// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root directory). // // Copyright (c) 2011 The LevelDB Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. See the AUTHORS file for names of contributors. #include "test_util/testutil.h" #include #include #include #include #include #include #include "db/memtable_list.h" #include "env/composite_env_wrapper.h" #include "file/random_access_file_reader.h" #include "file/sequence_file_reader.h" #include "file/writable_file_writer.h" #include "port/port.h" #include "rocksdb/convenience.h" #include "rocksdb/system_clock.h" #include "rocksdb/utilities/object_registry.h" #include "test_util/mock_time_env.h" #include "test_util/sync_point.h" #include "util/random.h" #ifndef ROCKSDB_UNITTESTS_WITH_CUSTOM_OBJECTS_FROM_STATIC_LIBS void RegisterCustomObjects(int /*argc*/, char** /*argv*/) {} #endif namespace ROCKSDB_NAMESPACE { namespace test { const uint32_t kDefaultFormatVersion = BlockBasedTableOptions().format_version; const std::set kFooterFormatVersionsToTest{ 5U, // In case any interesting future changes kDefaultFormatVersion, kLatestFormatVersion, }; std::string RandomKey(Random* rnd, int len, RandomKeyType type) { // Make sure to generate a wide variety of characters so we // test the boundary conditions for short-key optimizations. static const char kTestChars[] = {'\0', '\1', 'a', 'b', 'c', 'd', 'e', '\xfd', '\xfe', '\xff'}; std::string result; for (int i = 0; i < len; i++) { std::size_t indx = 0; switch (type) { case RandomKeyType::RANDOM: indx = rnd->Uniform(sizeof(kTestChars)); break; case RandomKeyType::LARGEST: indx = sizeof(kTestChars) - 1; break; case RandomKeyType::MIDDLE: indx = sizeof(kTestChars) / 2; break; case RandomKeyType::SMALLEST: indx = 0; break; } result += kTestChars[indx]; } return result; } extern Slice CompressibleString(Random* rnd, double compressed_fraction, int len, std::string* dst) { int raw = static_cast(len * compressed_fraction); if (raw < 1) raw = 1; std::string raw_data = rnd->RandomString(raw); // Duplicate the random data until we have filled "len" bytes dst->clear(); while (dst->size() < (unsigned int)len) { dst->append(raw_data); } dst->resize(len); return Slice(*dst); } namespace { class Uint64ComparatorImpl : public Comparator { public: Uint64ComparatorImpl() {} const char* Name() const override { return "rocksdb.Uint64Comparator"; } int Compare(const Slice& a, const Slice& b) const override { assert(a.size() == sizeof(uint64_t) && b.size() == sizeof(uint64_t)); const uint64_t* left = reinterpret_cast(a.data()); const uint64_t* right = reinterpret_cast(b.data()); uint64_t leftValue; uint64_t rightValue; GetUnaligned(left, &leftValue); GetUnaligned(right, &rightValue); if (leftValue == rightValue) { return 0; } else if (leftValue < rightValue) { return -1; } else { return 1; } } void FindShortestSeparator(std::string* /*start*/, const Slice& /*limit*/) const override { return; } void FindShortSuccessor(std::string* /*key*/) const override { return; } }; // A test implementation of comparator with 64-bit integer timestamp. class ComparatorWithU64TsImpl : public Comparator { public: ComparatorWithU64TsImpl() : Comparator(/*ts_sz=*/sizeof(uint64_t)), cmp_without_ts_(BytewiseComparator()) { assert(cmp_without_ts_); assert(cmp_without_ts_->timestamp_size() == 0); } const char* Name() const override { return "ComparatorWithU64Ts"; } void