// 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. #pragma once #include #include #include #include #include #include #include #include "rocksdb/block_cache_trace_writer.h" #include "rocksdb/iterator.h" #include "rocksdb/listener.h" #include "rocksdb/metadata.h" #include "rocksdb/options.h" #include "rocksdb/snapshot.h" #include "rocksdb/sst_file_writer.h" #include "rocksdb/thread_status.h" #include "rocksdb/transaction_log.h" #include "rocksdb/types.h" #include "rocksdb/version.h" #include "rocksdb/wide_columns.h" #ifdef _WIN32 // Windows API macro interference #undef DeleteFile #endif #if defined(__GNUC__) || defined(__clang__) #define ROCKSDB_DEPRECATED_FUNC __attribute__((__deprecated__)) #elif _WIN32 #define ROCKSDB_DEPRECATED_FUNC __declspec(deprecated) #endif namespace ROCKSDB_NAMESPACE { struct ColumnFamilyOptions; struct CompactionOptions; struct CompactRangeOptions; struct DBOptions; struct ExternalSstFileInfo; struct FlushOptions; struct Options; struct ReadOptions; struct TableProperties; struct WriteOptions; struct WaitForCompactOptions; class Env; class EventListener; class FileSystem; class Replayer; class StatsHistoryIterator; class TraceReader; class TraceWriter; class WriteBatch; extern const std::string kDefaultColumnFamilyName; extern const std::string kPersistentStatsColumnFamilyName; struct ColumnFamilyDescriptor { std::string name; ColumnFamilyOptions options; ColumnFamilyDescriptor() : name(kDefaultColumnFamilyName), options(ColumnFamilyOptions()) {} ColumnFamilyDescriptor(const std::string& _name, const ColumnFamilyOptions& _options) : name(_name), options(_options) {} }; class ColumnFamilyHandle { public: virtual ~ColumnFamilyHandle() {} // Returns the name of the column family associated with the current handle. virtual const std::string& GetName() const = 0; // Returns the ID of the column family associated with the current handle. virtual uint32_t GetID() const = 0; // Fills "*desc" with the up-to-date descriptor of the column family // associated with this handle. Since it fills "*desc" with the up-to-date // information, this call might internally lock and release DB mutex to // access the up-to-date CF options. In addition, all the pointer-typed // options cannot be referenced any longer than the original options exist. // // Note that this function is not supported in RocksDBLite. virtual Status GetDescriptor(ColumnFamilyDescriptor* desc) = 0; // Returns the comparator of the column family associated with the // current handle. virtual const Comparator* GetComparator() const = 0; }; static const int kMajorVersion = __ROCKSDB_MAJOR__; static const int kMinorVersion = __ROCKSDB_MINOR__; // A range of keys struct Range { Slice start; Slice limit; Range() {} Range(const Slice& s, const Slice& l) : start(s), limit(l) {} }; struct RangePtr { const Slice* start; const Slice* limit; RangePtr() : start(nullptr), limit(nullptr) {} RangePtr(const Slice* s, const Slice* l) : start(s), limit(l) {} }; // It is valid that files_checksums and files_checksum_func_names are both // empty (no checksum information is provided for ingestion). Otherwise, // their sizes should be the same as external_files. The file order should // be the same in three vectors and guaranteed by the caller. // Note that, we assume the temperatures of this batch of files to be // ingested are the same. struct IngestExternalFileArg { ColumnFamilyHandle* column_family = nullptr; std::vector external_files; IngestExternalFileOptions options; std::vector files_checksums; std::vector files_checksum_func_names; Temperature file_temperature = Temperature::kUnknown; }; struct GetMergeOperandsOptions { int expected_max_number_of_operands = 0; }; // A collections of table properties objects, where // key: is the table's file name. // value: the table properties object of the given table. using TablePropertiesCollection = std::unordered_map>; // A DB is a persistent, versioned ordered map from keys to values. // A DB is safe for concurrent access from multiple threads without // any external synchronization. // DB is an abstract base class with one primary implementation (DBImpl) // and a number of wrapper implementations. class DB { public: // Open the database with the specified "name" for reads and writes. // Stores a pointer to a heap-allocated database in *dbptr and returns // OK on success. // Stores nullptr in *dbptr and returns a non-OK status on error, including // if the DB is already open (read-write) by another DB object. (This // guarantee depends on options.env->LockFile(), which might not provide // this guarantee in a custom Env implementation.) // // Caller must delete *dbptr when it is no longer needed. static Status Open(const Options& options, const std::string& name, DB** dbptr); // Open DB with column families. // db_options specify database specific options // column_families is the vector of all column families in the database, // containing column family name and options. You need to open ALL column // families in the database. To get the list of column families, you can use // ListColumnFamilies(). // // The default column family name is 'default' and it's stored // in ROCKSDB_NAMESPACE::kDefaultColumnFamilyName. // If everything is OK, handles will on return be the same size // as column_families --- handles[i] will be a handle that you // will use to operate on column family column_family[i]. // Before delete DB, you have to close All column families by calling // DestroyColumnFamilyHandle() with all the handles. static Status Open(const DBOptions& db_options, const std::string& name, const std::vector& column_families, std::vector* handles, DB** dbptr); // OpenForReadOnly() creates a Read-only instance that supports reads alone. // // All DB interfaces that modify data, like put/delete, will return error. // Automatic Flush and Compactions are disabled and any manual calls // to Flush/Compaction will return error. // // While a given DB can be simultaneously opened via OpenForReadOnly // by any number of readers, if a DB is simultaneously opened by Open // and OpenForReadOnly, the read-only instance has undefined behavior // (though can often succeed if quickly closed) and the read-write // instance is unaffected. See also OpenAsSecondary. // Open the database for read only. // static Status OpenForReadOnly(const Options& options, const std::string& name, DB** dbptr, bool error_if_wal_file_exists = false); // Open the database for read only with column families. // // When opening DB with read only, you can specify only a subset of column // families in the database that should be opened. However, you always need // to specify default column family. The default column family name is // 'default' and it's stored in ROCKSDB_NAMESPACE::kDefaultColumnFamilyName // static Status OpenForReadOnly( const DBOptions& db_options, const std::string& name, const std::vector& column_families, std::vector* handles, DB** dbptr, bool error_if_wal_file_exists = false); // OpenAsSecondary() creates a secondary instance that supports read-only // operations and supports dynamic catch up with the primary (through a // call to TryCatchUpWithPrimary()). // // All DB interfaces that modify data, like put/delete, will return error. // Automatic Flush and Compactions are disabled and any manual calls // to Flush/Compaction will return error. // // Multiple secondary instances can co-exist at the same time. // // Open DB as secondary instance // // The options argument specifies the options to open the secondary instance. // Options.max_open_files should be set to -1. // The name argument specifies the name of the primary db that you have used // to open the primary instance. // The secondary_path argument points to a directory where the secondary // instance stores its info log. // The dbptr is an out-arg corresponding to the opened secondary instance. // The pointer points to a heap-allocated database, and the caller should // delete it after use. // // Return OK on success, non-OK on failures. static Status OpenAsSecondary(const Options& options, const std::string& name, const std::string& secondary_path, DB** dbptr); // Open DB as secondary instance with specified column families // // When opening DB in secondary mode, you can specify only a subset of column // families in the database that should be opened. However, you always need // to specify default column family. The default column family name is // 'default' and it's stored in ROCKSDB_NAMESPACE::kDefaultColumnFamilyName // // Column families created by the primary after the secondary instance starts // are currently ignored by the secondary instance. Column families opened // by secondary and dropped by the primary will be dropped by secondary as // well (on next invocation of TryCatchUpWithPrimary()). However the user // of the secondary instance can still access the data of such dropped column // family as long as they do not destroy the corresponding column family // handle. // // The options argument specifies the options to open the secondary instance. // Options.max_open_files should be set to -1. // The name argument specifies the name of the primary db that you have used // to open the primary instance. // The secondary_path argument points to a directory where the secondary // instance stores its info log. // The column_families argument specifies a list of column families to open. // If default column family is not specified or if any specified column // families does not exist, the function returns non-OK status. // The handles is an out-arg corresponding to the opened database column // family handles. // The dbptr is an out-arg corresponding to the opened secondary instance. // The pointer points to a heap-allocated database, and the caller should // delete it after use. Before deleting the dbptr, the user should also // delete the pointers stored in handles vector. // // Return OK on success, non-OK on failures. static Status OpenAsSecondary( const DBOptions& db_options, const std::string& name, const std::string& secondary_path, const std::vector& column_families, std::vector* handles, DB** dbptr); // Open DB and run the compaction. // It's a read-only operation, the result won't be installed to the DB, it // will be output to the `output_directory`. The API should only be used with // `options.CompactionService` to run compaction triggered by // `CompactionService`. static Status OpenAndCompact( const std::string& name, const std::string& output_directory, const std::string& input, std::string* output, const CompactionServiceOptionsOverride& override_options); static Status OpenAndCompact( const OpenAndCompactOptions& options, const