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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 State.cpp
* @author Gav Wood <i@gavwood.com>
* @date 2014
*/
#include "State.h"
#include <ctime>
#include <random>
#include <boost/filesystem.hpp>
#include <boost/timer.hpp>
#include <secp256k1/secp256k1.h>
#include <libdevcore/CommonIO.h>
#include <libdevcore/Assertions.h>
#include <libdevcore/StructuredLogger.h>
#include <libdevcore/TrieHash.h>
#include <libevmcore/Instruction.h>
#include <libethcore/Exceptions.h>
#include <libevm/VMFactory.h>
#include "BlockChain.h"
#include "Defaults.h"
#include "ExtVM.h"
#include "Executive.h"
#include "CachedAddressState.h"
#include "CanonBlockChain.h"
using namespace std;
using namespace dev;
using namespace dev::eth;
#define ctrace clog(StateTrace)
#define ETH_TIMED_ENACTMENTS 0
static const u256 c_blockReward = 1500 * finney;
const char* StateSafeExceptions::name() { return EthViolet "" EthBlue ""; }
const char* StateDetail::name() { return EthViolet "" EthWhite ""; }
const char* StateTrace::name() { return EthViolet "" EthGray ""; }
const char* StateChat::name() { return EthViolet "" EthWhite ""; }
OverlayDB State::openDB(std::string _path, WithExisting _we)
{
if (_path.empty())
_path = Defaults::get()->m_dbPath;
boost::filesystem::create_directory(_path);
if (_we == WithExisting::Kill)
boost::filesystem::remove_all(_path + "/state");
ldb::Options o;
o.max_open_files = 256;
o.create_if_missing = true;
ldb::DB* db = nullptr;
ldb::DB::Open(o, _path + "/state", &db);
if (!db)
{
if (boost::filesystem::space(_path + "/state").available < 1024)
{
cwarn << "Not enough available space found on hard drive. Please free some up and then re-run. Bailing.";
BOOST_THROW_EXCEPTION(NotEnoughAvailableSpace());
}
else
{
cwarn << "Database already open. You appear to have another instance of ethereum running. Bailing.";
BOOST_THROW_EXCEPTION(DatabaseAlreadyOpen());
}
}
cnote << "Opened state DB.";
return OverlayDB(db);
}
State::State(OverlayDB const& _db, BaseState _bs, Address _coinbaseAddress):
m_db(_db),
m_state(&m_db),
m_ourAddress(_coinbaseAddress),
m_blockReward(c_blockReward)
{
if (_bs != BaseState::PreExisting)
// Initialise to the state entailed by the genesis block; this guarantees the trie is built correctly.
m_state.init();
paranoia("beginning of Genesis construction.", true);
if (_bs == BaseState::CanonGenesis)
{
dev::eth::commit(genesisState(), m_db, m_state);
m_db.commit();
paranoia("after DB commit of Genesis construction.", true);
m_previousBlock = CanonBlockChain::genesis();
}
else
m_previousBlock.clear();
resetCurrent();
assert(m_state.root() == m_previousBlock.stateRoot);
paranoia("end of normal construction.", true);
}
State::State(OverlayDB const& _db, BlockChain const& _bc, h256 _h, ImportRequirements::value _ir):
m_db(_db),
m_state(&m_db),
m_blockReward(c_blockReward)
{
auto b = _bc.block(_h);
BlockInfo bi(b);
if (!bi)
{
// Might be worth throwing here.
cwarn << "Invalid block given for state population: " << _h;
return;
}
if (bi.number)
{
// Non-genesis:
// 1. Start at parent's end state (state root).
BlockInfo bip;
bip.populate(_bc.block(bi.parentHash));
sync(_bc, bi.parentHash, bip, _ir);
// 2. Enact the block's transactions onto this state.
m_ourAddress = bi.coinbaseAddress;
enact(&b, _bc, _ir);
}
else
{
// Genesis required:
// We know there are no transactions, so just populate directly.
m_state.init();
sync(_bc, _h, bi, _ir);
}
}
State::State(State const& _s):
m_db(_s.m_db),
m_state(&m_db, _s.m_state.root(), Verification::Skip),
m_transactions(_s.m_transactions),
m_receipts(_s.m_receipts),
m_transactionSet(_s.m_transactionSet),
m_cache(_s.m_cache),
m_previousBlock(_s.m_previousBlock),
m_currentBlock(_s.m_currentBlock),
m_ourAddress(_s.m_ourAddress),
m_blockReward(_s.m_blockReward)
{
paranoia("after state cloning (copy cons).", true);
}
void State::paranoia(std::string const& _when, bool _enforceRefs) const
{
#if ETH_PARANOIA && !ETH_FATDB
// TODO: variable on context; just need to work out when there should be no leftovers
// [in general this is hard since contract alteration will result in nodes in the DB that are no directly part of the state DB].
