replica();
1305   void _committed_pushed_object(epoch_t epoch, eversion_t lc);
1306   void recover_got(hobject_t oid, eversion_t v);
1307
1308   // -- copyfrom --
1309   std::map<hobject_t, CopyOpRef> copy_ops;
1310
1311   int do_copy_get(OpContext *ctx, ceph::buffer::list::const_iterator& bp, OSDOp& op,
1312                   ObjectContextRef& obc);
1313   int finish_copy_get();
1314
1315   void fill_in_copy_get_noent(OpRequestRef& op, hobject_t oid,
1316                               OSDOp& osd_op);
1317
1318   /**
1319    * To copy an object, call start_copy.
1320    *
1321    * @param cb: The CopyCallback to be activated when the copy is complete
1322    * @param obc: The ObjectContext we are copying into
1323    * @param src: The source object
1324    * @param oloc: the source object locator
1325    * @param version: the version of the source object to copy (0 for any)
1326    */
1327   void start_copy(CopyCallback *cb, ObjectContextRef obc, hobject_t src,
1328                   object_locator_t oloc, version_t version, unsigned flags,
1329                   bool mirror_snapset, unsigned src_obj_fadvise_flags,
1330                   unsigned dest_obj_fadvise_flags);
1331   void process_copy_chunk(hobject_t oid, ceph_tid_t tid, int r);
1332   void _write_copy_chunk(CopyOpRef cop, PGTransaction *t);
1333   uint64_t get_copy_chunk_size() const {
1334     uint64_t size = cct->_conf->osd_copyfrom_max_chunk;
1335     if (pool.info.required_alignment()) {
1336       uint64_t alignment = pool.info.required_alignment();
1337       if (size % alignment) {
1338         size += alignment - (size % alignment);
1339       }
1340     }
1341     return size;
1342   }
1343   void _copy_some(ObjectContextRef obc, CopyOpRef cop);
1344   void finish_copyfrom(CopyFromCallback *cb);
1345   void finish_promote(int r, CopyResults *results, ObjectContextRef obc);
1346   void cancel_copy(CopyOpRef cop, bool requeue, std::vector<ceph_tid_t> *tids);
1347   void cancel_copy_ops(bool requeue, std::vector<ceph_tid_t> *tids);
1348
1349   friend struct C_Copyfrom;
1350
1351   // -- flush --
1352   std::map<hobject_t, FlushOpRef> flush_ops;
1353
1354   /// start_flush takes ownership of on_flush iff ret == -EINPROGRESS
1355   int start_flush(
1356     OpRequestRef op, ObjectContextRef obc,
1357     bool blocking, hobject_t *pmissing,
1358     std::optional<std::function<void()>> &&on_flush);
1359   void finish_flush(hobject_t oid, ceph_tid_t tid, int r);
1360   int try_flush_mark_clean(FlushOpRef fop);
1361   void cancel_flush(FlushOpRef fop, bool requeue, std::vector<ceph_tid_t> *tids);
1362   void cancel_flush_ops(bool requeue, std::vector<ceph_tid_t> *tids);
1363
1364   /// @return false if clone is has been evicted
1365   bool is_present_clone(hobject_t coid);
1366
1367   friend struct C_Flush;
1368
1369   // -- cls_gather --
1370   std::map<hobject_t, CLSGatherOp> cls_gather_ops;
1371   void cancel_cls_gather(std::map<hobject_t,CLSGatherOp>::iterator iter, bool requeue, std::vector<ceph_tid_t> *tids);
1372   void cancel_cls_gather_ops(bool requeue, std::vector<ceph_tid_t> *tids);
1373
1374   // -- scrub --
1375   bool _range_available_for_scrub(
1376     const hobject_t &begin, const hobject_t &end) override;
1377
1378   void _split_into(pg_t child_pgid, PG *child,
1379                    unsigned split_bits) override;
1380   void apply_and_flush_repops(bool requeue);
1381
1382   int do_xattr_cmp_u64(int op, uint64_t v1, ceph::buffer::list& xattr);