std::string& name, const std::string& output_directory, const std::string& input, std::string* output, const CompactionServiceOptionsOverride& override_options); // Experimental and subject to change // Open DB and trim data newer than specified timestamp. // The trim_ts specified the user-defined timestamp trim bound. // This API should only be used at timestamp enabled column families recovery. // If some input column families do not support timestamp, nothing will // be happened to them. The data with timestamp > trim_ts // will be removed after this API returns successfully. static Status OpenAndTrimHistory( const DBOptions& db_options, const std::string& dbname, const std::vector& column_families, std::vector* handles, DB** dbptr, std::string trim_ts); // Manually, synchronously attempt to resume DB writes after a write failure // to the underlying filesystem. See // https://github.com/facebook/rocksdb/wiki/Background-Error-Handling // // Returns OK if writes are successfully resumed, or there was no // outstanding error to recover from. Returns underlying write error if // it is not recoverable. // // WART: Does not mix well with auto-resume. Will return Busy if an // auto-resume is in progress, without waiting for it to complete. // See DBOptions::max_bgerror_resume_count and // EventListener::OnErrorRecoveryBegin virtual Status Resume() { return Status::NotSupported(); } // Close the DB by releasing resources, closing files etc. This should be // called before calling the destructor so that the caller can get back a // status in case there are any errors. This will not fsync the WAL files. // If syncing is required, the caller must first call SyncWAL(), or Write() // using an empty write batch with WriteOptions.sync=true. // Regardless of the return status, the DB must be freed. // If the return status is Aborted(), closing fails because there is // unreleased snapshot in the system. In this case, users can release // the unreleased snapshots and try again and expect it to succeed. For // other status, re-calling Close() will be no-op and return the original // close status. If the return status is NotSupported(), then the DB // implementation does cleanup in the destructor virtual Status Close() { return Status::NotSupported(); } // ListColumnFamilies will open the DB specified by argument name // and return the list of all column families in that DB // through column_families argument. The ordering of // column families in column_families is unspecified. static Status ListColumnFamilies(const DBOptions& db_options, const std::string& name, std::vector* column_families); // Abstract class ctor DB() {} // No copying allowed DB(const DB&) = delete; void operator=(const DB&) = delete; virtual ~DB(); // Create a column_family and return the handle of column family // through the argument handle. virtual Status CreateColumnFamily(const ColumnFamilyOptions& options, const std::string& column_family_name, ColumnFamilyHandle** handle); // Bulk create column families with the same column family options. // Return the handles of the column families through the argument handles. // In case of error, the request may succeed partially, and handles will // contain column family handles that it managed to create, and have size // equal to the number of created column families. virtual Status CreateColumnFamilies( const ColumnFamilyOptions& options, const std::vector& column_family_names, std::vector* handles); // Bulk create column families. // Return the handles of the column families through the argument handles. // In case of error, the request may succeed partially, and handles will // contain column family handles that it managed to create, and have size // equal to the number of created column families. virtual Status CreateColumnFamilies( const std::vector& column_families, std::vector* handles); // Drop a column family specified by column_family handle. This call // only records a drop record in the manifest and prevents the column // family from flushing and compacting. virtual Status DropColumnFamily(ColumnFamilyHandle* column_family); // Bulk drop column families. This call only records drop records in the // manifest and prevents the column families from flushing and compacting. // In case of error, the request may succeed partially. User may call // ListColumnFamilies to check the result. virtual Status DropColumnFamilies( const std::vector& column_families); // Release and deallocate a column family handle. A column family is only // removed once it is dropped (DropColumnFamily) and all handles have been // destroyed (DestroyColumnFamilyHandle). Use this method to destroy // column family handles (except for DefaultColumnFamily()!) before closing // a DB. virtual Status DestroyColumnFamilyHandle(ColumnFamilyHandle* column_family); // Set the database entry for "key" to "value". // If "key" already exists, it will be overwritten. // Returns OK on success, and a non-OK status on error. // Note: consider setting options.sync = true. virtual Status Put(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& key, const Slice& value) = 0; virtual Status Put(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& key, const Slice& ts, const Slice& value) = 0; virtual Status Put(const WriteOptions& options, const Slice& key, const Slice& value) { return Put(options, DefaultColumnFamily(), key, value); } virtual Status Put(const WriteOptions& options, const Slice& key, const Slice& ts, const Slice& value) { return Put(options, DefaultColumnFamily(), key, ts, value); } // Set the database entry for "key" in the column family specified by // "column_family" to the wide-column entity defined by "columns". If the key // already exists in the column family, it will be overwritten. // // Returns OK on success, and a non-OK status on error. virtual Status PutEntity(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& key, const WideColumns& columns); // Remove the database entry (if any) for "key". Returns OK on // success, and a non-OK status on error. It is not an error if "key" // did not exist in the database. // Note: consider setting options.sync = true. virtual Status Delete(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& key) = 0; virtual Status Delete(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& key, const Slice& ts) = 0; virtual Status Delete(const WriteOptions& options, const Slice& key) { return Delete(options, DefaultColumnFamily(), key); } virtual Status Delete(const WriteOptions& options, const Slice& key, const Slice& ts) { return Delete(options, DefaultColumnFamily(), key, ts); } // Remove the database entry for "key". Requires that the key exists // and was not overwritten. Returns OK on success, and a non-OK status // on error. It is not an error if "key" did not exist in the database. // // If a key is overwritten (by calling Put() multiple times), then the result // of calling SingleDelete() on this key is undefined. SingleDelete() only // behaves correctly if there has been only one Put() for this key since the // previous call to SingleDelete() for this key. // // This feature is currently an experimental performance optimization // for a very specific workload. It is up to the caller to ensure that // SingleDelete is only used for a key that is not deleted using Delete() or // written using Merge(). Mixing SingleDelete operations with Deletes and // Merges can result in undefined behavior. // // Note: consider setting options.sync = true. virtual Status SingleDelete(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& key) = 0; virtual Status SingleDelete(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& key, const Slice& ts) = 0; virtual Status SingleDelete(const WriteOptions& options, const Slice& key) { return SingleDelete(options, DefaultColumnFamily(), key); } virtual Status SingleDelete(const WriteOptions& options, const Slice& key, const Slice& ts) { return SingleDelete(options, DefaultColumnFamily(), key, ts); } // Removes the database entries in the range ["begin_key", "end_key"), i.e., // including "begin_key" and excluding "end_key". Returns OK on success, and // a non-OK status on error. It is not an error if the database does not // contain any existing data in the range ["begin_key", "end_key"). // // If "end_key" comes before "start_key" according to the user's comparator, // a `Status::InvalidArgument` is returned. // // This feature is now usable in production, with the following caveats: // 1) Accumulating too many range tombstones in the memtable will degrade read // performance; this can be avoided by manually flushing occasionally. // 2) Limiting the maximum number of open files in the presence of range // tombstones can degrade read performance. To avoid this problem, set // max_open_files to -1 whenever possible. virtual Status DeleteRange(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& begin_key, const Slice& end_key); virtual Status DeleteRange(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& begin_key, const Slice& end_key, const Slice& ts); // Merge the database entry for "key" with "value". Returns OK on success, // and a non-OK status on error. The semantics of this operation is // determined by the user provided merge_operator when opening DB. // Note: consider setting options.sync = true. virtual Status Merge(const WriteOptions& options, ColumnFamilyHandle* column_family, const Slice& key, const Slice& value) = 0; virtual Status Merge(const WriteOptions& options, const Slice& key, const Slice& value) { return Merge(options, DefaultColumnFamily(), key, value); } virtual Status Merge(const WriteOptions& /*options*/, ColumnFamilyHandle* /*column_family*/, const Slice& /*key*/, const Slice& /*ts*/, const Slice& /*value*/); // Apply the specified updates to the database. // If `updates` contains no update, WAL will still be synced if // options.sync=true. // Returns OK on success, non-OK on failure. // Note: consider setting options.sync = true. virtual Status Write(const WriteOptions& options, WriteBatch* updates) = 0; // If the column family specified by "column_family" contains an entry for // "key", return the corresponding value in "*value". If the entry is a plain // key-value, return the value as-is; if it is a wide-column entity, return // the value of its default anonymous column (see kDefaultWideColumnName) if // any, or an empty value otherwise. // // If timestamp is enabled and a non-null timestamp pointer is passed in, // timestamp is returned. // // Returns OK on success. Returns NotFound and an empty value in "*value" if // there is no entry for "key". Returns some other non-OK status on error. virtual inline