/* This file is part of cpp-ethereum. cpp-ethereum is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. cpp-ethereum is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with cpp-ethereum. If not, see . */ /** @file MixClient.cpp * @author Yann yann@ethdev.com * @author Arkadiy Paronyan arkadiy@ethdev.com * @date 2015 * Ethereum IDE client. */ #include #include #include #include #include #include #include #include "Exceptions.h" #include "MixClient.h" using namespace dev; using namespace dev::eth; using namespace dev::mix; const Secret c_stdSecret = Secret("cb73d9408c4720e230387d956eb0f829d8a4dd2c1055f96257167e14e7169074"); MixClient::MixClient(): m_userAccount(c_stdSecret) { resetState(10000000 * ether); } void MixClient::resetState(u256 _balance) { WriteGuard l(x_state); Guard fl(m_filterLock); m_filters.clear(); m_watches.clear(); m_state = eth::State(m_userAccount.address(), m_stateDB, BaseState::Empty); m_state.addBalance(m_userAccount.address(), _balance); Block genesis; genesis.state = m_state; Block open; m_blocks = Blocks { genesis, open }; //last block contains a list of pending transactions to be finalized } void MixClient::executeTransaction(Transaction const& _t, State& _state) { bytes rlp = _t.rlp(); Executive execution(_state, LastHashes(), 0); execution.setup(&rlp); std::vector machineStates; std::vector levels; std::vector codes; std::map codeIndexes; std::vector data; std::map dataIndexes; bytes const* lastCode = nullptr; bytesConstRef const* lastData = nullptr; unsigned codeIndex = 0; unsigned dataIndex = 0; auto onOp = [&](uint64_t steps, Instruction inst, dev::bigint newMemSize, dev::bigint gasCost, void* voidVM, void const* voidExt) { VM& vm = *(VM*)voidVM; ExtVM const& ext = *(ExtVM const*)voidExt; if (lastCode == nullptr || lastCode != &ext.code) { auto const& iter = codeIndexes.find(&ext.code); if (iter != codeIndexes.end()) codeIndex = iter->second; else { codeIndex = codes.size(); codes.push_back(ext.code); codeIndexes[&ext.code] = codeIndex; } lastCode = &ext.code; } if (lastData == nullptr || lastData != &ext.data) { auto const& iter = dataIndexes.find(&ext.data); if (iter != dataIndexes.end()) dataIndex = iter->second; else { dataIndex = data.size(); data.push_back(ext.data.toBytes()); dataIndexes[&ext.data] = dataIndex; } lastData = &ext.data; } if (levels.size() < ext.depth) levels.push_back(machineStates.size() - 1); else levels.resize(ext.depth); machineStates.emplace_back(MachineState({steps, ext.myAddress, vm.curPC(), inst, newMemSize, vm.gas(), vm.stack(), vm.memory(), gasCost, ext.state().storage(ext.myAddress), levels, codeIndex, dataIndex})); }; execution.go(onOp); execution.finalize(); ExecutionResult d; d.returnValue = execution.out().toVector(); d.machineStates = machineStates; d.executionCode = std::move(codes); d.transactionData = std::move(data); d.address = _t.receiveAddress(); d.sender = _t.sender(); d.value = _t.value(); if (_t.isCreation()) d.contractAddress = right160(sha3(rlpList(_t.sender(), _t.nonce()))); d.receipt = TransactionReceipt(m_state.rootHash(), execution.gasUsed(), execution.logs()); //TODO: track gas usage m_blocks.back().transactions.emplace_back(d); h256Set changed; Guard l(m_filterLock); for (std::pair& i: m_filters) if ((unsigned)i.second.filter.latest() > m_blocks.size() - 1) { // acceptable number. auto m = i.second.filter.matches(d.receipt); if (m.size()) { // filter catches them for (LogEntry const& l: m) i.second.changes.push_back(LocalisedLogEntry(l, m_blocks.size())); changed.insert(i.first); } } changed.insert(dev::eth::PendingChangedFilter); noteChanged(changed); } void MixClient::validateBlock(int _block) const { if (_block != -1 && _block != 0 && (unsigned)_block >= m_blocks.size() - 