/*
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 = c_network = = Network : : Olympic ? ( 1500 * finney ) : ( 5 * ether ) ;
const char * StateSafeExceptions : : name ( ) { return EthViolet " ⚙ " EthBlue " ℹ " ; }
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 ) ;
}
PopulationStatistics State : : populateFromChain ( BlockChain const & _bc , h256 const & _h , ImportRequirements : : value _ir )
{
PopulationStatistics ret ;
if ( ! _bc . isKnown ( _h ) )
{
// Might be worth throwing here.
cwarn < < " Invalid block given for state population: " < < _h ;
return ret ;
}
auto b = _bc . block ( _h ) ;
BlockInfo bi ( b ) ;
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 ;
boost : : timer t ;
auto vb = BlockChain : : verifyBlock ( b ) ;
ret . verify = t . elapsed ( ) ;
t . restart ( ) ;
enact ( vb , _bc , _ir ) ;
ret . enact = t . elapsed ( ) ;
}
else
{
// Genesis required:
// We know there are no transactions, so just populate directly.
m_state . init ( ) ;
sync ( _bc , _h , bi , _ir ) ;
}
return ret ;
}
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_touched ( _s . m_touched ) ,
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 , bool _quick ) 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 ( ) ) ;
if ( _quick )
{
trieAds = m_touched ;
trieAdsD = _c . m_touched ;
( ads + = m_touched ) + = _c . m_touched ;
}
else
{
for ( auto const & i : trie )
ads . insert ( i . first ) , trieAds . insert ( i . first ) ;
for ( auto const & i : trieD )
ads . insert ( i . first ) , trieAdsD . insert ( i . first ) ;
}
for ( auto const & i : m_cache )
ads . insert ( i . first ) ;
for ( auto const & i : _c . m_cache )
ads . insert ( i . first ) ;
// cnote << *this;
// cnote << _c;
for ( auto const & 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 ( )
{
m_touched + = 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 ( VerifiedBlockRef const & _block , 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 ( _block . info . parentHash ) ;
_block . info . 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 , _block . info . 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_touched . 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 ;
string ret ;
unsigned i = 0 ;
for ( auto const & tr : rlp [ 1 ] )
{
StandardTrace st ;
st . setShowMnemonics ( ) ;
execute ( lh , Transaction ( tr . data ( ) , CheckTransaction : : Everything ) , Permanence : : Committed , st . onOp ( ) ) ;
ret + = ( ret . empty ( ) ? " [ " : " , " ) + st . json ( ) ;
RLPStream receiptRLP ;
m_receipts . back ( ) . streamRLP ( receiptRLP ) ;
receipts . push_back ( receiptRLP . out ( ) ) ;
+ + i ;
}
return ret . empty ( ) ? " [] " : ( ret + " ] " ) ;
}
u256 State : : enact ( VerifiedBlockRef const & _block , BlockChain const & _bc , ImportRequirements : : value _ir )
{
DEV_TIMED_FUNCTION_ABOVE ( 500 ) ;
// m_currentBlock is assumed to be prepopulated and reset.
# if !ETH_RELEASE
assert ( m_previousBlock . hash ( ) = = _block . info . parentHash ) ;
assert ( m_currentBlock . parentHash = = _block . info . parentHash ) ;
assert ( rootHash ( ) = = m_previousBlock . stateRoot ) ;
# endif
if ( m_currentBlock . parentHash ! = m_previousBlock . hash ( ) )
// Internal client error.
BOOST_THROW_EXCEPTION ( InvalidParentHash ( ) ) ;
// Populate m_currentBlock with the correct values.
m_currentBlock = _block . info ;
m_currentBlock . noteDirty ( ) ;
// cnote << "playback begins:" << m_state.root();
// cnote << m_state;
LastHashes lh ;
DEV_TIMED_ABOVE ( lastHashes , 500 )
lh = _bc . lastHashes ( ( unsigned ) m_previousBlock . number ) ;
RLP rlp ( _block . block ) ;
vector < bytes > receipts ;
// All ok with the block generally. Play back the transactions now...
