// -*- 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 * Copyright (C) 2013 Cloudwatt * * Author: Loic Dachary * * 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. * */ #pragma once // re-include our assert to clobber boost's #include "include/assert.h" #include "osd_types.h" #include "os/ObjectStore.h" #include using namespace std; #define PGLOG_INDEXED_OBJECTS (1 << 0) #define PGLOG_INDEXED_CALLER_OPS (1 << 1) #define PGLOG_INDEXED_EXTRA_CALLER_OPS (1 << 2) #define PGLOG_INDEXED_DUPS (1 << 3) #define PGLOG_INDEXED_ALL (PGLOG_INDEXED_OBJECTS | \ PGLOG_INDEXED_CALLER_OPS | \ PGLOG_INDEXED_EXTRA_CALLER_OPS | \ PGLOG_INDEXED_DUPS) class CephContext; struct PGLog : DoutPrefixProvider { DoutPrefixProvider *prefix_provider; string gen_prefix() const override { return prefix_provider ? prefix_provider->gen_prefix() : ""; } unsigned get_subsys() const override { return prefix_provider ? prefix_provider->get_subsys() : (unsigned)ceph_subsys_osd; } CephContext *get_cct() const override { return cct; } ////////////////////////////// sub classes ////////////////////////////// struct LogEntryHandler { virtual void rollback( const pg_log_entry_t &entry) = 0; virtual void rollforward( const pg_log_entry_t &entry) = 0; virtual void trim( const pg_log_entry_t &entry) = 0; virtual void remove( const hobject_t &hoid) = 0; virtual void try_stash( const hobject_t &hoid, version_t v) = 0; virtual ~LogEntryHandler() {} }; /* Exceptions */ class read_log_and_missing_error : public buffer::error { public: explicit read_log_and_missing_error(const char *what) { snprintf(buf, sizeof(buf), "read_log_and_missing_error: %s", what); } const char *what() const throw () override { return buf; } private: char buf[512]; }; public: /** * IndexLog - adds in-memory index of the log, by oid. * plus some methods to manipulate it all. */ struct IndexedLog : public pg_log_t { mutable ceph::unordered_map objects; // ptrs into log. be careful! mutable ceph::unordered_map caller_ops; mutable ceph::unordered_multimap extra_caller_ops; mutable ceph::unordered_map dup_index; // recovery pointers list::iterator complete_to; // not inclusive of referenced item version_t last_requested = 0; // last object requested by primary // private: mutable __u16 indexed_data = 0; /** * rollback_info_trimmed_to_riter points to the first log entry <= * rollback_info_trimmed_to * * It's a reverse_iterator because rend() is a natural representation for * tail, and rbegin() works nicely for head. */ mempool::osd_pglog::list::reverse_iterator rollback_info_trimmed_to_riter; template void advance_can_rollback_to(eversion_t to, F &&f) { if (to > can_rollback_to) can_rollback_to = to; if (to > rollback_info_trimmed_to) rollback_info_trimmed_to = to; while (rollback_info_trimmed_to_riter != log.rbegin()) { --rollback_info_trimmed_to_riter; if (rollback_info_trimmed_to_riter->version > rollback_info_trimmed_to) { ++rollback_info_trimmed_to_riter; break; } f(*rollback_info_trimmed_to_riter); } } void reset_rollback_info_trimmed_to_riter() { rollback_info_trimmed_to_riter = log.rbegin(); while (rollback_info_trimmed_to_riter != log.rend() && rollback_info_trimmed_to_riter->version > rollback_info_trimmed_to) ++rollback_info_trimmed_to_riter; } // indexes objects, caller ops and extra caller ops public: IndexedLog() : complete_to(log.end()), last_requested(0), indexed_data(0), rollback_info_trimmed_to_riter(log.rbegin()) { } template IndexedLog(Args&&... args) : pg_log_t(std::forward(args)...), complete_to(log.end()), last_requested(0), indexed_data(0), rollback_info_trimmed_to_riter(log.rbegin()) { reset_rollback_info_trimmed_to_riter(); index(); } IndexedLog(const IndexedLog &rhs) : pg_log_t(rhs), complete_to(log.end()), last_requested(rhs.last_requested), indexed_data(0), rollback_info_trimmed_to_riter(log.rbegin()) { reset_rollback_info_trimmed_to_riter(); index(rhs.indexed_data); } IndexedLog &operator=(const IndexedLog &rhs) { this->~IndexedLog(); new (this) IndexedLog(rhs); return *this; } void trim_rollback_info_to(eversion_t to, LogEntryHandler *h) { advance_can_rollback_to( to, [&](pg_log_entry_t &entry) { h->trim(entry); }); } void roll_forward_to(eversion_t to, LogEntryHandler *h) { advance_can_rollback_to( to, [&](pg_log_entry_t &entry) { h->rollforward(entry); }); } void skip_can_rollback_to_to_head() { advance_can_rollback_to(head, [&](const pg_log_entry_t &entry) {}); } mempool::osd_pglog::list rewind_from_head(eversion_t newhead) { auto divergent = pg_log_t::rewind_from_head(newhead); index(); reset_rollback_info_trimmed_to_riter(); return divergent; } template void scan_log_after( const eversion_t &bound, ///< [in] scan entries > bound T &&f) const { auto iter = log.rbegin(); while (iter != log.rend() && iter->version > bound) ++iter; while (true) { if (iter == log.rbegin()) break; f(*(--iter)); } } /****/ void