// Copyright (c) 2014-2022, The Monero Project // // All rights reserved. // // Redistribution and use in source and binary forms, with or without modification, are // permitted provided that the following conditions are met: // // 1. Redistributions of source code must retain the above copyright notice, this list of // conditions and the following disclaimer. // // 2. Redistributions in binary form must reproduce the above copyright notice, this list // of conditions and the following disclaimer in the documentation and/or other // materials provided with the distribution. // // 3. Neither the name of the copyright holder nor the names of its contributors may be // used to endorse or promote products derived from this software without specific // prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY // EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL // THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, // PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, // STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF // THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // // Parts of this file are originally copyright (c) 2012-2013 The Cryptonote developers #pragma once #include #include #include #include #include #include #include #include #include #include #include #include "include_base_utils.h" #include "common/boost_serialization_helper.h" #include "common/command_line.h" #include "common/threadpool.h" #include "cryptonote_basic/account_boost_serialization.h" #include "cryptonote_basic/cryptonote_basic.h" #include "cryptonote_basic/cryptonote_basic_impl.h" #include "cryptonote_basic/cryptonote_format_utils.h" #include "cryptonote_core/cryptonote_core.h" #include "cryptonote_protocol/enums.h" #include "cryptonote_basic/cryptonote_boost_serialization.h" #include "misc_language.h" #undef MONERO_DEFAULT_LOG_CATEGORY #define MONERO_DEFAULT_LOG_CATEGORY "tests.core" struct callback_entry { std::string callback_name; BEGIN_SERIALIZE_OBJECT() FIELD(callback_name) END_SERIALIZE() private: friend class boost::serialization::access; template void serialize(Archive & ar, const unsigned int /*version*/) { ar & callback_name; } }; template struct serialized_object { serialized_object() { } serialized_object(const cryptonote::blobdata& a_data) : data(a_data) { } cryptonote::blobdata data; BEGIN_SERIALIZE_OBJECT() FIELD(data) END_SERIALIZE() private: friend class boost::serialization::access; template void serialize(Archive & ar, const unsigned int /*version*/) { ar & data; } }; typedef serialized_object serialized_block; typedef serialized_object serialized_transaction; struct event_visitor_settings { int mask; enum settings { set_txs_keeped_by_block = 1 << 0, set_txs_do_not_relay = 1 << 1, set_local_relay = 1 << 2, set_txs_stem = 1 << 3 }; event_visitor_settings(int a_mask = 0) : mask(a_mask) { } private: friend class boost::serialization::access; template void serialize(Archive & ar, const unsigned int /*version*/) { ar & mask; } }; typedef std::vector> v_hardforks_t; struct event_replay_settings { boost::optional hard_forks; event_replay_settings() = default; private: friend class boost::serialization::access; template void serialize(Archive & ar, const unsigned int /*version*/) { ar & hard_forks; } }; VARIANT_TAG(binary_archive, callback_entry, 0xcb); VARIANT_TAG(binary_archive, cryptonote::account_base, 0xcc); VARIANT_TAG(binary_archive, serialized_block, 0xcd); VARIANT_TAG(binary_archive, serialized_transaction, 0xce); VARIANT_TAG(binary_archive, event_visitor_settings, 0xcf); VARIANT_TAG(binary_archive, event_replay_settings, 0xda); typedef boost::variant, cryptonote::account_base, callback_entry, serialized_block, serialized_transaction, event_visitor_settings, event_replay_settings> test_event_entry; typedef std::unordered_map map_hash2tx_t; class test_chain_unit_base { public: typedef boost::function &events)> verify_callback; typedef std::map callbacks_map; void register_callback(const std::string& cb_name, verify_callback cb); bool verify(const std::string& cb_name, cryptonote::core& c, size_t ev_index, const std::vector &events); bool check_block_verification_context(const cryptonote::block_verification_context& bvc, size_t event_idx, const cryptonote::block& /*blk*/); bool check_tx_verification_context(const cryptonote::tx_verification_context& tvc, bool /*tx_added*/, size_t /*event_index*/, const cryptonote::transaction& /*tx*/); bool check_tx_verification_context_array(const