// Copyright (c) 2009-2010 Satoshi Nakamoto
// Distributed under the MIT/X11 software license, see the accompanying
// file license.txt or http://www.opensource.org/licenses/mit-license.php.
# include "headers.h"
# include "cryptopp/sha.h"
//
// Global state
//
CCriticalSection cs_main ;
map < uint256 , CTransaction > mapTransactions ;
CCriticalSection cs_mapTransactions ;
unsigned int nTransactionsUpdated = 0 ;
map < COutPoint , CInPoint > mapNextTx ;
map < uint256 , CBlockIndex * > mapBlockIndex ;
uint256 hashGenesisBlock ( " 0x000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f " ) ;
CBigNum bnProofOfWorkLimit ( ~ uint256 ( 0 ) > > 32 ) ;
CBlockIndex * pindexGenesisBlock = NULL ;
int nBestHeight = - 1 ;
CBigNum bnBestChainWork = 0 ;
CBigNum bnBestInvalidWork = 0 ;
uint256 hashBestChain = 0 ;
CBlockIndex * pindexBest = NULL ;
int64 nTimeBestReceived = 0 ;
map < uint256 , CBlock * > mapOrphanBlocks ;
multimap < uint256 , CBlock * > mapOrphanBlocksByPrev ;
map < uint256 , CDataStream * > mapOrphanTransactions ;
multimap < uint256 , CDataStream * > mapOrphanTransactionsByPrev ;
map < uint256 , CWalletTx > mapWallet ;
vector < uint256 > vWalletUpdated ;
CCriticalSection cs_mapWallet ;
map < vector < unsigned char > , CPrivKey > mapKeys ;
map < uint160 , vector < unsigned char > > mapPubKeys ;
CCriticalSection cs_mapKeys ;
CKey keyUser ;
map < uint256 , int > mapRequestCount ;
CCriticalSection cs_mapRequestCount ;
map < string , string > mapAddressBook ;
CCriticalSection cs_mapAddressBook ;
vector < unsigned char > vchDefaultKey ;
double dHashesPerSec ;
int64 nHPSTimerStart ;
// Settings
int fGenerateBitcoins = false ;
int64 nTransactionFee = 0 ;
CAddress addrIncoming ;
int fLimitProcessors = false ;
int nLimitProcessors = 1 ;
int fMinimizeToTray = true ;
int fMinimizeOnClose = true ;
//////////////////////////////////////////////////////////////////////////////
//
// mapKeys
//
bool AddKey ( const CKey & key )
{
CRITICAL_BLOCK ( cs_mapKeys )
{
mapKeys [ key . GetPubKey ( ) ] = key . GetPrivKey ( ) ;
mapPubKeys [ Hash160 ( key . GetPubKey ( ) ) ] = key . GetPubKey ( ) ;
}
return CWalletDB ( ) . WriteKey ( key . GetPubKey ( ) , key . GetPrivKey ( ) ) ;
}
vector < unsigned char > GenerateNewKey ( )
{
RandAddSeedPerfmon ( ) ;
CKey key ;
key . MakeNewKey ( ) ;
if ( ! AddKey ( key ) )
throw runtime_error ( " GenerateNewKey() : AddKey failed " ) ;
return key . GetPubKey ( ) ;
}
//////////////////////////////////////////////////////////////////////////////
//
// mapWallet
//
bool AddToWallet ( const CWalletTx & wtxIn )
{
uint256 hash = wtxIn . GetHash ( ) ;
CRITICAL_BLOCK ( cs_mapWallet )
{
// Inserts only if not already there, returns tx inserted or tx found
pair < map < uint256 , CWalletTx > : : iterator , bool > ret = mapWallet . insert ( make_pair ( hash , wtxIn ) ) ;
CWalletTx & wtx = ( * ret . first ) . second ;
bool fInsertedNew = ret . second ;
if ( fInsertedNew )
wtx . nTimeReceived = GetAdjustedTime ( ) ;
bool fUpdated = false ;
if ( ! fInsertedNew )
{
// Merge
if ( wtxIn . hashBlock ! = 0 & & wtxIn . hashBlock ! = wtx . hashBlock )
{
wtx . hashBlock = wtxIn . hashBlock ;
fUpdated = true ;
}
if ( wtxIn . nIndex ! = - 1 & & ( wtxIn . vMerkleBranch ! = wtx . vMerkleBranch | | wtxIn . nIndex ! = wtx . nIndex ) )
{
wtx . vMerkleBranch = wtxIn . vMerkleBranch ;
wtx . nIndex = wtxIn . nIndex ;
fUpdated = true ;
}
if ( wtxIn . fFromMe & & wtxIn . fFromMe ! = wtx . fFromMe )
{
wtx . fFromMe = wtxIn . fFromMe ;
fUpdated = true ;
}
if ( wtxIn . fSpent & & wtxIn . fSpent ! = wtx . fSpent )
{
wtx . fSpent = wtxIn . fSpent ;
fUpdated = true ;
}
}
//// debug print
printf ( " AddToWallet %s %s%s \n " , wtxIn . GetHash ( ) . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) , ( fInsertedNew ? " new " : " " ) , ( fUpdated ? " update " : " " ) ) ;
// Write to disk
if ( fInsertedNew | | fUpdated )
if ( ! wtx . WriteToDisk ( ) )
return false ;
// If default receiving address gets used, replace it with a new one
CScript scriptDefaultKey ;
scriptDefaultKey . SetBitcoinAddress ( vchDefaultKey ) ;
foreach ( const CTxOut & txout , wtx . vout )
{
if ( txout . scriptPubKey = = scriptDefaultKey )
{
CWalletDB walletdb ;
vchDefaultKey = GetKeyFromKeyPool ( ) ;
walletdb . WriteDefaultKey ( vchDefaultKey ) ;
walletdb . WriteName ( PubKeyToAddress ( vchDefaultKey ) , " " ) ;
}
}
// Notify UI
vWalletUpdated . push_back ( hash ) ;
}
// Refresh UI
MainFrameRepaint ( ) ;
return true ;
}
bool AddToWalletIfMine ( const CTransaction & tx , const CBlock * pblock )
{
if ( tx . IsMine ( ) | | mapWallet . count ( tx . GetHash ( ) ) )
{
CWalletTx wtx ( tx ) ;
// Get merkle branch if transaction was found in a block
if ( pblock )
wtx . SetMerkleBranch ( pblock ) ;
return AddToWallet ( wtx ) ;
}
return true ;
}
bool AddToWalletIfFromMe ( const CTransaction & tx , const CBlock * pblock )
{
if ( tx . IsFromMe ( ) | | mapWallet . count ( tx . GetHash ( ) ) )
{
CWalletTx wtx ( tx ) ;
// Get merkle branch if transaction was found in a block
if ( pblock )
wtx . SetMerkleBranch ( pblock ) ;
return AddToWallet ( wtx ) ;
}
return true ;
}
bool EraseFromWallet ( uint256 hash )
{
CRITICAL_BLOCK ( cs_mapWallet )
{
if ( mapWallet . erase ( hash ) )
CWalletDB ( ) . EraseTx ( hash ) ;
}
return true ;
}
void WalletUpdateSpent ( const COutPoint & prevout )
{
// Anytime a signature is successfully verified, it's proof the outpoint is spent.
// Update the wallet spent flag if it doesn't know due to wallet.dat being
// restored from backup or the user making copies of wallet.dat.
CRITICAL_BLOCK ( cs_mapWallet )
{
map < uint256 , CWalletTx > : : iterator mi = mapWallet . find ( prevout . hash ) ;
if ( mi ! = mapWallet . end ( ) )
{
CWalletTx & wtx = ( * mi ) . second ;
if ( ! wtx . fSpent & & wtx . vout [ prevout . n ] . IsMine ( ) )
{
printf ( " WalletUpdateSpent found spent coin %sbc %s \n " , FormatMoney ( wtx . GetCredit ( ) ) . c_str ( ) , wtx . GetHash ( ) . ToString ( ) . c_str ( ) ) ;
wtx . fSpent = true ;
wtx . WriteToDisk ( ) ;
vWalletUpdated . push_back ( prevout . hash ) ;
}
}
}
}
//////////////////////////////////////////////////////////////////////////////
//
// mapOrphanTransactions
//
void AddOrphanTx ( const CDataStream & vMsg )
{
CTransaction tx ;
CDataStream ( vMsg ) > > tx ;
uint256 hash = tx . GetHash ( ) ;
if ( mapOrphanTransactions . count ( hash ) )
return ;
CDataStream * pvMsg = mapOrphanTransactions [ hash ] = new CDataStream ( vMsg ) ;
foreach ( const CTxIn & txin , tx . vin )
mapOrphanTransactionsByPrev . insert ( make_pair ( txin . prevout . hash , pvMsg ) ) ;
}
void EraseOrphanTx ( uint256 hash )
{
if ( ! mapOrphanTransactions . count ( hash ) )
return ;
const CDataStream * pvMsg = mapOrphanTransactions [ hash ] ;
CTransaction tx ;
CDataStream ( * pvMsg ) > > tx ;
foreach ( const CTxIn & txin , tx . vin )
{
for ( multimap < uint256 , CDataStream * > : : iterator mi = mapOrphanTransactionsByPrev . lower_bound ( txin . prevout . hash ) ;
mi ! = mapOrphanTransactionsByPrev . upper_bound ( txin . prevout . hash ) ; )
{
if ( ( * mi ) . second = = pvMsg )
mapOrphanTransactionsByPrev . erase ( mi + + ) ;
else
mi + + ;
}
}
delete pvMsg ;
mapOrphanTransactions . erase ( hash ) ;
}
//////////////////////////////////////////////////////////////////////////////
//
// CTransaction and CTxIndex
//
bool CTransaction : : ReadFromDisk ( CTxDB & txdb , COutPoint prevout , CTxIndex & txindexRet )
{
SetNull ( ) ;
if ( ! txdb . ReadTxIndex ( prevout . hash , txindexRet ) )
return false ;
if ( ! ReadFromDisk ( txindexRet . pos ) )
return false ;
if ( prevout . n > = vout . size ( ) )
{
SetNull ( ) ;
return false ;
}
return true ;
}
bool CTransaction : : ReadFromDisk ( CTxDB & txdb , COutPoint prevout )
{
CTxIndex txindex ;
return ReadFromDisk ( txdb , prevout , txindex ) ;
}
bool CTransaction : : ReadFromDisk ( COutPoint prevout )
{
CTxDB txdb ( " r " ) ;
CTxIndex txindex ;
return ReadFromDisk ( txdb , prevout , txindex ) ;
}
bool CTxIn : : IsMine ( ) const
{
CRITICAL_BLOCK ( cs_mapWallet )
{
map < uint256 , CWalletTx > : : iterator mi = mapWallet . find ( prevout . hash ) ;
if ( mi ! = mapWallet . end ( ) )
{
const CWalletTx & prev = ( * mi ) . second ;
if ( prevout . n < prev . vout . size ( ) )
if ( prev . vout [ prevout . n ] . IsMine ( ) )
return true ;
}
}
return false ;
}
int64 CTxIn : : GetDebit ( ) const
{
CRITICAL_BLOCK ( cs_mapWallet )
{
map < uint256 , CWalletTx > : : iterator mi = mapWallet . find ( prevout . hash ) ;
if ( mi ! = mapWallet . end ( ) )
{
const CWalletTx & prev = ( * mi ) . second ;
if ( prevout . n < prev . vout . size ( ) )
if ( prev . vout [ prevout . n ] . IsMine ( ) )
return prev . vout [ prevout . n ] . nValue ;
}
}
return 0 ;
}
int64 CWalletTx : : GetTxTime ( ) const
{
if ( ! fTimeReceivedIsTxTime & & hashBlock ! = 0 )
{
// If we did not receive the transaction directly, we rely on the block's
// time to figure out when it happened. We use the median over a range
// of blocks to try to filter out inaccurate block times.
map < uint256 , CBlockIndex * > : : iterator mi = mapBlockIndex . find ( hashBlock ) ;
if ( mi ! = mapBlockIndex . end ( ) )
{
CBlockIndex * pindex = ( * mi ) . second ;
if ( pindex )
return pindex - > GetMedianTime ( ) ;
}
}
return nTimeReceived ;
}
int CWalletTx : : GetRequestCount ( ) const
{
// Returns -1 if it wasn't being tracked
int nRequests = - 1 ;
CRITICAL_BLOCK ( cs_mapRequestCount )
{
if ( IsCoinBase ( ) )
{
// Generated block
if ( hashBlock ! = 0 )
{
map < uint256 , int > : : iterator mi = mapRequestCount . find ( hashBlock ) ;
if ( mi ! = mapRequestCount . end ( ) )
nRequests = ( * mi ) . second ;
}
}
else
{
// Did anyone request this transaction?
map < uint256 , int > : : iterator mi = mapRequestCount . find ( GetHash ( ) ) ;
if ( mi ! = mapRequestCount . end ( ) )
{
nRequests = ( * mi ) . second ;
// How about the block it's in?
if ( nRequests = = 0 & & hashBlock ! = 0 )
{
map < uint256 , int > : : iterator mi = mapRequestCount . find ( hashBlock ) ;
if ( mi ! = mapRequestCount . end ( ) )
nRequests = ( * mi ) . second ;
else
nRequests = 1 ; // If it's in someone else's block it must have got out
}
}
}
}
return nRequests ;
}
void CWalletTx : : GetAmounts ( int64 & nGenerated , list < pair < string , int64 > > & listReceived ,
list < pair < string , int64 > > & listSent , int64 & nFee , string & strSentAccount ) const
{
nGenerated = nFee = 0 ;
listReceived . clear ( ) ;
listSent . clear ( ) ;
strSentAccount = strFromAccount ;
if ( IsCoinBase ( ) )
{
if ( GetDepthInMainChain ( ) > = COINBASE_MATURITY )
nGenerated = GetCredit ( ) ;
return ;
}
// Compute fee:
int64 nDebit = GetDebit ( ) ;
if ( nDebit > 0 ) // debit>0 means we signed/sent this transaction
{
int64 nValueOut = GetValueOut ( ) ;
nFee = nDebit - nValueOut ;
}
// Sent/received. Standard client will never generate a send-to-multiple-recipients,
// but non-standard clients might (so return a list of address/amount pairs)
foreach ( const CTxOut & txout , vout )
{
string address ;
uint160 hash160 ;
vector < unsigned char > vchPubKey ;
if ( ExtractHash160 ( txout . scriptPubKey , hash160 ) )
address = Hash160ToAddress ( hash160 ) ;
else if ( ExtractPubKey ( txout . scriptPubKey , false , vchPubKey ) )
address = PubKeyToAddress ( vchPubKey ) ;
else
{
printf ( " CWalletTx::GetAmounts: Unknown transaction type found, txid %s \n " ,
this - > GetHash ( ) . ToString ( ) . c_str ( ) ) ;
address = " unknown " ;
}
// Don't report 'change' txouts
if ( nDebit > 0 & & txout . IsChange ( ) )
continue ;
if ( nDebit > 0 )
listSent . push_back ( make_pair ( address , txout . nValue ) ) ;
if ( txout . IsMine ( ) )
listReceived . push_back ( make_pair ( address , txout . nValue ) ) ;
}
}
void CWalletTx : : GetAccountAmounts ( const string & strAccount , int64 & nGenerated , int64 & nReceived ,
int64 & nSent , int64 & nFee ) const
{
nGenerated = nReceived = nSent = nFee = 0 ;
int64 allGenerated , allFee ;
allGenerated = allFee = 0 ;
string strSentAccount ;
list < pair < string , int64 > > listReceived ;
list < pair < string , int64 > > listSent ;
GetAmounts ( allGenerated , listReceived , listSent , allFee , strSentAccount ) ;
if ( strAccount = = " " )
nGenerated = allGenerated ;
if ( strAccount = = strSentAccount )
{
foreach ( const PAIRTYPE ( string , int64 ) & s , listSent )
nSent + = s . second ;
nFee = allFee ;
}
CRITICAL_BLOCK ( cs_mapAddressBook )
{
foreach ( const PAIRTYPE ( string , int64 ) & r , listReceived )
{
if ( mapAddressBook . count ( r . first ) )
{
if ( mapAddressBook [ r . first ] = = strAccount )
{
nReceived + = r . second ;
}
}
else if ( strAccount . empty ( ) )
{
nReceived + = r . second ;
}
}
}
}
int CMerkleTx : : SetMerkleBranch ( const CBlock * pblock )
{
if ( fClient )
{
if ( hashBlock = = 0 )
return 0 ;
}
else
{
CBlock blockTmp ;
if ( pblock = = NULL )
{
// Load the block this tx is in
CTxIndex txindex ;
if ( ! CTxDB ( " r " ) . ReadTxIndex ( GetHash ( ) , txindex ) )
return 0 ;
if ( ! blockTmp . ReadFromDisk ( txindex . pos . nFile , txindex . pos . nBlockPos ) )
return 0 ;
pblock = & blockTmp ;
}
// Update the tx's hashBlock
hashBlock = pblock - > GetHash ( ) ;
// Locate the transaction
for ( nIndex = 0 ; nIndex < pblock - > vtx . size ( ) ; nIndex + + )
if ( pblock - > vtx [ nIndex ] = = * ( CTransaction * ) this )
break ;
if ( nIndex = = pblock - > vtx . size ( ) )
{
vMerkleBranch . clear ( ) ;
nIndex = - 1 ;
printf ( " ERROR: SetMerkleBranch() : couldn't find tx in block \n " ) ;
return 0 ;
}
// Fill in merkle branch
vMerkleBranch = pblock - > GetMerkleBranch ( nIndex ) ;
}
// Is the tx in a block that's in the main chain
map < uint256 , CBlockIndex * > : : iterator mi = mapBlockIndex . find ( hashBlock ) ;
if ( mi = = mapBlockIndex . end ( ) )
return 0 ;
CBlockIndex * pindex = ( * mi ) . second ;
if ( ! pindex | | ! pindex - > IsInMainChain ( ) )
return 0 ;
return pindexBest - > nHeight - pindex - > nHeight + 1 ;
}
void CWalletTx : : AddSupportingTransactions ( CTxDB & txdb )
{
vtxPrev . clear ( ) ;
const int COPY_DEPTH = 3 ;
if ( SetMerkleBranch ( ) < COPY_DEPTH )
{
vector < uint256 > vWorkQueue ;
foreach ( const CTxIn & txin , vin )
vWorkQueue . push_back ( txin . prevout . hash ) ;
// This critsect is OK because txdb is already open
CRITICAL_BLOCK ( cs_mapWallet )
{
map < uint256 , const CMerkleTx * > mapWalletPrev ;
set < uint256 > setAlreadyDone ;
for ( int i = 0 ; i < vWorkQueue . size ( ) ; i + + )
{
uint256 hash = vWorkQueue [ i ] ;
if ( setAlreadyDone . count ( hash ) )
continue ;
setAlreadyDone . insert ( hash ) ;
CMerkleTx tx ;
if ( mapWallet . count ( hash ) )
{
tx = mapWallet [ hash ] ;
foreach ( const CMerkleTx & txWalletPrev , mapWallet [ hash ] . vtxPrev )
mapWalletPrev [ txWalletPrev . GetHash ( ) ] = & txWalletPrev ;
}
else if ( mapWalletPrev . count ( hash ) )
{
tx = * mapWalletPrev [ hash ] ;
}
else if ( ! fClient & & txdb . ReadDiskTx ( hash , tx ) )
{
;
}
else
{
printf ( " ERROR: AddSupportingTransactions() : unsupported transaction \n " ) ;
continue ;
}
int nDepth = tx . SetMerkleBranch ( ) ;
vtxPrev . push_back ( tx ) ;
if ( nDepth < COPY_DEPTH )
foreach ( const CTxIn & txin , tx . vin )
vWorkQueue . push_back ( txin . prevout . hash ) ;
}
}
}
reverse ( vtxPrev . begin ( ) , vtxPrev . end ( ) ) ;
}
bool CTransaction : : CheckTransaction ( ) const
{
// Basic checks that don't depend on any context
if ( vin . empty ( ) | | vout . empty ( ) )
return error ( " CTransaction::CheckTransaction() : vin or vout empty " ) ;
// Size limits
if ( : : GetSerializeSize ( * this , SER_NETWORK ) > MAX_BLOCK_SIZE )
return error ( " CTransaction::CheckTransaction() : size limits failed " ) ;
// Check for negative or overflow output values
int64 nValueOut = 0 ;
foreach ( const CTxOut & txout , vout )
{
if ( txout . nValue < 0 )
return error ( " CTransaction::CheckTransaction() : txout . nValue negative " ) ;
if ( txout . nValue > MAX_MONEY )
return error ( " CTransaction::CheckTransaction() : txout . nValue too high " ) ;
nValueOut + = txout . nValue ;
if ( ! MoneyRange ( nValueOut ) )
return error ( " CTransaction::CheckTransaction() : txout total out of range " ) ;
}
if ( IsCoinBase ( ) )
{
if ( vin [ 0 ] . scriptSig . size ( ) < 2 | | vin [ 0 ] . scriptSig . size ( ) > 100 )
return error ( " CTransaction::CheckTransaction() : coinbase script size " ) ;
}
else
{
foreach ( const CTxIn & txin , vin )
if ( txin . prevout . IsNull ( ) )
return error ( " CTransaction::CheckTransaction() : prevout is null " ) ;
}
return true ;
}
bool CTransaction : : AcceptToMemoryPool ( CTxDB & txdb , bool fCheckInputs , bool * pfMissingInputs )
{
if ( pfMissingInputs )
* pfMissingInputs = false ;
if ( ! CheckTransaction ( ) )
return error ( " AcceptToMemoryPool() : CheckTransaction failed " ) ;
// Coinbase is only valid in a block, not as a loose transaction
if ( IsCoinBase ( ) )
return error ( " AcceptToMemoryPool() : coinbase as individual tx " ) ;
// To help v0.1.5 clients who would see it as a negative number
if ( ( int64 ) nLockTime > INT_MAX )
return error ( " AcceptToMemoryPool() : not accepting nLockTime beyond 2038 yet " ) ;
// Safety limits
unsigned int nSize = : : GetSerializeSize ( * this , SER_NETWORK ) ;
// Checking ECDSA signatures is a CPU bottleneck, so to avoid denial-of-service
// attacks disallow transactions with more than one SigOp per 34 bytes.