1383   int do_xattr_cmp_str(int op, std::string& v1s, ceph::buffer::list& xattr);
1384
1385   // -- checksum --
1386   int do_checksum(OpContext *ctx, OSDOp& osd_op, ceph::buffer::list::const_iterator *bl_it);
1387   int finish_checksum(OSDOp& osd_op, Checksummer::CSumType csum_type,
1388                       ceph::buffer::list::const_iterator *init_value_bl_it,
1389                       const ceph::buffer::list &read_bl);
1390
1391   friend struct C_ChecksumRead;
1392
1393   int do_extent_cmp(OpContext *ctx, OSDOp& osd_op);
1394   int finish_extent_cmp(OSDOp& osd_op, const ceph::buffer::list &read_bl);
1395
1396   friend struct C_ExtentCmpRead;
1397
1398   int do_read(OpContext *ctx, OSDOp& osd_op);
1399   int do_sparse_read(OpContext *ctx, OSDOp& osd_op);
1400   int do_writesame(OpContext *ctx, OSDOp& osd_op);
1401
1402   bool pgls_filter(const PGLSFilter& filter, const hobject_t& sobj);
1403
1404   std::pair<int, std::unique_ptr<const PGLSFilter>> get_pgls_filter(
1405     ceph::buffer::list::const_iterator& iter);
1406
1407   std::map<hobject_t, std::list<OpRequestRef>> in_progress_proxy_ops;
1408   void kick_proxy_ops_blocked(hobject_t& soid);
1409   void cancel_proxy_ops(bool requeue, std::vector<ceph_tid_t> *tids);
1410
1411   // -- proxyread --
1412   std::map<ceph_tid_t, ProxyReadOpRef> proxyread_ops;
1413
1414   void do_proxy_read(OpRequestRef op, ObjectContextRef obc = NULL);
1415   void finish_proxy_read(hobject_t oid, ceph_tid_t tid, int r);
1416   void cancel_proxy_read(ProxyReadOpRef prdop, std::vector<ceph_tid_t> *tids);
1417
1418   friend struct C_ProxyRead;
1419
1420   // -- proxywrite --
1421   std::map<ceph_tid_t, ProxyWriteOpRef> proxywrite_ops;
1422
1423   void do_proxy_write(OpRequestRef op, ObjectContextRef obc = NULL);
1424   void finish_proxy_write(hobject_t oid, ceph_tid_t tid, int r);
1425   void cancel_proxy_write(ProxyWriteOpRef pwop, std::vector<ceph_tid_t> *tids);
1426
1427   friend struct C_ProxyWrite_Commit;
1428
1429   // -- chunkop --
1430   enum class refcount_t {
1431     INCREMENT_REF,
1432     DECREMENT_REF,
1433     CREATE_OR_GET_REF,
1434   };
1435   void do_proxy_chunked_op(OpRequestRef op, const hobject_t& missing_oid,
1436                            ObjectContextRef obc, bool write_ordered);
1437   void do_proxy_chunked_read(OpRequestRef op, ObjectContextRef obc, int op_index,
1438                              uint64_t chunk_index, uint64_t req_offset, uint64_t req_length,
1439                              uint64_t req_total_len, bool write_ordered);
1440   bool can_proxy_chunked_read(OpRequestRef op, ObjectContextRef obc);
1441   void _copy_some_manifest(ObjectContextRef obc, CopyOpRef cop, uint64_t start_offset);
1442   void process_copy_chunk_manifest(hobject_t oid, ceph_tid_t tid, int r, uint64_t offset);
1443   void finish_promote_manifest(int r, CopyResults *results, ObjectContextRef obc);
1444   void cancel_and_requeue_proxy_ops(hobject_t oid);
1445   void cancel_manifest_ops(bool requeue, std::vector<ceph_tid_t> *tids);
1446   ceph_tid_t refcount_manifest(hobject_t src_soid, hobject_t tgt_soid, refcount_t type,
1447                               Context *cb, std::optional<bufferlist> chunk);
1448   void dec_all_refcount_manifest(const object_info_t& oi, OpContext* ctx);
1449   void dec_refcount(const hobject_t& soid, const object_ref_delta_t& refs);
1450   void update_chunk_map_by_dirty(OpContext* ctx);
1451   void dec_refcount_by_dirty(OpContext* ctx);
