/*
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 main.cpp
* @ author Gav Wood < i @ gavwood . com >
* @ date 2014
* Ethereum client .
*/
# if ETH_ETHASHCL
# define __CL_ENABLE_EXCEPTIONS
# define CL_USE_DEPRECATED_OPENCL_2_0_APIS
# if defined(__clang__)
# pragma clang diagnostic push
# pragma clang diagnostic ignored "-Wunused-parameter"
# include <libethash-cl/cl.hpp>
# pragma clang diagnostic pop
# else
# include <libethash-cl/cl.hpp>
# endif
# endif
# include <functional>
# include <boost/filesystem.hpp>
# include <boost/algorithm/string.hpp>
# include <libdevcore/RangeMask.h>
# include <libdevcore/Log.h>
# include <libdevcore/Common.h>
# include <libdevcore/CommonData.h>
# include <libdevcore/RLP.h>
# include <libdevcore/TransientDirectory.h>
# include <libdevcore/CommonIO.h>
# include <libdevcrypto/TrieDB.h>
# include <libp2p/All.h>
# include <libethcore/ProofOfWork.h>
# include <libdevcrypto/FileSystem.h>
# include <libethereum/All.h>
# include <libethereum/Farm.h>
# include <libethereum/AccountDiff.h>
# include <libethereum/DownloadMan.h>
# include <libethereum/Client.h>
# include <liblll/All.h>
# include <libwhisper/WhisperPeer.h>
# include <libwhisper/WhisperHost.h>
# include <test/JsonSpiritHeaders.h>
using namespace std ;
using namespace dev ;
using namespace dev : : eth ;
using namespace dev : : p2p ;
using namespace dev : : shh ;
namespace js = json_spirit ;
namespace fs = boost : : filesystem ;
# if 1
inline h128 fromUUID ( std : : string const & _uuid ) { return h128 ( boost : : replace_all_copy ( _uuid , " - " , " " ) ) ; }
class KeyManager : public Worker
{
public :
KeyManager ( ) { readKeys ( ) ; }
~ KeyManager ( ) { }
Secret secret ( h128 const & _uuid , std : : string const & _pass )
{
auto it = m_keys . find ( _uuid ) ;
if ( it = = m_keys . end ( ) )
return Secret ( ) ;
return Secret ( decrypt ( it - > second , _pass ) ) ;
}
private :
void readKeys ( std : : string const & _keysPath = getDataDir ( " web3 " ) + " /keys " )
{
fs : : path p ( _keysPath ) ;
js : : mValue v ;
for ( fs : : directory_iterator it ( p ) ; it ! = fs : : directory_iterator ( ) ; + + it )
if ( is_regular_file ( it - > path ( ) ) )
{
cdebug < < " Reading " < < it - > path ( ) ;
js : : read_string ( contentsString ( it - > path ( ) . string ( ) ) , v ) ;
js : : mObject o = v . get_obj ( ) ;
int version = o . count ( " Version " ) ? stoi ( o [ " Version " ] . get_str ( ) ) : o . count ( " version " ) ? o [ " version " ] . get_int ( ) : 0 ;
if ( version = = 2 )
m_keys [ fromUUID ( o [ " id " ] . get_str ( ) ) ] = o [ " crypto " ] ;
else
cwarn < < " Cannot read key version " < < version ;
}
}
static bytes decrypt ( js : : mValue const & _v , std : : string const & _pass )
{
js : : mObject o = _v . get_obj ( ) ;
bytes pKey ;
if ( o [ " kdf " ] . get_str ( ) = = " pbkdf2 " )
{
auto params = o [ " kdfparams " ] . get_obj ( ) ;
unsigned iterations = params [ " c " ] . get_int ( ) ;
bytes salt = fromHex ( params [ " salt " ] . get_str ( ) ) ;
pKey = pbkdf2 ( _pass , salt , iterations ) . asBytes ( ) ;
}
else
{
cwarn < < " Unknown KDF " < < o [ " kdf " ] . get_str ( ) < < " not supported. " ;
return bytes ( ) ;
}
// TODO check MAC
