// Matrix Construct // // Copyright (C) Matrix Construct Developers, Authors & Contributors // Copyright (C) 2016-2018 Jason Volk // // Permission to use, copy, modify, and/or distribute this software for any // purpose with or without fee is hereby granted, provided that the above // copyright notice and this permission notice is present in all copies. The // full license for this software is available in the LICENSE file. #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // ircd::db interfaces requiring complete RocksDB (frontside). #include #include #include #include #include #include #include #include #include #include // RocksDB embedding environment callback interfaces (backside). #include #include #include #include #include #include #include #include // Internal utility interface for this definition file. #include "db.h" // RocksDB port linktime-overriding interfaces (experimental). #ifdef IRCD_DB_PORT #include #endif // // Misc / General linkages // /// Dedicated logging facility for the database subsystem decltype(ircd::db::log) ircd::db::log { "db", 'D' }; /// Dedicated logging facility for rocksdb's log callbacks decltype(ircd::db::rog) ircd::db::rog { "rdb", 'R' }; ircd::conf::item ircd::db::request_pool_stack_size { { "name", "ircd.db.request_pool.stack_size" }, { "default", long(128_KiB) }, }; ircd::conf::item ircd::db::request_pool_size { { { "name", "ircd.db.request_pool.size" }, { "default", 32L }, }, [] { request.set(size_t(request_pool_size)); } }; /// Concurrent request pool. Requests to seek may be executed on this /// pool in cases where a single context would find it advantageous. /// Some examples are a db::row seek, or asynchronous prefetching. /// /// The number of workers in this pool should upper bound at the /// number of concurrent AIO requests which are effective on this /// system. This is a static pool shared by all databases. decltype(ircd::db::request) ircd::db::request { "db req", size_t(request_pool_stack_size), 0, // don't prespawn because this is static }; /// This mutex is necessary to serialize entry into rocksdb's write impl /// otherwise there's a risk of a deadlock if their internal pthread /// mutexes are contended. This is because a few parts of rocksdb are /// incorrectly using std::mutex directly when they ought to be using their /// rocksdb::port wrapper. decltype(ircd::db::write_mutex) ircd::db::write_mutex; /////////////////////////////////////////////////////////////////////////////// // // init // namespace ircd::db { static std::string direct_io_test_file_path(); static void init_test_direct_io(); static void init_compressions(); static void init_directory(); } decltype(ircd::db::version) ircd::db::version { ROCKSDB_MAJOR, ROCKSDB_MINOR, ROCKSDB_PATCH }; char ircd_db_version_str_buf[64]; decltype(ircd::db::version_str) ircd::db::version_str ( ircd_db_version_str_buf, ::snprintf(ircd_db_version_str_buf, sizeof(ircd_db_version_str_buf), "%u.%u.%u", version[0], version[1], version[2]) ); decltype(ircd::db::abi_version) ircd::db::abi_version { //TODO: Get lib version. 0, 0, 0, }; char ircd_db_abi_version_str_buf[64]; decltype(ircd::db::abi_version_str) ircd::db::abi_version_str ( ircd_db_abi_version_str_buf, ::snprintf(ircd_db_abi_version_str_buf, sizeof(ircd_db_abi_version_str_buf), "%u.%u.%u", abi_version[0], abi_version[1], abi_version[2]) ); // // init::init // ircd::db::init::init() { init_compressions(); init_directory(); init_test_direct_io(); request.add(request_pool_size); } ircd::db::init::~init() noexcept { if(request.active()) log::warning { log, "Terminating %zu active of %zu client request contexts; %zu pending; %zu queued", request.active(), request.size(), request.pending(), request.queued() }; request.terminate(); log::debug { log, "Waiting for %zu active of %zu client request contexts; %zu pending; %zu queued", request.active(), request.size(), request.pending(), request.queued() }; request.join(); log::debug { log, "All contexts joined; all requests are clear." }; } void ircd::db::init_directory() try { const auto dbdir { fs::get(fs::DB) }; if(fs::mkdir(dbdir)) log::notice { log, "Created new database directory at `%s'", dbdir }; else log::info { log, "Using database directory at `%s'", dbdir }; } catch(const fs::error &e) { log::error { log, "Cannot start database system: %s", e.what() }; if(ircd::debugmode) throw; } void ircd::db::init_test_direct_io() try { const auto test_file_path { direct_io_test_file_path() }; if(fs::support::direct_io(test_file_path)) log::debug { log, "Detected Direct-IO works by opening test file at `%s'", test_file_path }; else log::warning { log, "Direct-IO is not supported in the database directory `%s'" "; Concurrent database queries will not be possible.", fs::get(fs::DB) }; } catch(const std::exception &e) { log::error { log, "Failed to test if Direct-IO possible with test file `%s'" "; Concurrent database queries will not be possible :%s", direct_io_test_file_path(), e.what() }; } std::string ircd::db::direct_io_test_file_path() { const auto dbdir { fs::get(fs::DB) }; const std::string parts[] { dbdir, "SUPPORTS_DIRECT_IO"s }; return fs::make_path(parts); } decltype(ircd::db::compressions) ircd::db::compressions; void ircd::db::init_compressions() { auto supported { rocksdb::GetSupportedCompressions() }; for(const rocksdb::CompressionType &type : supported) { auto &string(compressions.at(uint(type))); throw_on_error { rocksdb::GetStringFromCompressionType(&string, type) }; } if(supported.empty()) log::warning { "No compression libraries have been linked with the DB." " This is probably not what you want." }; } /////////////////////////////////////////////////////////////////////////////// // // database // /// Conf item toggles if full database checksum verification should occur /// when any database is opened. decltype(ircd::db::open_check) ircd::db::open_check { { "name", "ircd.db.open.check" }, { "default", false }, { "persist", false }, }; /// Conf item determines the recovery mode to use when opening any database. /// /// "absolute" - The default and is the same for an empty value. This means /// any database corruptions are treated as an error on open and an exception /// is thrown with nothing else done. /// /// "point" - The database is rolled back to before any corruption. This will /// lose some of the latest data last committed, but will open the database /// and continue normally thereafter. /// /// "skip" - The corrupted areas are skipped over and the database continues /// normally with just those assets missing. This option is dangerous because /// the database continues in a logically incoherent state which is only ok /// for very specific applications. /// /// !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! /// /// IRCd's applications are NOT tolerant of a skip of recovery. /// NEVER USE "skip" RECOVERY MODE. /// /// !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! /// decltype(ircd::db::open_recover) ircd::db::open_recover { { "name", "ircd.db.open.recover" }, { "default", "absolute" }, { "persist", false }, }; void ircd::db::sync(database &d) { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{write_mutex}; log::debug { log, "'%s': @%lu SYNC WAL", name(d), sequence(d) }; throw_on_error { d.d->SyncWAL() }; } /// Flushes all columns. Note that if blocking=true, blocking may occur for /// each column individually. void ircd::db::flush(database &d, const bool &sync) { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{write_mutex}; log::debug { log, "'%s': @%lu FLUSH WAL", name(d), sequence(d) }; throw_on_error { d.d->FlushWAL(sync) }; } /// Moves memory structures to SST files for all columns. This doesn't /// necessarily sort anything that wasn't previously sorted, but it may create /// new SST files and shouldn't be confused with a typical fflush(). /// Note that if blocking=true, blocking may occur for each column individually. void ircd::db::sort(database &d, const bool &blocking) { for(const auto &c : d.columns) { db::column column{*c}; db::sort(column, blocking); } } void ircd::db::compact(database &d, const compactor &cb) { static const std::pair range { {}, {} }; for(const auto &c : d.columns) { db::column column{*c}; compact(column, range, -1, cb); compact(column, -1, cb); } } void ircd::db::check(database &d) { assert(d.d); const ctx::uninterruptible::nothrow ui; throw_on_error { d.d->VerifyChecksum() }; } void ircd::db::resume(database &d) { assert(d.d); const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{write_mutex}; const auto errors { db::errors(d) }; log::debug { log, "'%s': Attempting to resume from %zu errors @%lu", name(d), errors.size(), sequence(d) }; throw_on_error { d.d->Resume() }; d.errors.clear(); log::info { log, "'%s': Resumed normal operation at sequence number %lu; cleared %zu errors", name(d), sequence(d), errors.size() }; } /// Writes a snapshot of this database to the directory specified. The /// snapshot consists of hardlinks to the bulk data files of this db, but /// copies the other stuff that usually gets corrupted. The directory can /// then be opened as its own database either read-only or read-write. /// Incremental backups and rollbacks can begin from this interface. Note /// this may be an expensive blocking operation. uint64_t ircd::db::checkpoint(database &d) { if(!d.checkpointer) throw error { "Checkpointing is not available for db(%p) '%s", &d, name(d) }; const std::lock_guard lock{write_mutex}; const ctx::uninterruptible::nothrow ui; const auto seqnum { sequence(d) }; const std::string dir { db::path(name(d), seqnum) }; throw_on_error { d.checkpointer->CreateCheckpoint(dir, 0) }; log::debug { log, "'%s': Checkpoint at sequence %lu in `%s' complete", name(d), seqnum, dir }; return seqnum; } /// This wraps RocksDB's "File Deletions" which means after RocksDB /// compresses some file it then destroys the uncompressed version; /// setting this to false will disable that and retain both versions. /// This is useful when a direct reference is being manually held by /// us into the uncompressed version which must remain valid. void ircd::db::fdeletions(database &d, const bool &enable, const bool &force) { const std::lock_guard lock{write_mutex}; const ctx::uninterruptible::nothrow ui; if(enable) throw_on_error { d.d->EnableFileDeletions(force) }; else throw_on_error { d.d->DisableFileDeletions() }; } void ircd::db::setopt(database &d, const string_view &key, const string_view &val) { const std::unordered_map options { { std::string{key}, std::string{val} } }; const std::lock_guard lock{write_mutex}; const ctx::uninterruptible::nothrow ui; throw_on_error { d.d->SetDBOptions(options) }; } size_t ircd::db::bytes(const database &d) { return std::accumulate(begin(d.columns), end(d.columns), size_t(0), [] (auto ret, const auto &colptr) { db::column c{*colptr}; return ret += db::bytes(c); }); } size_t ircd::db::file_count(const database &d) { return std::accumulate(begin(d.columns), end(d.columns), size_t(0), [] (auto ret, const auto &colptr) { db::column c{*colptr}; return ret += db::file_count(c); }); } /// Get the list of WAL (Write Ahead Log) files. std::vector ircd::db::wals(const database &cd) { auto &d { const_cast(cd) }; std::vector> vec; throw_on_error { d.d->GetSortedWalFiles(vec) }; std::vector ret(vec.size()); std::transform(begin(vec), end(vec), begin(ret), [] (const auto &file) { return file->PathName(); }); return ret; } /// Get the live file list for db; see overlord documentation. std::vector ircd::db::files(const database &d) { uint64_t ignored; return files(d, ignored); } /// Get the live file list for database relative to the database's directory. /// One of the files is a manifest file which is over-allocated and its used /// size is returned in the integer passed to the `msz` argument. /// /// This list may not be completely up to date. The reliable way to get the /// most current list is to flush all columns first and ensure no database /// activity took place between the flushing and this query. std::vector ircd::db::files(const database &cd, uint64_t &msz) { std::vector ret; auto &d(const_cast(cd)); const ctx::uninterruptible::nothrow ui; throw_on_error { d.d->GetLiveFiles(ret, &msz, false) }; return ret; } const std::vector & ircd::db::errors(const database &d) { return d.errors; } uint64_t ircd::db::sequence(const database &cd) { database &d(const_cast(cd)); return d.d->GetLatestSequenceNumber(); } rocksdb::Cache * ircd::db::cache(database &d) { return d.row_cache.get(); } const rocksdb::Cache * ircd::db::cache(const database &d) { return d.row_cache.get(); } template<> ircd::db::prop_int ircd::db::property(const database &cd, const string_view &name) { uint64_t ret(0); database &d(const_cast(cd)); const ctx::uninterruptible::nothrow ui; if(!d.d->GetAggregatedIntProperty(slice(name), &ret)) throw not_found { "property '%s' for all columns in '%s' not found or not an integer.", name, db::name(d) }; return ret; } std::shared_ptr ircd::db::shared_from(database::column &column) { return column.shared_from_this(); } std::shared_ptr ircd::db::shared_from(const database::column &column) { return column.shared_from_this(); } const std::string & ircd::db::uuid(const database &d) { return d.uuid; } const std::string & ircd::db::name(const database &d) { return d.name; } // // database // namespace ircd::db { extern const description default_description; } // Instance list linkage template<> decltype(ircd::util::instance_list::list) ircd::util::instance_list::list {}; decltype(ircd::db::default_description) ircd::db::default_description { /// Requirement of RocksDB going back to LevelDB. This column must /// always exist in all descriptions and probably should be at idx[0]. { "default" } }; ircd::db::database & ircd::db::database::get(column &column) { assert(column.d); return *column.d; } const ircd::db::database & ircd::db::database::get(const column &column) { assert(column.d); return *column.d; } ircd::db::database & ircd::db::database::get(const string_view &name) { const auto pair { namepoint(name) }; return get(pair.first, pair.second); } ircd::db::database & ircd::db::database::get(const string_view &name, const uint64_t &checkpoint) { auto *const &d { get(std::nothrow, name, checkpoint) }; if(likely(d)) return *d; throw checkpoint == uint64_t(-1)? std::out_of_range{"No database with that name exists"}: std::out_of_range{"No database with that name at that checkpoint exists"}; } ircd::db::database * ircd::db::database::get(std::nothrow_t, const string_view &name) { const auto pair { namepoint(name) }; return get(std::nothrow, pair.first, pair.second); } ircd::db::database * ircd::db::database::get(std::nothrow_t, const string_view &name, const uint64_t &checkpoint) { for(auto *const &d : list) if(name == d->name) if(checkpoint == uint64_t(-1) || checkpoint == d->checkpoint) return d; return nullptr; } // // database::database // ircd::db::database::database(const string_view &name, std::string optstr) :database { name, std::move(optstr), default_description } { } ircd::db::database::database(const string_view &name, std::string optstr, description description) :database { namepoint(name).first, namepoint(name).second, std::move(optstr), std::move(description) } { } ircd::db::database::database(const string_view &name, const uint64_t &checkpoint, std::string optstr, description description) try :name { namepoint(name).first } ,checkpoint { // a -1 may have been generated by the db::namepoint() util when the user // supplied just a name without a checkpoint. In the context of database // opening/creation -1 just defaults to 0. checkpoint == uint64_t(-1)? 0 : checkpoint } ,path { db::path(this->name, this->checkpoint) } ,optstr { std::move(optstr) } ,fsck { false } ,read_only { false } ,env { std::make_shared(this) } ,stats { std::make_shared(this) } ,logger { std::make_shared(this) } ,events { std::make_shared(this) } ,mergeop { std::make_shared(this) } ,ssts { // note: the sst file manager cannot be used for now because it will spawn // note: a pthread internally in rocksdb which does not use our callbacks // note: we gave in the supplied env. we really don't want that. //rocksdb::NewSstFileManager(env.get(), logger, {}, 0, true, nullptr, 0.05) } ,row_cache { std::make_shared(this, this->stats, 16_MiB) } ,descriptors { std::move(description) } ,opts{[this] { auto opts { std::make_unique(make_dbopts(this->optstr, &this->optstr, &read_only, &fsck)) }; // Setup sundry opts->create_if_missing = true; opts->create_missing_column_families = true; // Uses thread_local counters in rocksdb and probably useless for ircd::ctx. opts->enable_thread_tracking = false; // MUST be 0 or std::threads are spawned in rocksdb. opts->max_file_opening_threads = 0; // TODO: We should hint rocksdb with a harder value so it doesn't // potentially eat up all our fd's. opts->max_open_files = -1; //ircd::info::rlimit_nofile / 4; // These values are known to not cause any internal rocksdb issues for us, // but perhaps making them more aggressive can be looked into. opts->max_background_compactions = 1; opts->max_background_flushes = 1; opts->max_background_jobs = 2; // MUST be 1 (no subcompactions) or rocksdb spawns internal std::thread. opts->max_subcompactions = 1; // Disable noise opts->stats_dump_period_sec = 0; // Disables the timer to delete unused files; this operation occurs // instead with our compaction operations so we don't need to complicate. opts->delete_obsolete_files_period_micros = 0; // These values prevent codepaths from being taken in rocksdb which may // introduce issues for ircd::ctx. We should still fully investigate // if any of these features can safely be used. opts->allow_concurrent_memtable_write = false; opts->enable_write_thread_adaptive_yield = false; opts->enable_pipelined_write = false; opts->write_thread_max_yield_usec = 0; opts->write_thread_slow_yield_usec = 0; // Detect if O_DIRECT is possible if db::init left a file in the // database directory claiming such. User can force no direct io // with program option at startup (i.e -nodirect). opts->use_direct_reads = bool(fs::fd::opts::direct_io_enable)? fs::exists(direct_io_test_file_path()): false; // Use the determined direct io value for writes as well. opts->use_direct_io_for_flush_and_compaction = opts->use_direct_reads; // Doesn't appear to be in effect when direct io is used. Not supported by // all filesystems so disabled for now. // TODO: use fs::support::fallocate() test similar to direct_io_test_file. opts->allow_fallocate = false; #ifdef RB_DEBUG opts->dump_malloc_stats = true; #endif // Default corruption tolerance is zero-tolerance; db fails to open with // error by default to inform the user. The rest of the options are // various relaxations for how to proceed. opts->wal_recovery_mode = rocksdb::WALRecoveryMode::kAbsoluteConsistency; // When corrupted after crash, the DB is rolled back before the first // corruption and erases everything after it, giving a consistent // state up at that point, though losing some recent data. if(string_view(open_recover) == "point") opts->wal_recovery_mode = rocksdb::WALRecoveryMode::kPointInTimeRecovery; // Skipping corrupted records will create gaps in the DB timeline where the // application (like a matrix timeline) cannot tolerate the unexpected gap. if(string_view(open_recover) == "skip") opts->wal_recovery_mode = rocksdb::WALRecoveryMode::kSkipAnyCorruptedRecords; // Tolerating corrupted records is very last-ditch for getting the database to // open in a catastrophe. We have no use for this option but should use it for //TODO: emergency salvage-mode. if(string_view(open_recover) == "tolerate") opts->wal_recovery_mode = rocksdb::WALRecoveryMode::kTolerateCorruptedTailRecords; // This prevents the creation of additional files when the DB first opens. // It should be set to false once a comprehensive compaction system is // implemented which can reap those files. Otherwise we'll run out of fd's. opts->avoid_flush_during_recovery = true; // Setup env opts->env = env.get(); // Setup SST file mgmt opts->sst_file_manager = this->ssts; // Setup logging logger->SetInfoLogLevel(ircd::debugmode? rocksdb::DEBUG_LEVEL : rocksdb::WARN_LEVEL); opts->info_log_level = logger->GetInfoLogLevel(); opts->info_log = logger; // Setup event and statistics callbacks opts->listeners.emplace_back(this->events); // Setup histogram collecting //this->stats->stats_level_ = rocksdb::kAll; this->stats->stats_level_ = rocksdb::kExceptTimeForMutex; opts->statistics = this->stats; // Setup performance metric options //rocksdb::SetPerfLevel(rocksdb::PerfLevel::kDisable); // Setup row cache. opts->row_cache = this->row_cache; return opts; }()} ,column_names{[this] { // Existing columns at path. If any are left the descriptor set did not // describe all of the columns found in the database at path. const auto required { db::column_names(path, *opts) }; // As we find descriptors for all of the columns on the disk we'll // remove their names from this set. Anything remaining is undescribed // and that's a fatal error. std::set existing { begin(required), end(required) }; // The names of the columns extracted from the descriptor set decltype(this->column_names) ret; for(auto &descriptor : descriptors) { // Deprecated columns which have already been dropped won't appear // in the existing (required) list. We don't need to construct those. if(!existing.count(descriptor.name) && descriptor.drop) continue; // Construct the column instance and indicate that we have a description // for it by removing it from existing. ret.emplace(descriptor.name, std::make_shared(*this, descriptor)); existing.erase(descriptor.name); } for(const auto &remain : existing) throw error { "Failed to describe existing column '%s' (and %zd others...)", remain, existing.size() - 1 }; return ret; }()} ,d{[this] { std::vector handles; // filled by DB::Open() std::vector columns(this->column_names.size()); std::transform(begin(this->column_names), end(this->column_names), begin(columns), [] (const auto &pair) { const auto &column(*pair.second); return static_cast(column); }); // NOTE: rocksdb sez RepairDB is broken; can't use now if(fsck && fs::is_dir(path)) { const ctx::uninterruptible ui; log::notice { log, "Checking database @ `%s' columns[%zu]", path, columns.size() }; throw_on_error { rocksdb::RepairDB(path, *opts, columns) }; log::info { log, "Database @ `%s' check complete", path }; } // If the directory does not exist, though rocksdb will create it, we can // avoid scaring the user with an error log message if we just do that.. if(opts->create_if_missing && !fs::is_dir(path)) fs::mkdir(path); // Announce attempt before usual point where exceptions are thrown const ctx::uninterruptible ui; log::info { log, "Opening database \"%s\" @ `%s' with %zu columns...", this->name, path, columns.size() }; // Open DB into ptr rocksdb::DB *ptr; if(read_only) throw_on_error { rocksdb::DB::OpenForReadOnly(*opts, path, columns, &handles, &ptr) }; else throw_on_error { rocksdb::DB::Open(*opts, path, columns, &handles, &ptr) }; std::unique_ptr ret { ptr }; // Set the handles. We can't throw here so we just log an error. for(const auto &handle : handles) try { this->column_names.at(handle->GetName())->handle.reset(handle); } catch(const std::exception &e) { log::critical { "'%s': Error finding described handle '%s' which RocksDB opened :%s", this->name, handle->GetName(), e.what() }; } return ret; }()} ,column_index{[this] { size_t size{0}; for(const auto &p : column_names) { const auto &column(*p.second); if(db::id(column) + 1 > size) size = db::id(column) + 1; } // This may have some gaps containing nullptrs where a CFID is unused. decltype(this->column_index) ret(size); for(const auto &p : column_names) { const auto &colptr(p.second); ret.at(db::id(*colptr)) = colptr; } return