1452   ObjectContextRef get_prev_clone_obc(ObjectContextRef obc);
1453   bool recover_adjacent_clones(ObjectContextRef obc, OpRequestRef op);
1454   void get_adjacent_clones(ObjectContextRef src_obc,
1455                            ObjectContextRef& _l, ObjectContextRef& _g);
1456   bool inc_refcount_by_set(OpContext* ctx, object_manifest_t& tgt,
1457                            OSDOp& osd_op);
1458   int do_cdc(const object_info_t& oi, std::map<uint64_t, chunk_info_t>& chunk_map,
1459              std::map<uint64_t, bufferlist>& chunks);
1460   int start_dedup(OpRequestRef op, ObjectContextRef obc);
1461   std::pair<int, hobject_t> get_fpoid_from_chunk(const hobject_t soid, bufferlist& chunk);
1462   int finish_set_dedup(hobject_t oid, int r, ceph_tid_t tid, uint64_t offset);
1463   int finish_set_manifest_refcount(hobject_t oid, int r, ceph_tid_t tid, uint64_t offset);
1464
1465   friend struct C_ProxyChunkRead;
1466   friend class PromoteManifestCallback;
1467   friend struct C_CopyChunk;
1468   friend struct RefCountCallback;
1469   friend struct C_SetDedupChunks;
1470   friend struct C_SetManifestRefCountDone;
1471   friend struct SetManifestFinisher;
1472
1473 public:
1474   PrimaryLogPG(OSDService *o, OSDMapRef curmap,
1475                const PGPool &_pool,
1476                const std::map<std::string,std::string>& ec_profile,
1477                spg_t p);
1478   ~PrimaryLogPG() override;
1479
1480   void do_command(
1481     const std::string_view& prefix,
1482     const cmdmap_t& cmdmap,
1483     const ceph::buffer::list& idata,
1484     std::function<void(int,const std::string&,ceph::buffer::list&)> on_finish) override;
1485
1486   void clear_cache() override;
1487   int get_cache_obj_count() override {
1488     return object_contexts.get_count();
1489   }
1490   unsigned get_pg_shard() const {
1491     return info.pgid.hash_to_shard(osd->get_num_shards());
1492   }
1493   void do_request(
1494     OpRequestRef& op,
1495     ThreadPool::TPHandle &handle) override;
1496   void do_op(OpRequestRef& op);
1497   void record_write_error(OpRequestRef op, const hobject_t &soid,
1498                           MOSDOpReply *orig_reply, int r,
1499                           OpContext *ctx_for_op_returns=nullptr);
1500   void do_pg_op(OpRequestRef op);
1501   void do_scan(
1502     OpRequestRef op,
1503     ThreadPool::TPHandle &handle);
1504   void do_backfill(OpRequestRef op);
1505   void do_backfill_remove(OpRequestRef op);
1506
1507   void handle_backoff(OpRequestRef& op);
1508
1509   int trim_object(bool first, const hobject_t &coid, snapid_t snap_to_trim,
1510                   OpContextUPtr *ctxp);
1511   void snap_trimmer(epoch_t e) override;
1512   void kick_snap_trim() override;
1513   void snap_trimmer_scrub_complete() override;
1514   int do_osd_ops(OpContext *ctx, std::vector<OSDOp>& ops);
1515
1516   int _get_tmap(OpContext *ctx, ceph::buffer::list *header, ceph::buffer::list *vals);
1517   int do_tmap2omap(OpContext *ctx, unsigned flags);
1518   int do_tmapup(OpContext *ctx, ceph::buffer::list::const_iterator& bp, OSDOp& osd_op);
1519   int do_tmapup_slow(OpContext *ctx, ceph::buffer::list::const_iterator& bp, OSDOp& osd_op, ceph::buffer::list& bl);
1520
1521   void do_osd_op_effects(OpContext *ctx, const ConnectionRef& conn);
1522   int start_cls_gather(OpContext *ctx, std::map<std::string, bufferlist> *src_objs, const std::string& pool,
1523                        const char *cls, const char *method, bufferlist& inbl);
