// 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). #include "options/options_helper.h" #include #include #include #include #include #include #include "options/cf_options.h" #include "options/db_options.h" #include "rocksdb/cache.h" #include "rocksdb/compaction_filter.h" #include "rocksdb/convenience.h" #include "rocksdb/filter_policy.h" #include "rocksdb/flush_block_policy.h" #include "rocksdb/memtablerep.h" #include "rocksdb/merge_operator.h" #include "rocksdb/options.h" #include "rocksdb/rate_limiter.h" #include "rocksdb/slice_transform.h" #include "rocksdb/table.h" #include "rocksdb/utilities/object_registry.h" #include "rocksdb/utilities/options_type.h" #include "util/string_util.h" namespace ROCKSDB_NAMESPACE { ConfigOptions::ConfigOptions() #ifndef ROCKSDB_LITE : registry(ObjectRegistry::NewInstance()) #endif { env = Env::Default(); } ConfigOptions::ConfigOptions(const DBOptions& db_opts) : env(db_opts.env) { #ifndef ROCKSDB_LITE registry = ObjectRegistry::NewInstance(); #endif } Status ValidateOptions(const DBOptions& db_opts, const ColumnFamilyOptions& cf_opts) { Status s; #ifndef ROCKSDB_LITE auto db_cfg = DBOptionsAsConfigurable(db_opts); auto cf_cfg = CFOptionsAsConfigurable(cf_opts); s = db_cfg->ValidateOptions(db_opts, cf_opts); if (s.ok()) s = cf_cfg->ValidateOptions(db_opts, cf_opts); #else s = cf_opts.table_factory->ValidateOptions(db_opts, cf_opts); #endif return s; } DBOptions BuildDBOptions(const ImmutableDBOptions& immutable_db_options, const MutableDBOptions& mutable_db_options) { DBOptions options; options.create_if_missing = immutable_db_options.create_if_missing; options.create_missing_column_families = immutable_db_options.create_missing_column_families; options.error_if_exists = immutable_db_options.error_if_exists; options.paranoid_checks = immutable_db_options.paranoid_checks; options.flush_verify_memtable_count = immutable_db_options.flush_verify_memtable_count; options.track_and_verify_wals_in_manifest = immutable_db_options.track_and_verify_wals_in_manifest; options.verify_sst_unique_id_in_manifest = immutable_db_options.verify_sst_unique_id_in_manifest; options.env = immutable_db_options.env; options.rate_limiter = immutable_db_options.rate_limiter; options.sst_file_manager = immutable_db_options.sst_file_manager; options.info_log = immutable_db_options.info_log; options.info_log_level = immutable_db_options.info_log_level; options.max_open_files = mutable_db_options.max_open_files; options.max_file_opening_threads = immutable_db_options.max_file_opening_threads; options.max_total_wal_size = mutable_db_options.max_total_wal_size; options.statistics = immutable_db_options.statistics; options.use_fsync = immutable_db_options.use_fsync; options.db_paths = immutable_db_options.db_paths; options.db_log_dir = immutable_db_options.db_log_dir; options.wal_dir = immutable_db_options.wal_dir; options.delete_obsolete_files_period_micros = mutable_db_options.delete_obsolete_files_period_micros; options.max_background_jobs = mutable_db_options.max_background_jobs; options.max_background_compactions = mutable_db_options.max_background_compactions; options.bytes_per_sync = mutable_db_options.bytes_per_sync; options.wal_bytes_per_sync = mutable_db_options.wal_bytes_per_sync; options.strict_bytes_per_sync = mutable_db_options.strict_bytes_per_sync; options.max_subcompactions = mutable_db_options.max_subcompactions; options.max_background_flushes = mutable_db_options.max_background_flushes; options.max_log_file_size = immutable_db_options.max_log_file_size; options.log_file_time_to_roll = immutable_db_options.log_file_time_to_roll; options.keep_log_file_num = immutable_db_options.keep_log_file_num; options.recycle_log_file_num = immutable_db_options.recycle_log_file_num; options.max_manifest_file_size = immutable_db_options.max_manifest_file_size; options.table_cache_numshardbits = immutable_db_options.table_cache_numshardbits; options.WAL_ttl_seconds = immutable_db_options.WAL_ttl_seconds; options.WAL_size_limit_MB = immutable_db_options.WAL_size_limit_MB; options.manifest_preallocation_size = immutable_db_options.manifest_preallocation_size; options.allow_mmap_reads = immutable_db_options.allow_mmap_reads; options.allow_mmap_writes = immutable_db_options.allow_mmap_writes; options.use_direct_reads = immutable_db_options.use_direct_reads; options.use_direct_io_for_flush_and_compaction = immutable_db_options.use_direct_io_for_flush_and_compaction; options.allow_fallocate = immutable_db_options.allow_fallocate; options.is_fd_close_on_exec = immutable_db_options.is_fd_close_on_exec; options.stats_dump_period_sec = mutable_db_options.stats_dump_period_sec; options.stats_persist_period_sec = mutable_db_options.stats_persist_period_sec; options.persist_stats_to_disk = immutable_db_options.persist_stats_to_disk; options.stats_history_buffer_size = mutable_db_options.stats_history_buffer_size; options.advise_random_on_open = immutable_db_options.advise_random_on_open; options.db_write_buffer_size = immutable_db_options.db_write_buffer_size; options.write_buffer_manager = immutable_db_options.write_buffer_manager; options.access_hint_on_compaction_start = immutable_db_options.access_hint_on_compaction_start; options.compaction_readahead_size = mutable_db_options.compaction_readahead_size; options.random_access_max_buffer_size = immutable_db_options.random_access_max_buffer_size; options.writable_file_max_buffer_size = mutable_db_options.writable_file_max_buffer_size; options.use_adaptive_mutex = immutable_db_options.use_adaptive_mutex; options.listeners = immutable_db_options.listeners; options.enable_thread_tracking = immutable_db_options.enable_thread_tracking; options.delayed_write_rate = mutable_db_options.delayed_write_rate; options.enable_pipelined_write = immutable_db_options.enable_pipelined_write; options.unordered_write = immutable_db_options.unordered_write; options.allow_concurrent_memtable_write = immutable_db_options.allow_concurrent_memtable_write; options.enable_write_thread_adaptive_yield = immutable_db_options.enable_write_thread_adaptive_yield; options.max_write_batch_group_size_bytes = immutable_db_options.max_write_batch_group_size_bytes; options.write_thread_max_yield_usec = immutable_db_options.write_thread_max_yield_usec; options.write_thread_slow_yield_usec = immutable_db_options.write_thread_slow_yield_usec; options.skip_stats_update_on_db_open = immutable_db_options.skip_stats_update_on_db_open; options.skip_checking_sst_file_sizes_on_db_open = immutable_db_options.skip_checking_sst_file_sizes_on_db_open; options.wal_recovery_mode = immutable_db_options.wal_recovery_mode; options.allow_2pc = immutable_db_options.allow_2pc; options.row_cache = immutable_db_options.row_cache; #ifndef ROCKSDB_LITE options.wal_filter = immutable_db_options.wal_filter; #endif // ROCKSDB_LITE options.fail_if_options_file_error = immutable_db_options.fail_if_options_file_error; options.dump_malloc_stats = immutable_db_options.dump_malloc_stats; options.avoid_flush_during_recovery = immutable_db_options.avoid_flush_during_recovery; options.avoid_flush_during_shutdown = mutable_db_options.avoid_flush_during_shutdown; options.allow_ingest_behind = immutable_db_options.allow_ingest_behind; options.two_write_queues = immutable_db_options.two_write_queues; options.manual_wal_flush = immutable_db_options.manual_wal_flush; options.wal_compression = immutable_db_options.wal_compression; options.atomic_flush = immutable_db_options.atomic_flush; options.avoid_unnecessary_blocking_io = immutable_db_options.avoid_unnecessary_blocking_io; options.log_readahead_size = immutable_db_options.log_readahead_size; options.file_checksum_gen_factory = immutable_db_options.file_checksum_gen_factory; options.best_efforts_recovery = immutable_db_options.best_efforts_recovery; options.max_bgerror_resume_count = immutable_db_options.max_bgerror_resume_count; options.bgerror_resume_retry_interval = immutable_db_options.bgerror_resume_retry_interval; options.db_host_id = immutable_db_options.db_host_id; options.allow_data_in_errors = immutable_db_options.allow_data_in_errors; options.checksum_handoff_file_types = immutable_db_options.checksum_handoff_file_types; options.lowest_used_cache_tier = immutable_db_options.lowest_used_cache_tier; options.enforce_single_del_contracts = immutable_db_options.enforce_single_del_contracts; return options; } ColumnFamilyOptions BuildColumnFamilyOptions( const ColumnFamilyOptions& options, const MutableCFOptions& mutable_cf_options) { ColumnFamilyOptions cf_opts(options); UpdateColumnFamilyOptions(mutable_cf_options, &cf_opts); // TODO(yhchiang): find some way to handle the following derived options // * max_file_size return cf_opts; } void UpdateColumnFamilyOptions(const MutableCFOptions& moptions, ColumnFamilyOptions* cf_opts) { // Memtable related options cf_opts->write_buffer_size = moptions.write_buffer_size; cf_opts->max_write_buffer_number = moptions.max_write_buffer_number; cf_opts->arena_block_size = moptions.arena_block_size; cf_opts->memtable_prefix_bloom_size_ratio = moptions.memtable_prefix_bloom_size_ratio; cf_opts->memtable_whole_key_filtering = moptions.memtable_whole_key_filtering; cf_opts->memtable_huge_page_size = moptions.memtable_huge_page_size; cf_opts->max_successive_merges = moptions.max_successive_merges; cf_opts->inplace_update_num_locks = moptions.inplace_update_num_locks; cf_opts->prefix_extractor = moptions.prefix_extractor; cf_opts->experimental_mempurge_threshold = moptions.experimental_mempurge_threshold; // Compaction related options cf_opts->disable_auto_compactions = moptions.disable_auto_compactions; cf_opts->soft_pending_compaction_bytes_limit = moptions.soft_pending_compaction_bytes_limit; cf_opts->hard_pending_compaction_bytes_limit = moptions.hard_pending_compaction_bytes_limit; cf_opts->level0_file_num_compaction_trigger = moptions.level0_file_num_compaction_trigger; cf_opts->level0_slowdown_writes_trigger = moptions.level0_slowdown_writes_trigger; cf_opts->level0_stop_writes_trigger = moptions.level0_stop_writes_trigger; cf_opts->max_compaction_bytes = moptions.max_compaction_bytes; cf_opts->target_file_size_base = moptions.target_file_size_base; cf_opts->target_file_size_multiplier = moptions.target_file_size_multiplier; cf_opts->max_bytes_for_level_base = moptions.max_bytes_for_level_base; cf_opts->max_bytes_for_level_multiplier = moptions.max_bytes_for_level_multiplier; cf_opts->ttl = moptions.ttl; cf_opts->periodic_compaction_seconds = moptions.periodic_compaction_seconds; cf_opts->max_bytes_for_level_multiplier_additional.clear(); for (auto value : moptions.max_bytes_for_level_multiplier_additional) { cf_opts->max_bytes_for_level_multiplier_additional.emplace_back(value); } cf_opts->compaction_options_fifo = moptions.compaction_options_fifo; cf_opts->compaction_options_universal = moptions.compaction_options_universal; // Blob file related options cf_opts->enable_blob_files = moptions.enable_blob_files; cf_opts->min_blob_size = moptions.min_blob_size; cf_opts->blob_file_size = moptions.blob_file_size; cf_opts->blob_compression_type = moptions.blob_compression_type; cf_opts->enable_blob_garbage_collection = moptions.enable_blob_garbage_collection; cf_opts->blob_garbage_collection_age_cutoff = moptions.blob_garbage_collection_age_cutoff; cf_opts->blob_garbage_collection_force_threshold = moptions.blob_garbage_collection_force_threshold; cf_opts->blob_compaction_readahead_size = moptions.blob_compaction_readahead_size; cf_opts->blob_file_starting_level = moptions.blob_file_starting_level; // Misc options cf_opts->max_sequential_skip_in_iterations = moptions.max_sequential_skip_in_iterations; cf_opts->check_flush_compaction_key_order = moptions.check_flush_compaction_key_order; cf_opts->paranoid_file_checks = moptions.paranoid_file_checks; cf_opts->report_bg_io_stats = moptions.report_bg_io_stats; cf_opts->compression = moptions.compression; cf_opts->compression_opts = moptions.compression_opts; cf_opts->bottommost_compression = moptions.bottommost_compression; cf_opts->bottommost_compression_opts = moptions.bottommost_compression_opts; cf_opts->sample_for_compression = moptions.sample_for_compression; cf_opts->compression_per_level = moptions.compression_per_level; cf_opts->bottommost_temperature = moptions.bottommost_temperature; } void UpdateColumnFamilyOptions(const ImmutableCFOptions& ioptions, ColumnFamilyOptions* cf_opts) { cf_opts->compaction_style = ioptions.compaction_style; cf_opts->compaction_pri = ioptions.compaction_pri; cf_opts->comparator = ioptions.user_comparator; cf_opts->merge_operator = ioptions.merge_operator; cf_opts->compaction_filter = ioptions.compaction_filter; cf_opts->compaction_filter_factory = ioptions.compaction_filter_factory; cf_opts->min_write_buffer_number_to_merge = ioptions.min_write_buffer_number_to_merge; cf_opts->max_write_buffer_number_to_maintain = ioptions.max_write_buffer_number_to_maintain; cf_opts->max_write_buffer_size_to_maintain = ioptions.max_write_buffer_size_to_maintain; cf_opts->inplace_update_support = ioptions.inplace_update_support; cf_opts->inplace_callback = ioptions.inplace_callback; cf_opts->memtable_factory = ioptions.memtable_factory; cf_opts->table_factory = ioptions.table_factory; cf_opts->table_properties_collector_factories = ioptions.table_properties_collector_factories; cf_opts->bloom_locality = ioptions.bloom_locality; cf_opts->level_compaction_dynamic_level_bytes = ioptions.level_compaction_dynamic_level_bytes; cf_opts->num_levels = ioptions.num_levels; cf_opts->optimize_filters_for_hits = ioptions.optimize_filters_for_hits; cf_opts->force_consistency_checks = ioptions.force_consistency_checks; cf_opts->memtable_insert_with_hint_prefix_extractor = ioptions.memtable_insert_with_hint_prefix_extractor; cf_opts->cf_paths = ioptions.cf_paths; cf_opts->compaction_thread_limiter = ioptions.compaction_thread_limiter; cf_opts->sst_partitioner_factory = ioptions.sst_partitioner_factory; cf_opts->blob_cache = ioptions.blob_cache; cf_opts->preclude_last_level_data_seconds = ioptions.preclude_last_level_data_seconds; // TODO(yhchiang): find some way to handle the following derived options // * max_file_size } std::map OptionsHelper::compaction_style_to_string = { {kCompactionStyleLevel, "kCompactionStyleLevel"}, {kCompactionStyleUniversal, "kCompactionStyleUniversal"}, {kCompactionStyleFIFO, "kCompactionStyleFIFO"}, {kCompactionStyleNone, "kCompactionStyleNone"}}; std::map OptionsHelper::compaction_pri_to_string = { {kByCompensatedSize, "kByCompensatedSize"}, {kOldestLargestSeqFirst, "kOldestLargestSeqFirst"}, {kOldestSmallestSeqFirst, "kOldestSmallestSeqFirst"}, {kMinOverlappingRatio, "kMinOverlappingRatio"}, {kRoundRobin, "kRoundRobin"}}; std::map OptionsHelper::compaction_stop_style_to_string = { {kCompactionStopStyleSimilarSize, "kCompactionStopStyleSimilarSize"}, {kCompactionStopStyleTotalSize, "kCompactionStopStyleTotalSize"}}; std::map OptionsHelper::temperature_to_string = { {Temperature::kUnknown, "kUnknown"}, {Temperature::kHot, "kHot"}, {Temperature::kWarm, "kWarm"}, {Temperature::kCold, "kCold"}}; std::unordered_map OptionsHelper::checksum_type_string_map = {{"kNoChecksum", kNoChecksum}, {"kCRC32c", kCRC32c}, {"kxxHash", kxxHash}, {"kxxHash64", kxxHash64}, {"kXXH3", kXXH3}}; std::unordered_map OptionsHelper::compression_type_string_map = { {"kNoCompression", kNoCompression}, {"kSnappyCompression", kSnappyCompression}, {"kZlibCompression", kZlibCompression}, {"kBZip2Compression", kBZip2Compression}, {"kLZ4Compression", kLZ4Compression}, {"kLZ4HCCompression", kLZ4HCCompression}, {"kXpressCompression", kXpressCompression}, {"kZSTD", kZSTD}, {"kZSTDNotFinalCompression", kZSTDNotFinalCompression}, {"kDisableCompressionOption", kDisableCompressionOption}}; std::vector GetSupportedCompressions() { // std::set internally to deduplicate potential name aliases std::set supported_compressions; for (const auto& comp_to_name : OptionsHelper::compression_type_string_map) { CompressionType t = comp_to_name.second; if (t != kDisableCompressionOption && CompressionTypeSupported(t)) { supported_compressions.insert(t); } } return std::vector(supported_compressions.begin(), supported_compressions.end()); } std::vector GetSupportedDictCompressions() { std::set dict_compression_types; for (const auto& comp_to_name : OptionsHelper::compression_type_string_map) { CompressionType t = comp_to_name.second; if (t != kDisableCompressionOption && DictCompressionTypeSupported(t)) { dict_compression_types.insert(t); } } return std::vector(dict_compression_types.begin(), dict_compression_types.end()); } std::vector GetSupportedChecksums() { std::set checksum_types; for (const auto& e : OptionsHelper::checksum_type_string_map) { checksum_types.insert(e.second); } return std::vector(checksum_types.begin(), checksum_types.end()); } #ifndef ROCKSDB_LITE static bool ParseOptionHelper(void* opt_address, const OptionType& opt_type, const std::string& value) { switch (opt_type) { case OptionType::kBoolean: *static_cast(opt_address) = ParseBoolean("", value); break; case OptionType::kInt: *static_cast(opt_address) = ParseInt(value); break; case OptionType::kInt32T: *static_cast(opt_address) = ParseInt32(value); break; case OptionType::kInt64T: PutUnaligned(static_cast(opt_address), ParseInt64(value)); break; case OptionType::kUInt: *static_cast(opt_address) = ParseUint32(value); break; case OptionType::kUInt8T: *static_cast(opt_address) = ParseUint8(value); break; case OptionType::kUInt32T: *static_cast(opt_address) = ParseUint32(value); break; case OptionType::kUInt64T: PutUnaligned(static_cast(opt_address), ParseUint64(value)); break; case OptionType::kSizeT: PutUnaligned(static_cast(opt_address), ParseSizeT(value)); break; case OptionType::kString: *static_cast(opt_address) = value; break; case OptionType::kDouble: *static_cast(opt_address) = ParseDouble(value); break; case OptionType::kCompactionStyle: return ParseEnum( compaction_style_string_map, value, static_cast(opt_address)); case OptionType::kCompactionPri: return ParseEnum(compaction_pri_string_map, value, static_cast(opt_address)); case OptionType::kCompressionType: return ParseEnum( compression_type_string_map, value, static_cast(opt_address)); case