// Copyright (c) 2015-2021 The Bitcoin Core developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #ifndef BITCOIN_TEST_UTIL_SETUP_COMMON_H #define BITCOIN_TEST_UTIL_SETUP_COMMON_H #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /** This is connected to the logger. Can be used to redirect logs to any other log */ extern const std::function G_TEST_LOG_FUN; /** Retrieve the command line arguments. */ extern const std::function()> G_TEST_COMMAND_LINE_ARGUMENTS; // Enable BOOST_CHECK_EQUAL for enum class types namespace std { template std::ostream& operator<<(typename std::enable_if::value, std::ostream>::type& stream, const T& e) { return stream << static_cast::type>(e); } } // namespace std /** * This global and the helpers that use it are not thread-safe. * * If thread-safety is needed, the global could be made thread_local (given * that thread_local is supported on all architectures we support) or a * per-thread instance could be used in the multi-threaded test. */ extern FastRandomContext g_insecure_rand_ctx; /** * Flag to make GetRand in random.h return the same number */ extern bool g_mock_deterministic_tests; enum class SeedRand { ZEROS, //!< Seed with a compile time constant of zeros SEED, //!< Call the Seed() helper }; /** Seed the given random ctx or use the seed passed in via an environment var */ void Seed(FastRandomContext& ctx); static inline void SeedInsecureRand(SeedRand seed = SeedRand::SEED) { if (seed == SeedRand::ZEROS) { g_insecure_rand_ctx = FastRandomContext(/*fDeterministic=*/true); } else { Seed(g_insecure_rand_ctx); } } static inline uint32_t InsecureRand32() { return g_insecure_rand_ctx.rand32(); } static inline uint256 InsecureRand256() { return g_insecure_rand_ctx.rand256(); } static inline uint64_t InsecureRandBits(int bits) { return g_insecure_rand_ctx.randbits(bits); } static inline uint64_t InsecureRandRange(uint64_t range) { return g_insecure_rand_ctx.randrange(range); } static inline bool InsecureRandBool() { return g_insecure_rand_ctx.randbool(); } static constexpr CAmount CENT{1000000}; /** Basic testing setup. * This just configures logging, data dir and chain parameters. */ struct BasicTestingSetup { node::NodeContext m_node; // keep as first member to be destructed last explicit BasicTestingSetup(const std::string& chainName = CBaseChainParams::MAIN, const std::vector& extra_args = {}); ~BasicTestingSetup(); const fs::path m_path_root; ArgsManager m_args; }; /** Testing setup that performs all steps up until right before * ChainstateManager gets initialized. Meant for testing ChainstateManager * initialization behaviour. */ struct ChainTestingSetup : public BasicTestingSetup { node::CacheSizes m_cache_sizes{}; explicit ChainTestingSetup(const std::string& chainName = CBaseChainParams::MAIN, const std::vector& extra_args = {}); ~ChainTestingSetup(); }; /** Testing setup that configures a complete environment. */ struct TestingSetup : public ChainTestingSetup { explicit TestingSetup(const std::string& chainName = CBaseChainParams::MAIN, const std::vector& extra_args = {}); }; /** Identical to TestingSetup, but chain set to regtest */ struct RegTestingSetup : public TestingSetup { RegTestingSetup() : TestingSetup{CBaseChainParams::REGTEST} {} }; class CBlock; struct CMutableTransaction; class CScript; /** * Testing fixture that pre-creates a 100-block REGTEST-mode block chain */ struct TestChain100Setup : public TestingSetup { TestChain100Setup(const std::string& chain_name = CBaseChainParams::REGTEST, const std::vector& extra_args = {}); /** * Create a new block with just given transactions, coinbase paying to * scriptPubKey, and try to add it to the current chain. * If no chainstate is specified, default to the active. */ CBlock CreateAndProcessBlock(const std::vector& txns, const CScript& scriptPubKey, CChainState* chainstate = nullptr); /** * Create a new block with just given transactions, coinbase