std::vector& tvcs, size_t /*tx_added*/, size_t /*event_index*/, const std::vector& /*txs*/); private: callbacks_map m_callbacks; }; class test_generator { public: struct block_info { block_info() : prev_id() , already_generated_coins(0) , block_weight(0) { } block_info(crypto::hash a_prev_id, uint64_t an_already_generated_coins, size_t a_block_weight) : prev_id(a_prev_id) , already_generated_coins(an_already_generated_coins) , block_weight(a_block_weight) { } crypto::hash prev_id; uint64_t already_generated_coins; size_t block_weight; private: friend class boost::serialization::access; template void serialize(Archive & ar, const unsigned int /*version*/) { ar & prev_id; ar & already_generated_coins; ar & block_weight; } }; enum block_fields { bf_none = 0, bf_major_ver = 1 << 0, bf_minor_ver = 1 << 1, bf_timestamp = 1 << 2, bf_prev_id = 1 << 3, bf_miner_tx = 1 << 4, bf_tx_hashes = 1 << 5, bf_diffic = 1 << 6, bf_max_outs = 1 << 7, bf_hf_version= 1 << 8, bf_tx_fees = 1 << 9 }; test_generator(): m_events(nullptr) {} test_generator(const test_generator &other): m_blocks_info(other.m_blocks_info), m_events(other.m_events), m_nettype(other.m_nettype) {} void get_block_chain(std::vector& blockchain, const crypto::hash& head, size_t n) const; void get_last_n_block_weights(std::vector& block_weights, const crypto::hash& head, size_t n) const; uint64_t get_already_generated_coins(const crypto::hash& blk_id) const; uint64_t get_already_generated_coins(const cryptonote::block& blk) const; void add_block(const cryptonote::block& blk, size_t tsx_size, std::vector& block_weights, uint64_t already_generated_coins, uint64_t block_reward, uint8_t hf_version = 1); bool construct_block(cryptonote::block& blk, uint64_t height, const crypto::hash& prev_id, const cryptonote::account_base& miner_acc, uint64_t timestamp, uint64_t already_generated_coins, std::vector& block_weights, const std::list& tx_list, const boost::optional& hf_ver = boost::none); bool construct_block(cryptonote::block& blk, const cryptonote::account_base& miner_acc, uint64_t timestamp); bool construct_block(cryptonote::block& blk, const cryptonote::block& blk_prev, const cryptonote::account_base& miner_acc, const std::list& tx_list = std::list(), const boost::optional& hf_ver = boost::none); bool construct_block_manually(cryptonote::block& blk, const cryptonote::block& prev_block, const cryptonote::account_base& miner_acc, int actual_params = bf_none, uint8_t major_ver = 0, uint8_t minor_ver = 0, uint64_t timestamp = 0, const crypto::hash& prev_id = crypto::hash(), const cryptonote::difficulty_type& diffic = 1, const cryptonote::transaction& miner_tx = cryptonote::transaction(), const std::vector& tx_hashes = std::vector(), size_t txs_sizes = 0, size_t max_outs = 999, uint8_t hf_version = 1, uint64_t fees = 0); bool construct_block_manually_tx(cryptonote::block& blk, const cryptonote::block& prev_block, const cryptonote::account_base& miner_acc, const std::vector& tx_hashes, size_t txs_size); void fill_nonce(cryptonote::block& blk, const cryptonote::difficulty_type& diffic, uint64_t height); void set_events(const std::vector * events) { m_events = events; } void set_network_type(const cryptonote::network_type nettype) { m_nettype = nettype; } private: std::unordered_map m_blocks_info; const std::vector * m_events; cryptonote::network_type m_nettype; friend class boost::serialization::access; template void serialize(Archive & ar, const unsigned int /*version*/) { ar & m_blocks_info; } }; template std::string dump_keys(T * buff32) { std::ostringstream ss; char buff[10]; ss << "["; for(int i = 0; i < 32; i++) { snprintf(buff, 10, "0x%02x", ((uint8_t)buff32[i] & 0xff)); ss << buff; if (i < 31) ss << ","; } ss << "]"; return ss.str(); } struct output_index { const cryptonote::txout_target_v out; uint64_t amount; size_t blk_height; // block height size_t tx_no; // index of transaction in block size_t out_no; // index of out in transaction size_t idx; uint64_t unlock_time; bool is_coin_base; bool spent; bool rct; rct::key comm; const cryptonote::block *p_blk; const cryptonote::transaction *p_tx; output_index(const cryptonote::txout_target_v &_out, uint64_t _a, size_t _h, size_t tno, size_t ono, const cryptonote::block *_pb, const cryptonote::transaction *_pt) : out(_out), amount(_a), blk_height(_h), tx_no(tno), out_no(ono), idx(0), unlock_time(0), is_coin_base(false), spent(false), rct(false), p_blk(_pb), p_tx(_pt) { } output_index(const