// Copyright (c) 2014-2025 Zano Project // Copyright (c) 2014-2018 The Louisdor Project // Copyright (c) 2012-2013 The Cryptonote developers // Distributed under the MIT/X11 software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #include "chaingen.h" #include "block_validation.h" using namespace epee; using namespace currency; namespace { bool lift_up_difficulty(std::vector& events, std::vector& timestamps, std::vector& cummulative_difficulties, test_generator& generator, size_t new_block_count, const block blk_last, const account_base& miner_account) { wide_difficulty_type commulative_diffic = cummulative_difficulties.empty() ? 0 : cummulative_difficulties.back(); block blk_prev = blk_last; for (size_t i = 0; i < new_block_count; ++i) { block blk_next; wide_difficulty_type diffic = next_difficulty_1(timestamps, cummulative_difficulties, DIFFICULTY_POW_TARGET, DIFFICULTY_POW_STARTER); if (!generator.construct_block_manually(blk_next, blk_prev, miner_account, test_generator::bf_timestamp | test_generator::bf_diffic, 0, 0, blk_prev.timestamp, crypto::hash(), diffic)) return false; commulative_diffic += diffic; if (timestamps.size() == DIFFICULTY_WINDOW) { timestamps.erase(timestamps.begin()); cummulative_difficulties.erase(cummulative_difficulties.begin()); } //TODO: VERY ineffective way, need to rewrite timestamps.insert(timestamps.begin(), blk_next.timestamp); cummulative_difficulties.insert(cummulative_difficulties.begin(), commulative_diffic); events.push_back(blk_next); blk_prev = blk_next; } return true; } } #define BLOCK_VALIDATION_INIT_GENERATE() \ GENERATE_ACCOUNT(miner_account); \ MAKE_GENESIS_BLOCK(events, blk_0, miner_account, 1338224400); \ DO_CALLBACK(events, "configure_core"); //---------------------------------------------------------------------------------------------------------------------- // Tests bool gen_block_big_major_version::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_major_ver, CURRENT_BLOCK_MAJOR_VERSION + 1); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_big_minor_version::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_minor_ver, 0, CURRENT_BLOCK_MINOR_VERSION + 1); events.push_back(blk_1); DO_CALLBACK(events, "check_block_accepted"); return true; } bool gen_block_ts_not_checked::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); REWIND_BLOCKS_N(events, blk_0r, blk_0, miner_account, BLOCKCHAIN_TIMESTAMP_CHECK_WINDOW - 2); block blk_1; generator.construct_block_manually(blk_1, blk_0r, miner_account, test_generator::bf_timestamp, 0, 0, blk_0.timestamp - 60 * 60); events.push_back(blk_1); DO_CALLBACK(events, "check_block_accepted"); return true; } bool gen_block_ts_in_past::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); REWIND_BLOCKS_N(events, blk_0r, blk_0, miner_account, BLOCKCHAIN_TIMESTAMP_CHECK_WINDOW - 1); uint64_t ts_below_median = boost::get(events[BLOCKCHAIN_TIMESTAMP_CHECK_WINDOW / 2 - 1]).timestamp; block blk_1; generator.construct_block_manually(blk_1, blk_0r, miner_account, test_generator::bf_timestamp, 0, 0, ts_below_median); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_ts_in_future::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_timestamp, 0, 0, time(NULL) + 60*60 + CURRENCY_BLOCK_FUTURE_TIME_LIMIT); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_invalid_prev_id::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); block blk_1; crypto::hash prev_id = get_block_hash(blk_0); reinterpret_cast(prev_id) ^= 1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_prev_id, 0, 0, 0, prev_id); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_invalid_prev_id::check_block_verification_context(const currency::block_verification_context& bvc, size_t event_idx, const currency::block& /*blk*/) { if (1 == event_idx) return bvc.m_marked_as_orphaned && !bvc.m_added_to_main_chain && !bvc.m_verification_failed; else return !bvc.m_marked_as_orphaned && bvc.m_added_to_main_chain && !bvc.m_verification_failed; } bool gen_block_invalid_nonce::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); std::vector timestamps; std::vector commulative_difficulties; if (!lift_up_difficulty(events, timestamps, commulative_difficulties, generator, 2, blk_0, miner_account)) return