OptionType::kChecksumType: return ParseEnum(checksum_type_string_map, value, static_cast(opt_address)); case OptionType::kEncodingType: return ParseEnum(encoding_type_string_map, value, static_cast(opt_address)); case OptionType::kCompactionStopStyle: return ParseEnum( compaction_stop_style_string_map, value, static_cast(opt_address)); case OptionType::kEncodedString: { std::string* output_addr = static_cast(opt_address); (Slice(value)).DecodeHex(output_addr); break; } case OptionType::kTemperature: { return ParseEnum(temperature_string_map, value, static_cast(opt_address)); } default: return false; } return true; } bool SerializeSingleOptionHelper(const void* opt_address, const OptionType opt_type, std::string* value) { assert(value); switch (opt_type) { case OptionType::kBoolean: *value = *(static_cast(opt_address)) ? "true" : "false"; break; case OptionType::kInt: *value = std::to_string(*(static_cast(opt_address))); break; case OptionType::kInt32T: *value = std::to_string(*(static_cast(opt_address))); break; case OptionType::kInt64T: { int64_t v; GetUnaligned(static_cast(opt_address), &v); *value = std::to_string(v); } break; case OptionType::kUInt: *value = std::to_string(*(static_cast(opt_address))); break; case OptionType::kUInt8T: *value = std::to_string(*(static_cast(opt_address))); break; case OptionType::kUInt32T: *value = std::to_string(*(static_cast(opt_address))); break; case OptionType::kUInt64T: { uint64_t v; GetUnaligned(static_cast(opt_address), &v); *value = std::to_string(v); } break; case OptionType::kSizeT: { size_t v; GetUnaligned(static_cast(opt_address), &v); *value = std::to_string(v); } break; case OptionType::kDouble: *value = std::to_string(*(static_cast(opt_address))); break; case OptionType::kString: *value = EscapeOptionString(*(static_cast(opt_address))); break; case OptionType::kCompactionStyle: return SerializeEnum( compaction_style_string_map, *(static_cast(opt_address)), value); case OptionType::kCompactionPri: return SerializeEnum( compaction_pri_string_map, *(static_cast(opt_address)), value); case OptionType::kCompressionType: return SerializeEnum( compression_type_string_map, *(static_cast(opt_address)), value); break; case OptionType::kChecksumType: return SerializeEnum( checksum_type_string_map, *static_cast(opt_address), value); case OptionType::kEncodingType: return SerializeEnum( encoding_type_string_map, *static_cast(opt_address), value); case OptionType::kCompactionStopStyle: return SerializeEnum( compaction_stop_style_string_map, *static_cast(opt_address), value); case OptionType::kEncodedString: { const auto* ptr = static_cast(opt_address); *value = (Slice(*ptr)).ToString(true); break; } case OptionType::kTemperature: { return SerializeEnum( temperature_string_map, *static_cast(opt_address), value); } default: return false; } return true; } template Status ConfigureFromMap( const ConfigOptions& config_options, const std::unordered_map& opt_map, const std::string& option_name, Configurable* config, T* new_opts) { Status s = config->ConfigureFromMap(config_options, opt_map); if (s.ok()) { *new_opts = *(config->GetOptions(option_name)); } return s; } Status StringToMap(const std::string& opts_str, std::unordered_map* opts_map) { assert(opts_map); // Example: // opts_str = "write_buffer_size=1024;max_write_buffer_number=2;" // "nested_opt={opt1=1;opt2=2};max_bytes_for_level_base=100" size_t pos = 0; std::string opts = trim(opts_str); // If the input string starts and ends with "{...}", strip off the brackets while (opts.size() > 2 && opts[0] == '{' && opts[opts.size() - 1] == '}') { opts = trim(opts.substr(1, opts.size() - 2)); } while (pos < opts.size()) { size_t eq_pos = opts.find_first_of("={};", pos); if (eq_pos == std::string::npos) { return Status::InvalidArgument("Mismatched key value pair, '=' expected"); } else if (opts[eq_pos] != '=') { return Status::InvalidArgument("Unexpected char in key"); } std::string key = trim(opts.substr(pos, eq_pos - pos)); if (key.empty()) { return Status::InvalidArgument("Empty key found"); } std::string value; Status s = OptionTypeInfo::NextToken(opts, ';', eq_pos + 1, &pos, &value); if (!s.ok()) { return s; } else { (*opts_map)[key] = value; if (pos == std::string::npos) { break; } else { pos++; } } } return Status::OK(); } Status GetStringFromDBOptions(std::string* opt_string, const DBOptions& db_options, const std::string& delimiter) { ConfigOptions config_options(db_options); config_options.delimiter = delimiter; return GetStringFromDBOptions(config_options, db_options, opt_string); } Status GetStringFromDBOptions(const ConfigOptions& config_options, const DBOptions& db_options, std::string* opt_string) { assert(opt_string); opt_string->clear(); auto config = DBOptionsAsConfigurable(db_options); return config->GetOptionString(config_options, opt_string); } Status GetStringFromColumnFamilyOptions(std::string* opt_string, const ColumnFamilyOptions& cf_options, const std::string& delimiter) { ConfigOptions config_options; config_options.delimiter = delimiter; return GetStringFromColumnFamilyOptions(config_options, cf_options, opt_string); } Status GetStringFromColumnFamilyOptions(const ConfigOptions& config_options, const ColumnFamilyOptions& cf_options, std::string* opt_string) { const auto config = CFOptionsAsConfigurable(cf_options); return config->GetOptionString(config_options, opt_string); } Status GetStringFromCompressionType(std::string* compression_str, CompressionType compression_type) { bool ok = SerializeEnum(compression_type_string_map, compression_type, compression_str); if (ok) { return Status::OK(); } else { return Status::InvalidArgument("Invalid compression types"); } } Status GetColumnFamilyOptionsFromMap( const ColumnFamilyOptions& base_options, const std::unordered_map& opts_map, ColumnFamilyOptions* new_options, bool input_strings_escaped, bool ignore_unknown_options) { ConfigOptions config_options; config_options.ignore_unknown_options = ignore_unknown_options; config_options.input_strings_escaped = input_strings_escaped; return