claim_log_and_clear_rollback_info(const pg_log_t& o) { // we must have already trimmed the old entries assert(rollback_info_trimmed_to == head); assert(rollback_info_trimmed_to_riter == log.rbegin()); *this = IndexedLog(o); skip_can_rollback_to_to_head(); index(); } void split_out_child( pg_t child_pgid, unsigned split_bits, IndexedLog *target); void zero() { // we must have already trimmed the old entries assert(rollback_info_trimmed_to == head); assert(rollback_info_trimmed_to_riter == log.rbegin()); unindex(); pg_log_t::clear(); rollback_info_trimmed_to_riter = log.rbegin(); reset_recovery_pointers(); } void clear() { skip_can_rollback_to_to_head(); zero(); } void reset_recovery_pointers() { complete_to = log.end(); last_requested = 0; } bool logged_object(const hobject_t& oid) const { if (!(indexed_data & PGLOG_INDEXED_OBJECTS)) { index_objects(); } return objects.count(oid); } bool logged_req(const osd_reqid_t &r) const { if (!(indexed_data & PGLOG_INDEXED_CALLER_OPS)) { index_caller_ops(); } if (!caller_ops.count(r)) { if (!(indexed_data & PGLOG_INDEXED_EXTRA_CALLER_OPS)) { index_extra_caller_ops(); } return extra_caller_ops.count(r); } return true; } bool get_request( const osd_reqid_t &r, eversion_t *version, version_t *user_version, int *return_code) const { assert(version); assert(user_version); assert(return_code); ceph::unordered_map::const_iterator p; if (!(indexed_data & PGLOG_INDEXED_CALLER_OPS)) { index_caller_ops(); } p = caller_ops.find(r); if (p != caller_ops.end()) { *version = p->second->version; *user_version = p->second->user_version; *return_code = p->second->return_code; return true; } // warning: we will return *a* request for this reqid, but not // necessarily the most recent. if (!(indexed_data & PGLOG_INDEXED_EXTRA_CALLER_OPS)) { index_extra_caller_ops(); } p = extra_caller_ops.find(r); if (p != extra_caller_ops.end()) { for (auto i = p->second->extra_reqids.begin(); i != p->second->extra_reqids.end(); ++i) { if (i->first == r) { *version = p->second->version; *user_version = i->second; *return_code = p->second->return_code; return true; } } assert(0 == "in extra_caller_ops but not extra_reqids"); } if (!(indexed_data & PGLOG_INDEXED_DUPS)) { index_dups(); } auto q = dup_index.find(r); if (q != dup_index.end()) { *version = q->second->version; *user_version = q->second->user_version; *return_code = q->second->return_code; return true; } return false; } /// get a (bounded) list of recent reqids for the given object void get_object_reqids(const hobject_t& oid, unsigned max, mempool::osd_pglog::vector > *pls) const { // make sure object is present at least once before we do an // O(n) search. if (!(indexed_data & PGLOG_INDEXED_OBJECTS)) { index_objects(); } if (objects.count(oid) == 0) return; for (list::const_reverse_iterator i = log.rbegin(); i != log.rend(); ++i) { if (i->soid == oid) { if (i->reqid_is_indexed()) pls->push_back(make_pair(i->reqid, i->user_version)); pls->insert(pls->end(), i->extra_reqids.begin(), i->extra_reqids.end()); if (pls->size() >= max) { if (pls->size() > max) { pls->resize(max); } return; } } } } void index(__u16 to_index = PGLOG_INDEXED_ALL) const { // if to_index is 0, no need to run any of this code, especially // loop below; this can happen with copy constructor for // IndexedLog (and indirectly through assignment operator) if (!to_index) return; if (to_index & PGLOG_INDEXED_OBJECTS) objects.clear(); if (to_index & PGLOG_INDEXED_CALLER_OPS) caller_ops.clear(); if (to_index & PGLOG_INDEXED_EXTRA_CALLER_OPS) extra_caller_ops.clear(); if (to_index & PGLOG_INDEXED_DUPS) { dup_index.clear(); for (auto& i : dups) { dup_index[i.reqid] = const_cast(&i); } } constexpr __u16 any_log_entry_index = PGLOG_INDEXED_OBJECTS | PGLOG_INDEXED_CALLER_OPS | PGLOG_INDEXED_EXTRA_CALLER_OPS; if (to_index & any_log_entry_index) { for (list::const_iterator i = log.begin(); i != log.end(); ++i) { if (to_index & PGLOG_INDEXED_OBJECTS) { if (i->object_is_indexed()) { objects[i->soid] = const_cast(&(*i)); } } if (to_index & PGLOG_INDEXED_CALLER_OPS) { if (i->reqid_is_indexed()) { caller_ops[i->reqid] = const_cast(&(*i)); } } if (to_index & PGLOG_INDEXED_EXTRA_CALLER_OPS) { for (auto j = i->extra_reqids.begin(); j != i->extra_reqids.end(); ++j) { extra_caller_ops.insert( make_pair(j->first, const_cast(&(*i)))); } } } } indexed_data |= to_index; } void index_objects() const { index(PGLOG_INDEXED_OBJECTS); } void index_caller_ops() const { index(PGLOG_INDEXED_CALLER_OPS); } void index_extra_caller_ops() const { index(PGLOG_INDEXED_EXTRA_CALLER_OPS); } void index_dups() const { index(PGLOG_INDEXED_DUPS); } void index(pg_log_entry_t& e) { if ((indexed_data & PGLOG_INDEXED_OBJECTS) && e.object_is_indexed()) { if (objects.count(e.soid) == 0 || objects[e.soid]->version < e.version) objects[e.soid] = &e; } if (indexed_data & PGLOG_INDEXED_CALLER_OPS) { // divergent merge_log