false; // Create invalid nonce wide_difficulty_type diffic = next_difficulty_1(timestamps, commulative_difficulties, DIFFICULTY_POW_TARGET, DIFFICULTY_POW_STARTER); CHECK_AND_ASSERT_MES(diffic > 1, false, "diffic > 1 validation failed"); const block& blk_last = boost::get(events.back()); uint64_t timestamp = blk_last.timestamp; block blk_3; do { ++timestamp; blk_3.miner_tx = AUTO_VAL_INIT(blk_3.miner_tx); if (!generator.construct_block_manually(blk_3, blk_last, miner_account, test_generator::bf_diffic | test_generator::bf_timestamp, 0, 0, timestamp, crypto::hash(), diffic)) return false; } while (0 == blk_3.nonce); --blk_3.nonce; events.push_back(blk_3); return true; } bool gen_block_no_miner_tx::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); transaction miner_tx; miner_tx = AUTO_VAL_INIT(miner_tx); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_unlock_time_is_low::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); currency::set_tx_unlock_time(miner_tx, currency::get_tx_max_unlock_time(miner_tx) - 1); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_unlock_time_is_high::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); set_tx_unlock_time(miner_tx, get_tx_max_unlock_time(miner_tx) + 1); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_unlock_time_is_timestamp_in_past::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); set_tx_unlock_time(miner_tx, blk_0.timestamp - 10 * 60); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_unlock_time_is_timestamp_in_future::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); set_tx_unlock_time(miner_tx, blk_0.timestamp + 3 * CURRENCY_MINED_MONEY_UNLOCK_WINDOW * DIFFICULTY_BLOCKS_ESTIMATE_TIMESPAN); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_height_is_low::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); boost::get(miner_tx.vin[0]).height--; block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_height_is_high::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); boost::get(miner_tx.vin[0]).height++; block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_miner_tx_has_2_tx_gen_in::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); txin_gen in; in.height = get_block_height(blk_0) + 1; miner_tx.vin.push_back(in); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_miner_tx_has_2_in::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); REWIND_BLOCKS(events, blk_0r, blk_0, miner_account); GENERATE_ACCOUNT(alice); tx_source_entry se = AUTO_VAL_INIT(se); se.amount = boost::get(blk_0.miner_tx.vout[0]).amount; currency::tx_source_entry::output_entry oe = AUTO_VAL_INIT(oe); oe.out_reference = 0; oe.stealth_address = boost::get(boost::get(blk_0.miner_tx.vout[0]).target).key; se.outputs.push_back(oe); se.real_output = 0; se.real_out_tx_key = get_tx_pub_key_from_extra(blk_0.miner_tx); se.real_output_in_tx_index = 0; std::vector sources; sources.push_back(se); tx_destination_entry de = AUTO_VAL_INIT(de); de.addr.push_back(miner_account.get_keys().account_address); de.amount = se.amount; std::vector destinations; destinations.push_back(de); transaction tmp_tx; std::vector attachments; uint64_t tx_version = get_tx_version(get_block_height(blk_0r), m_hardforks); if (!construct_tx(miner_account.get_keys(), sources, destinations, attachments, tmp_tx, tx_version, 0)) return false; MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); miner_tx.vin.push_back(tmp_tx.vin[0]); block blk_1 = AUTO_VAL_INIT(blk_1); generator.construct_block_manually(blk_1, blk_0r, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_miner_tx_with_txin_to_key::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); // This block has only one output block blk_1 = AUTO_VAL_INIT(blk_1); generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_none); events.push_back(blk_1); REWIND_BLOCKS(events, blk_1r, blk_1, miner_account); tx_source_entry se = AUTO_VAL_INIT(se); se.amount = boost::get(blk_1.miner_tx.vout[0]).amount; currency::tx_source_entry::output_entry oe = AUTO_VAL_INIT(oe); oe.out_reference = 0; oe.stealth_address = boost::get(boost::get(blk_1.miner_tx.vout[0]).target).key; se.outputs.push_back(oe); se.real_output = 0; se.real_out_tx_key = get_tx_pub_key_from_extra(blk_1.miner_tx); se.real_output_in_tx_index = 0; std::vector sources; sources.push_back(se); tx_destination_entry de = AUTO_VAL_INIT(de); de.addr.push_back(miner_account.get_keys().account_address); de.amount = se.amount; std::vector destinations; destinations.push_back(de); transaction tmp_tx = AUTO_VAL_INIT(tmp_tx); std::vector attachments; uint64_t tx_version = get_tx_version(get_block_height(blk_1r), m_hardforks); if (!construct_tx(miner_account.get_keys(), sources, destinations, attachments, tmp_tx, tx_version, 0)) return false; MAKE_MINER_TX_MANUALLY(miner_tx, blk_1); miner_tx.vin[0] = tmp_tx.vin[0]; block blk_2 = AUTO_VAL_INIT(blk_2); generator.construct_block_manually(blk_2, blk_1r, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_2); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_miner_tx_out_is_small::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); boost::get( miner_tx.vout[0]).amount /= 2; block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_miner_tx_out_is_big::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); boost::get( miner_tx.vout[0]).amount *= 2; block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_miner_tx_has_no_out::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); miner_tx.vout.clear(); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_miner_tx_has_out_to_initiator::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); GENERATE_ACCOUNT(alice); keypair txkey; MAKE_MINER_TX_AND_KEY_MANUALLY(miner_tx, blk_0, &txkey); crypto::key_derivation derivation; crypto::public_key out_eph_public_key; crypto::generate_key_derivation(alice.get_keys().account_address.view_public_key, txkey.sec, derivation); crypto::derive_public_key(derivation, 1, alice.get_keys().account_address.spend_public_key, out_eph_public_key); tx_out_bare out_to_initiator; out_to_initiator.amount =boost::get( miner_tx.vout[0]).amount / 2; boost::get( miner_tx.vout[0]).amount -= out_to_initiator.amount; out_to_initiator.target = txout_to_key(out_eph_public_key); miner_tx.vout.push_back(out_to_initiator); block blk_1; generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx); events.push_back(blk_1); DO_CALLBACK(events, "check_block_accepted"); return true; } bool gen_block_has_invalid_tx::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); std::vector tx_hashes; tx_hashes.push_back(crypto::hash()); block blk_1; generator.construct_block_manually_tx(blk_1, blk_0, miner_account, tx_hashes, 0); events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } bool gen_block_is_too_big::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); // Creating a huge miner_tx, it will have a lot of outs MAKE_MINER_TX_MANUALLY(miner_tx, blk_0); static const size_t tx_out_count = CURRENCY_BLOCK_GRANTED_FULL_REWARD_ZONE / 2; uint64_t amount = get_outs_money_amount(miner_tx); uint64_t portion = amount / tx_out_count; uint64_t remainder = amount % tx_out_count; txout_target_v target =boost::get( miner_tx.vout[0]).target; miner_tx.vout.clear(); for (size_t i = 0; i < tx_out_count; ++i) { tx_out_bare o; o.amount = portion; o.target = target; miner_tx.vout.push_back(o); } if (0 < remainder) { tx_out_bare o; o.amount = remainder; o.target = target; miner_tx.vout.push_back(o); } // Block reward will be incorrect, as it must be reduced if cumulative block size is very big, // but in this test it doesn't matter block blk_1; if (!generator.construct_block_manually(blk_1, blk_0, miner_account, test_generator::bf_miner_tx, 0, 0, 0, crypto::hash(), 0, miner_tx)) return false; events.push_back(blk_1); DO_CALLBACK(events, "check_block_purged"); return true; } gen_block_invalid_binary_format::gen_block_invalid_binary_format() : m_corrupt_blocks_begin_idx(0) { REGISTER_CALLBACK("check_all_blocks_purged", gen_block_invalid_binary_format::check_all_blocks_purged); REGISTER_CALLBACK("corrupt_blocks_boundary", gen_block_invalid_binary_format::corrupt_blocks_boundary); } bool gen_block_invalid_binary_format::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); //wide_difficulty_type cummulative_diff = 1; // Unlock blk_0 outputs block blk_last = blk_0; assert(CURRENCY_MINED_MONEY_UNLOCK_WINDOW < DIFFICULTY_WINDOW); for (size_t i = 