// 34 bytes because a TxOut is:
// 20-byte address + 8 byte bitcoin amount + 5 bytes of ops + 1 byte script length
if ( GetSigOpCount ( ) > nSize / 34 | | nSize < 100 )
return error ( " AcceptToMemoryPool() : nonstandard transaction " ) ;
// Rather not work on nonstandard transactions
if ( ! IsStandard ( ) )
return error ( " AcceptToMemoryPool() : nonstandard transaction type " ) ;
// Do we already have it?
uint256 hash = GetHash ( ) ;
CRITICAL_BLOCK ( cs_mapTransactions )
if ( mapTransactions . count ( hash ) )
return false ;
if ( fCheckInputs )
if ( txdb . ContainsTx ( hash ) )
return false ;
// Check for conflicts with in-memory transactions
CTransaction * ptxOld = NULL ;
for ( int i = 0 ; i < vin . size ( ) ; i + + )
{
COutPoint outpoint = vin [ i ] . prevout ;
if ( mapNextTx . count ( outpoint ) )
{
// Disable replacement feature for now
return false ;
// Allow replacing with a newer version of the same transaction
if ( i ! = 0 )
return false ;
ptxOld = mapNextTx [ outpoint ] . ptx ;
if ( ptxOld - > IsFinal ( ) )
return false ;
if ( ! IsNewerThan ( * ptxOld ) )
return false ;
for ( int i = 0 ; i < vin . size ( ) ; i + + )
{
COutPoint outpoint = vin [ i ] . prevout ;
if ( ! mapNextTx . count ( outpoint ) | | mapNextTx [ outpoint ] . ptx ! = ptxOld )
return false ;
}
break ;
}
}
if ( fCheckInputs )
{
// Check against previous transactions
map < uint256 , CTxIndex > mapUnused ;
int64 nFees = 0 ;
if ( ! ConnectInputs ( txdb , mapUnused , CDiskTxPos ( 1 , 1 , 1 ) , pindexBest , nFees , false , false ) )
{
if ( pfMissingInputs )
* pfMissingInputs = true ;
return error ( " AcceptToMemoryPool() : ConnectInputs failed % s " , hash.ToString().substr(0,10).c_str()) ;
}
// Don't accept it if it can't get into a block
if ( nFees < GetMinFee ( 1000 ) )
return error ( " AcceptToMemoryPool() : not enough fees " ) ;
// Continuously rate-limit free transactions
// This mitigates 'penny-flooding' -- sending thousands of free transactions just to
// be annoying or make other's transactions take longer to confirm.
if ( nFees < CENT )
{
static CCriticalSection cs ;
static double dFreeCount ;
static int64 nLastTime ;
int64 nNow = GetTime ( ) ;
CRITICAL_BLOCK ( cs )
{
// Use an exponentially decaying ~10-minute window:
dFreeCount * = pow ( 1.0 - 1.0 / 600.0 , ( double ) ( nNow - nLastTime ) ) ;
nLastTime = nNow ;
// -limitfreerelay unit is thousand-bytes-per-minute
// At default rate it would take over a month to fill 1GB
if ( dFreeCount > GetArg ( " -limitfreerelay " , 15 ) * 10 * 1000 & & ! IsFromMe ( ) )
return error ( " AcceptToMemoryPool() : free transaction rejected by rate limiter " ) ;
if ( fDebug )
printf ( " Rate limit dFreeCount: %g => %g \n " , dFreeCount , dFreeCount + nSize ) ;
dFreeCount + = nSize ;
}
}
}
// Store transaction in memory
CRITICAL_BLOCK ( cs_mapTransactions )
{
if ( ptxOld )
{
printf ( " AcceptToMemoryPool() : replacing tx %s with new version \n " , ptxOld - > GetHash ( ) . ToString ( ) . c_str ( ) ) ;
ptxOld - > RemoveFromMemoryPool ( ) ;
}
AddToMemoryPoolUnchecked ( ) ;
}
///// are we sure this is ok when loading transactions or restoring block txes
// If updated, erase old tx from wallet
if ( ptxOld )
EraseFromWallet ( ptxOld - > GetHash ( ) ) ;
printf ( " AcceptToMemoryPool(): accepted %s \n " , hash . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) ) ;
return true ;
}
bool CTransaction : : AddToMemoryPoolUnchecked ( )
{
// Add to memory pool without checking anything. Don't call this directly,
// call AcceptToMemoryPool to properly check the transaction first.
CRITICAL_BLOCK ( cs_mapTransactions )
{
uint256 hash = GetHash ( ) ;
mapTransactions [ hash ] = * this ;
for ( int i = 0 ; i < vin . size ( ) ; i + + )
mapNextTx [ vin [ i ] . prevout ] = CInPoint ( & mapTransactions [ hash ] , i ) ;
nTransactionsUpdated + + ;
}
return true ;
}
bool CTransaction : : RemoveFromMemoryPool ( )
{
// Remove transaction from memory pool
CRITICAL_BLOCK ( cs_mapTransactions )
{
foreach ( const CTxIn & txin , vin )
mapNextTx . erase ( txin . prevout ) ;
mapTransactions . erase ( GetHash ( ) ) ;
nTransactionsUpdated + + ;
}
return true ;
}
int CMerkleTx : : GetDepthInMainChain ( int & nHeightRet ) const
{
if ( hashBlock = = 0 | | nIndex = = - 1 )
return 0 ;
// Find the block it claims to be in
map < uint256 , CBlockIndex * > : : iterator mi = mapBlockIndex . find ( hashBlock ) ;
if ( mi = = mapBlockIndex . end ( ) )
return 0 ;
CBlockIndex * pindex = ( * mi ) . second ;
if ( ! pindex | | ! pindex - > IsInMainChain ( ) )
return 0 ;
// Make sure the merkle branch connects to this block
if ( ! fMerkleVerified )
{
if ( CBlock : : CheckMerkleBranch ( GetHash ( ) , vMerkleBranch , nIndex ) ! = pindex - > hashMerkleRoot )
return 0 ;
fMerkleVerified = true ;
}
nHeightRet = pindex - > nHeight ;
return pindexBest - > nHeight - pindex - > nHeight + 1 ;
}
int CMerkleTx : : GetBlocksToMaturity ( ) const
{
if ( ! IsCoinBase ( ) )
return 0 ;
return max ( 0 , ( COINBASE_MATURITY + 20 ) - GetDepthInMainChain ( ) ) ;
}
bool CMerkleTx : : AcceptToMemoryPool ( CTxDB & txdb , bool fCheckInputs )
{
if ( fClient )
{
if ( ! IsInMainChain ( ) & & ! ClientConnectInputs ( ) )
return false ;
return CTransaction : : AcceptToMemoryPool ( txdb , false ) ;
}
else
{
return CTransaction : : AcceptToMemoryPool ( txdb , fCheckInputs ) ;
}
}
bool CWalletTx : : AcceptWalletTransaction ( CTxDB & txdb , bool fCheckInputs )
{
CRITICAL_BLOCK ( cs_mapTransactions )
{
// Add previous supporting transactions first
foreach ( CMerkleTx & tx , vtxPrev )
{
if ( ! tx . IsCoinBase ( ) )
{
uint256 hash = tx . GetHash ( ) ;
if ( ! mapTransactions . count ( hash ) & & ! txdb . ContainsTx ( hash ) )
tx . AcceptToMemoryPool ( txdb , fCheckInputs ) ;
}
}
return AcceptToMemoryPool ( txdb , fCheckInputs ) ;
}
return false ;
}
int ScanForWalletTransactions ( CBlockIndex * pindexStart )
{
int ret = 0 ;
CBlockIndex * pindex = pindexStart ;
CRITICAL_BLOCK ( cs_mapWallet )
{
while ( pindex )
{
CBlock block ;
block . ReadFromDisk ( pindex , true ) ;
foreach ( CTransaction & tx , block . vtx )
{
uint256 hash = tx . GetHash ( ) ;
if ( mapWallet . count ( hash ) ) continue ;
AddToWalletIfMine ( tx , & block ) ;
if ( mapWallet . count ( hash ) )
{
+ + ret ;
printf ( " Added missing RECEIVE %s \n " , hash . ToString ( ) . c_str ( ) ) ;
continue ;
}
AddToWalletIfFromMe ( tx , & block ) ;
if ( mapWallet . count ( hash ) )
{
+ + ret ;
printf ( " Added missing SEND %s \n " , hash . ToString ( ) . c_str ( ) ) ;
continue ;
}
}
pindex = pindex - > pnext ;
}
}
return ret ;
}
void ReacceptWalletTransactions ( )
{
CTxDB txdb ( " r " ) ;
bool fRepeat = true ;
while ( fRepeat ) CRITICAL_BLOCK ( cs_mapWallet )
{
fRepeat = false ;
vector < CDiskTxPos > vMissingTx ;
foreach ( PAIRTYPE ( const uint256 , CWalletTx ) & item , mapWallet )
{
CWalletTx & wtx = item . second ;
if ( wtx . fSpent & & wtx . IsCoinBase ( ) )
continue ;
CTxIndex txindex ;
if ( txdb . ReadTxIndex ( wtx . GetHash ( ) , txindex ) )
{
// Update fSpent if a tx got spent somewhere else by a copy of wallet.dat
if ( ! wtx . fSpent )
{
if ( txindex . vSpent . size ( ) ! = wtx . vout . size ( ) )
{
printf ( " ERROR: ReacceptWalletTransactions() : txindex.vSpent.size() %d != wtx.vout.size() %d \n " , txindex . vSpent . size ( ) , wtx . vout . size ( ) ) ;
continue ;
}
for ( int i = 0 ; i < txindex . vSpent . size ( ) ; i + + )
{
if ( ! txindex . vSpent [ i ] . IsNull ( ) & & wtx . vout [ i ] . IsMine ( ) )
{
wtx . fSpent = true ;
vMissingTx . push_back ( txindex . vSpent [ i ] ) ;
}
}
if ( wtx . fSpent )
{
printf ( " ReacceptWalletTransactions found spent coin %sbc %s \n " , FormatMoney ( wtx . GetCredit ( ) ) . c_str ( ) , wtx . GetHash ( ) . ToString ( ) . c_str ( ) ) ;
wtx . WriteToDisk ( ) ;
}
}
}
else
{
// Reaccept any txes of ours that aren't already in a block
if ( ! wtx . IsCoinBase ( ) )
wtx . AcceptWalletTransaction ( txdb , false ) ;
}
}
if ( ! vMissingTx . empty ( ) )
{
// TODO: optimize this to scan just part of the block chain?
if ( ScanForWalletTransactions ( pindexGenesisBlock ) )
fRepeat = true ; // Found missing transactions: re-do Reaccept.
}
}
}
void CWalletTx : : RelayWalletTransaction ( CTxDB & txdb )
{
foreach ( const CMerkleTx & tx , vtxPrev )
{
if ( ! tx . IsCoinBase ( ) )
{
uint256 hash = tx . GetHash ( ) ;
if ( ! txdb . ContainsTx ( hash ) )
RelayMessage ( CInv ( MSG_TX , hash ) , ( CTransaction ) tx ) ;
}
}
if ( ! IsCoinBase ( ) )
{
uint256 hash = GetHash ( ) ;
if ( ! txdb . ContainsTx ( hash ) )
{
printf ( " Relaying wtx %s \n " , hash . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) ) ;
RelayMessage ( CInv ( MSG_TX , hash ) , ( CTransaction ) * this ) ;
}
}
}
void ResendWalletTransactions ( )
{
// Do this infrequently and randomly to avoid giving away
// that these are our transactions.
static int64 nNextTime ;
if ( GetTime ( ) < nNextTime )
return ;
bool fFirst = ( nNextTime = = 0 ) ;
nNextTime = GetTime ( ) + GetRand ( 30 * 60 ) ;
if ( fFirst )
return ;
// Only do it if there's been a new block since last time
static int64 nLastTime ;
if ( nTimeBestReceived < nLastTime )
return ;
nLastTime = GetTime ( ) ;
// Rebroadcast any of our txes that aren't in a block yet
printf ( " ResendWalletTransactions() \n " ) ;
CTxDB txdb ( " r " ) ;
CRITICAL_BLOCK ( cs_mapWallet )
{
// Sort them in chronological order
multimap < unsigned int , CWalletTx * > mapSorted ;
foreach ( PAIRTYPE ( const uint256 , CWalletTx ) & item , mapWallet )
{
CWalletTx & wtx = item . second ;
// Don't rebroadcast until it's had plenty of time that
// it should have gotten in already by now.
