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/*
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 <http://www.gnu.org/licenses/>.
*/
/** @file MixClient.cpp
* @author Arkadiy Paronyan arkadiy@ethdev.com
* @date 2015
* Ethereum IDE client.
*/
#include <vector>
#include <libdevcore/Exceptions.h>
#include <libethereum/CanonBlockChain.h>
#include <libethereum/Transaction.h>
#include <libethereum/Executive.h>
#include <libethereum/ExtVM.h>
#include <libethereum/BlockChain.h>
#include <libevm/VM.h>
#include "Exceptions.h"
#include "MixClient.h"
using namespace dev;
using namespace dev::eth;
namespace dev
{
namespace mix
{
const Secret c_userAccountSecret = Secret("cb73d9408c4720e230387d956eb0f829d8a4dd2c1055f96257167e14e7169074");
const u256 c_mixGenesisDifficulty = (u256) 1 << 4;
class MixBlockChain: public dev::eth::BlockChain
{
public:
MixBlockChain(std::string const& _path, h256 _stateRoot): BlockChain(createGenesisBlock(_stateRoot), _path, true)
{
}
static bytes createGenesisBlock(h256 _stateRoot)
{
RLPStream block(3);
block.appendList(14)
<< h256() << EmptyListSHA3 << h160() << _stateRoot << EmptyTrie << EmptyTrie << LogBloom() << c_mixGenesisDifficulty << 0 << 1000000 << 0 << (unsigned)0 << std::string() << sha3(bytes(1, 42));
block.appendRaw(RLPEmptyList);
block.appendRaw(RLPEmptyList);
return block.out();
}
};
MixClient::MixClient(std::string const& _dbPath):
m_userAccount(c_userAccountSecret), m_dbPath(_dbPath), m_minigThreads(0)
{
resetState(10000000 * ether);
}
MixClient::~MixClient()
{
}
void MixClient::resetState(u256 _balance)
{
WriteGuard l(x_state);
Guard fl(m_filterLock);
m_filters.clear();
m_watches.clear();
m_stateDB = OverlayDB();
TrieDB<Address, MemoryDB> accountState(&m_stateDB);
accountState.init();
std::map<Address, Account> genesisState = { std::make_pair(KeyPair(c_userAccountSecret).address(), Account(_balance, Account::NormalCreation)) };
dev::eth::commit(genesisState, static_cast<MemoryDB&>(m_stateDB), accountState);
h256 stateRoot = accountState.root();
m_bc.reset();
m_bc.reset(new MixBlockChain(m_dbPath, stateRoot));
m_state = eth::State(m_userAccount.address(), m_stateDB, BaseState::Empty);
m_state.sync(bc());
m_startState = m_state;
m_executions.clear();
}
void MixClient::executeTransaction(Transaction const& _t, State& _state, bool _call)
{
bytes rlp = _t.rlp();
// do debugging run first
LastHashes lastHashes(256);
lastHashes[0] = bc().numberHash(bc().number());
for (unsigned i = 1; i < 256; ++i)
lastHashes[i] = lastHashes[i - 1] ? bc().details(lastHashes[i - 1]).parent : h256();
State execState = _state;
Executive execution(execState, lastHashes, 0);
execution.setup(&rlp);
std::vector<MachineState> machineStates;
std::vector<unsigned> levels;
std::vector<MachineCode> codes;
std::map<bytes const*, unsigned> codeIndexes;
std::vector<bytes> data;
std::map<bytesConstRef const*, unsigned> 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 = *static_cast<VM*>(voidVM);
ExtVM const& ext = *static_cast<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(MachineCode({ext.myAddress, 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, 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())));
if (!_call)
d.transactionIndex = m_state.pending().size();
m_executions.emplace_back(std::move(d));
// execute on a state
if (!_call)
{
_state.execute(lastHashes, rlp, nullptr, true);
// collect watches
h256Set changed;
Guard l(m_filterLock);
for (std::pair<h256 const, eth::InstalledFilter>& i: m_filters)
if ((unsigned)i.second.filter.latest() > bc().number())
{
// acceptable number.