1524
1525 private:
1526   int do_scrub_ls(const MOSDOp *op, OSDOp *osd_op);
1527   bool check_src_targ(const hobject_t& soid, const hobject_t& toid) const;
1528
1529   uint64_t temp_seq; ///< last id for naming temp objects
1530   /// generate a new temp object name
1531   hobject_t generate_temp_object(const hobject_t& target);
1532   /// generate a new temp object name (for recovery)
1533   hobject_t get_temp_recovery_object(const hobject_t& target,
1534                                      eversion_t version) override;
1535   int get_recovery_op_priority() const {
1536     int64_t pri = 0;
1537     pool.info.opts.get(pool_opts_t::RECOVERY_OP_PRIORITY, &pri);
1538     return  pri > 0 ? pri : cct->_conf->osd_recovery_op_priority;
1539   }
1540
1541 public:
1542   coll_t get_coll() {
1543     return coll;
1544   }
1545   void split_colls(
1546     spg_t child,
1547     int split_bits,
1548     int seed,
1549     const pg_pool_t *pool,
1550     ObjectStore::Transaction &t) override {
1551     coll_t target = coll_t(child);
1552     create_pg_collection(t, child, split_bits);
1553     t.split_collection(
1554       coll,
1555       split_bits,
1556       seed,
1557       target);
1558     init_pg_ondisk(t, child, pool);
1559   }
1560 private:
1561
1562   struct DoSnapWork : boost::statechart::event< DoSnapWork > {
1563     DoSnapWork() : boost::statechart::event < DoSnapWork >() {}
1564   };
1565   struct KickTrim : boost::statechart::event< KickTrim > {
1566     KickTrim() : boost::statechart::event < KickTrim >() {}
1567   };
1568   struct RepopsComplete : boost::statechart::event< RepopsComplete > {
1569     RepopsComplete() : boost::statechart::event < RepopsComplete >() {}
1570   };
1571   struct ScrubComplete : boost::statechart::event< ScrubComplete > {
1572     ScrubComplete() : boost::statechart::event < ScrubComplete >() {}
1573   };
1574   struct TrimWriteUnblocked : boost::statechart::event< TrimWriteUnblocked > {
1575     TrimWriteUnblocked() : boost::statechart::event < TrimWriteUnblocked >() {}
1576   };
1577   struct Reset : boost::statechart::event< Reset > {
1578     Reset() : boost::statechart::event< Reset >() {}
1579   };
1580   struct SnapTrimReserved : boost::statechart::event< SnapTrimReserved > {
1581     SnapTrimReserved() : boost::statechart::event< SnapTrimReserved >() {}
1582   };
1583   struct SnapTrimTimerReady : boost::statechart::event< SnapTrimTimerReady > {
1584     SnapTrimTimerReady() : boost::statechart::event< SnapTrimTimerReady >() {}
1585   };
1586
1587   struct NotTrimming;
1588   struct SnapTrimmer : public boost::statechart::state_machine< SnapTrimmer, NotTrimming > {
1589     PrimaryLogPG *pg;
1590     explicit SnapTrimmer(PrimaryLogPG *pg) : pg(pg) {}
1591     void log_enter(const char *state_name);
1592     void log_exit(const char *state_name, utime_t duration);
1593     bool permit_trim();
1594     bool can_trim() {
1595       return
1596         permit_trim() &&
1597         !pg->get_osdmap()->test_flag(CEPH_OSDMAP_NOSNAPTRIM);
1598     }
1599   } snap_trimmer_machine;
1600
1601   struct WaitReservation;
1602   struct Trimming : boost::statechart::state< Trimming, SnapTrimmer, WaitReservation >, NamedState {
1603     typedef boost::mpl::list <
1604       boost::statechart::custom_reaction< KickTrim >,
1605       boost::statechart::transition< Reset, NotTrimming >
1606       > reactions;
1607
1608     std::set<hobject_t> in_flight;
1609     snapid_t snap_to_trim;