if ( nTimeBestReceived - ( int64 ) wtx . nTimeReceived > 5 * 60 )
mapSorted . insert ( make_pair ( wtx . nTimeReceived , & wtx ) ) ;
}
foreach ( PAIRTYPE ( const unsigned int , CWalletTx * ) & item , mapSorted )
{
CWalletTx & wtx = * item . second ;
wtx . RelayWalletTransaction ( txdb ) ;
}
}
}
int CTxIndex : : GetDepthInMainChain ( ) const
{
// Read block header
CBlock block ;
if ( ! block . ReadFromDisk ( pos . nFile , pos . nBlockPos , false ) )
return 0 ;
// Find the block in the index
map < uint256 , CBlockIndex * > : : iterator mi = mapBlockIndex . find ( block . GetHash ( ) ) ;
if ( mi = = mapBlockIndex . end ( ) )
return 0 ;
CBlockIndex * pindex = ( * mi ) . second ;
if ( ! pindex | | ! pindex - > IsInMainChain ( ) )
return 0 ;
return 1 + nBestHeight - pindex - > nHeight ;
}
//////////////////////////////////////////////////////////////////////////////
//
// CBlock and CBlockIndex
//
bool CBlock : : ReadFromDisk ( const CBlockIndex * pindex , bool fReadTransactions )
{
if ( ! fReadTransactions )
{
* this = pindex - > GetBlockHeader ( ) ;
return true ;
}
if ( ! ReadFromDisk ( pindex - > nFile , pindex - > nBlockPos , fReadTransactions ) )
return false ;
if ( GetHash ( ) ! = pindex - > GetBlockHash ( ) )
return error ( " CBlock::ReadFromDisk() : GetHash ( ) doesn ' t match index " ) ;
return true ;
}
uint256 GetOrphanRoot ( const CBlock * pblock )
{
// Work back to the first block in the orphan chain
while ( mapOrphanBlocks . count ( pblock - > hashPrevBlock ) )
pblock = mapOrphanBlocks [ pblock - > hashPrevBlock ] ;
return pblock - > GetHash ( ) ;
}
int64 GetBlockValue ( int nHeight , int64 nFees )
{
int64 nSubsidy = 50 * COIN ;
// Subsidy is cut in half every 4 years
nSubsidy > > = ( nHeight / 210000 ) ;
return nSubsidy + nFees ;
}
unsigned int GetNextWorkRequired ( const CBlockIndex * pindexLast )
{
const int64 nTargetTimespan = 14 * 24 * 60 * 60 ; // two weeks
const int64 nTargetSpacing = 10 * 60 ;
const int64 nInterval = nTargetTimespan / nTargetSpacing ;
// Genesis block
if ( pindexLast = = NULL )
return bnProofOfWorkLimit . GetCompact ( ) ;
// Only change once per interval
if ( ( pindexLast - > nHeight + 1 ) % nInterval ! = 0 )
return pindexLast - > nBits ;
// Go back by what we want to be 14 days worth of blocks
const CBlockIndex * pindexFirst = pindexLast ;
for ( int i = 0 ; pindexFirst & & i < nInterval - 1 ; i + + )
pindexFirst = pindexFirst - > pprev ;
assert ( pindexFirst ) ;
// Limit adjustment step
int64 nActualTimespan = pindexLast - > GetBlockTime ( ) - pindexFirst - > GetBlockTime ( ) ;
printf ( " nActualTimespan = % " PRI64d " before bounds \n " , nActualTimespan ) ;
if ( nActualTimespan < nTargetTimespan / 4 )
nActualTimespan = nTargetTimespan / 4 ;
if ( nActualTimespan > nTargetTimespan * 4 )
nActualTimespan = nTargetTimespan * 4 ;
// Retarget
CBigNum bnNew ;
bnNew . SetCompact ( pindexLast - > nBits ) ;
bnNew * = nActualTimespan ;
bnNew / = nTargetTimespan ;
if ( bnNew > bnProofOfWorkLimit )
bnNew = bnProofOfWorkLimit ;
/// debug print
printf ( " GetNextWorkRequired RETARGET \n " ) ;
printf ( " nTargetTimespan = % " PRI64d " nActualTimespan = % " PRI64d " \n " , nTargetTimespan , nActualTimespan ) ;
printf ( " Before: %08x %s \n " , pindexLast - > nBits , CBigNum ( ) . SetCompact ( pindexLast - > nBits ) . getuint256 ( ) . ToString ( ) . c_str ( ) ) ;
printf ( " After: %08x %s \n " , bnNew . GetCompact ( ) , bnNew . getuint256 ( ) . ToString ( ) . c_str ( ) ) ;
return bnNew . GetCompact ( ) ;
}
bool CheckProofOfWork ( uint256 hash , unsigned int nBits )
{
CBigNum bnTarget ;
bnTarget . SetCompact ( nBits ) ;
// Check range
if ( bnTarget < = 0 | | bnTarget > bnProofOfWorkLimit )
return error ( " CheckProofOfWork() : nBits below minimum work " ) ;
// Check proof of work matches claimed amount
if ( hash > bnTarget . getuint256 ( ) )
return error ( " CheckProofOfWork() : hash doesn ' t match nBits " ) ;
return true ;
}
bool IsInitialBlockDownload ( )
{
if ( pindexBest = = NULL | | ( ! fTestNet & & nBestHeight < 105000 ) )
return true ;
static int64 nLastUpdate ;
static CBlockIndex * pindexLastBest ;
if ( pindexBest ! = pindexLastBest )
{
pindexLastBest = pindexBest ;
nLastUpdate = GetTime ( ) ;
}
return ( GetTime ( ) - nLastUpdate < 10 & &
pindexBest - > GetBlockTime ( ) < GetTime ( ) - 24 * 60 * 60 ) ;
}
void InvalidChainFound ( CBlockIndex * pindexNew )
{
if ( pindexNew - > bnChainWork > bnBestInvalidWork )
{
bnBestInvalidWork = pindexNew - > bnChainWork ;
CTxDB ( ) . WriteBestInvalidWork ( bnBestInvalidWork ) ;
MainFrameRepaint ( ) ;
}
printf ( " InvalidChainFound: invalid block=%s height=%d work=%s \n " , pindexNew - > GetBlockHash ( ) . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) , pindexNew - > nHeight , pindexNew - > bnChainWork . ToString ( ) . c_str ( ) ) ;
printf ( " InvalidChainFound: current best=%s height=%d work=%s \n " , hashBestChain . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) , nBestHeight , bnBestChainWork . ToString ( ) . c_str ( ) ) ;
if ( pindexBest & & bnBestInvalidWork > bnBestChainWork + pindexBest - > GetBlockWork ( ) * 6 )
printf ( " InvalidChainFound: WARNING: Displayed transactions may not be correct! You may need to upgrade, or other nodes may need to upgrade. \n " ) ;
}
bool CTransaction : : DisconnectInputs ( CTxDB & txdb )
{
// Relinquish previous transactions' spent pointers
if ( ! IsCoinBase ( ) )
{
foreach ( const CTxIn & txin , vin )
{
COutPoint prevout = txin . prevout ;
// Get prev txindex from disk
CTxIndex txindex ;
if ( ! txdb . ReadTxIndex ( prevout . hash , txindex ) )
return error ( " DisconnectInputs() : ReadTxIndex failed " ) ;
if ( prevout . n > = txindex . vSpent . size ( ) )
return error ( " DisconnectInputs() : prevout . n out of range " ) ;
// Mark outpoint as not spent
txindex . vSpent [ prevout . n ] . SetNull ( ) ;
// Write back
if ( ! txdb . UpdateTxIndex ( prevout . hash , txindex ) )
return error ( " DisconnectInputs() : UpdateTxIndex failed " ) ;
}
}
// Remove transaction from index
if ( ! txdb . EraseTxIndex ( * this ) )
return error ( " DisconnectInputs() : EraseTxPos failed " ) ;
return true ;
}
bool CTransaction : : ConnectInputs ( CTxDB & txdb , map < uint256 , CTxIndex > & mapTestPool , CDiskTxPos posThisTx ,
CBlockIndex * pindexBlock , int64 & nFees , bool fBlock , bool fMiner , int64 nMinFee )
{
// Take over previous transactions' spent pointers
if ( ! IsCoinBase ( ) )
{
int64 nValueIn = 0 ;
for ( int i = 0 ; i < vin . size ( ) ; i + + )
{
COutPoint prevout = vin [ i ] . prevout ;
// Read txindex
CTxIndex txindex ;
bool fFound = true ;
if ( fMiner & & mapTestPool . count ( prevout . hash ) )
{
// Get txindex from current proposed changes
txindex = mapTestPool [ prevout . hash ] ;
}
else
{
// Read txindex from txdb
fFound = txdb . ReadTxIndex ( prevout . hash , txindex ) ;
}
if ( ! fFound & & ( fBlock | | fMiner ) )
return fMiner ? false : error ( " ConnectInputs() : %s prev tx %s index entry not found " , GetHash ( ) . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) , prevout . hash . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) ) ;
// Read txPrev
CTransaction txPrev ;
if ( ! fFound | | txindex . pos = = CDiskTxPos ( 1 , 1 , 1 ) )
{
// Get prev tx from single transactions in memory
CRITICAL_BLOCK ( cs_mapTransactions )
{
if ( ! mapTransactions . count ( prevout . hash ) )
return error ( " ConnectInputs() : % s mapTransactions prev not found % s " , GetHash().ToString().substr(0,10).c_str(), prevout.hash.ToString().substr(0,10).c_str()) ;
txPrev = mapTransactions [ prevout . hash ] ;
}
if ( ! fFound )
txindex . vSpent . resize ( txPrev . vout . size ( ) ) ;
}
else
{
// Get prev tx from disk
if ( ! txPrev . ReadFromDisk ( txindex . pos ) )
return error ( " ConnectInputs() : % s ReadFromDisk prev tx % s failed " , GetHash().ToString().substr(0,10).c_str(), prevout.hash.ToString().substr(0,10).c_str()) ;
}
if ( prevout . n > = txPrev . vout . size ( ) | | prevout . n > = txindex . vSpent . size ( ) )
return error ( " ConnectInputs() : % s prevout . n out of range % d % d % d prev tx % s \ n % s " , GetHash().ToString().substr(0,10).c_str(), prevout.n, txPrev.vout.size(), txindex.vSpent.size(), prevout.hash.ToString().substr(0,10).c_str(), txPrev.ToString().c_str()) ;
// If prev is coinbase, check that it's matured
if ( txPrev . IsCoinBase ( ) )
for ( CBlockIndex * pindex = pindexBlock ; pindex & & pindexBlock - > nHeight - pindex - > nHeight < COINBASE_MATURITY ; pindex = pindex - > pprev )
if ( pindex - > nBlockPos = = txindex . pos . nBlockPos & & pindex - > nFile = = txindex . pos . nFile )
return error ( " ConnectInputs() : tried to spend coinbase at depth % d " , pindexBlock->nHeight - pindex->nHeight) ;
// Verify signature
if ( ! VerifySignature ( txPrev , * this , i ) )
return error ( " ConnectInputs() : % s VerifySignature failed " , GetHash().ToString().substr(0,10).c_str()) ;
// Check for conflicts
if ( ! txindex . vSpent [ prevout . n ] . IsNull ( ) )
return fMiner ? false : error ( " ConnectInputs() : %s prev tx already used at %s " , GetHash ( ) . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) , txindex . vSpent [ prevout . n ] . ToString ( ) . c_str ( ) ) ;
// Check for negative or overflow input values
nValueIn + = txPrev . vout [ prevout . n ] . nValue ;
if ( ! MoneyRange ( txPrev . vout [ prevout . n ] . nValue ) | | ! MoneyRange ( nValueIn ) )
return error ( " ConnectInputs() : txin values out of range " ) ;
// Mark outpoints as spent
txindex . vSpent [ prevout . n ] = posThisTx ;
// Write back
if ( fBlock )
{
if ( ! txdb . UpdateTxIndex ( prevout . hash , txindex ) )
return error ( " ConnectInputs() : UpdateTxIndex failed " ) ;
}
else if ( fMiner )
{
mapTestPool [ prevout . hash ] = txindex ;
}
}
if ( nValueIn < GetValueOut ( ) )
return error ( " ConnectInputs() : % s value in < value out " , GetHash().ToString().substr(0,10).c_str()) ;
// Tally transaction fees
int64 nTxFee = nValueIn - GetValueOut ( ) ;
if ( nTxFee < 0 )
return error ( " ConnectInputs() : % s nTxFee < 0 " , GetHash().ToString().substr(0,10).c_str()) ;
if ( nTxFee < nMinFee )
return false ;
nFees + = nTxFee ;
if ( ! MoneyRange ( nFees ) )
return error ( " ConnectInputs() : nFees out of range " ) ;
}
if ( fBlock )
{
// Add transaction to disk index
if ( ! txdb . AddTxIndex ( * this , posThisTx , pindexBlock - > nHeight ) )
return error ( " ConnectInputs() : AddTxPos failed " ) ;
}
else if ( fMiner )
{
// Add transaction to test pool
mapTestPool [ GetHash ( ) ] = CTxIndex ( CDiskTxPos ( 1 , 1 , 1 ) , vout . size ( ) ) ;
}
return true ;
}
bool CTransaction : : ClientConnectInputs ( )
{
if ( IsCoinBase ( ) )
return false ;
// Take over previous transactions' spent pointers
CRITICAL_BLOCK ( cs_mapTransactions )
{
int64 nValueIn = 0 ;
for ( int i = 0 ; i < vin . size ( ) ; i + + )
{
// Get prev tx from single transactions in memory
COutPoint prevout = vin [ i ] . prevout ;
if ( ! mapTransactions . count ( prevout . hash ) )
return false ;
CTransaction & txPrev = mapTransactions [ prevout . hash ] ;
if ( prevout . n > = txPrev . vout . size ( ) )
return false ;
// Verify signature
if ( ! VerifySignature ( txPrev , * this , i ) )
return error ( " ConnectInputs() : VerifySignature failed " ) ;
///// this is redundant with the mapNextTx stuff, not sure which I want to get rid of
///// this has to go away now that posNext is gone
// // Check for conflicts
// if (!txPrev.vout[prevout.n].posNext.IsNull())
// return error("ConnectInputs() : prev tx already used");
//
// // Flag outpoints as used
// txPrev.vout[prevout.n].posNext = posThisTx;
nValueIn + = txPrev . vout [ prevout . n ] . nValue ;
if ( ! MoneyRange ( txPrev . vout [ prevout . n ] . nValue ) | | ! MoneyRange ( nValueIn ) )
return error ( " ClientConnectInputs() : txin values out of range " ) ;
}
if ( GetValueOut ( ) > nValueIn )
return false ;
}
return true ;
}
bool CBlock : : DisconnectBlock ( CTxDB & txdb , CBlockIndex * pindex )
{
// Disconnect in reverse order
for ( int i = vtx . size ( ) - 1 ; i > = 0 ; i - - )
if ( ! vtx [ i ] . DisconnectInputs ( txdb ) )
return false ;
// Update block index on disk without changing it in memory.
// The memory index structure will be changed after the db commits.
if ( pindex - > pprev )
{
CDiskBlockIndex blockindexPrev ( pindex - > pprev ) ;
blockindexPrev . hashNext = 0 ;
if ( ! txdb . WriteBlockIndex ( blockindexPrev ) )
return error ( " DisconnectBlock() : WriteBlockIndex failed " ) ;
}
return true ;
}
bool CBlock : : ConnectBlock ( CTxDB & txdb , CBlockIndex * pindex )
{
// Check it again in case a previous version let a bad block in
if ( ! CheckBlock ( ) )
return false ;
//// issue here: it doesn't know the version
unsigned int nTxPos = pindex - > nBlockPos + : : GetSerializeSize ( CBlock ( ) , SER_DISK ) - 1 + GetSizeOfCompactSize ( vtx . size ( ) ) ;
map < uint256 , CTxIndex > mapUnused ;
int64 nFees = 0 ;
foreach ( CTransaction & tx , vtx )
{
CDiskTxPos posThisTx ( pindex - > nFile , pindex - > nBlockPos , nTxPos ) ;
nTxPos + = : : GetSerializeSize ( tx , SER_DISK ) ;
if ( ! tx . ConnectInputs ( txdb , mapUnused , posThisTx , pindex , nFees , true , false ) )
return false ;
}
if ( vtx [ 0 ] . GetValueOut ( ) > GetBlockValue ( pindex - > nHeight , nFees ) )
return false ;
// Update block index on disk without changing it in memory.
// The memory index structure will be changed after the db commits.