if (!isTrieGood(_enforceRefs, false))
{
cwarn << "BAD TRIE" << _when;
BOOST_THROW_EXCEPTION(InvalidTrie());
}
#else
(void)_when;
(void)_enforceRefs;
#endif
}
State& State::operator=(State const& _s)
{
m_db = _s.m_db;
m_state.open(&m_db, _s.m_state.root(), Verification::Skip);
m_transactions = _s.m_transactions;
m_receipts = _s.m_receipts;
m_transactionSet = _s.m_transactionSet;
m_cache = _s.m_cache;
m_previousBlock = _s.m_previousBlock;
m_currentBlock = _s.m_currentBlock;
m_ourAddress = _s.m_ourAddress;
m_blockReward = _s.m_blockReward;
m_lastTx = _s.m_lastTx;
paranoia("after state cloning (assignment op)", true);
m_committedToMine = false;
return *this;
}
State::~State()
{
}
StateDiff State::diff(State const& _c) const
{
StateDiff ret;
std::unordered_set<Address> ads;
std::unordered_set<Address> trieAds;
std::unordered_set<Address> trieAdsD;
auto trie = SecureTrieDB<Address, OverlayDB>(const_cast<OverlayDB*>(&m_db), rootHash());
auto trieD = SecureTrieDB<Address, OverlayDB>(const_cast<OverlayDB*>(&_c.m_db), _c.rootHash());
for (auto i: trie)
ads.insert(i.first), trieAds.insert(i.first);
for (auto i: trieD)
ads.insert(i.first), trieAdsD.insert(i.first);
for (auto i: m_cache)
ads.insert(i.first);
for (auto i: _c.m_cache)
ads.insert(i.first);
// cnote << *this;
// cnote << _c;
for (auto i: ads)
{
auto it = m_cache.find(i);
auto itD = _c.m_cache.find(i);
CachedAddressState source(trieAds.count(i) ? trie.at(i) : "", it != m_cache.end() ? &it->second : nullptr, &m_db);
CachedAddressState dest(trieAdsD.count(i) ? trieD.at(i) : "", itD != _c.m_cache.end() ? &itD->second : nullptr, &_c.m_db);
AccountDiff acd = source.diff(dest);
if (acd.changed())
ret.accounts[i] = acd;
}
return ret;
}
void State::ensureCached(Address _a, bool _requireCode, bool _forceCreate) const
{
ensureCached(m_cache, _a, _requireCode, _forceCreate);
}
void State::ensureCached(std::unordered_map<Address, Account>& _cache, Address _a, bool _requireCode, bool _forceCreate) const
{
auto it = _cache.find(_a);
if (it == _cache.end())
{
// populate basic info.
string stateBack = m_state.at(_a);
if (stateBack.empty() && !_forceCreate)
return;
RLP state(stateBack);
Account s;
if (state.isNull())
s = Account(0, Account::NormalCreation);
else
s = Account(state[0].toInt<u256>(), state[1].toInt<u256>(), state[2].toHash<h256>(), state[3].toHash<h256>(), Account::Unchanged);
bool ok;
tie(it, ok) = _cache.insert(make_pair(_a, s));
}
if (_requireCode && it != _cache.end() && !it->second.isFreshCode() && !it->second.codeCacheValid())
it->second.noteCode(it->second.codeHash() == EmptySHA3 ? bytesConstRef() : bytesConstRef(m_db.lookup(it->second.codeHash())));
}
void State::commit()
{
dev::eth::commit(m_cache, m_db, m_state);
m_cache.clear();
}
bool State::sync(BlockChain const& _bc)
{
return sync(_bc, _bc.currentHash());
}
bool State::sync(BlockChain const& _bc, h256 _block, BlockInfo const& _bi, ImportRequirements::value _ir)
{
(void)_ir;
bool ret = false;
// BLOCK
BlockInfo bi = _bi ? _bi : _bc.info(_block);
/* if (!bi)
while (1)
{
try
{
auto b = _bc.block(_block);
bi.populate(b);
// bi.verifyInternals(_bc.block(_block)); // Unneeded - we already verify on import into the blockchain.
break;
}
catch (Exception const& _e)
{
// TODO: Slightly nicer handling? :-)
cerr << "ERROR: Corrupt block-chain! Delete your block-chain DB and restart." << endl;
cerr << diagnostic_information(_e) << endl;
}
catch (std::exception const& _e)
{
// TODO: Slightly nicer handling? :-)
cerr << "ERROR: Corrupt block-chain! Delete your block-chain DB and restart." << endl;
cerr << _e.what() << endl;
}
}*/
if (bi == m_currentBlock)
{
// We mined the last block.
// Our state is good - we just need to move on to next.
m_previousBlock = m_currentBlock;
resetCurrent();
ret = true;
}
else if (bi == m_previousBlock)
{
// No change since last sync.
// Carry on as we were.
}
else
{
// New blocks available, or we've switched to a different branch. All change.
// Find most recent state dump and replay what's left.
// (Most recent state dump might end up being genesis.)
if (m_db.lookup(bi.stateRoot).empty())
{
cwarn << "Unable to sync to" << bi.hash() << "; state root" << bi.stateRoot << "not found in database.";
cwarn << "Database corrupt: contains block without stateRoot:" << bi;
cwarn << "Bailing.";
exit(-1);
}
m_previousBlock = bi;
resetCurrent();
ret = true;
}
#if ALLOW_REBUILD
else
{
// New blocks available, or we've switched to a different branch. All change.
// Find most recent state dump and replay what's left.
// (Most recent state dump might end up being genesis.)
std::vector<h256> chain;
while (bi.number != 0 && m_db.lookup(bi.stateRoot).empty()) // while we don't have the state root of the latest block...