unsigned i = 0 ;
DEV_TIMED_ABOVE ( txEcec , 500 )
for ( auto const & tr : _block . transactions )
{
try
{
LogOverride < ExecutiveWarnChannel > o ( false ) ;
execute ( lh , tr ) ;
}
catch ( Exception & ex )
{
ex < < errinfo_transactionIndex ( i ) ;
throw ;
}
RLPStream receiptRLP ;
m_receipts . back ( ) . streamRLP ( receiptRLP ) ;
receipts . push_back ( receiptRLP . out ( ) ) ;
+ + i ;
}
h256 receiptsRoot ;
DEV_TIMED_ABOVE ( receiptsRoot , 500 )
receiptsRoot = orderedTrieRoot ( receipts ) ;
if ( receiptsRoot ! = m_currentBlock . receiptsRoot )
{
InvalidReceiptsStateRoot ex ;
ex < < Hash256RequirementError ( receiptsRoot , m_currentBlock . receiptsRoot ) ;
ex < < errinfo_receipts ( receipts ) ;
ex < < errinfo_vmtrace ( vmTrace ( _block . block , _bc , _ir ) ) ;
BOOST_THROW_EXCEPTION ( ex ) ;
}
if ( m_currentBlock . logBloom ! = logBloom ( ) )
{
InvalidLogBloom ex ;
ex < < LogBloomRequirementError ( logBloom ( ) , m_currentBlock . logBloom ) ;
ex < < errinfo_receipts ( receipts ) ;
BOOST_THROW_EXCEPTION ( ex ) ;
}
// Initialise total difficulty calculation.
u256 tdIncrease = m_currentBlock . difficulty ;
// Check uncles & apply their rewards to state.
if ( rlp [ 2 ] . itemCount ( ) > 2 )
{
TooManyUncles ex ;
ex < < errinfo_max ( 2 ) ;
ex < < errinfo_got ( rlp [ 2 ] . itemCount ( ) ) ;
BOOST_THROW_EXCEPTION ( ex ) ;
}
vector < BlockInfo > rewarded ;
h256Hash excluded ;
DEV_TIMED_ABOVE ( allKin , 500 )
excluded = _bc . allKinFrom ( m_currentBlock . parentHash , 6 ) ;
excluded . insert ( m_currentBlock . hash ( ) ) ;
unsigned ii = 0 ;
DEV_TIMED_ABOVE ( uncleCheck , 500 )
for ( auto const & i : rlp [ 2 ] )
{
try
{
auto h = sha3 ( i . data ( ) ) ;
if ( excluded . count ( h ) )
{
UncleInChain ex ;
ex < < errinfo_comment ( " Uncle in block already mentioned " ) ;
ex < < errinfo_unclesExcluded ( excluded ) ;
ex < < errinfo_hash256 ( sha3 ( i . data ( ) ) ) ;
BOOST_THROW_EXCEPTION ( ex ) ;
}
excluded . insert ( h ) ;
BlockInfo uncle = BlockInfo : : fromHeader ( i . data ( ) , ( _ir & ImportRequirements : : CheckUncles ) ? CheckEverything : IgnoreNonce , h ) ;
BlockInfo uncleParent ;
if ( ! _bc . isKnown ( uncle . parentHash ) )
BOOST_THROW_EXCEPTION ( UnknownParent ( ) ) ;
uncleParent = BlockInfo ( _bc . block ( uncle . parentHash ) ) ;
if ( ( bigint ) uncleParent . number < ( bigint ) m_currentBlock . number - 7 )
{
UncleTooOld ex ;
ex < < errinfo_uncleNumber ( uncle . number ) ;
ex < < errinfo_currentNumber ( m_currentBlock . number ) ;
BOOST_THROW_EXCEPTION ( ex ) ;
}
else if ( uncle . number = = m_currentBlock . number )
{
UncleIsBrother ex ;
ex < < errinfo_uncleNumber ( uncle . number ) ;
ex < < errinfo_currentNumber ( m_currentBlock . number ) ;
BOOST_THROW_EXCEPTION ( ex ) ;
}
uncle . verifyParent ( uncleParent ) ;
rewarded . push_back ( uncle ) ;
+ + ii ;
}
catch ( Exception & ex )
{
ex < < errinfo_uncleIndex ( ii ) ;
throw ;
}
}
DEV_TIMED_ABOVE ( applyRewards , 500 )
applyRewards ( rewarded ) ;
// Commit all cached state changes to the state trie.
DEV_TIMED_ABOVE ( commit , 500 )
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 ( ) )
{
m_db . rollback ( ) ;
BOOST_THROW_EXCEPTION ( InvalidStateRoot ( ) < < Hash256RequirementError ( rootHash ( ) , m_currentBlock . stateRoot ) ) ;
}
if ( m_currentBlock . gasUsed ! = gasUsed ( ) )
{
// Rollback the trie.
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.
if ( isChannelVisible < StateTrace > ( ) ) // Avoid calling toHex if not needed
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 ( ) ;
if ( isChannelVisible < StateTrace > ( ) ) // Avoid calling toHex if not needed
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 ( BlockChain : : verifyBlock ( 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 ;
if ( m_cache [ _contract ] . isFreshCode ( ) )
return sha3 ( code ( _contract ) ) ;
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 ;
}
# define ETH_VMTIMER 1
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 ) ;
ExecutionResult res ;
e . setResultRecipient ( res ) ;
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
{
if ( isChannelVisible < VMTraceChannel > ( ) )
e . go ( e . simpleTrace ( ) ) ;
else
e . go ( _onOp ) ;
}
# 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 res ;
}
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 ;
}