h256 mac ( o [ " mac " ] . get_str ( ) ) ;
( void ) mac ;
bytes cipherText = fromHex ( o [ " ciphertext " ] . get_str ( ) ) ;
bytes ret ;
if ( o [ " cipher " ] . get_str ( ) = = " aes-128-cbc " )
{
auto params = o [ " cipherparams " ] . get_obj ( ) ;
h128 key ( sha3 ( h128 ( pKey , h128 : : AlignRight ) ) , h128 : : AlignRight ) ;
h128 iv ( params [ " iv " ] . get_str ( ) ) ;
decryptSymNoAuth ( key , iv , & cipherText , ret ) ;
}
else
{
cwarn < < " Unknown cipher " < < o [ " cipher " ] . get_str ( ) < < " not supported. " ;
return bytes ( ) ;
}
return ret ;
}
std : : map < h128 , js : : mValue > m_keys ;
} ;
int main ( )
{
KeyManager keyman ;
cdebug < < " Secret key for 0498f19a-59db-4d54-ac95-33901b4f1870 is " < < keyman . secret ( fromUUID ( " 0498f19a-59db-4d54-ac95-33901b4f1870 " ) , " foo " ) ;
}
# elif 0
int main ( )
{
DownloadMan man ;
DownloadSub s0 ( man ) ;
DownloadSub s1 ( man ) ;
DownloadSub s2 ( man ) ;
man . resetToChain ( h256s ( { u256 ( 0 ) , u256 ( 1 ) , u256 ( 2 ) , u256 ( 3 ) , u256 ( 4 ) , u256 ( 5 ) , u256 ( 6 ) , u256 ( 7 ) , u256 ( 8 ) } ) ) ;
assert ( ( s0 . nextFetch ( 2 ) = = h256Set { ( u256 ) 7 , ( u256 ) 8 } ) ) ;
assert ( ( s1 . nextFetch ( 2 ) = = h256Set { ( u256 ) 5 , ( u256 ) 6 } ) ) ;
assert ( ( s2 . nextFetch ( 2 ) = = h256Set { ( u256 ) 3 , ( u256 ) 4 } ) ) ;
s0 . noteBlock ( u256 ( 8 ) ) ;
s0 . doneFetch ( ) ;
assert ( ( s0 . nextFetch ( 2 ) = = h256Set { ( u256 ) 2 , ( u256 ) 7 } ) ) ;
s1 . noteBlock ( u256 ( 6 ) ) ;
s1 . noteBlock ( u256 ( 5 ) ) ;
s1 . doneFetch ( ) ;
assert ( ( s1 . nextFetch ( 2 ) = = h256Set { ( u256 ) 0 , ( u256 ) 1 } ) ) ;
s0 . doneFetch ( ) ; // TODO: check exact semantics of doneFetch & nextFetch. Not sure if they're right -> doneFetch calls resetFetch which kills all the info of past fetches.
cdebug < < s0 . nextFetch ( 2 ) ;
assert ( ( s0 . nextFetch ( 2 ) = = h256Set { ( u256 ) 3 , ( u256 ) 4 } ) ) ;
/* RangeMask<unsigned> m(0, 100);
cnote < < m ;
m + = UnsignedRange ( 3 , 10 ) ;
cnote < < m ;
m + = UnsignedRange ( 11 , 16 ) ;
cnote < < m ;
m + = UnsignedRange ( 10 , 11 ) ;
cnote < < m ;
cnote < < ~ m ;
cnote < < ( ~ m ) . lowest ( 10 ) ;
for ( auto i : ( ~ m ) . lowest ( 10 ) )
cnote < < i ; */
return 0 ;
}
# elif 0
int main ( )
{
KeyPair u = KeyPair : : create ( ) ;
KeyPair cb = KeyPair : : create ( ) ;
OverlayDB db ;
State s ( cb . address ( ) , db , BaseState : : Empty ) ;
cnote < < s . rootHash ( ) ;
s . addBalance ( u . address ( ) , 1 * ether ) ;
Address c = s . newContract ( 1000 * ether , compileLLL ( " (suicide (caller)) " ) ) ;
s . commit ( ) ;
State before = s ;
cnote < < " State before transaction: " < < before ;
Transaction t ( 0 , 10000 , 10000 , c , bytes ( ) , 0 , u . secret ( ) ) ;
cnote < < " Transaction: " < < t ;
cnote < < s . balance ( c ) ;
s . execute ( LastHashes ( ) , t . rlp ( ) ) ;
cnote < < " State after transaction: " < < s ;
cnote < < before . diff ( s ) ;
}
# elif 0
int main ( )
{
GenericFarm < Ethash > f ;
BlockInfo genesis = CanonBlockChain : : genesis ( ) ;
genesis . difficulty = 1 < < 18 ;
cdebug < < genesis . boundary ( ) ;
auto mine = [ ] ( GenericFarm < Ethash > & f , BlockInfo const & g , unsigned timeout ) {
BlockInfo bi = g ;
bool completed = false ;