ret; }()} ,columns{[this] { // Skip the gaps in the column_index vector to make the columns list // only contain active column instances. decltype(this->columns) ret; for(const auto &ptr : this->column_index) if(ptr) ret.emplace_back(ptr); return ret; }()} ,uuid{[this] { const ctx::uninterruptible ui; std::string ret; throw_on_error { d->GetDbIdentity(ret) }; return ret; }()} ,checkpointer{[this] { const ctx::uninterruptible ui; rocksdb::Checkpoint *checkpointer{nullptr}; throw_on_error { rocksdb::Checkpoint::Create(this->d.get(), &checkpointer) }; return checkpointer; }()} { // Conduct drops from schema changes. The database must be fully opened // as if they were not dropped first, then we conduct the drop operation // here. The drop operation has no effects until the database is next // closed; the dropped columns will still work during this instance. for(const auto &colptr : columns) if(describe(*colptr).drop) db::drop(*colptr); // Database integrity check branch. if(bool(open_check)) { log::notice { log, "'%s': Verifying database integrity. This may take several minutes...", this->name }; const ctx::uninterruptible ui; check(*this); } log::info { log, "'%s': Opened database @ `%s' with %zu columns at sequence number %lu.", this->name, path, columns.size(), d->GetLatestSequenceNumber() }; } catch(const corruption &e) { throw corruption { "Corruption for '%s' (%s). Try restarting with the -pitrecdb command line option", this->name, e.what() }; } catch(const std::exception &e) { throw error { "Failed to open db '%s': %s", this->name, e.what() }; } ircd::db::database::~database() noexcept try { const ctx::uninterruptible::nothrow ui; log::info { log, "'%s': closing database @ `%s'...", name, path }; rocksdb::CancelAllBackgroundWork(d.get(), true); // true = blocking log::debug { log, "'%s': background_errors: %lu; flushing...", name, property(*this, rocksdb::DB::Properties::kBackgroundErrors) }; flush(*this); log::debug { log, "'%s': flushed; closing columns...", name }; this->checkpointer.reset(nullptr); this->column_names.clear(); this->column_index.clear(); this->columns.clear(); log::debug { log, "'%s': closed columns; synchronizing...", name }; sync(*this); log::debug { log, "'%s': synchronized with hardware.", name }; const auto sequence { d->GetLatestSequenceNumber() }; throw_on_error { d->Close() }; log::info { log, "'%s': closed database @ `%s' at sequence number %lu.", name, path, sequence }; } catch(const std::exception &e) { log::error { log, "'%s': Error closing database(%p) :%s", name, this, e.what() }; return; } catch(...) { log::critical { log, "'%s': Unknown error closing database(%p)", name, this }; return; } void ircd::db::database::operator()(const delta &delta) { operator()(sopts{}, delta); } void ircd::db::database::operator()(const std::initializer_list &deltas) { operator()(sopts{}, deltas); } void ircd::db::database::operator()(const delta *const &begin, const delta *const &end) { operator()(sopts{}, begin, end); } void ircd::db::database::operator()(const sopts &sopts, const delta &delta) { operator()(sopts, &delta, &delta + 1); } void ircd::db::database::operator()(const sopts &sopts, const std::initializer_list &deltas) { operator()(sopts, std::begin(deltas), std::end(deltas)); } void ircd::db::database::operator()(const sopts &sopts, const delta *const &begin, const delta *const &end) { rocksdb::WriteBatch batch; std::for_each(begin, end, [this, &batch] (const delta &delta) { const auto &op(std::get(delta)); const auto &col(std::get<1>(delta)); const auto &key(std::get<2>(delta)); const auto &val(std::get<3>(delta)); db::column column(operator[](col)); append(batch, column, db::column::delta { op, key, val }); }); commit(*this, batch, sopts); } ircd::db::database::column & ircd::db::database::operator[](const string_view &name) { const auto it{column_names.find(name)}; if(unlikely(it == std::end(column_names))) throw schema_error { "'%s': column '%s' is not available or specified in schema", this->name, name }; return operator[](db::id(*it->second)); } ircd::db::database::column & ircd::db::database::operator[](const uint32_t &id) try { auto &ret(*column_index.at(id)); assert(db::id(ret) == id); return ret; } catch(const std::out_of_range &e) { throw schema_error { "'%s': column id[%u] is not available or specified in schema", this->name, id }; } const ircd::db::database::column & ircd::db::database::operator[](const string_view &name) const { const auto it{column_names.find(name)}; if(unlikely(it == std::end(column_names))) throw schema_error { "'%s': column '%s' is not available or specified in schema", this->name, name }; return operator[](db::id(*it->second)); } const ircd::db::database::column & ircd::db::database::operator[](const uint32_t &id) const try { auto &ret(*column_index.at(id)); assert(db::id(ret) == id); return ret; } catch(const std::out_of_range &e) { throw schema_error { "'%s': column id[%u] is not available or specified in schema", this->name, id }; } /////////////////////////////////////////////////////////////////////////////// // // database::comparator // ircd::db::database::comparator::comparator(database *const &d, db::comparator user) :d{d} ,user { std::move(user) } { } const char * ircd::db::database::comparator::Name() const noexcept { assert(!user.name.empty()); return user.name.data(); } bool ircd::db::database::comparator::Equal(const Slice &a, const Slice &b) const noexcept { return user.equal? user.equal(slice(a), slice(b)): Compare(a, b) == 0; } int ircd::db::database::comparator::Compare(const Slice &a, const Slice &b) const noexcept { assert(bool(user.less)); const auto sa{slice(a)}; const auto sb{slice(b)}; return user.less(sa, sb)? -1: // less[Y], equal[?], greater[?] user.equal && user.equal(sa, sb)? 0: // less[N], equal[Y], greater[?] user.equal? 1: // less[N], equal[N], greater[Y] user.less(sb, sa)? 1: // less[N], equal[?], greater[Y] 0; // less[N], equal[Y], greater[N] } void ircd::db::database::comparator::FindShortestSeparator(std::string *const key, const Slice &limit) const noexcept { assert(key != nullptr); if(user.separator) user.separator(*key, slice(limit)); } void ircd::db::database::comparator::FindShortSuccessor(std::string *const key) const noexcept { assert(key != nullptr); if(user.successor) user.successor(*key); } bool ircd::db::database::comparator::IsSameLengthImmediateSuccessor(const Slice &s, const Slice &t) const noexcept { return rocksdb::Comparator::IsSameLengthImmediateSuccessor(s, t); } bool ircd::db::database::comparator::CanKeysWithDifferentByteContentsBeEqual() const noexcept { // When keys with different byte contents can be equal the keys are // not hashable. return !user.hashable; } /////////////////////////////////////////////////////////////////////////////// // // database::prefix_transform // const char * ircd::db::database::prefix_transform::Name() const noexcept { assert(!user.name.empty()); return user.name.c_str(); } rocksdb::Slice ircd::db::database::prefix_transform::Transform(const Slice &key) const noexcept { assert(bool(user.get)); return slice(user.get(slice(key))); } bool ircd::db::database::prefix_transform::InRange(const Slice &key) const noexcept { return InDomain(key); } bool ircd::db::database::prefix_transform::InDomain(const Slice &key) const noexcept { assert(bool(user.has)); return user.has(slice(key)); } /////////////////////////////////////////////////////////////////////////////// // // database::column // void ircd::db::drop(database::column &c) { if(!c.handle) return; database &d(c); const std::lock_guard lock{write_mutex}; const ctx::uninterruptible::nothrow ui; log::debug { log, "'%s':'%s' @%lu DROPPING COLUMN", name(d), name(c), sequence(d) }; throw_on_error { c.d->d->DropColumnFamily(c.handle.get()) }; log::notice { log, "'%s':'%s' @%lu DROPPED COLUMN", name(d), name(c), sequence(d) }; } uint32_t ircd::db::id(const database::column &c) { if(!c.handle) return -1; return c.handle->GetID(); } const std::string & ircd::db::name(const database::column &c) { return c.name; } const ircd::db::descriptor & ircd::db::describe(const database::column &c) { assert(c.descriptor); return *c.descriptor; } // // database::column // ircd::db::database::column::column(database &d, db::descriptor &descriptor) :rocksdb::ColumnFamilyDescriptor ( descriptor.name, database::options{descriptor.options} ) ,d{&d} ,descriptor{&descriptor} ,key_type{this->descriptor->type.first} ,mapped_type{this->descriptor->type.second} ,cmp{this->d, this->descriptor->cmp} ,prefix{this->d, this->descriptor->prefix} ,cfilter{this, this->descriptor->compactor} ,stats{std::make_shared(this->d)} ,handle { nullptr, [&d](rocksdb::ColumnFamilyHandle *const handle) { assert(d.d); if(handle && d.d) d.d->DestroyColumnFamilyHandle(handle); } } { // If possible, deduce comparator based on type given in descriptor if(!this->descriptor->cmp.less) { if(key_type == typeid(string_view)) this->cmp.user = cmp_string_view{}; else if(key_type == typeid(int64_t)) this->cmp.user = cmp_int64_t{}; else if(key_type == typeid(uint64_t)) this->cmp.user = cmp_uint64_t{}; else throw error { "column '%s' key type[%s] requires user supplied comparator", this->name, key_type.name() }; } // Set the key comparator this->options.comparator = &this->cmp; // Set the prefix extractor if(this->prefix.user.get && this->prefix.user.has) this->options.prefix_extractor = std::shared_ptr { &this->prefix, [](const rocksdb::SliceTransform *) {} }; // Set the insert hint prefix extractor if(this->options.prefix_extractor) this->options.memtable_insert_with_hint_prefix_extractor = this->options.prefix_extractor; // Set the compaction filter this->options.compaction_filter = &this->cfilter; //this->options.paranoid_file_checks = true; // More stats reported by the rocksdb.stats property. this->options.report_bg_io_stats = true; // Set the compaction style; we don't override this in the descriptor yet. //this->options.compaction_style = rocksdb::kCompactionStyleNone; this->options.compaction_style = rocksdb::kCompactionStyleLevel; // Set the compaction priority; this should probably be in the descriptor // but this is currently selected for the general matrix workload. this->options.compaction_pri = rocksdb::CompactionPri::kOldestLargestSeqFirst; // Set filter reductions for this column. This means we expect a key to exist. this->options.optimize_filters_for_hits = this->descriptor->expect_queries_hit; // Compression type this->options.compression = find_supported_compression(this->descriptor->compression); //this->options.compression = rocksdb::kNoCompression; // Compression options this->options.compression_opts.enabled = true; this->options.compression_opts.max_dict_bytes = 0;//8_MiB; // Mimic the above for bottommost compression. //this->options.bottommost_compression = this->options.compression; //this->options.bottommost_compression_opts = this->options.compression_opts; //TODO: descriptor / conf this->options.num_levels = 7; //this->options.level0_file_num_compaction_trigger = 1; this->options.target_file_size_base = 32_MiB; //this->options.max_bytes_for_level_base = 192_MiB; this->options.target_file_size_multiplier = 2; // size at level //this->options.max_bytes_for_level_multiplier = 3; // size at level //this->options.write_buffer_size = 2_MiB; //this->options.disable_auto_compactions = true; //this->options.level_compaction_dynamic_level_bytes = true; // // Table options // // Block based table index type. table_opts.format_version = 3; // RocksDB >= 5.15 compat only; otherwise use 2. table_opts.index_type = rocksdb::BlockBasedTableOptions::kTwoLevelIndexSearch; table_opts.partition_filters = true; table_opts.use_delta_encoding = true; table_opts.enable_index_compression = false; table_opts.read_amp_bytes_per_bit = 8; // Specify that index blocks should use the cache. If not, they will be // pre-read into RAM by rocksdb internally. Because of the above // TwoLevelIndex + partition_filters configuration on RocksDB v5.15 it's // better to use pre-read except in the case of a massive database. table_opts.cache_index_and_filter_blocks = true; table_opts.cache_index_and_filter_blocks_with_high_priority = false; table_opts.pin_top_level_index_and_filter = false; table_opts.pin_l0_filter_and_index_blocks_in_cache = false; // Setup the block size table_opts.block_size = this->descriptor->block_size; table_opts.metadata_block_size = this->descriptor->meta_block_size; table_opts.block_size_deviation = 50; // Block alignment doesn't work if compression is enabled for this // column. If not, we want block alignment for direct IO. table_opts.block_align = this->options.compression == rocksdb::kNoCompression; // Setup the cache for assets. const auto &cache_size(this->descriptor->cache_size); if(cache_size != 0) table_opts.block_cache = std::make_shared(this->d, this->stats, cache_size); // Setup the cache for compressed assets. const auto &cache_size_comp(this->descriptor->cache_size_comp); if(cache_size_comp != 0) table_opts.block_cache_compressed = std::make_shared(this->d, this->stats, cache_size_comp); // Setup the bloom filter. const auto &bloom_bits(this->descriptor->bloom_bits); if(bloom_bits) table_opts.filter_policy.reset(rocksdb::NewBloomFilterPolicy(bloom_bits, false)); // Tickers::READ_AMP_TOTAL_READ_BYTES / Tickers::READ_AMP_ESTIMATE_USEFUL_BYTES //table_opts.read_amp_bytes_per_bit = 8; // Finally set the table options in the column options. this->options.table_factory.reset(rocksdb::NewBlockBasedTableFactory(table_opts)); log::debug { log, "schema '%s' column [%s => %s] cmp[%s] pfx[%s] lru:%s:%s bloom:%zu compression:%d %s", db::name(d), demangle(key_type.name()), demangle(mapped_type.name()), this->cmp.Name(), this->options.prefix_extractor? this->prefix.Name() : "none", cache_size? "YES": "NO", cache_size_comp? "YES": "NO", bloom_bits, int(this->options.compression), this->descriptor->name }; } ircd::db::database::column::~column() noexcept { } ircd::db::database::column::operator database &() { return *d; } ircd::db::database::column::operator rocksdb::ColumnFamilyHandle *() { return handle.get(); } ircd::db::database::column::operator const database &() const { return *d; } ircd::db::database::column::operator const rocksdb::ColumnFamilyHandle *() const { return handle.get(); } ircd::db::database::column::operator const rocksdb::ColumnFamilyOptions &() const { return options; } /////////////////////////////////////////////////////////////////////////////// // // database::snapshot // uint64_t ircd::db::sequence(const database::snapshot &s) { const rocksdb::Snapshot *const rs(s); return sequence(rs); } uint64_t ircd::db::sequence(const rocksdb::Snapshot *const &rs) { return likely(rs)? rs->GetSequenceNumber() : 0ULL; } ircd::db::database::snapshot::snapshot(database &d) :s { d.d->GetSnapshot(), [dp(weak_from(d))](const rocksdb::Snapshot *const s) { if(!s) return; const auto d(dp.lock()); d->d->ReleaseSnapshot(s); } } { } ircd::db::database::snapshot::~snapshot() noexcept { } /////////////////////////////////////////////////////////////////////////////// // // database::logger // ircd::db::database::logger::logger(database *const &d) :rocksdb::Logger{} ,d{d} { } ircd::db::database::logger::~logger() noexcept { } rocksdb::Status ircd::db::database::logger::Close() noexcept { return rocksdb::Status::NotSupported(); } static ircd::log::facility translate(const rocksdb::InfoLogLevel &level) { switch(level) { // Treat all infomational messages from rocksdb as debug here for now. // We can clean them up and make better reports for our users eventually. default: case rocksdb::InfoLogLevel::DEBUG_LEVEL: return ircd::log::facility::DEBUG; case rocksdb::InfoLogLevel::INFO_LEVEL: return ircd::log::facility::DEBUG; case rocksdb::InfoLogLevel::WARN_LEVEL: return ircd::log::facility::WARNING; case rocksdb::InfoLogLevel::ERROR_LEVEL: return ircd::log::facility::ERROR; case rocksdb::InfoLogLevel::FATAL_LEVEL: return ircd::log::facility::CRITICAL; case rocksdb::InfoLogLevel::HEADER_LEVEL: return ircd::log::facility::NOTICE; } } void ircd::db::database::logger::Logv(const char *const fmt, va_list ap) noexcept { Logv(rocksdb::InfoLogLevel::DEBUG_LEVEL, fmt, ap); } void ircd::db::database::logger::LogHeader(const char *const fmt, va_list ap) noexcept { Logv(rocksdb::InfoLogLevel::DEBUG_LEVEL, fmt, ap); } #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wsuggest-attribute=format" void ircd::db::database::logger::Logv(const rocksdb::InfoLogLevel level, const char *const fmt, va_list ap) noexcept { if(level < GetInfoLogLevel()) return; thread_local char buf[1024]; const auto len { vsnprintf(buf, sizeof(buf), fmt, ap) }; const auto str { // RocksDB adds annoying leading whitespace to attempt to right-justify things and idc lstrip(string_view{buf, size_t(len)}, ' ') }; // Skip the options for now if(startswith(str, "Options")) return; rog(translate(level), "'%s': %s", d->name, str); } #pragma GCC diagnostic pop /////////////////////////////////////////////////////////////////////////////// // // database::mergeop // ircd::db::database::mergeop::mergeop(database *const &d, merge_closure merger) :d{d} ,merger { merger? std::move(merger): ircd::db::merge_operator } { } ircd::db::database::mergeop::~mergeop() noexcept { } const char * ircd::db::database::mergeop::Name() const noexcept { return ""; } bool ircd::db::database::mergeop::Merge(const rocksdb::Slice &_key, const rocksdb::Slice *const _exist, const rocksdb::Slice &_update, std::string *const newval, rocksdb::Logger *const) const noexcept try { const string_view key { _key.data(), _key.size() }; const string_view exist { _exist? string_view { _exist->data(), _exist->size() } : string_view{} }; const string_view update { _update.data(), _update.size() }; if(exist.empty()) { *newval = std::string(update); return true; } //XXX caching opportunity? *newval = merger(key, {exist, update}); // call the user return true; } catch(const std::bad_function_call &e) { log.critical("merge: missing merge operator (%s)", e); return false; } catch(const std::exception &e) { log.error("merge: %s", e); return false; } /////////////////////////////////////////////////////////////////////////////// // // db/stats.h // std::string ircd::db::string(const rocksdb::IOStatsContext &ic, const bool &all) { const bool exclude_zeros(!all); return ic.ToString(exclude_zeros); } const rocksdb::IOStatsContext & ircd::db::iostats_current() { const auto *const &ret { rocksdb::get_iostats_context() }; if(unlikely(!ret)) throw error { "IO counters are not available on this thread." }; return *ret; } std::string ircd::db::string(const rocksdb::PerfContext &pc, const bool &all) { const bool exclude_zeros(!all); return pc.ToString(exclude_zeros); } const rocksdb::PerfContext & ircd::db::perf_current() { const auto *const &ret { rocksdb::get_perf_context() }; if(unlikely(!ret)) throw error { "Performance counters are not available on this thread." }; return *ret; } void ircd::db::perf_level(const uint &level) { if(level >= rocksdb::PerfLevel::kOutOfBounds) throw error { "Perf level of '%u' is invalid; maximum is '%u'", level, uint(rocksdb::PerfLevel::kOutOfBounds) }; rocksdb::SetPerfLevel(rocksdb::PerfLevel(level)); } uint ircd::db::perf_level() { return rocksdb::GetPerfLevel(); } // // ticker // uint64_t ircd::db::ticker(const database &d, const string_view &key) { return ticker(d, ticker_id(key)); } uint64_t ircd::db::ticker(const database &d, const uint32_t &id) { return d.stats->getTickerCount(id); } uint32_t ircd::db::ticker_id(const string_view &key) { for(const auto &pair : rocksdb::TickersNameMap) if(key == pair.second) return pair.first; throw std::out_of_range { "No ticker with that key" }; } ircd::string_view ircd::db::ticker_id(const uint32_t &id) { for(const auto &pair : rocksdb::TickersNameMap) if(id == pair.first) return pair.second; return {}; } decltype(ircd::db::ticker_max) ircd::db::ticker_max { rocksdb::TICKER_ENUM_MAX }; // // histogram // const struct ircd::db::histogram & ircd::db::histogram(const database &d, const string_view &key) { return histogram(d, histogram_id(key)); } const struct ircd::db::histogram & ircd::db::histogram(const database &d, const uint32_t &id) { return d.stats->histogram.at(id); } uint32_t ircd::db::histogram_id(const string_view &key) { for(const auto &pair : rocksdb::HistogramsNameMap) if(key == pair.second) return pair.first; throw std::out_of_range { "No histogram with that key" }; } ircd::string_view ircd::db::histogram_id(const uint32_t &id) { for(const auto &pair : rocksdb::HistogramsNameMap) if(id == pair.first) return pair.second; return {}; } decltype(ircd::db::histogram_max) ircd::db::histogram_max { rocksdb::HISTOGRAM_ENUM_MAX }; /////////////////////////////////////////////////////////////////////////////// // // database::stats (db/database/stats.h) internal // // // stats::stats // ircd::db::database::stats::stats(database *const &d) :d{d} { } ircd::db::database::stats::~stats() noexcept { } rocksdb::Status ircd::db::database::stats::Reset() noexcept { ticker.fill(0); histogram.fill({0.0}); return rocksdb::Status::OK(); } uint64_t ircd::db::database::stats::getAndResetTickerCount(const uint32_t type) noexcept { const auto ret(getTickerCount(type)); setTickerCount(type, 0); return ret; } bool ircd::db::database::stats::HistEnabledForType(const uint32_t type) const noexcept { return type < histogram.size(); } void ircd::db::database::stats::measureTime(const uint32_t type, const uint64_t time) noexcept { auto &data(histogram.at(type)); data.time += time; data.hits++; data.max = std::max(data.max, double(time)); data.avg = data.time / static_cast(data.hits); } void ircd::db::database::stats::histogramData(const uint32_t type, rocksdb::HistogramData *const data) const noexcept { assert(data); const auto &h { histogram.at(type) }; data->median = h.median; data->percentile95 = h.pct95; data->percentile99 = h.pct99; data->average = h.avg; data->standard_deviation = h.stddev; data->max = h.max; } void ircd::db::database::stats::recordTick(const uint32_t type, const uint64_t count) noexcept { ticker.at(type) += count; } void ircd::db::database::stats::setTickerCount(const uint32_t type, const uint64_t count) noexcept { ticker.at(type) = count; } uint64_t ircd::db::database::stats::getTickerCount(const uint32_t type) const noexcept { return ticker.at(type); } // // database::stats::passthru // ircd::db::database::stats::passthru::passthru(rocksdb::Statistics *const &a, rocksdb::Statistics *const &b) :pass { { a, b } } { } ircd::db::database::stats::passthru::~passthru() noexcept { } [[noreturn]] rocksdb::Status ircd::db::database::stats::passthru::Reset() noexcept { throw assertive {"Unavailable for passthru"}; } void ircd::db::database::stats::passthru::recordTick(const uint32_t tickerType, const uint64_t count) noexcept { for(auto *const &pass : this->pass) pass->recordTick(tickerType, count); } void ircd::db::database::stats::passthru::measureTime(const uint32_t histogramType, const uint64_t time) noexcept { for(auto *const &pass : this->pass) pass->measureTime(histogramType, time); } bool ircd::db::database::stats::passthru::HistEnabledForType(const uint32_t type) const noexcept { return std::all_of(begin(pass), end(pass), [&type] (const auto *const &pass) { return pass->HistEnabledForType(type); }); } [[noreturn]] uint64_t ircd::db::database::stats::passthru::getTickerCount(const uint32_t tickerType) const noexcept { throw assertive {"Unavailable for passthru"}; } [[noreturn]] void ircd::db::database::stats::passthru::setTickerCount(const uint32_t tickerType, const uint64_t count) noexcept { throw assertive {"Unavailable for passthru"}; } [[noreturn]] void ircd::db::database::stats::passthru::histogramData(const uint32_t type, rocksdb::HistogramData *const data) const noexcept { throw