if ( pindex - > pprev )
{
CDiskBlockIndex blockindexPrev ( pindex - > pprev ) ;
blockindexPrev . hashNext = pindex - > GetBlockHash ( ) ;
if ( ! txdb . WriteBlockIndex ( blockindexPrev ) )
return error ( " ConnectBlock() : WriteBlockIndex failed " ) ;
}
// Watch for transactions paying to me
foreach ( CTransaction & tx , vtx )
AddToWalletIfMine ( tx , this ) ;
return true ;
}
bool Reorganize ( CTxDB & txdb , CBlockIndex * pindexNew )
{
printf ( " REORGANIZE \n " ) ;
// Find the fork
CBlockIndex * pfork = pindexBest ;
CBlockIndex * plonger = pindexNew ;
while ( pfork ! = plonger )
{
while ( plonger - > nHeight > pfork - > nHeight )
if ( ! ( plonger = plonger - > pprev ) )
return error ( " Reorganize() : plonger - > pprev is null " ) ;
if ( pfork = = plonger )
break ;
if ( ! ( pfork = pfork - > pprev ) )
return error ( " Reorganize() : pfork - > pprev is null " ) ;
}
// List of what to disconnect
vector < CBlockIndex * > vDisconnect ;
for ( CBlockIndex * pindex = pindexBest ; pindex ! = pfork ; pindex = pindex - > pprev )
vDisconnect . push_back ( pindex ) ;
// List of what to connect
vector < CBlockIndex * > vConnect ;
for ( CBlockIndex * pindex = pindexNew ; pindex ! = pfork ; pindex = pindex - > pprev )
vConnect . push_back ( pindex ) ;
reverse ( vConnect . begin ( ) , vConnect . end ( ) ) ;
// Disconnect shorter branch
vector < CTransaction > vResurrect ;
foreach ( CBlockIndex * pindex , vDisconnect )
{
CBlock block ;
if ( ! block . ReadFromDisk ( pindex ) )
return error ( " Reorganize() : ReadFromDisk for disconnect failed " ) ;
if ( ! block . DisconnectBlock ( txdb , pindex ) )
return error ( " Reorganize() : DisconnectBlock failed " ) ;
// Queue memory transactions to resurrect
foreach ( const CTransaction & tx , block . vtx )
if ( ! tx . IsCoinBase ( ) )
vResurrect . push_back ( tx ) ;
}
// Connect longer branch
vector < CTransaction > vDelete ;
for ( int i = 0 ; i < vConnect . size ( ) ; i + + )
{
CBlockIndex * pindex = vConnect [ i ] ;
CBlock block ;
if ( ! block . ReadFromDisk ( pindex ) )
return error ( " Reorganize() : ReadFromDisk for connect failed " ) ;
if ( ! block . ConnectBlock ( txdb , pindex ) )
{
// Invalid block
txdb . TxnAbort ( ) ;
return error ( " Reorganize() : ConnectBlock failed " ) ;
}
// Queue memory transactions to delete
foreach ( const CTransaction & tx , block . vtx )
vDelete . push_back ( tx ) ;
}
if ( ! txdb . WriteHashBestChain ( pindexNew - > GetBlockHash ( ) ) )
return error ( " Reorganize() : WriteHashBestChain failed " ) ;
// Make sure it's successfully written to disk before changing memory structure
if ( ! txdb . TxnCommit ( ) )
return error ( " Reorganize() : TxnCommit failed " ) ;
// Disconnect shorter branch
foreach ( CBlockIndex * pindex , vDisconnect )
if ( pindex - > pprev )
pindex - > pprev - > pnext = NULL ;
// Connect longer branch
foreach ( CBlockIndex * pindex , vConnect )
if ( pindex - > pprev )
pindex - > pprev - > pnext = pindex ;
// Resurrect memory transactions that were in the disconnected branch
foreach ( CTransaction & tx , vResurrect )
tx . AcceptToMemoryPool ( txdb , false ) ;
// Delete redundant memory transactions that are in the connected branch
foreach ( CTransaction & tx , vDelete )
tx . RemoveFromMemoryPool ( ) ;
return true ;
}
bool CBlock : : SetBestChain ( CTxDB & txdb , CBlockIndex * pindexNew )
{
uint256 hash = GetHash ( ) ;
txdb . TxnBegin ( ) ;
if ( pindexGenesisBlock = = NULL & & hash = = hashGenesisBlock )
{
txdb . WriteHashBestChain ( hash ) ;
if ( ! txdb . TxnCommit ( ) )
return error ( " SetBestChain() : TxnCommit failed " ) ;
pindexGenesisBlock = pindexNew ;
}
else if ( hashPrevBlock = = hashBestChain )
{
// Adding to current best branch
if ( ! ConnectBlock ( txdb , pindexNew ) | | ! txdb . WriteHashBestChain ( hash ) )
{
txdb . TxnAbort ( ) ;
InvalidChainFound ( pindexNew ) ;
return error ( " SetBestChain() : ConnectBlock failed " ) ;
}
if ( ! txdb . TxnCommit ( ) )
return error ( " SetBestChain() : TxnCommit failed " ) ;
// Add to current best branch
pindexNew - > pprev - > pnext = pindexNew ;
// Delete redundant memory transactions
foreach ( CTransaction & tx , vtx )
tx . RemoveFromMemoryPool ( ) ;
}
else
{
// New best branch
if ( ! Reorganize ( txdb , pindexNew ) )
{
txdb . TxnAbort ( ) ;
InvalidChainFound ( pindexNew ) ;
return error ( " SetBestChain() : Reorganize failed " ) ;
}
}
// New best block
hashBestChain = hash ;
pindexBest = pindexNew ;
nBestHeight = pindexBest - > nHeight ;
bnBestChainWork = pindexNew - > bnChainWork ;
nTimeBestReceived = GetTime ( ) ;
nTransactionsUpdated + + ;
printf ( " SetBestChain: new best=%s height=%d work=%s \n " , hashBestChain . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) , nBestHeight , bnBestChainWork . ToString ( ) . c_str ( ) ) ;
return true ;
}
bool CBlock : : AddToBlockIndex ( unsigned int nFile , unsigned int nBlockPos )
{
// Check for duplicate
uint256 hash = GetHash ( ) ;
if ( mapBlockIndex . count ( hash ) )
return error ( " AddToBlockIndex() : % s already exists " , hash.ToString().substr(0,20).c_str()) ;
// Construct new block index object
CBlockIndex * pindexNew = new CBlockIndex ( nFile , nBlockPos , * this ) ;
if ( ! pindexNew )
return error ( " AddToBlockIndex() : new CBlockIndex failed " ) ;
map < uint256 , CBlockIndex * > : : iterator mi = mapBlockIndex . insert ( make_pair ( hash , pindexNew ) ) . first ;
pindexNew - > phashBlock = & ( ( * mi ) . first ) ;
map < uint256 , CBlockIndex * > : : iterator miPrev = mapBlockIndex . find ( hashPrevBlock ) ;
if ( miPrev ! = mapBlockIndex . end ( ) )
{
pindexNew - > pprev = ( * miPrev ) . second ;
pindexNew - > nHeight = pindexNew - > pprev - > nHeight + 1 ;
}
pindexNew - > bnChainWork = ( pindexNew - > pprev ? pindexNew - > pprev - > bnChainWork : 0 ) + pindexNew - > GetBlockWork ( ) ;
CTxDB txdb ;
txdb . TxnBegin ( ) ;
txdb . WriteBlockIndex ( CDiskBlockIndex ( pindexNew ) ) ;
if ( ! txdb . TxnCommit ( ) )
return false ;
// New best
if ( pindexNew - > bnChainWork > bnBestChainWork )
if ( ! SetBestChain ( txdb , pindexNew ) )
return false ;
txdb . Close ( ) ;
if ( pindexNew = = pindexBest )
{
// Notify UI to display prev block's coinbase if it was ours
static uint256 hashPrevBestCoinBase ;
CRITICAL_BLOCK ( cs_mapWallet )
vWalletUpdated . push_back ( hashPrevBestCoinBase ) ;
hashPrevBestCoinBase = vtx [ 0 ] . GetHash ( ) ;
}
MainFrameRepaint ( ) ;
return true ;
}
bool CBlock : : CheckBlock ( ) const
{
// These are checks that are independent of context
// that can be verified before saving an orphan block.
// Size limits
if ( vtx . empty ( ) | | vtx . size ( ) > MAX_BLOCK_SIZE | | : : GetSerializeSize ( * this , SER_NETWORK ) > MAX_BLOCK_SIZE )
return error ( " CheckBlock() : size limits failed " ) ;
// Check proof of work matches claimed amount
if ( ! CheckProofOfWork ( GetHash ( ) , nBits ) )
return error ( " CheckBlock() : proof of work failed " ) ;
// Check timestamp
if ( GetBlockTime ( ) > GetAdjustedTime ( ) + 2 * 60 * 60 )
return error ( " CheckBlock() : block timestamp too far in the future " ) ;
// First transaction must be coinbase, the rest must not be
if ( vtx . empty ( ) | | ! vtx [ 0 ] . IsCoinBase ( ) )
return error ( " CheckBlock() : first tx is not coinbase " ) ;
for ( int i = 1 ; i < vtx . size ( ) ; i + + )
if ( vtx [ i ] . IsCoinBase ( ) )
return error ( " CheckBlock() : more than one coinbase " ) ;
// Check transactions
foreach ( const CTransaction & tx , vtx )
if ( ! tx . CheckTransaction ( ) )
return error ( " CheckBlock() : CheckTransaction failed " ) ;
// Check that it's not full of nonstandard transactions
if ( GetSigOpCount ( ) > MAX_BLOCK_SIGOPS )
return error ( " CheckBlock() : too many nonstandard transactions " ) ;
// Check merkleroot
if ( hashMerkleRoot ! = BuildMerkleTree ( ) )
return error ( " CheckBlock() : hashMerkleRoot mismatch " ) ;
return true ;
}
bool CBlock : : AcceptBlock ( )
{
// Check for duplicate
uint256 hash = GetHash ( ) ;
if ( mapBlockIndex . count ( hash ) )
return error ( " AcceptBlock() : block already in mapBlockIndex " ) ;
// Get prev block index
map < uint256 , CBlockIndex * > : : iterator mi = mapBlockIndex . find ( hashPrevBlock ) ;
if ( mi = = mapBlockIndex . end ( ) )
return error ( " AcceptBlock() : prev block not found " ) ;
CBlockIndex * pindexPrev = ( * mi ) . second ;
int nHeight = pindexPrev - > nHeight + 1 ;
// Check proof of work
if ( nBits ! = GetNextWorkRequired ( pindexPrev ) )
return error ( " AcceptBlock() : incorrect proof of work " ) ;
// Check timestamp against prev
if ( GetBlockTime ( ) < = pindexPrev - > GetMedianTimePast ( ) )
return error ( " AcceptBlock() : block ' s timestamp is too early " ) ;
// Check that all transactions are finalized
foreach ( const CTransaction & tx , vtx )
if ( ! tx . IsFinal ( nHeight , GetBlockTime ( ) ) )
return error ( " AcceptBlock() : contains a non - final transaction " ) ;
// Check that the block chain matches the known block chain up to a checkpoint
if ( ! fTestNet )
if ( ( nHeight = = 11111 & & hash ! = uint256 ( " 0x0000000069e244f73d78e8fd29ba2fd2ed618bd6fa2ee92559f542fdb26e7c1d " ) ) | |
( nHeight = = 33333 & & hash ! = uint256 ( " 0x000000002dd5588a74784eaa7ab0507a18ad16a236e7b1ce69f00d7ddfb5d0a6 " ) ) | |
( nHeight = = 68555 & & hash ! = uint256 ( " 0x00000000001e1b4903550a0b96e9a9405c8a95f387162e4944e8d9fbe501cd6a " ) ) | |
( nHeight = = 70567 & & hash ! = uint256 ( " 0x00000000006a49b14bcf27462068f1264c961f11fa2e0eddd2be0791e1d4124a " ) ) | |
( nHeight = = 74000 & & hash ! = uint256 ( " 0x0000000000573993a3c9e41ce34471c079dcf5f52a0e824a81e7f953b8661a20 " ) ) | |
( nHeight = = 105000 & & hash ! = uint256 ( " 0x00000000000291ce28027faea320c8d2b054b2e0fe44a773f3eefb151d6bdc97 " ) ) )
return error ( " AcceptBlock() : rejected by checkpoint lockin at % d " , nHeight) ;
// Write block to history file
if ( ! CheckDiskSpace ( : : GetSerializeSize ( * this , SER_DISK ) ) )
return error ( " AcceptBlock() : out of disk space " ) ;
unsigned int nFile = - 1 ;
unsigned int nBlockPos = 0 ;
if ( ! WriteToDisk ( nFile , nBlockPos ) )
return error ( " AcceptBlock() : WriteToDisk failed " ) ;
if ( ! AddToBlockIndex ( nFile , nBlockPos ) )
return error ( " AcceptBlock() : AddToBlockIndex failed " ) ;
// Relay inventory, but don't relay old inventory during initial block download
if ( hashBestChain = = hash )
CRITICAL_BLOCK ( cs_vNodes )
foreach ( CNode * pnode , vNodes )
if ( nBestHeight > ( pnode - > nStartingHeight ! = - 1 ? pnode - > nStartingHeight - 2000 : 105000 ) )
pnode - > PushInventory ( CInv ( MSG_BLOCK , hash ) ) ;
return true ;
}
bool ProcessBlock ( CNode * pfrom , CBlock * pblock )
{
// Check for duplicate
uint256 hash = pblock - > GetHash ( ) ;
if ( mapBlockIndex . count ( hash ) )
return error ( " ProcessBlock() : already have block % d % s " , mapBlockIndex[hash]->nHeight, hash.ToString().substr(0,20).c_str()) ;
if ( mapOrphanBlocks . count ( hash ) )
return error ( " ProcessBlock() : already have block ( orphan ) % s " , hash.ToString().substr(0,20).c_str()) ;
// Preliminary checks
if ( ! pblock - > CheckBlock ( ) )
return error ( " ProcessBlock() : CheckBlock FAILED " ) ;
// If don't already have its previous block, shunt it off to holding area until we get it
if ( ! mapBlockIndex . count ( pblock - > hashPrevBlock ) )
{
printf ( " ProcessBlock: ORPHAN BLOCK, prev=%s \n " , pblock - > hashPrevBlock . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) ) ;
CBlock * pblock2 = new CBlock ( * pblock ) ;
mapOrphanBlocks . insert ( make_pair ( hash , pblock2 ) ) ;
mapOrphanBlocksByPrev . insert ( make_pair ( pblock2 - > hashPrevBlock , pblock2 ) ) ;
// Ask this guy to fill in what we're missing
if ( pfrom )
pfrom - > PushGetBlocks ( pindexBest , GetOrphanRoot ( pblock2 ) ) ;
return true ;
}
// Store to disk
if ( ! pblock - > AcceptBlock ( ) )
return error ( " ProcessBlock() : AcceptBlock FAILED " ) ;
// Recursively process any orphan blocks that depended on this one
vector < uint256 > vWorkQueue ;
vWorkQueue . push_back ( hash ) ;
for ( int i = 0 ; i < vWorkQueue . size ( ) ; i + + )
{
uint256 hashPrev = vWorkQueue [ i ] ;
for ( multimap < uint256 , CBlock * > : : iterator mi = mapOrphanBlocksByPrev . lower_bound ( hashPrev ) ;
mi ! = mapOrphanBlocksByPrev . upper_bound ( hashPrev ) ;
+ + mi )
{
CBlock * pblockOrphan = ( * mi ) . second ;
if ( pblockOrphan - > AcceptBlock ( ) )
vWorkQueue . push_back ( pblockOrphan - > GetHash ( ) ) ;
mapOrphanBlocks . erase ( pblockOrphan - > GetHash ( ) ) ;
delete pblockOrphan ;
}
mapOrphanBlocksByPrev . erase ( hashPrev ) ;
}
printf ( " ProcessBlock: ACCEPTED \n " ) ;
return true ;
}
template < typename Stream >
bool ScanMessageStart ( Stream & s )
{
// Scan ahead to the next pchMessageStart, which should normally be immediately
// at the file pointer. Leaves file pointer at end of pchMessageStart.
s . clear ( 0 ) ;
short prevmask = s . exceptions ( 0 ) ;
const char * p = BEGIN ( pchMessageStart ) ;
try
{
loop
{
char c ;
s . read ( & c , 1 ) ;
if ( s . fail ( ) )
{
s . clear ( 0 ) ;
s . exceptions ( prevmask ) ;
return false ;
}
if ( * p ! = c )
p = BEGIN ( pchMessageStart ) ;
if ( * p = = c )
{
if ( + + p = = END ( pchMessageStart ) )
{
s . clear ( 0 ) ;
s . exceptions ( prevmask ) ;
return true ;
}
}
}
}
catch ( . . . )
{
s . clear ( 0 ) ;
s . exceptions ( prevmask ) ;
return false ;
}
}
bool CheckDiskSpace ( uint64 nAdditionalBytes )
{
uint64 nFreeBytesAvailable = filesystem : : space ( GetDataDir ( ) ) . available ;
// Check for 15MB because database could create another 10MB log file at any time
if ( nFreeBytesAvailable < ( uint64 ) 15000000 + nAdditionalBytes )
{
fShutdown = true ;
string strMessage = _ ( " Warning: Disk space is low " ) ;
strMiscWarning = strMessage ;
printf ( " *** %s \n " , strMessage . c_str ( ) ) ;
ThreadSafeMessageBox ( strMessage , " Bitcoin " , wxOK | wxICON_EXCLAMATION ) ;
CreateThread ( Shutdown , NULL ) ;
return false ;
}
return true ;
}
FILE * OpenBlockFile ( unsigned int nFile , unsigned int nBlockPos , const char * pszMode )
{
if ( nFile = = - 1 )
return NULL ;
FILE * file = fopen ( strprintf ( " %s/blk%04d.dat " , GetDataDir ( ) . c_str ( ) , nFile ) . c_str ( ) , pszMode ) ;
if ( ! file )
return NULL ;
if ( nBlockPos ! = 0 & & ! strchr ( pszMode , ' a ' ) & & ! strchr ( pszMode , ' w ' ) )
{
if ( fseek ( file , nBlockPos , SEEK_SET ) ! = 0 )
{
fclose ( file ) ;
return NULL ;
}
}
return file ;
}
static unsigned int nCurrentBlockFile = 1 ;
FILE * AppendBlockFile ( unsigned int & nFileRet )
{
nFileRet = 0 ;
loop
{
FILE * file = OpenBlockFile ( nCurrentBlockFile , 0 , " ab " ) ;
if ( ! file )
return NULL ;
if ( fseek ( file , 0 , SEEK_END ) ! = 0 )
return NULL ;
// FAT32 filesize max 4GB, fseek and ftell max 2GB, so we must stay under 2GB
if ( ftell ( file ) < 0x7F000000 - MAX_SIZE )
{
nFileRet = nCurrentBlockFile ;
return file ;
}
fclose ( file ) ;
nCurrentBlockFile + + ;
}
}
bool LoadBlockIndex ( bool fAllowNew )
{
if ( fTestNet )
{
hashGenesisBlock = uint256 ( " 0x00000007199508e34a9ff81e6ec0c477a4cccff2a4767a8eee39c11db367b008 " ) ;
bnProofOfWorkLimit = CBigNum ( ~ uint256 ( 0 ) > > 28 ) ;
pchMessageStart [ 0 ] = 0xfa ;
pchMessageStart [ 1 ] = 0xbf ;
pchMessageStart [ 2 ] = 0xb5 ;
pchMessageStart [ 3 ] = 0xda ;
}
//
// Load block index
//
CTxDB txdb ( " cr " ) ;
if ( ! txdb . LoadBlockIndex ( ) )
return false ;
txdb . Close ( ) ;
//
// Init with genesis block
//
if ( mapBlockIndex . empty ( ) )
{
if ( ! fAllowNew )
return false ;
// Genesis Block:
// CBlock(hash=000000000019d6, ver=1, hashPrevBlock=00000000000000, hashMerkleRoot=4a5e1e, nTime=1231006505, nBits=1d00ffff, nNonce=2083236893, vtx=1)
// CTransaction(hash=4a5e1e, ver=1, vin.size=1, vout.size=1, nLockTime=0)
// CTxIn(COutPoint(000000, -1), coinbase 04ffff001d0104455468652054696d65732030332f4a616e2f32303039204368616e63656c6c6f72206f6e206272696e6b206f66207365636f6e64206261696c6f757420666f722062616e6b73)
// CTxOut(nValue=50.00000000, scriptPubKey=0x5F1DF16B2B704C8A578D0B)
// vMerkleTree: 4a5e1e
// Genesis block
const char * pszTimestamp = " The Times 03/Jan/2009 Chancellor on brink of second bailout for banks " ;
CTransaction txNew ;
txNew . vin . resize ( 1 ) ;
txNew . vout . resize ( 1 ) ;
txNew . vin [ 0 ] . scriptSig = CScript ( ) < < 486604799 < < CBigNum ( 4 ) < < vector < unsigned char > ( ( const unsigned char * ) pszTimestamp , ( const unsigned char * ) pszTimestamp + strlen ( pszTimestamp ) ) ;
txNew . vout [ 0 ] . nValue = 50 * COIN ;
txNew . vout [ 0 ] . scriptPubKey = CScript ( ) < < ParseHex ( " 04678afdb0fe5548271967f1a67130b7105cd6a828e03909a67962e0ea1f61deb649f6bc3f4cef38c4f35504e51ec112de5c384df7ba0b8d578a4c702b6bf11d5f " ) < < OP_CHECKSIG ;