0; i < CURRENCY_MINED_MONEY_UNLOCK_WINDOW; ++i) { MAKE_NEXT_BLOCK(events, blk_curr, blk_last, miner_account); blk_last = blk_curr; } // Lifting up takes a while wide_difficulty_type diffic; do { MAKE_NEXT_BLOCK(events, blk_curr, blk_last, miner_account); diffic = generator.get_block_difficulty(get_block_hash(blk_curr)); std::cout << "Block #" << events.size() << ", difficulty: " << diffic << std::endl; blk_last = blk_curr; } while (diffic < 200); blk_last = boost::get(events.back()); MAKE_TX(events, tx_0, miner_account, miner_account, MK_TEST_COINS(120), blk_last); DO_CALLBACK(events, "corrupt_blocks_boundary"); block blk_test; std::vector tx_hashes; tx_hashes.push_back(get_transaction_hash(tx_0)); size_t txs_size = get_object_blobsize(tx_0); diffic = generator.get_difficulty_for_next_block(get_block_hash(blk_last)); if (!generator.construct_block_manually(blk_test, blk_last, miner_account, test_generator::bf_diffic | test_generator::bf_timestamp | test_generator::bf_tx_hashes, 0, 0, blk_last.timestamp, crypto::hash(), diffic, transaction(), tx_hashes, txs_size)) return false; blobdata blob = t_serializable_object_to_blob(blk_test); for (size_t i = 0; i < blob.size(); ++i) { for (size_t bit_idx = 0; bit_idx < sizeof(blobdata::value_type) * 8; ++bit_idx) { serialized_block sr_block(blob); blobdata::value_type& ch = sr_block.data[i]; ch ^= 1 << bit_idx; events.push_back(sr_block); } } DO_CALLBACK(events, "check_all_blocks_purged"); return true; } bool gen_block_invalid_binary_format::check_block_verification_context(const currency::block_verification_context& bvc, size_t event_idx, const currency::block& blk) { if (0 == m_corrupt_blocks_begin_idx || event_idx < m_corrupt_blocks_begin_idx) { return bvc.m_added_to_main_chain; } else { return !bvc.m_added_to_main_chain && (bvc.m_already_exists || bvc.m_marked_as_orphaned || bvc.m_verification_failed); } } bool gen_block_invalid_binary_format::corrupt_blocks_boundary(currency::core& c, size_t ev_index, const std::vector& events) { m_corrupt_blocks_begin_idx = ev_index + 1; return true; } bool gen_block_invalid_binary_format::check_all_blocks_purged(currency::core& c, size_t ev_index, const std::vector& events) { CHECK_EQ(1, c.get_pool_transactions_count()); CHECK_EQ(m_corrupt_blocks_begin_idx - 2, c.get_current_blockchain_size()); return true; } gen_block_wrong_version_agains_hardfork::gen_block_wrong_version_agains_hardfork() { REGISTER_CALLBACK("c1", gen_block_wrong_version_agains_hardfork::c1); } bool gen_block_wrong_version_agains_hardfork::c1(currency::core& c, size_t ev_index, const std::vector& events) { currency::core_runtime_config pc = c.get_blockchain_storage().get_core_runtime_config(); pc.min_coinstake_age = TESTS_POS_CONFIG_MIN_COINSTAKE_AGE; //four blocks pc.pos_minimum_heigh = TESTS_POS_CONFIG_POS_MINIMUM_HEIGH; //four blocks pc.hard_forks.set_hardfork_height(1, 10); pc.hard_forks.set_hardfork_height(2, 10); pc.hard_forks.set_hardfork_height(3, 10); c.get_blockchain_storage().set_core_runtime_config(pc); currency::account_base mining_accunt; mining_accunt.generate(); bool r = mine_next_pow_block_in_playtime(mining_accunt.get_public_address(), c); // block with height 1 uint8_t major_version_to_set = 0; uint8_t minor_version_to_set = 0; auto cb = [&] (currency::block& b) { b.major_version = major_version_to_set; b.minor_version = minor_version_to_set; }; //between 1 and 2 hardforks pc.hard_forks.set_hardfork_height(1, 1); pc.hard_forks.set_hardfork_height(2, 10); pc.hard_forks.set_hardfork_height(3, 20); c.get_blockchain_storage().set_core_runtime_config(pc); //major unknown major_version_to_set = 2; r = mine_next_pow_block_in_playtime(mining_accunt.get_public_address(), c, cb); // block with height 2 (won't pass) CHECK_TEST_CONDITION(!r); //minor unknown major_version_to_set = 1; minor_version_to_set = 2; r = mine_next_pow_block_in_playtime(mining_accunt.get_public_address(), c, cb); // block with height 2 CHECK_TEST_CONDITION(r); //between 1 and 2 hardforks pc.hard_forks.set_hardfork_height(1, 1); pc.hard_forks.set_hardfork_height(2, 1); pc.hard_forks.set_hardfork_height(3, 1); c.get_blockchain_storage().set_core_runtime_config(pc); //major correct major_version_to_set = 