Status Get(const ReadOptions& options, ColumnFamilyHandle* column_family, const Slice& key, std::string* value) { assert(value != nullptr); PinnableSlice pinnable_val(value); assert(!pinnable_val.IsPinned()); auto s = Get(options, column_family, key, &pinnable_val); if (s.ok() && pinnable_val.IsPinned()) { value->assign(pinnable_val.data(), pinnable_val.size()); } // else value is already assigned return s; } virtual Status Get(const ReadOptions& options, ColumnFamilyHandle* column_family, const Slice& key, PinnableSlice* value) = 0; virtual Status Get(const ReadOptions& options, const Slice& key, std::string* value) { return Get(options, DefaultColumnFamily(), key, value); } // Get() methods that return timestamp. Derived DB classes don't need to worry // about this group of methods if they don't care about timestamp feature. virtual inline Status Get(const ReadOptions& options, ColumnFamilyHandle* column_family, const Slice& key, std::string* value, std::string* timestamp) { assert(value != nullptr); PinnableSlice pinnable_val(value); assert(!pinnable_val.IsPinned()); auto s = Get(options, column_family, key, &pinnable_val, timestamp); if (s.ok() && pinnable_val.IsPinned()) { value->assign(pinnable_val.data(), pinnable_val.size()); } // else value is already assigned return s; } virtual Status Get(const ReadOptions& /*options*/, ColumnFamilyHandle* /*column_family*/, const Slice& /*key*/, PinnableSlice* /*value*/, std::string* /*timestamp*/) { return Status::NotSupported( "Get() that returns timestamp is not implemented."); } virtual Status Get(const ReadOptions& options, const Slice& key, std::string* value, std::string* timestamp) { return Get(options, DefaultColumnFamily(), key, value, timestamp); } // If the column family specified by "column_family" contains an entry for // "key", return it as a wide-column entity in "*columns". If the entry is a // wide-column entity, return it as-is; if it is a plain key-value, return it // as an entity with a single anonymous column (see kDefaultWideColumnName) // which contains the value. // // Returns OK on success. Returns NotFound and an empty wide-column entity in // "*columns" if there is no entry for "key". Returns some other non-OK status // on error. virtual Status GetEntity(const ReadOptions& /* options */, ColumnFamilyHandle* /* column_family */, const Slice& /* key */, PinnableWideColumns* /* columns */) { return Status::NotSupported("GetEntity not supported"); } // Populates the `merge_operands` array with all the merge operands in the DB // for `key`. The `merge_operands` array will be populated in the order of // insertion. The number of entries populated in `merge_operands` will be // assigned to `*number_of_operands`. // // If the number of merge operands in DB for `key` is greater than // `merge_operands_options.expected_max_number_of_operands`, // `merge_operands` is not populated and the return value is // `Status::Incomplete`. In that case, `*number_of_operands` will be assigned // the number of merge operands found in the DB for `key`. // // `merge_operands`- Points to an array of at-least // merge_operands_options.expected_max_number_of_operands and the // caller is responsible for allocating it. // // The caller should delete or `Reset()` the `merge_operands` entries when // they are no longer needed. All `merge_operands` entries must be destroyed // or `Reset()` before this DB is closed or destroyed. virtual Status GetMergeOperands( const ReadOptions& options, ColumnFamilyHandle* column_family, const Slice& key, PinnableSlice* merge_operands, GetMergeOperandsOptions* get_merge_operands_options, int* number_of_operands) = 0; // Consistent Get of many keys across column families without the need // for an explicit snapshot. NOTE: the implementation of this MultiGet API // does not have the performance benefits of the void-returning MultiGet // functions. // // If keys[i] does not exist in the database, then the i'th returned // status will be one for which Status::IsNotFound() is true, and // (*values)[i] will be set to some arbitrary value (often ""). Otherwise, // the i'th returned status will have Status::ok() true, and (*values)[i] // will store the value associated with keys[i]. // // (*values) will always be resized to be the same size as (keys). // Similarly, the number of returned statuses will be the number of keys. // Note: keys will not be "de-duplicated". Duplicate keys will return // duplicate values in order. virtual std::vector MultiGet( const ReadOptions& options, const std::vector& column_family, const std::vector& keys, std::vector* values) = 0; virtual std::vector MultiGet(const ReadOptions& options, const std::vector& keys, std::vector* values) { return MultiGet( options, std::vector(keys.size(), DefaultColumnFamily()), keys, values); } virtual std::vector MultiGet( const ReadOptions& /*options*/, const std::vector& /*column_family*/, const std::vector& keys, std::vector* /*values*/, std::vector* /*timestamps*/) { return std::vector( keys.size(), Status::NotSupported( "MultiGet() returning timestamps not implemented.")); } virtual std::vector MultiGet(const ReadOptions& options, const std::vector& keys, std::vector* values, std::vector* timestamps) { return MultiGet( options, std::vector(keys.size(), DefaultColumnFamily()), keys, values, timestamps); } // Overloaded MultiGet API that improves performance by batching operations // in the read path for greater efficiency. Currently, only the block based // table format with full filters are supported. Other table formats such // as plain table, block based table with block based filters and // partitioned indexes will still work, but will not get any performance // benefits. // Parameters - // options - ReadOptions // column_family - ColumnFamilyHandle* that the keys belong to. All the keys // passed to the API are restricted to a single column family // num_keys - Number of keys to lookup // keys - Pointer to C style array of key Slices with num_keys elements // values - Pointer to C style array of PinnableSlices with num_keys elements // statuses - Pointer to C style array of Status with num_keys elements // sorted_input - If true, it means the input keys are already sorted by key // order, so the MultiGet() API doesn't have to sort them // again. If false, the keys will be copied and sorted // internally by the API - the input array will not be // modified virtual void MultiGet(const ReadOptions& options, ColumnFamilyHandle* column_family, const size_t num_keys, const Slice* keys, PinnableSlice* values, Status* statuses, const bool /*sorted_input*/ = false) { std::vector cf; std::vector user_keys; std::vector status; std::vector vals; for (size_t i = 0; i < num_keys; ++i) { cf.emplace_back(column_family); user_keys.emplace_back(keys[i]); } status = MultiGet(options, cf, user_keys, &vals); std::copy(status.begin(), status.end(), statuses); for (auto& value : vals) { values->PinSelf(value); values++; } } virtual void MultiGet(const ReadOptions& options, ColumnFamilyHandle* column_family, const size_t num_keys, const Slice* keys, PinnableSlice* values, std::string* timestamps, Status* statuses, const bool /*sorted_input*/ = false) { std::vector cf; std::vector user_keys; std::vector status; std::vector vals; std::vector tss; for (size_t i = 0; i < num_keys; ++i) { cf.emplace_back(column_family); user_keys.emplace_back(keys[i]); } status = MultiGet(options, cf, user_keys, &vals, &tss); std::copy(status.begin(), status.end(), statuses); std::copy(tss.begin(), tss.end(), timestamps); for (auto& value : vals) { values->PinSelf(value); values++; } } // Overloaded MultiGet API that improves performance by batching operations // in the read path for greater efficiency. Currently, only the block based // table format with full filters are supported. Other table formats such // as plain table, block based table with block based filters and // partitioned indexes will still work, but will not get any performance // benefits. // Parameters - // options - ReadOptions // column_family - ColumnFamilyHandle* that the keys belong to. All the keys // passed to the API are restricted to a single column family // num_keys - Number of keys to lookup // keys - Pointer to C style array of key Slices with num_keys elements // values - Pointer to C style array of PinnableSlices with num_keys elements // statuses - Pointer to C style array of Status with num_keys elements // sorted_input - If true, it means the input keys are already sorted by key // order, so the MultiGet() API doesn't have to sort them // again. If false, the keys will be copied and sorted // internally by the API - the input array will not be // modified virtual void MultiGet(const ReadOptions& options, const size_t num_keys, ColumnFamilyHandle** column_families, const Slice* keys, PinnableSlice* values, Status* statuses, const bool /*sorted_input*/ = false) { std::vector cf; std::vector user_keys; std::vector status; std::vector vals; for (size_t i = 0; i < num_keys; ++i) { cf.emplace_back(column_families[i]); user_keys.emplace_back(keys[i]); } status = MultiGet(options, cf, user_keys, &vals); std::copy(status.begin(), status.end(), statuses); for (auto& value : vals) { values->PinSelf(value); values++; } } virtual void MultiGet(const ReadOptions& options, const size_t num_keys, ColumnFamilyHandle** column_families, const Slice* keys, PinnableSlice* values, std::string* timestamps, Status* statuses, const bool /*sorted_input*/ = false) { std::vector cf; std::vector user_keys; std::vector status; std::vector vals; std::vector tss; for (size_t i = 0; i < num_keys; ++i) { cf.emplace_back(column_families[i]); user_keys.emplace_back(keys[i]); } status = MultiGet(options, cf, user_keys, &vals, &tss); std::copy(status.begin(), status.end(), statuses); std::copy(tss.begin(), tss.end(), timestamps); for (auto& value : vals) { values->PinSelf(value); values++; } } // Batched MultiGet-like API that returns wide-column entities from a single // column family. For any given "key[i]" in "keys" (where 0 <= "i" < // "num_keys"), if the column family specified by "column_family" contains an // entry, it is returned it as a wide-column entity in "results[i]". If the // entry is a wide-column entity, it is returned as-is; if it is a plain // key-value, it is returned as an entity with a single anonymous column (see // kDefaultWideColumnName) which contains the value. // // "statuses[i]" is set to OK if "keys[i]" is successfully retrieved. It is // set to NotFound and an empty wide-column entity is returned in "results[i]" // if there is no entry for "keys[i]". Finally, "statuses[i]" is set to some // other non-OK status on error. // // If "keys" are sorted according to the column family's comparator, the // "sorted_input" flag can be set for a small performance improvement. // // Note that it is the caller's responsibility to ensure that "keys", // "results", and "statuses" point to "num_keys" number of contiguous objects // (Slices, PinnableWideColumns, and Statuses respectively). virtual void MultiGetEntity(const ReadOptions& /* options */, ColumnFamilyHandle* /* column_family */, size_t num_keys, const Slice* /* keys */, PinnableWideColumns* /* results */, Status* statuses, bool /* sorted_input */ = false) { for (size_t i = 0; i < num_keys; ++i) { statuses[i] = Status::NotSupported("MultiGetEntity not supported"); } } // Batched MultiGet-like API that returns wide-column entities potentially // from multiple column families. For any given "key[i]" in "keys" (where 0 <= // "i" < "num_keys"), if the column family specified by "column_families[i]" // contains an entry, it is returned it as a wide-column entity in // "results[i]". If the entry is a wide-column entity, it is returned as-is; // if it is a plain key-value, it is returned as an entity with a single // anonymous column (see kDefaultWideColumnName) which contains the value. // // "statuses[i]" is set to OK if "keys[i]" is successfully retrieved. It is // set to NotFound and an empty wide-column entity is returned in "results[i]" // if there is no entry for "keys[i]". Finally, "statuses[i]" is set to some // other non-OK status on error. // // If "keys" are sorted by column family id and within each column family, // according to the column family's comparator, the "sorted_input" flag can be // set for a small performance improvement. // // Note that it is the caller's responsibility to ensure that // "column_families", "keys", "results", and "statuses" point to "num_keys" // number of contiguous objects (ColumnFamilyHandle pointers, Slices, // PinnableWideColumns, and Statuses respectively). virtual void MultiGetEntity(const ReadOptions& /* options */, size_t num_keys, ColumnFamilyHandle** /* column_families */, const Slice* /* keys */, PinnableWideColumns* /* results */, Status* statuses, bool /* sorted_input */ = false) { for (size_t i = 0; i < num_keys; ++i) { statuses[i] = Status::NotSupported("MultiGetEntity not supported"); } } // If the key definitely does not exist in the database, then this method // returns false, else true. If the caller wants to obtain value when the key // is found in memory, a bool for 'value_found' must be passed. 'value_found' // will be true on return if value has been set properly. // This check is potentially lighter-weight than invoking DB::Get(). One way // to make this lighter weight is to avoid doing any IOs. // Default implementation here returns true and sets 'value_found' to false virtual bool KeyMayExist(const ReadOptions& /*options*/, ColumnFamilyHandle* /*column_family*/, const Slice& /*key*/, std::string* /*value*/, std::string* /*timestamp*/, bool* value_found = nullptr) { if (value_found != nullptr) { *value_found = false; } return true; } virtual bool KeyMayExist(const ReadOptions& options, ColumnFamilyHandle* column_family, const Slice& key, std::string* value, bool* value_found = nullptr) { return KeyMayExist(options, column_family, key, value, /*timestamp=*/nullptr, value_found); } virtual bool KeyMayExist(const ReadOptions& options, const Slice& key, std::string* value, bool* value_found = nullptr) { return KeyMayExist(options, DefaultColumnFamily(), key, value, value_found); } virtual bool KeyMayExist(const ReadOptions& options, const Slice& key, std::string* value, std::string* timestamp, bool* value_found = nullptr) { return KeyMayExist(options, DefaultColumnFamily(), key, value, timestamp, value_found); } // Return a heap-allocated iterator over the contents of the database. // The result of NewIterator() is initially invalid (caller must // call one of the Seek methods on the iterator before using it). // // Caller should delete the iterator when it is no longer needed. // The returned iterator should be deleted before this db is deleted. virtual Iterator* NewIterator(const ReadOptions& options, ColumnFamilyHandle* column_family) = 0; virtual Iterator* NewIterator(const ReadOptions& options) { return NewIterator(options, DefaultColumnFamily()); } // Returns iterators from a consistent database state across multiple // column families. Iterators are heap allocated and need to be deleted // before the db is deleted virtual Status NewIterators( const ReadOptions& options, const std::vector& column_families, std::vector* iterators) = 0; // Return a handle to the current DB state. Iterators created with // this handle will all observe a stable snapshot of the current DB // state. The caller must call ReleaseSnapshot(result) when the // snapshot is no longer needed. // // nullptr will be returned if the DB fails to take a snapshot or does // not support snapshot (eg: inplace_update_support enabled). virtual const Snapshot* GetSnapshot() = 0; // Release a previously acquired snapshot. The caller must not // use "snapshot" after this call. virtual void ReleaseSnapshot(const Snapshot* snapshot) = 0; // Contains all valid property arguments for GetProperty() or // GetMapProperty(). Each is a "string" property for retrieval with // GetProperty() unless noted as a "map" property, for GetMapProperty(). // // NOTE: Property names cannot end in numbers since those are interpreted as // arguments, e.g., see kNumFilesAtLevelPrefix. struct Properties { // "rocksdb.num-files-at-level" - returns string containing the number // of files at level , where is an ASCII representation of a // level number (e.g., "0"). static const std::string kNumFilesAtLevelPrefix; // "rocksdb.compression-ratio-at-level" - returns string containing the // compression ratio of data at level , where is an ASCII // representation of a level number (e.g., "0"). Here, compression // ratio is defined as uncompressed data size / compressed file size. // Returns "-1.0" if no open files at level . static const std::string kCompressionRatioAtLevelPrefix; // "rocksdb.stats" - returns a multi-line string containing the data // described by kCFStats followed by the data described by kDBStats. static const std::string kStats; // "rocksdb.sstables" - returns a multi-line string summarizing current // SST files. static const std::string kSSTables; // "rocksdb.cfstats" - Raw data from "rocksdb.cfstats-no-file-histogram" // and "rocksdb.cf-file-histogram" as a "map" property. static const std::string kCFStats; // "rocksdb.cfstats-no-file-histogram" - returns a multi-line string with // general column family stats per-level over db's lifetime ("L"), // aggregated over db's lifetime ("Sum"), and aggregated over the // interval since the last retrieval ("Int"). static const std::string kCFStatsNoFileHistogram; // "rocksdb.cf-file-histogram" - print out how many file reads to every // level, as well as the histogram of latency of single requests. static const std::string kCFFileHistogram; // "rocksdb.cf-write-stall-stats" - returns a multi-line string or // map with statistics on CF-scope write stalls for a given CF // See`WriteStallStatsMapKeys` for structured representation of keys // available in the map form. static const std::string kCFWriteStallStats; // "rocksdb.db-write-stall-stats" - returns a multi-line string or // map with statistics on DB-scope write stalls // See`WriteStallStatsMapKeys` for structured representation of keys // available in the map form. static const std::string kDBWriteStallStats; // "rocksdb.dbstats" - As a string property, returns a multi-line string // with general database stats, both cumulative (over the db's // lifetime) and interval (since the last retrieval of kDBStats). // As a map property, returns cumulative stats only and does not // update the baseline for the interval stats. static const std::string kDBStats; // "rocksdb.levelstats" - returns multi-line string containing the number // of files per level and total size of each level (MB). static const std::string kLevelStats; // "rocksdb.block-cache-entry-stats" - returns a multi-line string or // map with statistics on block cache usage. See // `BlockCacheEntryStatsMapKeys` for structured representation of keys // available in the map form. static const std::string kBlockCacheEntryStats; // "rocksdb.fast-block-cache-entry-stats" - same as above, but returns // stale values more frequently to reduce overhead and latency. static const std::string kFastBlockCacheEntryStats; // "rocksdb.num-immutable-mem-table" - returns number of immutable // memtables that have not yet been flushed. static const std::string kNumImmutableMemTable; // "rocksdb.num-immutable-mem-table-flushed" - returns number of immutable // memtables that have already been flushed. static const std::string kNumImmutableMemTableFlushed; // "rocksdb.mem-table-flush-pending" - returns 1 if a memtable flush is // pending; otherwise, returns 0. static const std::string kMemTableFlushPending; // "rocksdb.num-running-flushes" - returns the number of currently running // flushes. static const std::string kNumRunningFlushes; // "rocksdb.compaction-pending" - returns 1 if at least one compaction is // pending; otherwise, returns 0. static const std::string kCompactionPending; // "rocksdb.num-running-compactions" - returns the number of currently // running compactions. static const std::string kNumRunningCompactions; // "rocksdb.background-errors" - returns accumulated number of background // errors. static const std::string kBackgroundErrors; // "rocksdb.cur-size-active-mem-table" - returns approximate size of active // memtable (bytes). static const std::string kCurSizeActiveMemTable; // "rocksdb.cur-size-all-mem-tables" - returns approximate size of active // and unflushed immutable memtables (bytes). static const std::string kCurSizeAllMemTables; // "rocksdb.size-all-mem-tables" - returns approximate size of active, // unflushed immutable, and pinned immutable memtables (bytes). static const std::string kSizeAllMemTables; // "rocksdb.num-entries-active-mem-table" - returns total number of entries // in the active memtable. static const std::string kNumEntriesActiveMemTable; // "rocksdb.num-entries-imm-mem-tables" - returns total number of entries // in the unflushed immutable memtables. static const std::string kNumEntriesImmMemTables; // "rocksdb.num-deletes-active-mem-table" - returns total number of delete // entries in the active memtable. static const std::string kNumDeletesActiveMemTable; // "rocksdb.num-deletes-imm-mem-tables" - returns total number of delete // entries in the unflushed immutable memtables. static const