indexes new before unindexing old if (e.reqid_is_indexed()) { caller_ops[e.reqid] = &e; } } if (indexed_data & PGLOG_INDEXED_EXTRA_CALLER_OPS) { for (auto j = e.extra_reqids.begin(); j != e.extra_reqids.end(); ++j) { extra_caller_ops.insert(make_pair(j->first, &e)); } } } void unindex() { objects.clear(); caller_ops.clear(); extra_caller_ops.clear(); dup_index.clear(); indexed_data = 0; } void unindex(const pg_log_entry_t& e) { // NOTE: this only works if we remove from the _tail_ of the log! if (indexed_data & PGLOG_INDEXED_OBJECTS) { if (objects.count(e.soid) && objects[e.soid]->version == e.version) objects.erase(e.soid); } if (e.reqid_is_indexed()) { if (indexed_data & PGLOG_INDEXED_CALLER_OPS) { // divergent merge_log indexes new before unindexing old if (caller_ops.count(e.reqid) && caller_ops[e.reqid] == &e) caller_ops.erase(e.reqid); } } if (indexed_data & PGLOG_INDEXED_EXTRA_CALLER_OPS) { for (auto j = e.extra_reqids.begin(); j != e.extra_reqids.end(); ++j) { for (ceph::unordered_multimap::iterator k = extra_caller_ops.find(j->first); k != extra_caller_ops.end() && k->first == j->first; ++k) { if (k->second == &e) { extra_caller_ops.erase(k); break; } } } } } void index(pg_log_dup_t& e) { if (indexed_data & PGLOG_INDEXED_DUPS) { dup_index[e.reqid] = &e; } } void unindex(const pg_log_dup_t& e) { if (indexed_data & PGLOG_INDEXED_DUPS) { auto i = dup_index.find(e.reqid); if (i != dup_index.end()) { dup_index.erase(i); } } } // actors void add(const pg_log_entry_t& e, bool applied = true) { if (!applied) { assert(get_can_rollback_to() == head); } // make sure our buffers don't pin bigger buffers e.mod_desc.trim_bl(); // add to log log.push_back(e); // riter previously pointed to the previous entry if (rollback_info_trimmed_to_riter == log.rbegin()) ++rollback_info_trimmed_to_riter; assert(e.version > head); assert(head.version == 0 || e.version.version > head.version); head = e.version; // to our index if ((indexed_data & PGLOG_INDEXED_OBJECTS) && e.object_is_indexed()) { objects[e.soid] = &(log.back()); } if (indexed_data & PGLOG_INDEXED_CALLER_OPS) { if (e.reqid_is_indexed()) { caller_ops[e.reqid] = &(log.back()); } } if (indexed_data & PGLOG_INDEXED_EXTRA_CALLER_OPS) { for (auto j = e.extra_reqids.begin(); j != e.extra_reqids.end(); ++j) { extra_caller_ops.insert(make_pair(j->first, &(log.back()))); } } if (!applied) { skip_can_rollback_to_to_head(); } } // add void trim( CephContext* cct, eversion_t s, set *trimmed, set* trimmed_dups, eversion_t *write_from_dups); ostream& print(ostream& out) const; }; // IndexedLog protected: //////////////////// data members //////////////////// pg_missing_tracker_t missing; IndexedLog log; eversion_t dirty_to; ///< must clear/writeout all keys <= dirty_to eversion_t dirty_from; ///< must clear/writeout all keys >= dirty_from eversion_t writeout_from; ///< must writout keys >= writeout_from set trimmed; ///< must clear keys in trimmed eversion_t dirty_to_dups; ///< must clear/writeout all dups <= dirty_to_dups eversion_t dirty_from_dups; ///< must clear/writeout all dups >= dirty_from_dups eversion_t write_from_dups; ///< must write keys >= write_from_dups set trimmed_dups; ///< must clear keys in trimmed_dups CephContext *cct; bool pg_log_debug; /// Log is clean on [dirty_to, dirty_from) bool touched_log; bool clear_divergent_priors; bool rebuilt_missing_with_deletes = false; void mark_dirty_to(eversion_t to) { if (to > dirty_to) dirty_to = to; } void mark_dirty_from(eversion_t from) { if (from < dirty_from) dirty_from = from; } void mark_writeout_from(eversion_t from) { if (from < writeout_from) writeout_from = from; } void mark_dirty_to_dups(eversion_t to) { if (to > dirty_to_dups) dirty_to_dups = to; } void mark_dirty_from_dups(eversion_t from) { if (from < dirty_from_dups) dirty_from_dups = from; } public: bool is_dirty() const { return !touched_log || (dirty_to != eversion_t()) || (dirty_from != eversion_t::max()) || (writeout_from != eversion_t::max()) || !(trimmed.empty()) || !missing.is_clean() || !(trimmed_dups.empty()) || (dirty_to_dups != eversion_t()) || (dirty_from_dups != eversion_t::max()) || (write_from_dups != eversion_t::max()) || rebuilt_missing_with_deletes; } void mark_log_for_rewrite() { mark_dirty_to(eversion_t::max()); mark_dirty_from(eversion_t()); mark_dirty_to_dups(eversion_t::max()); mark_dirty_from_dups(eversion_t()); touched_log = false; } bool get_rebuilt_missing_with_deletes() const { return rebuilt_missing_with_deletes; } protected: /// DEBUG set log_keys_debug; static void clear_after(set *log_keys_debug, const string &lb) { if (!log_keys_debug) return; for (set::iterator i = log_keys_debug->lower_bound(lb); i != log_keys_debug->end(); log_keys_debug->erase(i++)); } static void clear_up_to(set *log_keys_debug, const string &ub) { if (!log_keys_debug) return; for (set::iterator i = log_keys_debug->begin(); i != log_keys_debug->end() && *i < ub; log_keys_debug->erase(i++)); } void check(); void undirty() { dirty_to = eversion_t(); dirty_from = eversion_t::max(); touched_log = true; trimmed.clear(); trimmed_dups.clear(); writeout_from = eversion_t::max(); check(); missing.flush(); dirty_to_dups = eversion_t(); dirty_from_dups = eversion_t::max(); write_from_dups = eversion_t::max(); } public: // cppcheck-suppress noExplicitConstructor PGLog(CephContext *cct, DoutPrefixProvider *dpp = nullptr) : prefix_provider(dpp), dirty_from(eversion_t::max()), writeout_from(eversion_t::max()), dirty_from_dups(eversion_t::max()), write_from_dups(eversion_t::max()), cct(cct), pg_log_debug(!