FindShortSuccessor(std::string*) const override {} void FindShortestSeparator(std::string*, const Slice&) const override {} int Compare(const Slice& a, const Slice& b) const override { int ret = CompareWithoutTimestamp(a, b); size_t ts_sz = timestamp_size(); if (ret != 0) { return ret; } // Compare timestamp. // For the same user key with different timestamps, larger (newer) timestamp // comes first. return -CompareTimestamp(ExtractTimestampFromUserKey(a, ts_sz), ExtractTimestampFromUserKey(b, ts_sz)); } using Comparator::CompareWithoutTimestamp; int CompareWithoutTimestamp(const Slice& a, bool a_has_ts, const Slice& b, bool b_has_ts) const override { const size_t ts_sz = timestamp_size(); assert(!a_has_ts || a.size() >= ts_sz); assert(!b_has_ts || b.size() >= ts_sz); Slice lhs = a_has_ts ? StripTimestampFromUserKey(a, ts_sz) : a; Slice rhs = b_has_ts ? StripTimestampFromUserKey(b, ts_sz) : b; return cmp_without_ts_->Compare(lhs, rhs); } int CompareTimestamp(const Slice& ts1, const Slice& ts2) const override { assert(ts1.size() == sizeof(uint64_t)); assert(ts2.size() == sizeof(uint64_t)); uint64_t lhs = DecodeFixed64(ts1.data()); uint64_t rhs = DecodeFixed64(ts2.data()); if (lhs < rhs) { return -1; } else if (lhs > rhs) { return 1; } else { return 0; } } private: const Comparator* cmp_without_ts_{nullptr}; }; } // namespace const Comparator* Uint64Comparator() { static Uint64ComparatorImpl uint64comp; return &uint64comp; } const Comparator* ComparatorWithU64Ts() { static ComparatorWithU64TsImpl comp_with_u64_ts; return &comp_with_u64_ts; } void CorruptKeyType(InternalKey* ikey) { std::string keystr = ikey->Encode().ToString(); keystr[keystr.size() - 8] = kTypeLogData; ikey->DecodeFrom(Slice(keystr.data(), keystr.size())); } std::string KeyStr(const std::string& user_key, const SequenceNumber& seq, const ValueType& t, bool corrupt) { InternalKey k(user_key, seq, t); if (corrupt) { CorruptKeyType(&k); } return k.Encode().ToString(); } std::string KeyStr(uint64_t ts, const std::string& user_key, const SequenceNumber& seq, const ValueType& t, bool corrupt) { std::string user_key_with_ts(user_key); std::string ts_str; PutFixed64(&ts_str, ts); user_key_with_ts.append(ts_str); return KeyStr(user_key_with_ts, seq, t, corrupt); } bool SleepingBackgroundTask::TimedWaitUntilSleeping(uint64_t wait_time) { auto abs_time = SystemClock::Default()->NowMicros() + wait_time; MutexLock l(&mutex_); while (!sleeping_ || !should_sleep_) { if (bg_cv_.TimedWait(abs_time)) { return true; } } return false; } bool SleepingBackgroundTask::TimedWaitUntilDone(uint64_t wait_time) { auto abs_time = SystemClock::Default()->NowMicros() + wait_time; MutexLock l(&mutex_); while (!done_with_sleep_) { if (bg_cv_.TimedWait(abs_time)) { return true; } } return false; } std::string RandomName(Random* rnd, const size_t len) { std::stringstream ss; for (size_t i = 0; i < len; ++i) { ss << static_cast(rnd->Uniform(26) + 'a'); } return ss.str(); } CompressionType RandomCompressionType(Random* rnd) { auto ret = static_cast(rnd->Uniform(6)); while (!CompressionTypeSupported(ret)) { ret = static_cast((static_cast(ret) + 1) % 6); } return ret; } void RandomCompressionTypeVector(const size_t count, std::vector* types, Random* rnd) { types->clear(); for (size_t i = 0; i < count; ++i) { types->emplace_back(RandomCompressionType(rnd)); } } const SliceTransform* RandomSliceTransform(Random* rnd, int