{
chain.push_back(bi.hash()); // push back for later replay.
bi.populate(_bc.block(bi.parentHash)); // move to parent.
}
m_previousBlock = bi;
resetCurrent();
// Iterate through in reverse, playing back each of the blocks.
try
{
for (auto it = chain.rbegin(); it != chain.rend(); ++it)
{
auto b = _bc.block(*it);
enact(&b, _bc, _ir);
cleanup(true);
}
}
catch (...)
{
// TODO: Slightly nicer handling? :-)
cerr << "ERROR: Corrupt block-chain! Delete your block-chain DB and restart." << endl;
cerr << boost::current_exception_diagnostic_information() << endl;
exit(1);
}
resetCurrent();
ret = true;
}
#endif
return ret;
}
u256 State::enactOn(bytesConstRef _block, BlockInfo const& _bi, BlockChain const& _bc, ImportRequirements::value _ir)
{
#if ETH_TIMED_ENACTMENTS
boost::timer t;
double populateVerify;
double populateGrand;
double syncReset;
double enactment;
#endif
// Check family:
BlockInfo biParent = _bc.info(_bi.parentHash);
_bi.verifyParent(biParent);
#if ETH_TIMED_ENACTMENTS
populateVerify = t.elapsed();
t.restart();
#endif
BlockInfo biGrandParent;
if (biParent.number)
biGrandParent = _bc.info(biParent.parentHash);
#if ETH_TIMED_ENACTMENTS
populateGrand = t.elapsed();
t.restart();
#endif
sync(_bc, _bi.parentHash, BlockInfo(), _ir);
resetCurrent();
#if ETH_TIMED_ENACTMENTS
syncReset = t.elapsed();
t.restart();
#endif
m_previousBlock = biParent;
auto ret = enact(_block, _bc, _ir);
#if ETH_TIMED_ENACTMENTS
enactment = t.elapsed();
cnote << "popVer/popGrand/syncReset/enactment = " << populateVerify << "/" << populateGrand << "/" << syncReset << "/" << enactment;
#endif
return ret;
}
unordered_map<Address, u256> State::addresses() const
{
#if ETH_FATDB
unordered_map<Address, u256> ret;
for (auto i: m_cache)
if (i.second.isAlive())
ret[i.first] = i.second.balance();
for (auto const& i: m_state)
if (m_cache.find(i.first) == m_cache.end())
ret[i.first] = RLP(i.second)[1].toInt<u256>();
return ret;
#else
throw InterfaceNotSupported("State::addresses()");
#endif
}
void State::resetCurrent()
{
m_transactions.clear();
m_receipts.clear();
m_transactionSet.clear();
m_cache.clear();
m_currentBlock = BlockInfo();
m_currentBlock.coinbaseAddress = m_ourAddress;
m_currentBlock.timestamp = max(m_previousBlock.timestamp + 1, (u256)time(0));
m_currentBlock.transactionsRoot = h256();
m_currentBlock.sha3Uncles = h256();
m_currentBlock.populateFromParent(m_previousBlock);
// Update timestamp according to clock.
// TODO: check.
m_lastTx = m_db;
m_state.setRoot(m_previousBlock.stateRoot);
m_committedToMine = false;
paranoia("begin resetCurrent", true);
}
pair<TransactionReceipts, bool> State::sync(BlockChain const& _bc, TransactionQueue& _tq, GasPricer const& _gp, unsigned msTimeout)
{
// TRANSACTIONS
pair<TransactionReceipts, bool> ret;
ret.second = false;
auto ts = _tq.transactions();
LastHashes lh;
auto deadline = chrono::steady_clock::now() + chrono::milliseconds(msTimeout);
for (int goodTxs = 1; goodTxs; )
{
goodTxs = 0;
for (auto const& i: ts)
if (!m_transactionSet.count(i.first))
{
try
{
if (i.second.gasPrice() >= _gp.ask(*this))
{
// boost::timer t;
if (lh.empty())
lh = _bc.lastHashes();
execute(lh, i.second);
ret.first.push_back(m_receipts.back());
_tq.noteGood(i);
++goodTxs;
// cnote << "TX took:" << t.elapsed() * 1000;
}
else if (i.second.gasPrice() < _gp.ask(*this) * 9 / 10)
{
// less than 90% of our ask price for gas. drop.
cnote << i.first << "Dropping El Cheapo transaction (<90% of ask price)";
_tq.drop(i.first);
}
}
catch (InvalidNonce const& in)
{
bigint const& req = *boost::get_error_info<errinfo_required>(in);
bigint const& got = *boost::get_error_info<errinfo_got>(in);
if (req > got)
{
// too old
cnote << i.first << "Dropping old transaction (nonce too low)";
_tq.drop(i.first);
}
else if (got > req + _tq.waiting(i.second.sender()))
{
// too new
cnote << i.first << "Dropping new transaction (too many nonces ahead)";
_tq.drop(i.first);
}
else
_tq.setFuture(i);
}
catch (BlockGasLimitReached const& e)
{
bigint const& got = *boost::get_error_info<errinfo_got>(e);
if (got > m_currentBlock.gasLimit)
{
cnote << i.first << "Dropping over-gassy transaction (gas > block's gas limit)";
_tq.drop(i.first);
}
else
{
// Temporarily no gas left in current block.
