// 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). #pragma once #ifndef ROCKSDB_LITE #include "rocksdb/options.h" #include "port/port.h" #include "rocksdb/utilities/optimistic_transaction_db.h" #include "rocksdb/utilities/transaction_db.h" namespace rocksdb { class DB; class Random64; // Utility class for stress testing transactions. Can be used to write many // transactions in parallel and then validate that the data written is logically // consistent. This class assumes the input DB is initially empty. // // Each call to TransactionDBInsert()/OptimisticTransactionDBInsert() will // increment the value of a key in #num_sets sets of keys. Regardless of // whether the transaction succeeds, the total sum of values of keys in each // set is an invariant that should remain equal. // // After calling TransactionDBInsert()/OptimisticTransactionDBInsert() many // times, Verify() can be called to validate that the invariant holds. // // To test writing Transaction in parallel, multiple threads can create a // RandomTransactionInserter with similar arguments using the same DB. class RandomTransactionInserter { public: // num_keys is the number of keys in each set. // num_sets is the number of sets of keys. explicit RandomTransactionInserter( Random64* rand, const WriteOptions& write_options = WriteOptions(), const ReadOptions& read_options = ReadOptions(), uint64_t num_keys = 1000, uint16_t num_sets = 3); ~RandomTransactionInserter(); // Increment a key in each set using a Transaction on a TransactionDB. // // Returns true if the transaction succeeded OR if any error encountered was // expected (eg a write-conflict). Error status may be obtained by calling // GetLastStatus(); bool TransactionDBInsert( TransactionDB* db, const TransactionOptions& txn_options = TransactionOptions()); // Increment a key in each set using a Transaction on an // OptimisticTransactionDB // // Returns true if the transaction succeeded OR if any error encountered was // expected (eg a write-conflict). Error status may be obtained by calling // GetLastStatus(); bool OptimisticTransactionDBInsert( OptimisticTransactionDB* db, const OptimisticTransactionOptions& txn_options = OptimisticTransactionOptions()); // Increment a key in each set without using a transaction. If this function // is called in parallel, then Verify() may fail. // // Returns true if the write succeeds. // Error status may be obtained by calling GetLastStatus(). bool DBInsert(DB* db); // Returns OK if Invariant is true. static Status Verify(DB* db, uint16_t num_sets); // Returns the status of the previous Insert operation Status GetLastStatus() { return last_status_; } // Returns the number of successfully written calls to // TransactionDBInsert/OptimisticTransactionDBInsert/DBInsert uint64_t GetSuccessCount() { return success_count_; } // Returns the number of calls to // TransactionDBInsert/OptimisticTransactionDBInsert/DBInsert that did not // write any data. uint64_t GetFailureCount() { return failure_count_; } private: // Input options Random64* rand_; const WriteOptions write_options_; const ReadOptions read_options_; const uint64_t num_keys_; const uint16_t num_sets_; // Number of successful insert batches performed uint64_t success_count_ = 0; // Number of failed insert batches attempted uint64_t failure_count_ = 0; // Status returned by most recent insert operation Status last_status_; // optimization: re-use allocated transaction objects. Transaction* txn_ = nullptr; Transaction* optimistic_txn_ = nullptr; std::atomic txn_id_; bool DoInsert(DB* db, Transaction* txn, bool is_optimistic); }; } // namespace rocksdb #endif // ROCKSDB_LITE