GetColumnFamilyOptionsFromMap(config_options, base_options, opts_map, new_options); } Status GetColumnFamilyOptionsFromMap( const ConfigOptions& config_options, const ColumnFamilyOptions& base_options, const std::unordered_map& opts_map, ColumnFamilyOptions* new_options) { assert(new_options); *new_options = base_options; const auto config = CFOptionsAsConfigurable(base_options); Status s = ConfigureFromMap( config_options, opts_map, OptionsHelper::kCFOptionsName, config.get(), new_options); // Translate any errors (NotFound, NotSupported, to InvalidArgument if (s.ok() || s.IsInvalidArgument()) { return s; } else { return Status::InvalidArgument(s.getState()); } } Status GetColumnFamilyOptionsFromString( const ColumnFamilyOptions& base_options, const std::string& opts_str, ColumnFamilyOptions* new_options) { ConfigOptions config_options; config_options.input_strings_escaped = false; config_options.ignore_unknown_options = false; return GetColumnFamilyOptionsFromString(config_options, base_options, opts_str, new_options); } Status GetColumnFamilyOptionsFromString(const ConfigOptions& config_options, const ColumnFamilyOptions& base_options, const std::string& opts_str, ColumnFamilyOptions* new_options) { std::unordered_map opts_map; Status s = StringToMap(opts_str, &opts_map); if (!s.ok()) { *new_options = base_options; return s; } return GetColumnFamilyOptionsFromMap(config_options, base_options, opts_map, new_options); } Status GetDBOptionsFromMap( const DBOptions& base_options, const std::unordered_map& opts_map, DBOptions* new_options, bool input_strings_escaped, bool ignore_unknown_options) { ConfigOptions config_options(base_options); config_options.input_strings_escaped = input_strings_escaped; config_options.ignore_unknown_options = ignore_unknown_options; return GetDBOptionsFromMap(config_options, base_options, opts_map, new_options); } Status GetDBOptionsFromMap( const ConfigOptions& config_options, const DBOptions& base_options, const std::unordered_map& opts_map, DBOptions* new_options) { assert(new_options); *new_options = base_options; auto config = DBOptionsAsConfigurable(base_options); Status s = ConfigureFromMap(config_options, opts_map, OptionsHelper::kDBOptionsName, config.get(), new_options); // Translate any errors (NotFound, NotSupported, to InvalidArgument if (s.ok() || s.IsInvalidArgument()) { return s; } else { return Status::InvalidArgument(s.getState()); } } Status GetDBOptionsFromString(const DBOptions& base_options, const std::string& opts_str, DBOptions* new_options) { ConfigOptions config_options(base_options); config_options.input_strings_escaped = false; config_options.ignore_unknown_options = false; return GetDBOptionsFromString(config_options, base_options, opts_str, new_options); } Status GetDBOptionsFromString(const ConfigOptions& config_options, const DBOptions& base_options, const std::string& opts_str, DBOptions* new_options) { std::unordered_map opts_map; Status s = StringToMap(opts_str, &opts_map); if (!s.ok()) { *new_options = base_options; return s; } return GetDBOptionsFromMap(config_options, base_options, opts_map, new_options); } Status GetOptionsFromString(const Options& base_options, const std::string& opts_str, Options* new_options) { ConfigOptions config_options(base_options); config_options.input_strings_escaped = false; config_options.ignore_unknown_options = false; return GetOptionsFromString(config_options, base_options, opts_str, new_options); } Status GetOptionsFromString(const ConfigOptions& config_options, const Options& base_options, const std::string& opts_str, Options* new_options) { ColumnFamilyOptions new_cf_options; std::unordered_map unused_opts; std::unordered_map opts_map; assert(new_options); *new_options = base_options; Status s = StringToMap(opts_str, &opts_map); if (!s.ok()) { return s; } auto config = DBOptionsAsConfigurable(base_options); s = config->ConfigureFromMap(config_options, opts_map, &unused_opts); if (s.ok()) { DBOptions* new_db_options = config->GetOptions(OptionsHelper::kDBOptionsName); if (!unused_opts.empty()) { s = GetColumnFamilyOptionsFromMap(config_options, base_options, unused_opts, &new_cf_options); if (s.ok()) { *new_options = Options(*new_db_options, new_cf_options); } } else { *new_options = Options(*new_db_options, base_options); } } // Translate any errors (NotFound, NotSupported, to InvalidArgument if (s.ok() || s.IsInvalidArgument()) { return s; } else { return Status::InvalidArgument(s.getState()); } } std::unordered_map OptionsHelper::encoding_type_string_map = {{"kPlain", kPlain}, {"kPrefix", kPrefix}}; std::unordered_map OptionsHelper::compaction_style_string_map = { {"kCompactionStyleLevel", kCompactionStyleLevel}, {"kCompactionStyleUniversal", kCompactionStyleUniversal}, {"kCompactionStyleFIFO", kCompactionStyleFIFO}, {"kCompactionStyleNone", kCompactionStyleNone}}; std::unordered_map OptionsHelper::compaction_pri_string_map = { {"kByCompensatedSize", kByCompensatedSize}, {"kOldestLargestSeqFirst", kOldestLargestSeqFirst}, {"kOldestSmallestSeqFirst", kOldestSmallestSeqFirst}, {"kMinOverlappingRatio", kMinOverlappingRatio}, {"kRoundRobin", kRoundRobin}}; std::unordered_map OptionsHelper::compaction_stop_style_string_map = { {"kCompactionStopStyleSimilarSize", kCompactionStopStyleSimilarSize}, {"kCompactionStopStyleTotalSize", kCompactionStopStyleTotalSize}}; std::unordered_map OptionsHelper::temperature_string_map = { {"kUnknown", Temperature::kUnknown}, {"kHot", Temperature::kHot}, {"kWarm", Temperature::kWarm}, {"kCold", Temperature::kCold}}; Status OptionTypeInfo::NextToken(const std::string& opts, char delimiter, size_t pos, size_t* end, std::string* token) { while (pos < opts.size() && isspace(opts[pos])) { ++pos; } // Empty value at the end if (pos >= opts.size()) { *token = ""; *end = std::string::npos; return Status::OK(); } else if (opts[pos] == '{') { int count = 1; size_t brace_pos = pos + 1; while (brace_pos < opts.size()) { if (opts[brace_pos] == '{') { ++count; } else if (opts[brace_pos] == '}') { --count; if (count == 