CBlock block ;
block . vtx . push_back ( txNew ) ;
block . hashPrevBlock = 0 ;
block . hashMerkleRoot = block . BuildMerkleTree ( ) ;
block . nVersion = 1 ;
block . nTime = 1231006505 ;
block . nBits = 0x1d00ffff ;
block . nNonce = 2083236893 ;
if ( fTestNet )
{
block . nTime = 1296688602 ;
block . nBits = 0x1d07fff8 ;
block . nNonce = 384568319 ;
}
//// debug print
printf ( " %s \n " , block . GetHash ( ) . ToString ( ) . c_str ( ) ) ;
printf ( " %s \n " , hashGenesisBlock . ToString ( ) . c_str ( ) ) ;
printf ( " %s \n " , block . hashMerkleRoot . ToString ( ) . c_str ( ) ) ;
assert ( block . hashMerkleRoot = = uint256 ( " 0x4a5e1e4baab89f3a32518a88c31bc87f618f76673e2cc77ab2127b7afdeda33b " ) ) ;
block . print ( ) ;
assert ( block . GetHash ( ) = = hashGenesisBlock ) ;
// Start new block file
unsigned int nFile ;
unsigned int nBlockPos ;
if ( ! block . WriteToDisk ( nFile , nBlockPos ) )
return error ( " LoadBlockIndex() : writing genesis block to disk failed " ) ;
if ( ! block . AddToBlockIndex ( nFile , nBlockPos ) )
return error ( " LoadBlockIndex() : genesis block not accepted " ) ;
}
return true ;
}
void PrintBlockTree ( )
{
// precompute tree structure
map < CBlockIndex * , vector < CBlockIndex * > > mapNext ;
for ( map < uint256 , CBlockIndex * > : : iterator mi = mapBlockIndex . begin ( ) ; mi ! = mapBlockIndex . end ( ) ; + + mi )
{
CBlockIndex * pindex = ( * mi ) . second ;
mapNext [ pindex - > pprev ] . push_back ( pindex ) ;
// test
//while (rand() % 3 == 0)
// mapNext[pindex->pprev].push_back(pindex);
}
vector < pair < int , CBlockIndex * > > vStack ;
vStack . push_back ( make_pair ( 0 , pindexGenesisBlock ) ) ;
int nPrevCol = 0 ;
while ( ! vStack . empty ( ) )
{
int nCol = vStack . back ( ) . first ;
CBlockIndex * pindex = vStack . back ( ) . second ;
vStack . pop_back ( ) ;
// print split or gap
if ( nCol > nPrevCol )
{
for ( int i = 0 ; i < nCol - 1 ; i + + )
printf ( " | " ) ;
printf ( " | \\ \n " ) ;
}
else if ( nCol < nPrevCol )
{
for ( int i = 0 ; i < nCol ; i + + )
printf ( " | " ) ;
printf ( " | \n " ) ;
}
nPrevCol = nCol ;
// print columns
for ( int i = 0 ; i < nCol ; i + + )
printf ( " | " ) ;
// print item
CBlock block ;
block . ReadFromDisk ( pindex ) ;
printf ( " %d (%u,%u) %s %s tx %d " ,
pindex - > nHeight ,
pindex - > nFile ,
pindex - > nBlockPos ,
block . GetHash ( ) . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) ,
DateTimeStrFormat ( " %x %H:%M:%S " , block . GetBlockTime ( ) ) . c_str ( ) ,
block . vtx . size ( ) ) ;
CRITICAL_BLOCK ( cs_mapWallet )
{
if ( mapWallet . count ( block . vtx [ 0 ] . GetHash ( ) ) )
{
CWalletTx & wtx = mapWallet [ block . vtx [ 0 ] . GetHash ( ) ] ;
printf ( " mine: %d %d %d " , wtx . GetDepthInMainChain ( ) , wtx . GetBlocksToMaturity ( ) , wtx . GetCredit ( ) ) ;
}
}
printf ( " \n " ) ;
// put the main timechain first
vector < CBlockIndex * > & vNext = mapNext [ pindex ] ;
for ( int i = 0 ; i < vNext . size ( ) ; i + + )
{
if ( vNext [ i ] - > pnext )
{
swap ( vNext [ 0 ] , vNext [ i ] ) ;
break ;
}
}
// iterate children
for ( int i = 0 ; i < vNext . size ( ) ; i + + )
vStack . push_back ( make_pair ( nCol + i , vNext [ i ] ) ) ;
}
}
//////////////////////////////////////////////////////////////////////////////
//
// CAlert
//
map < uint256 , CAlert > mapAlerts ;
CCriticalSection cs_mapAlerts ;
string GetWarnings ( string strFor )
{
int nPriority = 0 ;
string strStatusBar ;
string strRPC ;
if ( GetBoolArg ( " -testsafemode " ) )
strRPC = " test " ;
// Misc warnings like out of disk space and clock is wrong
if ( strMiscWarning ! = " " )
{
nPriority = 1000 ;
strStatusBar = strMiscWarning ;
}
// Longer invalid proof-of-work chain
if ( pindexBest & & bnBestInvalidWork > bnBestChainWork + pindexBest - > GetBlockWork ( ) * 6 )
{
nPriority = 2000 ;
strStatusBar = strRPC = " WARNING: Displayed transactions may not be correct! You may need to upgrade, or other nodes may need to upgrade. " ;
}
// Alerts
CRITICAL_BLOCK ( cs_mapAlerts )
{
foreach ( PAIRTYPE ( const uint256 , CAlert ) & item , mapAlerts )
{
const CAlert & alert = item . second ;
if ( alert . AppliesToMe ( ) & & alert . nPriority > nPriority )
{
nPriority = alert . nPriority ;
strStatusBar = alert . strStatusBar ;
}
}
}
if ( strFor = = " statusbar " )
return strStatusBar ;
else if ( strFor = = " rpc " )
return strRPC ;
assert ( ( " GetWarnings() : invalid parameter " , false ) ) ;
return " error " ;
}
bool CAlert : : ProcessAlert ( )
{
if ( ! CheckSignature ( ) )
return false ;
if ( ! IsInEffect ( ) )
return false ;
CRITICAL_BLOCK ( cs_mapAlerts )
{
// Cancel previous alerts
for ( map < uint256 , CAlert > : : iterator mi = mapAlerts . begin ( ) ; mi ! = mapAlerts . end ( ) ; )
{
const CAlert & alert = ( * mi ) . second ;
if ( Cancels ( alert ) )
{
printf ( " cancelling alert %d \n " , alert . nID ) ;
mapAlerts . erase ( mi + + ) ;
}
else if ( ! alert . IsInEffect ( ) )
{
printf ( " expiring alert %d \n " , alert . nID ) ;
mapAlerts . erase ( mi + + ) ;
}
else
mi + + ;
}
// Check if this alert has been cancelled
foreach ( PAIRTYPE ( const uint256 , CAlert ) & item , mapAlerts )
{
const CAlert & alert = item . second ;
if ( alert . Cancels ( * this ) )
{
printf ( " alert already cancelled by %d \n " , alert . nID ) ;
return false ;
}
}
// Add to mapAlerts
mapAlerts . insert ( make_pair ( GetHash ( ) , * this ) ) ;
}
printf ( " accepted alert %d, AppliesToMe()=%d \n " , nID , AppliesToMe ( ) ) ;
MainFrameRepaint ( ) ;
return true ;
}
//////////////////////////////////////////////////////////////////////////////
//
// Messages
//
bool AlreadyHave ( CTxDB & txdb , const CInv & inv )
{
switch ( inv . type )
{
case MSG_TX : return mapTransactions . count ( inv . hash ) | | mapOrphanTransactions . count ( inv . hash ) | | txdb . ContainsTx ( inv . hash ) ;
case MSG_BLOCK : return mapBlockIndex . count ( inv . hash ) | | mapOrphanBlocks . count ( inv . hash ) ;
}
// Don't know what it is, just say we already got one
return true ;
}
// The message start string is designed to be unlikely to occur in normal data.
// The characters are rarely used upper ascii, not valid as UTF-8, and produce
// a large 4-byte int at any alignment.
char pchMessageStart [ 4 ] = { 0xf9 , 0xbe , 0xb4 , 0xd9 } ;
bool ProcessMessages ( CNode * pfrom )
{
CDataStream & vRecv = pfrom - > vRecv ;
if ( vRecv . empty ( ) )
return true ;
//if (fDebug)
// printf("ProcessMessages(%u bytes)\n", vRecv.size());
//
// Message format
// (4) message start
// (12) command
// (4) size
// (4) checksum
// (x) data
//
loop
{
// Scan for message start
CDataStream : : iterator pstart = search ( vRecv . begin ( ) , vRecv . end ( ) , BEGIN ( pchMessageStart ) , END ( pchMessageStart ) ) ;
int nHeaderSize = vRecv . GetSerializeSize ( CMessageHeader ( ) ) ;
if ( vRecv . end ( ) - pstart < nHeaderSize )
{
if ( vRecv . size ( ) > nHeaderSize )
{
printf ( " \n \n PROCESSMESSAGE MESSAGESTART NOT FOUND \n \n " ) ;
vRecv . erase ( vRecv . begin ( ) , vRecv . end ( ) - nHeaderSize ) ;
}
break ;
}
if ( pstart - vRecv . begin ( ) > 0 )
printf ( " \n \n PROCESSMESSAGE SKIPPED %d BYTES \n \n " , pstart - vRecv . begin ( ) ) ;
vRecv . erase ( vRecv . begin ( ) , pstart ) ;
// Read header
vector < char > vHeaderSave ( vRecv . begin ( ) , vRecv . begin ( ) + nHeaderSize ) ;
CMessageHeader hdr ;
vRecv > > hdr ;
if ( ! hdr . IsValid ( ) )
{
printf ( " \n \n PROCESSMESSAGE: ERRORS IN HEADER %s \n \n \n " , hdr . GetCommand ( ) . c_str ( ) ) ;
continue ;
}
string strCommand = hdr . GetCommand ( ) ;
// Message size
unsigned int nMessageSize = hdr . nMessageSize ;
if ( nMessageSize > MAX_SIZE )
{
printf ( " ProcessMessage(%s, %u bytes) : nMessageSize > MAX_SIZE \n " , strCommand . c_str ( ) , nMessageSize ) ;
continue ;
}
if ( nMessageSize > vRecv . size ( ) )
{
// Rewind and wait for rest of message
vRecv . insert ( vRecv . begin ( ) , vHeaderSave . begin ( ) , vHeaderSave . end ( ) ) ;
break ;
}
// Checksum
if ( vRecv . GetVersion ( ) > = 209 )
{
uint256 hash = Hash ( vRecv . begin ( ) , vRecv . begin ( ) + nMessageSize ) ;
unsigned int nChecksum = 0 ;
memcpy ( & nChecksum , & hash , sizeof ( nChecksum ) ) ;
if ( nChecksum ! = hdr . nChecksum )
{
printf ( " ProcessMessage(%s, %u bytes) : CHECKSUM ERROR nChecksum=%08x hdr.nChecksum=%08x \n " ,
strCommand . c_str ( ) , nMessageSize , nChecksum , hdr . nChecksum ) ;
continue ;
}
}
// Copy message to its own buffer
CDataStream vMsg ( vRecv . begin ( ) , vRecv . begin ( ) + nMessageSize , vRecv . nType , vRecv . nVersion ) ;
vRecv . ignore ( nMessageSize ) ;
// Process message
bool fRet = false ;
try
{
CRITICAL_BLOCK ( cs_main )
fRet = ProcessMessage ( pfrom , strCommand , vMsg ) ;
if ( fShutdown )
return true ;
}
catch ( std : : ios_base : : failure & e )
{
if ( strstr ( e . what ( ) , " end of data " ) )
{
// Allow exceptions from underlength message on vRecv
printf ( " ProcessMessage(%s, %u bytes) : Exception '%s' caught, normally caused by a message being shorter than its stated length \n " , strCommand . c_str ( ) , nMessageSize , e . what ( ) ) ;
}
else if ( strstr ( e . what ( ) , " size too large " ) )
{
// Allow exceptions from overlong size
printf ( " ProcessMessage(%s, %u bytes) : Exception '%s' caught \n " , strCommand . c_str ( ) , nMessageSize , e . what ( ) ) ;
}
else
{
PrintExceptionContinue ( & e , " ProcessMessage() " ) ;
}
}
catch ( std : : exception & e ) {
PrintExceptionContinue ( & e , " ProcessMessage() " ) ;
} catch ( . . . ) {
PrintExceptionContinue ( NULL , " ProcessMessage() " ) ;
}
if ( ! fRet )
printf ( " ProcessMessage(%s, %u bytes) FAILED \n " , strCommand . c_str ( ) , nMessageSize ) ;
}
vRecv . Compact ( ) ;
return true ;
}
bool ProcessMessage ( CNode * pfrom , string strCommand , CDataStream & vRecv )
{
static map < unsigned int , vector < unsigned char > > mapReuseKey ;
RandAddSeedPerfmon ( ) ;
if ( fDebug )
printf ( " %s " , DateTimeStrFormat ( " %x %H:%M:%S " , GetTime ( ) ) . c_str ( ) ) ;
printf ( " received: %s (%d bytes) \n " , strCommand . c_str ( ) , vRecv . size ( ) ) ;
if ( mapArgs . count ( " -dropmessagestest " ) & & GetRand ( atoi ( mapArgs [ " -dropmessagestest " ] ) ) = = 0 )
{
printf ( " dropmessagestest DROPPING RECV MESSAGE \n " ) ;
return true ;
}
if ( strCommand = = " version " )
{
// Each connection can only send one version message
if ( pfrom - > nVersion ! = 0 )
return false ;
int64 nTime ;
CAddress addrMe ;
CAddress addrFrom ;
uint64 nNonce = 1 ;
vRecv > > pfrom - > nVersion > > pfrom - > nServices > > nTime > > addrMe ;
if ( pfrom - > nVersion = = 10300 )
pfrom - > nVersion = 300 ;
if ( pfrom - > nVersion > = 106 & & ! vRecv . empty ( ) )
vRecv > > addrFrom > > nNonce ;
if ( pfrom - > nVersion > = 106 & & ! vRecv . empty ( ) )
vRecv > > pfrom - > strSubVer ;
if ( pfrom - > nVersion > = 209 & & ! vRecv . empty ( ) )
vRecv > > pfrom - > nStartingHeight ;
if ( pfrom - > nVersion = = 0 )
return false ;
// Disconnect if we connected to ourself
if ( nNonce = = nLocalHostNonce & & nNonce > 1 )
{
printf ( " connected to self at %s, disconnecting \n " , pfrom - > addr . ToString ( ) . c_str ( ) ) ;
pfrom - > fDisconnect = true ;
return true ;
}
pfrom - > fClient = ! ( pfrom - > nServices & NODE_NETWORK ) ;
AddTimeData ( pfrom - > addr . ip , nTime ) ;
// Change version
if ( pfrom - > nVersion > = 209 )
pfrom - > PushMessage ( " verack " ) ;
pfrom - > vSend . SetVersion ( min ( pfrom - > nVersion , VERSION ) ) ;
if ( pfrom - > nVersion < 209 )
pfrom - > vRecv . SetVersion ( min ( pfrom - > nVersion , VERSION ) ) ;
if ( ! pfrom - > fInbound )
{
// Advertise our address
if ( addrLocalHost . IsRoutable ( ) & & ! fUseProxy )
{
CAddress addr ( addrLocalHost ) ;
addr . nTime = GetAdjustedTime ( ) ;
pfrom - > PushAddress ( addr ) ;
}
// Get recent addresses
if ( pfrom - > nVersion > = 31402 | | mapAddresses . size ( ) < 1000 )
{
pfrom - > PushMessage ( " getaddr " ) ;
pfrom - > fGetAddr = true ;
}
}
// Ask the first connected node for block updates
static int nAskedForBlocks ;
if ( ! pfrom - > fClient & & ( nAskedForBlocks < 1 | | vNodes . size ( ) < = 1 ) )
{
nAskedForBlocks + + ;
pfrom - > PushGetBlocks ( pindexBest , uint256 ( 0 ) ) ;
}
// Relay alerts
CRITICAL_BLOCK ( cs_mapAlerts )
foreach ( PAIRTYPE ( const uint256 , CAlert ) & item , mapAlerts )
item . second . RelayTo ( pfrom ) ;
pfrom - > fSuccessfullyConnected = true ;
printf ( " version message: version %d, blocks=%d \n " , pfrom - > nVersion , pfrom - > nStartingHeight ) ;
}
else if ( pfrom - > nVersion = = 0 )
{
// Must have a version message before anything else
return false ;
}
else if ( strCommand = = " verack " )
{
pfrom - > vRecv . SetVersion ( min ( pfrom - > nVersion , VERSION ) ) ;
}
else if ( strCommand = = " addr " )
{
vector < CAddress > vAddr ;
vRecv > > vAddr ;
// Don't want addr from older versions unless seeding
if ( pfrom - > nVersion < 209 )
return true ;
if ( pfrom - > nVersion < 31402 & & mapAddresses . size ( ) > 1000 )
return true ;
if ( vAddr . size ( ) > 1000 )
return error ( " message addr size() = % d " , vAddr.size()) ;
// Store the new addresses
int64 nNow = GetAdjustedTime ( ) ;
int64 nSince = nNow - 10 * 60 ;
foreach ( CAddress & addr , vAddr )
{
if ( fShutdown )
return true ;
// ignore IPv6 for now, since it isn't implemented anyway
if ( ! addr . IsIPv4 ( ) )
continue ;
if ( addr . nTime < = 100000000 | | addr . nTime > nNow + 10 * 60 )
addr . nTime = nNow - 5 * 24 * 60 * 60 ;
AddAddress ( addr , 2 * 60 * 60 ) ;
pfrom - > AddAddressKnown ( addr ) ;
if ( addr . nTime > nSince & & ! pfrom - > fGetAddr & & vAddr . size ( ) < = 10 & & addr . IsRoutable ( ) )
{
// Relay to a limited number of other nodes
CRITICAL_BLOCK ( cs_vNodes )
{
// Use deterministic randomness to send to the same nodes for 24 hours
// at a time so the setAddrKnowns of the chosen nodes prevent repeats
static uint256 hashSalt ;
if ( hashSalt = = 0 )
RAND_bytes ( ( unsigned char * ) & hashSalt , sizeof ( hashSalt ) ) ;
uint256 hashRand = hashSalt ^ ( ( ( int64 ) addr . ip ) < < 32 ) ^ ( ( GetTime ( ) + addr . ip ) / ( 24 * 60 * 60 ) ) ;
hashRand = Hash ( BEGIN ( hashRand ) , END ( hashRand ) ) ;
multimap < uint256 , CNode * > mapMix ;
foreach ( CNode * pnode , vNodes )
{
if ( pnode - > nVersion < 31402 )
continue ;
unsigned int nPointer ;
memcpy ( & nPointer , & pnode , sizeof ( nPointer ) ) ;
uint256 hashKey = hashRand ^ nPointer ;
hashKey = Hash ( BEGIN ( hashKey ) , END ( hashKey ) ) ;
mapMix . insert ( make_pair ( hashKey , pnode ) ) ;
}
int nRelayNodes = 2 ;
for ( multimap < uint256 , CNode * > : : iterator mi = mapMix . begin ( ) ; mi ! = mapMix . end ( ) & & nRelayNodes - - > 0 ; + + mi )
( ( * mi ) . second ) - > PushAddress ( addr ) ;
}
}
}
if ( vAddr . size ( ) < 1000 )
pfrom - > fGetAddr = false ;
}
else if ( strCommand = = " inv " )
{
vector < CInv > vInv ;
vRecv > > vInv ;
if ( vInv . size ( ) > 50000 )
return error ( " message inv size() = % d " , vInv.size()) ;
CTxDB txdb ( " r " ) ;
foreach ( const CInv & inv , vInv )
{
if ( fShutdown )
return true ;
pfrom - > AddInventoryKnown ( inv ) ;
bool fAlreadyHave = AlreadyHave ( txdb , inv ) ;
printf ( " got inventory: %s %s \n " , inv . ToString ( ) . c_str ( ) , fAlreadyHave ? " have " : " new " ) ;
if ( ! fAlreadyHave )
pfrom - > AskFor ( inv ) ;
else if ( inv . type = = MSG_BLOCK & & mapOrphanBlocks . count ( inv . hash ) )
pfrom - > PushGetBlocks ( pindexBest , GetOrphanRoot ( mapOrphanBlocks [ inv . hash ] ) ) ;
// Track requests for our stuff
CRITICAL_BLOCK ( cs_mapRequestCount )
{
map < uint256 , int > : : iterator mi = mapRequestCount . find ( inv . hash ) ;
if ( mi ! = mapRequestCount . end ( ) )
( * mi ) . second + + ;
}
}
}
else if ( strCommand = = " getdata " )
{
vector < CInv > vInv ;
vRecv > > vInv ;
if ( vInv . size ( ) > 50000 )
return error ( " message getdata size() = % d " , vInv.size()) ;
foreach ( const CInv & inv , vInv )
{
if ( fShutdown )
return true ;
printf ( " received getdata for: %s \n " , inv . ToString ( ) . c_str ( ) ) ;
if ( inv . type = = MSG_BLOCK )
{
// Send block from disk
map < uint256 , CBlockIndex * > : : iterator mi = mapBlockIndex . find ( inv . hash ) ;
if ( mi ! = mapBlockIndex . end ( ) )
{
CBlock block ;
block . ReadFromDisk ( ( * mi ) . second ) ;
pfrom - > PushMessage ( " block " , block ) ;
// Trigger them to send a getblocks request for the next batch of inventory
if ( inv . hash = = pfrom - > hashContinue )
{
// Bypass PushInventory, this must send even if redundant,
// and we want it right after the last block so they don't
// wait for other stuff first.