std::string kNumDeletesImmMemTables; // "rocksdb.estimate-num-keys" - returns estimated number of total keys in // the active and unflushed immutable memtables and storage. static const std::string kEstimateNumKeys; // "rocksdb.estimate-table-readers-mem" - returns estimated memory used for // reading SST tables, excluding memory used in block cache (e.g., // filter and index blocks). static const std::string kEstimateTableReadersMem; // "rocksdb.is-file-deletions-enabled" - returns 0 if deletion of obsolete // files is enabled; otherwise, returns a non-zero number. // This name may be misleading because true(non-zero) means disable, // but we keep the name for backward compatibility. static const std::string kIsFileDeletionsEnabled; // "rocksdb.num-snapshots" - returns number of unreleased snapshots of the // database. static const std::string kNumSnapshots; // "rocksdb.oldest-snapshot-time" - returns number representing unix // timestamp of oldest unreleased snapshot. static const std::string kOldestSnapshotTime; // "rocksdb.oldest-snapshot-sequence" - returns number representing // sequence number of oldest unreleased snapshot. static const std::string kOldestSnapshotSequence; // "rocksdb.num-live-versions" - returns number of live versions. `Version` // is an internal data structure. See version_set.h for details. More // live versions often mean more SST files are held from being deleted, // by iterators or unfinished compactions. static const std::string kNumLiveVersions; // "rocksdb.current-super-version-number" - returns number of current LSM // version. It is a uint64_t integer number, incremented after there is // any change to the LSM tree. The number is not preserved after restarting // the DB. After DB restart, it will start from 0 again. static const std::string kCurrentSuperVersionNumber; // "rocksdb.estimate-live-data-size" - returns an estimate of the amount of // live data in bytes. For BlobDB, it also includes the exact value of // live bytes in the blob files of the version. static const std::string kEstimateLiveDataSize; // "rocksdb.min-log-number-to-keep" - return the minimum log number of the // log files that should be kept. static const std::string kMinLogNumberToKeep; // "rocksdb.min-obsolete-sst-number-to-keep" - return the minimum file // number for an obsolete SST to be kept. The max value of `uint64_t` // will be returned if all obsolete files can be deleted. static const std::string kMinObsoleteSstNumberToKeep; // "rocksdb.total-sst-files-size" - returns total size (bytes) of all SST // files belonging to any of the CF's versions. // WARNING: may slow down online queries if there are too many files. static const std::string kTotalSstFilesSize; // "rocksdb.live-sst-files-size" - returns total size (bytes) of all SST // files belong to the CF's current version. static const std::string kLiveSstFilesSize; // "rocksdb.obsolete-sst-files-size" - returns total size (bytes) of all // SST files that became obsolete but have not yet been deleted or // scheduled for deletion. SST files can end up in this state when // using `DisableFileDeletions()`, for example. // // N.B. Unlike the other "*SstFilesSize" properties, this property // includes SST files that originated in any of the DB's CFs. static const std::string kObsoleteSstFilesSize; // "rocksdb.live_sst_files_size_at_temperature" - returns total size (bytes) // of SST files at all certain file temperature static const std::string kLiveSstFilesSizeAtTemperature; // "rocksdb.base-level" - returns number of level to which L0 data will be // compacted. static const std::string kBaseLevel; // "rocksdb.estimate-pending-compaction-bytes" - returns estimated total // number of bytes compaction needs to rewrite to get all levels down // to under target size. Not valid for other compactions than level- // based. static const std::string kEstimatePendingCompactionBytes; // "rocksdb.aggregated-table-properties" - returns a string or map // representation of the aggregated table properties of the target // column family. Only properties that make sense for aggregation // are included. static const std::string kAggregatedTableProperties; // "rocksdb.aggregated-table-properties-at-level", same as the previous // one but only returns the aggregated table properties of the // specified level "N" at the target column family. static const std::string kAggregatedTablePropertiesAtLevel; // "rocksdb.actual-delayed-write-rate" - returns the current actual delayed // write rate. 0 means no delay. static const std::string kActualDelayedWriteRate; // "rocksdb.is-write-stopped" - Return 1 if write has been stopped. static const std::string kIsWriteStopped; // "rocksdb.estimate-oldest-key-time" - returns an estimation of // oldest key timestamp in the DB. Currently only available for // FIFO compaction with // compaction_options_fifo.allow_compaction = false. static const std::string kEstimateOldestKeyTime; // "rocksdb.block-cache-capacity" - returns block cache capacity. static const std::string kBlockCacheCapacity; // "rocksdb.block-cache-usage" - returns the memory size for the entries // residing in block cache. static const std::string kBlockCacheUsage; // "rocksdb.block-cache-pinned-usage" - returns the memory size for the // entries being pinned. static const std::string kBlockCachePinnedUsage; // "rocksdb.options-statistics" - returns multi-line string // of options.statistics static const std::string kOptionsStatistics; // "rocksdb.num-blob-files" - returns number of blob files in the current // version. static const std::string kNumBlobFiles; // "rocksdb.blob-stats" - return the total number and size of all blob // files, and total amount of garbage (bytes) in the blob files in // the current version. static const std::string kBlobStats; // "rocksdb.total-blob-file-size" - returns the total size of all blob // files over all versions. static const std::string kTotalBlobFileSize; // "rocksdb.live-blob-file-size" - returns the total size of all blob // files in the current version. static const std::string kLiveBlobFileSize; // "rocksdb.live-blob-file-garbage-size" - returns the total amount of // garbage in the blob files in the current version. static const std::string kLiveBlobFileGarbageSize; // "rocksdb.blob-cache-capacity" - returns blob cache capacity. static const std::string kBlobCacheCapacity; // "rocksdb.blob-cache-usage" - returns the memory size for the entries // residing in blob cache. static const std::string kBlobCacheUsage; // "rocksdb.blob-cache-pinned-usage" - returns the memory size for the // entries being pinned in blob cache. static const std::string kBlobCachePinnedUsage; }; // DB implementations export properties about their state via this method. // If "property" is a valid "string" property understood by this DB // implementation (see Properties struct above for valid options), fills // "*value" with its current value and returns true. Otherwise, returns // false. virtual bool GetProperty(ColumnFamilyHandle* column_family, const Slice& property, std::string* value) = 0; virtual bool GetProperty(const Slice& property, std::string* value) { return GetProperty(DefaultColumnFamily(), property, value); } // Like GetProperty but for valid "map" properties. (Some properties can be // accessed as either "string" properties or "map" properties.) virtual bool GetMapProperty(ColumnFamilyHandle* column_family, const Slice& property, std::map* value) = 0; virtual bool GetMapProperty(const Slice& property, std::map* value) { return GetMapProperty(DefaultColumnFamily(), property, value); } // Similar to GetProperty(), but only works for a subset of properties whose // return value is an integer. Return the value by integer. Supported // properties: // "rocksdb.num-immutable-mem-table" // "rocksdb.mem-table-flush-pending" // "rocksdb.compaction-pending" // "rocksdb.background-errors" // "rocksdb.cur-size-active-mem-table" // "rocksdb.cur-size-all-mem-tables" // "rocksdb.size-all-mem-tables" // "rocksdb.num-entries-active-mem-table" // "rocksdb.num-entries-imm-mem-tables" // "rocksdb.num-deletes-active-mem-table" // "rocksdb.num-deletes-imm-mem-tables" // "rocksdb.estimate-num-keys" // "rocksdb.estimate-table-readers-mem" // "rocksdb.is-file-deletions-enabled" // "rocksdb.num-snapshots" // "rocksdb.oldest-snapshot-time" // "rocksdb.num-live-versions" // "rocksdb.current-super-version-number" // "rocksdb.estimate-live-data-size" // "rocksdb.min-log-number-to-keep" // "rocksdb.min-obsolete-sst-number-to-keep" // "rocksdb.total-sst-files-size" // "rocksdb.live-sst-files-size" // "rocksdb.obsolete-sst-files-size" // "rocksdb.base-level" // "rocksdb.estimate-pending-compaction-bytes" // "rocksdb.num-running-compactions" // "rocksdb.num-running-flushes" // "rocksdb.actual-delayed-write-rate" // "rocksdb.is-write-stopped" // "rocksdb.estimate-oldest-key-time" // "rocksdb.block-cache-capacity" // "rocksdb.block-cache-usage" // "rocksdb.block-cache-pinned-usage" // // Properties dedicated for BlobDB: // "rocksdb.num-blob-files" // "rocksdb.total-blob-file-size" // "rocksdb.live-blob-file-size" // "rocksdb.blob-cache-capacity" // "rocksdb.blob-cache-usage" // "rocksdb.blob-cache-pinned-usage" virtual bool GetIntProperty(ColumnFamilyHandle* column_family, const Slice& property, uint64_t* value) = 0; virtual bool GetIntProperty(const Slice& property, uint64_t* value) { return GetIntProperty(DefaultColumnFamily(), property, value); } // Reset internal stats for DB and all column families. // Note this doesn't reset options.statistics as it is not owned by // DB. virtual Status ResetStats() { return Status::NotSupported("Not implemented"); } // Same as GetIntProperty(), but this one returns the aggregated int // property from all column families. virtual bool GetAggregatedIntProperty(const Slice& property, uint64_t* value) = 0; // Flags for DB::GetSizeApproximation that specify whether memtable // stats should be included, or file stats approximation or both enum class SizeApproximationFlags : uint8_t { NONE = 0, INCLUDE_MEMTABLES = 1 << 0, INCLUDE_FILES = 1 << 1 }; // For each i in [0,n-1], store in "sizes[i]", the approximate // file system space used by keys in "[range[i].start .. range[i].limit)" // in a single column family. // // Note that the returned sizes measure file system space usage, so // if the user data compresses by a factor of ten, the returned // sizes will be one-tenth the size of the corresponding user data size. virtual Status GetApproximateSizes(const SizeApproximationOptions& options, ColumnFamilyHandle* column_family, const Range* ranges, int n, uint64_t* sizes) = 0; // Simpler versions of the GetApproximateSizes() method