0) { break; } } ++brace_pos; } // found the matching closing brace if (count == 0) { *token = trim(opts.substr(pos + 1, brace_pos - pos - 1)); // skip all whitespace and move to the next delimiter // brace_pos points to the next position after the matching '}' pos = brace_pos + 1; while (pos < opts.size() && isspace(opts[pos])) { ++pos; } if (pos < opts.size() && opts[pos] != delimiter) { return Status::InvalidArgument("Unexpected chars after nested options"); } *end = pos; } else { return Status::InvalidArgument( "Mismatched curly braces for nested options"); } } else { *end = opts.find(delimiter, pos); if (*end == std::string::npos) { // It either ends with a trailing semi-colon or the last key-value pair *token = trim(opts.substr(pos)); } else { *token = trim(opts.substr(pos, *end - pos)); } } return Status::OK(); } Status OptionTypeInfo::Parse(const ConfigOptions& config_options, const std::string& opt_name, const std::string& value, void* opt_ptr) const { if (IsDeprecated()) { return Status::OK(); } try { const std::string& opt_value = config_options.input_strings_escaped ? UnescapeOptionString(value) : value; if (opt_ptr == nullptr) { return Status::NotFound("Could not find option", opt_name); } else if (parse_func_ != nullptr) { ConfigOptions copy = config_options; copy.invoke_prepare_options = false; void* opt_addr = GetOffset(opt_ptr); return parse_func_(copy, opt_name, opt_value, opt_addr); } else if (ParseOptionHelper(GetOffset(opt_ptr), type_, opt_value)) { return Status::OK(); } else if (IsConfigurable()) { // The option is . Configurable* config = AsRawPointer(opt_ptr); if (opt_value.empty()) { return Status::OK(); } else if (config == nullptr) { return Status::NotFound("Could not find configurable: ", opt_name); } else { ConfigOptions copy = config_options; copy.ignore_unknown_options = false; copy.invoke_prepare_options = false; if (opt_value.find("=") != std::string::npos) { return config->ConfigureFromString(copy, opt_value); } else { return config->ConfigureOption(copy, opt_name, opt_value); } } } else if (IsByName()) { return Status::NotSupported("Deserializing the option " + opt_name + " is not supported"); } else { return Status::InvalidArgument("Error parsing:", opt_name); } } catch (std::exception& e) { return Status::InvalidArgument("Error parsing " + opt_name + ":" + std::string(e.what())); } } Status OptionTypeInfo::ParseType( const ConfigOptions& config_options, const std::string& opts_str, const std::unordered_map& type_map, void* opt_addr, std::unordered_map* unused) { std::unordered_map opts_map; Status status = StringToMap(opts_str, &opts_map); if (!status.ok()) { return status; } else { return ParseType(config_options, opts_map, type_map, opt_addr, unused); } } Status OptionTypeInfo::ParseType( const ConfigOptions& config_options, const std::unordered_map& opts_map, const std::unordered_map& type_map, void* opt_addr, std::unordered_map* unused) { for (const auto& opts_iter : opts_map) { std::string opt_name; const auto* opt_info = Find(opts_iter.first, type_map, &opt_name); if (opt_info != nullptr) { Status status = opt_info->Parse(config_options, opt_name, opts_iter.second, opt_addr); if (!status.ok()) { return status; } } else if (unused != nullptr) { (*unused)[opts_iter.first] = opts_iter.second; } else if (!config_options.ignore_unknown_options) { return Status::NotFound("Unrecognized option", opts_iter.first); } } return Status::OK(); } Status OptionTypeInfo::ParseStruct( const ConfigOptions& config_options, const std::string& struct_name, const std::unordered_map* struct_map, const std::string& opt_name, const std::string& opt_value, void* opt_addr) { assert(struct_map); Status status; if (opt_name == struct_name || EndsWith(opt_name, "." + struct_name)) { // This option represents the entire struct std::unordered_map unused; status = ParseType(config_options, opt_value, *struct_map, opt_addr, &unused); if (status.ok() && !unused.empty()) { status = Status::InvalidArgument( "Unrecognized option", struct_name + "." + unused.begin()->first); } } else if (StartsWith(opt_name, struct_name + ".")) { // This option represents a nested field in the struct (e.g, struct.field) std::string elem_name; const auto opt_info = Find(opt_name.substr(struct_name.size() + 1), *struct_map, &elem_name); if (opt_info != nullptr) { status = opt_info->Parse(config_options, elem_name, opt_value, opt_addr); } else { status = Status::InvalidArgument("Unrecognized option", opt_name); } } else { // This option represents a field in the struct (e.g. field) std::string elem_name; const auto opt_info = Find(opt_name, *struct_map, &elem_name); if (opt_info != nullptr) { status = opt_info->Parse(config_options, elem_name, opt_value, opt_addr); } else { status = Status::InvalidArgument("Unrecognized option", struct_name + "." + opt_name); } } return status; } Status OptionTypeInfo::Serialize(const ConfigOptions& config_options, const std::string& opt_name, const void* const opt_ptr, std::string* opt_value) const { // If the option is no longer used in rocksdb and marked as deprecated, // we skip it in the serialization. if (opt_ptr == nullptr || IsDeprecated()) { return Status::OK(); } else if (IsEnabled(OptionTypeFlags::kDontSerialize)) { return Status::NotSupported("Cannot serialize option: ", opt_name); } else if (serialize_func_ != nullptr) { const void* opt_addr = GetOffset(opt_ptr); return serialize_func_(config_options, opt_name, opt_addr, opt_value); } else if (IsCustomizable()) { const Customizable* custom = AsRawPointer(opt_ptr); opt_value->clear(); if (custom == nullptr) { // We do not have a custom object to serialize. // If the option is not mutable and we are doing only mutable options, // we return an empty string (which will cause the option not to be // printed). Otherwise, we return the "nullptr" string, which will result // in "option=nullptr" being printed. if (IsMutable() || !config_options.mutable_options_only) { *opt_value = kNullptrString; } else { *opt_value = ""; } } else if (IsEnabled(OptionTypeFlags::kStringNameOnly) && !config_options.IsDetailed()) { if (!config_options.mutable_options_only || IsMutable()) { *opt_value = custom->GetId(); } } else { ConfigOptions embedded = config_options; embedded.delimiter = ";"; // If this option is mutable, everything inside it should be considered // mutable if (IsMutable()) { embedded.mutable_options_only = false; } std::string value = custom->ToString(embedded); if (!embedded.mutable_options_only || value.find("=") != std::string::npos) { *opt_value = value; } else { *opt_value = ""; } } return Status::OK(); } else if (IsConfigurable()) { const Configurable* config = AsRawPointer(opt_ptr); if (config != nullptr) { ConfigOptions embedded = config_options; embedded.delimiter = ";"; *opt_value = config->ToString(embedded); } return Status::OK(); } else if (config_options.mutable_options_only && !IsMutable()) { return Status::OK(); } else if (SerializeSingleOptionHelper(GetOffset(opt_ptr), type_, opt_value)) { return Status::OK(); } else { return Status::InvalidArgument("Cannot serialize option: ", opt_name); } } Status OptionTypeInfo::SerializeType( const ConfigOptions& config_options, const std::unordered_map& type_map, const void* opt_addr, std::string* result) { Status status; for (const auto& iter : type_map) { std::string single; const auto& opt_info = iter.second; if (opt_info.ShouldSerialize()) { status = opt_info.Serialize(config_options, iter.first, opt_addr, &single); if (!status.ok()) { return status; } else { result->append(iter.first + "=" + single + config_options.delimiter); } } } return status; } Status OptionTypeInfo::SerializeStruct( const ConfigOptions& config_options, const std::string& struct_name, const std::unordered_map* struct_map, const std::string& opt_name, const void* opt_addr, std::string* value) { assert(struct_map); Status status; if (EndsWith(opt_name, struct_name)) { // We are going to write the struct as "{ prop1=value1; prop2=value2;}. // Set the delimiter to ";" so that the everything will be on one line. ConfigOptions embedded = config_options; embedded.delimiter = ";"; // This option represents the entire struct std::string result; status = SerializeType(embedded, *struct_map, opt_addr, &result); if (!status.ok()) { return status; } else { *value = "{" + result + "}"; } } else if (StartsWith(opt_name, struct_name + ".")) { // This option represents a nested field in the struct (e.g, struct.field) std::string elem_name; const auto opt_info = Find(opt_name.substr(struct_name.size() + 1), *struct_map, &elem_name); if (opt_info != nullptr) { status = opt_info->Serialize(config_options, elem_name, opt_addr, value); } else { status = Status::InvalidArgument("Unrecognized option", opt_name); } } else { // This option represents a field in the struct (e.g. field) std::string elem_name; const auto opt_info = Find(opt_name, *struct_map, &elem_name); if (opt_info == nullptr) { status = Status::InvalidArgument("Unrecognized option", opt_name); } else if (opt_info->ShouldSerialize()) { status = opt_info->Serialize(config_options, opt_name + "." + elem_name, opt_addr, value); } } return status; } template bool IsOptionEqual(const void* offset1, const void* offset2) { return (*static_cast(offset1) == *static_cast(offset2)); } static bool AreEqualDoubles(const double a, const double b) { return (fabs(a - b) < 0.00001); } static bool AreOptionsEqual(OptionType type, const void* this_offset, const void* that_offset) { switch (type) { case OptionType::kBoolean: return IsOptionEqual(this_offset, that_offset); case OptionType::kInt: return IsOptionEqual(this_offset, that_offset); case OptionType::kUInt: return IsOptionEqual(this_offset, that_offset); case OptionType::kInt32T: return IsOptionEqual(this_offset, that_offset); case OptionType::kInt64T: { int64_t v1, v2; GetUnaligned(static_cast(this_offset), &v1); GetUnaligned(static_cast(that_offset), &v2); return (v1 == v2); } case OptionType::kUInt8T: return IsOptionEqual(this_offset, that_offset); case OptionType::kUInt32T: return IsOptionEqual(this_offset, that_offset); case OptionType::kUInt64T: { uint64_t v1, v2; GetUnaligned(static_cast(this_offset), &v1); GetUnaligned(static_cast(that_offset), &v2); return (v1 == v2); } case OptionType::kSizeT: { size_t v1, v2; GetUnaligned(static_cast(this_offset), &v1); GetUnaligned(static_cast(that_offset), &v2); return (v1 == v2); } case OptionType::kString: return IsOptionEqual(this_offset, that_offset); case OptionType::kDouble: return AreEqualDoubles(*static_cast(this_offset), *static_cast(that_offset)); case OptionType::kCompactionStyle: return IsOptionEqual(this_offset, that_offset); case OptionType::kCompactionStopStyle: return IsOptionEqual(this_offset, that_offset); case OptionType::kCompactionPri: return IsOptionEqual(this_offset, that_offset); case OptionType::kCompressionType: return IsOptionEqual(this_offset, that_offset); case OptionType::kChecksumType: return IsOptionEqual(this_offset, that_offset); case OptionType::kEncodingType: return IsOptionEqual(this_offset, that_offset); case OptionType::kEncodedString: return IsOptionEqual(this_offset, that_offset); case OptionType::kTemperature: return IsOptionEqual(this_offset, that_offset); default: return false; } // End switch } bool OptionTypeInfo::AreEqual(const ConfigOptions& config_options, const std::string& opt_name, const void* const this_ptr, const void* const that_ptr, std::string* mismatch) const { auto level = GetSanityLevel(); if (!config_options.IsCheckEnabled(level)) { return true; // If the sanity level is not being checked, skip it } if (this_ptr == nullptr || that_ptr == nullptr) { if (this_ptr == that_ptr) { return true; } } else if (equals_func_ != nullptr) { const void* this_addr = GetOffset(this_ptr); const void* that_addr = GetOffset(that_ptr); if (equals_func_(config_options, opt_name, this_addr, that_addr, mismatch)) { return true; } } else { const void* this_addr = GetOffset(this_ptr); const void* that_addr = GetOffset(that_ptr); if (AreOptionsEqual(type_, this_addr, that_addr)) { return true; } else if (IsConfigurable()) { const auto* this_config = AsRawPointer(this_ptr); const