paying to * scriptPubKey. */ CBlock CreateBlock( const std::vector& txns, const CScript& scriptPubKey, CChainState& chainstate); //! Mine a series of new blocks on the active chain. void mineBlocks(int num_blocks); /** * Create a transaction and submit to the mempool. * * @param input_transaction The transaction to spend * @param input_vout The vout to spend from the input_transaction * @param input_height The height of the block that included the input_transaction * @param input_signing_key The key to spend the input_transaction * @param output_destination Where to send the output * @param output_amount How much to send * @param submit Whether or not to submit to mempool */ CMutableTransaction CreateValidMempoolTransaction(CTransactionRef input_transaction, int input_vout, int input_height, CKey input_signing_key, CScript output_destination, CAmount output_amount = CAmount(1 * COIN), bool submit = true); /** Create transactions spending from m_coinbase_txns. These transactions will only spend coins * that exist in the current chain, but may be premature coinbase spends, have missing * signatures, or violate some other consensus rules. They should only be used for testing * mempool consistency. All transactions will have some random number of inputs and outputs * (between 1 and 24). Transactions may or may not be dependent upon each other; if dependencies * exit, every parent will always be somewhere in the list before the child so each transaction * can be submitted in the same order they appear in the list. * @param[in] submit When true, submit transactions to the mempool. * When false, return them but don't submit them. * @returns A vector of transactions that can be submitted to the mempool. */ std::vector PopulateMempool(FastRandomContext& det_rand, size_t num_transactions, bool submit); std::vector m_coinbase_txns; // For convenience, coinbase transactions CKey coinbaseKey; // private/public key needed to spend coinbase transactions }; /** * Make a test setup that has disk access to the debug.log file disabled. Can * be used in "hot loops", for example fuzzing or benchmarking. */ template std::unique_ptr MakeNoLogFileContext(const std::string& chain_name = CBaseChainParams::REGTEST, const std::vector& extra_args = {}) { const std::vector arguments = Cat( { "-nodebuglogfile", "-nodebug", }, extra_args); return std::make_unique(chain_name, arguments); } class CTxMemPoolEntry; struct TestMemPoolEntryHelper { // Default values CAmount nFee; int64_t nTime; unsigned int nHeight; bool spendsCoinbase; unsigned int sigOpCost; LockPoints lp; TestMemPoolEntryHelper() : nFee(0), nTime(0), nHeight(1), spendsCoinbase(false), sigOpCost(4) { } CTxMemPoolEntry FromTx(const CMutableTransaction& tx) const; CTxMemPoolEntry FromTx(const CTransactionRef& tx) const; // Change the default value TestMemPoolEntryHelper &Fee(CAmount _fee) { nFee = _fee; return *this; } TestMemPoolEntryHelper &Time(int64_t _time) { nTime = _time; return *this; } TestMemPoolEntryHelper &Height(unsigned int _height) { nHeight = _height; return *this; } TestMemPoolEntryHelper &SpendsCoinbase(bool _flag) { spendsCoinbase = _flag; return *this; } TestMemPoolEntryHelper &SigOpsCost(unsigned int _sigopsCost) { sigOpCost = _sigopsCost; return *this; } }; CBlock getBlock13b8a(); // define an implicit conversion here so that uint256 may be used directly in BOOST_CHECK_* std::ostream& operator<<(std::ostream& os, const uint256& num); /** * BOOST_CHECK_EXCEPTION predicates to check the specific validation error. * Use as * BOOST_CHECK_EXCEPTION(code that throws, exception type, HasReason("foo")); */ class HasReason { public: explicit HasReason(const std::string& reason) : m_reason(reason) {} bool operator()(const std::exception& e) const { return std::string(e.what()).find(m_reason) != std::string::npos; }; private: const std::string m_reason; }; #endif // BITCOIN_TEST_UTIL_SETUP_COMMON_H