above. // The include_flags argument must of type DB::SizeApproximationFlags // and can not be NONE. virtual Status GetApproximateSizes(ColumnFamilyHandle* column_family, const Range* ranges, int n, uint64_t* sizes, SizeApproximationFlags include_flags = SizeApproximationFlags::INCLUDE_FILES); virtual Status GetApproximateSizes( const Range* ranges, int n, uint64_t* sizes, SizeApproximationFlags include_flags = SizeApproximationFlags::INCLUDE_FILES) { return GetApproximateSizes(DefaultColumnFamily(), ranges, n, sizes, include_flags); } // The method is similar to GetApproximateSizes, except it // returns approximate number of records in memtables. virtual void GetApproximateMemTableStats(ColumnFamilyHandle* column_family, const Range& range, uint64_t* const count, uint64_t* const size) = 0; virtual void GetApproximateMemTableStats(const Range& range, uint64_t* const count, uint64_t* const size) { GetApproximateMemTableStats(DefaultColumnFamily(), range, count, size); } // Compact the underlying storage for the key range [*begin,*end]. // The actual compaction interval might be superset of [*begin, *end]. // In particular, deleted and overwritten versions are discarded, // and the data is rearranged to reduce the cost of operations // needed to access the data. This operation should typically only // be invoked by users who understand the underlying implementation. // This call blocks until the operation completes successfully, fails, // or is aborted (Status::Incomplete). See DisableManualCompaction. // // begin==nullptr is treated as a key before all keys in the database. // end==nullptr is treated as a key after all keys in the database. // Therefore the following call will compact the entire database: // db->CompactRange(options, nullptr, nullptr); // Note that after the entire database is compacted, all data are pushed // down to the last level containing any data. If the total data size after // compaction is reduced, that level might not be appropriate for hosting all // the files. In this case, client could set options.change_level to true, to // move the files back to the minimum level capable of holding the data set // or a given level (specified by non-negative options.target_level). virtual Status CompactRange(const CompactRangeOptions& options, ColumnFamilyHandle* column_family, const Slice* begin, const Slice* end) = 0; virtual Status CompactRange(const CompactRangeOptions& options, const Slice* begin, const Slice* end) { return CompactRange(options, DefaultColumnFamily(), begin, end); } // Dynamically change column family options or table factory options in a // running DB, for the specified column family. Only options internally // marked as "mutable" can be changed. Options not listed in `opts_map` will // keep their current values. See GetColumnFamilyOptionsFromMap() in // convenience.h for the details of `opts_map`. Not supported in LITE mode. // // USABILITY NOTE: SetOptions is intended only for expert users, and does // not apply the same sanitization to options as the standard DB::Open code // path does. Use with caution. // // RELIABILITY & PERFORMANCE NOTE: SetOptions is not fully stress-tested for // reliability, and this is a slow call because a new OPTIONS file is // serialized and persisted for each call. Use only infrequently. // // EXAMPLES: // s = db->SetOptions(cfh, {{"ttl", "36000"}}); // s = db->SetOptions(cfh, {{"block_based_table_factory", // "{prepopulate_block_cache=kDisable;}"}}); virtual Status SetOptions( ColumnFamilyHandle* /*column_family*/, const std::unordered_map& /*opts_map*/) { return Status::NotSupported("Not implemented"); } // Shortcut for SetOptions on the default column family handle. virtual Status SetOptions( const std::unordered_map& new_options) { return SetOptions(DefaultColumnFamily(), new_options); } // Like SetOptions but for DBOptions, including the same caveats for // usability, reliability, and performance. See GetDBOptionsFromMap() (and // GetColumnFamilyOptionsFromMap()) in convenience.h for details on // `opts_map`. Note supported in LITE mode. // // EXAMPLES: // s = db->SetDBOptions({{"max_subcompactions", "2"}}); // s = db->SetDBOptions({{"stats_dump_period_sec", "0"}, // {"stats_persist_period_sec", "0"}}); virtual Status SetDBOptions( const std::unordered_map& new_options) = 0; // CompactFiles() inputs a list of files specified by file numbers and // compacts them to the specified level. A small difference compared to // CompactRange() is that CompactFiles() performs the compaction job // using the CURRENT thread, so is not considered a "background" job. // // @see GetDataBaseMetaData // @see GetColumnFamilyMetaData virtual Status CompactFiles( const CompactionOptions& compact_options, ColumnFamilyHandle* column_family, const std::vector& input_file_names, const int output_level, const int output_path_id = -1, std::vector* const output_file_names = nullptr, CompactionJobInfo* compaction_job_info = nullptr) = 0; virtual Status CompactFiles( const CompactionOptions& compact_options, const std::vector& input_file_names, const int output_level, const int output_path_id = -1, std::vector* const output_file_names = nullptr, CompactionJobInfo* compaction_job_info = nullptr) { return CompactFiles(compact_options, DefaultColumnFamily(), input_file_names, output_level, output_path_id, output_file_names, compaction_job_info); } // This function will wait until all currently running background processes // finish. After it returns, no background process will be run until // ContinueBackgroundWork is called, once for each preceding OK-returning // call to PauseBackgroundWork. virtual Status PauseBackgroundWork() = 0; virtual Status ContinueBackgroundWork() = 0; // This function will enable automatic compactions for the given column // families if they were previously disabled. The function will first set the // disable_auto_compactions option for each column family to 'false', after // which it will schedule a flush/compaction. // // NOTE: Setting disable_auto_compactions to 'false' through SetOptions() API // does NOT schedule a flush/compaction afterwards, and only changes the // parameter itself within the column family option. // virtual Status EnableAutoCompaction( const std::vector& column_family_handles) = 0; // After this function call, CompactRange() or CompactFiles() will not // run compactions and fail. Calling this function will tell outstanding // manual compactions to abort and will wait for them to finish or abort // before returning. virtual void DisableManualCompaction() = 0; // Re-enable CompactRange() and ComapctFiles() that are disabled by // DisableManualCompaction(). This function must be called as many times // as DisableManualCompaction() has been called in order to re-enable // manual compactions, and must not be called more times than // DisableManualCompaction() has been called. virtual void EnableManualCompaction() = 0; // Wait for all flush and compactions jobs to finish. Jobs to wait include the // unscheduled (queued, but not scheduled yet). If the db is shutting down, // Status::ShutdownInProgress will be returned. // // NOTE: This may also never return if there's sufficient ongoing writes that // keeps flush and compaction going without stopping. The user would have to // cease all the writes to DB to make this eventually return in a stable // state. virtual Status WaitForCompact( const WaitForCompactOptions& /* wait_for_compact_options */) = 0; // Number of levels used for this DB. virtual int NumberLevels(ColumnFamilyHandle* column_family) = 0; virtual int NumberLevels() { return NumberLevels(DefaultColumnFamily()); } // Maximum level to which a new compacted memtable is pushed if it // does not create overlap. virtual int MaxMemCompactionLevel(ColumnFamilyHandle* column_family) = 0; virtual int MaxMemCompactionLevel() { return MaxMemCompactionLevel(DefaultColumnFamily()); } // Number of files in level-0 that would stop writes. virtual int Level0StopWriteTrigger(ColumnFamilyHandle* column_family) = 0; virtual int Level0StopWriteTrigger() { return Level0StopWriteTrigger(DefaultColumnFamily()); } // Get DB name -- the exact same name that was provided as an argument to // DB::Open() virtual const std::string& GetName() const = 0; // Get Env object from the DB virtual Env* GetEnv() const = 0; // A shortcut for GetEnv()->->GetFileSystem().get(), possibly cached for // efficiency. virtual FileSystem* GetFileSystem() const; // Get DB Options that we use. During the process of opening the // column family, the options provided when calling DB::Open() or // DB::CreateColumnFamily() will have been "sanitized" and transformed // in an implementation-defined manner. virtual Options GetOptions(ColumnFamilyHandle* column_family) const = 0; virtual Options GetOptions() const { return GetOptions(DefaultColumnFamily()); } virtual DBOptions GetDBOptions() const = 0; // Flush all memtable data. // Flush a single column family, even when atomic flush is enabled. To flush // multiple column families, use Flush(options, column_families). virtual Status Flush(const FlushOptions& options, ColumnFamilyHandle* column_family) = 0; virtual Status Flush(const FlushOptions& options) { return Flush(options, DefaultColumnFamily()); } // Flushes memtables of multiple column families. // If atomic flush is not enabled, Flush(options, column_families) is // equivalent to calling Flush(options, column_family) multiple times. // If atomic flush is enabled, Flush(options, column_families) will flush all // column families specified in 'column_families' up to the latest sequence // number at the time when flush is requested. // Note that RocksDB 5.15 and earlier may not be able to open later versions // with atomic flush enabled. virtual Status Flush( const FlushOptions& options, const std::vector& column_families) = 0; // When using the manual_wal_flush option, flushes RocksDB internal buffers // of WAL data to the file, so that the data can survive process crash or be // included in a Checkpoint or Backup. Without manual_wal_flush, there is no // such internal buffer. If sync is true, it calls SyncWAL() afterwards. virtual Status FlushWAL(bool /*sync*/) { return Status::NotSupported("FlushWAL not implemented"); } // Ensure all WAL writes have been synced to storage, so that (assuming OS // and hardware support) data will survive power loss. This function does // not imply FlushWAL, so `FlushWAL(true)` is recommended if using // manual_wal_flush=true. Currently only works if allow_mmap_writes = false // in Options. // // Note that Write() followed by SyncWAL() is not exactly the same as Write() // with sync=true: in the latter case the changes won't