(cct && !(cct->_conf->osd_debug_pg_log_writeout))), touched_log(false), clear_divergent_priors(false) { } void reset_backfill(); void clear(); //////////////////// get or set missing //////////////////// const pg_missing_tracker_t& get_missing() const { return missing; } void revise_have(hobject_t oid, eversion_t have) { missing.revise_have(oid, have); } void missing_add(const hobject_t& oid, eversion_t need, eversion_t have) { missing.add(oid, need, have, false); } //////////////////// get or set log //////////////////// const IndexedLog &get_log() const { return log; } const eversion_t &get_tail() const { return log.tail; } void set_tail(eversion_t tail) { log.tail = tail; } const eversion_t &get_head() const { return log.head; } void set_head(eversion_t head) { log.head = head; } void set_last_requested(version_t last_requested) { log.last_requested = last_requested; } void index() { log.index(); } void unindex() { log.unindex(); } void add(const pg_log_entry_t& e, bool applied = true) { mark_writeout_from(e.version); log.add(e, applied); } void reset_recovery_pointers() { log.reset_recovery_pointers(); } static void clear_info_log( spg_t pgid, ObjectStore::Transaction *t); void trim( eversion_t trim_to, pg_info_t &info); void roll_forward_to( eversion_t roll_forward_to, LogEntryHandler *h) { log.roll_forward_to( roll_forward_to, h); } eversion_t get_can_rollback_to() const { return log.get_can_rollback_to(); } void roll_forward(LogEntryHandler *h) { roll_forward_to( log.head, h); } //////////////////// get or set log & missing //////////////////// void reset_backfill_claim_log(const pg_log_t &o, LogEntryHandler *h) { log.trim_rollback_info_to(log.head, h); log.claim_log_and_clear_rollback_info(o); missing.clear(); mark_dirty_to(eversion_t::max()); mark_dirty_to_dups(eversion_t::max()); } void split_into( pg_t child_pgid, unsigned split_bits, PGLog *opg_log) { log.split_out_child(child_pgid, split_bits, &opg_log->log); missing.split_into(child_pgid, split_bits, &(opg_log->missing)); opg_log->mark_dirty_to(eversion_t::max()); opg_log->mark_dirty_to_dups(eversion_t::max()); mark_dirty_to(eversion_t::max()); mark_dirty_to_dups(eversion_t::max()); if (missing.may_include_deletes) opg_log->rebuilt_missing_with_deletes = true; } void recover_got(hobject_t oid, eversion_t v, pg_info_t &info) { if (missing.is_missing(oid, v)) { missing.got(oid, v); // raise last_complete? if (missing.get_items().empty()) { log.complete_to = log.log.end(); info.last_complete = info.last_update; } while (log.complete_to != log.log.end()) { if (missing.get_items().at( missing.get_rmissing().begin()->second ).need <= log.complete_to->version) break; if (info.last_complete < log.complete_to->version) info.last_complete = log.complete_to->version; ++log.complete_to; } } assert(log.get_can_rollback_to() >= v); } void reset_complete_to(pg_info_t *info) { log.complete_to = log.log.begin(); while (!missing.get_items().empty() && log.complete_to->version < missing.get_items().at( missing.get_rmissing().begin()->second ).need) { assert(log.complete_to != log.log.end()); ++log.complete_to; } assert(log.complete_to != log.log.end()); if (log.complete_to == log.log.begin()) { if (info) info->last_complete = eversion_t(); } else { --log.complete_to; if (info) info->last_complete = log.complete_to->version; ++log.complete_to; } } void activate_not_complete(pg_info_t &info) { reset_complete_to(&info); log.last_requested = 0; } void proc_replica_log(pg_info_t &oinfo, const pg_log_t &olog, pg_missing_t& omissing, pg_shard_t from) const; void rebuild_missing_set_with_deletes(ObjectStore *store, coll_t pg_coll, const pg_info_t &info); protected: static void split_by_object( mempool::osd_pglog::list &entries, map> *out_entries) { while (!entries.empty()) { auto &out_list = (*out_entries)[entries.front().soid]; out_list.splice(out_list.end(), entries, entries.begin()); } } /** * _merge_object_divergent_entries * * There are 5 distinct cases: * 1) There is a more recent update: in this case we assume we adjusted the * store and missing during merge_log * 2) The first entry in the divergent sequence is a create. This might * either be because the object is a clone