vector < CInv > vInv ;
vInv . push_back ( CInv ( MSG_BLOCK , hashBestChain ) ) ;
pfrom - > PushMessage ( " inv " , vInv ) ;
pfrom - > hashContinue = 0 ;
}
}
}
else if ( inv . IsKnownType ( ) )
{
// Send stream from relay memory
CRITICAL_BLOCK ( cs_mapRelay )
{
map < CInv , CDataStream > : : iterator mi = mapRelay . find ( inv ) ;
if ( mi ! = mapRelay . end ( ) )
pfrom - > PushMessage ( inv . GetCommand ( ) , ( * mi ) . second ) ;
}
}
// Track requests for our stuff
CRITICAL_BLOCK ( cs_mapRequestCount )
{
map < uint256 , int > : : iterator mi = mapRequestCount . find ( inv . hash ) ;
if ( mi ! = mapRequestCount . end ( ) )
( * mi ) . second + + ;
}
}
}
else if ( strCommand = = " getblocks " )
{
CBlockLocator locator ;
uint256 hashStop ;
vRecv > > locator > > hashStop ;
// Find the last block the caller has in the main chain
CBlockIndex * pindex = locator . GetBlockIndex ( ) ;
// Send the rest of the chain
if ( pindex )
pindex = pindex - > pnext ;
int nLimit = 500 + locator . GetDistanceBack ( ) ;
printf ( " getblocks %d to %s limit %d \n " , ( pindex ? pindex - > nHeight : - 1 ) , hashStop . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) , nLimit ) ;
for ( ; pindex ; pindex = pindex - > pnext )
{
if ( pindex - > GetBlockHash ( ) = = hashStop )
{
printf ( " getblocks stopping at %d %s \n " , pindex - > nHeight , pindex - > GetBlockHash ( ) . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) ) ;
break ;
}
pfrom - > PushInventory ( CInv ( MSG_BLOCK , pindex - > GetBlockHash ( ) ) ) ;
if ( - - nLimit < = 0 )
{
// When this block is requested, we'll send an inv that'll make them
// getblocks the next batch of inventory.
printf ( " getblocks stopping at limit %d %s \n " , pindex - > nHeight , pindex - > GetBlockHash ( ) . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) ) ;
pfrom - > hashContinue = pindex - > GetBlockHash ( ) ;
break ;
}
}
}
else if ( strCommand = = " getheaders " )
{
CBlockLocator locator ;
uint256 hashStop ;
vRecv > > locator > > hashStop ;
CBlockIndex * pindex = NULL ;
if ( locator . IsNull ( ) )
{
// If locator is null, return the hashStop block
map < uint256 , CBlockIndex * > : : iterator mi = mapBlockIndex . find ( hashStop ) ;
if ( mi = = mapBlockIndex . end ( ) )
return true ;
pindex = ( * mi ) . second ;
}
else
{
// Find the last block the caller has in the main chain
pindex = locator . GetBlockIndex ( ) ;
if ( pindex )
pindex = pindex - > pnext ;
}
vector < CBlock > vHeaders ;
int nLimit = 2000 + locator . GetDistanceBack ( ) ;
printf ( " getheaders %d to %s limit %d \n " , ( pindex ? pindex - > nHeight : - 1 ) , hashStop . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) , nLimit ) ;
for ( ; pindex ; pindex = pindex - > pnext )
{
vHeaders . push_back ( pindex - > GetBlockHeader ( ) ) ;
if ( - - nLimit < = 0 | | pindex - > GetBlockHash ( ) = = hashStop )
break ;
}
pfrom - > PushMessage ( " headers " , vHeaders ) ;
}
else if ( strCommand = = " tx " )
{
vector < uint256 > vWorkQueue ;
CDataStream vMsg ( vRecv ) ;
CTransaction tx ;
vRecv > > tx ;
CInv inv ( MSG_TX , tx . GetHash ( ) ) ;
pfrom - > AddInventoryKnown ( inv ) ;
bool fMissingInputs = false ;
if ( tx . AcceptToMemoryPool ( true , & fMissingInputs ) )
{
AddToWalletIfMine ( tx , NULL ) ;
RelayMessage ( inv , vMsg ) ;
mapAlreadyAskedFor . erase ( inv ) ;
vWorkQueue . push_back ( inv . hash ) ;
// Recursively process any orphan transactions that depended on this one
for ( int i = 0 ; i < vWorkQueue . size ( ) ; i + + )
{
uint256 hashPrev = vWorkQueue [ i ] ;
for ( multimap < uint256 , CDataStream * > : : iterator mi = mapOrphanTransactionsByPrev . lower_bound ( hashPrev ) ;
mi ! = mapOrphanTransactionsByPrev . upper_bound ( hashPrev ) ;
+ + mi )
{
const CDataStream & vMsg = * ( ( * mi ) . second ) ;
CTransaction tx ;
CDataStream ( vMsg ) > > tx ;
CInv inv ( MSG_TX , tx . GetHash ( ) ) ;
if ( tx . AcceptToMemoryPool ( true ) )
{
printf ( " accepted orphan tx %s \n " , inv . hash . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) ) ;
AddToWalletIfMine ( tx , NULL ) ;
RelayMessage ( inv , vMsg ) ;
mapAlreadyAskedFor . erase ( inv ) ;
vWorkQueue . push_back ( inv . hash ) ;
}
}
}
foreach ( uint256 hash , vWorkQueue )
EraseOrphanTx ( hash ) ;
}
else if ( fMissingInputs )
{
printf ( " storing orphan tx %s \n " , inv . hash . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) ) ;
AddOrphanTx ( vMsg ) ;
}
}
else if ( strCommand = = " block " )
{
CBlock block ;
vRecv > > block ;
printf ( " received block %s \n " , block . GetHash ( ) . ToString ( ) . substr ( 0 , 20 ) . c_str ( ) ) ;
// block.print();
CInv inv ( MSG_BLOCK , block . GetHash ( ) ) ;
pfrom - > AddInventoryKnown ( inv ) ;
if ( ProcessBlock ( pfrom , & block ) )
mapAlreadyAskedFor . erase ( inv ) ;
}
else if ( strCommand = = " getaddr " )
{
// Nodes rebroadcast an addr every 24 hours
pfrom - > vAddrToSend . clear ( ) ;
int64 nSince = GetAdjustedTime ( ) - 3 * 60 * 60 ; // in the last 3 hours
CRITICAL_BLOCK ( cs_mapAddresses )
{
unsigned int nCount = 0 ;
foreach ( const PAIRTYPE ( vector < unsigned char > , CAddress ) & item , mapAddresses )
{
const CAddress & addr = item . second ;
if ( addr . nTime > nSince )
nCount + + ;
}
foreach ( const PAIRTYPE ( vector < unsigned char > , CAddress ) & item , mapAddresses )
{
const CAddress & addr = item . second ;
if ( addr . nTime > nSince & & GetRand ( nCount ) < 2500 )
pfrom - > PushAddress ( addr ) ;
}
}
}
else if ( strCommand = = " checkorder " )
{
uint256 hashReply ;
vRecv > > hashReply ;
if ( ! GetBoolArg ( " -allowreceivebyip " ) )
{
pfrom - > PushMessage ( " reply " , hashReply , ( int ) 2 , string ( " " ) ) ;
return true ;
}
CWalletTx order ;
vRecv > > order ;
/// we have a chance to check the order here
// Keep giving the same key to the same ip until they use it
if ( ! mapReuseKey . count ( pfrom - > addr . ip ) )
mapReuseKey [ pfrom - > addr . ip ] = GetKeyFromKeyPool ( ) ;
// Send back approval of order and pubkey to use
CScript scriptPubKey ;
scriptPubKey < < mapReuseKey [ pfrom - > addr . ip ] < < OP_CHECKSIG ;
pfrom - > PushMessage ( " reply " , hashReply , ( int ) 0 , scriptPubKey ) ;
}
else if ( strCommand = = " submitorder " )
{
uint256 hashReply ;
vRecv > > hashReply ;
if ( ! GetBoolArg ( " -allowreceivebyip " ) )
{
pfrom - > PushMessage ( " reply " , hashReply , ( int ) 2 ) ;
return true ;
}
CWalletTx wtxNew ;
vRecv > > wtxNew ;
wtxNew . fFromMe = false ;
// Broadcast
if ( ! wtxNew . AcceptWalletTransaction ( ) )
{
pfrom - > PushMessage ( " reply " , hashReply , ( int ) 1 ) ;
return error ( " submitorder AcceptWalletTransaction() failed , returning error 1 " ) ;
}
wtxNew . fTimeReceivedIsTxTime = true ;
AddToWallet ( wtxNew ) ;
wtxNew . RelayWalletTransaction ( ) ;
mapReuseKey . erase ( pfrom - > addr . ip ) ;
// Send back confirmation
pfrom - > PushMessage ( " reply " , hashReply , ( int ) 0 ) ;
}
else if ( strCommand = = " reply " )
{
uint256 hashReply ;
vRecv > > hashReply ;
CRequestTracker tracker ;
CRITICAL_BLOCK ( pfrom - > cs_mapRequests )
{
map < uint256 , CRequestTracker > : : iterator mi = pfrom - > mapRequests . find ( hashReply ) ;
if ( mi ! = pfrom - > mapRequests . end ( ) )
{
tracker = ( * mi ) . second ;
pfrom - > mapRequests . erase ( mi ) ;
}
}
if ( ! tracker . IsNull ( ) )
tracker . fn ( tracker . param1 , vRecv ) ;
}
else if ( strCommand = = " ping " )
{
}
else if ( strCommand = = " alert " )
{
CAlert alert ;
vRecv > > alert ;
if ( alert . ProcessAlert ( ) )
{
// Relay
pfrom - > setKnown . insert ( alert . GetHash ( ) ) ;
CRITICAL_BLOCK ( cs_vNodes )
foreach ( CNode * pnode , vNodes )
alert . RelayTo ( pnode ) ;
}
}
else
{
// Ignore unknown commands for extensibility
}
// Update the last seen time for this node's address
if ( pfrom - > fNetworkNode )
if ( strCommand = = " version " | | strCommand = = " addr " | | strCommand = = " inv " | | strCommand = = " getdata " | | strCommand = = " ping " )
AddressCurrentlyConnected ( pfrom - > addr ) ;
return true ;
}
bool SendMessages ( CNode * pto , bool fSendTrickle )
{
CRITICAL_BLOCK ( cs_main )
{
// Don't send anything until we get their version message
if ( pto - > nVersion = = 0 )
return true ;
// Keep-alive ping
if ( pto - > nLastSend & & GetTime ( ) - pto - > nLastSend > 30 * 60 & & pto - > vSend . empty ( ) )
pto - > PushMessage ( " ping " ) ;
// Resend wallet transactions that haven't gotten in a block yet
ResendWalletTransactions ( ) ;
// Address refresh broadcast
static int64 nLastRebroadcast ;
if ( GetTime ( ) - nLastRebroadcast > 24 * 60 * 60 )
{
nLastRebroadcast = GetTime ( ) ;
CRITICAL_BLOCK ( cs_vNodes )
{
foreach ( CNode * pnode , vNodes )
{
// Periodically clear setAddrKnown to allow refresh broadcasts
pnode - > setAddrKnown . clear ( ) ;
// Rebroadcast our address
if ( addrLocalHost . IsRoutable ( ) & & ! fUseProxy )
{
CAddress addr ( addrLocalHost ) ;
addr . nTime = GetAdjustedTime ( ) ;
pnode - > PushAddress ( addr ) ;
}
}
}
}
// Clear out old addresses periodically so it's not too much work at once
static int64 nLastClear ;
if ( nLastClear = = 0 )
nLastClear = GetTime ( ) ;
if ( GetTime ( ) - nLastClear > 10 * 60 & & vNodes . size ( ) > = 3 )
{
nLastClear = GetTime ( ) ;
CRITICAL_BLOCK ( cs_mapAddresses )
{
CAddrDB addrdb ;
int64 nSince = GetAdjustedTime ( ) - 14 * 24 * 60 * 60 ;
for ( map < vector < unsigned char > , CAddress > : : iterator mi = mapAddresses . begin ( ) ;
mi ! = mapAddresses . end ( ) ; )
{
const CAddress & addr = ( * mi ) . second ;
if ( addr . nTime < nSince )
{
if ( mapAddresses . size ( ) < 1000 | | GetTime ( ) > nLastClear + 20 )
break ;
addrdb . EraseAddress ( addr ) ;
mapAddresses . erase ( mi + + ) ;
}
else
mi + + ;
}
}
}
//
// Message: addr
//
if ( fSendTrickle )
{
vector < CAddress > vAddr ;
vAddr . reserve ( pto - > vAddrToSend . size ( ) ) ;
foreach ( const CAddress & addr , pto - > vAddrToSend )
{
// returns true if wasn't already contained in the set
if ( pto - > setAddrKnown . insert ( addr ) . second )
{
vAddr . push_back ( addr ) ;
// receiver rejects addr messages larger than 1000
if ( vAddr . size ( ) > = 1000 )
{
pto - > PushMessage ( " addr " , vAddr ) ;
vAddr . clear ( ) ;
}
}
}
pto - > vAddrToSend . clear ( ) ;
if ( ! vAddr . empty ( ) )
pto - > PushMessage ( " addr " , vAddr ) ;
}
//
// Message: inventory
//
vector < CInv > vInv ;
vector < CInv > vInvWait ;
CRITICAL_BLOCK ( pto - > cs_inventory )
{
vInv . reserve ( pto - > vInventoryToSend . size ( ) ) ;
vInvWait . reserve ( pto - > vInventoryToSend . size ( ) ) ;
foreach ( const CInv & inv , pto - > vInventoryToSend )
{
if ( pto - > setInventoryKnown . count ( inv ) )
continue ;
// trickle out tx inv to protect privacy
if ( inv . type = = MSG_TX & & ! fSendTrickle )
{
// 1/4 of tx invs blast to all immediately
static uint256 hashSalt ;
if ( hashSalt = = 0 )
RAND_bytes ( ( unsigned char * ) & hashSalt , sizeof ( hashSalt ) ) ;
uint256 hashRand = inv . hash ^ hashSalt ;
hashRand = Hash ( BEGIN ( hashRand ) , END ( hashRand ) ) ;
bool fTrickleWait = ( ( hashRand & 3 ) ! = 0 ) ;
// always trickle our own transactions
if ( ! fTrickleWait )
{
TRY_CRITICAL_BLOCK ( cs_mapWallet )
{
map < uint256 , CWalletTx > : : iterator mi = mapWallet . find ( inv . hash ) ;
if ( mi ! = mapWallet . end ( ) )
{
CWalletTx & wtx = ( * mi ) . second ;
if ( wtx . fFromMe )
fTrickleWait = true ;
}
}
}
if ( fTrickleWait )
{
vInvWait . push_back ( inv ) ;
continue ;
}
}
// returns true if wasn't already contained in the set
if ( pto - > setInventoryKnown . insert ( inv ) . second )
{
vInv . push_back ( inv ) ;
if ( vInv . size ( ) > = 1000 )
{
pto - > PushMessage ( " inv " , vInv ) ;
vInv . clear ( ) ;
}
}
}
pto - > vInventoryToSend = vInvWait ;
}
if ( ! vInv . empty ( ) )
pto - > PushMessage ( " inv " , vInv ) ;
//
// Message: getdata
//
vector < CInv > vGetData ;
int64 nNow = GetTime ( ) * 1000000 ;
CTxDB txdb ( " r " ) ;
while ( ! pto - > mapAskFor . empty ( ) & & ( * pto - > mapAskFor . begin ( ) ) . first < = nNow )
{
const CInv & inv = ( * pto - > mapAskFor . begin ( ) ) . second ;
if ( ! AlreadyHave ( txdb , inv ) )
{
printf ( " sending getdata: %s \n " , inv . ToString ( ) . c_str ( ) ) ;
vGetData . push_back ( inv ) ;
if ( vGetData . size ( ) > = 1000 )
{
pto - > PushMessage ( " getdata " , vGetData ) ;
vGetData . clear ( ) ;
}
}
pto - > mapAskFor . erase ( pto - > mapAskFor . begin ( ) ) ;
}
if ( ! vGetData . empty ( ) )
pto - > PushMessage ( " getdata " , vGetData ) ;
}
return true ;
}
//////////////////////////////////////////////////////////////////////////////
//
// BitcoinMiner
//
void GenerateBitcoins ( bool fGenerate )
{
if ( fGenerateBitcoins ! = fGenerate )
{
fGenerateBitcoins = fGenerate ;
CWalletDB ( ) . WriteSetting ( " fGenerateBitcoins " , fGenerateBitcoins ) ;
MainFrameRepaint ( ) ;
}
if ( fGenerateBitcoins )
{
int nProcessors = boost : : thread : : hardware_concurrency ( ) ;
printf ( " %d processors \n " , nProcessors ) ;
if ( nProcessors < 1 )
nProcessors = 1 ;
if ( fLimitProcessors & & nProcessors > nLimitProcessors )
nProcessors = nLimitProcessors ;
int nAddThreads = nProcessors - vnThreadsRunning [ 3 ] ;