pre_defined) { int random_num = pre_defined >= 0 ? pre_defined : rnd->Uniform(4); switch (random_num) { case 0: return NewFixedPrefixTransform(rnd->Uniform(20) + 1); case 1: return NewCappedPrefixTransform(rnd->Uniform(20) + 1); case 2: return NewNoopTransform(); default: return nullptr; } } BlockBasedTableOptions RandomBlockBasedTableOptions(Random* rnd) { BlockBasedTableOptions opt; opt.cache_index_and_filter_blocks = rnd->Uniform(2); opt.pin_l0_filter_and_index_blocks_in_cache = rnd->Uniform(2); opt.pin_top_level_index_and_filter = rnd->Uniform(2); using IndexType = BlockBasedTableOptions::IndexType; const std::array index_types = { {IndexType::kBinarySearch, IndexType::kHashSearch, IndexType::kTwoLevelIndexSearch, IndexType::kBinarySearchWithFirstKey}}; opt.index_type = index_types[rnd->Uniform(static_cast(index_types.size()))]; opt.hash_index_allow_collision = rnd->Uniform(2); opt.checksum = static_cast(rnd->Uniform(3)); opt.block_size = rnd->Uniform(10000000); opt.block_size_deviation = rnd->Uniform(100); opt.block_restart_interval = rnd->Uniform(100); opt.index_block_restart_interval = rnd->Uniform(100); opt.whole_key_filtering = rnd->Uniform(2); return opt; } TableFactory* RandomTableFactory(Random* rnd, int pre_defined) { #ifndef ROCKSDB_LITE int random_num = pre_defined >= 0 ? pre_defined : rnd->Uniform(4); switch (random_num) { case 0: return NewPlainTableFactory(); case 1: return NewCuckooTableFactory(); default: return NewBlockBasedTableFactory(); } #else (void)rnd; (void)pre_defined; return NewBlockBasedTableFactory(); #endif // !ROCKSDB_LITE } MergeOperator* RandomMergeOperator(Random* rnd) { return new ChanglingMergeOperator(RandomName(rnd, 10)); } CompactionFilter* RandomCompactionFilter(Random* rnd) { return new ChanglingCompactionFilter(RandomName(rnd, 10)); } CompactionFilterFactory* RandomCompactionFilterFactory(Random* rnd) { return new ChanglingCompactionFilterFactory(RandomName(rnd, 10)); } void RandomInitDBOptions(DBOptions* db_opt, Random* rnd) { // boolean options db_opt->advise_random_on_open = rnd->Uniform(2); db_opt->allow_mmap_reads = rnd->Uniform(2); db_opt->allow_mmap_writes = rnd->Uniform(2); db_opt->use_direct_reads = rnd->Uniform(2); db_opt->use_direct_io_for_flush_and_compaction = rnd->Uniform(2); db_opt->create_if_missing = rnd->Uniform(2); db_opt->create_missing_column_families = rnd->Uniform(2); db_opt->enable_thread_tracking = rnd->Uniform(2); db_opt->error_if_exists = rnd->Uniform(2); db_opt->is_fd_close_on_exec = rnd->Uniform(2); db_opt->paranoid_checks = rnd->Uniform(2); db_opt->track_and_verify_wals_in_manifest = rnd->Uniform(2); db_opt->skip_log_error_on_recovery = rnd->Uniform(2); db_opt->skip_stats_update_on_db_open = rnd->Uniform(2); db_opt->skip_checking_sst_file_sizes_on_db_open = rnd->Uniform(2); db_opt->use_adaptive_mutex = rnd->Uniform(2); db_opt->use_fsync = rnd->Uniform(2); db_opt->recycle_log_file_num = rnd->Uniform(2); db_opt->avoid_flush_during_recovery = rnd->Uniform(2); db_opt->avoid_flush_during_shutdown = rnd->Uniform(2); // int options db_opt->max_background_compactions = rnd->Uniform(100); db_opt->max_background_flushes = rnd->Uniform(100); db_opt->max_file_opening_threads = rnd->Uniform(100); db_opt->max_open_files = rnd->Uniform(100); db_opt->table_cache_numshardbits = rnd->Uniform(100); // size_t options db_opt->db_write_buffer_size = rnd->Uniform(10000); db_opt->keep_log_file_num = rnd->Uniform(10000); db_opt->log_file_time_to_roll = rnd->Uniform(10000); db_opt->manifest_preallocation_size = rnd->Uniform(10000); db_opt->max_log_file_size = rnd->Uniform(10000); // std::string options db_opt->db_log_dir = "path/to/db_log_dir"; db_opt->wal_dir = "path/to/wal_dir"; // uint32_t options db_opt->max_subcompactions = rnd->Uniform(100000); // uint64_t options static const uint64_t uint_max = static_cast(UINT_MAX); db_opt->WAL_size_limit_MB = uint_max + rnd->Uniform(100000); db_opt->WAL_ttl_seconds = uint_max + rnd->Uniform(100000); db_opt->bytes_per_sync = uint_max + rnd->Uniform(100000); db_opt->delayed_write_rate = uint_max + rnd->Uniform(100000); db_opt->delete_obsolete_files_period_micros = uint_max + rnd->Uniform(100000); db_opt->max_manifest_file_size = uint_max + rnd->Uniform(100000); db_opt->max_total_wal_size = uint_max + rnd->Uniform(100000); db_opt->wal_bytes_per_sync = uint_max + rnd->Uniform(100000); // unsigned int options db_opt->stats_dump_period_sec = rnd->Uniform(100000); } void RandomInitCFOptions(ColumnFamilyOptions* cf_opt, DBOptions& db_options, Random* rnd) { cf_opt->compaction_style = (CompactionStyle)(rnd->Uniform(4)); // boolean options cf_opt->report_bg_io_stats = rnd->Uniform(2); cf_opt->disable_auto_compactions = rnd->Uniform(2); cf_opt->inplace_update_support = rnd->Uniform(2); cf_opt->level_compaction_dynamic_level_bytes = rnd->Uniform(2); cf_opt->optimize_filters_for_hits = rnd->Uniform(2); cf_opt->paranoid_file_checks = rnd->Uniform(2); cf_opt->force_consistency_checks = rnd->Uniform(2); cf_opt->compaction_options_fifo.allow_compaction = rnd->Uniform(2); cf_opt->memtable_whole_key_filtering = rnd->Uniform(2); cf_opt->enable_blob_files = rnd->Uniform(2); cf_opt->enable_blob_garbage_collection = rnd->Uniform(2); // double options cf_opt->hard_rate_limit = static_cast(rnd->Uniform(10000)) / 13; cf_opt->soft_rate_limit = static_cast(rnd->Uniform(10000)) / 13; cf_opt->memtable_prefix_bloom_size_ratio = static_cast(rnd->Uniform(10000)) / 20000.0; cf_opt->blob_garbage_collection_age_cutoff = rnd->Uniform(10000) / 10000.0; cf_opt->blob_garbage_collection_force_threshold = rnd->Uniform(10000) / 10000.0; // int options cf_opt->level0_file_num_compaction_trigger = rnd->Uniform(100); cf_opt->level0_slowdown_writes_trigger = rnd->Uniform(100); cf_opt->level0_stop_writes_trigger = rnd->Uniform(100); cf_opt->max_bytes_for_level_multiplier = rnd->Uniform(100); cf_opt->max_mem_compaction_level = rnd->Uniform(100); cf_opt->max_write_buffer_number = rnd->Uniform(100); cf_opt->max_write_buffer_number_to_maintain = rnd->Uniform(100); cf_opt->max_write_buffer_size_to_maintain = rnd->Uniform(10000); cf_opt->min_write_buffer_number_to_merge = rnd->Uniform(100); cf_opt->num_levels = rnd->Uniform(100); cf_opt->target_file_size_multiplier = rnd->Uniform(100); // vector int options cf_opt->max_bytes_for_level_multiplier_additional.resize(cf_opt->num_levels); for (int i = 0; i < cf_opt->num_levels; i++) { cf_opt->max_bytes_for_level_multiplier_additional[i] = rnd->Uniform(100); } // size_t options cf_opt->arena_block_size = rnd->Uniform(10000); cf_opt->inplace_update_num_locks = rnd->Uniform(10000); cf_opt->max_successive_merges = rnd->Uniform(10000); cf_opt->memtable_huge_page_size = rnd->Uniform(10000); cf_opt->write_buffer_size = rnd->Uniform(10000); // uint32_t options