be visible until the // sync is done. virtual Status SyncWAL() = 0; // Freezes the logical state of the DB (by stopping writes), and if WAL is // enabled, ensures that state has been flushed to DB files (as in // FlushWAL()). This can be used for taking a Checkpoint at a known DB // state, though the user must use options to insure no DB flush is invoked // in this frozen state. Other operations allowed on a "read only" DB should // work while frozen. Each LockWAL() call that returns OK must eventually be // followed by a corresponding call to UnlockWAL(). Where supported, non-OK // status is generally only possible with some kind of corruption or I/O // error. virtual Status LockWAL() { return Status::NotSupported("LockWAL not implemented"); } // Unfreeze the DB state from a successful LockWAL(). // The write stop on the database will be cleared when UnlockWAL() have been // called for each successful LockWAL(). virtual Status UnlockWAL() { return Status::NotSupported("UnlockWAL not implemented"); } // The sequence number of the most recent transaction. virtual SequenceNumber GetLatestSequenceNumber() const = 0; // Prevent file deletions. Compactions will continue to occur, // but no obsolete files will be deleted. Calling this multiple // times have the same effect as calling it once. virtual Status DisableFileDeletions() = 0; // Increase the full_history_ts of column family. The new ts_low value should // be newer than current full_history_ts value. // If another thread updates full_history_ts_low concurrently to a higher // timestamp than the requested ts_low, a try again error will be returned. virtual Status IncreaseFullHistoryTsLow(ColumnFamilyHandle* column_family, std::string ts_low) = 0; // Get current full_history_ts value. virtual Status GetFullHistoryTsLow(ColumnFamilyHandle* column_family, std::string* ts_low) = 0; // Allow compactions to delete obsolete files. // If force == true, the call to EnableFileDeletions() will guarantee that // file deletions are enabled after the call, even if DisableFileDeletions() // was called multiple times before. // If force == false, EnableFileDeletions will only enable file deletion // after it's been called at least as many times as DisableFileDeletions(), // enabling the two methods to be called by two threads concurrently without // synchronization -- i.e., file deletions will be enabled only after both // threads call EnableFileDeletions() virtual Status EnableFileDeletions(bool force = true) = 0; // Retrieves the creation time of the oldest file in the DB. // This API only works if max_open_files = -1, if it is not then // Status returned is Status::NotSupported() // The file creation time is set using the env provided to the DB. // If the DB was created from a very old release then its possible that // the SST files might not have file_creation_time property and even after // moving to a newer release its possible that some files never got compacted // and may not have file_creation_time property. In both the cases // file_creation_time is considered 0 which means this API will return // creation_time = 0 as there wouldn't be a timestamp lower than 0. virtual Status GetCreationTimeOfOldestFile(uint64_t* creation_time) = 0; // Note: this API is not yet consistent with WritePrepared transactions. // // Sets iter to an iterator that is positioned at a write-batch whose // sequence number range [start_seq, end_seq] covers seq_number. If no such // write-batch exists, then iter is positioned at the next write-batch whose // start_seq > seq_number. // // Returns Status::OK if iterator is valid // Must set WAL_ttl_seconds or WAL_size_limit_MB to large values to // use this api, else the WAL files will get // cleared aggressively and the iterator might keep getting invalid before // an update is read. virtual Status GetUpdatesSince( SequenceNumber seq_number, std::unique_ptr* iter, const TransactionLogIterator::ReadOptions& read_options = TransactionLogIterator::ReadOptions()) = 0; // Windows API macro interference #undef DeleteFile // WARNING: This API is planned for removal in RocksDB 7.0 since it does not // operate at the proper level of abstraction for a key-value store, and its // contract/restrictions are poorly documented. For example, it returns non-OK // `Status` for non-bottommost files and files undergoing compaction. Since we // do not plan to maintain it, the contract will likely remain underspecified // until its removal. Any user is encouraged to read the implementation // carefully and migrate away from it when possible. // // Delete the file name from the db directory and update the internal state to // reflect that. Supports deletion of sst and log files only. 'name' must be // path relative to the db directory. eg. 000001.sst, /archive/000003.log virtual Status DeleteFile(std::string name) = 0; // Obtains a list of all live table (SST) files and how they fit into the // LSM-trees, such as column family, level, key range, etc. // This builds a de-normalized form of GetAllColumnFamilyMetaData(). // For information about all files in a DB, use GetLiveFilesStorageInfo(). virtual void GetLiveFilesMetaData( std::vector* /*metadata*/) {} // Return a list of all table (SST) and blob files checksum info. // Note: This function might be of limited use because it cannot be // synchronized with other "live files" APIs. GetLiveFilesStorageInfo() // is recommended instead. virtual Status GetLiveFilesChecksumInfo(FileChecksumList* checksum_list) = 0; // Get information about all live files that make up a DB, for making // live copies (Checkpoint, backups, etc.) or other storage-related purposes. // If creating a live copy, use DisableFileDeletions() before and // EnableFileDeletions() after to prevent deletions. // For LSM-tree metadata, use Get*MetaData() functions instead. virtual Status GetLiveFilesStorageInfo( const LiveFilesStorageInfoOptions& opts, std::vector* files) = 0; // Obtains the LSM-tree meta data of the specified column family of the DB, // including metadata for each live table (SST) file in that column family. virtual void GetColumnFamilyMetaData(ColumnFamilyHandle* /*column_family*/, ColumnFamilyMetaData* /*metadata*/) {} // Get the metadata of the default column family. void GetColumnFamilyMetaData(ColumnFamilyMetaData* metadata) { GetColumnFamilyMetaData(DefaultColumnFamily(), metadata); } // Obtains the LSM-tree meta data of all column families of the DB, including // metadata for each live table (SST) file and each blob file in the DB. virtual void GetAllColumnFamilyMetaData( std::vector* /*metadata*/) {} // Retrieve the list of all files in the database except WAL files. The files // are relative to the dbname (or db_paths/cf_paths), not absolute paths. // (Not recommended with db_paths/cf_paths because that information is not // returned.) Despite being relative paths, the file names begin with "/". // The valid size of the manifest file is returned in manifest_file_size. // The manifest file is an ever growing file, but only the portion specified // by manifest_file_size is valid for this snapshot. Setting flush_memtable // to true does Flush before recording the live files (unless DB is // read-only). Setting flush_memtable to false is useful when we don't want // to wait for flush which may have to wait for compaction to complete // taking an indeterminate time. // // NOTE: Although GetLiveFiles() followed by GetSortedWalFiles() can generate // a lossless backup, GetLiveFilesStorageInfo() is strongly recommended // instead, because it ensures a single consistent view of all files is // captured in one call. virtual Status GetLiveFiles(std::vector&, uint64_t* manifest_file_size, bool flush_memtable = true) = 0; // Retrieve the sorted list of all wal files with earliest file first virtual Status GetSortedWalFiles(VectorLogPtr& files) = 0; // Retrieve information about the current wal file // // Note that the log might have rolled after this call in which case // the current_log_file would not point to the current log file. // // Additionally, for the sake of optimization current_log_file->StartSequence // would always be set to 0 virtual Status GetCurrentWalFile( std::unique_ptr* current_log_file) = 0; // IngestExternalFile() will load a list of external SST files (1) into the DB // Two primary modes are supported: // - Duplicate keys in the new files will overwrite exiting keys (default) // - Duplicate keys will be skipped (set ingest_behind=true) // In the first mode we will try to find the lowest possible level that // the file can fit in, and ingest the file into this level (2). A file that // have a key range that overlap with the memtable key range will require us // to Flush the memtable first before ingesting the file. // In the second mode we will always ingest in the bottom most level (see // docs to IngestExternalFileOptions::ingest_behind). // // (1) External SST files can be created using SstFileWriter // (2) We will try to ingest the files to the lowest possible level // even if the file compression doesn't match the level compression // (3) If IngestExternalFileOptions->ingest_behind is set to true, // we always ingest at the bottommost level, which should be reserved // for this purpose (see DBOPtions::allow_ingest_behind flag). // (4) If IngestExternalFileOptions->fail_if_not_bottommost_level is set to // true, then this method can return Status:TryAgain() indicating that // the files cannot be ingested to the bottommost level, and it is the // user's responsibility to clear the bottommost level in the overlapping // range before re-attempting the ingestion. virtual Status IngestExternalFile( ColumnFamilyHandle* column_family, const std::vector& external_files, const IngestExternalFileOptions& options) = 0; virtual Status IngestExternalFile( const std::vector& external_files, const IngestExternalFileOptions& options) { return IngestExternalFile(DefaultColumnFamily(), external_files, options); } // IngestExternalFiles() will ingest files for multiple column families, and // record the result atomically to the MANIFEST. // If this function returns OK, all column families' ingestion must succeed. // If this function returns NOK, or the process crashes, then non-of the // files will be ingested into the database after recovery. // Note that it is possible for application to observe a mixed state during // the execution of this function. If the user performs range scan over the // column families with iterators, iterator on one column family may return // ingested data, while iterator on other column family returns old data. // Users can use snapshot for a consistent view of data. // If your db ingests multiple