1610
1611     explicit Trimming(my_context ctx)
1612       : my_base(ctx),
1613         NamedState(nullptr, "Trimming") {
1614       context< SnapTrimmer >().log_enter(state_name);
1615       ceph_assert(context< SnapTrimmer >().permit_trim());
1616       ceph_assert(in_flight.empty());
1617     }
1618     void exit() {
1619       context< SnapTrimmer >().log_exit(state_name, enter_time);
1620       auto *pg = context< SnapTrimmer >().pg;
1621       pg->osd->snap_reserver.cancel_reservation(pg->get_pgid());
1622       pg->state_clear(PG_STATE_SNAPTRIM);
1623       pg->publish_stats_to_osd();
1624     }
1625     boost::statechart::result react(const KickTrim&) {
1626       return discard_event();
1627     }
1628   };
1629
1630   /* SnapTrimmerStates */
1631   struct WaitTrimTimer : boost::statechart::state< WaitTrimTimer, Trimming >, NamedState {
1632     typedef boost::mpl::list <
1633       boost::statechart::custom_reaction< SnapTrimTimerReady >
1634       > reactions;
1635     Context *wakeup = nullptr;
1636     explicit WaitTrimTimer(my_context ctx)
1637       : my_base(ctx),
1638         NamedState(nullptr, "Trimming/WaitTrimTimer") {
1639       context< SnapTrimmer >().log_enter(state_name);
1640       ceph_assert(context<Trimming>().in_flight.empty());
1641       struct OnTimer : Context {
1642         PrimaryLogPGRef pg;
1643         epoch_t epoch;
1644         OnTimer(PrimaryLogPGRef pg, epoch_t epoch) : pg(pg), epoch(epoch) {}
1645         void finish(int) override {
1646           pg->lock();
1647           if (!pg->pg_has_reset_since(epoch))
1648             pg->snap_trimmer_machine.process_event(SnapTrimTimerReady());
1649           pg->unlock();
1650         }
1651       };
1652       auto *pg = context< SnapTrimmer >().pg;
1653       float osd_snap_trim_sleep = pg->osd->osd->get_osd_snap_trim_sleep();
1654       if (osd_snap_trim_sleep > 0) {
1655         std::lock_guard l(pg->osd->sleep_lock);
1656         wakeup = pg->osd->sleep_timer.add_event_after(
1657           osd_snap_trim_sleep,
1658           new OnTimer{pg, pg->get_osdmap_epoch()});
1659       } else {
1660         post_event(SnapTrimTimerReady());
1661       }
1662     }
1663     void exit() {
1664       context< SnapTrimmer >().log_exit(state_name, enter_time);
1665       auto *pg = context< SnapTrimmer >().pg;
1666       if (wakeup) {
1667         std::lock_guard l(pg->osd->sleep_lock);
1668         pg->osd->sleep_timer.cancel_event(wakeup);
1669         wakeup = nullptr;
1670       }
1671     }
1672     boost::statechart::result react(const SnapTrimTimerReady &) {
1673       wakeup = nullptr;
1674       if (!context< SnapTrimmer >().can_trim()) {
1675         post_event(KickTrim());
1676         return transit< NotTrimming >();
1677       } else {
1678         return transit< AwaitAsyncWork >();
1679       }
1680     }
1681   };
1682
1683   struct WaitRWLock : boost::statechart::state< WaitRWLock, Trimming >, NamedState {
1684     typedef boost::mpl::list <
1685       boost::statechart::custom_reaction< TrimWriteUnblocked >
1686       > reactions;
1687     explicit WaitRWLock(my_context ctx)
1688       : my_base(ctx),
1689         NamedState(nullptr, "Trimming/WaitRWLock") {
1690       context< SnapTrimmer >().log_enter(state_name);
1691       ceph_assert(context<Trimming>().in_flight.empty());
1692     }
1693     void exit() {
1694       context< SnapTrimmer >().log_exit(state_name, enter_time);
1695     }