or because prior_version is * eversion_t(). In this case the object does not exist and we must * adjust missing and the store to match. * 3) We are currently missing the object. In this case, we adjust the * missing to our prior_version taking care to add a divergent_prior * if necessary * 4) We can rollback all of the entries. In this case, we do so using * the rollbacker and return -- the object does not go into missing. * 5) We cannot rollback at least 1 of the entries. In this case, we * clear the object out of the store and add a missing entry at * prior_version taking care to add a divergent_prior if * necessary. */ template static void _merge_object_divergent_entries( const IndexedLog &log, ///< [in] log to merge against const hobject_t &hoid, ///< [in] object we are merging const mempool::osd_pglog::list &orig_entries, ///< [in] entries for hoid to merge const pg_info_t &info, ///< [in] info for merging entries eversion_t olog_can_rollback_to, ///< [in] rollback boundary missing_type &missing, ///< [in,out] missing to adjust, use LogEntryHandler *rollbacker, ///< [in] optional rollbacker object const DoutPrefixProvider *dpp ///< [in] logging provider ) { ldpp_dout(dpp, 20) << __func__ << ": merging hoid " << hoid << " entries: " << orig_entries << dendl; if (hoid > info.last_backfill) { ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " after last_backfill" << dendl; return; } // entries is non-empty assert(!orig_entries.empty()); // strip out and ignore ERROR entries mempool::osd_pglog::list entries; eversion_t last; bool seen_non_error = false; for (list::const_iterator i = orig_entries.begin(); i != orig_entries.end(); ++i) { // all entries are on hoid assert(i->soid == hoid); // did not see error entries before this entry and this entry is not error // then this entry is the first non error entry bool first_non_error = ! seen_non_error && ! i->is_error(); if (! i->is_error() ) { // see a non error entry now seen_non_error = true; } // No need to check the first entry since it prior_version is unavailable // in the list // No need to check if the prior_version is the minimal version // No need to check the first non-error entry since the leading error // entries are not its prior version if (i != orig_entries.begin() && i->prior_version != eversion_t() && ! first_non_error) { // in increasing order of version assert(i->version > last); // prior_version correct (unless it is an ERROR entry) assert(i->prior_version == last || i->is_error()); } if (i->is_error()) { ldpp_dout(dpp, 20) << __func__ << ": ignoring " << *i << dendl; } else { ldpp_dout(dpp, 20) << __func__ << ": keeping " << *i << dendl; entries.push_back(*i); last = i->version; } } if (entries.empty()) { ldpp_dout(dpp, 10) << __func__ << ": no non-ERROR entries" << dendl; return; } const eversion_t prior_version = entries.begin()->prior_version; const eversion_t first_divergent_update = entries.begin()->version; const eversion_t last_divergent_update = entries.rbegin()->version; const bool object_not_in_store = !missing.is_missing(hoid) && entries.rbegin()->is_delete(); ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " prior_version: " << prior_version << " first_divergent_update: " << first_divergent_update << " last_divergent_update: " << last_divergent_update << dendl; ceph::unordered_map::const_iterator objiter = log.objects.find(hoid); if (objiter != log.objects.end() && objiter->second->version >= first_divergent_update) { /// Case 1) ldpp_dout(dpp, 10) << __func__ << ": more recent entry found: " << *objiter->second << ", already merged" << dendl; assert(objiter->second->version > last_divergent_update); // ensure missing has been updated appropriately if (objiter->second->is_update() || (missing.may_include_deletes && objiter->second->is_delete())) { assert(missing.is_missing(hoid) && missing.get_items().at(hoid).need == objiter->second->version); } else { assert(!missing.is_missing(hoid)); } missing.revise_have(hoid, eversion_t()); if (rollbacker) { if (!object_not_in_store) { rollbacker->remove(hoid); } for (auto &&i: entries) { rollbacker->trim(i); } } return; } ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid <<" has no more recent entries in log" << dendl; if (prior_version == eversion_t() || entries.front().is_clone()) { /// Case 2) ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " prior_version or op type indicates creation," << " deleting" << dendl; if (missing.is_missing(hoid)) missing.rm(missing.get_items().find(hoid)); if (rollbacker) { if (!object_not_in_store) { rollbacker->remove(hoid); } for (auto &&i: entries) { rollbacker->trim(i); } } return; } if (missing.is_missing(hoid)) { /// Case 3) ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " missing, " << missing.get_items().at(hoid) << " adjusting" << dendl; if (missing.get_items().at(hoid).have == prior_version) { ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " missing.have is prior_version " << prior_version << " removing from missing" << dendl; missing.rm(missing.get_items().find(hoid)); } else { ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " missing.have is " << missing.get_items().at(hoid).have << ", adjusting" << dendl; missing.revise_need(hoid, prior_version, false); if (prior_version <= info.log_tail) { ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " prior_version " << prior_version << " <= info.log_tail " << info.log_tail << dendl; } } if (rollbacker) { for (auto &&i: entries) { rollbacker->trim(i); } } return; } ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " must be rolled back or recovered," << " attempting to rollback" << dendl; bool can_rollback = true; /// Distinguish between 4) and 5) for (list::const_reverse_iterator i = entries.rbegin(); i != entries.rend(); ++i) { if (!i->can_rollback() || i->version <= olog_can_rollback_to) { ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " cannot rollback " << *i << dendl; can_rollback = false; break; } } if (can_rollback) { /// Case 4) for (list::const_reverse_iterator i = entries.rbegin(); i != entries.rend(); ++i) { assert(i->can_rollback() && i->version > olog_can_rollback_to); ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " rolling back " << *i << dendl; if (rollbacker) rollbacker->rollback(*i); } ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " rolled back" << dendl; return; } else { /// Case 5) ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " cannot roll back, " << "removing and adding to missing" << dendl; if (rollbacker) { if (!object_not_in_store) rollbacker->remove(hoid); for (auto &&i: entries) { rollbacker->trim(i); } } missing.add(hoid, prior_version, eversion_t(), false); if (prior_version <= info.log_tail) { ldpp_dout(dpp, 10) << __func__ << ": hoid " << hoid << " prior_version " << prior_version << " <= info.log_tail " << info.log_tail << dendl; } } } /// Merge all entries using above template static void _merge_divergent_entries( const IndexedLog &log, ///< [in] log to merge against mempool::osd_pglog::list &entries, ///< [in] entries to merge const pg_info_t &oinfo, ///< [in] info for merging entries eversion_t olog_can_rollback_to, ///< [in] rollback boundary missing_type &omissing, ///< [in,out] missing to adjust, use LogEntryHandler *rollbacker, ///< [in] optional rollbacker object const DoutPrefixProvider *dpp ///< [in] logging provider ) { map > split; split_by_object(entries, &split); for (map>::iterator i = split.begin(); i != split.end(); ++i) { _merge_object_divergent_entries( log, i->first, i->second, oinfo, olog_can_rollback_to, omissing, rollbacker, dpp); } } /** * Exists for use in TestPGLog for simply testing single divergent log * cases */ void merge_old_entry( ObjectStore::Transaction& t, const pg_log_entry_t& oe, const pg_info_t& info, LogEntryHandler *rollbacker) { mempool::osd_pglog::list entries; entries.push_back(oe); _merge_object_divergent_entries( log, oe.soid, entries, info, log.get_can_rollback_to(), missing, rollbacker, this); } bool merge_log_dups(const pg_log_t& olog); public: void rewind_divergent_log(eversion_t newhead, pg_info_t &info, LogEntryHandler *rollbacker, bool &dirty_info, bool &dirty_big_info); void merge_log(pg_info_t &oinfo, pg_log_t &olog, pg_shard_t from, pg_info_t &info, LogEntryHandler *rollbacker, bool &dirty_info, bool &dirty_big_info); template static bool append_log_entries_update_missing( const hobject_t &last_backfill, bool last_backfill_bitwise, const mempool::osd_pglog::list &entries, bool maintain_rollback, IndexedLog *log, missing_type &missing, LogEntryHandler *rollbacker, const DoutPrefixProvider *dpp) { bool invalidate_stats = false; if (log && !entries.empty()) { assert(log->head < entries.begin()->version); } for (list::const_iterator p = entries.begin(); p != entries.end(); ++p) { invalidate_stats = invalidate_stats || !p->is_error(); if (log) { ldpp_dout(dpp, 20) << "update missing, append " << *p << dendl; log->add(*p); } if (p->soid <= last_backfill && !p->is_error()) { if (missing.may_include_deletes) { missing.add_next_event(*p); } else { if (p->is_delete()) { missing.rm(p->soid, p->version); } else { missing.add_next_event(*p); } if (rollbacker) { // hack to match PG::mark_all_unfound_lost if (maintain_rollback && p->is_lost_delete() && p->can_rollback()) { rollbacker->try_stash(p->soid, p->version.version); } else if (p->is_delete()) { rollbacker->remove(p->soid); } } } } } return invalidate_stats; } bool append_new_log_entries( const hobject_t &last_backfill, bool last_backfill_bitwise, const mempool::osd_pglog::list &entries, LogEntryHandler *rollbacker) { bool invalidate_stats = append_log_entries_update_missing( last_backfill, last_backfill_bitwise, entries, true, &log, missing, rollbacker, this); if (!entries.empty()) { mark_writeout_from(entries.begin()->version); if (entries.begin()->is_lost_delete()) { // hack: since lost deletes queue recovery directly, and don't // go through activate_not_complete() again, our complete_to // iterator may still point at log.end(). Reset it to point // before these new lost_delete entries. This only occurs // when lost+delete entries are initially added, which is // always in a list of solely lost_delete entries, so it is // sufficient to check whether the first entry is a // lost_delete reset_complete_to(nullptr); } } return invalidate_stats; } void write_log_and_missing( ObjectStore::Transaction& t, map *km, const coll_t& coll, const ghobject_t &log_oid, bool require_rollback); static void write_log_and_missing_wo_missing( ObjectStore::Transaction& t, map* km, pg_log_t &log, const coll_t& coll, const ghobject_t &log_oid, map &divergent_priors, bool require_rollback); static void write_log_and_missing( ObjectStore::Transaction& t, map* km, pg_log_t &log, const coll_t& coll, const ghobject_t &log_oid, const pg_missing_tracker_t &missing, bool require_rollback, bool *rebuilt_missing_set_with_deletes); static void _write_log_and_missing_wo_missing( ObjectStore::Transaction& t, map* km, pg_log_t &log, const coll_t& coll, const ghobject_t &log_oid, map &divergent_priors, eversion_t dirty_to, eversion_t dirty_from, eversion_t writeout_from, const set &trimmed, const set &trimmed_dups, bool dirty_divergent_priors, bool touch_log, bool require_rollback, eversion_t dirty_to_dups, eversion_t dirty_from_dups, eversion_t write_from_dups, set *log_keys_debug ); static void _write_log_and_missing( ObjectStore::Transaction& t, map* km, pg_log_t &log, const coll_t& coll, const ghobject_t &log_oid, eversion_t dirty_to, eversion_t dirty_from, eversion_t writeout_from, const set &trimmed, const set &trimmed_dups, const pg_missing_tracker_t &missing, bool touch_log, bool require_rollback, bool clear_divergent_priors, eversion_t dirty_to_dups, eversion_t dirty_from_dups, eversion_t write_from_dups, bool *rebuilt_missing_with_deletes, set *log_keys_debug ); void read_log_and_missing( ObjectStore *store, coll_t pg_coll, coll_t log_coll, ghobject_t log_oid, const pg_info_t &info, bool force_rebuild_missing, ostringstream &oss, bool tolerate_divergent_missing_log, bool debug_verify_stored_missing = false ) { return read_log_and_missing( store, pg_coll, log_coll, log_oid, info, log, missing, force_rebuild_missing, oss, tolerate_divergent_missing_log, &clear_divergent_priors, this, (pg_log_debug ? &log_keys_debug : nullptr), debug_verify_stored_missing); } template static void read_log_and_missing( ObjectStore *store, coll_t pg_coll, coll_t log_coll, ghobject_t log_oid, const pg_info_t &info, IndexedLog &log, missing_type &missing, bool force_rebuild_missing, ostringstream &oss, bool tolerate_divergent_missing_log, bool *clear_divergent_priors = nullptr, const DoutPrefixProvider *dpp = nullptr, set *log_keys_debug = nullptr, bool debug_verify_stored_missing = false ) { ldpp_dout(dpp, 20) << "read_log_and_missing coll " << pg_coll << " log_oid " << log_oid << dendl; // legacy? struct stat st; int r = store->stat(log_coll, log_oid, &st); assert(r == 0); assert(st.st_size == 0); // will get overridden below if it had been recorded eversion_t on_disk_can_rollback_to = info.last_update; eversion_t on_disk_rollback_info_trimmed_to = eversion_t(); ObjectMap::ObjectMapIterator p = store->get_omap_iterator(log_coll, log_oid); map divergent_priors; bool must_rebuild = force_rebuild_missing; missing.may_include_deletes = false; list entries; list dups; if (p) { for (p->seek_to_first(); p->valid() ; p->next(false)) { // non-log pgmeta_oid keys are prefixed with _; skip those if (p->key()[0] == '_') continue; bufferlist bl = p->value();//Copy bufferlist before creating iterator bufferlist::iterator bp = bl.begin(); if (p->key() == "divergent_priors") { ::decode(divergent_priors, bp); ldpp_dout(dpp, 20) << "read_log_and_missing " << divergent_priors.size() << " divergent_priors" << dendl; must_rebuild = true; debug_verify_stored_missing = false; } else if (p->key() == "can_rollback_to") { ::decode(on_disk_can_rollback_to, bp); } else if (p->key() == "rollback_info_trimmed_to") { ::decode(on_disk_rollback_info_trimmed_to, bp); } else if (p->key() == "may_include_deletes_in_missing") { missing.may_include_deletes = true; } else if (p->key().substr(0, 7) == string("missing")) { hobject_t oid; pg_missing_item item; ::decode(oid, bp); ::decode(item, bp); if (item.is_delete()) { assert(missing.may_include_deletes); } missing.add(oid, item.need, item.have, item.is_delete()); } else if (p->key().substr(0, 4) == string("dup_")) { pg_log_dup_t dup; ::decode(dup, bp); if (!dups.empty()) { assert(dups.back().version < dup.version); } dups.push_back(dup); } else { pg_log_entry_t