SST files using this API, i.e. args.size() // > 1, then RocksDB 5.15 and earlier will not be able to open it. // // REQUIRES: each arg corresponds to a different column family: namely, for // 0 <= i < j < len(args), args[i].column_family != args[j].column_family. virtual Status IngestExternalFiles( const std::vector& args) = 0; // CreateColumnFamilyWithImport() will create a new column family with // column_family_name and import external SST files specified in `metadata` // into this column family. // (1) External SST files can be created using SstFileWriter. // (2) External SST files can be exported from a particular column family in // an existing DB using Checkpoint::ExportColumnFamily. `metadata` should // be the output from Checkpoint::ExportColumnFamily. // Option in import_options specifies whether the external files are copied or // moved (default is copy). When option specifies copy, managing files at // external_file_path is caller's responsibility. When option specifies a // move, the call makes a best effort to delete the specified files at // external_file_path on successful return, logging any failure to delete // rather than returning in Status. Files are not modified on any error // return, and a best effort is made to remove any newly-created files. // On error return, column family handle returned will be nullptr. // ColumnFamily will be present on successful return and will not be present // on error return. ColumnFamily may be present on any crash during this call. virtual Status CreateColumnFamilyWithImport( const ColumnFamilyOptions& options, const std::string& column_family_name, const ImportColumnFamilyOptions& import_options, const ExportImportFilesMetaData& metadata, ColumnFamilyHandle** handle) { const std::vector& metadatas{&metadata}; return CreateColumnFamilyWithImport(options, column_family_name, import_options, metadatas, handle); } // EXPERIMENTAL // Overload of the CreateColumnFamilyWithImport() that allows the caller to // pass a list of ExportImportFilesMetaData pointers to support creating // ColumnFamily by importing multiple ColumnFamilies. // It should be noticed that if the user keys of the imported column families // overlap with each other, an error will be returned. virtual Status CreateColumnFamilyWithImport( const ColumnFamilyOptions& options, const std::string& column_family_name, const ImportColumnFamilyOptions& import_options, const std::vector& metadatas, ColumnFamilyHandle** handle) = 0; // EXPERIMENTAL // ClipColumnFamily() will clip the entries in the CF according to the range // [begin_key, end_key). Returns OK on success, and a non-OK status on error. // Any entries outside this range will be completely deleted (including // tombstones). // The main difference between ClipColumnFamily(begin, end) and // DeleteRange(begin, end) // is that the former physically deletes all keys outside the range, but is // more heavyweight than the latter. // This feature is mainly used to ensure that there is no overlapping Key when // calling CreateColumnFamilyWithImport() to import multiple CFs. // Note that: concurrent updates cannot be performed during Clip. virtual Status ClipColumnFamily(ColumnFamilyHandle* column_family, const Slice& begin_key, const Slice& end_key) = 0; // Verify the checksums of files in db. Currently the whole-file checksum of // table files are checked. virtual Status VerifyFileChecksums(const ReadOptions& /*read_options*/) { return Status::NotSupported("File verification not supported"); } // Verify the block checksums of files in db. The block checksums of table // files are checked. virtual Status VerifyChecksum(const ReadOptions& read_options) = 0; virtual Status VerifyChecksum() { return VerifyChecksum(ReadOptions()); } // Returns the unique ID which is read from IDENTITY file during the opening // of database by setting in the identity variable // Returns Status::OK if identity could be set properly virtual Status GetDbIdentity(std::string& identity) const = 0; // Return a unique identifier for each DB object that is opened // This DB session ID should be unique among all open DB instances on all // hosts, and should be unique among re-openings of the same or other DBs. // (Two open DBs have the same identity from other function GetDbIdentity when // one is physically copied from the other.) virtual Status GetDbSessionId(std::string& session_id) const = 0; // Returns default column family handle virtual ColumnFamilyHandle* DefaultColumnFamily() const = 0; virtual Status GetPropertiesOfAllTables(ColumnFamilyHandle* column_family, TablePropertiesCollection* props) = 0; virtual Status GetPropertiesOfAllTables(TablePropertiesCollection* props) { return GetPropertiesOfAllTables(DefaultColumnFamily(), props); } virtual Status GetPropertiesOfTablesInRange( ColumnFamilyHandle* column_family, const Range* range, std::size_t n, TablePropertiesCollection* props) = 0; virtual Status SuggestCompactRange(ColumnFamilyHandle* /*column_family*/, const Slice* /*begin*/, const Slice* /*end*/) { return Status::NotSupported("SuggestCompactRange() is not implemented."); } virtual Status PromoteL0(ColumnFamilyHandle* /*column_family*/, int /*target_level*/) { return Status::NotSupported("PromoteL0() is not implemented."); } // Trace DB operations. Use EndTrace() to stop tracing. virtual Status StartTrace(const TraceOptions& /*options*/, std::unique_ptr&& /*trace_writer*/) { return Status::NotSupported("StartTrace() is not implemented."); } virtual Status EndTrace() { return Status::NotSupported("EndTrace() is not implemented."); } // IO Tracing operations. Use EndIOTrace() to stop tracing. virtual Status StartIOTrace(const TraceOptions& /*options*/, std::unique_ptr&& /*trace_writer*/) { return Status::NotSupported("StartIOTrace() is not implemented."); } virtual Status EndIOTrace() { return Status::NotSupported("EndIOTrace() is not implemented."); } // Trace block cache accesses. Use EndBlockCacheTrace() to stop tracing. virtual Status StartBlockCacheTrace( const TraceOptions& /*trace_options*/, std::unique_ptr&& /*trace_writer*/) { return Status::NotSupported("StartBlockCacheTrace() is not implemented."); } virtual Status StartBlockCacheTrace( const BlockCacheTraceOptions& /*options*/, std::unique_ptr&& /*trace_writer*/) { return Status::NotSupported("StartBlockCacheTrace() is not implemented."); } virtual Status EndBlockCacheTrace() { return Status::NotSupported("EndBlockCacheTrace() is not implemented."); } // Create a default trace replayer. virtual Status NewDefaultReplayer( const std::vector& /*handles*/, std::unique_ptr&& /*reader*/, std::unique_ptr* /*replayer*/) { return Status::NotSupported("NewDefaultReplayer() is not implemented."); } // Needed for StackableDB virtual DB* GetRootDB() { return this; } // Given a window [start_time, end_time), setup a StatsHistoryIterator // to access stats history. Note the start_time and end_time are epoch // time measured in seconds, and end_time is an exclusive bound. virtual Status GetStatsHistory( uint64_t /*start_time*/, uint64_t /*end_time*/, std::unique_ptr* /*stats_iterator*/) { return Status::NotSupported("GetStatsHistory() is not implemented."); } // Make the secondary instance catch up with the primary by tailing and // replaying the MANIFEST and WAL of the primary. // Column families created by the primary after the secondary instance starts // will be ignored unless the secondary instance closes and restarts with the // newly created column families. // Column families that exist before secondary instance starts and dropped by // the primary afterwards will be marked as dropped. However, as long as the // secondary instance does not delete the corresponding column family // handles, the data of the column family is still accessible to the // secondary. virtual Status TryCatchUpWithPrimary() { return Status::NotSupported("Supported only by secondary instance"); } }; struct WriteStallStatsMapKeys { static const std::string& TotalStops(); static const std::string& TotalDelays(); static const std::string& CFL0FileCountLimitDelaysWithOngoingCompaction(); static const std::string& CFL0FileCountLimitStopsWithOngoingCompaction(); // REQUIRES: // `cause` isn't any of these: `WriteStallCause::kNone`, // `WriteStallCause::kCFScopeWriteStallCauseEnumMax`, // `WriteStallCause::kDBScopeWriteStallCauseEnumMax` // // REQUIRES: // `condition` isn't any of these: `WriteStallCondition::kNormal` static std::string CauseConditionCount(WriteStallCause cause, WriteStallCondition condition); }; // Overloaded operators for enum class SizeApproximationFlags. inline DB::SizeApproximationFlags operator&(DB::SizeApproximationFlags lhs, DB::SizeApproximationFlags rhs) { return static_cast(static_cast(lhs) & static_cast(rhs)); } inline DB::SizeApproximationFlags operator|(DB::SizeApproximationFlags lhs, DB::SizeApproximationFlags rhs) { return static_cast(static_cast(lhs) | static_cast(rhs)); } inline Status DB::GetApproximateSizes(ColumnFamilyHandle* column_family, const Range* ranges, int n, uint64_t* sizes, SizeApproximationFlags include_flags) { SizeApproximationOptions options; options.include_memtables = ((include_flags & SizeApproximationFlags::INCLUDE_MEMTABLES) != SizeApproximationFlags::NONE); options.include_files = ((include_flags & SizeApproximationFlags::INCLUDE_FILES) != SizeApproximationFlags::NONE); return GetApproximateSizes(options, column_family, ranges, n, sizes); } // Destroy the contents of the specified database. // Be very careful using this method. Status DestroyDB(const std::string& name, const Options& options, const std::vector& column_families = std::vector()); // If a DB cannot be opened, you may attempt to call this method to // resurrect as much of the contents of the database as possible. // Some data may be lost, so be careful when calling this function // on a database that contains important information. // // With this API, we will warn and skip data associated with column families not // specified in column_families. // // @param column_families Descriptors for known column families Status RepairDB(const std::string& dbname, const DBOptions& db_options, const std::vector& column_families); // @param unknown_cf_opts Options for column families encountered during the // repair that were not specified in column_families. Status RepairDB(const std::string& dbname, const DBOptions& db_options, const std::vector& column_families, const ColumnFamilyOptions& unknown_cf_opts); // @param options These options will be used for the database and for ALL column // families encountered during the repair Status RepairDB(const std::string& dbname, const Options& options); } // namespace ROCKSDB_NAMESPACE