// OPTIMISE: could note this and then we don't evaluate until a block that does have the gas left.
// for now, just leave alone.
// _tq.setFuture(i);
}
}
catch (Exception const& _e)
{
// Something else went wrong - drop it.
cnote << i.first << "Dropping invalid transaction:" << diagnostic_information(_e);
_tq.drop(i.first);
}
catch (std::exception const&)
{
// Something else went wrong - drop it.
_tq.drop(i.first);
cnote << i.first << "Transaction caused low-level exception :(";
}
}
if (chrono::steady_clock::now() > deadline)
{
ret.second = true;
break;
}
}
return ret;
}
string State::vmTrace(bytesConstRef _block, BlockChain const& _bc, ImportRequirements::value _ir)
{
RLP rlp(_block);
cleanup(false);
BlockInfo bi(_block, (_ir & ImportRequirements::ValidNonce) ? CheckEverything : IgnoreNonce);
m_currentBlock = bi;
m_currentBlock.verifyInternals(_block);
m_currentBlock.noteDirty();
LastHashes lh = _bc.lastHashes((unsigned)m_previousBlock.number);
vector<bytes> receipts;
ostringstream ss;
unsigned i = 0;
for (auto const& tr: rlp[1])
{
ss << " VM Execution of transaction" << i << ":" << endl;
execute(lh, Transaction(tr.data(), CheckTransaction::Everything), Permanence::Committed, Executive::standardTrace(ss));
RLPStream receiptRLP;
m_receipts.back().streamRLP(receiptRLP);
receipts.push_back(receiptRLP.out());
++i;
ss << endl;
}
return ss.str();
}
template <class Channel>
class LogOverride
{
public:
LogOverride(bool _value): m_old(g_logOverride.count(&typeid(Channel)) ? (int)g_logOverride[&typeid(Channel)] : c_null) { g_logOverride[&typeid(Channel)] = _value; }
~LogOverride()
{
if (m_old == c_null)
g_logOverride.erase(&typeid(Channel));
else
g_logOverride[&typeid(Channel)] = (bool)m_old;
}
private:
static const int c_null = -1;
int m_old;
};
u256 State::enact(bytesConstRef _block, BlockChain const& _bc, ImportRequirements::value _ir)
{
// m_currentBlock is assumed to be prepopulated and reset.
BlockInfo bi(_block, (_ir & ImportRequirements::ValidNonce) ? CheckEverything : IgnoreNonce);
#if !ETH_RELEASE
assert(m_previousBlock.hash() == bi.parentHash);
assert(m_currentBlock.parentHash == bi.parentHash);
assert(rootHash() == m_previousBlock.stateRoot);
#endif
if (m_currentBlock.parentHash != m_previousBlock.hash())
BOOST_THROW_EXCEPTION(InvalidParentHash());
// Populate m_currentBlock with the correct values.
m_currentBlock = bi;
m_currentBlock.verifyInternals(_block);
m_currentBlock.noteDirty();
// cnote << "playback begins:" << m_state.root();
// cnote << m_state;
LastHashes lh = _bc.lastHashes((unsigned)m_previousBlock.number);
RLP rlp(_block);
vector<bytes> receipts;
// All ok with the block generally. Play back the transactions now...
unsigned i = 0;
for (auto const& tr: rlp[1])
{
try {
LogOverride<ExecutiveWarnChannel> o(false);
execute(lh, Transaction(tr.data(), CheckTransaction::Everything));
}
catch (...)
{
badBlock(_block, "Invalid transaction");
cwarn << " Transaction Index:" << i;
LogOverride<ExecutiveWarnChannel> o(true);
execute(lh, Transaction(tr.data(), CheckTransaction::Everything));
throw;
}
RLPStream receiptRLP;
m_receipts.back().streamRLP(receiptRLP);
receipts.push_back(receiptRLP.out());
++i;
}
auto receiptsRoot = orderedTrieRoot(receipts);
if (receiptsRoot != m_currentBlock.receiptsRoot)
{
badBlock(_block, "Bad receipts state root");
cwarn << " Received: " << toString(m_currentBlock.receiptsRoot);
cwarn << " Expected: " << toString(receiptsRoot) << " which is:";
for (unsigned j = 0; j < i; ++j)
{
auto b = receipts[j];
cwarn << j << ": ";
cwarn << " RLP: " << RLP(b);
cwarn << " Hex: " << toHex(b);
cwarn << " " << TransactionReceipt(&b);
}
cwarn << " VMTrace:\n" << vmTrace(_block, _bc, _ir);
BOOST_THROW_EXCEPTION(InvalidReceiptsStateRoot());
}
if (m_currentBlock.logBloom != logBloom())
{
badBlock(_block, "Bad log bloom");
cwarn << " Receipt blooms:";
for (unsigned j = 0; j < i; ++j)
{
auto b = receipts[j];
cwarn << " " << j << ":" << TransactionReceipt(&b).bloom().hex();
}
cwarn << " Final bloom:" << m_currentBlock.logBloom.hex();
BOOST_THROW_EXCEPTION(InvalidLogBloom());
}
// Initialise total difficulty calculation.