printf ( " Starting %d BitcoinMiner threads \n " , nAddThreads ) ;
for ( int i = 0 ; i < nAddThreads ; i + + )
{
if ( ! CreateThread ( ThreadBitcoinMiner , NULL ) )
printf ( " Error: CreateThread(ThreadBitcoinMiner) failed \n " ) ;
Sleep ( 10 ) ;
}
}
}
void ThreadBitcoinMiner ( void * parg )
{
try
{
vnThreadsRunning [ 3 ] + + ;
BitcoinMiner ( ) ;
vnThreadsRunning [ 3 ] - - ;
}
catch ( std : : exception & e ) {
vnThreadsRunning [ 3 ] - - ;
PrintException ( & e , " ThreadBitcoinMiner() " ) ;
} catch ( . . . ) {
vnThreadsRunning [ 3 ] - - ;
PrintException ( NULL , " ThreadBitcoinMiner() " ) ;
}
UIThreadCall ( boost : : bind ( CalledSetStatusBar , " " , 0 ) ) ;
nHPSTimerStart = 0 ;
if ( vnThreadsRunning [ 3 ] = = 0 )
dHashesPerSec = 0 ;
printf ( " ThreadBitcoinMiner exiting, %d threads remaining \n " , vnThreadsRunning [ 3 ] ) ;
}
# if defined(__GNUC__) && defined(CRYPTOPP_X86_ASM_AVAILABLE)
void CallCPUID ( int in , int & aret , int & cret )
{
int a , c ;
asm (
" mov %2, %%eax; " // in into eax
" cpuid; "
" mov %%eax, %0; " // eax into a
" mov %%ecx, %1; " // ecx into c
: " =r " ( a ) , " =r " ( c ) /* output */
: " r " ( in ) /* input */
: " %eax " , " %ebx " , " %ecx " , " %edx " /* clobbered register */
) ;
aret = a ;
cret = c ;
}
bool Detect128BitSSE2 ( )
{
int a , c , nBrand ;
CallCPUID ( 0 , a , nBrand ) ;
bool fIntel = ( nBrand = = 0x6c65746e ) ; // ntel
bool fAMD = ( nBrand = = 0x444d4163 ) ; // cAMD
struct
{
unsigned int nStepping : 4 ;
unsigned int nModel : 4 ;
unsigned int nFamily : 4 ;
unsigned int nProcessorType : 2 ;
unsigned int nUnused : 2 ;
unsigned int nExtendedModel : 4 ;
unsigned int nExtendedFamily : 8 ;
}
cpu ;
CallCPUID ( 1 , a , c ) ;
memcpy ( & cpu , & a , sizeof ( cpu ) ) ;
int nFamily = cpu . nExtendedFamily + cpu . nFamily ;
int nModel = cpu . nExtendedModel * 16 + cpu . nModel ;
// We need Intel Nehalem or AMD K10 or better for 128bit SSE2
// Nehalem = i3/i5/i7 and some Xeon
// K10 = Opterons with 4 or more cores, Phenom, Phenom II, Athlon II
// Intel Core i5 family 6, model 26 or 30
// Intel Core i7 family 6, model 26 or 30
// Intel Core i3 family 6, model 37
// AMD Phenom family 16, model 10
bool fUseSSE2 = ( ( fIntel & & nFamily * 10000 + nModel > = 60026 ) | |
( fAMD & & nFamily * 10000 + nModel > = 160010 ) ) ;
// AMD reports a lower model number in 64-bit mode
if ( fAMD & & sizeof ( void * ) > 4 & & nFamily * 10000 + nModel > = 160000 )
fUseSSE2 = true ;
static bool fPrinted ;
if ( ! fPrinted )
{
fPrinted = true ;
printf ( " CPUID %08x family %d, model %d, stepping %d, fUseSSE2=%d \n " , nBrand , nFamily , nModel , cpu . nStepping , fUseSSE2 ) ;
}
return fUseSSE2 ;
}
# else
bool Detect128BitSSE2 ( ) { return false ; }
# endif
int FormatHashBlocks ( void * pbuffer , unsigned int len )
{
unsigned char * pdata = ( unsigned char * ) pbuffer ;
unsigned int blocks = 1 + ( ( len + 8 ) / 64 ) ;
unsigned char * pend = pdata + 64 * blocks ;
memset ( pdata + len , 0 , 64 * blocks - len ) ;
pdata [ len ] = 0x80 ;
unsigned int bits = len * 8 ;
pend [ - 1 ] = ( bits > > 0 ) & 0xff ;
pend [ - 2 ] = ( bits > > 8 ) & 0xff ;
pend [ - 3 ] = ( bits > > 16 ) & 0xff ;
pend [ - 4 ] = ( bits > > 24 ) & 0xff ;
return blocks ;
}
using CryptoPP : : ByteReverse ;
static const unsigned int pSHA256InitState [ 8 ] =
{ 0x6a09e667 , 0xbb67ae85 , 0x3c6ef372 , 0xa54ff53a , 0x510e527f , 0x9b05688c , 0x1f83d9ab , 0x5be0cd19 } ;
inline void SHA256Transform ( void * pstate , void * pinput , const void * pinit )
{
memcpy ( pstate , pinit , 32 ) ;
CryptoPP : : SHA256 : : Transform ( ( CryptoPP : : word32 * ) pstate , ( CryptoPP : : word32 * ) pinput ) ;
}
//
// ScanHash scans nonces looking for a hash with at least some zero bits.
// It operates on big endian data. Caller does the byte reversing.
// All input buffers are 16-byte aligned. nNonce is usually preserved
// between calls, but periodically or if nNonce is 0xffff0000 or above,
// the block is rebuilt and nNonce starts over at zero.
//
unsigned int ScanHash_CryptoPP ( char * pmidstate , char * pdata , char * phash1 , char * phash , unsigned int & nHashesDone )
{
unsigned int & nNonce = * ( unsigned int * ) ( pdata + 12 ) ;
for ( ; ; )
{
// Crypto++ SHA-256
// Hash pdata using pmidstate as the starting state into
// preformatted buffer phash1, then hash phash1 into phash
nNonce + + ;
SHA256Transform ( phash1 , pdata , pmidstate ) ;
SHA256Transform ( phash , phash1 , pSHA256InitState ) ;
// Return the nonce if the hash has at least some zero bits,
// caller will check if it has enough to reach the target
if ( ( ( unsigned short * ) phash ) [ 14 ] = = 0 )
return nNonce ;
// If nothing found after trying for a while, return -1
if ( ( nNonce & 0xffff ) = = 0 )
{
nHashesDone = 0xffff + 1 ;
return - 1 ;
}
}
}
extern unsigned int ScanHash_4WaySSE2 ( char * pmidstate , char * pblock , char * phash1 , char * phash , unsigned int & nHashesDone ) ;
class COrphan
{
public :
CTransaction * ptx ;
set < uint256 > setDependsOn ;
double dPriority ;
COrphan ( CTransaction * ptxIn )
{
ptx = ptxIn ;
dPriority = 0 ;
}
void print ( ) const
{
printf ( " COrphan(hash=%s, dPriority=%.1f) \n " , ptx - > GetHash ( ) . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) , dPriority ) ;
foreach ( uint256 hash , setDependsOn )
printf ( " setDependsOn %s \n " , hash . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) ) ;
}
} ;
CBlock * CreateNewBlock ( CReserveKey & reservekey )
{
CBlockIndex * pindexPrev = pindexBest ;
// Create new block
auto_ptr < CBlock > pblock ( new CBlock ( ) ) ;
if ( ! pblock . get ( ) )
return NULL ;
// Create coinbase tx
CTransaction txNew ;
txNew . vin . resize ( 1 ) ;
txNew . vin [ 0 ] . prevout . SetNull ( ) ;
txNew . vout . resize ( 1 ) ;
txNew . vout [ 0 ] . scriptPubKey < < reservekey . GetReservedKey ( ) < < OP_CHECKSIG ;
// Add our coinbase tx as first transaction
pblock - > vtx . push_back ( txNew ) ;
// Collect memory pool transactions into the block
int64 nFees = 0 ;
CRITICAL_BLOCK ( cs_main )
CRITICAL_BLOCK ( cs_mapTransactions )
{
CTxDB txdb ( " r " ) ;
// Priority order to process transactions
list < COrphan > vOrphan ; // list memory doesn't move
map < uint256 , vector < COrphan * > > mapDependers ;
multimap < double , CTransaction * > mapPriority ;
for ( map < uint256 , CTransaction > : : iterator mi = mapTransactions . begin ( ) ; mi ! = mapTransactions . end ( ) ; + + mi )
{
CTransaction & tx = ( * mi ) . second ;
if ( tx . IsCoinBase ( ) | | ! tx . IsFinal ( ) )
continue ;
COrphan * porphan = NULL ;
double dPriority = 0 ;
foreach ( const CTxIn & txin , tx . vin )
{
// Read prev transaction
CTransaction txPrev ;
CTxIndex txindex ;
if ( ! txPrev . ReadFromDisk ( txdb , txin . prevout , txindex ) )
{
// Has to wait for dependencies
if ( ! porphan )
{
// Use list for automatic deletion
vOrphan . push_back ( COrphan ( & tx ) ) ;
porphan = & vOrphan . back ( ) ;
}
mapDependers [ txin . prevout . hash ] . push_back ( porphan ) ;
porphan - > setDependsOn . insert ( txin . prevout . hash ) ;
continue ;
}
int64 nValueIn = txPrev . vout [ txin . prevout . n ] . nValue ;
// Read block header
int nConf = txindex . GetDepthInMainChain ( ) ;
dPriority + = ( double ) nValueIn * nConf ;
if ( fDebug & & GetBoolArg ( " -printpriority " ) )
printf ( " priority nValueIn=%-12I64d nConf=%-5d dPriority=%-20.1f \n " , nValueIn , nConf , dPriority ) ;
}
// Priority is sum(valuein * age) / txsize
dPriority / = : : GetSerializeSize ( tx , SER_NETWORK ) ;
if ( porphan )
porphan - > dPriority = dPriority ;
else
mapPriority . insert ( make_pair ( - dPriority , & ( * mi ) . second ) ) ;
if ( fDebug & & GetBoolArg ( " -printpriority " ) )
{
printf ( " priority %-20.1f %s \n %s " , dPriority , tx . GetHash ( ) . ToString ( ) . substr ( 0 , 10 ) . c_str ( ) , tx . ToString ( ) . c_str ( ) ) ;
if ( porphan )
porphan - > print ( ) ;
printf ( " \n " ) ;
}
}
// Collect transactions into block
map < uint256 , CTxIndex > mapTestPool ;
uint64 nBlockSize = 1000 ;
int nBlockSigOps = 100 ;
while ( ! mapPriority . empty ( ) )
{
// Take highest priority transaction off priority queue
double dPriority = - ( * mapPriority . begin ( ) ) . first ;
CTransaction & tx = * ( * mapPriority . begin ( ) ) . second ;
mapPriority . erase ( mapPriority . begin ( ) ) ;
// Size limits
unsigned int nTxSize = : : GetSerializeSize ( tx , SER_NETWORK ) ;
if ( nBlockSize + nTxSize > = MAX_BLOCK_SIZE_GEN )
continue ;
int nTxSigOps = tx . GetSigOpCount ( ) ;
if ( nBlockSigOps + nTxSigOps > = MAX_BLOCK_SIGOPS )
continue ;
// Transaction fee required depends on block size
bool fAllowFree = ( nBlockSize + nTxSize < 4000 | | CTransaction : : AllowFree ( dPriority ) ) ;
int64 nMinFee = tx . GetMinFee ( nBlockSize , fAllowFree ) ;
// Connecting shouldn't fail due to dependency on other memory pool transactions
// because we're already processing them in order of dependency
map < uint256 , CTxIndex > mapTestPoolTmp ( mapTestPool ) ;
if ( ! tx . ConnectInputs ( txdb , mapTestPoolTmp , CDiskTxPos ( 1 , 1 , 1 ) , pindexPrev , nFees , false , true , nMinFee ) )
continue ;
swap ( mapTestPool , mapTestPoolTmp ) ;
// Added
pblock - > vtx . push_back ( tx ) ;
nBlockSize + = nTxSize ;
nBlockSigOps + = nTxSigOps ;
// Add transactions that depend on this one to the priority queue
uint256 hash = tx . GetHash ( ) ;
if ( mapDependers . count ( hash ) )
{
foreach ( COrphan * porphan , mapDependers [ hash ] )
{
if ( ! porphan - > setDependsOn . empty ( ) )
{
porphan - > setDependsOn . erase ( hash ) ;
if ( porphan - > setDependsOn . empty ( ) )
mapPriority . insert ( make_pair ( - porphan - > dPriority , porphan - > ptx ) ) ;
}
}
}
}
}
pblock - > vtx [ 0 ] . vout [ 0 ] . nValue = GetBlockValue ( pindexPrev - > nHeight + 1 , nFees ) ;
// Fill in header
pblock - > hashPrevBlock = pindexPrev - > GetBlockHash ( ) ;
pblock - > hashMerkleRoot = pblock - > BuildMerkleTree ( ) ;
pblock - > nTime = max ( pindexPrev - > GetMedianTimePast ( ) + 1 , GetAdjustedTime ( ) ) ;
pblock - > nBits = GetNextWorkRequired ( pindexPrev ) ;
pblock - > nNonce = 0 ;
return pblock . release ( ) ;
}
void IncrementExtraNonce ( CBlock * pblock , CBlockIndex * pindexPrev , unsigned int & nExtraNonce , int64 & nPrevTime )
{
// Update nExtraNonce
int64 nNow = max ( pindexPrev - > GetMedianTimePast ( ) + 1 , GetAdjustedTime ( ) ) ;
if ( + + nExtraNonce > = 0x7f & & nNow > nPrevTime + 1 )
{
nExtraNonce = 1 ;
nPrevTime = nNow ;
}
pblock - > vtx [ 0 ] . vin [ 0 ] . scriptSig = CScript ( ) < < pblock - > nBits < < CBigNum ( nExtraNonce ) ;
pblock - > hashMerkleRoot = pblock - > BuildMerkleTree ( ) ;
}
void FormatHashBuffers ( CBlock * pblock , char * pmidstate , char * pdata , char * phash1 )
{
//
// Prebuild hash buffers
//
struct
{
struct unnamed2
{
int nVersion ;
uint256 hashPrevBlock ;
uint256 hashMerkleRoot ;
unsigned int nTime ;
unsigned int nBits ;
unsigned int nNonce ;
}
block ;
unsigned char pchPadding0 [ 64 ] ;
uint256 hash1 ;
unsigned char pchPadding1 [ 64 ] ;
}
tmp ;
memset ( & tmp , 0 , sizeof ( tmp ) ) ;
tmp . block . nVersion = pblock - > nVersion ;
tmp . block . hashPrevBlock = pblock - > hashPrevBlock ;
tmp . block . hashMerkleRoot = pblock - > hashMerkleRoot ;
tmp . block . nTime = pblock - > nTime ;
tmp . block . nBits = pblock - > nBits ;
tmp . block . nNonce = pblock - > nNonce ;
FormatHashBlocks ( & tmp . block , sizeof ( tmp . block ) ) ;
FormatHashBlocks ( & tmp . hash1 , sizeof ( tmp . hash1 ) ) ;
// Byte swap all the input buffer
for ( int i = 0 ; i < sizeof ( tmp ) / 4 ; i + + )
( ( unsigned int * ) & tmp ) [ i ] = ByteReverse ( ( ( unsigned int * ) & tmp ) [ i ] ) ;
// Precalc the first half of the first hash, which stays constant
SHA256Transform ( pmidstate , & tmp . block , pSHA256InitState ) ;
memcpy ( pdata , & tmp . block , 128 ) ;
memcpy ( phash1 , & tmp . hash1 , 64 ) ;
}
bool CheckWork ( CBlock * pblock , CReserveKey & reservekey )
{
uint256 hash = pblock - > GetHash ( ) ;
uint256 hashTarget = CBigNum ( ) . SetCompact ( pblock - > nBits ) . getuint256 ( ) ;
if ( hash > hashTarget )
return false ;
//// debug print
printf ( " BitcoinMiner: \n " ) ;
printf ( " proof-of-work found \n hash: %s \n target: %s \n " , hash . GetHex ( ) . c_str ( ) , hashTarget . GetHex ( ) . c_str ( ) ) ;
pblock - > print ( ) ;
printf ( " %s " , DateTimeStrFormat ( " %x %H:%M " , GetTime ( ) ) . c_str ( ) ) ;
printf ( " generated %s \n " , FormatMoney ( pblock - > vtx [ 0 ] . vout [ 0 ] . nValue ) . c_str ( ) ) ;
// Found a solution
CRITICAL_BLOCK ( cs_main )
{
if ( pblock - > hashPrevBlock ! = hashBestChain )
return error ( " BitcoinMiner : generated block is stale " ) ;
// Remove key from key pool
reservekey . KeepKey ( ) ;
// Track how many getdata requests this block gets
CRITICAL_BLOCK ( cs_mapRequestCount )
mapRequestCount [ pblock - > GetHash ( ) ] = 0 ;
// Process this block the same as if we had received it from another node
if ( ! ProcessBlock ( NULL , pblock ) )
return error ( " BitcoinMiner : ProcessBlock, block not accepted " ) ;
}
Sleep ( 2000 ) ;
return true ;
}
void BitcoinMiner ( )
{