assertive {"Unavailable for passthru"}; } [[noreturn]] uint64_t ircd::db::database::stats::passthru::getAndResetTickerCount(const uint32_t tickerType) noexcept { throw assertive {"Unavailable for passthru"}; } /////////////////////////////////////////////////////////////////////////////// // // database::events // void ircd::db::database::events::OnFlushCompleted(rocksdb::DB *const db, const rocksdb::FlushJobInfo &info) noexcept { log::info { rog, "'%s' flush complete: column[%s] path[%s] ctx[%lu] job[%d] writes[slow:%d stop:%d] seq[%zu -> %zu] reason:%d", d->name, info.cf_name, info.file_path, info.thread_id, info.job_id, info.triggered_writes_slowdown, info.triggered_writes_stop, info.smallest_seqno, info.largest_seqno, int(info.flush_reason) }; } void ircd::db::database::events::OnFlushBegin(rocksdb::DB *const db, const rocksdb::FlushJobInfo &info) noexcept { log::info { rog, "'%s' flush begin column[%s] ctx[%lu] job[%d] writes[slow:%d stop:%d] seq[%zu -> %zu] reason:%d", d->name, info.cf_name, info.thread_id, info.job_id, info.triggered_writes_slowdown, info.triggered_writes_stop, info.smallest_seqno, info.largest_seqno, int(info.flush_reason) }; } void ircd::db::database::events::OnCompactionCompleted(rocksdb::DB *const db, const rocksdb::CompactionJobInfo &info) noexcept { log::info { rog, "'%s' compacted column[%s] ctx[%lu] job[%d] level[in:%d out:%d] files[in:%zu out:%zu] reason:%d :%s", d->name, info.cf_name, info.thread_id, info.job_id, info.base_input_level, info.output_level, info.input_files.size(), info.output_files.size(), int(info.compaction_reason), info.status.ToString() }; } void ircd::db::database::events::OnTableFileDeleted(const rocksdb::TableFileDeletionInfo &info) noexcept { log::debug { rog, "'%s': table file deleted: db[%s] path[%s] status[%d] job[%d]", d->name, info.db_name, info.file_path, int(info.status.code()), info.job_id }; } void ircd::db::database::events::OnTableFileCreated(const rocksdb::TableFileCreationInfo &info) noexcept { log::debug { rog, "'%s': table file created: db[%s] path[%s] status[%d] job[%d]", d->name, info.db_name, info.file_path, int(info.status.code()), info.job_id }; } void ircd::db::database::events::OnTableFileCreationStarted(const rocksdb::TableFileCreationBriefInfo &info) noexcept { log::debug { rog, "'%s': table file creating: db[%s] column[%s] path[%s] job[%d]", d->name, info.db_name, info.cf_name, info.file_path, info.job_id }; } void ircd::db::database::events::OnMemTableSealed(const rocksdb::MemTableInfo &info) noexcept { log::debug { rog, "'%s': memory table sealed: column[%s] entries[%lu] deletes[%lu]", d->name, info.cf_name, info.num_entries, info.num_deletes }; } void ircd::db::database::events::OnColumnFamilyHandleDeletionStarted(rocksdb::ColumnFamilyHandle *const h) noexcept { log::debug { rog, "'%s': column[%s] handle closing @ %p", d->name, h->GetName(), h }; } void ircd::db::database::events::OnExternalFileIngested(rocksdb::DB *const d, const rocksdb::ExternalFileIngestionInfo &info) noexcept { log::notice { rog, "'%s' external file ingested column[%s] external[%s] internal[%s] sequence:%lu", this->d->name, info.cf_name, info.external_file_path, info.internal_file_path, info.global_seqno }; } void ircd::db::database::events::OnBackgroundError(rocksdb::BackgroundErrorReason reason, rocksdb::Status *const status) noexcept { assert(d); assert(status); thread_local char buf[1024]; const string_view str{fmt::sprintf { buf, "%s error in %s :%s", reflect(status->severity()), reflect(reason), status->ToString() }}; // This is a legitimate when we want to use it. If the error is not // suppressed the DB will enter read-only mode and will require a // call to db::resume() to clear the error (i.e by admin at console). const bool ignore { false }; const log::facility fac { ignore? log::facility::DERROR: log::facility::ERROR }; log::logf { log, fac, "'%s': %s", d->name, str }; if(ignore) { *status = rocksdb::Status::OK(); return; } // Downgrade select fatal errors to hard errors. If this downgrade // does not occur then it can never be cleared by a db::resume() and // the daemon must be restarted. if(reason == rocksdb::BackgroundErrorReason::kCompaction) if(status->severity() == rocksdb::Status::kFatalError) *status = rocksdb::Status(*status, rocksdb::Status::kHardError); // Save the error string to the database instance for later examination. d->errors.emplace_back(str); } void ircd::db::database::events::OnStallConditionsChanged(const rocksdb::WriteStallInfo &info) noexcept { log::warning { rog, "'%s' stall condition column[%s] %s -> %s", d->name, info.cf_name, reflect(info.condition.prev), reflect(info.condition.cur) }; } /////////////////////////////////////////////////////////////////////////////// // // database::cache (internal) // decltype(ircd::db::database::cache::DEFAULT_SHARD_BITS) ircd::db::database::cache::DEFAULT_SHARD_BITS ( std::min(std::log2(size_t(db::request_pool_size)), 8.0) ); decltype(ircd::db::database::cache::DEFAULT_STRICT) ircd::db::database::cache::DEFAULT_STRICT { false }; decltype(ircd::db::database::cache::DEFAULT_HI_PRIO) ircd::db::database::cache::DEFAULT_HI_PRIO { 0.10 }; // // cache::cache // ircd::db::database::cache::cache(database *const &d, std::shared_ptr stats, const ssize_t &initial_capacity) :d{d} ,stats{std::move(stats)} ,c { rocksdb::NewLRUCache ( std::max(initial_capacity, ssize_t(0)) ,DEFAULT_SHARD_BITS ,DEFAULT_STRICT ,DEFAULT_HI_PRIO ) } { assert(bool(c)); } ircd::db::database::cache::~cache() noexcept { } const char * ircd::db::database::cache::Name() const noexcept { assert(bool(c)); return c->Name(); } rocksdb::Status ircd::db::database::cache::Insert(const Slice &key, void *const value, size_t charge, deleter del, Handle **const handle, Priority priority) noexcept { assert(bool(c)); assert(bool(stats)); const rocksdb::Status &ret { c->Insert(key, value, charge, del, handle, priority) }; stats->recordTick(rocksdb::Tickers::BLOCK_CACHE_ADD, ret.ok()); stats->recordTick(rocksdb::Tickers::BLOCK_CACHE_ADD_FAILURES, !ret.ok()); stats->recordTick(rocksdb::Tickers::BLOCK_CACHE_DATA_BYTES_INSERT, ret.ok()? charge : 0UL); return ret; } rocksdb::Cache::Handle * ircd::db::database::cache::Lookup(const Slice &key, Statistics *const statistics) noexcept { assert(bool(c)); assert(bool(this->stats)); database::stats::passthru passthru { this->stats.get(), statistics }; rocksdb::Statistics *const s { statistics? dynamic_cast(&passthru): dynamic_cast(this->stats.get()) }; auto *const &ret { c->Lookup(key, s) }; // Rocksdb's LRUCache stats are broke. The statistics ptr is null and // passing it to Lookup() does nothing internally. We have to do this // here ourselves :/ this->stats->recordTick(rocksdb::Tickers::BLOCK_CACHE_HIT, bool(ret)); this->stats->recordTick(rocksdb::Tickers::BLOCK_CACHE_MISS, !bool(ret)); return ret; } bool ircd::db::database::cache::Ref(Handle *const handle) noexcept { assert(bool(c)); return c->Ref(handle); } bool ircd::db::database::cache::Release(Handle *const handle, bool force_erase) noexcept { assert(bool(c)); return c->Release(handle, force_erase); } void * ircd::db::database::cache::Value(Handle *const handle) noexcept { assert(bool(c)); return c->Value(handle); } void ircd::db::database::cache::Erase(const Slice &key) noexcept { assert(bool(c)); return c->Erase(key); } uint64_t ircd::db::database::cache::NewId() noexcept { assert(bool(c)); return c->NewId(); } void ircd::db::database::cache::SetCapacity(size_t capacity) noexcept { assert(bool(c)); return c->SetCapacity(capacity); } void ircd::db::database::cache::SetStrictCapacityLimit(bool strict_capacity_limit) noexcept { assert(bool(c)); return c->SetStrictCapacityLimit(strict_capacity_limit); } bool ircd::db::database::cache::HasStrictCapacityLimit() const noexcept { assert(bool(c)); return c->HasStrictCapacityLimit(); } size_t ircd::db::database::cache::GetCapacity() const noexcept { assert(bool(c)); return c->GetCapacity(); } size_t ircd::db::database::cache::GetUsage() const noexcept { assert(bool(c)); return c->GetUsage(); } size_t ircd::db::database::cache::GetUsage(Handle *const handle) const noexcept { assert(bool(c)); return c->GetUsage(handle); } size_t ircd::db::database::cache::GetPinnedUsage() const noexcept { assert(bool(c)); return c->GetPinnedUsage(); } void ircd::db::database::cache::DisownData() noexcept { assert(bool(c)); return c->DisownData(); } void ircd::db::database::cache::ApplyToAllCacheEntries(callback cb, bool thread_safe) noexcept { assert(bool(c)); return c->ApplyToAllCacheEntries(cb, thread_safe); } void ircd::db::database::cache::EraseUnRefEntries() noexcept { assert(bool(c)); return c->EraseUnRefEntries(); } std::string ircd::db::database::cache::GetPrintableOptions() const noexcept { assert(bool(c)); return c->GetPrintableOptions(); } void ircd::db::database::cache::TEST_mark_as_data_block(const Slice &key, size_t charge) noexcept { assert(bool(c)); return c->TEST_mark_as_data_block(key, charge); } /////////////////////////////////////////////////////////////////////////////// // // database::compaction_filter // ircd::db::database::compaction_filter::compaction_filter(column *const &c, db::compactor user) :c{c} ,d{c->d} ,user{std::move(user)} { } ircd::db::database::compaction_filter::~compaction_filter() noexcept { } rocksdb::CompactionFilter::Decision ircd::db::database::compaction_filter::FilterV2(const int level, const Slice &key, const ValueType type, const Slice &oldval, std::string *const newval, std::string *const skip) const noexcept { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV const auto typestr { type == kValue? "VALUE"_sv: type == kMergeOperand? "MERGE"_sv: "BLOB"_sv }; log::debug { log, "'%s':'%s': compaction level:%d key:%zu@%p type:%s old:%zu@%p new:%p skip:%p", d->name, c->name, level, size(key), data(key), typestr, size(oldval), data(oldval), (const void *)newval, (const void *)skip }; #endif const db::compactor::callback &callback { type == ValueType::kValue && user.value? user.value: type == ValueType::kMergeOperand && user.merge? user.merge: compactor::callback{} }; if(!callback) return Decision::kKeep; const compactor::args args { level, slice(key), slice(oldval), newval, skip }; switch(callback(args)) { default: case db::op::GET: return Decision::kKeep; case db::op::SET: return Decision::kChangeValue; case db::op::DELETE: return Decision::kRemove; case db::op::DELETE_RANGE: return Decision::kRemoveAndSkipUntil; } } bool ircd::db::database::compaction_filter::IgnoreSnapshots() const noexcept { return false; } const char * ircd::db::database::compaction_filter::Name() const noexcept { assert(c); return db::name(*c).c_str(); } /////////////////////////////////////////////////////////////////////////////// // // database::sst // void ircd::db::database::sst::tool(const vector_view &args) { const ctx::uninterruptible::nothrow ui; static const size_t ARG_MAX {16}; static const size_t ARG_MAX_LEN {256}; thread_local char arg[ARG_MAX][ARG_MAX_LEN] { "./sst_dump" }; size_t i(0); char *argv[ARG_MAX] { arg[i++] }; for(; i < ARG_MAX - 1 && i - 1 < args.size(); ++i) { strlcpy(arg[i], args.at(i - 1)); argv[i] = arg[i]; } argv[i++] = nullptr; assert(i <= ARG_MAX); rocksdb::SSTDumpTool tool; const int ret { tool.Run(i, argv) }; if(ret != 0) throw error { "Error from SST dump tool: return value: %d", ret }; } // // sst::dump::dump // ircd::db::database::sst::dump::dump(db::column column, const key_range &range, const string_view &path_) { const ctx::uninterruptible::nothrow ui; database::column &c(column); const database &d(column); std::string path{path_}; if(path.empty()) { const string_view path_parts[] { fs::get(fs::DB), db::name(d), db::name(c) }; path = fs::make_path(path_parts); } rocksdb::Options opts(d.d->GetOptions(c)); rocksdb::EnvOptions eopts(opts); rocksdb::SstFileWriter writer { eopts, opts, c }; throw_on_error { writer.Open(path) }; size_t i(0); for(auto it(column.begin()); it != column.end(); ++it, ++i) throw_on_error { writer.Put(slice(it->first), slice(it->second)) }; rocksdb::ExternalSstFileInfo info; if(i) throw_on_error { writer.Finish(&info) }; this->info.column = db::name(column); this->info.path = std::move(info.file_path); this->info.min_key = std::move(info.smallest_key); this->info.max_key = std::move(info.largest_key); this->info.min_seq = info.sequence_number; this->info.max_seq = info.sequence_number; this->info.size = info.file_size; this->info.entries = info.num_entries; this->info.version = info.version; } // // sst::info::vector // ircd::db::database::sst::info::vector::vector(const database &d) { this->reserve(db::file_count(d)); for(const auto &c : d.columns) { db::column column{*c}; for(auto &&info : vector(column)) this->emplace_back(std::move(info)); } } ircd::db::database::sst::info::vector::vector(const db::column &column) { const ctx::uninterruptible::nothrow ui; database::column &c(const_cast(column)); database &d(*c.d); rocksdb::ColumnFamilyMetaData cfmd; d.d->GetColumnFamilyMetaData(c, &cfmd); rocksdb::TablePropertiesCollection tpc; throw_on_error { d.d->GetPropertiesOfAllTables(c, &tpc) }; size_t i(0); this->resize(std::max(cfmd.file_count, tpc.size())); for(rocksdb::LevelMetaData &level : cfmd.levels) for(rocksdb::SstFileMetaData md : level.files) { auto &info(this->at(i++)); info.operator=(std::move(md)); info.level = level.level; const auto path(info.path + info.name); auto tp(*tpc.at(path)); info.operator=(std::move(tp)); tpc.erase(path); } for(auto &&kv : tpc) { auto &info(this->at(i++)); auto tp(*kv.second); info.operator=(std::move(tp)); info.path = kv.first; } assert(i == this->size()); } // // sst::info::info // ircd::db::database::sst::info::info(const database &d_, const string_view &filename) { auto &d(const_cast(d_)); const ctx::uninterruptible::nothrow ui; std::vector v; d.d->GetLiveFilesMetaData(&v); for(auto &md : v) if(md.name == filename) { rocksdb::TablePropertiesCollection tpc; throw_on_error { d.d->GetPropertiesOfAllTables(d[md.column_family_name], &tpc) }; auto tp(*tpc.at(md.db_path + md.name)); this->operator=(std::move(md)); this->operator=(std::move(tp)); return; } throw not_found { "No file named '%s' is live in database '%s'", filename, d.name }; } ircd::db::database::sst::info & ircd::db::database::sst::info::operator=(rocksdb::LiveFileMetaData &&md) { name = std::move(md.name); path = std::move(md.db_path); column = std::move(md.column_family_name); size = std::move(md.size); min_seq = std::move(md.smallest_seqno); max_seq = std::move(md.largest_seqno); min_key = std::move(md.smallestkey); max_key = std::move(md.largestkey); num_reads = std::move(md.num_reads_sampled); level = std::move(md.level); compacting = std::move(md.being_compacted); return *this; } ircd::db::database::sst::info & ircd::db::database::sst::info::operator=(rocksdb::SstFileMetaData &&md) { name = std::move(md.name); path = std::move(md.db_path); size = std::move(md.size); min_seq = std::move(md.smallest_seqno); max_seq = std::move(md.largest_seqno); min_key = std::move(md.smallestkey); max_key = std::move(md.largestkey); num_reads = std::move(md.num_reads_sampled); compacting = std::move(md.being_compacted); return *this; } ircd::db::database::sst::info & ircd::db::database::sst::info::operator=(rocksdb::TableProperties &&tp) { column = std::move(tp.column_family_name); filter = std::move(tp.filter_policy_name); comparator = std::move(tp.comparator_name); merge_operator = std::move(tp.merge_operator_name); prefix_extractor = std::move(tp.prefix_extractor_name); compression = std::move(tp.compression_name); format = std::move(tp.format_version); cfid = std::move(tp.column_family_id); data_size = std::move(tp.data_size); index_size = std::move(tp.index_size); top_index_size = std::move(tp.top_level_index_size); filter_size = std::move(tp.filter_size); keys_size = std::move(tp.raw_key_size); values_size = std::move(tp.raw_value_size); index_parts = std::move(tp.index_partitions); data_blocks = std::move(tp.num_data_blocks); entries = std::move(tp.num_entries); range_deletes = std::move(tp.num_range_deletions); fixed_key_len = std::move(tp.fixed_key_len); created = std::move(tp.creation_time); oldest_key = std::move(tp.oldest_key_time); return *this; } /////////////////////////////////////////////////////////////////////////////// // // database::wal // // // wal::info::vector // ircd::db::database::wal::info::vector::vector(const database &d_) { auto &d{const_cast(d_)}; std::vector> vec; throw_on_error { d.d->GetSortedWalFiles(vec) }; this->resize(vec.size()); for(size_t i(0); i < vec.size(); ++i) this->at(i).operator=(*vec.at(i)); } // // wal::info::info // ircd::db::database::wal::info::info(const database &d_, const string_view &filename) { auto &d{const_cast(d_)}; std::vector> vec; throw_on_error { d.d->GetSortedWalFiles(vec) }; for(const auto &ptr : vec) if(ptr->PathName() == filename) { this->operator=(*ptr); return; } throw not_found { "No file named '%s' is live in database '%s'", filename, d.name }; } ircd::db::database::wal::info & ircd::db::database::wal::info::operator=(const rocksdb::LogFile &lf) { name = lf.PathName(); number = lf.LogNumber(); seq = lf.StartSequence(); size = lf.SizeFileBytes(); alive = lf.Type() == rocksdb::WalFileType::kAliveLogFile; return *this; } /////////////////////////////////////////////////////////////////////////////// // // database::env // // // env::state // ircd::db::database::env::state::state(database *const &d) :d{*d} { } ircd::db::database::env::state::~state() noexcept { for(auto &p : pool) try { p.terminate(); p.join(); } catch(...) { continue; } } // // env::env // ircd::db::database::env::env(database *const &d) :d{*d}, st{std::make_unique(d)} { } ircd::db::database::env::~env() noexcept { } rocksdb::Status ircd::db::database::env::NewSequentialFile(const std::string &name, std::unique_ptr *const r, const EnvOptions &options) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': new sequential file '%s' options:%p", d.name, name, &options }; #endif *r = std::make_unique(&d, name, options); return Status::OK(); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::NewRandomAccessFile(const std::string &name, std::unique_ptr *const r, const EnvOptions &options) noexcept try { ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': new random access file '%s' options:%p", d.name, name, &options }; #endif *r = std::make_unique(&d, name, options); return Status::OK(); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::NewWritableFile(const std::string &name, std::unique_ptr *const r, const EnvOptions &options) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': new writable file '%s' options:%p", d.name, name, &options }; #endif if(options.use_direct_writes) *r = std::make_unique(&d, name, options, true); else *r = std::make_unique(&d, name, options, true); return Status::OK(); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::ReopenWritableFile(const std::string &name, std::unique_ptr *const r, const EnvOptions &options) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': reopen writable file '%s' options:%p", d.name, name, &options }; #endif if(options.use_direct_writes) *r = std::make_unique(&d, name, options, false); else *r = std::make_unique(&d, name, options, false); return Status::OK(); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::ReuseWritableFile(const std::string &name, const std::string &old_name, std::unique_ptr *const r, const EnvOptions &options) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': reuse writable file '%s' old '%s' options:%p", d.name, name, old_name, &options }; #endif assert(0); return Status::OK(); //return defaults.ReuseWritableFile(name, old_name, r, options); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::NewRandomRWFile(const std::string &name, std::unique_ptr *const result, const EnvOptions &options) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': new random read/write file '%s' options:%p", d.name, name, &options }; #endif *result = std::make_unique(&d, name, options); return Status::OK(); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::NewDirectory(const std::string &name, std::unique_ptr *const result) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': new directory '%s'", d.name, name }; #endif std::unique_ptr defaults; const auto ret { this->defaults.NewDirectory(name, &defaults) }; *result = std::make_unique(&d, name, std::move(defaults)); return ret; } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::FileExists(const std::string &f) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': file exists '%s'", d.name, f }; #endif return defaults.FileExists(f); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::GetChildren(const std::string &dir, std::vector *const r) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get children of directory '%s'", d.name, dir }; #endif return defaults.GetChildren(dir, r); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::GetChildrenFileAttributes(const std::string &dir, std::vector *const result) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get children file attributes of directory '%s'", d.name, dir }; #endif return defaults.GetChildrenFileAttributes(dir, result); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::DeleteFile(const std::string &name) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': delete file '%s'", d.name, name }; #endif return defaults.DeleteFile(name); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::CreateDir(const std::string &name) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': create directory '%s'", d.name, name }; #endif return defaults.CreateDir(name); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::CreateDirIfMissing(const std::string &name) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': create directory if missing '%s'", d.name, name }; #endif return defaults.CreateDirIfMissing(name); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::DeleteDir(const std::string &name) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': delete directory '%s'", d.name, name }; #endif return defaults.DeleteDir(name); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::GetFileSize(const std::string &name, uint64_t *const s) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get file size '%s'", d.name, name }; #endif assert(s); *s = fs::size(name); return Status::OK(); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::GetFileModificationTime(const std::string &name, uint64_t *const file_mtime) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get file mtime '%s'", d.name, name }; #endif return defaults.GetFileModificationTime(name, file_mtime); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::RenameFile(const std::string &s, const std::string &t) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rename file '%s' to '%s'", d.name, s, t }; #endif return defaults.RenameFile(s, t); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::LinkFile(const std::string &s, const std::string &t) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': link file '%s' to '%s'", d.name, s, t }; #endif return defaults.LinkFile(s, t); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::LockFile(const std::string &name, FileLock** l) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': lock file '%s'", d.name, name }; #endif return defaults.LockFile(name, l); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::UnlockFile(FileLock *const l) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': unlock file lock:%p", d.name, l }; #endif return defaults.UnlockFile(l); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::GetTestDirectory(std::string *const path) noexcept try { const ctx::uninterruptible::nothrow ui; return defaults.GetTestDirectory(path); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::GetAbsolutePath(const