output_index &other) : out(other.out), amount(other.amount), blk_height(other.blk_height), tx_no(other.tx_no), rct(other.rct), out_no(other.out_no), idx(other.idx), unlock_time(other.unlock_time), is_coin_base(other.is_coin_base), spent(other.spent), comm(other.comm), p_blk(other.p_blk), p_tx(other.p_tx) { } void set_rct(bool arct) { rct = arct; if (rct && p_tx->rct_signatures.outPk.size() > out_no) comm = p_tx->rct_signatures.outPk[out_no].mask; else comm = rct::commit(amount, rct::identity()); } rct::key commitment() const { return comm; } const std::string toString() const { std::stringstream ss; ss << "output_index{blk_height=" << blk_height << " tx_no=" << tx_no << " out_no=" << out_no << " amount=" << amount << " idx=" << idx << " unlock_time=" << unlock_time << " spent=" << spent << " is_coin_base=" << is_coin_base << " rct=" << rct << " comm=" << dump_keys(comm.bytes) << "}"; return ss.str(); } output_index& operator=(const output_index& other) { new(this) output_index(other); return *this; } }; typedef std::tuple get_outs_entry; typedef std::pair output_hasher; typedef boost::hash output_hasher_hasher; typedef std::map > map_output_t; typedef std::map > map_output_idx_t; typedef std::unordered_map map_block_t; typedef std::unordered_map map_txid_output_t; typedef std::unordered_map subaddresses_t; typedef std::pair outloc_t; typedef boost::variant var_addr_t; typedef struct { const var_addr_t addr; bool is_subaddr; uint64_t amount; } dest_wrapper_t; // Daemon functionality class block_tracker { public: map_output_idx_t m_outs; map_txid_output_t m_map_outs; // mapping (txid, out) -> output_index map_block_t m_blocks; block_tracker() = default; block_tracker(const block_tracker &bt): m_outs(bt.m_outs), m_map_outs(bt.m_map_outs), m_blocks(bt.m_blocks) {}; map_txid_output_t::iterator find_out(const crypto::hash &txid, size_t out); map_txid_output_t::iterator find_out(const output_hasher &id); void process(const std::vector& blockchain, const map_hash2tx_t& mtx); void process(const std::vector& blockchain, const map_hash2tx_t& mtx); void process(const cryptonote::block* blk, const cryptonote::transaction * tx, size_t i); void global_indices(const cryptonote::transaction *tx, std::vector &indices); void get_fake_outs(size_t num_outs, uint64_t amount, uint64_t global_index, uint64_t cur_height, std::vector &outs); std::string dump_data(); void dump_data(const std::string & fname); private: friend class boost::serialization::access; template void serialize(Archive & ar, const unsigned int /*version*/) { ar & m_outs; ar & m_map_outs; ar & m_blocks; } }; std::string dump_data(const cryptonote::transaction &tx); cryptonote::account_public_address get_address(const var_addr_t& inp); cryptonote::account_public_address get_address(const cryptonote::account_public_address& inp); cryptonote::account_public_address get_address(const cryptonote::account_keys& inp); cryptonote::account_public_address get_address(const cryptonote::account_base& inp); cryptonote::account_public_address get_address(const cryptonote::tx_destination_entry& inp); inline cryptonote::difficulty_type get_test_difficulty(const boost::optional& hf_ver=boost::none) {return !hf_ver || hf_ver.get() <= 1 ? 1 : 2;} inline uint64_t current_difficulty_window(const boost::optional& hf_ver=boost::none){ return !hf_ver || hf_ver.get() <= 1 ? DIFFICULTY_TARGET_V1 : DIFFICULTY_TARGET_V2; } cryptonote::tx_destination_entry build_dst(const var_addr_t& to, bool is_subaddr=false, uint64_t amount=0); std::vector build_dsts(const var_addr_t& to1, bool sub1=false, uint64_t am1=0); std::vector build_dsts(std::initializer_list inps); uint64_t sum_amount(const std::vector& destinations); uint64_t sum_amount(const std::vector& sources); bool construct_miner_tx_manually(size_t height, uint64_t already_generated_coins, const cryptonote::account_public_address& miner_address, cryptonote::transaction& tx, uint64_t fee, uint8_t hf_version = 1, cryptonote::keypair* p_txkey = nullptr); bool construct_tx_to_key(const std::vector& events, cryptonote::transaction& tx, const cryptonote::block& blk_head, const cryptonote::account_base& from, const var_addr_t& to, uint64_t amount, uint64_t fee, size_t nmix, bool rct=false, rct::RangeProofType range_proof_type=rct::RangeProofBorromean, int bp_version = 0); bool construct_tx_to_key(const std::vector& events, cryptonote::transaction& tx, const cryptonote::block& blk_head, const cryptonote::account_base& from, std::vector