u256 tdIncrease = m_currentBlock.difficulty;
// Check uncles & apply their rewards to state.
if (rlp[2].itemCount() > 2)
{
badBlock(_block, "Too many uncles");
BOOST_THROW_EXCEPTION(TooManyUncles());
}
vector<BlockInfo> rewarded;
h256Hash excluded = _bc.allKinFrom(m_currentBlock.parentHash, 6);
excluded.insert(m_currentBlock.hash());
for (auto const& i: rlp[2])
{
auto h = sha3(i.data());
if (excluded.count(h))
{
badBlock(_block, "Invalid uncle included");
BOOST_THROW_EXCEPTION(UncleInChain() << errinfo_comment("Uncle in block already mentioned") << errinfo_data(toString(excluded)) << errinfo_hash256(sha3(i.data())));
}
excluded.insert(h);
BlockInfo uncle = BlockInfo::fromHeader(i.data(), (_ir & ImportRequirements::CheckUncles) ? CheckEverything : IgnoreNonce, h);
BlockInfo uncleParent(_bc.block(uncle.parentHash));
if ((bigint)uncleParent.number < (bigint)m_currentBlock.number - 7)
{
badBlock(_block, "Uncle too old");
cwarn << " Uncle number: " << uncle.number;
cwarn << " Uncle parent number: " << uncleParent.number;
cwarn << " Block number: " << m_currentBlock.number;
BOOST_THROW_EXCEPTION(UncleTooOld());
}
else if (uncle.number == m_currentBlock.number)
{
badBlock(_block, "Uncle is brother");
cwarn << " Uncle number: " << uncle.number;
cwarn << " Uncle parent number: " << uncleParent.number;
cwarn << " Block number: " << m_currentBlock.number;
BOOST_THROW_EXCEPTION(UncleIsBrother());
}
uncle.verifyParent(uncleParent);
// tdIncrease += uncle.difficulty;
rewarded.push_back(uncle);
}
applyRewards(rewarded);
// Commit all cached state changes to the state trie.
commit();
// Hash the state trie and check against the state_root hash in m_currentBlock.
if (m_currentBlock.stateRoot != m_previousBlock.stateRoot && m_currentBlock.stateRoot != rootHash())
{
badBlock(_block, "Bad state root");
cnote << " Given to be:" << m_currentBlock.stateRoot;
// TODO: Fix
// cnote << SecureTrieDB<Address, OverlayDB>(&m_db, m_currentBlock.stateRoot);
cnote << " Calculated to be:" << rootHash();
cwarn << " VMTrace:\n" << vmTrace(_block, _bc, _ir);
// cnote << m_state;
// Rollback the trie.
m_db.rollback();
BOOST_THROW_EXCEPTION(InvalidStateRoot());
}
if (m_currentBlock.gasUsed != gasUsed())
{
// Rollback the trie.
badBlock(_block, "Invalid gas used");
m_db.rollback();
BOOST_THROW_EXCEPTION(InvalidGasUsed() << RequirementError(bigint(gasUsed()), bigint(m_currentBlock.gasUsed)));
}
return tdIncrease;
}
void State::cleanup(bool _fullCommit)
{
if (_fullCommit)
{
paranoia("immediately before database commit", true);
// Commit the new trie to disk.
clog(StateTrace) << "Committing to disk: stateRoot" << m_currentBlock.stateRoot << "=" << rootHash() << "=" << toHex(asBytes(m_db.lookup(rootHash())));
try {
EnforceRefs er(m_db, true);
rootHash();
}
catch (BadRoot const&)
{
clog(StateChat) << "Trie corrupt! :-(";
throw;
}
m_db.commit();
clog(StateTrace) << "Committed: stateRoot" << m_currentBlock.stateRoot << "=" << rootHash() << "=" << toHex(asBytes(m_db.lookup(rootHash())));
paranoia("immediately after database commit", true);
m_previousBlock = m_currentBlock;
m_currentBlock.populateFromParent(m_previousBlock);
clog(StateTrace) << "finalising enactment. current -> previous, hash is" << m_previousBlock.hash();
}
else
m_db.rollback();
resetCurrent();
}
void State::uncommitToMine()
{
if (m_committedToMine)
{
m_cache.clear();
if (!m_transactions.size())
m_state.setRoot(m_previousBlock.stateRoot);
else
m_state.setRoot(m_receipts.back().stateRoot());
m_db = m_lastTx;
paranoia("Uncommited to mine", true);
m_committedToMine = false;
}
}
bool State::amIJustParanoid(BlockChain const& _bc)
{
commitToMine(_bc);
// Update difficulty according to timestamp.
m_currentBlock.difficulty = m_currentBlock.calculateDifficulty(m_previousBlock);
// Compile block:
RLPStream block;
block.appendList(3);
m_currentBlock.streamRLP(block, WithNonce);
block.appendRaw(m_currentTxs);
block.appendRaw(m_currentUncles);
State s(*this);
s.resetCurrent();
try
{
cnote << "PARANOIA root:" << s.rootHash();
// s.m_currentBlock.populate(&block.out(), false);
// s.m_currentBlock.verifyInternals(&block.out());
s.enact(&block.out(), _bc, false); // don't check nonce for this since we haven't mined it yet.