std::string &db_path, std::string *const output_path) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get absolute path from '%s' ret:%p", d.name, db_path, output_path }; #endif return defaults.GetAbsolutePath(db_path, output_path); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::NewLogger(const std::string &name, std::shared_ptr *const result) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': new logger '%s' result:%p", d.name, name, (const void *)result }; #endif return defaults.NewLogger(name, result); } catch(const std::exception &e) { return error_to_status{e}; } rocksdb::Status ircd::db::database::env::GetHostName(char *const name, uint64_t len) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get host name name:%p len:%lu", d.name, name, len }; #endif return defaults.GetHostName(name, len); } catch(const std::exception &e) { return error_to_status{e}; } uint64_t ircd::db::database::env::NowMicros() noexcept try { return defaults.NowMicros(); } catch(const std::exception &e) { throw assertive { "'%s': now micros :%s", d.name, e.what() }; } rocksdb::Status ircd::db::database::env::GetCurrentTime(int64_t *const unix_time) noexcept try { return defaults.GetCurrentTime(unix_time); } catch(const std::exception &e) { return error_to_status{e}; } std::string ircd::db::database::env::TimeToString(uint64_t time) noexcept try { return defaults.TimeToString(time); } catch(const std::exception &e) { throw assertive { "'%s': time to string :%s", d.name, e.what() }; } void ircd::db::database::env::SleepForMicroseconds(int micros) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { "'%s': sleep for %d microseconds", d.name, micros }; #endif ctx::sleep(microseconds(micros)); } catch(const std::exception &e) { log::critical { log, "'%s': sleep micros:%d :%s", d.name, micros, e.what() }; } void ircd::db::database::env::Schedule(void (*f)(void* arg), void *const a, Priority prio, void *const tag, void (*u)(void* arg)) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': schedule func:%p a:%p tag:%p u:%p prio:%s", d.name, f, a, tag, u, reflect(prio) }; #endif assert(st); auto &pool { st->pool.at(prio) }; auto &tasks { st->tasks.at(prio) }; tasks.emplace_back(state::task { f, u, a }); pool([this, &tasks] { ctx::uninterruptible::nothrow ui; assert(this->st); if(tasks.empty()) return; const auto task { std::move(tasks.front()) }; tasks.pop_front(); #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': func:%p arg:%p", this->d.name, task.func, task.arg, }; #endif // Execute the task task.func(task.arg); }); } catch(const std::exception &e) { log::critical { log, "'%s': schedule func:%p a:%p tag:%p u:%p prio:%s", d.name, f, a, tag, u, reflect(prio) }; } int ircd::db::database::env::UnSchedule(void *const tag, const Priority prio) noexcept try { ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': unschedule tag:%p prio:%s", d.name, tag, reflect(prio) }; #endif assert(st); auto &tasks { st->tasks.at(prio) }; size_t i(0); for(auto it(begin(tasks)); it != end(tasks); it = tasks.erase(it), ++i) it->cancel(it->arg); return i; } catch(const std::exception &e) { log::critical { log, "'%s': unschedule tag:%p prio:%s :%s", d.name, tag, reflect(prio), e.what() }; return 0; } void ircd::db::database::env::StartThread(void (*f)(void*), void *const a) noexcept { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': start thread func:%p a:%p", d.name, f, a }; #endif throw assertive { "Independent (non-pool) context spawning not yet implemented" }; } void ircd::db::database::env::WaitForJoin() noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wait for all ctx to join", d.name }; #endif assert(st); for(auto &pool : st->pool) pool.join(); } catch(const std::exception &e) { log::critical { log, "'%s': wait for join :%s", d.name, e.what() }; } unsigned int ircd::db::database::env::GetThreadPoolQueueLen(Priority prio) const noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get thread pool queue len prio:%s", d.name, reflect(prio) }; #endif assert(st); const auto &pool { st->pool.at(prio) }; return pool.queued(); } catch(const std::exception &e) { throw assertive { "'%s': set background threads :%s", d.name, e.what() }; } void ircd::db::database::env::SetBackgroundThreads(int num, Priority prio) noexcept try { ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': set background threads num:%d prio:%s", d.name, num, reflect(prio) }; #endif assert(st); auto &pool { st->pool.at(prio) }; const auto &size { ssize_t(pool.size()) }; if(size > num) pool.del(size - num); else if(size < num) pool.add(num - size); } catch(const std::exception &e) { log::critical { log, "'%s': set background threads :%s", d.name, e.what() }; } void ircd::db::database::env::IncBackgroundThreadsIfNeeded(int num, Priority prio) noexcept try { ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': increase background threads num:%d prio:%s", d.name, num, reflect(prio) }; #endif assert(st); auto &pool { st->pool.at(prio) }; pool.add(num); } catch(const std::exception &e) { log::critical { log, "'%s': inc background threads num:%d prio:%s :%s", d.name, num, reflect(prio), e.what() }; } void ircd::db::database::env::LowerThreadPoolIOPriority(Priority pool) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': lower thread pool priority prio:%s", d.name, reflect(pool) }; #endif defaults.LowerThreadPoolIOPriority(pool); } catch(const std::exception &e) { log::critical { log, "'%s': lower thread pool IO priority pool:%s :%s", d.name, reflect(pool), e.what() }; } rocksdb::Status ircd::db::database::env::GetThreadList(std::vector *const list) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get thread list %p (%zu)", d.name, list, list? list->size() : 0UL }; #endif assert(0); return defaults.GetThreadList(list); } catch(const std::exception &e) { log::critical { log, "'%s': get thread list:%p :%s", d.name, list, e.what() }; return error_to_status{e}; } rocksdb::ThreadStatusUpdater * ircd::db::database::env::GetThreadStatusUpdater() const noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get thread status updater", d.name, }; #endif return defaults.GetThreadStatusUpdater(); } catch(const std::exception &e) { log::critical { log, "'%s': get thread status updater :%s", d.name, e.what() }; return nullptr; } uint64_t ircd::db::database::env::GetThreadID() const noexcept try { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get thread ID", d.name, }; #endif return ctx::this_ctx::id(); } catch(const std::exception &e) { throw assertive { "'%s': get thread id :%s", d.name, e.what() }; } int ircd::db::database::env::GetBackgroundThreads(Priority prio) noexcept try { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': get background threads prio:%s", d.name, reflect(prio) }; #endif assert(st); const auto &pool { st->pool.at(prio) }; return pool.size(); } catch(const std::exception &e) { log::critical { log, "'%s': get background threads prio:%s :%s", d.name, reflect(prio), e.what() }; return 0; } // // writable_file // ircd::db::database::env::writable_file::writable_file(database *const &d, const std::string &name, const EnvOptions &env_opts, const bool &trunc) try :d { *d } ,env_opts { env_opts } ,opts{[this, &trunc] { fs::fd::opts ret { std::ios::out | (trunc? std::ios::trunc : std::ios::openmode(0)) }; ret.direct = this->env_opts.use_direct_writes; ret.cloexec = this->env_opts.set_fd_cloexec; return ret; }()} ,fd { name, this->opts } ,preallocation_block_size { ircd::info::page_size } { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': opened wfile:%p fd:%d '%s'", d->name, this, int(fd), name }; #endif // Workaround a RocksDB bug which doesn't propagate EnvOptions properly // on some constructions of WritableFile early on during db open. We'll // get an env_opts.allow_fallocate==true here while it should be false // from the DBOptions at d->opts. We use &= so it's not set to true when // the caller specifically wants it false just for them. assert(d && d->opts); this->env_opts.allow_fallocate &= d->opts->allow_fallocate; //assert(env_opts.allow_fallocate == d->opts->allow_fallocate); } catch(const std::exception &e) { log::error { log, "'%s': opening wfile:%p `%s' :%s", d->name, this, name, e.what() }; } ircd::db::database::env::writable_file::~writable_file() noexcept { Close(); #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': closed wfile:%p fd:%d", d.name, this, int(fd) }; #endif } rocksdb::Status ircd::db::database::env::writable_file::Close() noexcept try { const ctx::uninterruptible::nothrow ui; std::unique_lock lock{mutex}; if(!fd) return Status::OK(); #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p fd:%d close", d.name, this, int(fd) }; #endif fd = fs::fd{}; return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p close :%s", d.name, this, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::error { log, "'%s': wfile:%p close :%s", d.name, this, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file::Flush() noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p fd:%d flush", d.name, this, int(fd), }; #endif fs::fsync_opts opts; fs::fdsync(fd, opts); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p fd:%d flush :%s", d.name, this, int(fd), e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::error { log, "'%s': wfile:%p fd:%d flush :%s", d.name, this, int(fd), e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file::Sync() noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p sync", d.name, this }; #endif fs::fsync_opts opts; fs::fdsync(fd, opts); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p sync :%s", d.name, this, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::error { log, "'%s': wfile:%p sync :%s", d.name, this, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file::Fsync() noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p fsync", d.name, this }; #endif fs::fsync_opts opts; fs::fsync(fd, opts); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p fsync :%s", d.name, this, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::error { log, "'%s': wfile:%p fsync :%s", d.name, this, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file::RangeSync(uint64_t offset, uint64_t length) noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { "'%s': wfile:%p fd:%d range sync offset:%lu length:%lu", d.name, this, int(fd), offset, length }; #endif assert(0); return Status::NotSupported(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p fd:%d range sync offset:%zu length:%zu :%s", d.name, this, int(fd), offset, length, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p fd:%d range sync offset:%zu length:%zu :%s", d.name, this, int(fd), offset, length, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file::Truncate(uint64_t size) noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { "'%s': wfile:%p fd:%d truncate to %lu bytes", d.name, this, int(fd), size }; #endif fs::write_opts wopts; wopts.priority = this->prio; fs::truncate(fd, size, wopts); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p fd:%d truncate to %lu bytes :%s", d.name, this, int(fd), size, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p fd:%d truncate to %lu bytes :%s", d.name, this, int(fd), size, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file::InvalidateCache(size_t offset, size_t length) noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p fd:%d invalidate cache offset:%zu length:%zu", d.name, this, int(fd), offset, length }; #endif if(opts.direct) return Status::OK(); #if defined(HAVE_POSIX_FADVISE) && defined(FADV_DONTNEED) syscall(::posix_fadvise, fd, offset, length, FADV_DONTNEED); #endif return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p fd:%d invalidate cache offset:%zu length:%zu", d.name, this, int(fd), offset, length }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p fd:%d invalidate cache offset:%zu length:%zu", d.name, this, int(fd), offset, length }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file::Append(const Slice &s) noexcept try { assert(!opts.direct); const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p fd:%d append:%p bytes:%zu", d.name, this, int(fd), data(s), size(s), }; #endif fs::write_opts wopts; wopts.priority = this->prio; const const_buffer buf { data(s), size(s) }; fs::append(fd, buf, wopts); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p fd:%d append:%p size:%zu :%s", d.name, this, int(fd), data(s), size(s), e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p fd:%d append:%p size:%zu :%s", d.name, this, int(fd), data(s), size(s), e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file::PositionedAppend(const Slice &s, uint64_t offset) noexcept try { assert(!opts.direct); const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { "'%s': wfile:%p fd:%d append:%p bytes:%zu offset:%lu", d.name, this, int(fd), data(s), size(s), offset }; #endif fs::write_opts wopts; wopts.priority = this->prio; wopts.offset = offset; const const_buffer buf { data(s), size(s) }; fs::append(fd, buf, wopts); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p fd:%d append:%p size:%zu offset:%zu :%s", d.name, this, int(fd), data(s), size(s), offset, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p fd:%d append:%p size:%zu offset:%lu :%s", d.name, this, int(fd), data(s), size(s), offset, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file::Allocate(uint64_t offset, uint64_t length) noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p fd:%d allocate offset:%lu length:%lu%s%s", d.name, this, int(fd), offset, length, env_opts.fallocate_with_keep_size? " KEEP_SIZE" : "", env_opts.allow_fallocate? "" : " (DISABLED)" }; #endif if(!env_opts.allow_fallocate) return Status::NotSupported(); _allocate(offset, length); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p fd:%d allocate offset:%zu length:%zu :%s", d.name, this, int(fd), offset, length, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p fd:%d allocate offset:%zu length:%zu :%s", d.name, this, int(fd), offset, length, e.what() }; return error_to_status{e}; } void ircd::db::database::env::writable_file::PrepareWrite(size_t offset, size_t length) noexcept { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p prepare write offset:%zu length:%zu", d.name, this, offset, length }; #endif if(!env_opts.allow_fallocate) return; _allocate(offset, length); } void ircd::db::database::env::writable_file::_allocate(const size_t &offset, const size_t &length) { const size_t first_block { offset / preallocation_block_size }; const size_t last_block { (offset + length) / preallocation_block_size }; const ssize_t missing_blocks { ssize_t(last_block) - preallocation_last_block }; // Fast bail when the offset and length are behind the last block already // allocated. We don't support windowing here. If this branch is not taken // we'll fallocate() contiguously from the last fallocate() (or offset 0). if(missing_blocks <= 0) return; const ssize_t start_block { preallocation_last_block + 1 }; const size_t allocate_offset { start_block * preallocation_block_size }; const size_t allocate_length { missing_blocks * preallocation_block_size }; fs::write_opts wopts; wopts.offset = allocate_offset; wopts.priority = this->prio; wopts.keep_size = env_opts.fallocate_with_keep_size; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p fd:%d allocating %zd blocks after block:%zu offset:%lu length:%lu%s", d.name, this, int(fd), missing_blocks, start_block, allocate_offset, allocate_length, wopts.keep_size? " KEEP_SIZE" : "" }; #endif assert(env_opts.allow_fallocate); assert(bool(d.opts)); assert(d.opts->allow_fallocate); fs::allocate(fd, allocate_length, wopts); this->preallocation_last_block = last_block; } void ircd::db::database::env::writable_file::GetPreallocationStatus(size_t *const block_size, size_t *const last_allocated_block) noexcept { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; *block_size = this->preallocation_block_size; *last_allocated_block = this->preallocation_last_block; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p get preallocation block_size(%p):%zu last_block(%p):%zu", d.name, this, block_size, *block_size, last_allocated_block, *last_allocated_block }; #endif } void ircd::db::database::env::writable_file::SetPreallocationBlockSize(size_t size) noexcept { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p set preallocation block size:%zu", d.name, this, size }; #endif this->preallocation_block_size = size; } uint64_t ircd::db::database::env::writable_file::GetFileSize() noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p fd:%d get file size", d.name, this, int(fd) }; #endif return fs::size(fd); } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p fd:%d get file size :%s", d.name, this, int(fd), e.what() }; return 0; } void ircd::db::database::env::writable_file::SetIOPriority(Env::IOPriority prio) noexcept { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p IO priority %s", d.name, this, reflect(prio) }; #endif this->prio = prio; } rocksdb::Env::IOPriority ircd::db::database::env::writable_file::GetIOPriority() noexcept { return prio; } void ircd::db::database::env::writable_file::SetWriteLifeTimeHint(WriteLifeTimeHint hint) noexcept { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p hint %s", d.name, this, reflect(hint) }; #endif this->hint = hint; //TODO: fcntl F_SET_FILE_RW_HINT } rocksdb::Env::WriteLifeTimeHint ircd::db::database::env::writable_file::GetWriteLifeTimeHint() noexcept { return hint; } size_t ircd::db::database::env::writable_file::GetUniqueId(char *const id, size_t max_size) const noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { "'%s': wfile:%p get unique id:%p max_size:%zu", d.name, this, id, max_size }; #endif const mutable_buffer buf { id, max_size }; //return size(fs::uuid(fd, buf)); return 0; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p get unique id :%s", d.name, this, e.what() }; return 0; } bool ircd::db::database::env::writable_file::IsSyncThreadSafe() const noexcept try { return true; } catch(...) { return false; } // // writable_file_direct // ircd::db::database::env::writable_file_direct::writable_file_direct(database *const &d, const std::string &name, const EnvOptions &env_opts, const bool &trunc) :writable_file { d, name, env_opts, trunc } ,alignment { fs::block_size(fd) } ,logical_offset { !trunc? fs::size(fd): size_t(0) } ,buffer { alignment, alignment } { zero(buffer); if(!aligned(logical_offset)) throw assertive { "direct writable file requires read into buffer." }; } rocksdb::Status ircd::db::database::env::writable_file_direct::Close() noexcept try { const ctx::uninterruptible::nothrow ui; std::unique_lock lock{mutex}; if(!fd) return Status::OK(); #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p DIRECT fd:%d close", d.name, this, int(fd) }; #endif if(logical_offset > 0 && fs::size(fd) != logical_offset) { fs::write_opts wopts; wopts.priority = this->prio; fs::truncate(fd, logical_offset, wopts); } fd = fs::fd{}; return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p DIRECT close :%s", d.name, this, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::error { log, "'%s': wfile:%p DIRECT close :%s", d.name, this, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file_direct::Truncate(uint64_t size) noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { "'%s': wfile:%p DIRECT fd:%d truncate to %lu bytes", d.name, this, int(fd), size }; #endif fs::write_opts wopts; wopts.priority = this->prio; fs::truncate(fd, size, wopts); logical_offset = size; return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p DIRECT fd:%d truncate to %lu bytes :%s", d.name, this, int(fd), size, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p DIRECT fd:%d truncate to %lu bytes :%s", d.name, this, int(fd), size, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file_direct::Append(const Slice &s) noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p DIRECT fd:%d append:%p%s bytes:%zu%s logical_offset:%zu%s", d.name, this, int(fd), data(s), aligned(data(s))? "" : "#AC", size(s), aligned(size(s))? "" : "#AC", logical_offset, aligned(logical_offset)? "" : "#AC" }; #endif const auto logical_check { logical_offset }; const_buffer buf { slice(s) }; while(!empty(buf)) buf = write(buf); assert(logical_check + size(slice(s)) == logical_offset); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': wfile:%p DIRECT fd:%d append:%p size:%zu :%s", d.name, this, int(fd), data(s), size(s), e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p DIRECT fd:%d append:%p size:%zu :%s", d.name, this, int(fd), data(s), size(s), e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::writable_file_direct::PositionedAppend(const Slice &s, uint64_t offset) noexcept { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p DIRECT fd:%d append:%p%s bytes:%zu%s offset:%zu%s", d.name, this, int(fd), data(s), aligned(data(s))? "" : "#AC", size(s), aligned(size(s))? "" : "#AC", offset, aligned(offset)? "" : "#AC" }; #endif return rocksdb::Status::NotSupported(); } uint64_t ircd::db::database::env::writable_file_direct::GetFileSize() noexcept try { const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{mutex}; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p DIRECT fd:%d get file size", d.name, this, int(fd) }; #endif const auto &ret { logical_offset }; assert(ret <= fs::size(fd)); return ret; } catch(const std::exception &e) { log::critical { log, "'%s': wfile:%p DIRECT fd:%d get file size :%s", d.name, this, int(fd), e.what() }; return 0; } /// (Internal) Append buffer. This function is the internal entry interface /// for appending a buffer of any size and alignment to the file. It is /// internal because it does no locking or error handling back to rocksdb, /// because it's expected to be called from some virtual override which does /// those things. This function will branch off as required to other internal /// write_* functions to properly align and rebuffer the supplied buffer /// eventually culminating in an aligned append to the file. /// /// Calling this function will always result in some write to the file; even /// if temporary buffering is used to achieve alignment; even if the entire /// supplied buffer is hopelessly unaligned: the supplied data will be written /// out some way or another during this call. This means there is no /// requirement to care about flushing the temporary this->buffer after this /// call is made. Note that the temporary this->buffer has no reason to be /// touched by anything other than this function stack. /// /// !!! NOTE !!! /// There is a requirement to truncate the file after this call is made before /// closing the file. If a crash occurs after a write() which was padded out /// to the block alignment: the file size will reflect the padding when it is /// opened at next startup; RocksDB will not detect its terminator character /// sequence and consider this file corrupt. /// !!! /// /// - any offset /// - any data /// - any size ircd::const_buffer ircd::db::database::env::writable_file_direct::write(const const_buffer &buf_) { const_buffer buf { // If the file's offset is aligned and the buffer's data is aligned // we take an easy branch which writes everything and copies any // unaligned overflow to the temporary this->buffer. Nothing is // returned into buf from this branch so there's nothing else done // as this function will return when empty(buf) is checked below. aligned(logical_offset) && aligned(data(buf_))? write_aligned(buf_): // If the file's offset isn't aligned we have to bring it up to // alignment first by using data from the front of buf_. All the // remaining data will be returned to here, which may make a mess // of buf's alignment and size but this frame will deal with