destinations, uint64_t fee, size_t nmix, bool rct=false, rct::RangeProofType range_proof_type=rct::RangeProofBorromean, int bp_version = 0); bool construct_tx_to_key(cryptonote::transaction& tx, const cryptonote::account_base& from, const var_addr_t& to, uint64_t amount, std::vector &sources, uint64_t fee, bool rct=false, rct::RangeProofType range_proof_type=rct::RangeProofBorromean, int bp_version = 0); bool construct_tx_to_key(cryptonote::transaction& tx, const cryptonote::account_base& from, const std::vector& destinations, std::vector &sources, uint64_t fee, bool rct, rct::RangeProofType range_proof_type, int bp_version = 0); cryptonote::transaction construct_tx_with_fee(std::vector& events, const cryptonote::block& blk_head, const cryptonote::account_base& acc_from, const var_addr_t& to, uint64_t amount, uint64_t fee); bool construct_tx_rct(const cryptonote::account_keys& sender_account_keys, std::vector& sources, const std::vector& destinations, const boost::optional& change_addr, std::vector extra, cryptonote::transaction& tx, bool rct=false, rct::RangeProofType range_proof_type=rct::RangeProofBorromean, int bp_version = 0); uint64_t num_blocks(const std::vector& events); cryptonote::block get_head_block(const std::vector& events); void get_confirmed_txs(const std::vector& blockchain, const map_hash2tx_t& mtx, map_hash2tx_t& confirmed_txs); bool trim_block_chain(std::vector& blockchain, const crypto::hash& tail); bool trim_block_chain(std::vector& blockchain, const crypto::hash& tail); bool find_block_chain(const std::vector& events, std::vector& blockchain, map_hash2tx_t& mtx, const crypto::hash& head); bool find_block_chain(const std::vector& events, std::vector& blockchain, map_hash2tx_t& mtx, const crypto::hash& head); void fill_tx_destinations(const var_addr_t& from, const cryptonote::account_public_address& to, uint64_t amount, uint64_t fee, const std::vector &sources, std::vector& destinations, bool always_change=false); void fill_tx_destinations(const var_addr_t& from, const std::vector& dests, uint64_t fee, const std::vector &sources, std::vector& destinations, bool always_change); void fill_tx_destinations(const var_addr_t& from, const cryptonote::account_public_address& to, uint64_t amount, uint64_t fee, const std::vector &sources, std::vector& destinations, std::vector& destinations_pure, bool always_change=false); void fill_tx_sources_and_destinations(const std::vector& events, const cryptonote::block& blk_head, const cryptonote::account_base& from, const cryptonote::account_public_address& to, uint64_t amount, uint64_t fee, size_t nmix, std::vector& sources, std::vector& destinations); void fill_tx_sources_and_destinations(const std::vector& events, const cryptonote::block& blk_head, const cryptonote::account_base& from, const cryptonote::account_base& to, uint64_t amount, uint64_t fee, size_t nmix, std::vector& sources, std::vector& destinations); uint64_t get_balance(const cryptonote::account_base& addr, const std::vector& blockchain, const map_hash2tx_t& mtx); bool extract_hard_forks(const std::vector& events, v_hardforks_t& hard_forks); bool extract_hard_forks_from_blocks(const std::vector& events, v_hardforks_t& hard_forks); /************************************************************************/ /* */ /************************************************************************/ template struct push_core_event_visitor: public boost::static_visitor { private: cryptonote::core& m_c; const std::vector& m_events; t_test_class& m_validator; size_t m_ev_index; cryptonote::relay_method m_tx_relay; public: push_core_event_visitor(cryptonote::core& c, const std::vector& events, t_test_class& validator) : m_c(c) , m_events(events) , m_validator(validator) , m_ev_index(0) , m_tx_relay(cryptonote::relay_method::fluff) { } void event_index(size_t ev_index) { m_ev_index = ev_index; } bool operator()(const event_replay_settings& settings) { log_event("event_replay_settings"); return true; } bool operator()(const event_visitor_settings& settings) { log_event("event_visitor_settings"); if (settings.mask & event_visitor_settings::set_txs_keeped_by_block) { m_tx_relay = cryptonote::relay_method::block; } else if (settings.mask & event_visitor_settings::set_local_relay) { m_tx_relay = cryptonote::relay_method::local; } else if (settings.mask & event_visitor_settings::set_txs_do_not_relay) { m_tx_relay = cryptonote::relay_method::none; } else if (settings.mask & event_visitor_settings::set_txs_stem) { m_tx_relay = cryptonote::relay_method::stem; } else { m_tx_relay = cryptonote::relay_method::fluff; } return true; } bool operator()(const cryptonote::transaction& tx) const { log_event("cryptonote::transaction"); cryptonote::tx_verification_context tvc = AUTO_VAL_INIT(tvc); size_t pool_size = m_c.get_pool_transactions_count(); m_c.handle_incoming_tx({t_serializable_object_to_blob(tx), crypto::null_hash}, tvc, m_tx_relay, false); bool tx_added = pool_size + 1 == m_c.get_pool_transactions_count(); bool r = m_validator.check_tx_verification_context(tvc, tx_added, m_ev_index, tx); CHECK_AND_NO_ASSERT_MES(r, false, "tx verification context check failed"); return true; } bool operator()(const std::vector& txs) const { log_event("cryptonote::transaction"); std::vector tx_blobs; std::vector tvcs; cryptonote::tx_verification_context tvc0 = AUTO_VAL_INIT(tvc0); for (const auto &tx: txs) { tx_blobs.push_back({t_serializable_object_to_blob(tx)}); tvcs.push_back(tvc0); } size_t pool_size = m_c.get_pool_transactions_count(); m_c.handle_incoming_txs(tx_blobs, tvcs, m_tx_relay, false); size_t tx_added = m_c.get_pool_transactions_count() - pool_size; bool r = m_validator.check_tx_verification_context_array(tvcs, tx_added, m_ev_index, txs); CHECK_AND_NO_ASSERT_MES(r, false, "tx verification context check failed"); return true; } bool operator()(const cryptonote::block& b) const { log_event("cryptonote::block"); cryptonote::block_verification_context bvc = AUTO_VAL_INIT(bvc); cryptonote::blobdata bd = t_serializable_object_to_blob(b); std::vector pblocks; cryptonote::block_complete_entry bce; bce.pruned = false; bce.block = bd; bce.txs = {}; if (m_c.prepare_handle_incoming_blocks(std::vector(1, bce), pblocks)) { m_c.handle_incoming_block(bd, &b, bvc); m_c.cleanup_handle_incoming_blocks(); } else bvc.m_verifivation_failed = true; bool r = m_validator.check_block_verification_context(bvc, m_ev_index, b); CHECK_AND_NO_ASSERT_MES(r, false, "block verification context check failed"); return r; } bool operator()(const callback_entry& cb) const { log_event(std::string("callback_entry ") + cb.callback_name); return m_validator.verify(cb.callback_name, m_c, m_ev_index, m_events); } bool operator()(const cryptonote::account_base& ab) const { log_event("cryptonote::account_base"); return true; } bool operator()(const serialized_block& sr_block) const { log_event("serialized_block"); cryptonote::block_verification_context bvc = AUTO_VAL_INIT(bvc); std::vector pblocks; cryptonote::block_complete_entry bce; bce.pruned = false; bce.block = sr_block.data; bce.txs = {}; if (m_c.prepare_handle_incoming_blocks(std::vector(1, bce), pblocks)) { m_c.handle_incoming_block(sr_block.data, NULL, bvc); m_c.cleanup_handle_incoming_blocks(); } else bvc.m_verifivation_failed = true; cryptonote::block blk; binary_archive ba{epee::strspan(sr_block.data)}; ::serialization::serialize(ba, blk); if (!ba.good()) { blk = cryptonote::block(); } bool r = m_validator.check_block_verification_context(bvc, m_ev_index, blk); CHECK_AND_NO_ASSERT_MES(r, false, "block verification context check failed"); return true; } bool operator()(const serialized_transaction& sr_tx) const { log_event("serialized_transaction"); cryptonote::tx_verification_context tvc = AUTO_VAL_INIT(tvc); size_t pool_size = m_c.get_pool_transactions_count(); m_c.handle_incoming_tx(sr_tx.data, tvc, m_tx_relay, false); bool tx_added = pool_size + 1 == m_c.get_pool_transactions_count(); cryptonote::transaction tx; binary_archive ba{epee::strspan(sr_tx.data)}; ::serialization::serialize(ba, tx); if (!ba.good()) { tx = cryptonote::transaction(); } bool r = m_validator.check_tx_verification_context(tvc, tx_added, m_ev_index, tx); CHECK_AND_NO_ASSERT_MES(r, false, "transaction verification context check failed"); return true; } private: void log_event(const std::string& event_type) const { MGINFO_YELLOW("=== EVENT # " << m_ev_index << ": " << event_type); } }; //-------------------------------------------------------------------------- template inline bool replay_events_through_core(cryptonote::core& cr, const std::vector& events, t_test_class& validator) { return replay_events_through_core_plain(cr, events, validator, true); } //-------------------------------------------------------------------------- template inline bool replay_events_through_core_plain(cryptonote::core& cr, const std::vector& events, t_test_class& validator, bool reinit=true) { TRY_ENTRY(); //init