s.cleanup(false);
return true;
}
catch (Exception const& _e)
{
cwarn << "Bad block: " << diagnostic_information(_e);
}
catch (std::exception const& _e)
{
cwarn << "Bad block: " << _e.what();
}
return false;
}
LogBloom State::logBloom() const
{
LogBloom ret;
for (TransactionReceipt const& i: m_receipts)
ret |= i.bloom();
return ret;
}
void State::commitToMine(BlockChain const& _bc)
{
uncommitToMine();
// cnote << "Committing to mine on block" << m_previousBlock.hash;
#if ETH_PARANOIA && 0
commit();
cnote << "Pre-reward stateRoot:" << m_state.root();
#endif
m_lastTx = m_db;
vector<BlockInfo> uncleBlockHeaders;
RLPStream unclesData;
unsigned unclesCount = 0;
if (m_previousBlock.number != 0)
{
// Find great-uncles (or second-cousins or whatever they are) - children of great-grandparents, great-great-grandparents... that were not already uncles in previous generations.
// cout << "Checking " << m_previousBlock.hash << ", parent=" << m_previousBlock.parentHash << endl;
h256Hash excluded = _bc.allKinFrom(m_currentBlock.parentHash, 6);
auto p = m_previousBlock.parentHash;
for (unsigned gen = 0; gen < 6 && p != _bc.genesisHash() && unclesCount < 2; ++gen, p = _bc.details(p).parent)
{
auto us = _bc.details(p).children;
assert(us.size() >= 1); // must be at least 1 child of our grandparent - it's our own parent!
for (auto const& u: us)
if (!excluded.count(u)) // ignore any uncles/mainline blocks that we know about.
{
BlockInfo ubi(_bc.block(u));
ubi.streamRLP(unclesData, WithNonce);
++unclesCount;
uncleBlockHeaders.push_back(ubi);
if (unclesCount == 2)
break;
}
}
}
BytesMap transactionsMap;
BytesMap receiptsMap;
RLPStream txs;
txs.appendList(m_transactions.size());
for (unsigned i = 0; i < m_transactions.size(); ++i)
{
RLPStream k;
k << i;
RLPStream receiptrlp;
m_receipts[i].streamRLP(receiptrlp);
receiptsMap.insert(std::make_pair(k.out(), receiptrlp.out()));
RLPStream txrlp;
m_transactions[i].streamRLP(txrlp);
transactionsMap.insert(std::make_pair(k.out(), txrlp.out()));
txs.appendRaw(txrlp.out());
}
txs.swapOut(m_currentTxs);
RLPStream(unclesCount).appendRaw(unclesData.out(), unclesCount).swapOut(m_currentUncles);
m_currentBlock.transactionsRoot = hash256(transactionsMap);
m_currentBlock.receiptsRoot = hash256(receiptsMap);
m_currentBlock.logBloom = logBloom();
m_currentBlock.sha3Uncles = sha3(m_currentUncles);
// Apply rewards last of all.
applyRewards(uncleBlockHeaders);
// Commit any and all changes to the trie that are in the cache, then update the state root accordingly.
commit();
// cnote << "Post-reward stateRoot:" << m_state.root();
// cnote << m_state;
// cnote << *this;
m_currentBlock.gasUsed = gasUsed();
m_currentBlock.stateRoot = m_state.root();
m_currentBlock.parentHash = m_previousBlock.hash();
m_committedToMine = true;
}
void State::completeMine()
{
cdebug << "Completing mine!";
// Got it!
// Compile block:
RLPStream ret;
ret.appendList(3);
m_currentBlock.streamRLP(ret, WithNonce);
ret.appendRaw(m_currentTxs);
ret.appendRaw(m_currentUncles);
ret.swapOut(m_currentBytes);
m_currentBlock.noteDirty();
cnote << "Mined " << m_currentBlock.hash() << "(parent: " << m_currentBlock.parentHash << ")";
StructuredLogger::minedNewBlock(
m_currentBlock.hash().abridged(),
m_currentBlock.nonce.abridged(),
"", //TODO: chain head hash here ??
m_currentBlock.parentHash.abridged()
);
// Quickly reset the transactions.
// TODO: Leave this in a better state than this limbo, or at least record that it's in limbo.
m_transactions.clear();
m_receipts.clear();
m_transactionSet.clear();
m_lastTx = m_db;
}
bool State::addressInUse(Address _id) const
{
ensureCached(_id, false, false);
auto it = m_cache.find(_id);
if (it == m_cache.end())
return false;
return true;
}
bool State::addressHasCode(Address _id) const
{
ensureCached(_id, false, false);
auto it = m_cache.find(_id);
if (it == m_cache.end())
return false;
return it->second.isFreshCode() || it->second.codeHash() != EmptySHA3;
}
u256 State::balance(Address _id) const
{
ensureCached(_id, false, false);
auto it = m_cache.find(_id);
if (it == m_cache.end())
return 0;
return it->second.balance();
}
void State::noteSending(Address _id)
{
ensureCached(_id, false, false);
auto it = m_cache.find(_id);
if (asserts(it != m_cache.end()))
{
cwarn << "Sending from non-existant account. How did it pay!?!";
// this is impossible. but we'll continue regardless...