that. !aligned(logical_offset)? write_unaligned_off(buf_): // The file's offset is aligned but buf is not aligned. We'll deal // with that in this frame. buf_ }; assert(aligned(logical_offset) || empty(buf)); // buf can be empty here if it was entirely dealt with by the above // branches and there's nothing else to do here. if(empty(buf)) return buf; // Branch on whether the buffer's address is aligned. If so, considering // the logical_offset is aligned here we are then finished. if(aligned(data(buf))) return write_aligned(buf); // Deal with an unaligned buffer by bringing it up to alignment. This // will end up returning an aligned buffer, but may unalign the // logical_offset by doing so. This write() call must be looped until // it empties the buffer. It will be loopy if everything comes very // unaligned out of rocksdb. return write_unaligned_buf(buf); } /// Called when the logical_offset aligned but the supplied buffer's address /// is not aligned. The supplied buffer's size can be unaligned here. This /// function will fill up the temporary this->buffer with the front of buf /// until an aligned address is achieved. /// /// The rest of the buffer which starts at an aligned address is returned and /// not written. It is not written since this function may leave the /// logical_offset at an unaligned address. /// /// * aligned offset /// * unaligned data /// - any size ircd::const_buffer ircd::db::database::env::writable_file_direct::write_unaligned_buf(const const_buffer &buf) { assert(aligned(logical_offset)); assert(!aligned(data(buf))); assert(!aligned(buf)); // Window on the data between the given buffer's pointer and the next // alignment boundary. const const_buffer under_buf { data(buf), std::min(remain(uintptr_t(data(buf))), size(buf)) }; // Window on the data from the alignment boundary to the end of the // given buffer. const const_buffer remaining_buf { buf + size(under_buf) }; assert(size(under_buf) <= size(buf)); assert(size(under_buf) + size(remaining_buf) == size(buf)); assert(data(buf) + size(under_buf) == data(remaining_buf)); assert(aligned(data(remaining_buf)) || empty(remaining_buf)); // We have to use the temporary buffer to deal with the unaligned // leading part of the buffer. Since logical_offset is aligned this // buffer isn't being used right now. We copy as much as possible // to fill out a complete block, both the unaligned and aligned inputs // and zero padding if both are not sufficient. mutable_buffer dst(this->buffer); consume(dst, copy(dst, under_buf)); consume(dst, copy(dst, remaining_buf)); consume(dst, zero(dst)); assert(empty(dst)); // Flush the temporary buffer. _write__aligned(this->buffer, logical_offset); // The logical_offset is only advanced by the underflow amount, even if // we padded the temporary buffer with some remaing_buf data. The caller // is lead to believe they must deal with remaining_buf in its entirety // starting at the logical_offset. logical_offset += size(under_buf); return remaining_buf; } /// Called when the logical_offset is not aligned, indicating that something /// was left in the temporary this->buffer which must be completed out to /// alignment by consuming the front of the argument buf. This function appends /// the front of buf to this->buffer and flushes this->buffer. /// /// logical_offset is incremented, either to the next block alignment or less /// if size(buf) can't get it there. /// /// The rest of buf which isn't used to fill out this->buffer is returned and /// not written. It is not written since the returned data(buf) might not /// be aligned. In fact, this function does not care about the alignment of buf /// at all. /// /// * unaligned offset /// - any data /// - any size ircd::const_buffer ircd::db::database::env::writable_file_direct::write_unaligned_off(const const_buffer &buf) { assert(!aligned(logical_offset)); // Window on the amount of buf we can take to fill up remaining space in // the temporary this->buffer const const_buffer src { data(buf), std::min(size(buf), buffer_remain()) }; // Window on the remaining space in the temporary this->buffer. const mutable_buffer dst { this->buffer + buffer_consumed() }; // Window on the remaining space in dst after src is copied to dst, if any. const mutable_buffer pad { dst + size(src) }; assert(size(dst) - size(pad) == size(src)); assert(size(src) + size(pad) == buffer_remain()); assert(size(src) + size(pad) + buffer_consumed() == alignment); assert(size(src) + buffer_consumed() != alignment || empty(pad)); copy(dst, src); zero(pad); // Backtrack the logical_offset to the aligned offset where this->buffer's // data starts. const auto aligned_offset { align(logical_offset) }; // Write the whole temporary this->buffer at the aligned offset. _write__aligned(this->buffer, aligned_offset); // Only increment the logical_offset to indicate the appending of // what this function added to the temporary this->buffer. logical_offset += size(src); // The logical_offset should either be aligned now after using buf's // data to eliminate the temporary this->buffer, or buf's data wasn't // enough and we'll have to call this function again later with more. assert(aligned(logical_offset) || size(buf) < alignment); // Return the rest of buf which we didn't use to fill out this->buf // Caller will have to deal figuring out how to align the next write. return const_buffer { buf + size(src) }; } /// Write function callable when the current logical_offset and the supplied /// buffer's pointer are both aligned, but the size of the buffer need not /// be aligned. This function thus assumes that the temporary this->buffer /// is empty; it will write as much of the input buffer as aligned. The /// unaligned overflow will be copied to the front of the temporary /// this->buffer which will be padded to alignment and flushed and the /// logical_offset will indicate an increment of the size of the input buffer. /// /// * aligned offset /// * aligned data /// - any size ircd::const_buffer ircd::db::database::env::writable_file_direct::write_aligned(const const_buffer &buf) { assert(aligned(data(buf))); assert(aligned(logical_offset)); // This portion at the end of buf did not fill out to the alignment. const const_buffer overflow { _write_aligned(buf, logical_offset) }; // The aligned portion was written so the offset is incremented here. logical_offset += size(buf) - size(overflow); assert(aligned(logical_offset)); assert(size(overflow) < alignment); assert(aligned(data(overflow)) || empty(overflow)); assert(align(size(buf)) + size(overflow) == size(buf)); assert(blocks(size(buf)) * alignment + size(overflow) == size(buf)); if(!empty(overflow)) { // The overflow is copied to the temporary this->buffer, padded out with // zero and then flushed. The logical offset will be incremented by the // size of that overflow and will no longer be an aligned value, // indicating there is something in the temporary this->buffer. mutable_buffer dst(this->buffer); consume(dst, copy(dst, overflow)); consume(dst, zero(dst)); assert(empty(dst)); _write__aligned(this->buffer, logical_offset); logical_offset += size(overflow); assert(!aligned(logical_offset)); } // Nothing is ever returned and required by the caller here because the // input is aligned to its address and offset and any unaligned size was // dealt with using the temporary this->buffer. return {}; } /// Lower level write to an aligned offset. The pointer of the buffer and the /// offset both have to be aligned to alignment. The size of the buffer does /// not have to be aligned to alignment. The unaligned portion of the input /// buffer (the last partial block), if any, will be returned to the caller. /// /// No modifications to the logical_offset or the temporary this->buffer take /// place here so the caller must manipulate those accordingly. /// /// * aligned data /// * aligned offset /// - any size ircd::const_buffer ircd::db::database::env::writable_file_direct::_write_aligned(const const_buffer &buf, const uint64_t &offset) { assert(aligned(data(buf))); assert(aligned(offset)); // This portion will be written const const_buffer aligned_buf { data(buf), blocks(size(buf)) * alignment }; // This trailing portion will be returned to caller const const_buffer ret { data(buf) + size(aligned_buf), size(buf) - size(aligned_buf) }; assert(!empty(aligned_buf) || size(buf) < alignment); assert(size(aligned_buf) + size(ret) == size(buf)); assert(size(ret) < alignment); // aligned_buf will be empty if buf itself is smaller than the alignment. if(empty(aligned_buf)) { assert(size(ret) == size(buf)); return ret; } _write__aligned(aligned_buf, offset); return ret; } /// Lowest level write of a fully aligned buffer to an aligned offset. The /// pointer of the buffer, the size of the buffer, and the offset ALL have /// to be aligned to alignment for this function. This function is the only /// in the stack which actually writes to the filesystem. /// /// No modifications to the logical_offset take place here so the caller must /// increment that accordingly. The return value is a const_buffer to conform /// with the rest of the stack but it is unconditionally empty here because /// there is no possible overflowing. /// /// * aligned offset /// * aligned data /// * aligned size ircd::const_buffer ircd::db::database::env::writable_file_direct::_write__aligned(const const_buffer &buf, const uint64_t &offset) { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': wfile:%p DIRECT fd:%d write:%p%s bytes:%zu%s offset:%zu%s (logical:%zu)", d.name, this, int(fd), data(buf), aligned(data(buf))? "" : "#AC", size(buf), aligned(size(buf))? "" : "#AC", offset, aligned(offset)? "" : "#AC", logical_offset }; #endif assert(aligned(buf)); assert(aligned(offset)); fs::write_opts wopts; wopts.priority = this->prio; wopts.offset = offset; fs::write(fd, buf, wopts); // Nothing is ever returned to the caller here because the input buffer // and the offset must be fully aligned at this stage. return {}; } size_t ircd::db::database::env::writable_file_direct::buffer_consumed() const { return likely(alignment != 0)? logical_offset % alignment: 0UL; } size_t ircd::db::database::env::writable_file_direct::buffer_remain() const { return remain(logical_offset); } size_t ircd::db::database::env::writable_file_direct::blocks(const size_t &value) const { return likely(alignment != 0)? value / alignment: 0UL; } size_t ircd::db::database::env::writable_file_direct::remain(const size_t &value) const { return likely(alignment != 0)? alignment - (value - align(value)): 0UL; } size_t ircd::db::database::env::writable_file_direct::align(const size_t &value) const { return likely(alignment != 0)? value - (value % alignment): value; } bool ircd::db::database::env::writable_file_direct::aligned(const const_buffer &buf) const { return buffer::aligned(buf, alignment); } bool ircd::db::database::env::writable_file_direct::aligned(const void *const &value) const { return aligned(size_t(value)); } bool ircd::db::database::env::writable_file_direct::aligned(const size_t &value) const { return (alignment == 0) || (value % alignment == 0UL); } // // sequential_file // decltype(ircd::db::database::env::sequential_file::default_opts) ircd::db::database::env::sequential_file::default_opts{[] { ircd::fs::fd::opts ret{std::ios_base::in}; return ret; }()}; ircd::db::database::env::sequential_file::sequential_file(database *const &d, const std::string &name, const EnvOptions &env_opts) try :d { *d } ,opts{[&env_opts] { fs::fd::opts ret{default_opts}; ret.direct = env_opts.use_direct_reads; return ret; }()} ,fd { name, this->opts } ,_buffer_align { fs::block_size(fd) } ,offset { 0 } { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': opened seqfile:%p fd:%d bs:%zu '%s'", d->name, this, int(fd), _buffer_align, name }; #endif } catch(const std::exception &e) { log::error { log, "'%s': opening seqfile:%p `%s' :%s", d->name, this, name, e.what() }; } ircd::db::database::env::sequential_file::~sequential_file() noexcept { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': close seqfile:%p fd:%d", d.name, this, int(fd) }; #endif } rocksdb::Status ircd::db::database::env::sequential_file::Read(size_t length, Slice *const result, char *const scratch) noexcept try { const ctx::uninterruptible::nothrow ui; const std::unique_lock lock { mutex, std::try_to_lock }; // RocksDB sez that this call requires "External synchronization" i.e the // caller, not this class is responsible for exclusion. We assert anyway. if(unlikely(!bool(lock))) throw assertive { "'%s': Unexpected concurrent access to seqfile %p", d.name, this }; assert(result); assert(scratch); #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': seqfile:%p read:%p offset:%zu length:%zu scratch:%p", d.name, this, result, offset, length, scratch }; #endif const mutable_buffer buf { scratch, length }; const const_buffer read { fs::read(fd, buf, offset) }; *result = slice(read); this->offset += size(read); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': seqfile:%p read:%p offset:%zu length:%zu scratch:%p :%s", d.name, this, result, offset, length, scratch, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': seqfile:%p read:%p offset:%zu length:%zu scratch:%p :%s", d.name, this, result, offset, length, scratch, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::sequential_file::PositionedRead(uint64_t offset, size_t length, Slice *const result, char *const scratch) noexcept try { const ctx::uninterruptible::nothrow ui; const std::unique_lock lock { mutex, std::try_to_lock }; if(unlikely(!bool(lock))) throw assertive { "'%s': Unexpected concurrent access to seqfile %p", d.name, this }; assert(result); assert(scratch); #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': seqfile:%p offset:%zu positioned read:%p offset:%zu length:%zu scratch:%p", d.name, this, this->offset, result, offset, length, scratch }; #endif const mutable_buffer buf { scratch, length }; const const_buffer read { fs::read(fd, buf, offset) }; *result = slice(read); this->offset = std::max(this->offset, off_t(offset + size(read))); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': seqfile:%p positioned read:%p offset:%zu length:%zu scratch:%p :%s", d.name, this, result, offset, length, scratch, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': seqfile:%p positioned read:%p offset:%zu length:%zu scratch:%p :%s", d.name, this, result, offset, length, scratch, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::sequential_file::Skip(uint64_t size) noexcept { const ctx::uninterruptible::nothrow ui; const std::unique_lock lock { mutex, std::try_to_lock }; // RocksDB sez that this call requires "External synchronization" i.e the // caller, not this class is responsible for exclusion. We assert anyway. if(unlikely(!bool(lock))) throw assertive { "'%s': Unexpected concurrent access to seqfile %p", d.name, this }; #ifdef RB_DEBUG_DB_ENV log::debug { "'%s': seqfile:%p offset:zu skip:%zu", d.name, this, offset, size }; #endif offset += size; return Status::OK(); } rocksdb::Status ircd::db::database::env::sequential_file::InvalidateCache(size_t offset, size_t length) noexcept try { ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { "'%s': seqfile:%p invalidate cache offset:%zu length:%zu", d.name, this, offset, length }; #endif if(opts.direct) return Status::OK(); #if defined(HAVE_POSIX_FADVISE) && defined(FADV_DONTNEED) syscall(::posix_fadvise, fd, offset, length, FADV_DONTNEED); #endif return Status::OK(); } catch(const fs::error &e) { log::error { "'%s': seqfile:%p invalidate cache offset:%zu length:%zu :%s", d.name, this, offset, length, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { "'%s': seqfile:%p invalidate cache offset:%zu length:%zu :%s", d.name, this, offset, length, e.what() }; return error_to_status{e}; } bool ircd::db::database::env::sequential_file::use_direct_io() const noexcept { return opts.direct; } size_t ircd::db::database::env::sequential_file::GetRequiredBufferAlignment() const noexcept { const auto &ret { _buffer_align }; return ret; } // // random_access_file // decltype(ircd::db::database::env::random_access_file::default_opts) ircd::db::database::env::random_access_file::default_opts{[] { ircd::fs::fd::opts ret{std::ios_base::in}; return ret; }()}; ircd::db::database::env::random_access_file::random_access_file(database *const &d, const std::string &name, const EnvOptions &env_opts) try :d { *d } ,opts{[&env_opts] { fs::fd::opts ret{default_opts}; ret.direct = env_opts.use_direct_reads; return ret; }()} ,fd { name, this->opts } ,_buffer_align { fs::block_size(fd) } { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': opened rfile:%p fd:%d bs:%zu '%s'", d->name, this, int(fd), _buffer_align, name }; #endif } catch(const std::exception &e) { log::error { log, "'%s': opening rfile:%p `%s' :%s", d->name, this, name, e.what() }; } ircd::db::database::env::random_access_file::~random_access_file() noexcept { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': close rfile:%p fd:%d", d.name, this, int(fd) }; #endif } rocksdb::Status ircd::db::database::env::random_access_file::Prefetch(uint64_t offset, size_t length) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rfile:%p prefetch offset:%zu length:%zu", d.name, this, offset, length }; #endif fs::prefetch(fd, length, offset); return Status::OK(); } catch(const fs::error &e) { return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': rfile:%p prefetch offset:%zu length:%zu :%s", d.name, this, offset, length, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::random_access_file::Read(uint64_t offset, size_t length, Slice *const result, char *const scratch) const noexcept try { const ctx::uninterruptible::nothrow ui; assert(result); assert(scratch); #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rfile:%p read:%p offset:%zu length:%zu scratch:%p", d.name, this, result, offset, length, scratch }; #endif const mutable_buffer buf { scratch, length }; const auto read { fs::read(fd, buf, offset) }; *result = slice(read); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': rfile:%p read:%p offset:%zu length:%zu scratch:%p :%s", d.name, this, result, offset, length, scratch, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': rfile:%p read:%p offset:%zu length:%zu scratch:%p :%s", d.name, this, result, offset, length, scratch, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::random_access_file::InvalidateCache(size_t offset, size_t length) noexcept { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rfile:%p invalidate cache offset:%zu length:%zu", d.name, this, offset, length }; #endif if(opts.direct) return Status::OK(); #if defined(HAVE_POSIX_FADVISE) && defined(FADV_DONTNEED) syscall(::posix_fadvise, fd, offset, length, FADV_DONTNEED); #endif return Status::OK(); } size_t ircd::db::database::env::random_access_file::GetUniqueId(char *const id, size_t max_size) const noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rfile:%p get unique id:%p max_size:%zu", d.name, this, id, max_size }; #endif const mutable_buffer buf { id, max_size }; //return size(fs::uuid(fd, buf)); return 0; } catch(const std::exception &e) { log::critical { log, "'%s': rfile:%p GetUniqueId id:%p max_size:%zu :%s", d.name, this, id, max_size, e.what() }; return 0; } void ircd::db::database::env::random_access_file::Hint(AccessPattern pattern) noexcept { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rfile:%p hint %s", d.name, this, reflect(pattern) }; #endif } bool ircd::db::database::env::random_access_file::use_direct_io() const noexcept { return opts.direct; } size_t ircd::db::database::env::random_access_file::GetRequiredBufferAlignment() const noexcept { const auto &ret { _buffer_align }; return ret; } // // random_rw_file // decltype(ircd::db::database::env::random_rw_file::default_opts) ircd::db::database::env::random_rw_file::default_opts{[] { ircd::fs::fd::opts ret { std::ios_base::in | std::ios_base::out }; return ret; }()}; ircd::db::database::env::random_rw_file::random_rw_file(database *const &d, const std::string &name, const EnvOptions &opts) try :d { *d } ,opts{[&opts] { fs::fd::opts ret{default_opts}; ret.direct = opts.use_direct_reads && opts.use_direct_writes; return ret; }()} ,fd { name, this->opts } ,_buffer_align { fs::block_size(fd) } { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': opened rwfile:%p fd:%d bs:%zu '%s'", d->name, this, int(fd), _buffer_align, name }; #endif } catch(const std::exception &e) { log::error { log, "'%s': opening rwfile:%p `%s' :%s", d->name, this, name, e.what() }; } ircd::db::database::env::random_rw_file::~random_rw_file() noexcept { #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': close rwfile:%p fd:%d '%s'", d.name, this, int(fd) }; #endif } rocksdb::Status ircd::db::database::env::random_rw_file::Close() noexcept try { ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': close rwfile:%p fd:%d '%s'", d.name, this, int(fd) }; #endif this->fd = fs::fd{}; return Status::OK(); } catch(const fs::error &e) { log::error { "'%s': rwfile:%p close :%s", d.name, this, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { "'%s': rwfile:%p close :%s", d.name, this, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::random_rw_file::Fsync() noexcept try { ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rwfile:%p fd:%d fsync", d.name, int(fd), this }; #endif fs::fsync_opts opts; fs::fsync(fd, opts); return Status::OK(); } catch(const fs::error &e) { log::error { "'%s': rwfile:%p fd:%d fsync :%s", d.name, this, int(fd), e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { "'%s': rwfile:%p fd:%d fsync :%s", d.name, this, int(fd), e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::random_rw_file::Sync() noexcept try { ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rwfile:%p fd:%d sync", d.name, int(fd), this }; #endif fs::fsync_opts opts; fs::fdsync(fd, opts); return Status::OK(); } catch(const fs::error &e) { log::error { "'%s': rwfile:%p fd:%d sync :%s", d.name, this, int(fd), e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { "'%s': rwfile:%p fd:%d sync :%s", d.name, this, int(fd), e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::random_rw_file::Flush() noexcept try { ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rwfile:%p fd:%d flush", d.name, int(fd), this }; #endif fs::fsync_opts opts; fs::fdsync(fd, opts); return Status::OK(); } catch(const fs::error &e) { log::error { "'%s': rwfile:%p fd:%d flush :%s", d.name, this, int(fd), e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { "'%s': rwfile:%p fd:%d flush :%s", d.name, this, int(fd), e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::random_rw_file::Read(uint64_t offset, size_t length, Slice *const result, char *const scratch) const noexcept try { const ctx::uninterruptible::nothrow ui; assert(result); assert(scratch); #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rwfile:%p read:%p offset:%zu length:%zu scratch:%p", d.name, this, result, offset, length, scratch }; #endif const mutable_buffer buf { scratch, length }; const auto read { fs::read(fd, buf, offset) }; *result = slice(read); return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': rwfile:%p read:%p offset:%zu length:%zu scratch:%p :%s", d.name, this, result, offset, length, scratch, e.what() }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': rwfile:%p read:%p offset:%zu length:%zu scratch:%p :%s", d.name, this, result, offset, length, scratch, e.what() }; return error_to_status{e}; } rocksdb::Status ircd::db::database::env::random_rw_file::Write(uint64_t offset, const Slice &slice) noexcept try { const ctx::uninterruptible::nothrow ui; #ifdef RB_DEBUG_DB_ENV log::debug { log, "'%s': rwfile:%p fd:%d write:%p length:%zu