2; minor_version_to_set = 0; r = mine_next_pow_block_in_playtime(mining_accunt.get_public_address(), c, cb); // block with height 3 CHECK_TEST_CONDITION(r); //major incorrect major_version_to_set = 3; minor_version_to_set = 0; r = mine_next_pow_block_in_playtime(mining_accunt.get_public_address(), c, cb); // block with height 4 (won't pass) CHECK_TEST_CONDITION(!r); //minor incorrect for hf3 major_version_to_set = 2; minor_version_to_set = 1; r = mine_next_pow_block_in_playtime(mining_accunt.get_public_address(), c, cb); // block with height 4 (won't pass) CHECK_TEST_CONDITION(!r); //major lower then normal for hf3 (do we need this half-working backward compability? nope, hardfork 3 always put HF3_BLOCK_MAJOR_VERSION in major version ) major_version_to_set = 0; minor_version_to_set = 0; r = mine_next_pow_block_in_playtime(mining_accunt.get_public_address(), c, cb); // block with height 4 (won't pass) CHECK_TEST_CONDITION(!r); return true; } bool gen_block_wrong_version_agains_hardfork::generate(std::vector& events) const { BLOCK_VALIDATION_INIT_GENERATE(); DO_CALLBACK(events, "c1"); return true; } block_with_correct_prev_id_on_wrong_height::block_with_correct_prev_id_on_wrong_height() { REGISTER_CALLBACK("assert_blk_2_has_wrong_height", block_with_correct_prev_id_on_wrong_height::assert_blk_2_has_wrong_height); } bool block_with_correct_prev_id_on_wrong_height::generate(std::vector& events) const { // Test idea: make sure that a block with correct previous block identifier that is at the wrong height won't be accepted by the core. GENERATE_ACCOUNT(miner); MAKE_GENESIS_BLOCK(events, blk_0, miner, test_core_time::get_time()); DO_CALLBACK(events, "configure_core"); REWIND_BLOCKS_N(events, blk_0r, blk_0, miner, CURRENCY_MINED_MONEY_UNLOCK_WINDOW); MAKE_TX(events, tx_0, miner, miner, MK_TEST_COINS(2), blk_0r); MAKE_NEXT_BLOCK(events, blk_1, blk_0r, miner); m_blk_2.prev_id = currency::get_block_hash(blk_1); m_blk_2.miner_tx = blk_0r.miner_tx; m_blk_2.major_version = blk_0r.major_version; // blk_1 is the previous for blk_2, but height(blk_2) < height(blk_1). CHECK_AND_ASSERT_EQ(currency::get_block_height(blk_1), 11); CHECK_AND_ASSERT_EQ(currency::get_block_height(m_blk_2), 10); DO_CALLBACK(events, "assert_blk_2_has_wrong_height"); return true; } bool block_with_correct_prev_id_on_wrong_height::assert_blk_2_has_wrong_height(currency::core& c, [[maybe_unused]] size_t ev_index, [[maybe_unused]] const std::vector& events) const { currency::block_verification_context context_blk_2{}; CHECK_AND_ASSERT_EQ(boost::get(m_blk_2.miner_tx.vin.front()).height, 10); CHECK_AND_ASSERT_EQ(c.get_blockchain_storage().add_new_block(m_blk_2, context_blk_2), false); return true; } struct block_reward_in_main_chain_basic::argument_assert { uint64_t m_height{}, m_balance{}; std::list m_rewards{}; argument_assert() = default; template argument_assert(const test* instance, uint64_t height, const std::list& blk_tx_fees = {}, const argument_assert previous = {}) : m_height{height} { CHECK_AND_ASSERT_THROW(instance, std::runtime_error{"Pointer to an instance of the test equals to the nullptr."}); CHECK_AND_ASSERT_THROW(m_height >= previous.m_height, std::runtime_error{"A height specified in the previous argument is greather than current height."}); if (height == 0) { m_rewards.push_back(PREMINE_AMOUNT); m_balance = m_rewards.back(); } else { m_balance = previous.m_balance; for (auto fee_iterator{blk_tx_fees.rbegin()}; fee_iterator != blk_tx_fees.rend(); ++fee_iterator) { if (height != 0) { m_rewards.push_back(COIN); if (const auto& fee{*fee_iterator}; fee <= m_rewards.back()) { if (instance->m_hardforks.is_hardfork_active_for_height(ZANO_HARDFORK_04_ZARCANUM, height)) { m_rewards.back() -= fee; } } m_balance += m_rewards.back(); } else { m_balance += PREMINE_AMOUNT; } --height; } } CHECK_AND_ASSERT_THROW(m_rewards.size() > 0, std::runtime_error{"A list of the rewards is empty."