/* 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 Executive.cpp * @author Gav Wood * @date 2014 */ #include "Executive.h" #include #include #include #include #include "Interface.h" #include "State.h" #include "ExtVM.h" #include "Precompiled.h" #include "BlockChain.h" using namespace std; using namespace dev; using namespace dev::eth; #define ETH_VMTRACE 1 Executive::Executive(State& _s, BlockChain const& _bc, unsigned _level): m_s(_s), m_lastHashes(_s.getLastHashes(_bc, (unsigned)_s.info().number - 1)), m_depth(_level) {} u256 Executive::gasUsed() const { return m_t.gas() - m_endGas; } void Executive::accrueSubState(SubState& _parentContext) { if (m_ext) _parentContext += m_ext->sub; } bool Executive::setup(bytesConstRef _rlp) { // Entry point for a user-executed transaction. m_t = Transaction(_rlp, CheckSignature::Sender); return setup(); } bool Executive::setup() { // Entry point for a user-executed transaction. // Avoid invalid transactions. auto nonceReq = m_s.transactionsFrom(m_t.sender()); if (m_t.nonce() != nonceReq) { clog(StateDetail) << "Invalid Nonce: Require" << nonceReq << " Got" << m_t.nonce(); BOOST_THROW_EXCEPTION(InvalidNonce() << RequirementError((bigint)nonceReq, (bigint)m_t.nonce())); } // Check gas cost is enough. auto gasCost = Interface::txGas(m_t.data()); if (m_t.gas() < gasCost) { clog(StateDetail) << "Not enough gas to pay for the transaction: Require >" << gasCost << " Got" << m_t.gas(); BOOST_THROW_EXCEPTION(OutOfGas() << RequirementError((bigint)gasCost, (bigint)m_t.gas())); } bigint cost = m_t.value() + (bigint)m_t.gas() * m_t.gasPrice(); // Avoid unaffordable transactions. if (m_s.balance(m_t.sender()) < cost) { clog(StateDetail) << "Not enough cash: Require >" << cost << " Got" << m_s.balance(m_t.sender()); BOOST_THROW_EXCEPTION(NotEnoughCash() << RequirementError(cost, (bigint)m_s.balance(m_t.sender()))); } u256 startGasUsed = m_s.gasUsed(); if (startGasUsed + (bigint)m_t.gas() > m_s.m_currentBlock.gasLimit) { clog(StateDetail) << "Too much gas used in this block: Require <" << (m_s.m_currentBlock.gasLimit - startGasUsed) << " Got" << m_t.gas(); BOOST_THROW_EXCEPTION(BlockGasLimitReached() << RequirementError((bigint)(m_s.m_currentBlock.gasLimit - startGasUsed), (bigint)m_t.gas())); } // Increment associated nonce for sender. m_s.noteSending(m_t.sender()); // Pay... clog(StateDetail) << "Paying" << formatBalance(u256(cost)) << "from sender (includes" << m_t.gas() << "gas at" << formatBalance(m_t.gasPrice()) << ")"; m_s.subBalance(m_t.sender(), cost); if (m_t.isCreation()) return create(m_t.sender(), m_t.value(), m_t.gasPrice(), m_t.gas() - (u256)gasCost, &m_t.data(), m_t.sender()); else return call(m_t.receiveAddress(), m_t.receiveAddress(), m_t.sender(), m_t.value(), m_t.gasPrice(), bytesConstRef(&m_t.data()), m_t.gas() - (u256)gasCost, m_t.sender()); } bool Executive::call(Address _receiveAddress, Address _codeAddress, Address _senderAddress, u256 _value, u256 _gasPrice, bytesConstRef _data, u256 _gas, Address _originAddress) { m_isCreation = false; // cnote << "Transferring" << formatBalance(_value) << "to receiver."; m_s.addBalance(_receiveAddress, _value); auto it = !