auto* that_config = AsRawPointer(that_ptr); if (this_config == that_config) { return true; } else if (this_config != nullptr && that_config != nullptr) { std::string bad_name; bool matches; if (level < config_options.sanity_level) { ConfigOptions copy = config_options; copy.sanity_level = level; matches = this_config->AreEquivalent(copy, that_config, &bad_name); } else { matches = this_config->AreEquivalent(config_options, that_config, &bad_name); } if (!matches) { *mismatch = opt_name + "." + bad_name; } return matches; } } } if (mismatch->empty()) { *mismatch = opt_name; } return false; } bool OptionTypeInfo::TypesAreEqual( const ConfigOptions& config_options, const std::unordered_map& type_map, const void* this_addr, const void* that_addr, std::string* mismatch) { for (const auto& iter : type_map) { const auto& opt_info = iter.second; if (!opt_info.AreEqual(config_options, iter.first, this_addr, that_addr, mismatch)) { return false; } } return true; } bool OptionTypeInfo::StructsAreEqual( const ConfigOptions& config_options, const std::string& struct_name, const std::unordered_map* struct_map, const std::string& opt_name, const void* this_addr, const void* that_addr, std::string* mismatch) { assert(struct_map); bool matches = true; std::string result; if (EndsWith(opt_name, struct_name)) { // This option represents the entire struct matches = TypesAreEqual(config_options, *struct_map, this_addr, that_addr, &result); if (!matches) { *mismatch = struct_name + "." + result; return false; } } else if (StartsWith(opt_name, struct_name + ".")) { // This option represents a nested field in the struct (e.g, struct.field) std::string elem_name; const auto opt_info = Find(opt_name.substr(struct_name.size() + 1), *struct_map, &elem_name); assert(opt_info); if (opt_info == nullptr) { *mismatch = opt_name; matches = false; } else if (!opt_info->AreEqual(config_options, elem_name, this_addr, that_addr, &result)) { matches = false; *mismatch = struct_name + "." + result; } } else { // This option represents a field in the struct (e.g. field) std::string elem_name; const auto opt_info = Find(opt_name, *struct_map, &elem_name); assert(opt_info); if (opt_info == nullptr) { *mismatch = struct_name + "." + opt_name; matches = false; } else if (!opt_info->AreEqual(config_options, elem_name, this_addr, that_addr, &result)) { matches = false; *mismatch = struct_name + "." + result; } } return matches; } bool MatchesOptionsTypeFromMap( const ConfigOptions& config_options, const std::unordered_map& type_map, const void* const this_ptr, const void* const that_ptr, std::string* mismatch) { for (auto& pair : type_map) { // We skip checking deprecated variables as they might // contain random values since they might not be initialized if (config_options.IsCheckEnabled(pair.second.GetSanityLevel())) { if (!pair.second.AreEqual(config_options, pair.first, this_ptr, that_ptr, mismatch) && !pair.second.AreEqualByName(config_options, pair.first, this_ptr, that_ptr)) { return false; } } } return true; } bool OptionTypeInfo::AreEqualByName(const ConfigOptions& config_options, const std::string& opt_name, const void* const this_ptr, const void* const that_ptr) const { if (IsByName()) { std::string that_value; if (Serialize(config_options, opt_name, that_ptr, &that_value).ok()) { return AreEqualByName(config_options, opt_name, this_ptr, that_value); } } return false; } bool OptionTypeInfo::AreEqualByName(const ConfigOptions& config_options, const std::string& opt_name, const void* const opt_ptr, const std::string& that_value) const { std::string this_value; if (!IsByName()) { return false; } else if (!Serialize(config_options, opt_name, opt_ptr, &this_value).ok()) { return false; } else if (IsEnabled(OptionVerificationType::kByNameAllowFromNull)) { if (that_value == kNullptrString) { return true; } } else if (IsEnabled(OptionVerificationType::kByNameAllowNull)) { if (that_value == kNullptrString) { return true; } } return (this_value == that_value); } Status OptionTypeInfo::Prepare(const ConfigOptions& config_options, const std::string& name, void* opt_ptr) const { if (ShouldPrepare()) { if (prepare_func_ != nullptr) { void* opt_addr = GetOffset(opt_ptr); return prepare_func_(config_options, name, opt_addr); } else if (IsConfigurable()) { Configurable* config = AsRawPointer(opt_ptr); if (config != nullptr) { return config->PrepareOptions(config_options); } else if (!CanBeNull()) { return Status::NotFound("Missing configurable object", name); } } } return Status::OK(); } Status OptionTypeInfo::Validate(const DBOptions& db_opts, const ColumnFamilyOptions& cf_opts, const std::string& name, const void* opt_ptr) const { if (ShouldValidate()) { if (validate_func_ != nullptr) { const void* opt_addr = GetOffset(opt_ptr); return validate_func_(db_opts, cf_opts, name, opt_addr); } else if (IsConfigurable()) { const Configurable* config = AsRawPointer(opt_ptr); if (config != nullptr) { return config->ValidateOptions(db_opts, cf_opts); } else if (!CanBeNull()) { return Status::NotFound("Missing configurable object", name); } } } return Status::OK(); } const OptionTypeInfo* OptionTypeInfo::Find( const std::string& opt_name, const std::unordered_map& opt_map, std::string* elem_name) { const auto iter = opt_map.find(opt_name); // Look up the value in the map if (iter != opt_map.end()) { // Found the option in the map *elem_name = opt_name; // Return the name return &(iter->second); // Return the contents of the iterator } else { auto idx = opt_name.find("."); // Look for a separator if (idx > 0 && idx != std::string::npos) { // We found a separator auto siter = opt_map.find(opt_name.substr(0, idx)); // Look for the short name if (siter != opt_map.end()) { // We found the short name if (siter->second.IsStruct() || // If the object is a struct siter->second.IsConfigurable()) { // or a Configurable *elem_name = opt_name.substr(idx + 1); // Return the rest return &(siter->second); // Return the contents of the iterator } } } } return nullptr; } #endif // !ROCKSDB_LITE } // namespace ROCKSDB_NAMESPACE