f . onSolutionFound ( [ & ] ( ProofOfWork : : Solution sol )
{
ProofOfWork : : assignResult ( sol , bi ) ;
return completed = true ;
} ) ;
f . setWork ( bi ) ;
for ( unsigned i = 0 ; ! completed & & i < timeout * 10 ; + + i , cout < < f . miningProgress ( ) < < " \r " < < flush )
this_thread : : sleep_for ( chrono : : milliseconds ( 100 ) ) ;
cout < < endl < < flush ;
cdebug < < bi . mixHash < < bi . nonce < < ( Ethash : : verify ( bi ) ? " GOOD " : " bad " ) ;
} ;
Ethash : : prep ( genesis ) ;
genesis . difficulty = u256 ( 1 ) < < 40 ;
genesis . noteDirty ( ) ;
f . startCPU ( ) ;
mine ( f , genesis , 10 ) ;
f . startGPU ( ) ;
cdebug < < " Good: " ;
genesis . difficulty = 1 < < 18 ;
genesis . noteDirty ( ) ;
mine ( f , genesis , 30 ) ;
cdebug < < " Bad: " ;
genesis . difficulty = ( u256 ( 1 ) < < 40 ) ;
genesis . noteDirty ( ) ;
mine ( f , genesis , 30 ) ;
f . stop ( ) ;
return 0 ;
}
# elif 0
void mine ( State & s , BlockChain const & _bc )
{
s . commitToMine ( _bc ) ;
GenericFarm < ProofOfWork > f ;
bool completed = false ;
f . onSolutionFound ( [ & ] ( ProofOfWork : : Solution sol )
{
return completed = s . completeMine < ProofOfWork > ( sol ) ;
} ) ;
f . setWork ( s . info ( ) ) ;
f . startCPU ( ) ;
while ( ! completed )
this_thread : : sleep_for ( chrono : : milliseconds ( 20 ) ) ;
}
# elif 0
int main ( )
{
cnote < < " Testing State... " ;
KeyPair me = sha3 ( " Gav Wood " ) ;
KeyPair myMiner = sha3 ( " Gav's Miner " ) ;
// KeyPair you = sha3("123");
Defaults : : setDBPath ( boost : : filesystem : : temp_directory_path ( ) . string ( ) + " / " + toString ( chrono : : system_clock : : now ( ) . time_since_epoch ( ) . count ( ) ) ) ;
OverlayDB stateDB = State : : openDB ( ) ;
CanonBlockChain bc ;
cout < < bc ;
State s ( stateDB , BaseState : : CanonGenesis , myMiner . address ( ) ) ;
cout < < s ;
// Sync up - this won't do much until we use the last state.
s . sync ( bc ) ;
cout < < s ;
// Mine to get some ether!
mine ( s , bc ) ;
bc . attemptImport ( s . blockData ( ) , stateDB ) ;
cout < < bc ;
s . sync ( bc ) ;
cout < < s ;
// Inject a transaction to transfer funds from miner to me.
Transaction t ( 1000 , 10000 , 30000 , me . address ( ) , bytes ( ) , s . transactionsFrom ( myMiner . address ( ) ) , myMiner . secret ( ) ) ;
assert ( t . sender ( ) = = myMiner . address ( ) ) ;
s . execute ( bc . lastHashes ( ) , t ) ;
cout < < s ;
// Mine to get some ether and set in stone.
s . commitToMine ( bc ) ;
s . commitToMine ( bc ) ;
mine ( s , bc ) ;
bc . attemptImport ( s . blockData ( ) , stateDB ) ;
cout < < bc ;
s . sync ( bc ) ;
cout < < s ;
return 0 ;
}
# else
int main ( )
{
string tempDir = boost : : filesystem : : temp_directory_path ( ) . string ( ) + " / " + toString ( chrono : : system_clock : : now ( ) . time_since_epoch ( ) . count ( ) ) ;
KeyPair myMiner = sha3 ( " Gav's Miner " ) ;
p2p : : Host net ( " Test " ) ;
cdebug < < " Path: " < < tempDir ;
Client c ( & net , tempDir ) ;
c . setAddress ( myMiner . address ( ) ) ;
this_thread : : sleep_for ( chrono : : milliseconds ( 1000 ) ) ;
c . startMining ( ) ;
this_thread : : sleep_for ( chrono : : milliseconds ( 6000 ) ) ;
c . stopMining ( ) ;
return 0 ;
}
# endif