1696     boost::statechart::result react(const TrimWriteUnblocked&) {
1697       if (!context< SnapTrimmer >().can_trim()) {
1698         post_event(KickTrim());
1699         return transit< NotTrimming >();
1700       } else {
1701         return transit< AwaitAsyncWork >();
1702       }
1703     }
1704   };
1705
1706   struct WaitRepops : boost::statechart::state< WaitRepops, Trimming >, NamedState {
1707     typedef boost::mpl::list <
1708       boost::statechart::custom_reaction< RepopsComplete >
1709       > reactions;
1710     explicit WaitRepops(my_context ctx)
1711       : my_base(ctx),
1712         NamedState(nullptr, "Trimming/WaitRepops") {
1713       context< SnapTrimmer >().log_enter(state_name);
1714       ceph_assert(!context<Trimming>().in_flight.empty());
1715     }
1716     void exit() {
1717       context< SnapTrimmer >().log_exit(state_name, enter_time);
1718     }
1719     boost::statechart::result react(const RepopsComplete&) {
1720       if (!context< SnapTrimmer >().can_trim()) {
1721         post_event(KickTrim());
1722         return transit< NotTrimming >();
1723       } else {
1724         return transit< WaitTrimTimer >();
1725       }
1726     }
1727   };
1728
1729   struct AwaitAsyncWork : boost::statechart::state< AwaitAsyncWork, Trimming >, NamedState {
1730     typedef boost::mpl::list <
1731       boost::statechart::custom_reaction< DoSnapWork >
1732       > reactions;
1733     explicit AwaitAsyncWork(my_context ctx);
1734     void exit() {
1735       context< SnapTrimmer >().log_exit(state_name, enter_time);
1736     }
1737     boost::statechart::result react(const DoSnapWork&);
1738   };
1739
1740   struct WaitReservation : boost::statechart::state< WaitReservation, Trimming >, NamedState {
1741     /* WaitReservation is a sub-state of trimming simply so that exiting Trimming
1742      * always cancels the reservation */
1743     typedef boost::mpl::list <
1744       boost::statechart::custom_reaction< SnapTrimReserved >
1745       > reactions;
1746     struct ReservationCB : public Context {
1747       PrimaryLogPGRef pg;
1748       bool canceled;
1749       explicit ReservationCB(PrimaryLogPG *pg) : pg(pg), canceled(false) {}
1750       void finish(int) override {
1751         pg->lock();
1752         if (!canceled)
1753           pg->snap_trimmer_machine.process_event(SnapTrimReserved());
1754         pg->unlock();
1755       }
1756       void cancel() {
1757         ceph_assert(pg->is_locked());
1758         ceph_assert(!canceled);
1759         canceled = true;
1760       }
1761     };
1762     ReservationCB *pending = nullptr;
1763
1764     explicit WaitReservation(my_context ctx)
1765       : my_base(ctx),
1766         NamedState(nullptr, "Trimming/WaitReservation") {
1767       context< SnapTrimmer >().log_enter(state_name);
1768       ceph_assert(context<Trimming>().in_flight.empty());
1769       auto *pg = context< SnapTrimmer >().pg;
1770       pending = new ReservationCB(pg);
1771       pg->osd->snap_reserver.request_reservation(
1772         pg->get_pgid(),
1773         pending,
1774         0);
1775       pg->state_set(PG_STATE_SNAPTRIM_WAIT);
1776       pg->publish_stats_to_osd();
1777     }
1778     boost::statechart::result react(const SnapTrimReserved&);
1779     void exit() {
1780       context< SnapTrimmer >().log_exit(state_name, enter_time);
1781       if (pending)
1782         pending->cancel();
1783       pending = nullptr;
1784       auto *pg = context< SnapTrimmer >().pg;