cf_opt->bloom_locality = rnd->Uniform(10000); cf_opt->max_bytes_for_level_base = rnd->Uniform(10000); // uint64_t options static const uint64_t uint_max = static_cast(UINT_MAX); cf_opt->ttl = db_options.max_open_files == -1 ? uint_max + rnd->Uniform(10000) : 0; cf_opt->periodic_compaction_seconds = db_options.max_open_files == -1 ? uint_max + rnd->Uniform(10000) : 0; cf_opt->max_sequential_skip_in_iterations = uint_max + rnd->Uniform(10000); cf_opt->target_file_size_base = uint_max + rnd->Uniform(10000); cf_opt->max_compaction_bytes = cf_opt->target_file_size_base * rnd->Uniform(100); cf_opt->compaction_options_fifo.max_table_files_size = uint_max + rnd->Uniform(10000); cf_opt->min_blob_size = uint_max + rnd->Uniform(10000); cf_opt->blob_file_size = uint_max + rnd->Uniform(10000); cf_opt->blob_compaction_readahead_size = uint_max + rnd->Uniform(10000); // unsigned int options cf_opt->rate_limit_delay_max_milliseconds = rnd->Uniform(10000); // pointer typed options cf_opt->prefix_extractor.reset(RandomSliceTransform(rnd)); cf_opt->table_factory.reset(RandomTableFactory(rnd)); cf_opt->merge_operator.reset(RandomMergeOperator(rnd)); if (cf_opt->compaction_filter) { delete cf_opt->compaction_filter; } cf_opt->compaction_filter = RandomCompactionFilter(rnd); cf_opt->compaction_filter_factory.reset(RandomCompactionFilterFactory(rnd)); // custom typed options cf_opt->compression = RandomCompressionType(rnd); RandomCompressionTypeVector(cf_opt->num_levels, &cf_opt->compression_per_level, rnd); cf_opt->blob_compression_type = RandomCompressionType(rnd); } bool IsDirectIOSupported(Env* env, const std::string& dir) { EnvOptions env_options; env_options.use_mmap_writes = false; env_options.use_direct_writes = true; std::string tmp = TempFileName(dir, 999); Status s; { std::unique_ptr file; s = env->NewWritableFile(tmp, &file, env_options); } if (s.ok()) { s = env->DeleteFile(tmp); } return s.ok(); } bool IsPrefetchSupported(const std::shared_ptr& fs, const std::string& dir) { bool supported = false; std::string tmp = TempFileName(dir, 999); Random rnd(301); std::string test_string = rnd.RandomString(4096); Slice data(test_string); Status s = WriteStringToFile(fs.get(), data, tmp, true); if (s.ok()) { std::unique_ptr file; auto io_s = fs->NewRandomAccessFile(tmp, FileOptions(), &file, nullptr); if (io_s.ok()) { supported = !(file->Prefetch(0, data.size(), IOOptions(), nullptr) .IsNotSupported()); } s = fs->DeleteFile(tmp, IOOptions(), nullptr); } return s.ok() && supported; } size_t GetLinesCount(const std::string& fname, const std::string& pattern) { std::stringstream ssbuf; std::string line; size_t count = 0; std::ifstream inFile(fname.c_str()); ssbuf << inFile.rdbuf(); while (getline(ssbuf, line)) { if (line.find(pattern) != std::string::npos) { count++; } } return count; } Status CorruptFile(Env* env, const std::string& fname, int offset, int bytes_to_corrupt, bool verify_checksum /*=true*/) { uint64_t size; Status s = env->GetFileSize(fname, &size); if (!s.ok()) { return s; } else if (offset < 0) { // Relative to end of file; make it absolute if (-offset > static_cast(size)) { offset = 0; } else { offset = static_cast(size + offset); } } if (offset > static_cast(size)) { offset = static_cast(size); } if (offset + bytes_to_corrupt > static_cast(size)) { bytes_to_corrupt = static_cast(size - offset); } // Do it std::string contents; s = ReadFileToString(env, fname, &contents); if (s.ok()) { for (int i = 0; i < bytes_to_corrupt; i++) { contents[i + offset] ^= 0x80; } s = WriteStringToFile(env, contents, fname); } if (s.ok() && verify_checksum) { #ifndef ROCKSDB_LITE Options options; options.env = env; EnvOptions env_options; Status v = VerifySstFileChecksum(options, env_options, fname); assert(!v.ok()); #endif } return s; } Status TruncateFile(Env* env, const std::string& fname, uint64_t new_length) { uint64_t old_length; Status s = env->GetFileSize(fname, &old_length); if (!s.ok() || new_length == old_length) { return s; } // Do it std::string contents; s = ReadFileToString(env, fname, &contents); if (s.ok()) { contents.resize(static_cast(new_length), 'b'); s = WriteStringToFile(env, contents, fname); } return s; } // Try and delete a directory if it exists Status TryDeleteDir(Env* env, const std::string& dirname) { bool is_dir = false; Status s = env->IsDirectory(dirname, &is_dir); if (s.ok() && is_dir) { s = env->DeleteDir(dirname); } return s; } // Delete a directory if it exists void DeleteDir(Env* env, const std::string& dirname) { TryDeleteDir(env, dirname).PermitUncheckedError(); } Status CreateEnvFromSystem(const ConfigOptions& config_options, Env** result, std::shared_ptr* guard) { const char* env_uri = getenv("TEST_ENV_URI"); const char* fs_uri = getenv("TEST_FS_URI"); if (env_uri || fs_uri) { return Env::CreateFromUri(config_options, (env_uri != nullptr) ? env_uri : "", (fs_uri != nullptr) ? fs_uri : "", result, guard); } else { // Neither specified. Use the default *result = config_options.env; guard->reset(); return Status::OK(); } } namespace { // A hacky skip list mem table that triggers flush after number of entries. class SpecialMemTableRep : public MemTableRep { public: explicit SpecialMemTableRep(Allocator* allocator, MemTableRep* memtable, int num_entries_flush) : MemTableRep(allocator), memtable_(memtable), num_entries_flush_(num_entries_flush), num_entries_(0) {} virtual KeyHandle Allocate(const size_t len, char** buf) override { return memtable_->Allocate(len, buf); } // Insert key into the list. // REQUIRES: nothing that compares equal to key is currently in the list. virtual void Insert(KeyHandle handle) override { num_entries_++; memtable_->Insert(handle); } void InsertConcurrently(KeyHandle handle) override { num_entries_++; memtable_->Insert(handle); } // Returns true iff an entry that compares equal to key is in the list. virtual bool Contains(const char* key) const override { return memtable_->Contains(key); } virtual size_t ApproximateMemoryUsage() override { // Return a high memory usage when number of entries exceeds the threshold // to trigger a flush. return (num_entries_ < num_entries_flush_) ? 0 : 1024 * 1024 * 1024; } virtual void Get(const LookupKey& k, void* callback_args, bool (*callback_func)(void* arg, const char* entry)) override { memtable_->Get(k, callback_args, callback_func); } uint64_t ApproximateNumEntries(const Slice& start_ikey, const Slice& end_ikey) override { return memtable_->ApproximateNumEntries(start_ikey, end_ikey); } virtual MemTableRep::Iterator* GetIterator(Arena* arena = nullptr) override { return memtable_->GetIterator(arena); } virtual ~SpecialMemTableRep() override {} private: std::unique_ptr memtable_; int num_entries_flush_; int num_entries_; }; class SpecialSkipListFactory : public MemTableRepFactory { public: #ifndef ROCKSDB_LITE static bool Register(ObjectLibrary& library, const std::string& /*arg*/) { library.AddFactory( ObjectLibrary::PatternEntry(SpecialSkipListFactory::kClassName(), true) .AddNumber(":"), [](const std::string& uri, std::unique_ptr* guard, std::string* /* errmsg */) { auto colon = uri.find(":"); if (colon != std::string::npos) { auto count = ParseInt(uri.substr(colon + 1)); guard->reset(new SpecialSkipListFactory(count)); } else { guard->reset(new SpecialSkipListFactory(2)); } return guard->get(); }); return true; } #endif // ROCKSDB_LITE // After number of inserts exceeds `num_entries_flush` in a mem table, trigger // flush. explicit SpecialSkipListFactory(int num_entries_flush) : num_entries_flush_(num_entries_flush) {} using MemTableRepFactory::CreateMemTableRep; virtual MemTableRep* CreateMemTableRep( const MemTableRep::KeyComparator& compare, Allocator* allocator, const SliceTransform* transform, Logger* /*logger*/) override { return new SpecialMemTableRep( allocator, factory_.CreateMemTableRep(compare, allocator, transform, nullptr), num_entries_flush_); } static const char* kClassName() { return "SpecialSkipListFactory"; } virtual const char* Name() const override { return kClassName(); } std::string GetId() const override { std::string id = Name(); if (num_entries_flush_ > 0) { id.append(":").append(ROCKSDB_NAMESPACE::ToString(num_entries_flush_)); } return id; } bool IsInsertConcurrentlySupported() const override { return factory_.IsInsertConcurrentlySupported(); } private: SkipListFactory factory_; int num_entries_flush_; }; } // namespace MemTableRepFactory* NewSpecialSkipListFactory(int num_entries_per_flush) { RegisterTestLibrary(); return new SpecialSkipListFactory(num_entries_per_flush); } #ifndef ROCKSDB_LITE // This method loads existing test classes into the ObjectRegistry int RegisterTestObjects(ObjectLibrary& library, const std::string& arg) { size_t num_types; library.AddFactory( test::SimpleSuffixReverseComparator::kClassName(), [](const std::string& /*uri*/, std::unique_ptr* /*guard*/, std::string* /* errmsg */) { static test::SimpleSuffixReverseComparator ssrc; return &ssrc; }); SpecialSkipListFactory::Register(library, arg); library.AddFactory( "Changling", [](const std::string& uri, std::unique_ptr* guard, std::string* /* errmsg */) { guard->reset(new test::ChanglingMergeOperator(uri)); return guard->get(); }); library.AddFactory( "Changling", [](const std::string& uri, std::unique_ptr* /*guard*/, std::string* /* errmsg */) { return new test::ChanglingCompactionFilter(uri); }); library.AddFactory( "Changling", [](const std::string& uri, std::unique_ptr* guard, std::string* /* errmsg */) { guard->reset(new test::ChanglingCompactionFilterFactory(uri)); return guard->get(); }); library.AddFactory( MockSystemClock::kClassName(), [](const std::string& /*uri*/, std::unique_ptr* guard, std::string* /* errmsg */) { guard->reset(new MockSystemClock(SystemClock::Default())); return guard->get(); }); return static_cast(library.GetFactoryCount(&num_types)); } #endif // ROCKSDB_LITE void RegisterTestLibrary(const std::string& arg) { static bool registered = false; if (!registered) { registered = true; #ifndef ROCKSDB_LITE ObjectRegistry::Default()->AddLibrary("test", RegisterTestObjects, arg); #else (void)arg; #endif // ROCKSDB_LITE } } } // namespace test } // namespace ROCKSDB_NAMESPACE