auto m = i.second.filter.matches(_state.receipt(_state.pending().size() - 1));
if (m.size())
{
// filter catches them
for (LogEntry const& l: m)
i.second.changes.push_back(LocalisedLogEntry(l, bc().number() + 1));
changed.insert(i.first);
}
}
changed.insert(dev::eth::PendingChangedFilter);
noteChanged(changed);
}
}
void MixClient::mine()
{
WriteGuard l(x_state);
m_state.commitToMine(bc());
while (!m_state.mine(100, true).completed) {}
m_state.completeMine();
bc().import(m_state.blockData(), m_stateDB);
m_state.sync(bc());
m_startState = m_state;
h256Set changed { dev::eth::PendingChangedFilter, dev::eth::ChainChangedFilter };
noteChanged(changed);
}
ExecutionResult const& MixClient::lastExecution() const
{
return m_executions.back();
}
ExecutionResults const& MixClient::executions() const
{
return m_executions;
}
State MixClient::asOf(int _block) const
{
ReadGuard l(x_state);
if (_block == 0)
return m_state;
else if (_block == -1)
return m_startState;
else
return State(m_stateDB, bc(), bc().numberHash(_block));
}
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, false);
}
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, false);
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, false);
}
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, true);
return lastExecution().returnValue;
}
u256 MixClient::balanceAt(Address _a, int _block) const
{
return asOf(_block).balance(_a);
}
u256 MixClient::countAt(Address _a, int _block) const
{
return asOf(_block).transactionsFrom(_a);
}
u256 MixClient::stateAt(Address _a, u256 _l, int _block) const
{
return asOf(_block).storage(_a, _l);
}
bytes MixClient::codeAt(Address _a, int _block) const
{
return asOf(_block).code(_a);
}
std::map<u256, u256> MixClient::storageAt(Address _a, int _block) const
{
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 = bc().number();
unsigned block = std::min<unsigned>(lastBlock, (unsigned)_f.latest());
unsigned end = std::min(lastBlock, std::min(block, (unsigned)_f.earliest()));
unsigned skip = _f.skip();
// Pending transactions
if (block > bc().number())
{
ReadGuard l(x_state);
for (unsigned i = 0; i < m_state.pending().size(); ++i)
{
// Might have a transaction that contains a matching log.
TransactionReceipt const& tr = m_state.receipt(i);
LogEntries logEntries = _f.matches(tr);
for (unsigned entry = 0; entry < logEntries.size() && ret.size() != _f.max(); ++entry)
ret.insert(ret.begin(), LocalisedLogEntry(logEntries[entry], block));
skip -= std::min(skip, static_cast<unsigned>(logEntries.size()));
}
block = bc().number();
}
// The rest
auto h = bc().numberHash(block);
for (; ret.size() != block && block != end; block--)
{
if (_f.matches(bc().info(h).logBloom))
for (TransactionReceipt receipt: bc().receipts(h).receipts)
if (_f.matches(receipt.bloom()))
{
LogEntries logEntries = _f.matches(receipt);
for (unsigned entry = skip; entry < logEntries.size() && ret.size() != _f.max(); ++entry)
ret.insert(ret.begin(), LocalisedLogEntry(logEntries[entry], block));
skip -= std::min(skip, static_cast<unsigned>(logEntries.size()));
}
h = bc().details(h).parent;
}
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
{
return bc().numberHash(_number);
}
eth::BlockInfo MixClient::blockInfo(h256 _hash) const
{
return BlockInfo(bc().block(_hash));
}
eth::BlockInfo MixClient::blockInfo() const
{
return BlockInfo(bc().block());
}
eth::BlockDetails MixClient::blockDetails(h256 _hash) const
{
return bc().details(_hash);
}
eth::Transaction MixClient::transaction(h256 _blockHash, unsigned _i) const
{
auto bl = bc().block(_blockHash);
RLP b(bl);
if (_i < b[1].itemCount())
return Transaction(b[1][_i].data(), CheckSignature::Range);
else
return Transaction();
}
eth::BlockInfo MixClient::uncle(h256 _blockHash, unsigned _i) const
{
auto bl = bc().block(_blockHash);
RLP b(bl);
if (_i < b[2].itemCount())
return BlockInfo::fromHeader(b[2][_i].data());
else
return BlockInfo();
}
unsigned MixClient::transactionCount(h256 _blockHash) const
{
auto bl = bc().block(_blockHash);
RLP b(bl);
return b[1].itemCount();
}
unsigned MixClient::uncleCount(h256 _blockHash) const
{
auto bl = bc().block(_blockHash);
RLP b(bl);
return b[2].itemCount();
}
unsigned MixClient::number() const
{
return bc().number();
}
eth::Transactions MixClient::pending() const
{
return m_state.pending();
}
eth::StateDiff MixClient::diff(unsigned _txi, h256 _block) const
{
State st(m_stateDB, bc(), _block);
return st.fromPending(_txi).diff(st.fromPending(_txi + 1));
}
eth::StateDiff MixClient::diff(unsigned _txi, int _block) const
{
State st = asOf(_block);
return st.fromPending(_txi).diff(st.fromPending(_txi + 1));
}
Addresses MixClient::addresses(int _block) const
{
Addresses ret;
for (auto const& i: asOf(_block).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)
{
m_minigThreads = _threads;
}
unsigned MixClient::miningThreads() const
{
return m_minigThreads;
}
void MixClient::startMining()
{
//no-op
}
void MixClient::stopMining()
{
//no-op
}
bool MixClient::isMining()
{
return false;
}
eth::MineProgress MixClient::miningProgress() const
{
return eth::MineProgress();
}
}
}