(_codeAddress & ~h160(0xffffffff)) ? precompiled().find((unsigned)(u160)_codeAddress) : precompiled().end(); if (it != precompiled().end()) { bigint g = it->second.gas(_data); if (_gas < g) { m_endGas = 0; m_excepted = true; } else { m_endGas = (u256)(_gas - g); m_precompiledOut = it->second.exec(_data); m_out = &m_precompiledOut; } } else if (m_s.addressHasCode(_codeAddress)) { m_vm = VMFactory::create(_gas); bytes const& c = m_s.code(_codeAddress); m_ext = make_shared(m_s, m_lastHashes, _receiveAddress, _senderAddress, _originAddress, _value, _gasPrice, _data, &c, m_depth); } else m_endGas = _gas; return !m_ext; } bool Executive::create(Address _sender, u256 _endowment, u256 _gasPrice, u256 _gas, bytesConstRef _init, Address _origin) { m_isCreation = true; // We can allow for the reverted state (i.e. that with which m_ext is constructed) to contain the m_newAddress, since // we delete it explicitly if we decide we need to revert. m_newAddress = right160(sha3(rlpList(_sender, m_s.transactionsFrom(_sender) - 1))); // Set up new account... m_s.m_cache[m_newAddress] = Account(m_s.balance(m_newAddress) + _endowment, Account::ContractConception); // Execute _init. if (_init.empty()) { m_s.m_cache[m_newAddress].setCode({}); m_endGas = _gas; } else { m_vm = VMFactory::create(_gas); m_ext = make_shared(m_s, m_lastHashes, m_newAddress, _sender, _origin, _endowment, _gasPrice, bytesConstRef(), _init, m_depth); } return !m_ext; } OnOpFunc Executive::simpleTrace() { return [](uint64_t steps, Instruction inst, bigint newMemSize, bigint gasCost, VM* voidVM, ExtVMFace const* voidExt) { ExtVM const& ext = *static_cast(voidExt); VM& vm = *voidVM; ostringstream o; o << endl << " STACK" << endl; for (auto i: vm.stack()) o << (h256)i << endl; o << " MEMORY" << endl << ((vm.memory().size() > 1000) ? " mem size greater than 1000 bytes " : memDump(vm.memory())); o << " STORAGE" << endl; for (auto const& i: ext.state().storage(ext.myAddress)) o << showbase << hex << i.first << ": " << i.second << endl; dev::LogOutputStream(true) << o.str(); dev::LogOutputStream(false) << " | " << dec << ext.depth << " | " << ext.myAddress << " | #" << steps << " | " << hex << setw(4) << setfill('0') << vm.curPC() << " : " << instructionInfo(inst).name << " | " << dec << vm.gas() << " | -" << dec << gasCost << " | " << newMemSize << "x32" << " ]"; }; } bool Executive::go(OnOpFunc const& _onOp) { if (m_vm) { #if ETH_TIMED_EXECUTIONS boost::timer t; #endif try { m_out = m_vm->go(*m_ext, _onOp); m_endGas = m_vm->gas(); if (m_isCreation) { if (m_out.size() * c_createDataGas <= m_endGas) m_endGas -= m_out.size() * c_createDataGas; else m_out.reset(); m_s.m_cache[m_newAddress].setCode(m_out.toBytes()); } } catch (StepsDone const&) { return false; } catch (VMException const& _e) { clog(StateSafeExceptions) << "Safe VM Exception. " << diagnostic_information(_e); m_endGas = 0; m_excepted = true; m_ext->revert(); } catch (Exception const& _e) { // TODO: AUDIT: check that this can never reasonably happen. Consider what to do if it does. cwarn << "Unexpected exception in VM. There may be a bug in this implementation. " << diagnostic_information(_e); } catch (std::exception const& _e) { // TODO: AUDIT: check that this can never reasonably happen. Consider what to do if it does. cwarn << "Unexpected std::exception in VM. This is probably unrecoverable. " << _e.what(); } #if ETH_TIMED_EXECUTIONS cnote << "VM took:" << t.elapsed() << "; gas used: " << (sgas - m_endGas); #endif } return true; } void Executive::finalize() { // Accumulate refunds for suicides. if (m_ext) m_ext->sub.refunds += c_suicideRefundGas * m_ext->sub.suicides.size(); // SSTORE refunds... // must be done before the miner gets the fees. if (m_ext) m_endGas += min((m_t.gas() - m_endGas) / 2, m_ext->sub.refunds); // cnote << "Refunding" << formatBalance(m_endGas * m_ext->gasPrice) << "to origin (=" << m_endGas << "*" << formatBalance(m_ext->gasPrice) << ")"; m_s.addBalance(m_t.sender(), m_endGas * m_t.gasPrice()); u256 feesEarned = (m_t.gas() - m_endGas) * m_t.gasPrice(); m_s.addBalance(m_s.m_currentBlock.coinbaseAddress, feesEarned); // Suicides... if (m_ext) for (auto a: m_ext->sub.suicides) m_s.m_cache[a].kill(); // Logs.. if (m_ext) m_logs = m_ext->sub.logs; }