e; e.decode_with_checksum(bp); ldpp_dout(dpp, 20) << "read_log_and_missing " << e << dendl; if (!entries.empty()) { pg_log_entry_t last_e(entries.back()); assert(last_e.version.version < e.version.version); assert(last_e.version.epoch <= e.version.epoch); } entries.push_back(e); if (log_keys_debug) log_keys_debug->insert(e.get_key_name()); } } } log = IndexedLog( info.last_update, info.log_tail, on_disk_can_rollback_to, on_disk_rollback_info_trimmed_to, std::move(entries), std::move(dups)); if (must_rebuild || debug_verify_stored_missing) { // build missing if (debug_verify_stored_missing || info.last_complete < info.last_update) { ldpp_dout(dpp, 10) << "read_log_and_missing checking for missing items over interval (" << info.last_complete << "," << info.last_update << "]" << dendl; set did; set checked; set skipped; for (list::reverse_iterator i = log.log.rbegin(); i != log.log.rend(); ++i) { if (!debug_verify_stored_missing && i->version <= info.last_complete) break; if (i->soid > info.last_backfill) continue; if (i->is_error()) continue; if (did.count(i->soid)) continue; did.insert(i->soid); if (!missing.may_include_deletes && i->is_delete()) continue; bufferlist bv; int r = store->getattr( pg_coll, ghobject_t(i->soid, ghobject_t::NO_GEN, info.pgid.shard), OI_ATTR, bv); if (r >= 0) { object_info_t oi(bv); if (oi.version < i->version) { ldpp_dout(dpp, 15) << "read_log_and_missing missing " << *i << " (have " << oi.version << ")" << dendl; if (debug_verify_stored_missing) { auto miter = missing.get_items().find(i->soid); assert(miter != missing.get_items().end()); assert(miter->second.need == i->version); // the 'have' version is reset if an object is deleted, // then created again assert(miter->second.have == oi.version || miter->second.have == eversion_t()); checked.insert(i->soid); } else { missing.add(i->soid, i->version, oi.version, i->is_delete()); } } } else { ldpp_dout(dpp, 15) << "read_log_and_missing missing " << *i << dendl; if (debug_verify_stored_missing) { auto miter = missing.get_items().find(i->soid); if (i->is_delete()) { assert(miter == missing.get_items().end() || (miter->second.need == i->version && miter->second.have == eversion_t())); } else { assert(miter != missing.get_items().end()); assert(miter->second.need == i->version); assert(miter->second.have == eversion_t()); } checked.insert(i->soid); } else { missing.add(i->soid, i->version, eversion_t(), i->is_delete()); } } } if (debug_verify_stored_missing) { for (auto &&i: missing.get_items()) { if (checked.count(i.first)) continue; if (i.first > info.last_backfill) { ldpp_dout(dpp, -1) << __func__ << ": invalid missing set entry " << "found before last_backfill: " << i.first << " " << i.second << " last_backfill = " << info.last_backfill << dendl; assert(0 == "invalid missing set entry found"); } bufferlist bv; int r = store->getattr( pg_coll, ghobject_t(i.first, ghobject_t::NO_GEN, info.pgid.shard), OI_ATTR, bv); if (r >= 0) { object_info_t oi(bv); assert(oi.version == i.second.have); } else { assert(i.second.is_delete() || eversion_t() == i.second.have); } } } else { assert(must_rebuild); for (map::reverse_iterator i = divergent_priors.rbegin(); i != divergent_priors.rend(); ++i) { if (i->first <= info.last_complete) break; if (i->second > info.last_backfill) continue; if (did.count(i->second)) continue; did.insert(i->second); bufferlist bv; int r = store->getattr( pg_coll, ghobject_t(i->second, ghobject_t::NO_GEN, info.pgid.shard), OI_ATTR, bv); if (r >= 0) { object_info_t oi(bv); /** * 1) we see this entry in the divergent priors mapping * 2) we didn't see an entry for this object in the log * * From 1 & 2 we know that either the object does not exist * or it is at the version specified in the divergent_priors * map since the object would have been deleted atomically * with the addition of the divergent_priors entry, an older * version would not have been recovered, and a newer version * would show up in the log above. */ /** * Unfortunately the assessment above is incorrect because of * http://tracker.ceph.com/issues/17916 (we were incorrectly * not removing the divergent_priors set from disk state!), * so let's check that. */ if (oi.version > i->first && tolerate_divergent_missing_log) { ldpp_dout(dpp, 0) << "read_log divergent_priors entry (" << *i << ") inconsistent with disk state (" << oi << "), assuming it is tracker.ceph.com/issues/17916" << dendl; } else { assert(oi.version == i->first); } } else { ldpp_dout(dpp, 15) << "read_log_and_missing missing " << *i << dendl; missing.add(i->second, i->first, eversion_t(), false); } } } if (clear_divergent_priors) (*clear_divergent_priors) = true; } } if (!must_rebuild) { if (clear_divergent_priors) (*clear_divergent_priors) = false; missing.flush(); } ldpp_dout(dpp, 10) << "read_log_and_missing done" << dendl; } // static read_log_and_missing }; // struct PGLog