offset:%zu", d.name, this, int(fd), data(slice), size(slice), offset }; #endif const const_buffer buf { data(slice), size(slice) }; const auto read { fs::write(fd, buf, offset) }; return Status::OK(); } catch(const fs::error &e) { log::error { log, "'%s': rwfile:%p fd:%d write:%p length:%zu offset:%zu", d.name, this, int(fd), data(slice), size(slice), offset }; return error_to_status{e}; } catch(const std::exception &e) { log::critical { log, "'%s': rwfile:%p fd:%d write:%p length:%zu offset:%zu", d.name, this, int(fd), data(slice), size(slice), offset }; return error_to_status{e}; } bool ircd::db::database::env::random_rw_file::use_direct_io() const noexcept { return opts.direct; } size_t ircd::db::database::env::random_rw_file::GetRequiredBufferAlignment() const noexcept { const auto &ret { _buffer_align }; return ret; } // // directory // ircd::db::database::env::directory::directory(database *const &d, const std::string &name, std::unique_ptr defaults) :d{*d} ,defaults{std::move(defaults)} { } ircd::db::database::env::directory::~directory() noexcept { } rocksdb::Status ircd::db::database::env::directory::Fsync() noexcept { #ifdef RB_DEBUG_DB_ENV log.debug("'%s': directory:%p fsync", d.name, this); #endif return defaults->Fsync(); } // // file_lock // ircd::db::database::env::file_lock::file_lock(database *const &d) :d{*d} { } ircd::db::database::env::file_lock::~file_lock() noexcept { } // // rocksdb::port (EXPERIMENTAL) // #ifdef IRCD_DB_PORT // // Mutex // static_assert ( sizeof(rocksdb::port::Mutex) <= sizeof(pthread_mutex_t) + 1, "link-time punning of our structure won't work if the structure is larger " "than the one rocksdb has assumed space for." ); rocksdb::port::Mutex::Mutex() { #ifdef RB_DEBUG_DB_PORT_ if(unlikely(!ctx::current)) return; log::debug { db::log, "mutex %lu %p CTOR", ctx::id(), this }; #endif } rocksdb::port::Mutex::Mutex(bool adaptive) :Mutex{} { } rocksdb::port::Mutex::~Mutex() { #ifdef RB_DEBUG_DB_PORT_ if(unlikely(!ctx::current)) return; log::debug { db::log, "mutex %lu %p DTOR", ctx::id(), this }; #endif } void rocksdb::port::Mutex::Lock() { if(unlikely(!ctx::current)) return; #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "mutex %lu %p LOCK", ctx::id(), this }; #endif mu.lock(); } void rocksdb::port::Mutex::Unlock() { if(unlikely(!ctx::current)) return; #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "mutex %lu %p UNLOCK", ctx::id(), this }; #endif assert(mu.locked()); mu.unlock(); } void rocksdb::port::Mutex::AssertHeld() { if(unlikely(!ctx::current)) return; assert(mu.locked()); } // // RWMutex // static_assert ( sizeof(rocksdb::port::RWMutex) <= sizeof(pthread_rwlock_t), "link-time punning of our structure won't work if the structure is larger " "than the one rocksdb has assumed space for." ); rocksdb::port::RWMutex::RWMutex() { #ifdef RB_DEBUG_DB_PORT_ if(unlikely(!ctx::current)) return; log::debug { db::log, "shared_mutex %lu %p CTOR", ctx::id(), this }; #endif } rocksdb::port::RWMutex::~RWMutex() { #ifdef RB_DEBUG_DB_PORT_ if(unlikely(!ctx::current)) return; log::debug { db::log, "shared_mutex %lu %p DTOR", ctx::id(), this }; #endif } void rocksdb::port::RWMutex::ReadLock() { if(unlikely(!ctx::current)) return; #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "shared_mutex %lu %p LOCK SHARED", ctx::id(), this }; #endif assert_main_thread(); mu.lock_shared(); } void rocksdb::port::RWMutex::WriteLock() { if(unlikely(!ctx::current)) return; #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "shared_mutex %lu %p LOCK", ctx::id(), this }; #endif assert_main_thread(); mu.lock(); } void rocksdb::port::RWMutex::ReadUnlock() { if(unlikely(!ctx::current)) return; #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "shared_mutex %lu %p UNLOCK SHARED", ctx::id(), this }; #endif assert_main_thread(); mu.unlock_shared(); } void rocksdb::port::RWMutex::WriteUnlock() { if(unlikely(!ctx::current)) return; #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "shared_mutex %lu %p UNLOCK", ctx::id(), this }; #endif assert_main_thread(); mu.unlock(); } // // CondVar // static_assert ( sizeof(rocksdb::port::CondVar) <= sizeof(pthread_cond_t) + sizeof(void *), "link-time punning of our structure won't work if the structure is larger " "than the one rocksdb has assumed space for." ); rocksdb::port::CondVar::CondVar(Mutex *mu) :mu{mu} { #ifdef RB_DEBUG_DB_PORT_ if(unlikely(!ctx::current)) return; log::debug { db::log, "cond %lu %p %p CTOR", ctx::id(), this, mu }; #endif } rocksdb::port::CondVar::~CondVar() { #ifdef RB_DEBUG_DB_PORT_ if(unlikely(!ctx::current)) return; log::debug { db::log, "cond %lu %p %p DTOR", ctx::id(), this, mu }; #endif } void rocksdb::port::CondVar::Wait() { if(unlikely(!ctx::current)) return; #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "cond %lu %p %p WAIT", ctx::id(), this, mu }; #endif assert(mu); assert_main_thread(); mu->AssertHeld(); cv.wait(mu->mu); } // Returns true if timeout occurred bool rocksdb::port::CondVar::TimedWait(uint64_t abs_time_us) { assert(ctx::current); #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "cond %lu %p %p WAIT_UNTIL %lu", ctx::id(), this, mu, abs_time_us }; #endif assert(mu); assert_main_thread(); mu->AssertHeld(); const std::chrono::microseconds us(abs_time_us); const std::chrono::steady_clock::time_point tp(us); return cv.wait_until(mu->mu, tp) == std::cv_status::timeout; } void rocksdb::port::CondVar::Signal() { if(unlikely(!ctx::current)) return; #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "cond %lu %p %p NOTIFY", ctx::id(), this, mu }; #endif assert_main_thread(); cv.notify_one(); } void rocksdb::port::CondVar::SignalAll() { if(unlikely(!ctx::current)) return; #ifdef RB_DEBUG_DB_PORT log::debug { db::log, "cond %lu %p %p BROADCAST", ctx::id(), this, mu }; #endif assert_main_thread(); cv.notify_all(); } #endif // IRCD_DB_PORT /////////////////////////////////////////////////////////////////////////////// // // db/database/env/state.h // /////////////////////////////////////////////////////////////////////////////// // // db/txn.h // void ircd::db::get(database &d, const uint64_t &seq, const seq_closure &closure) { for_each(d, seq, seq_closure_bool{[&closure] (txn &txn, const uint64_t &seq) { closure(txn, seq); return false; }}); } void ircd::db::for_each(database &d, const uint64_t &seq, const seq_closure &closure) { for_each(d, seq, seq_closure_bool{[&closure] (txn &txn, const uint64_t &seq) { closure(txn, seq); return true; }}); } bool ircd::db::for_each(database &d, const uint64_t &seq, const seq_closure_bool &closure) { std::unique_ptr tit; { const ctx::uninterruptible ui; throw_on_error { d.d->GetUpdatesSince(seq, &tit) }; } assert(bool(tit)); for(; tit->Valid(); tit->Next()) { const ctx::uninterruptible ui; auto batchres { tit->GetBatch() }; throw_on_error { tit->status() }; db::txn txn { d, std::move(batchres.writeBatchPtr) }; assert(bool(txn.wb)); if(!closure(txn, batchres.sequence)) return false; } return true; } std::string ircd::db::debug(const txn &t) { const rocksdb::WriteBatch &wb(t); return db::debug(wb); } void ircd::db::for_each(const txn &t, const std::function &closure) { const auto re{[&closure] (const delta &delta) { closure(delta); return true; }}; const database &d(t); const rocksdb::WriteBatch &wb{t}; txn::handler h{d, re}; wb.Iterate(&h); } bool ircd::db::for_each(const txn &t, const std::function &closure) { const database &d(t); const rocksdb::WriteBatch &wb{t}; txn::handler h{d, closure}; wb.Iterate(&h); return h._continue; } /// /// handler (db/database/txn.h) /// rocksdb::Status ircd::db::txn::handler::PutCF(const uint32_t cfid, const Slice &key, const Slice &val) noexcept { return callback(cfid, op::SET, key, val); } rocksdb::Status ircd::db::txn::handler::DeleteCF(const uint32_t cfid, const Slice &key) noexcept { return callback(cfid, op::DELETE, key, {}); } rocksdb::Status ircd::db::txn::handler::DeleteRangeCF(const uint32_t cfid, const Slice &begin, const Slice &end) noexcept { return callback(cfid, op::DELETE_RANGE, begin, end); } rocksdb::Status ircd::db::txn::handler::SingleDeleteCF(const uint32_t cfid, const Slice &key) noexcept { return callback(cfid, op::SINGLE_DELETE, key, {}); } rocksdb::Status ircd::db::txn::handler::MergeCF(const uint32_t cfid, const Slice &key, const Slice &value) noexcept { return callback(cfid, op::MERGE, key, value); } rocksdb::Status ircd::db::txn::handler::MarkBeginPrepare(bool b) noexcept { ircd::assertion("not implemented"); return Status::OK(); } rocksdb::Status ircd::db::txn::handler::MarkEndPrepare(const Slice &xid) noexcept { ircd::assertion("not implemented"); return Status::OK(); } rocksdb::Status ircd::db::txn::handler::MarkCommit(const Slice &xid) noexcept { ircd::assertion("not implemented"); return Status::OK(); } rocksdb::Status ircd::db::txn::handler::MarkRollback(const Slice &xid) noexcept { ircd::assertion("not implemented"); return Status::OK(); } rocksdb::Status ircd::db::txn::handler::callback(const uint32_t &cfid, const op &op, const Slice &a, const Slice &b) noexcept try { auto &c{d[cfid]}; const delta delta { op, db::name(c), slice(a), slice(b) }; return callback(delta); } catch(const std::exception &e) { _continue = false; log::critical { "txn::handler: cfid[%u]: %s", cfid, e.what() }; ircd::terminate(); } rocksdb::Status ircd::db::txn::handler::callback(const delta &delta) noexcept try { _continue = cb(delta); return Status::OK(); } catch(const std::exception &e) { _continue = false; return Status::OK(); } bool ircd::db::txn::handler::Continue() noexcept { return _continue; } // // txn // ircd::db::txn::txn(database &d) :txn{d, opts{}} { } ircd::db::txn::txn(database &d, const opts &opts) :d{&d} ,wb { std::make_unique(opts.reserve_bytes, opts.max_bytes) } { } ircd::db::txn::txn(database &d, std::unique_ptr &&wb) :d{&d} ,wb{std::move(wb)} { } ircd::db::txn::~txn() noexcept { } void ircd::db::txn::operator()(const sopts &opts) { assert(bool(d)); operator()(*d, opts); } void ircd::db::txn::operator()(database &d, const sopts &opts) { assert(bool(wb)); commit(d, *wb, opts); } void ircd::db::txn::clear() { assert(bool(wb)); wb->Clear(); } size_t ircd::db::txn::size() const { assert(bool(wb)); return wb->Count(); } size_t ircd::db::txn::bytes() const { assert(bool(wb)); return wb->GetDataSize(); } bool ircd::db::txn::has(const op &op) const { assert(bool(wb)); switch(op) { case op::GET: assert(0); return false; case op::SET: return wb->HasPut(); case op::MERGE: return wb->HasMerge(); case op::DELETE: return wb->HasDelete(); case op::DELETE_RANGE: return wb->HasDeleteRange(); case op::SINGLE_DELETE: return wb->HasSingleDelete(); } return false; } bool ircd::db::txn::has(const op &op, const string_view &col) const { return !for_each(*this, delta_closure_bool{[&op, &col] (const auto &delta) { return std::get(delta) == op && std::get(delta) == col; }}); } void ircd::db::txn::at(const op &op, const string_view &col, const delta_closure &closure) const { if(!get(op, col, closure)) throw not_found { "db::txn::at(%s, %s): no matching delta in transaction", reflect(op), col }; } bool ircd::db::txn::get(const op &op, const string_view &col, const delta_closure &closure) const { return !for_each(*this, delta_closure_bool{[&op, &col, &closure] (const delta &delta) { if(std::get(delta) == op && std::get(delta) == col) { closure(delta); return false; } else return true; }}); } bool ircd::db::txn::has(const op &op, const string_view &col, const string_view &key) const { return !for_each(*this, delta_closure_bool{[&op, &col, &key] (const auto &delta) { return std::get(delta) == op && std::get(delta) == col && std::get(delta) == key; }}); } void ircd::db::txn::at(const op &op, const string_view &col, const string_view &key, const value_closure &closure) const { if(!get(op, col, key, closure)) throw not_found { "db::txn::at(%s, %s, %s): no matching delta in transaction", reflect(op), col, key }; } bool ircd::db::txn::get(const op &op, const string_view &col, const string_view &key, const value_closure &closure) const { return !for_each(*this, delta_closure_bool{[&op, &col, &key, &closure] (const delta &delta) { if(std::get(delta) == op && std::get(delta) == col && std::get(delta) == key) { closure(std::get(delta)); return false; } else return true; }}); } ircd::db::txn::operator ircd::db::database &() { assert(bool(d)); return *d; } ircd::db::txn::operator rocksdb::WriteBatch &() { assert(bool(wb)); return *wb; } ircd::db::txn::operator const ircd::db::database &() const { assert(bool(d)); return *d; } ircd::db::txn::operator const rocksdb::WriteBatch &() const { assert(bool(wb)); return *wb; } // // Checkpoint // ircd::db::txn::checkpoint::checkpoint(txn &t) :t{t} { assert(bool(t.wb)); t.wb->SetSavePoint(); } ircd::db::txn::checkpoint::~checkpoint() noexcept { const ctx::uninterruptible ui; if(likely(!std::uncaught_exceptions())) throw_on_error { t.wb->PopSavePoint() }; else throw_on_error { t.wb->RollbackToSavePoint() }; } ircd::db::txn::append::append(txn &t, const string_view &key, const json::iov &iov) { std::for_each(std::begin(iov), std::end(iov), [&t, &key] (const auto &member) { append { t, delta { member.first, // col key, // key member.second // val } }; }); } ircd::db::txn::append::append(txn &t, const delta &delta) { assert(bool(t.d)); append(t, *t.d, delta); } ircd::db::txn::append::append(txn &t, const row::delta &delta) { assert(0); } ircd::db::txn::append::append(txn &t, const cell::delta &delta) { db::append(*t.wb, delta); } ircd::db::txn::append::append(txn &t, column &c, const column::delta &delta) { db::append(*t.wb, c, delta); } ircd::db::txn::append::append(txn &t, database &d, const delta &delta) { db::column c{d[std::get<1>(delta)]}; db::append(*t.wb, c, db::column::delta { std::get(delta), std::get<2>(delta), std::get<3>(delta) }); } /////////////////////////////////////////////////////////////////////////////// // // db/index.h // const ircd::db::gopts ircd::db::index::applied_opts { { get::PREFIX } }; template bool ircd::db::seek(index::const_iterator_base &it, const pos &p) { it.opts |= index::applied_opts; return seek(static_cast(it), p); } template bool ircd::db::seek(index::const_iterator_base &, const pos &); template bool ircd::db::seek(index::const_iterator_base &, const string_view &); ircd::db::index::const_iterator ircd::db::index::begin(const string_view &key, gopts opts) { const_iterator ret { c, {}, std::move(opts) }; seek(ret, key); return ret; } ircd::db::index::const_iterator ircd::db::index::end(const string_view &key, gopts opts) { const_iterator ret { c, {}, std::move(opts) }; if(seek(ret, key)) seek(ret, pos::END); return ret; } /// NOTE: RocksDB says they don't support reverse iteration over a prefix range /// This means we have to forward scan to the end and then walk back! Reverse /// iterations of an index shoud only be used for debugging and statistics! The /// index should be ordered the way it will be primarily accessed using the /// comparator. If it will be accessed in different directions, make another /// index column. ircd::db::index::const_reverse_iterator ircd::db::index::rbegin(const string_view &key, gopts opts) { const_reverse_iterator ret { c, {}, std::move(opts) }; if(seek(ret, key)) { while(seek(ret, pos::NEXT)); seek(ret, pos::PREV); } return ret; } ircd::db::index::const_reverse_iterator ircd::db::index::rend(const string_view &key, gopts opts) { const_reverse_iterator ret { c, {}, std::move(opts) }; if(seek(ret, key)) seek(ret, pos::END); return ret; } // // const_iterator // ircd::db::index::const_iterator & ircd::db::index::const_iterator::operator--() { if(likely(bool(*this))) seek(*this, pos::PREV); else seek(*this, pos::BACK); return *this; } ircd::db::index::const_iterator & ircd::db::index::const_iterator::operator++() { if(likely(bool(*this))) seek(*this, pos::NEXT); else seek(*this, pos::FRONT); return *this; } ircd::db::index::const_reverse_iterator & ircd::db::index::const_reverse_iterator::operator--() { if(likely(bool(*this))) seek(*this, pos::NEXT); else seek(*this, pos::FRONT); return *this; } ircd::db::index::const_reverse_iterator & ircd::db::index::const_reverse_iterator::operator++() { if(likely(bool(*this))) seek(*this, pos::PREV); else seek(*this, pos::BACK); return *this; } const ircd::db::index::const_iterator_base::value_type & ircd::db::index::const_iterator_base::operator*() const { const auto &prefix { describe(*c).prefix }; // Fetch the full value like a standard column first column::const_iterator_base::operator*(); string_view &key{val.first}; // When there's no prefixing this index column is just // like a normal column. Otherwise, we remove the prefix // from the key the user will end up seeing. if(prefix.has && prefix.has(key)) { const auto &first(prefix.get(key)); const auto &second(key.substr(first.size())); key = second; } return val; } const ircd::db::index::const_iterator_base::value_type * ircd::db::index::const_iterator_base::operator->() const { return &this->operator*(); } /////////////////////////////////////////////////////////////////////////////// // // db/cell.h // uint64_t ircd::db::sequence(const cell &c) { const database::snapshot &ss(c); return sequence(database::snapshot(c)); } const std::string & ircd::db::name(const cell &c) { return name(c.c); } void ircd::db::write(const cell::delta &delta, const sopts &sopts) { write(&delta, &delta + 1, sopts); } void ircd::db::write(const sopts &sopts, const std::initializer_list &deltas) { write(deltas, sopts); } void ircd::db::write(const std::initializer_list &deltas, const sopts &sopts) { write(std::begin(deltas), std::end(deltas), sopts); } void ircd::db::write(const cell::delta *const &begin, const cell::delta *const &end, const sopts &sopts) { if(begin == end) return; // Find the database through one of the cell's columns. cell::deltas // may come from different columns so we do nothing else with this. auto &front(*begin); column &c(std::get(front)->c); database &d(c); rocksdb::WriteBatch batch; std::for_each(begin, end, [&batch] (const cell::delta &delta) { append(batch, delta); }); commit(d, batch, sopts); } template bool ircd::db::seek(cell &c, const pos &p, gopts opts) { column &cc(c); database::column &dc(cc); if(!opts.snapshot) opts.snapshot = c.ss; const auto ropts(make_opts(opts)); return seek(dc, p, ropts, c.it); } template bool ircd::db::seek(cell &, const pos &, gopts); template bool ircd::db::seek(cell &, const string_view &, gopts); // Linkage for incomplete rocksdb::Iterator ircd::db::cell::cell() { } ircd::db::cell::cell(database &d, const string_view &colname, gopts opts) :cell { column(d[colname]), std::unique_ptr{}, std::move(opts) } { } ircd::db::cell::cell(database &d, const string_view &colname, const string_view &index, gopts opts) :cell { column(d[colname]), index, std::move(opts) } { } ircd::db::cell::cell(column column, const string_view &index, gopts opts) :c{std::move(column)} ,ss{opts.snapshot} ,it { !index.empty()? seek(this->c, index, opts): std::unique_ptr{} } { if(bool(this->it)) if(!valid_eq(*this->it, index)) this->it.reset(); } ircd::db::cell::cell(column column, const string_view &index, std::unique_ptr it, gopts opts) :c{std::move(column)} ,ss{opts.snapshot} ,it{std::move(it)} { if(index.empty()) return; seek(*this, index, opts); if(!valid_eq(*this->it, index)) this->it.reset(); } ircd::db::cell::cell(column column, std::unique_ptr it, gopts opts) :c{std::move(column)} ,ss{std::move(opts.snapshot)} ,it{std::move(it)} { } // Linkage for incomplete rocksdb::Iterator ircd::db::cell::cell(cell &&o) noexcept :c{std::move(o.c)} ,ss{std::move(o.ss)} ,it{std::move(o.it)} { } // Linkage for incomplete rocksdb::Iterator ircd::db::cell & ircd::db::cell::operator=(cell &&o) noexcept { c = std::move(o.c); ss = std::move(o.ss); it = std::move(o.it); return *this; } // Linkage for incomplete rocksdb::Iterator ircd::db::cell::~cell() noexcept { } bool ircd::db::cell::load(const string_view &index, gopts opts) { database &d(c); if(valid(index) && !opts.snapshot && sequence(ss) == sequence(d)) return true; if(bool(opts.snapshot)) { this->it.reset(); this->ss = std::move(opts.snapshot); } database::column &c(this->c); return seek(c, index, opts, this->it); } ircd::db::cell & ircd::db::cell::operator=(const string_view &s) { write(c, key(), s); return *this; } void ircd::db::cell::operator()(const op &op, const string_view &val, const sopts &sopts) { write(cell::delta{op, *this, val}, sopts); } ircd::db::cell::operator string_view() { return val(); } ircd::db::cell::operator string_view() const { return val(); } ircd::string_view ircd::db::cell::val() { if(!valid()) load(); return likely(valid())? db::val(*it) : string_view{}; } ircd::string_view ircd::db::cell::key() { if(!valid()) load(); return likely(valid())? db::key(*it) : string_view{}; } ircd::string_view ircd::db::cell::val() const { return likely(valid())? db::val(*it) : string_view{}; } ircd::string_view ircd::db::cell::key() const { return likely(valid())? db::key(*it) : string_view{}; } bool ircd::db::cell::valid() const { return bool(it) && db::valid(*it); } bool ircd::db::cell::valid(const string_view &s) const { return bool(it) && db::valid_eq(*it, s); } bool ircd::db::cell::valid_gt(const string_view &s) const { return bool(it) && db::valid_gt(*it, s); } bool ircd::db::cell::valid_lte(const string_view &s) const { return bool(it) && db::valid_lte(*it, s); } /////////////////////////////////////////////////////////////////////////////// // // db/row.h // void ircd::db::del(row &row, const sopts &sopts) { write(row::delta{op::DELETE, row}, sopts); } void ircd::db::write(const row::delta &delta, const sopts &sopts) { write(&delta, &delta + 1, sopts); } void ircd::db::write(const sopts &sopts, const std::initializer_list &deltas) { write(deltas, sopts); } void ircd::db::write(const std::initializer_list &deltas, const sopts &sopts) { write(std::begin(deltas), std::end(deltas), sopts); } void ircd::db::write(const row::delta *const &begin, const row::delta *const &end, const sopts &sopts) { // Count the total number of cells for this transaction. const auto cells { std::accumulate(begin, end, size_t(0), [] (auto ret, const row::delta &delta) { const auto &row(std::get(delta)); return ret += row->size(); }) }; //TODO: allocator? std::vector deltas; deltas.reserve(cells); // Compose all of the cells from all of the rows into a single txn std::for_each(begin, end, [&deltas] (const auto &delta) { const auto &op(std::get(delta)); const auto &row(std::get(delta)); std::for_each(std::begin(*row), std::end(*row), [&deltas, &op] (auto &cell) { // For operations like DELETE which don't require a value in // the delta, we can skip a potentially expensive load of the cell. const auto value { value_required(op)? cell.val() : string_view{} }; deltas.emplace_back(op, cell, value); }); }); // Commitment write(&deltas.front(), &deltas.front() + deltas.size(), sopts); } size_t ircd::db::seek(row &r, const string_view &key) { // This frame can't be interrupted because it may have requests // pending in the request pool which must synchronize back here. const ctx::uninterruptible ui; #ifdef RB_DEBUG_DB_SEEK const ircd::timer timer; #endif size_t ret{0}; ctx::latch latch{r.size()}; const auto closure{[&latch, &ret, &key] (auto &cell) { ret += bool(seek(cell, key)); latch.count_down(); }}; for(auto &cell : r) { db::column &column(cell); //TODO: should check a bloom filter on the cache for this branch //TODO: because right now double-querying the cache is gross. if(!exists(cache(column), key)) request([&closure, &cell] { closure(cell); }); else closure(cell); } latch.wait(); #ifdef RB_DEBUG_DB_SEEK const column &c(r[0]); const database &d(c); log::debug { log, "'%s' %lu:%lu '%s' row SEEK KEY %zu of %zu in %ld$us", name(d), sequence(d), sequence(r[0]), name(c), ret, r.size(), timer.at().count() }; #endif assert(ret <= r.size()); return ret; } // // row // #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wstack-usage=" ircd::db::row::row(database &d, const string_view &key, const vector_view &colnames, const vector_view &buf, gopts opts) :vector_view { buf.data(), colnames.empty()? d.columns.size(): colnames.size() } { using std::end; using std::begin; using rocksdb::Iterator; using rocksdb::ColumnFamilyHandle; if(!opts.snapshot) opts.snapshot = database::snapshot(d); const rocksdb::ReadOptions options { make_opts(opts) }; const size_t &column_count { vector_view::size() }; database::column *colptr[column_count]; if(colnames.empty()) std::transform(begin(d.column_names), end(d.column_names), colptr, [&colnames] (const auto &p) { return p.second.get(); }); else std::transform(begin(colnames), end(colnames), colptr, [&d] (const auto &name) { return &d[name]; }); std::vector iterators; { // The goal here is to optimize away the heap allocation incurred by // having to pass RocksDB the specific std::vector type which doesn't // have room for an allocator. We use a single thread_local vector // and reserve() it with one worst-case size of all possible columns. // Then we resize it to this specific call's requirements and copy the // column pointers. On sane platforms only one allocation ever occurs. thread_local std::vector handles; assert(column_count <= d.columns.size()); handles.reserve(d.columns.size()); handles.resize(column_count); std::transform(colptr, colptr + column_count, begin(handles), [] (database::column *const &ptr) { return ptr->handle.get(); }); // This has been seen to lead to IO and block the ircd::ctx; // specifically when background options are aggressive and shortly // after db opens. throw_on_error { d.d->NewIterators(options, handles, &iterators) }; } for(size_t i(0); i < this->size() && i < column_count; ++i) { std::unique_ptr it(iterators.at(i)); (*this)[i] = cell { *colptr[i], std::move(it), opts }; } if(key) seek(*this, key); } #pragma GCC diagnostic pop void ircd::db::row::operator()(const op &op, const string_view &col, const string_view &val, const sopts &sopts) { write(cell::delta{op, (*this)[col], val}, sopts); } ircd::db::cell & ircd::db::row::operator[](const string_view &column) { const auto it(find(column)); if(unlikely(it == end())) throw schema_error { "column '%s' not specified in the descriptor schema", column }; return *it; } const ircd::db::cell & ircd::db::row::operator[](const string_view &column) const { const auto it(find(column)); if(unlikely(it == end())) throw schema_error { "column '%s' not specified in the descriptor schema", column }; return *it; } ircd::db::row::iterator ircd::db::row::find(const string_view &col) { return std::find_if(std::begin(*this), std::end(*this), [&col] (const auto &cell) { return name(cell.c) == col; }); } ircd::db::row::const_iterator ircd::db::row::find(const string_view &col) const { return std::find_if(std::begin(*this), std::end(*this), [&col] (const auto &cell) { return name(cell.c) == col; }); } bool ircd::db::row::valid() const { return std::any_of(std::begin(*this), std::end(*this), [] (const auto &cell) { return cell.valid(); }); } bool ircd::db::row::valid(const string_view &s) const { return std::any_of(std::begin(*this), std::end(*this), [&s] (const auto &cell) { return cell.valid(s); }); } /////////////////////////////////////////////////////////////////////////////// // // db/column.h // std::string ircd::db::read(column &column, const string_view &key, const gopts &gopts) { std::string ret; const auto closure([&ret] (const string_view &src) { ret.assign(begin(src), end(src)); }); column(key, closure, gopts); return ret; } ircd::string_view ircd::db::read(column &column, const string_view &key, const mutable_buffer &buf, const gopts &gopts) { string_view ret; const auto closure([&ret, &buf] (const string_view &src) { ret = { data(buf), copy(buf, src) }; }); column(key, closure, gopts); return ret; } std::string ircd::db::read(column &column, const string_view &key, bool &found, const gopts &gopts) { std::string ret; const auto closure([&ret] (const string_view &src) { ret.assign(begin(src), end(src)); }); found = column(key, std::nothrow, closure, gopts); return ret; } ircd::string_view ircd::db::read(column &column, const string_view &key, bool &found, const mutable_buffer &buf, const gopts &gopts) { string_view ret; const auto closure([&buf, &ret] (const string_view &src) { ret = { data(buf), copy(buf, src) }; }); found = column(key, std::nothrow, closure, gopts); return ret; } rocksdb::Cache * ircd::db::cache(column &column) { database::column &c(column); return c.table_opts.block_cache.get(); } rocksdb::Cache * ircd::db::cache_compressed(column &column) { database::column &c(column); return c.table_opts.block_cache_compressed.get(); } const rocksdb::Cache * ircd::db::cache(const column &column) { const database::column &c(column); return c.table_opts.block_cache.get(); } const rocksdb::Cache * ircd::db::cache_compressed(const column &column) { const database::column &c(column); return c.table_opts.block_cache_compressed.get(); } template<> ircd::db::prop_str ircd::db::property(const column &column, const string_view &name) { std::string ret; database::column &c(const_cast(column)); database &d(const_cast(column)); if(!d.d->GetProperty(c, slice(name), &ret)) throw not_found { "'property '%s' for column '%s' in '%s' not found.", name, db::name(column), db::name(d) }; return ret; } template<> ircd::db::prop_int ircd::db::property(const column &column, const string_view &name) { uint64_t ret(0); database::column &c(const_cast(column)); database &d(const_cast(column)); if(!d.d->GetIntProperty(c, slice(name), &ret)) throw not_found { "property '%s' for column '%s' in '%s' not found or not an integer.", name, db::name(column), db::name(d) }; return ret; } template<> ircd::db::prop_map ircd::db::property(const column &column, const string_view &name) { std::map ret; database::column &c(const_cast(column)); database &d(const_cast(column)); if(!d.d->GetMapProperty(c, slice(name), &ret)) ret.emplace(std::string{name}, property(column, name)); return ret; } size_t ircd::db::bytes(const column &column) { rocksdb::ColumnFamilyMetaData cfm; database &d(const_cast(column)); database::column &c(const_cast(column)); assert(bool(c.handle)); d.d->GetColumnFamilyMetaData(c.handle.get(), &cfm); return cfm.size; } size_t ircd::db::file_count(const column &column) { rocksdb::ColumnFamilyMetaData cfm; database &d(const_cast(column)); database::column &c(const_cast(column)); assert(bool(c.handle)); d.d->GetColumnFamilyMetaData(c.handle.get(), &cfm); return cfm.file_count; } uint32_t ircd::db::id(const column &column) { const database::column &c(column); return id(c); } const std::string & ircd::db::name(const column &column) { const database::column &c(column); return name(c); } const ircd::db::descriptor & ircd::db::describe(const column &column) { const database::column &c(column); return describe(c); } std::vector ircd::db::files(const column &column) { database::column &c(const_cast(column)); database &d(*c.d); rocksdb::ColumnFamilyMetaData cfmd; d.d->GetColumnFamilyMetaData(c, &cfmd); size_t count(0); for(const auto &level : cfmd.levels) count += level.files.size(); std::vector ret; ret.reserve(count); for(auto &level : cfmd.levels) for(auto &file : level.files) ret.emplace_back(std::move(file.name)); return ret; } void ircd::db::drop(column &column) { database::column &c(column); drop(c); } void ircd::db::sort(column &column, const bool &blocking) { database::column &c(column); database &d(*c.d); rocksdb::FlushOptions opts; opts.wait = blocking; const ctx::uninterruptible::nothrow ui; const std::lock_guard lock{write_mutex}; log::debug { log, "'%s':'%s' @%lu FLUSH (sort) %s", name(d), name(c), sequence(d), blocking? "blocking"_sv: "non-blocking"_sv }; throw_on_error { d.d->Flush(opts, c) }; } void ircd::db::compact(column &column, const int &level_, const compactor &cb) { database::column &c(column); database &d(*c.d); rocksdb::ColumnFamilyMetaData cfmd; d.d->GetColumnFamilyMetaData(c, &cfmd); for(const auto &level : cfmd.levels) { if(level_ != -1 && level.level != level_) continue; if(level.files.empty()) continue; rocksdb::CompactionOptions opts; { const rocksdb::ColumnFamilyOptions &copts(c); opts.compression = copts.compression; } std::vector files(level.files.size()); std::transform(level.files.begin(), level.files.end(), files.begin(), [] (auto &metadata) { return std::move(metadata.name); }); // Locking the write_mutex here prevents writes during a column's // compaction. This is needed because if contention occurs inside // rocksdb we will hit some std::mutex's which do not use the // rocksdb::port wrapper and deadlock the process. (It is an error // on the part of rocksdb to directly use std::mutex rather than their // port wrapper). const ctx::uninterruptible ui; const std::lock_guard lock{write_mutex}; // Save and restore the existing filter callback so we can allow our // caller to use theirs. Note that this manual compaction should be // exclusive for this column (no background compaction should be // occurring, at least one relying on this filter). auto their_filter(std::move(c.cfilter.user)); const unwind unfilter{[&c, &their_filter] { c.cfilter.user = std::move(their_filter); }}; c.cfilter.user = cb; log::debug { log, "'%s':'%s' COMPACT level:%d files:%zu size:%zu", name(d), name(c), level.level, level.files.size(), level.size }; throw_on_error { d.d->CompactFiles(opts, c, files, level.level) }; } } void ircd::db::compact(column &column, const std::pair &range, const int &to_level, const compactor &cb) { database &d(column); database::column &c(column); const auto begin(slice(range.first)); const rocksdb::Slice *const b { empty(range.first)? nullptr : &begin }; const auto end(slice(range.second)); const rocksdb::Slice *const e { empty(range.second)? nullptr : &end }; rocksdb::CompactRangeOptions opts; opts.change_level = true; opts.target_level = std::max(to_level, -1); opts.allow_write_stall = true; const ctx::uninterruptible ui; const std::lock_guard lock{write_mutex}; // Save and restore the existing filter callback so we can allow our // caller to use theirs. Note that this manual compaction should be // exclusive for this column (no background compaction should be // occurring, at least one relying on this filter). auto their_filter(std::move(c.cfilter.user)); const unwind unfilter{[&c, &their_filter] { c.cfilter.user = std::move(their_filter); }}; c.cfilter.user = cb; log::debug { log, "'%s':'%s' @%lu COMPACT [%s, %s] to level %d", name(d), name(c), sequence(d), range.first, range.second, opts.target_level }; throw_on_error { d.d->CompactRange(opts, c, b, e) }; } void ircd::db::setopt(column &column, const string_view &key, const string_view &val) { database &d(column); database::column &c(column); const std::unordered_map options { { std::string{key}, std::string{val} } }; const std::lock_guard lock{write_mutex}; const ctx::uninterruptible::nothrow ui; throw_on_error { d.d->SetOptions(c, options) }; } void ircd::db::ingest(column &column, const string_view &path) { database &d(column); database::column &c(column); rocksdb::IngestExternalFileOptions opts; opts.allow_global_seqno = true; opts.allow_blocking_flush = true; // Automatically determine if we can avoid issuing new sequence // numbers by considering this ingestion as "backfill" of missing // data which did actually exist but was physically removed. const auto &copts{d.d->GetOptions(c)}; opts.ingest_behind = copts.allow_ingest_behind; const std::vector files { { std::string{path} } }; const std::lock_guard lock{write_mutex}; const ctx::uninterruptible::nothrow ui; throw_on_error { d.d->IngestExternalFile(c, files, opts) }; } void ircd::db::del(column &column, const string_view &key, const sopts &sopts) { database &d(column); database::column &c(column); auto opts(make_opts(sopts)); const std::lock_guard lock{write_mutex}; const ctx::uninterruptible::nothrow ui; log::debug { log, "'%s' %lu '%s' DELETE key(%zu B)", name(d), sequence(d), name(c), key.size() }; throw_on_error { d.d->Delete(opts, c, slice(key)) }; } void ircd::db::write(column &column, const string_view &key, const const_buffer &val, const sopts &sopts) { database &d(column); database::column &c(column); auto opts(make_opts(sopts)); const std::lock_guard lock{write_mutex}; const ctx::uninterruptible::nothrow ui; log::debug { log, "'%s' %lu '%s' PUT key(%zu B) val(%zu B)", name(d), sequence(d), name(c), size(key), size(val) }; throw_on_error { d.d->Put(opts, c, slice(key), slice(val)) }; } void ircd::db::prefetch(column &column, const string_view &key, const gopts &gopts) { if(exists(cache(column), key)) return; request([column(column), key(std::string(key)), gopts] () mutable { has(column, key, gopts); }); } bool ircd::db::cached(column &column, const string_view &key, const gopts &gopts) { database &d(column); database::column &c(column); auto opts(make_opts(gopts)); opts.read_tier = NON_BLOCKING; opts.fill_cache = false; std::unique_ptr it; if(!seek(c, key, opts, it)) return false; assert(bool(it)); return valid_eq(*it, key); } bool ircd::db::has(column &column, const string_view &key, const gopts &gopts) { database &d(column); database::column &c(column); // Perform a co-RP query to the filtration // NOTE disabled for rocksdb >= v5.15 due to a regression // where rocksdb does not init SuperVersion data in the column // family handle and this codepath triggers null derefs and ub. if(0 && c.table_opts.filter_policy) { const auto k(slice(key)); auto opts(make_opts(gopts)); opts.read_tier = NON_BLOCKING; thread_local std::string discard; if(!d.d->KeyMayExist(opts, c, k, &discard, nullptr)) return false; } const auto it { seek(column, key, gopts) }; return valid_eq(*it, key); } // // column // ircd::db::column::column(database::column &c) :c{&c} { } ircd::db::column::column(database &d, const string_view &column_name) :c{&d[column_name]} {} void ircd::db::column::operator()(const delta &delta, const sopts &sopts) { operator()(&delta, &delta + 1, sopts); } void ircd::db::column::operator()(const sopts &sopts, const std::initializer_list &deltas) { operator()(deltas, sopts); } void ircd::db::column::operator()(const std::initializer_list &deltas, const sopts &sopts) { operator()(std::begin(deltas), std::end(deltas), sopts); } void ircd::db::column::operator()(const delta *const &begin, const delta *const &end, const sopts &sopts) { database &d(*this); rocksdb::WriteBatch batch; std::for_each(begin, end, [this, &batch] (const delta &delta) { append(batch, *this, delta); }); commit(d, batch, sopts); } void ircd::db::column::operator()(const string_view &key, const gopts &gopts, const view_closure &func) { return operator()(key, func, gopts); } void ircd::db::column::operator()(const string_view &key, const view_closure &func, const gopts &gopts) { const auto it(seek(*this, key, gopts)); valid_eq_or_throw(*it, key); func(val(*it)); } bool ircd::db::column::operator()(const string_view &key, const std::nothrow_t, const gopts &gopts, const view_closure &func) { return operator()(key, std::nothrow, func, gopts); } bool ircd::db::column::operator()(const string_view &key, const std::nothrow_t, const view_closure &func, const gopts &gopts) { const auto it(seek(*this, key, gopts)); if(!valid_eq(*it, key)) return false; func(val(*it)); return true; } ircd::db::cell ircd::db::column::operator[](const string_view &key) const { return { *this, key }; } ircd::db::column::operator const descriptor &() const { assert(c->descriptor); return *c->descriptor; } // // column::const_iterator // ircd::db::column::const_iterator ircd::db::column::end(gopts gopts) { const_iterator ret { c, {}, std::move(gopts) }; seek(ret, pos::END); return ret; } ircd::db::column::const_iterator ircd::db::column::begin(gopts gopts) { const_iterator ret { c, {}, std::move(gopts) }; seek(ret, pos::FRONT); return ret; } ircd::db::column::const_reverse_iterator ircd::db::column::rend(gopts gopts) { const_reverse_iterator ret { c, {}, std::move(gopts) }; seek(ret, pos::END); return ret; } ircd::db::column::const_reverse_iterator ircd::db::column::rbegin(gopts gopts) { const_reverse_iterator ret { c, {}, std::move(gopts) }; seek(ret, pos::BACK); return ret; } ircd::db::column::const_iterator ircd::db::column::upper_bound(const string_view &key, gopts gopts) { auto it(lower_bound(key, std::move(gopts))); if(it && it.it->key().compare(slice(key)) == 0) ++it; return it; } ircd::db::column::const_iterator ircd::db::column::find(const string_view &key, gopts gopts) { auto it(lower_bound(key, gopts)); if(!it || it.it->key().compare(slice(key)) != 0) return end(gopts); return it; } ircd::db::column::const_iterator ircd::db::column::lower_bound(const string_view &key, gopts gopts) { const_iterator ret { c, {}, std::move(gopts) }; seek(ret, key); return ret; } ircd::db::column::const_iterator & ircd::db::column::const_iterator::operator--() { if(likely(bool(*this))) seek(*this, pos::PREV); else seek(*this, pos::BACK); return *this; } ircd::db::column::const_iterator & ircd::db::column::const_iterator::operator++() { if(likely(bool(*this))) seek(*this, pos::NEXT); else seek(*this, pos::FRONT); return *this; } ircd::db::column::const_reverse_iterator & ircd::db::column::const_reverse_iterator::operator--() { if(likely(bool(*this))) seek(*this, pos::NEXT); else seek(*this, pos::FRONT); return *this; } ircd::db::column::const_reverse_iterator & ircd::db::column::const_reverse_iterator::operator++() { if(likely(bool(*this))) seek(*this, pos::PREV); else seek(*this, pos::BACK); return *this; } ircd::db::column::const_iterator_base::const_iterator_base(const_iterator_base &&o) noexcept :c{std::move(o.c)} ,opts{std::move(o.opts)} ,it{std::move(o.it)} ,val{std::move(o.val)} { } ircd::db::column::const_iterator_base & ircd::db::column::const_iterator_base::operator=(const_iterator_base &&o) noexcept { c = std::move(o.c); opts = std::move(o.opts); it = std::move(o.it); val = std::move(o.val); return *this; } // linkage for incmplete rocksdb::Iterator ircd::db::column::const_iterator_base::const_iterator_base() { } // linkage for incmplete rocksdb::Iterator ircd::db::column::const_iterator_base::~const_iterator_base() noexcept { } ircd::db::column::const_iterator_base::const_iterator_base(database::column *const &c, std::unique_ptr &&it, gopts opts) :c{c} ,opts{std::move(opts)} ,it{std::move(it)} { } const ircd::db::column::const_iterator_base::value_type & ircd::db::column::const_iterator_base::operator*() const { assert(it && valid(*it)); val.first = db::key(*it); val.second = db::val(*it); return val; } const ircd::db::column::const_iterator_base::value_type * ircd::db::column::const_iterator_base::operator->() const { return &operator*(); } bool ircd::db::column::const_iterator_base::operator!() const { return !static_cast(*this); } ircd::db::column::const_iterator_base::operator bool() const { if(!it) return false; if(!valid(*it)) return false; return true; } bool ircd::db::operator!=(const column::const_iterator_base &a, const column::const_iterator_base &b) { return !(a == b); } bool ircd::db::operator==(const column::const_iterator_base &a, const column::const_iterator_base &b) { if(a && b) { const auto &ak(a.it->key()); const auto &bk(b.it->key()); return ak.compare(bk) == 0; } if(!a && !b) return true; return false; } bool ircd::db::operator>(const column::const_iterator_base &a, const column::const_iterator_base &b) { if(a && b) { const auto &ak(a.it->key()); const auto &bk(b.it->key()); return ak.compare(bk) == 1; } if(!a && b) return true; if(!a && !b) return false; assert(!a && b); return false; } bool ircd::db::operator<(const column::const_iterator_base &a, const column::const_iterator_base &b) { if(a && b) { const auto &ak(a.it->key()); const auto &bk(b.it->key()); return ak.compare(bk) == -1; } if(!a && b) return false; if(!a && !b) return false; assert(a && !b); return true; } template bool ircd::db::seek(column::const_iterator_base &it, const pos &p) { database::column &c(it); return seek(c, p, it.opts, it.it); } template bool ircd::db::seek(column::const_iterator_base &, const pos &); template bool ircd::db::seek(column::const_iterator_base &, const string_view &); /////////////////////////////////////////////////////////////////////////////// // // comparator.h // // // linkage placements for integer comparators so they all have the same addr // ircd::db::cmp_int64_t::cmp_int64_t() { } ircd::db::cmp_int64_t::~cmp_int64_t() noexcept { } ircd::db::cmp_uint64_t::cmp_uint64_t() { } ircd::db::cmp_uint64_t::~cmp_uint64_t() noexcept { } ircd::db::reverse_cmp_int64_t::reverse_cmp_int64_t() { } ircd::db::reverse_cmp_int64_t::~reverse_cmp_int64_t() noexcept { } ircd::db::reverse_cmp_uint64_t::reverse_cmp_uint64_t() { } ircd::db::reverse_cmp_uint64_t::~reverse_cmp_uint64_t() noexcept { } // // cmp_string_view // ircd::db::cmp_string_view::cmp_string_view() :db::comparator{"string_view", &less, &equal} { } bool ircd::db::cmp_string_view::less(const string_view &a, const string_view &b) { return a < b; } bool ircd::db::cmp_string_view::equal(const string_view &a, const string_view &b) { return a == b; } // // reverse_cmp_string_view // ircd::db::reverse_cmp_string_view::reverse_cmp_string_view() :db::comparator{"reverse_string_view", &less, &equal} { } bool ircd::db::reverse_cmp_string_view::less(const string_view &a, const string_view &b) { /// RocksDB sez things will not work correctly unless a shorter string /// result returns less than a longer string even if one intends some /// reverse ordering if(a.size() < b.size()) return true; /// Furthermore, b.size() < a.size() returning false from this function /// appears to not be correct. The reversal also has to also come in /// the form of a bytewise forward iteration. return std::memcmp(a.data(), b.data(), std::min(a.size(), b.size())) > 0; } bool ircd::db::reverse_cmp_string_view::equal(const string_view &a, const string_view &b) { return a == b; } /////////////////////////////////////////////////////////////////////////////// // // merge.h // std::string ircd::db::merge_operator(const string_view &key, const std::pair &delta) { //ircd::json::index index{delta.first}; //index += delta.second; //return index; assert(0); return {}; } /////////////////////////////////////////////////////////////////////////////// // // writebatch // void ircd::db::append(rocksdb::WriteBatch &batch, const cell::delta &delta) { auto &column(std::get(delta)->c); append(batch, column, column::delta { std::get(delta), std::get(delta)->key(), std::get(delta) }); } void ircd::db::append(rocksdb::WriteBatch &batch, column &column, const column::delta &delta) { database::column &c(column); const auto k(slice(std::get<1>(delta))); const auto v(slice(std::get<2>(delta))); switch(std::get<0>(delta)) { case op::GET: assert(0); break; case op::SET: batch.Put(c, k, v); break; case op::MERGE: batch.Merge(c, k, v); break; case op::DELETE: batch.Delete(c, k); break; case op::DELETE_RANGE: batch.DeleteRange(c, k, v); break; case op::SINGLE_DELETE: batch.SingleDelete(c, k); break; } } void ircd::db::commit(database &d, rocksdb::WriteBatch &batch, const sopts &sopts) { const auto opts(make_opts(sopts)); commit(d, batch, opts); } void ircd::db::commit(database &d, rocksdb::WriteBatch &batch, const rocksdb::WriteOptions &opts) { #ifdef RB_DEBUG_DB_SEEK ircd::timer timer; #endif const std::lock_guard lock{write_mutex}; const ctx::uninterruptible ui; throw_on_error { d.d->Write(opts, &batch) }; #ifdef RB_DEBUG_DB_SEEK log::debug { log, "'%s' %lu COMMIT %s in %ld$us", d.name, sequence(d), debug(batch), timer.at().count() }; #endif } std::string ircd::db::debug(const rocksdb::WriteBatch &batch) { return ircd::string(512, [&batch] (const mutable_buffer &ret) { return snprintf(data(ret), size(ret)+1, "%d deltas; size: %zuB :%s%s%s%s%s%s%s%s%s", batch.Count(), batch.GetDataSize(), batch.HasPut()? " PUT" : "", batch.HasDelete()? " DELETE" : "", batch.HasSingleDelete()? " SINGLE_DELETE" : "", batch.HasDeleteRange()? " DELETE_RANGE" : "", batch.HasMerge()? " MERGE" : "", batch.HasBeginPrepare()? " BEGIN_PREPARE" : "", batch.HasEndPrepare()? " END_PREPARE" : "", batch.HasCommit()? " COMMIT" : "", batch.HasRollback()? " ROLLBACK" : ""); }); } bool ircd::db::has(const rocksdb::WriteBatch &wb, const op &op) { switch(op) { case op::GET: assert(0); return false; case op::SET: return wb.HasPut(); case op::MERGE: return wb.HasMerge(); case op::DELETE: return wb.HasDelete(); case op::DELETE_RANGE: return wb.HasDeleteRange(); case op::SINGLE_DELETE: return wb.HasSingleDelete(); } return false; } /////////////////////////////////////////////////////////////////////////////// // // seek // namespace ircd::db { static rocksdb::Iterator &_seek_(rocksdb::Iterator &, const pos &); static rocksdb::Iterator &_seek_(rocksdb::Iterator &, const string_view &); static rocksdb::Iterator &_seek_lower_(rocksdb::Iterator &, const string_view &); static rocksdb::Iterator &_seek_upper_(rocksdb::Iterator &, const string_view &); static bool _seek(database::column &, const pos &, const rocksdb::ReadOptions &, rocksdb::Iterator &it); static bool _seek(database::column &, const string_view &, const rocksdb::ReadOptions &, rocksdb::Iterator &it); } std::unique_ptr ircd::db::seek(column &column, const string_view &key, const gopts &opts) { database &d(column); database::column &c(column); std::unique_ptr ret; seek(c, key, opts, ret); return std::move(ret); } template bool ircd::db::seek(database::column &c, const pos &p, const gopts &gopts, std::unique_ptr &it) { const rocksdb::ReadOptions opts { make_opts(gopts) }; return seek(c, p, opts, it); } template bool ircd::db::seek(database::column &c, const pos &p, const rocksdb::ReadOptions &opts, std::unique_ptr &it) { const ctx::uninterruptible::nothrow ui; if(!it) { database &d(*c.d); rocksdb::ColumnFamilyHandle *const &cf(c); it.reset(d.d->NewIterator(opts, cf)); } return _seek(c, p, opts, *it); } bool ircd::db::_seek(database::column &c, const string_view &p, const rocksdb::ReadOptions &opts, rocksdb::Iterator &it) { #ifdef RB_DEBUG_DB_SEEK database &d(*c.d); const ircd::timer timer; #endif _seek_(it, p); #ifdef RB_DEBUG_DB_SEEK log::debug { log, "'%s' %lu:%lu SEEK %s in %ld$us '%s'", name(d), sequence(d), sequence(opts.snapshot), it.status().ToString(), timer.at().count(), name(c) }; #endif return valid(it); } bool ircd::db::_seek(database::column &c, const pos &p, const rocksdb::ReadOptions &opts, rocksdb::Iterator &it) { #ifdef RB_DEBUG_DB_SEEK database &d(*c.d); const ircd::timer timer; const bool valid_it { valid(it) }; #endif _seek_(it, p); #ifdef RB_DEBUG_DB_SEEK log::debug { log, "'%s' %lu:%lu SEEK[%s] %s -> %s in %ld$us '%s'", name(d), sequence(d), sequence(opts.snapshot), reflect(p), valid_it? "VALID" : "INVALID", it.status().ToString(), timer.at().count(), name(c) }; #endif return valid(it); } /// Seek to entry NOT GREATER THAN key. That is, equal to or less than key rocksdb::Iterator & ircd::db::_seek_lower_(rocksdb::Iterator &it, const string_view &sv) { it.SeekForPrev(slice(sv)); return it; } /// Seek to entry NOT LESS THAN key. That is, equal to or greater than key rocksdb::Iterator & ircd::db::_seek_upper_(rocksdb::Iterator &it, const string_view &sv) { it.Seek(slice(sv)); return it; } /// Defaults to _seek_upper_ because it has better support from RocksDB. rocksdb::Iterator & ircd::db::_seek_(rocksdb::Iterator &it, const string_view &sv) { return _seek_upper_(it, sv); } rocksdb::Iterator & ircd::db::_seek_(rocksdb::Iterator &it, const pos &p) { switch(p) { case pos::NEXT: it.Next(); break; case pos::PREV: it.Prev(); break; case pos::FRONT: it.SeekToFirst(); break; case pos::BACK: it.SeekToLast(); break; default: case pos::END: { it.SeekToLast(); if(it.Valid()) it.Next(); break; } } return it; } /////////////////////////////////////////////////////////////////////////////// // // cache.h // void ircd::db::clear(rocksdb::Cache *const &cache) { if(cache) return clear(*cache); } void ircd::db::clear(rocksdb::Cache &cache) { cache.EraseUnRefEntries(); } bool ircd::db::remove(rocksdb::Cache *const &cache, const string_view &key) { return cache? remove(*cache, key) : false; } bool ircd::db::remove(rocksdb::Cache &cache, const string_view &key) { cache.Erase(slice(key)); return true; } bool ircd::db::insert(rocksdb::Cache *const &cache, const string_view &key, const string_view &value) { return cache? insert(*cache, key, value) : false; } bool ircd::db::insert(rocksdb::Cache &cache, const string_view &key, const string_view &value) { unique_buffer buf { const_buffer{value} }; return insert(cache, key, std::move(buf)); } bool ircd::db::insert(rocksdb::Cache *const &cache, const string_view &key, unique_buffer value) { return cache? insert(*cache, key, std::move(value)) : false; } bool ircd::db::insert(rocksdb::Cache &cache, const string_view &key, unique_buffer value) { const size_t value_size { size(value) }; static const auto deleter{[] (const rocksdb::Slice &key, void *const value) { delete[] reinterpret_cast(value); }}; // Note that because of the nullptr handle argument below, rocksdb // will run the deleter if the insert throws; just make sure // the argument execution doesn't throw after release() throw_on_error { cache.Insert(slice(key), const_cast(data(value.release())), value_size, deleter, nullptr) }; return true; } void ircd::db::for_each(const rocksdb::Cache *const &cache, const cache_closure &closure) { if(cache) for_each(*cache, closure); } void ircd::db::for_each(const rocksdb::Cache &cache, const cache_closure &closure) { // Due to the use of the global variables which are required when using a // C-style callback for RocksDB, we have to make use of this function // exclusive for different contexts. thread_local ctx::mutex mutex; const std::lock_guard lock{mutex}; thread_local rocksdb::Cache *_cache; _cache = const_cast(&cache); thread_local const cache_closure *_closure; _closure = &closure; _cache->ApplyToAllCacheEntries([] (void *const value_buffer, const size_t buffer_size) noexcept { assert(_cache); assert(_closure); const const_buffer buf { reinterpret_cast(value_buffer), buffer_size }; (*_closure)(buf); }, true); } bool ircd::db::exists(const rocksdb::Cache *const &cache, const string_view &key) { return cache? exists(*cache, key) : false; } bool ircd::db::exists(const rocksdb::Cache &cache_, const string_view &key) { auto &cache(const_cast(cache_)); const custom_ptr handle { cache.Lookup(slice(key)), [&cache](auto *const &handle) { cache.Release(handle); } }; return bool(handle); } size_t ircd::db::pinned(const rocksdb::Cache *const &cache) { return cache? pinned(*cache) : 0; } size_t ircd::db::pinned(const rocksdb::Cache &cache) { return cache.GetPinnedUsage(); } size_t ircd::db::usage(const rocksdb::Cache *const &cache) { return cache? usage(*cache) : 0; } size_t ircd::db::usage(const rocksdb::Cache &cache) { return cache.GetUsage(); } bool ircd::db::capacity(rocksdb::Cache *const &cache, const size_t &cap) { if(!cache) return false; capacity(*cache, cap); return true; } void ircd::db::capacity(rocksdb::Cache &cache, const size_t &cap) { cache.SetCapacity(cap); } size_t ircd::db::capacity(const rocksdb::Cache *const &cache) { return cache? capacity(*cache): 0; } size_t ircd::db::capacity(const rocksdb::Cache &cache) { return cache.GetCapacity(); } uint64_t ircd::db::ticker(const rocksdb::Cache *const &cache, const uint32_t &ticker_id) { return cache? ticker(*cache, ticker_id) : 0UL; } const uint64_t & ircd::db::ticker(const rocksdb::Cache &cache, const uint32_t &ticker_id) { const auto &c { dynamic_cast(cache) }; static const uint64_t &zero { 0ULL }; return c.stats? c.stats->ticker.at(ticker_id): zero; } /////////////////////////////////////////////////////////////////////////////// // // Misc // std::vector ircd::db::column_names(const std::string &path, const std::string &options) { return column_names(path, database::options{options}); } std::vector ircd::db::column_names(const std::string &path, const rocksdb::DBOptions &opts) try { const ctx::uninterruptible::nothrow ui; std::vector ret; throw_on_error { rocksdb::DB::ListColumnFamilies(opts, path, &ret) }; return ret; } catch(const io_error &e) { return // No database found at path. Assume fresh. { { rocksdb::kDefaultColumnFamilyName } }; } ircd::db::database::options::options(const database &d) :options{d.d->GetDBOptions()} { } ircd::db::database::options::options(const database::column &c) :options { rocksdb::ColumnFamilyOptions { c.d->d->GetOptions(c.handle.get()) } }{} ircd::db::database::options::options(const rocksdb::DBOptions &opts) { throw_on_error { rocksdb::GetStringFromDBOptions(this, opts) }; } ircd::db::database::options::options(const rocksdb::ColumnFamilyOptions &opts) { throw_on_error { rocksdb::GetStringFromColumnFamilyOptions(this, opts) }; } ircd::db::database::options::operator rocksdb::PlainTableOptions() const { rocksdb::PlainTableOptions ret; throw_on_error { rocksdb::GetPlainTableOptionsFromString(ret, *this, &ret) }; return ret; } ircd::db::database::options::operator rocksdb::BlockBasedTableOptions() const { rocksdb::BlockBasedTableOptions ret; throw_on_error { rocksdb::GetBlockBasedTableOptionsFromString(ret, *this, &ret) }; return ret; } ircd::db::database::options::operator rocksdb::ColumnFamilyOptions() const { rocksdb::ColumnFamilyOptions ret; throw_on_error { rocksdb::GetColumnFamilyOptionsFromString(ret, *this, &ret) }; return ret; } ircd::db::database::options::operator rocksdb::DBOptions() const { rocksdb::DBOptions ret; throw_on_error { rocksdb::GetDBOptionsFromString(ret, *this, &ret) }; return ret; } ircd::db::database::options::operator rocksdb::Options() const { rocksdb::Options ret; throw_on_error { rocksdb::GetOptionsFromString(ret, *this, &ret) }; return ret; } ircd::db::database::options::map::map(const options &o) { throw_on_error { rocksdb::StringToMap(o, this) }; } ircd::db::database::options::map::operator rocksdb::PlainTableOptions() const { rocksdb::PlainTableOptions ret; throw_on_error { rocksdb::GetPlainTableOptionsFromMap(ret, *this, &ret) }; return ret; } ircd::db::database::options::map::operator rocksdb::BlockBasedTableOptions() const { rocksdb::BlockBasedTableOptions ret; throw_on_error { rocksdb::GetBlockBasedTableOptionsFromMap(ret, *this, &ret) }; return ret; } ircd::db::database::options::map::operator rocksdb::ColumnFamilyOptions() const { rocksdb::ColumnFamilyOptions ret; throw_on_error { rocksdb::GetColumnFamilyOptionsFromMap(ret, *this, &ret) }; return ret; } ircd::db::database::options::map::operator rocksdb::DBOptions() const { rocksdb::DBOptions ret; throw_on_error { rocksdb::GetDBOptionsFromMap(ret, *this, &ret) }; return ret; } /////////////////////////////////////////////////////////////////////////////// // // Misc // rocksdb::CompressionType ircd::db::find_supported_compression(const std::string &list) { rocksdb::CompressionType ret { rocksdb::kNoCompression }; tokens(list, ';', [&ret] (const string_view &name) { if(ret != rocksdb::kNoCompression) return; for(size_t i(0); i < db::compressions.size(); ++i) if(!db::compressions.at(i).empty()) if(name == db::compressions.at(i)) { ret = rocksdb::CompressionType(i); break; } }); return ret; } rocksdb::DBOptions ircd::db::make_dbopts(std::string optstr, std::string *const &out, bool *const read_only, bool *const fsck) { // RocksDB doesn't parse a read_only option, so we allow that to be added // to open the database as read_only and then remove that from the string. if(read_only) *read_only = optstr_find_and_remove(optstr, "read_only=true;"s); else optstr_find_and_remove(optstr, "read_only=true;"s); // We also allow the user to specify fsck=true to run a repair operation on // the db. This may be expensive to do by default every startup. if(fsck) *fsck = optstr_find_and_remove(optstr, "fsck=true;"s); else optstr_find_and_remove(optstr, "fsck=true;"s); // Generate RocksDB options from string rocksdb::DBOptions opts { database::options(optstr) }; if(out) *out = std::move(optstr); return opts; } bool ircd::db::optstr_find_and_remove(std::string &optstr, const std::string &what) { const auto pos(optstr.find(what)); if(pos == std::string::npos) return false; optstr.erase(pos, what.size()); return true; } /// Convert our options structure into RocksDB's options structure. rocksdb::ReadOptions ircd::db::make_opts(const gopts &opts) { rocksdb::ReadOptions ret; assert(ret.fill_cache); ret.read_tier = BLOCKING; // slice* for exclusive upper bound. when prefixes are used this value must // have the same prefix because ordering is not guaranteed between prefixes ret.iterate_lower_bound = opts.lower_bound; ret.iterate_upper_bound = opts.upper_bound; ret += opts; return ret; } ircd::conf::item read_checksum { { "name", "ircd.db.read.checksum" }, { "default", false } }; /// Update a RocksDB options structure with our options structure. We use /// operator+= for fun here; we can avoid reconstructing and returning a new /// options structure in some cases by breaking out this function from /// make_opts(). rocksdb::ReadOptions & ircd::db::operator+=(rocksdb::ReadOptions &ret, const gopts &opts) { ret.pin_data = test(opts, get::PIN); ret.fill_cache |= test(opts, get::CACHE); ret.fill_cache &= !test(opts, get::NO_CACHE); ret.tailing = test(opts, get::NO_SNAPSHOT); ret.prefix_same_as_start = test(opts, get::PREFIX); ret.total_order_seek = test(opts, get::ORDERED); ret.verify_checksums = bool(read_checksum); ret.verify_checksums |= test(opts, get::CHECKSUM); ret.verify_checksums &= !test(opts, get::NO_CHECKSUM); ret.readahead_size = opts.readahead; ret.iter_start_seqnum = opts.seqnum; if(opts.snapshot && !test(opts, get::NO_SNAPSHOT)) ret.snapshot = opts.snapshot; return ret; } rocksdb::WriteOptions ircd::db::make_opts(const sopts &opts) { rocksdb::WriteOptions ret; //ret.no_slowdown = true; // read_tier = NON_BLOCKING for writes ret += opts; return ret; } rocksdb::WriteOptions & ircd::db::operator+=(rocksdb::WriteOptions &ret, const sopts &opts) { ret.sync = test(opts, set::FSYNC); ret.disableWAL = test(opts, set::NO_JOURNAL); ret.ignore_missing_column_families = test(opts, set::MISSING_COLUMNS); return ret; } void ircd::db::valid_eq_or_throw(const rocksdb::Iterator &it, const string_view &sv) { assert(!empty(sv)); if(!valid_eq(it, sv)) { throw_on_error(it.status()); throw not_found{}; } } void ircd::db::valid_or_throw(const rocksdb::Iterator &it) { if(!valid(it)) { throw_on_error(it.status()); throw not_found{}; //assert(0); // status == ok + !Valid() == ??? } } bool ircd::db::valid_lte(const rocksdb::Iterator &it, const string_view &sv) { return valid(it, [&sv](const auto &it) { return it.key().compare(slice(sv)) <= 0; }); } bool ircd::db::valid_gt(const rocksdb::Iterator &it, const string_view &sv) { return valid(it, [&sv](const auto &it) { return it.key().compare(slice(sv)) > 0; }); } bool ircd::db::valid_eq(const rocksdb::Iterator &it, const string_view &sv) { return valid(it, [&sv](const auto &it) { return it.key().compare(slice(sv)) == 0; }); } bool ircd::db::valid(const rocksdb::Iterator &it, const valid_proffer &proffer) { return valid(it)? proffer(it) : false; } bool ircd::db::operator!(const rocksdb::Iterator &it) { return !valid(it); } bool ircd::db::valid(const rocksdb::Iterator &it) { switch(it.status().code()) { using rocksdb::Status; case Status::kOk: break; case Status::kNotFound: break; case Status::kIncomplete: break; default: throw_on_error(it.status()); __builtin_unreachable(); } return it.Valid(); } // // error_to_status // ircd::db::error_to_status::error_to_status(const fs::error &e) :error_to_status{e.code} { } ircd::db::error_to_status::error_to_status(const std::exception &e) :rocksdb::Status { Status::Aborted(slice(string_view(e.what()))) } { } ircd::db::error_to_status::error_to_status(const std::error_code &e) :rocksdb::Status{[&e] { using std::errc; switch(e.value()) { case 0: return Status::OK(); case int(errc::no_such_file_or_directory): return Status::NotFound(); case int(errc::not_supported): return Status::NotSupported(); case int(errc::invalid_argument): return Status::InvalidArgument(); case int(errc::io_error): return Status::IOError(); case int(errc::timed_out): return Status::TimedOut(); case int(errc::device_or_resource_busy): return Status::Busy(); case int(errc::resource_unavailable_try_again): return Status::TryAgain(); case int(errc::no_space_on_device): return Status::NoSpace(); case int(errc::not_enough_memory): return Status::MemoryLimit(); default: return Status::Aborted(slice(string_view(e.message()))); } }()} { } // // throw_on_error // ircd::db::throw_on_error::throw_on_error(const rocksdb::Status &s) { using rocksdb::Status; switch(s.code()) { case Status::kOk: return; case Status::kNotFound: throw not_found("%s", s.ToString()); case Status::kCorruption: throw corruption("%s", s.ToString()); case Status::kNotSupported: throw not_supported("%s", s.ToString()); case Status::kInvalidArgument: throw invalid_argument("%s", s.ToString()); case Status::kIOError: throw io_error("%s", s.ToString()); case Status::kMergeInProgress: throw merge_in_progress("%s", s.ToString()); case Status::kIncomplete: throw incomplete("%s", s.ToString()); case Status::kShutdownInProgress: throw shutdown_in_progress("%s", s.ToString()); case Status::kTimedOut: throw timed_out("%s", s.ToString()); case Status::kAborted: throw aborted("%s", s.ToString()); case Status::kBusy: throw busy("%s", s.ToString()); case Status::kExpired: throw expired("%s", s.ToString()); case Status::kTryAgain: throw try_again("%s", s.ToString()); default: throw error { "code[%d] %s", s.code(), s.ToString() }; } } // // // std::vector ircd::db::available() { const auto prefix { fs::get(fs::DB) }; const auto dirs { fs::ls(prefix) }; std::vector ret; for(const auto &dir : dirs) { if(!fs::is_dir(dir)) continue; const auto name { lstrip(dir, prefix) }; const auto checkpoints { fs::ls(dir) }; for(const auto cpdir : checkpoints) try { const auto checkpoint { lstrip(lstrip(cpdir, dir), '/') //TODO: x-platform }; auto path { db::path(name, lex_cast(checkpoint)) }; ret.emplace_back(std::move(path)); } catch(const bad_lex_cast &e) { continue; } } return ret; } std::string ircd::db::path(const string_view &name) { const auto pair { namepoint(name) }; return path(pair.first, pair.second); } std::string ircd::db::path(const string_view &name, const uint64_t &checkpoint) { const auto prefix { fs::get(fs::DB) }; const string_view parts[] { prefix, name, lex_cast(checkpoint) }; return fs::make_path(parts); } std::pair ircd::db::namepoint(const string_view &name_) { const auto s { split(name_, ':') }; return { s.first, s.second? lex_cast(s.second) : uint64_t(-1) }; } std::string ircd::db::namepoint(const string_view &name, const uint64_t &checkpoint) { return std::string{name} + ':' + std::string{lex_cast(checkpoint)}; } std::pair ircd::db::operator*(const rocksdb::Iterator &it) { return { key(it), val(it) }; } ircd::string_view ircd::db::key(const rocksdb::Iterator &it) { return slice(it.key()); } ircd::string_view ircd::db::val(const rocksdb::Iterator &it) { return slice(it.value()); } const char * ircd::db::data(const rocksdb::Slice &slice) { return slice.data(); } size_t ircd::db::size(const rocksdb::Slice &slice) { return slice.size(); } rocksdb::Slice ircd::db::slice(const string_view &sv) { return { sv.data(), sv.size() }; } ircd::string_view ircd::db::slice(const rocksdb::Slice &sk) { return { sk.data(), sk.size() }; } const std::string & ircd::db::reflect(const rocksdb::Tickers &type) { const auto &names(rocksdb::TickersNameMap); const auto it(std::find_if(begin(names), end(names), [&type] (const auto &pair) { return pair.first == type; })); static const auto empty{"?????"s}; return it != end(names)? it->second : empty; } const std::string & ircd::db::reflect(const rocksdb::Histograms &type) { const auto &names(rocksdb::HistogramsNameMap); const auto it(std::find_if(begin(names), end(names), [&type] (const auto &pair) { return pair.first == type; })); static const auto empty{"?????"s}; return it != end(names)? it->second : empty; } ircd::string_view ircd::db::reflect(const pos &pos) { switch(pos) { case pos::NEXT: return "NEXT"; case pos::PREV: return "PREV"; case pos::FRONT: return "FRONT"; case pos::BACK: return "BACK"; case pos::END: return "END"; } return "?????"; } ircd::string_view ircd::db::reflect(const op &op) { switch(op) { case op::GET: return "GET"; case op::SET: return "SET"; case op::MERGE: return "MERGE"; case op::DELETE_RANGE: return "DELETE_RANGE"; case op::DELETE: return "DELETE"; case op::SINGLE_DELETE: return "SINGLE_DELETE"; } return "?????"; } ircd::string_view ircd::db::reflect(const rocksdb::WriteStallCondition &c) { using rocksdb::WriteStallCondition; switch(c) { case WriteStallCondition::kNormal: return "NORMAL"; case WriteStallCondition::kDelayed: return "DELAYED"; case WriteStallCondition::kStopped: return "STOPPED"; } return "??????"; } ircd::string_view ircd::db::reflect(const rocksdb::BackgroundErrorReason &r) { using rocksdb::BackgroundErrorReason; switch(r) { case BackgroundErrorReason::kFlush: return "FLUSH"; case BackgroundErrorReason::kCompaction: return "COMPACTION"; case BackgroundErrorReason::kWriteCallback: return "WRITE"; case BackgroundErrorReason::kMemTable: return "MEMTABLE"; } return "??????"; } ircd::string_view ircd::db::reflect(const rocksdb::Env::Priority &p) { switch(p) { case rocksdb::Env::Priority::BOTTOM: return "BOTTOM"_sv; case rocksdb::Env::Priority::LOW: return "LOW"_sv; case rocksdb::Env::Priority::HIGH: return "HIGH"_sv; case rocksdb::Env::Priority::TOTAL: assert(0); break; } return "????"_sv; } ircd::string_view ircd::db::reflect(const rocksdb::Env::IOPriority &p) { switch(p) { case rocksdb::Env::IOPriority::IO_LOW: return "IO_LOW"_sv; case rocksdb::Env::IOPriority::IO_HIGH: return "IO_HIGH"_sv; case rocksdb::Env::IOPriority::IO_TOTAL: assert(0); break; } return "IO_????"_sv; } ircd::string_view ircd::db::reflect(const rocksdb::Env::WriteLifeTimeHint &h) { using WriteLifeTimeHint = rocksdb::Env::WriteLifeTimeHint; switch(h) { case WriteLifeTimeHint::WLTH_NOT_SET: return "NOT_SET"; case WriteLifeTimeHint::WLTH_NONE: return "NONE"; case WriteLifeTimeHint::WLTH_SHORT: return "SHORT"; case WriteLifeTimeHint::WLTH_MEDIUM: return "MEDIUM"; case WriteLifeTimeHint::WLTH_LONG: return "LONG"; case WriteLifeTimeHint::WLTH_EXTREME: return "EXTREME"; } return "WLTH_????"_sv; } ircd::string_view ircd::db::reflect(const rocksdb::Status::Severity &s) { using Severity = rocksdb::Status::Severity; switch(s) { case Severity::kNoError: return "NONE"; case Severity::kSoftError: return "SOFT"; case Severity::kHardError: return "HARD"; case Severity::kFatalError: return "FATAL"; case Severity::kUnrecoverableError: return "UNRECOVERABLE"; case Severity::kMaxSeverity: break; } return "?????"; } ircd::string_view ircd::db::reflect(const rocksdb::RandomAccessFile::AccessPattern &p) { switch(p) { case rocksdb::RandomAccessFile::AccessPattern::NORMAL: return "NORMAL"_sv; case rocksdb::RandomAccessFile::AccessPattern::RANDOM: return "RANDOM"_sv; case rocksdb::RandomAccessFile::AccessPattern::SEQUENTIAL: return "SEQUENTIAL"_sv; case rocksdb::RandomAccessFile::AccessPattern::WILLNEED: return "WILLNEED"_sv; case rocksdb::RandomAccessFile::AccessPattern::DONTNEED: return "DONTNEED"_sv; } return "??????"_sv; } bool ircd::db::value_required(const op &op) { switch(op) { case op::SET: case op::MERGE: case op::DELETE_RANGE: return true; case op::GET: case op::DELETE: case op::SINGLE_DELETE: return false; } assert(0); return false; }