1785       pg->state_clear(PG_STATE_SNAPTRIM_WAIT);
1786       pg->state_clear(PG_STATE_SNAPTRIM_ERROR);
1787       pg->publish_stats_to_osd();
1788     }
1789   };
1790
1791   struct WaitScrub : boost::statechart::state< WaitScrub, SnapTrimmer >, NamedState {
1792     typedef boost::mpl::list <
1793       boost::statechart::custom_reaction< ScrubComplete >,
1794       boost::statechart::custom_reaction< KickTrim >,
1795       boost::statechart::transition< Reset, NotTrimming >
1796       > reactions;
1797     explicit WaitScrub(my_context ctx)
1798       : my_base(ctx),
1799         NamedState(nullptr, "Trimming/WaitScrub") {
1800       context< SnapTrimmer >().log_enter(state_name);
1801     }
1802     void exit() {
1803       context< SnapTrimmer >().log_exit(state_name, enter_time);
1804     }
1805     boost::statechart::result react(const ScrubComplete&) {
1806       post_event(KickTrim());
1807       return transit< NotTrimming >();
1808     }
1809     boost::statechart::result react(const KickTrim&) {
1810       return discard_event();
1811     }
1812   };
1813
1814   struct NotTrimming : boost::statechart::state< NotTrimming, SnapTrimmer >, NamedState {
1815     typedef boost::mpl::list <
1816       boost::statechart::custom_reaction< KickTrim >,
1817       boost::statechart::transition< Reset, NotTrimming >
1818       > reactions;
1819     explicit NotTrimming(my_context ctx);
1820     void exit();
1821     boost::statechart::result react(const KickTrim&);
1822   };
1823
1824   int _verify_no_head_clones(const hobject_t& soid,
1825                              const SnapSet& ss);
1826   // return true if we're creating a local object, false for a
1827   // whiteout or no change.
1828   void maybe_create_new_object(OpContext *ctx, bool ignore_transaction=false);
1829   int _delete_oid(OpContext *ctx, bool no_whiteout, bool try_no_whiteout);
1830   int _rollback_to(OpContext *ctx, OSDOp& op);
1831   void _do_rollback_to(OpContext *ctx, ObjectContextRef rollback_to,
1832                                     OSDOp& op);
1833 public:
1834   bool is_missing_object(const hobject_t& oid) const;
1835   bool is_unreadable_object(const hobject_t &oid) const {
1836     return is_missing_object(oid) ||
1837       !recovery_state.get_missing_loc().readable_with_acting(
1838         oid, get_actingset());
1839   }
1840   void maybe_kick_recovery(const hobject_t &soid);
1841   void wait_for_unreadable_object(const hobject_t& oid, OpRequestRef op);
1842
1843   int get_manifest_ref_count(ObjectContextRef obc, std::string& fp_oid, OpRequestRef op);
1844
1845   bool check_laggy(OpRequestRef& op);
1846   bool check_laggy_requeue(OpRequestRef& op);
1847   void recheck_readable() override;
1848
1849   bool is_backfill_target(pg_shard_t osd) const {
1850     return recovery_state.is_backfill_target(osd);
1851   }
1852   const std::set<pg_shard_t> &get_backfill_targets() const {
1853     return recovery_state.get_backfill_targets();
1854   }
1855   bool is_async_recovery_target(pg_shard_t peer) const {
1856     return recovery_state.is_async_recovery_target(peer);
1857   }
1858   const std::set<pg_shard_t> &get_async_recovery_targets() const {
1859     return recovery_state.get_async_recovery_targets();
1860   }
1861   bool is_degraded_or_backfilling_object(const hobject_t& oid);
1862   bool is_degraded_on_async_recovery_target(const hobject_t& soid);
1863   void wait_for_degraded_object(const hobject_t& oid, OpRequestRef op);
1864