m_cache[_id] = Account(1, 0);
}
else
it->second.incNonce();
}
void State::addBalance(Address _id, u256 _amount)
{
ensureCached(_id, false, false);
auto it = m_cache.find(_id);
if (it == m_cache.end())
m_cache[_id] = Account(_amount, Account::NormalCreation);
else
it->second.addBalance(_amount);
}
void State::subBalance(Address _id, bigint _amount)
{
ensureCached(_id, false, false);
auto it = m_cache.find(_id);
if (it == m_cache.end() || (bigint)it->second.balance() < _amount)
BOOST_THROW_EXCEPTION(NotEnoughCash());
else
it->second.addBalance(-_amount);
}
Address State::newContract(u256 _balance, bytes const& _code)
{
auto h = sha3(_code);
m_db.insert(h, &_code);
while (true)
{
Address ret = Address::random();
ensureCached(ret, false, false);
auto it = m_cache.find(ret);
if (it == m_cache.end())
{
m_cache[ret] = Account(0, _balance, EmptyTrie, h, Account::Changed);
return ret;
}
}
}
u256 State::transactionsFrom(Address _id) const
{
ensureCached(_id, false, false);
auto it = m_cache.find(_id);
if (it == m_cache.end())
return 0;
else
return it->second.nonce();
}
u256 State::storage(Address _id, u256 _memory) const
{
ensureCached(_id, false, false);
auto it = m_cache.find(_id);
// Account doesn't exist - exit now.
if (it == m_cache.end())
return 0;
// See if it's in the account's storage cache.
auto mit = it->second.storageOverlay().find(_memory);
if (mit != it->second.storageOverlay().end())
return mit->second;
// Not in the storage cache - go to the DB.
SecureTrieDB<h256, OverlayDB> memdb(const_cast<OverlayDB*>(&m_db), it->second.baseRoot()); // promise we won't change the overlay! :)
string payload = memdb.at(_memory);
u256 ret = payload.size() ? RLP(payload).toInt<u256>() : 0;
it->second.setStorage(_memory, ret);
return ret;
}
unordered_map<u256, u256> State::storage(Address _id) const
{
unordered_map<u256, u256> ret;
ensureCached(_id, false, false);
auto it = m_cache.find(_id);
if (it != m_cache.end())
{
// Pull out all values from trie storage.
if (it->second.baseRoot())
{
SecureTrieDB<h256, OverlayDB> memdb(const_cast<OverlayDB*>(&m_db), it->second.baseRoot()); // promise we won't alter the overlay! :)
for (auto const& i: memdb)
ret[i.first] = RLP(i.second).toInt<u256>();
}
// Then merge cached storage over the top.
for (auto const& i: it->second.storageOverlay())
if (i.second)
ret[i.first] = i.second;
else
ret.erase(i.first);
}
return ret;
}
h256 State::storageRoot(Address _id) const
{
string s = m_state.at(_id);
if (s.size())
{
RLP r(s);
return r[2].toHash<h256>();
}
return EmptyTrie;
}
bytes const& State::code(Address _contract) const
{
if (!addressHasCode(_contract))
return NullBytes;
ensureCached(_contract, true, false);
return m_cache[_contract].code();
}
h256 State::codeHash(Address _contract) const
{
if (!addressHasCode(_contract))
return EmptySHA3;
return m_cache[_contract].codeHash();
}
bool State::isTrieGood(bool _enforceRefs, bool _requireNoLeftOvers) const
{
for (int e = 0; e < (_enforceRefs ? 2 : 1); ++e)
try
{
EnforceRefs r(m_db, !!e);
auto lo = m_state.leftOvers();
if (!lo.empty() && _requireNoLeftOvers)
{
cwarn << "LEFTOVERS" << (e ? "[enforced" : "[unenforced") << "refs]";
cnote << "Left:" << lo;
cnote << "Keys:" << m_db.keys();
// m_state.debugStructure(cerr);
return false;
}
// TODO: Enable once fixed.
/* for (auto const& i: m_state)
{
RLP r(i.second);
SecureTrieDB<h256, OverlayDB> storageDB(const_cast<OverlayDB*>(&m_db), r[2].toHash<h256>()); // promise not to alter OverlayDB.
for (auto const& j: storageDB) { (void)j; }
if (!e && r[3].toHash<h256>() != EmptySHA3 && m_db.lookup(r[3].toHash<h256>()).empty())
return false;
}*/
}
catch (InvalidTrie const&)
{
cwarn << "BAD TRIE" << (e ? "[enforced" : "[unenforced") << "refs]";
cnote << m_db.keys();
// m_state.debugStructure(cerr);
return false;
}
return true;
}
ExecutionResult State::execute(LastHashes const& _lh, Transaction const& _t, Permanence _p, OnOpFunc const& _onOp)
{
#if ETH_PARANOIA
paranoia("start of execution.", true);
State old(*this);
auto h = rootHash();
#endif
// Create and initialize the executive. This will throw fairly cheaply and quickly if the
// transaction is bad in any way.