core here if (reinit) { CHECK_AND_ASSERT_MES(typeid(cryptonote::block) == events[0].type(), false, "First event must be genesis block creation"); cr.set_genesis_block(boost::get(events[0])); } bool r = true; push_core_event_visitor visitor(cr, events, validator); for(size_t i = 1; i < events.size() && r; ++i) { visitor.event_index(i); r = boost::apply_visitor(visitor, events[i]); } return r; CATCH_ENTRY_L0("replay_events_through_core", false); } //-------------------------------------------------------------------------- template struct get_test_options { const std::pair hard_forks[2]; const cryptonote::test_options test_options = { hard_forks, 0 }; get_test_options():hard_forks{std::make_pair((uint8_t)1, (uint64_t)0), std::make_pair((uint8_t)0, (uint64_t)0)}{} }; //-------------------------------------------------------------------------- template inline bool do_replay_events_get_core(std::vector& events, cryptonote::core *core) { boost::program_options::options_description desc("Allowed options"); cryptonote::core::init_options(desc); boost::program_options::variables_map vm; bool r = command_line::handle_error_helper(desc, [&]() { boost::program_options::store(boost::program_options::basic_parsed_options(&desc), vm); boost::program_options::notify(vm); return true; }); if (!r) return false; auto & c = *core; // FIXME: make sure that vm has arg_testnet_on set to true or false if // this test needs for it to be so. get_test_options gto; // Hardforks can be specified in events. v_hardforks_t hardforks; cryptonote::test_options test_options_tmp{nullptr, 0}; const cryptonote::test_options * test_options_ = >o.test_options; if (extract_hard_forks(events, hardforks)){ hardforks.push_back(std::make_pair((uint8_t)0, (uint64_t)0)); // terminator test_options_tmp.hard_forks = hardforks.data(); test_options_ = &test_options_tmp; } if (!c.init(vm, test_options_)) { MERROR("Failed to init core"); return false; } c.get_blockchain_storage().get_db().set_batch_transactions(true); // start with a clean pool std::vector pool_txs; if (!c.get_pool_transaction_hashes(pool_txs)) { MERROR("Failed to flush txpool"); return false; } c.get_blockchain_storage().flush_txes_from_pool(pool_txs); t_test_class validator; bool ret = replay_events_through_core(c, events, validator); tools::threadpool::getInstanceForCompute().recycle(); // c.deinit(); return ret; } //-------------------------------------------------------------------------- template inline bool replay_events_through_core_validate(std::vector& events, cryptonote::core & c) { std::vector pool_txs; if (!c.get_pool_transaction_hashes(pool_txs)) { MERROR("Failed to flush txpool"); return false; } c.get_blockchain_storage().flush_txes_from_pool(pool_txs); t_test_class validator; return replay_events_through_core_plain(c, events, validator, false); } //-------------------------------------------------------------------------- template inline bool do_replay_events(std::vector& events) { cryptonote::core core(nullptr); bool ret = do_replay_events_get_core(events, &core); core.deinit(); return ret; } //-------------------------------------------------------------------------- template inline bool do_replay_file(const std::string& filename) { std::vector events; if (!tools::unserialize_obj_from_file(events, filename)) { MERROR("Failed to deserialize data from file: "); return false; } return do_replay_events(events); } //-------------------------------------------------------------------------- #define DEFAULT_HARDFORKS(HARDFORKS) do { \ HARDFORKS.push_back(std::make_pair((uint8_t)1, (uint64_t)0)); \ } while(0) #define ADD_HARDFORK(HARDFORKS, FORK, HEIGHT) HARDFORKS.push_back(std::make_pair((uint8_t)FORK, (uint64_t)HEIGHT)) #define GENERATE_ACCOUNT(account) \ cryptonote::account_base account; \ account.generate(); #define GENERATE_MULTISIG_ACCOUNT(account, threshold, total) \ CHECK_AND_ASSERT_MES(threshold >= 2 && threshold <= total, false, "Invalid multisig scheme"); \ std::vector account(total); \ do \ { \ for (size_t msidx = 0; msidx < total; ++msidx) \ account[msidx].generate(); \ CHECK_AND_ASSERT_MES(make_multisig_accounts(account, threshold), false, "Failed to make multisig accounts."); \ } while(0) #define MAKE_ACCOUNT(VEC_EVENTS, account) \ cryptonote::account_base account; \ account.generate(); \ VEC_EVENTS.push_back(account); #define DO_CALLBACK(VEC_EVENTS, CB_NAME) \ { \ callback_entry CALLBACK_ENTRY; \ CALLBACK_ENTRY.callback_name = CB_NAME; \ VEC_EVENTS.push_back(CALLBACK_ENTRY); \ } #define REGISTER_CALLBACK(CB_NAME, CLBACK) \ register_callback(CB_NAME, std::bind(&CLBACK, this, std::placeholders::_1, std::placeholders::_2, std::placeholders::_3)); #define REGISTER_CALLBACK_METHOD(CLASS, METHOD) \ register_callback(#METHOD, std::bind(&CLASS::METHOD, this, std::placeholders::_1, std::placeholders::_2, std::placeholders::_3)); #define MAKE_GENESIS_BLOCK(VEC_EVENTS, BLK_NAME, MINER_ACC, TS) \ test_generator generator; \ cryptonote::block BLK_NAME; \ generator.construct_block(BLK_NAME, MINER_ACC, TS); \ VEC_EVENTS.push_back(BLK_NAME); #define MAKE_NEXT_BLOCK(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC) \ cryptonote::block BLK_NAME; \ generator.construct_block(BLK_NAME, PREV_BLOCK, MINER_ACC); \ VEC_EVENTS.push_back(BLK_NAME); #define MAKE_NEXT_BLOCK_HF(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, HF) \ cryptonote::block BLK_NAME; \ generator.construct_block(BLK_NAME, PREV_BLOCK, MINER_ACC, std::list(), HF); \ VEC_EVENTS.push_back(BLK_NAME); #define MAKE_NEXT_BLOCK_TX1(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, TX1) \ cryptonote::block BLK_NAME; \ { \ std::list tx_list; \ tx_list.push_back(TX1); \ generator.construct_block(BLK_NAME, PREV_BLOCK, MINER_ACC, tx_list); \ } \ VEC_EVENTS.push_back(BLK_NAME); #define MAKE_NEXT_BLOCK_TX1_HF(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, TX1, HF) \ cryptonote::block BLK_NAME; \ { \ std::list tx_list; \ tx_list.push_back(TX1); \ generator.construct_block(BLK_NAME, PREV_BLOCK, MINER_ACC, tx_list, HF); \ } \ VEC_EVENTS.push_back(BLK_NAME); #define MAKE_NEXT_BLOCK_TX_LIST(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, TXLIST) \ cryptonote::block BLK_NAME; \ generator.construct_block(BLK_NAME, PREV_BLOCK, MINER_ACC, TXLIST); \ VEC_EVENTS.push_back(BLK_NAME); #define MAKE_NEXT_BLOCK_TX_LIST_HF(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, TXLIST, HF) \ cryptonote::block BLK_NAME; \ generator.construct_block(BLK_NAME, PREV_BLOCK, MINER_ACC, TXLIST, HF); \ VEC_EVENTS.push_back(BLK_NAME); #define REWIND_BLOCKS_N_HF(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, COUNT, HF) \ cryptonote::block BLK_NAME; \ { \ cryptonote::block blk_last = PREV_BLOCK; \ for (size_t i = 0; i < COUNT; ++i) \ { \ MAKE_NEXT_BLOCK_HF(VEC_EVENTS, blk, blk_last, MINER_ACC, HF); \ blk_last = blk; \ } \ BLK_NAME = blk_last; \ } #define REWIND_BLOCKS_N(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, COUNT) REWIND_BLOCKS_N_HF(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, COUNT, boost::none) #define REWIND_BLOCKS(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC) REWIND_BLOCKS_N(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, CRYPTONOTE_MINED_MONEY_UNLOCK_WINDOW) #define REWIND_BLOCKS_HF(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, HF) REWIND_BLOCKS_N_HF(VEC_EVENTS, BLK_NAME, PREV_BLOCK, MINER_ACC, CRYPTONOTE_MINED_MONEY_UNLOCK_WINDOW, HF) #define MAKE_TX_MIX(VEC_EVENTS, TX_NAME, FROM, TO, AMOUNT, NMIX, HEAD) \ cryptonote::transaction TX_NAME; \ construct_tx_to_key(VEC_EVENTS, TX_NAME, HEAD, FROM, TO, AMOUNT, TESTS_DEFAULT_FEE, NMIX); \ VEC_EVENTS.push_back(TX_NAME); #define MAKE_TX_MIX_RCT(VEC_EVENTS, TX_NAME, FROM, TO, AMOUNT, NMIX, HEAD) \ cryptonote::transaction TX_NAME; \ construct_tx_to_key(VEC_EVENTS, TX_NAME, HEAD, FROM, TO, AMOUNT, TESTS_DEFAULT_FEE, NMIX, true, rct::RangeProofPaddedBulletproof); \ VEC_EVENTS.push_back(TX_NAME); #define MAKE_TX(VEC_EVENTS, TX_NAME, FROM, TO, AMOUNT, HEAD) MAKE_TX_MIX(VEC_EVENTS, TX_NAME, FROM, TO, AMOUNT, 0, HEAD) #define MAKE_TX_MIX_LIST(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, NMIX, HEAD) \ { \ cryptonote::transaction t; \ construct_tx_to_key(VEC_EVENTS, t, HEAD, FROM, TO, AMOUNT, TESTS_DEFAULT_FEE, NMIX); \ SET_NAME.push_back(t); \ VEC_EVENTS.push_back(t); \ } #define MAKE_TX_MIX_LIST_RCT(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, NMIX, HEAD) \ MAKE_TX_MIX_LIST_RCT_EX(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, NMIX, HEAD, rct::RangeProofPaddedBulletproof, 1) #define MAKE_TX_MIX_LIST_RCT_EX(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, NMIX, HEAD, RCT_TYPE, BP_VER) \ { \ cryptonote::transaction t; \ construct_tx_to_key(VEC_EVENTS, t, HEAD, FROM, TO, AMOUNT, TESTS_DEFAULT_FEE, NMIX, true, RCT_TYPE, BP_VER); \ SET_NAME.push_back(t); \ VEC_EVENTS.push_back(t); \ } #define MAKE_TX_MIX_DEST_LIST_RCT(VEC_EVENTS, SET_NAME, FROM, TO, NMIX, HEAD) \ MAKE_TX_MIX_DEST_LIST_RCT_EX(VEC_EVENTS, SET_NAME, FROM, TO, NMIX, HEAD, rct::RangeProofPaddedBulletproof, 1) #define MAKE_TX_MIX_DEST_LIST_RCT_EX(VEC_EVENTS, SET_NAME, FROM, TO, NMIX, HEAD, RCT_TYPE, BP_VER) \ { \ cryptonote::transaction t; \ construct_tx_to_key(VEC_EVENTS, t, HEAD, FROM, TO, TESTS_DEFAULT_FEE, NMIX, true, RCT_TYPE, BP_VER); \ SET_NAME.push_back(t); \ VEC_EVENTS.push_back(t); \ } #define MAKE_TX_LIST(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, HEAD) MAKE_TX_MIX_LIST(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, 0, HEAD) #define MAKE_TX_LIST_START(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, HEAD) \ std::list SET_NAME; \ MAKE_TX_LIST(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, HEAD); #define MAKE_TX_LIST_START_RCT(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, NMIX, HEAD) \ std::list SET_NAME; \ MAKE_TX_MIX_LIST_RCT(VEC_EVENTS, SET_NAME, FROM, TO, AMOUNT, NMIX, HEAD); #define MAKE_MINER_TX_AND_KEY_AT_HF_MANUALLY(TX, BLK, HF_VERSION, KEY) \ transaction TX; \ if (!construct_miner_tx_manually(get_block_height(BLK) + 1, generator.get_already_generated_coins(BLK), \ miner_account.get_keys().m_account_address, TX, 0, HF_VERSION, KEY)) \ return false; #define MAKE_MINER_TX_AND_KEY_MANUALLY(TX, BLK, KEY) MAKE_MINER_TX_AND_KEY_AT_HF_MANUALLY(TX, BLK, 1, KEY) #define MAKE_MINER_TX_MANUALLY(TX, BLK) MAKE_MINER_TX_AND_KEY_MANUALLY(TX, BLK, 0) #define SET_EVENT_VISITOR_SETT(VEC_EVENTS, SETT) VEC_EVENTS.push_back(event_visitor_settings(SETT)); #define GENERATE(filename, genclass) \ { \ std::vector events; \ genclass g; \ g.generate(events); \ if (!tools::serialize_obj_to_file(events, filename)) \ { \ MERROR("Failed to serialize data to file: " << filename); \ throw std::runtime_error("Failed to serialize data to file"); \ } \ } #define PLAY(filename, genclass) \ if(!do_replay_file(filename)) \ { \ MERROR("Failed to pass test : " << #genclass); \ return 1; \ } #define CATCH_REPLAY(genclass) \ catch (const std::exception& ex) \ { \ MERROR(#genclass << " generation failed: what=" << ex.what()); \ } \ catch (...) \ { \ MERROR(#genclass << " generation failed: generic exception"); \ } #define REPLAY_CORE(genclass) \ if (generated && do_replay_events< genclass >(events)) \ { \ MGINFO_GREEN("#TEST# Succeeded " << #genclass); \ } \ else \ { \ MERROR("#TEST# Failed " << #genclass); \ failed_tests.push_back(#genclass); \ } #define REPLAY_WITH_CORE(genclass, CORE) \ if (generated && replay_events_through_core_validate< genclass >(events, CORE)) \ { \ MGINFO_GREEN("#TEST# Succeeded " << #genclass); \ } \ else \ { \ MERROR("#TEST# Failed " << #genclass); \ failed_tests.push_back(#genclass); \ } #define CATCH_GENERATE_REPLAY(genclass) \ CATCH_REPLAY(genclass); \ REPLAY_CORE(genclass); #define CATCH_GENERATE_REPLAY_CORE(genclass, CORE) \ CATCH_REPLAY(genclass); \ REPLAY_WITH_CORE(genclass, CORE); #define GENERATE_AND_PLAY(genclass) \ if (list_tests) \ std::cout << #genclass << std::endl; \ else if (filter.empty() || boost::regex_match(std::string(#genclass), match, boost::regex(filter))) \ { \ std::vector events; \ ++tests_count; \ bool generated = false; \ try \ { \ genclass g; \ generated = g.generate(events); \ } \ CATCH_GENERATE_REPLAY(genclass); \ } #define GENERATE_AND_PLAY_INSTANCE(genclass, ins, CORE) \ if (filter.empty() || boost::regex_match(std::string(#genclass), match, boost::regex(filter))) \ { \ std::vector events; \ ++tests_count; \ bool generated = false; \ try \ { \ generated = ins.generate(events); \ } \ CATCH_GENERATE_REPLAY_CORE(genclass, CORE); \ } #define CALL_TEST(test_name, function) \ { \ if(!function()) \ { \ MERROR("#TEST# Failed " << test_name); \ return 1; \ } \ else \ { \ MGINFO_GREEN("#TEST# Succeeded " << test_name); \ } \ } #define QUOTEME(x) #x #define DEFINE_TESTS_ERROR_CONTEXT(text) const char* perr_context = text; (void) perr_context; #define CHECK_TEST_CONDITION(cond) CHECK_AND_ASSERT_MES(cond, false, "[" << perr_context << "] failed: \"" << QUOTEME(cond) << "\"") #define CHECK_EQ(v1, v2) CHECK_AND_ASSERT_MES(v1 == v2, false, "[" << perr_context << "] failed: \"" << QUOTEME(v1) << " == " << QUOTEME(v2) << "\", " << v1 << " != " << v2) #define CHECK_NOT_EQ(v1, v2) CHECK_AND_ASSERT_MES(!(v1 == v2), false, "[" << perr_context << "] failed: \"" << QUOTEME(v1) << " != " << QUOTEME(v2) << "\", " << v1 << " == " << v2) #define MK_COINS(amount) (UINT64_C(amount) * COIN) #define TESTS_DEFAULT_FEE ((uint64_t)20000000000) // 2 * pow(10, 10)