}); } BEGIN_SERIALIZE() FIELD(m_height) FIELD(m_balance) FIELD(m_rewards) END_SERIALIZE() }; block_reward_in_main_chain_basic::block_reward_in_main_chain_basic() { REGISTER_CALLBACK_METHOD(block_reward_in_main_chain_basic, assert_balance); REGISTER_CALLBACK_METHOD(block_reward_in_main_chain_basic, assert_reward); } bool block_reward_in_main_chain_basic::generate(std::vector& events) const { // The test idea: make sure that receiving rewards for block insertion is counted correctly. const auto assert_balance{[&events](const argument_assert& argument) -> void { DO_CALLBACK_PARAMS_STR(events, "assert_balance", t_serializable_object_to_blob(argument)); } }; const auto assert_reward{[&events](const argument_assert& argument) -> void { DO_CALLBACK_PARAMS_STR(events, "assert_reward", t_serializable_object_to_blob(argument)); } }; GENERATE_ACCOUNT(miner); MAKE_GENESIS_BLOCK(events, blk_0, miner, test_core_time::get_time()); argument_assert argument{this, get_block_height(blk_0)}; m_accounts.push_back(miner); assert_reward(argument); // Make sure the balance equals to the PREMINE_AMOUNT. assert_balance(argument); DO_CALLBACK(events, "configure_core"); MAKE_NEXT_BLOCK(events, blk_1, blk_0, miner); argument = argument_assert{this, get_block_height(blk_1), {0}, argument}; assert_balance(argument); assert_reward(argument); REWIND_BLOCKS_N(events, blk_1r, blk_1, miner, CURRENCY_MINED_MONEY_UNLOCK_WINDOW - 1); argument = argument_assert{this, get_block_height(blk_1r), std::list(CURRENCY_MINED_MONEY_UNLOCK_WINDOW - 1), argument}; assert_balance(argument); assert_reward(argument); MAKE_TX_FEE(events, tx_0, miner, miner, MK_TEST_COINS(1), TESTS_DEFAULT_FEE, blk_1r); MAKE_NEXT_BLOCK_TX1(events, blk_2, blk_1r, miner, tx_0); argument = {this, get_block_height(blk_2), {TESTS_DEFAULT_FEE}, argument}; assert_reward(argument); // Make sure in the balance change in the case of a transaction with the default fee. assert_balance(argument); MAKE_TX_FEE(events, tx_1, miner, miner, MK_TEST_COINS(3), 2 * TESTS_DEFAULT_FEE, blk_2); MAKE_TX_FEE(events, tx_2, miner, miner, MK_TEST_COINS(2), 3 * TESTS_DEFAULT_FEE, blk_2); const std::list txs{tx_1, tx_2}; MAKE_NEXT_BLOCK_TX_LIST(events, blk_3, blk_2, miner, txs); argument = argument_assert{this, get_block_height(blk_3), {(2 + 3) * TESTS_DEFAULT_FEE}, argument}; assert_reward(argument); // A case of one inserted block with a several transactions with a non default fees. assert_balance(argument); MAKE_TX_FEE(events, tx_3, miner, miner, MK_TEST_COINS(1), COIN + TESTS_DEFAULT_FEE, blk_3); MAKE_NEXT_BLOCK(events, blk_4, blk_3, miner); argument = argument_assert{this, get_block_height(blk_4), {COIN + TESTS_DEFAULT_FEE}, argument}; assert_reward(argument); // A transaction inside blk_4 has a fee greater than a block reward. blk_4 includes only one transaction. assert_balance(argument); MAKE_TX_FEE(events, tx_4, miner, miner, MK_TEST_COINS(1), 76 * COIN + 14 * TESTS_DEFAULT_FEE, blk_4); MAKE_NEXT_BLOCK(events, blk_5, blk_4, miner); argument = argument_assert{this, get_block_height(blk_5), {76 * COIN + 14 * TESTS_DEFAULT_FEE}, argument}; assert_reward(argument); // A transaction inside blk_5 has a fee greater than a block reward. blk_5 includes only one transaction. assert_balance(argument); REWIND_BLOCKS_N(events, blk_5r, blk_5, miner, CURRENCY_MINED_MONEY_UNLOCK_WINDOW); argument = argument_assert{this, get_block_height(blk_5r), std::list(CURRENCY_MINED_MONEY_UNLOCK_WINDOW), argument}; assert_reward(argument); assert_balance(argument); return true; } bool block_reward_in_main_chain_basic::assert_balance(currency::core& core, size_t event_index, const std::vector& events) const { argument_assert argument{}; { const auto serialized_argument{boost::get(events.at(event_index)).callback_params}; CHECK_AND_ASSERT_EQ(t_unserializable_object_from_blob(argument, serialized_argument), true); } CHECK_AND_ASSERT_EQ(core.get_blockchain_storage().get_top_block_height(), argument.m_height); const auto wallet{init_playtime_test_wallet(events, core, m_accounts.front())}; CHECK_AND_ASSERT(wallet, false); wallet->refresh(); CHECK_AND_ASSERT_EQ(wallet->balance(), argument.m_balance); return true; } bool block_reward_in_main_chain_basic::assert_reward(currency::core& core, size_t event_index, const std::vector& events) const { argument_assert argument{}; { const auto serialized_argument{boost::get(events.at(event_index)).callback_params}; CHECK_AND_ASSERT_EQ(t_unserializable_object_from_blob(argument, serialized_argument), true); } for (const auto expected_reward : argument.m_rewards) { uint64_t reward{}; CHECK_AND_ASSERT_EQ(core.get_blockchain_storage().get_block_reward_by_main_chain_height(argument.m_height, reward), true); CHECK_AND_ASSERT_EQ(reward, expected_reward); --argument.m_height; } return true; } struct block_reward_in_alt_chain_basic::argument_assert { uint64_t m_height{}, m_balance{}; crypto::hash blk_id{}; std::list m_rewards{}; argument_assert() = default; template argument_assert(const test* instance, const block& block, const std::list& blk_tx_fees = {}, const argument_assert previous = {}) : blk_id{get_block_hash(block)} { CHECK_AND_ASSERT_THROW(instance, std::runtime_error{"Pointer to an instance of the test equals to the nullptr."}); auto height{get_block_height(block)}; m_height = height; if (height == 0) { m_rewards.push_back(PREMINE_AMOUNT); m_balance = m_rewards.back(); return; } m_balance = previous.m_balance; for (auto fee_iterator{blk_tx_fees.rbegin()}; fee_iterator != blk_tx_fees.rend(); ++fee_iterator) { if (height != 0) { m_rewards.push_back(COIN); if (const auto& fee{*fee_iterator}; fee <= m_rewards.back()) { if (instance->m_hardforks.is_hardfork_active_for_height(ZANO_HARDFORK_04_ZARCANUM, height)) { m_rewards.back() -= fee; } } m_balance += m_rewards.back(); } else { m_balance += PREMINE_AMOUNT; } --height; } CHECK_AND_ASSERT_THROW(m_rewards.size() > 0, std::runtime_error{"A list of the rewards is empty."}); } BEGIN_SERIALIZE() FIELD(m_height) FIELD(m_balance) FIELD(m_rewards) FIELD(blk_id) END_SERIALIZE() }; block_reward_in_alt_chain_basic::block_reward_in_alt_chain_basic() { REGISTER_CALLBACK_METHOD(block_reward_in_alt_chain_basic, assert_balance); REGISTER_CALLBACK_METHOD(block_reward_in_alt_chain_basic, assert_reward); } bool block_reward_in_alt_chain_basic::generate(std::vector& events) const { // The test idea: make sure that receiving rewards for block insertion is counted correctly. const auto assert_balance{[&events](const argument_assert& argument) -> void { DO_CALLBACK_PARAMS_STR(events, "assert_balance", t_serializable_object_to_blob(argument)); } }; const auto assert_reward{[&events](const argument_assert& argument) -> void { DO_CALLBACK_PARAMS_STR(events, "assert_reward", t_serializable_object_to_blob(argument)); } }; GENERATE_ACCOUNT(miner); MAKE_GENESIS_BLOCK(events, blk_0, miner, test_core_time::get_time()); argument_assert argument{this, blk_0}, argument_alt{}; /* 0 (blk_0) */ m_accounts.push_back(miner); // Make sure a reward for the blk_0 equals to PREMINE_AMOUNT. assert_reward(argument); // Make sure the balance equals to the PREMINE_AMOUNT. assert_balance(argument); DO_CALLBACK(events, "configure_core"); REWIND_BLOCKS_N(events, blk_0r, blk_0, miner, CURRENCY_MINED_MONEY_UNLOCK_WINDOW); /* 0 10 (blk_0) - ... - (blk_0r) */ // A case of a 10 sequentally inserted empty sblocks. argument_alt = argument = argument_assert{this, blk_0r, std::list(CURRENCY_MINED_MONEY_UNLOCK_WINDOW), argument}; // Miner inserted 10 empty blocks. A sum of the rewards for them equals to 10 coins. assert_reward(argument); // Make sure the balance equals to PREMINE_AMOUNT + 10 * COIN. assert_balance(argument); MAKE_TX_FEE(events, tx_0, miner, miner, MK_TEST_COINS(1), TESTS_DEFAULT_FEE, blk_0r); MAKE_NEXT_BLOCK_TX1(events, blk_1, blk_0r, miner, tx_0); /* 0 10 11 (blk_0) - ... - (blk_0r) - (blk_1) {tx_0} */ MAKE_TX_FEE(events, tx_1, miner, miner, MK_TEST_COINS(1), 33 * TESTS_DEFAULT_FEE, blk_0r); MAKE_NEXT_BLOCK_TX1(events, blk_1a, blk_0r, miner, tx_1); /* 0 10 11 (blk_0) - ... - (blk_0r) - (blk_1a) | {tx_1} | \ 11 - (blk_1) {tx_0} height(blk_1a) = height(blk_1) fee(tx_1) > fee(tx_0). */ CHECK_AND_ASSERT_EQ(get_block_height(blk_1), get_block_height(blk_1a)); // Case of an alt block on the height 11 with greater total fee than total fee of blk_1 - the top of the main chain. argument_alt = argument_assert{this, blk_1a, {33 * TESTS_DEFAULT_FEE}, argument_alt}; argument = argument_assert{this, blk_1, {TESTS_DEFAULT_FEE}, argument}; if (m_hardforks.is_hardfork_active_for_height(ZANO_HARDFORK_04_ZARCANUM, get_block_height(blk_1))) { // Make sure that a reward for blk_1 equals to COIN. assert_reward(argument_alt); // Make sure that the balance equals to PREMINE_AMOUNT + 11 * COIN - 33 * TESTS_DEFAULT_FEE. assert_balance(argument_alt); } else { // Make sure that a reward for blk_1a equals to COIN. assert_reward(argument); // Make sure that the balance equals to PREMINE_AMOUNT + 11 * COIN. assert_balance(argument); } MAKE_TX_FEE(events, tx_2, miner, miner, MK_TEST_COINS(1), 8 * TESTS_DEFAULT_FEE, blk_1); MAKE_TX_FEE(events, tx_3, miner, miner, MK_TEST_COINS(1), 57 * TESTS_DEFAULT_FEE, blk_1); const std::list txs_0{tx_2, tx_3}; MAKE_NEXT_BLOCK_TX_LIST(events, blk_2, blk_1, miner, txs_0); /* 0 10 11 12 (blk_0) - ... - (blk_0r) - (blk_1) - (blk_2) | {tx_0} {tx_2, tx_3} | \ 11 - (blk_1a) {tx_1} height(blk_2) > height(blk_1a). */ // A case of block on the height 12 in the main chain. argument = argument_assert{this, blk_2, {(8 + 57) * TESTS_DEFAULT_FEE}, argument}; // A reward of blk_2 equals to coin. assert_reward(argument); /* HF3: The balance equals to PREMINE_AMOUNT + 12 * COIN. HF4: The balance equals to PREMINE_AMOUNT + 12 * COIN - 65 * TESTS_DEFAULT_FEE. */ assert_balance(argument); const auto& head_blk_for_txs_on_height_12{m_hardforks.is_hardfork_active_for_height(ZANO_HARDFORK_04_ZARCANUM, get_block_height(blk_2)) ? blk_1a : blk_0r}; MAKE_TX_FEE(events, tx_4, miner, miner, MK_TEST_COINS(2), 15 * TESTS_DEFAULT_FEE, head_blk_for_txs_on_height_12); MAKE_TX_FEE(events, tx_5, miner, miner, MK_TEST_COINS(5), 29 * TESTS_DEFAULT_FEE, head_blk_for_txs_on_height_12); MAKE_TX_FEE(events, tx_6, miner, miner, MK_TEST_COINS(7), 22 * TESTS_DEFAULT_FEE, head_blk_for_txs_on_height_12); const std::list txs_1{tx_4, tx_5, tx_6}; MAKE_NEXT_BLOCK_TX_LIST(events, blk_2a, blk_1a, miner, txs_1); CHECK_AND_ASSERT_EQ(get_block_height(blk_2a), get_block_height(blk_2)); /* 0 10 11 12 (blk_0) - ... - (blk_0r) - (blk_1a) - (blk_2a) | {tx_1} {tx_4, tx_5, tx_6} | \ 11 12 - (blk_1) - (blk_2) {tx_0} {tx_2, tx_3} height(blk_2a) = height(blk_2) = 12 fee(tx_2) + fee(tx_3) = (8 + 57) * TESTS_DEFAULT_FEE = 65 * TESTS_DEFAULT_FEE fee(tx_4) + fee(tx_5) + fee(tx_6) = (15 + 29 + 22) * TESTS_DEFAULT_FEE = 66 * TESTS_DEFAULT_FEE 66 > 65. */ if (m_hardforks.is_hardfork_active_for_height(ZANO_HARDFORK_04_ZARCANUM, get_block_height(blk_2))) { // Case of an alt block on the height 12 with greater total fee than total fee of blk_2 - the top of the main chain. argument_alt = argument_assert{this, blk_2a, {(15 + 29 + 22) * TESTS_DEFAULT_FEE}, argument_alt}; // Make sure a reward for blk_2a is equals to COIN. assert_reward(argument_alt); // Make sure the balance equals to PREMINE_AMOUNT + 12 * COIN - 99 * TESTS_DEFAULT_FEE. assert_balance(argument_alt); } else { // Make sure a reward for blk_2 is equals to COIN. assert_reward(argument); // Make sure the balance equals to PREMINE_AMOUNT + 12 * COIN. assert_balance(argument); } return true; } bool block_reward_in_alt_chain_basic::assert_balance(currency::core& core, size_t event_index, const std::vector& events) const { argument_assert argument{}; { const auto serialized_argument{boost::get(events.at(event_index)).callback_params}; CHECK_AND_ASSERT_EQ(t_unserializable_object_from_blob(argument, serialized_argument), true); } CHECK_AND_ASSERT_EQ(core.get_blockchain_storage().get_top_block_height(), argument.m_height); CHECK_AND_ASSERT_EQ(core.get_blockchain_storage().get_top_block_id(), argument.blk_id); const auto wallet{init_playtime_test_wallet(events, core, m_accounts.front())}; CHECK_AND_ASSERT(wallet, false); wallet->refresh(); CHECK_AND_ASSERT_EQ(wallet->balance(), argument.m_balance); return true; } bool block_reward_in_alt_chain_basic::assert_reward(currency::core& core, size_t event_index, const std::vector& events) const { argument_assert argument{}; { const auto serialized_argument{boost::get(events.at(event_index)).callback_params}; CHECK_AND_ASSERT_EQ(t_unserializable_object_from_blob(argument, serialized_argument), true); } { auto blk_id{argument.blk_id}; for (const auto expected_reward : argument.m_rewards) { uint64_t reward{}; block blk{}; CHECK_AND_ASSERT_EQ(core.get_blockchain_storage().get_block_reward_by_hash(blk_id, reward), true); CHECK_AND_ASSERT_EQ(reward, expected_reward); CHECK_AND_ASSERT_EQ(core.get_blockchain_storage().get_block_by_hash(blk_id, blk), true); blk_id = blk.prev_id; } } return true; }