Executive e(*this, _lh, 0);
e.initialize(_t);
// Uncommitting is a non-trivial operation - only do it once we've verified as much of the
// transaction as possible.
uncommitToMine();
// OK - transaction looks valid - execute.
u256 startGasUsed = gasUsed();
#if ETH_PARANOIA
ctrace << "Executing" << e.t() << "on" << h;
ctrace << toHex(e.t().rlp());
#endif
if (!e.execute())
#if ETH_VMTRACE
{
(void)_onOp;
e.go(e.simpleTrace());
}
#else
e.go(_onOp);
#endif
e.finalize();
#if ETH_PARANOIA
ctrace << "Ready for commit;";
ctrace << old.diff(*this);
#endif
if (_p == Permanence::Reverted)
m_cache.clear();
else
{
commit();
#if ETH_PARANOIA && !ETH_FATDB
ctrace << "Executed; now" << rootHash();
ctrace << old.diff(*this);
paranoia("after execution commit.", true);
if (e.t().receiveAddress())
{
EnforceRefs r(m_db, true);
if (storageRoot(e.t().receiveAddress()) && m_db.lookup(storageRoot(e.t().receiveAddress())).empty())
{
cwarn << "TRIE immediately after execution; no node for receiveAddress";
BOOST_THROW_EXCEPTION(InvalidTrie());
}
}
#endif
// TODO: CHECK TRIE after level DB flush to make sure exactly the same.
// Add to the user-originated transactions that we've executed.
m_transactions.push_back(e.t());
m_receipts.push_back(TransactionReceipt(rootHash(), startGasUsed + e.gasUsed(), e.logs()));
m_transactionSet.insert(e.t().sha3());
}
return e.executionResult();
}
State State::fromPending(unsigned _i) const
{
State ret = *this;
ret.m_cache.clear();
_i = min<unsigned>(_i, m_transactions.size());
if (!_i)
ret.m_state.setRoot(m_previousBlock.stateRoot);
else
ret.m_state.setRoot(m_receipts[_i - 1].stateRoot());
while (ret.m_transactions.size() > _i)
{
ret.m_transactionSet.erase(ret.m_transactions.back().sha3());
ret.m_transactions.pop_back();
ret.m_receipts.pop_back();
}
return ret;
}
void State::applyRewards(vector<BlockInfo> const& _uncleBlockHeaders)
{
u256 r = m_blockReward;
for (auto const& i: _uncleBlockHeaders)
{
addBalance(i.coinbaseAddress, m_blockReward * (8 + i.number - m_currentBlock.number) / 8);
r += m_blockReward / 32;
}
addBalance(m_currentBlock.coinbaseAddress, r);
}
std::ostream& dev::eth::operator<<(std::ostream& _out, State const& _s)
{
_out << "--- " << _s.rootHash() << std::endl;
std::set<Address> d;
std::set<Address> dtr;
auto trie = SecureTrieDB<Address, OverlayDB>(const_cast<OverlayDB*>(&_s.m_db), _s.rootHash());
for (auto i: trie)
d.insert(i.first), dtr.insert(i.first);
for (auto i: _s.m_cache)
d.insert(i.first);
for (auto i: d)
{
auto it = _s.m_cache.find(i);
Account* cache = it != _s.m_cache.end() ? &it->second : nullptr;
string rlpString = dtr.count(i) ? trie.at(i) : "";
RLP r(rlpString);
assert(cache || r);
if (cache && !cache->isAlive())
_out << "XXX " << i << std::endl;
else
{
string lead = (cache ? r ? " * " : " + " : " ");
if (cache && r && cache->nonce() == r[0].toInt<u256>() && cache->balance() == r[1].toInt<u256>())
lead = " . ";
stringstream contout;
if ((cache && cache->codeBearing()) || (!cache && r && (h256)r[3] != EmptySHA3))
{
std::map<u256, u256> mem;
std::set<u256> back;
std::set<u256> delta;
std::set<u256> cached;
if (r)
{
SecureTrieDB<h256, OverlayDB> memdb(const_cast<OverlayDB*>(&_s.m_db), r[2].toHash<h256>()); // promise we won't alter the overlay! :)
for (auto const& j: memdb)
mem[j.first] = RLP(j.second).toInt<u256>(), back.insert(j.first);
}
if (cache)
for (auto const& j: cache->storageOverlay())
{
if ((!mem.count(j.first) && j.second) || (mem.count(j.first) && mem.at(j.first) != j.second))
mem[j.first] = j.second, delta.insert(j.first);
else if (j.second)
cached.insert(j.first);
}
if (!delta.empty())
lead = (lead == " . ") ? "*.* " : "*** ";
contout << " @:";
if (!delta.empty())
contout << "???";
else
contout << r[2].toHash<h256>();
if (cache && cache->isFreshCode())
contout << " $" << toHex(cache->code());
else
contout << " $" << (cache ? cache->codeHash() : r[3].toHash<h256>());
for (auto const& j: mem)
if (j.second)
contout << std::endl << (delta.count(j.first) ? back.count(j.first) ? " * " : " + " : cached.count(j.first) ? " . " : " ") << std::hex << nouppercase << std::setw(64) << j.first << ": " << std::setw(0) << j.second ;
else
contout << std::endl << "XXX " << std::hex << nouppercase << std::setw(64) << j.first << "";
}
else
contout << " [SIMPLE]";
_out << lead << i << ": " << std::dec << (cache ? cache->nonce() : r[0].toInt<u256>()) << " #:" << (cache ? cache->balance() : r[1].toInt<u256>()) << contout.str() << std::endl;
}
}
return _out;
}