1) BOOST_THROW_EXCEPTION(InvalidBlockException() << BlockIndex(_block)); } void MixClient::mine() { WriteGuard l(x_state); Block& block = m_blocks.back(); m_state.completeMine(); block.state = m_state; block.info = m_state.info(); block.hash = block.info.hash; m_blocks.push_back(Block()); h256Set changed { dev::eth::PendingChangedFilter, dev::eth::ChainChangedFilter }; noteChanged(changed); } State const& MixClient::asOf(int _block) const { validateBlock(_block); if (_block == 0) return m_blocks[m_blocks.size() - 2].state; else if (_block == -1) return m_state; else return m_blocks[_block].state; } void MixClient::transact(Secret _secret, u256 _value, Address _dest, bytes const& _data, u256 _gas, u256 _gasPrice) { WriteGuard l(x_state); u256 n = m_state.transactionsFrom(toAddress(_secret)); Transaction t(_value, _gasPrice, _gas, _dest, _data, n, _secret); executeTransaction(t, m_state); } Address MixClient::transact(Secret _secret, u256 _endowment, bytes const& _init, u256 _gas, u256 _gasPrice) { WriteGuard l(x_state); u256 n = m_state.transactionsFrom(toAddress(_secret)); eth::Transaction t(_endowment, _gasPrice, _gas, _init, n, _secret); executeTransaction(t, m_state); Address address = right160(sha3(rlpList(t.sender(), t.nonce()))); return address; } void MixClient::inject(bytesConstRef _rlp) { WriteGuard l(x_state); eth::Transaction t(_rlp, CheckSignature::None); executeTransaction(t, m_state); } void MixClient::flushTransactions() { } bytes MixClient::call(Secret _secret, u256 _value, Address _dest, bytes const& _data, u256 _gas, u256 _gasPrice) { u256 n; State temp; { ReadGuard lr(x_state); temp = m_state; n = temp.transactionsFrom(toAddress(_secret)); } Transaction t(_value, _gasPrice, _gas, _dest, _data, n, _secret); bytes rlp = t.rlp(); WriteGuard lw(x_state); //TODO: lock is required only for last execution state executeTransaction(t, temp); return m_blocks.back().transactions.back().returnValue; } u256 MixClient::balanceAt(Address _a, int _block) const { ReadGuard l(x_state); return asOf(_block).balance(_a); } u256 MixClient::countAt(Address _a, int _block) const { ReadGuard l(x_state); return asOf(_block).transactionsFrom(_a); } u256 MixClient::stateAt(Address _a, u256 _l, int _block) const { ReadGuard l(x_state); return asOf(_block).storage(_a, _l); } bytes MixClient::codeAt(Address _a, int _block) const { ReadGuard l(x_state); return asOf(_block).code(_a); } std::map MixClient::storageAt(Address _a, int _block) const { ReadGuard l(x_state); return asOf(_block).storage(_a); } eth::LocalisedLogEntries MixClient::logs(unsigned _watchId) const { Guard l(m_filterLock); h256 h = m_watches.at(_watchId).id; auto filterIter = m_filters.find(h); if (filterIter != m_filters.end()) return logs(filterIter->second.filter); return eth::LocalisedLogEntries(); } eth::LocalisedLogEntries MixClient::logs(eth::LogFilter const& _f) const { LocalisedLogEntries ret; unsigned lastBlock = m_blocks.size() - 1; //last block contains pending transactions unsigned block = std::min(lastBlock, (unsigned)_f.latest()); unsigned end = std::min(lastBlock, std::min(block, (unsigned)_f.earliest())); for (; ret.size() != _f.max() && block != end; block--) { bool pendingBlock = (block == lastBlock); if (pendingBlock || _f.matches(m_blocks[block].info.logBloom)) for (ExecutionResult const& t: m_blocks[block].transactions) if (pendingBlock || _f.matches(t.receipt.bloom())) { LogEntries logEntries = _f.matches(t.receipt); if (logEntries.size()) { for (unsigned entry = _f.skip(); entry < logEntries.size() && ret.size() != _f.max(); ++entry) ret.insert(ret.begin(), LocalisedLogEntry(logEntries[entry], block)); } } } return ret; } unsigned MixClient::installWatch(h256 _h) { unsigned ret; { Guard l(m_filterLock); ret = m_watches.size() ? m_watches.rbegin()->first + 1 : 0; m_watches[ret] = ClientWatch(_h); } auto ch = logs(ret); if (ch.empty()) ch.push_back(eth::InitialChange); { Guard l(m_filterLock); swap(m_watches[ret].changes, ch); } return ret; } unsigned MixClient::installWatch(eth::LogFilter const& _f) { h256 h = _f.sha3(); { Guard l(m_filterLock); m_filters.insert(std::make_pair(h, _f)); } return installWatch(h); } void MixClient::uninstallWatch(unsigned _i) { Guard l(m_filterLock); auto it = m_watches.find(_i); if (it == m_watches.end()) return; auto id = it->second.id; m_watches.erase(it); auto fit = m_filters.find(id); if (fit != m_filters.end()) if (!--fit->second.refCount) m_filters.erase(fit); } void MixClient::noteChanged(h256Set const& _filters) { for (auto& i: m_watches) if (_filters.count(i.second.id)) { if (m_filters.count(i.second.id)) i.second.changes += m_filters.at(i.second.id).changes; else i.second.changes.push_back(LocalisedLogEntry(SpecialLogEntry, 0)); } for (auto& i: m_filters) i.second.changes.clear(); } LocalisedLogEntries MixClient::peekWatch(unsigned _watchId) const { Guard l(m_filterLock); if (_watchId < m_watches.size()) return m_watches.at(_watchId).changes; return LocalisedLogEntries(); } LocalisedLogEntries MixClient::checkWatch(unsigned _watchId) { Guard l(m_filterLock); LocalisedLogEntries ret; if (_watchId < m_watches.size()) std::swap(ret, m_watches.at(_watchId).changes); return ret; } h256 MixClient::hashFromNumber(unsigned _number) const { validateBlock(_number); return m_blocks[_number].hash; } eth::BlockInfo MixClient::blockInfo(h256 _hash) const { (void)_hash; BOOST_THROW_EXCEPTION(InterfaceNotSupported("dev::eth::Interface::blockInfo")); } eth::BlockDetails MixClient::blockDetails(h256 _hash) const { (void)_hash; BOOST_THROW_EXCEPTION(InterfaceNotSupported("dev::eth::Interface::blockDetails")); } eth::Transaction MixClient::transaction(h256 _blockHash, unsigned _i) const { (void)_blockHash; (void)_i; BOOST_THROW_EXCEPTION(InterfaceNotSupported("dev::eth::Interface::transaction")); } eth::BlockInfo MixClient::uncle(h256 _blockHash, unsigned _i) const { (void)_blockHash; (void)_i; BOOST_THROW_EXCEPTION(InterfaceNotSupported("dev::eth::Interface::uncle")); } unsigned MixClient::number() const { return m_blocks.size() - 1; } eth::Transactions MixClient::pending() const { return eth::Transactions(); } eth::StateDiff MixClient::diff(unsigned _txi, h256 _block) const { (void)_txi; (void)_block; BOOST_THROW_EXCEPTION(InterfaceNotSupported("dev::eth::Interface::diff")); } eth::StateDiff MixClient::diff(unsigned _txi, int _block) const { (void)_txi; (void)_block; BOOST_THROW_EXCEPTION(InterfaceNotSupported("dev::eth::Interface::diff")); } Addresses MixClient::addresses(int _block) const { validateBlock(_block); ReadGuard l(x_state); Addresses ret; for (auto const& i: m_state.addresses()) ret.push_back(i.first); return ret; } u256 MixClient::gasLimitRemaining() const { ReadGuard l(x_state); return m_state.gasLimitRemaining(); } void MixClient::setAddress(Address _us) { WriteGuard l(x_state); m_state.setAddress(_us); } Address MixClient::address() const { ReadGuard l(x_state); return m_state.address(); } void MixClient::setMiningThreads(unsigned _threads) { (void)_threads; BOOST_THROW_EXCEPTION(InterfaceNotSupported("dev::eth::Interface::setMiningThreads")); } unsigned MixClient::miningThreads() const { return 0; } void MixClient::startMining() { BOOST_THROW_EXCEPTION(InterfaceNotSupported("dev::eth::Interface::startMining")); } void MixClient::stopMining() { BOOST_THROW_EXCEPTION(InterfaceNotSupported("dev::eth::Interface::stopMining")); } bool MixClient::isMining() { return false; } eth::MineProgress MixClient::miningProgress() const { return eth::MineProgress(); }