1865   void block_write_on_full_cache(
1866     const hobject_t& oid, OpRequestRef op);
1867   void block_for_clean(
1868     const hobject_t& oid, OpRequestRef op);
1869   void block_write_on_snap_rollback(
1870     const hobject_t& oid, ObjectContextRef obc, OpRequestRef op);
1871   void block_write_on_degraded_snap(const hobject_t& oid, OpRequestRef op);
1872
1873   bool maybe_await_blocked_head(const hobject_t &soid, OpRequestRef op);
1874   void wait_for_blocked_object(const hobject_t& soid, OpRequestRef op);
1875   void kick_object_context_blocked(ObjectContextRef obc);
1876   void requeue_op_blocked_by_object(const hobject_t &soid);
1877
1878   void maybe_force_recovery();
1879
1880   void mark_all_unfound_lost(
1881     int what,
1882     std::function<void(int,const std::string&,ceph::buffer::list&)> on_finish);
1883   eversion_t pick_newest_available(const hobject_t& oid);
1884
1885   void do_update_log_missing(
1886     OpRequestRef &op);
1887
1888   void do_update_log_missing_reply(
1889     OpRequestRef &op);
1890
1891   void plpg_on_role_change() override;
1892   void plpg_on_pool_change() override;
1893   void clear_async_reads();
1894   void on_change(ObjectStore::Transaction &t) override;
1895   void on_activate_complete() override;
1896   void on_flushed() override;
1897   void on_removal(ObjectStore::Transaction &t) override;
1898   void on_shutdown() override;
1899   bool check_failsafe_full() override;
1900   bool maybe_preempt_replica_scrub(const hobject_t& oid) override;
1901   int rep_repair_primary_object(const hobject_t& soid, OpContext *ctx);
1902
1903   // attr cache handling
1904   void setattr_maybe_cache(
1905     ObjectContextRef obc,
1906     PGTransaction *t,
1907     const std::string &key,
1908     ceph::buffer::list &val);
1909   void setattrs_maybe_cache(
1910     ObjectContextRef obc,
1911     PGTransaction *t,
1912     std::map<std::string, ceph::buffer::list, std::less<>> &attrs);
1913   void rmattr_maybe_cache(
1914     ObjectContextRef obc,
1915     PGTransaction *t,
1916     const std::string &key);
1917   int getattr_maybe_cache(
1918     ObjectContextRef obc,
1919     const std::string &key,
1920     ceph::buffer::list *val);
1921   int getattrs_maybe_cache(
1922     ObjectContextRef obc,
1923     std::map<std::string, ceph::buffer::list, std::less<>> *out);
1924
1925 public:
1926   void set_dynamic_perf_stats_queries(
1927       const std::list<OSDPerfMetricQuery> &queries)  override;
1928   void get_dynamic_perf_stats(DynamicPerfStats *stats)  override;
1929
1930 private:
1931   DynamicPerfStats m_dynamic_perf_stats;
1932 };
1933
1934 inline ostream& operator<<(ostream& out, const PrimaryLogPG::RepGather& repop)
1935 {
1936   out << "repgather(" << &repop
1937       << " " << repop.v
1938       << " rep_tid=" << repop.rep_tid
1939       << " committed?=" << repop.all_committed
1940       << " r=" << repop.r
1941       << ")";
1942   return out;
1943 }
1944
1945 inline ostream& operator<<(ostream& out,
1946                            const PrimaryLogPG::ProxyWriteOpRef& pwop)
1947 {
1948   out << "proxywrite(" << &pwop
1949       << " " << pwop->user_version
1950       << " pwop_tid=" << pwop->objecter_tid;
1951   if (pwop->ctx->op)
1952     out << " op=" << *(pwop->ctx->op->get_req());
1953   out << ")";
1954   return out;
1955 }
1956
1957 void intrusive_ptr_add_ref(PrimaryLogPG::RepGather *repop);
1958 void intrusive_ptr_release(PrimaryLogPG::RepGather *repop);
1959
1960
1961 #endif