printf ( " BitcoinMiner started \n " ) ;
SetThreadPriority ( THREAD_PRIORITY_LOWEST ) ;
bool f4WaySSE2 = Detect128BitSSE2 ( ) ;
if ( mapArgs . count ( " -4way " ) )
f4WaySSE2 = GetBoolArg ( " -4way " ) ;
// Each thread has its own key and counter
CReserveKey reservekey ;
unsigned int nExtraNonce = 0 ;
int64 nPrevTime = 0 ;
while ( fGenerateBitcoins )
{
if ( AffinityBugWorkaround ( ThreadBitcoinMiner ) )
return ;
if ( fShutdown )
return ;
while ( vNodes . empty ( ) | | IsInitialBlockDownload ( ) )
{
Sleep ( 1000 ) ;
if ( fShutdown )
return ;
if ( ! fGenerateBitcoins )
return ;
}
//
// Create new block
//
unsigned int nTransactionsUpdatedLast = nTransactionsUpdated ;
CBlockIndex * pindexPrev = pindexBest ;
auto_ptr < CBlock > pblock ( CreateNewBlock ( reservekey ) ) ;
if ( ! pblock . get ( ) )
return ;
IncrementExtraNonce ( pblock . get ( ) , pindexPrev , nExtraNonce , nPrevTime ) ;
printf ( " Running BitcoinMiner with %d transactions in block \n " , pblock - > vtx . size ( ) ) ;
//
// Prebuild hash buffers
//
char pmidstatebuf [ 32 + 16 ] ; char * pmidstate = alignup < 16 > ( pmidstatebuf ) ;
char pdatabuf [ 128 + 16 ] ; char * pdata = alignup < 16 > ( pdatabuf ) ;
char phash1buf [ 64 + 16 ] ; char * phash1 = alignup < 16 > ( phash1buf ) ;
FormatHashBuffers ( pblock . get ( ) , pmidstate , pdata , phash1 ) ;
unsigned int & nBlockTime = * ( unsigned int * ) ( pdata + 64 + 4 ) ;
unsigned int & nBlockNonce = * ( unsigned int * ) ( pdata + 64 + 12 ) ;
//
// Search
//
int64 nStart = GetTime ( ) ;
uint256 hashTarget = CBigNum ( ) . SetCompact ( pblock - > nBits ) . getuint256 ( ) ;
uint256 hashbuf [ 2 ] ;
uint256 & hash = * alignup < 16 > ( hashbuf ) ;
loop
{
unsigned int nHashesDone = 0 ;
unsigned int nNonceFound ;
# ifdef FOURWAYSSE2
if ( f4WaySSE2 )
// tcatm's 4-way 128-bit SSE2 SHA-256
nNonceFound = ScanHash_4WaySSE2 ( pmidstate , pdata + 64 , phash1 , ( char * ) & hash , nHashesDone ) ;
else
# endif
// Crypto++ SHA-256
nNonceFound = ScanHash_CryptoPP ( pmidstate , pdata + 64 , phash1 , ( char * ) & hash , nHashesDone ) ;
// Check if something found
if ( nNonceFound ! = - 1 )
{
for ( int i = 0 ; i < sizeof ( hash ) / 4 ; i + + )
( ( unsigned int * ) & hash ) [ i ] = ByteReverse ( ( ( unsigned int * ) & hash ) [ i ] ) ;
if ( hash < = hashTarget )
{
// Found a solution
pblock - > nNonce = ByteReverse ( nNonceFound ) ;
assert ( hash = = pblock - > GetHash ( ) ) ;
SetThreadPriority ( THREAD_PRIORITY_NORMAL ) ;
CheckWork ( pblock . get ( ) , reservekey ) ;
SetThreadPriority ( THREAD_PRIORITY_LOWEST ) ;
break ;
}
}
// Meter hashes/sec
static int64 nHashCounter ;
if ( nHPSTimerStart = = 0 )
{
nHPSTimerStart = GetTimeMillis ( ) ;
nHashCounter = 0 ;
}
else
nHashCounter + = nHashesDone ;
if ( GetTimeMillis ( ) - nHPSTimerStart > 4000 )
{
static CCriticalSection cs ;
CRITICAL_BLOCK ( cs )
{
if ( GetTimeMillis ( ) - nHPSTimerStart > 4000 )
{
dHashesPerSec = 1000.0 * nHashCounter / ( GetTimeMillis ( ) - nHPSTimerStart ) ;
nHPSTimerStart = GetTimeMillis ( ) ;
nHashCounter = 0 ;
string strStatus = strprintf ( " %.0f khash/s " , dHashesPerSec / 1000.0 ) ;
UIThreadCall ( boost : : bind ( CalledSetStatusBar , strStatus , 0 ) ) ;
static int64 nLogTime ;
if ( GetTime ( ) - nLogTime > 30 * 60 )
{
nLogTime = GetTime ( ) ;
printf ( " %s " , DateTimeStrFormat ( " %x %H:%M " , GetTime ( ) ) . c_str ( ) ) ;
printf ( " hashmeter %3d CPUs %6.0f khash/s \n " , vnThreadsRunning [ 3 ] , dHashesPerSec / 1000.0 ) ;
}
}
}
}
// Check for stop or if block needs to be rebuilt
if ( fShutdown )
return ;
if ( ! fGenerateBitcoins )
return ;
if ( fLimitProcessors & & vnThreadsRunning [ 3 ] > nLimitProcessors )
return ;
if ( vNodes . empty ( ) )
break ;
if ( nBlockNonce > = 0xffff0000 )
break ;
if ( nTransactionsUpdated ! = nTransactionsUpdatedLast & & GetTime ( ) - nStart > 60 )
break ;
if ( pindexPrev ! = pindexBest )
break ;
// Update nTime every few seconds
pblock - > nTime = max ( pindexPrev - > GetMedianTimePast ( ) + 1 , GetAdjustedTime ( ) ) ;
nBlockTime = ByteReverse ( pblock - > nTime ) ;
}
}
}
//////////////////////////////////////////////////////////////////////////////
//
// Actions
//
int64 GetBalance ( )
{
int64 nStart = GetTimeMillis ( ) ;
int64 nTotal = 0 ;
CRITICAL_BLOCK ( cs_mapWallet )
{
for ( map < uint256 , CWalletTx > : : iterator it = mapWallet . begin ( ) ; it ! = mapWallet . end ( ) ; + + it )
{
CWalletTx * pcoin = & ( * it ) . second ;
if ( ! pcoin - > IsFinal ( ) | | pcoin - > fSpent | | ! pcoin - > IsConfirmed ( ) )
continue ;
nTotal + = pcoin - > GetCredit ( ) ;
}
}
//printf("GetBalance() %"PRI64d"ms\n", GetTimeMillis() - nStart);
return nTotal ;
}
bool SelectCoinsMinConf ( int64 nTargetValue , int nConfMine , int nConfTheirs , set < CWalletTx * > & setCoinsRet )
{
setCoinsRet . clear ( ) ;
// List of values less than target
int64 nLowestLarger = INT64_MAX ;
CWalletTx * pcoinLowestLarger = NULL ;
vector < pair < int64 , CWalletTx * > > vValue ;
int64 nTotalLower = 0 ;
CRITICAL_BLOCK ( cs_mapWallet )
{
vector < CWalletTx * > vCoins ;
vCoins . reserve ( mapWallet . size ( ) ) ;
for ( map < uint256 , CWalletTx > : : iterator it = mapWallet . begin ( ) ; it ! = mapWallet . end ( ) ; + + it )
vCoins . push_back ( & ( * it ) . second ) ;
random_shuffle ( vCoins . begin ( ) , vCoins . end ( ) , GetRandInt ) ;
foreach ( CWalletTx * pcoin , vCoins )
{
if ( ! pcoin - > IsFinal ( ) | | pcoin - > fSpent | | ! pcoin - > IsConfirmed ( ) )
continue ;
int nDepth = pcoin - > GetDepthInMainChain ( ) ;
if ( nDepth < ( pcoin - > IsFromMe ( ) ? nConfMine : nConfTheirs ) )
continue ;
int64 n = pcoin - > GetCredit ( ) ;
if ( n < = 0 )
continue ;
if ( n = = nTargetValue )
{
setCoinsRet . insert ( pcoin ) ;
return true ;
}
else if ( n < nTargetValue + CENT )
{
vValue . push_back ( make_pair ( n , pcoin ) ) ;
nTotalLower + = n ;
}
else if ( n < nLowestLarger )
{
nLowestLarger = n ;
pcoinLowestLarger = pcoin ;
}
}
}
if ( nTotalLower = = nTargetValue | | nTotalLower = = nTargetValue + CENT )
{
for ( int i = 0 ; i < vValue . size ( ) ; + + i )
setCoinsRet . insert ( vValue [ i ] . second ) ;
return true ;
}
if ( nTotalLower < nTargetValue + ( pcoinLowestLarger ? CENT : 0 ) )
{
if ( pcoinLowestLarger = = NULL )
return false ;
setCoinsRet . insert ( pcoinLowestLarger ) ;
return true ;
}
if ( nTotalLower > = nTargetValue + CENT )
nTargetValue + = CENT ;
// Solve subset sum by stochastic approximation
sort ( vValue . rbegin ( ) , vValue . rend ( ) ) ;
vector < char > vfIncluded ;
vector < char > vfBest ( vValue . size ( ) , true ) ;
int64 nBest = nTotalLower ;
for ( int nRep = 0 ; nRep < 1000 & & nBest ! = nTargetValue ; nRep + + )
{
vfIncluded . assign ( vValue . size ( ) , false ) ;
int64 nTotal = 0 ;
bool fReachedTarget = false ;
for ( int nPass = 0 ; nPass < 2 & & ! fReachedTarget ; nPass + + )
{
for ( int i = 0 ; i < vValue . size ( ) ; i + + )
{
if ( nPass = = 0 ? rand ( ) % 2 : ! vfIncluded [ i ] )
{
nTotal + = vValue [ i ] . first ;
vfIncluded [ i ] = true ;
if ( nTotal > = nTargetValue )
{
fReachedTarget = true ;
if ( nTotal < nBest )
{
nBest = nTotal ;
vfBest = vfIncluded ;
}
nTotal - = vValue [ i ] . first ;
vfIncluded [ i ] = false ;
}
}
}
}
}
// If the next larger is still closer, return it
if ( pcoinLowestLarger & & nLowestLarger - nTargetValue < = nBest - nTargetValue )
setCoinsRet . insert ( pcoinLowestLarger ) ;
else
{
for ( int i = 0 ; i < vValue . size ( ) ; i + + )
if ( vfBest [ i ] )
setCoinsRet . insert ( vValue [ i ] . second ) ;
//// debug print
printf ( " SelectCoins() best subset: " ) ;
for ( int i = 0 ; i < vValue . size ( ) ; i + + )
if ( vfBest [ i ] )
printf ( " %s " , FormatMoney ( vValue [ i ] . first ) . c_str ( ) ) ;
printf ( " total %s \n " , FormatMoney ( nBest ) . c_str ( ) ) ;
}
return true ;
}
bool SelectCoins ( int64 nTargetValue , set < CWalletTx * > & setCoinsRet )
{
return ( SelectCoinsMinConf ( nTargetValue , 1 , 6 , setCoinsRet ) | |
SelectCoinsMinConf ( nTargetValue , 1 , 1 , setCoinsRet ) | |
SelectCoinsMinConf ( nTargetValue , 0 , 1 , setCoinsRet ) ) ;
}
bool CreateTransaction ( const vector < pair < CScript , int64 > > & vecSend , CWalletTx & wtxNew , CReserveKey & reservekey , int64 & nFeeRet )
{
int64 nValue = 0 ;
foreach ( const PAIRTYPE ( CScript , int64 ) & s , vecSend )
{
if ( nValue < 0 )
return false ;
nValue + = s . second ;
}
if ( vecSend . empty ( ) | | nValue < 0 )
return false ;
CRITICAL_BLOCK ( cs_main )
{
// txdb must be opened before the mapWallet lock
CTxDB txdb ( " r " ) ;
CRITICAL_BLOCK ( cs_mapWallet )
{
nFeeRet = nTransactionFee ;
loop
{
wtxNew . vin . clear ( ) ;
wtxNew . vout . clear ( ) ;
wtxNew . fFromMe = true ;
int64 nTotalValue = nValue + nFeeRet ;
double dPriority = 0 ;
// vouts to the payees
foreach ( const PAIRTYPE ( CScript , int64 ) & s , vecSend )
wtxNew . vout . push_back ( CTxOut ( s . second , s . first ) ) ;
// Choose coins to use
set < CWalletTx * > setCoins ;
if ( ! SelectCoins ( nTotalValue , setCoins ) )
return false ;
int64 nValueIn = 0 ;
foreach ( CWalletTx * pcoin , setCoins )
{
int64 nCredit = pcoin - > GetCredit ( ) ;
nValueIn + = nCredit ;
dPriority + = ( double ) nCredit * pcoin - > GetDepthInMainChain ( ) ;
}
// Fill a vout back to self with any change
int64 nChange = nValueIn - nTotalValue ;
if ( nChange > = CENT )
{
// Note: We use a new key here to keep it from being obvious which side is the change.
// The drawback is that by not reusing a previous key, the change may be lost if a
// backup is restored, if the backup doesn't have the new private key for the change.
// If we reused the old key, it would be possible to add code to look for and
// rediscover unknown transactions that were written with keys of ours to recover
// post-backup change.
// Reserve a new key pair from key pool
vector < unsigned char > vchPubKey = reservekey . GetReservedKey ( ) ;
assert ( mapKeys . count ( vchPubKey ) ) ;
// Fill a vout to ourself, using same address type as the payment
CScript scriptChange ;
if ( vecSend [ 0 ] . first . GetBitcoinAddressHash160 ( ) ! = 0 )
scriptChange . SetBitcoinAddress ( vchPubKey ) ;
else
scriptChange < < vchPubKey < < OP_CHECKSIG ;
// Insert change txn at random position:
vector < CTxOut > : : iterator position = wtxNew . vout . begin ( ) + GetRandInt ( wtxNew . vout . size ( ) ) ;
wtxNew . vout . insert ( position , CTxOut ( nChange , scriptChange ) ) ;
}
else
reservekey . ReturnKey ( ) ;
// Fill vin
foreach ( CWalletTx * pcoin , setCoins )
for ( int nOut = 0 ; nOut < pcoin - > vout . size ( ) ; nOut + + )
if ( pcoin - > vout [ nOut ] . IsMine ( ) )
wtxNew . vin . push_back ( CTxIn ( pcoin - > GetHash ( ) , nOut ) ) ;
// Sign
int nIn = 0 ;
foreach ( CWalletTx * pcoin , setCoins )
for ( int nOut = 0 ; nOut < pcoin - > vout . size ( ) ; nOut + + )
if ( pcoin - > vout [ nOut ] . IsMine ( ) )
if ( ! SignSignature ( * pcoin , wtxNew , nIn + + ) )
return false ;
// Limit size
unsigned int nBytes = : : GetSerializeSize ( * ( CTransaction * ) & wtxNew , SER_NETWORK ) ;
if ( nBytes > = MAX_BLOCK_SIZE_GEN / 5 )
return false ;
dPriority / = nBytes ;
// Check that enough fee is included
int64 nPayFee = nTransactionFee * ( 1 + ( int64 ) nBytes / 1000 ) ;
bool fAllowFree = CTransaction : : AllowFree ( dPriority ) ;
int64 nMinFee = wtxNew . GetMinFee ( 1 , fAllowFree ) ;
if ( nFeeRet < max ( nPayFee , nMinFee ) )
{
nFeeRet = max ( nPayFee , nMinFee ) ;
continue ;
}
// Fill vtxPrev by copying from previous transactions vtxPrev
wtxNew . AddSupportingTransactions ( txdb ) ;
wtxNew . fTimeReceivedIsTxTime = true ;
break ;
}
}
}
return true ;
}
bool CreateTransaction ( CScript scriptPubKey , int64 nValue , CWalletTx & wtxNew , CReserveKey & reservekey , int64 & nFeeRet )
{
vector < pair < CScript , int64 > > vecSend ;
vecSend . push_back ( make_pair ( scriptPubKey , nValue ) ) ;
return CreateTransaction ( vecSend , wtxNew , reservekey , nFeeRet ) ;
}
// Call after CreateTransaction unless you want to abort
bool CommitTransaction ( CWalletTx & wtxNew , CReserveKey & reservekey )
{
CRITICAL_BLOCK ( cs_main )
{
printf ( " CommitTransaction: \n %s " , wtxNew . ToString ( ) . c_str ( ) ) ;
CRITICAL_BLOCK ( cs_mapWallet )
{
// This is only to keep the database open to defeat the auto-flush for the
// duration of this scope. This is the only place where this optimization
// maybe makes sense; please don't do it anywhere else.
CWalletDB walletdb ( " r " ) ;
// Take key pair from key pool so it won't be used again
reservekey . KeepKey ( ) ;
// Add tx to wallet, because if it has change it's also ours,
// otherwise just for transaction history.
AddToWallet ( wtxNew ) ;
// Mark old coins as spent
set < CWalletTx * > setCoins ;
foreach ( const CTxIn & txin , wtxNew . vin )
setCoins . insert ( & mapWallet [ txin . prevout . hash ] ) ;
foreach ( CWalletTx * pcoin , setCoins )
{
pcoin - > fSpent = true ;
pcoin - > WriteToDisk ( ) ;
vWalletUpdated . push_back ( pcoin - > GetHash ( ) ) ;
}
}
// Track how many getdata requests our transaction gets
CRITICAL_BLOCK ( cs_mapRequestCount )
mapRequestCount [ wtxNew . GetHash ( ) ] = 0 ;
// Broadcast
if ( ! wtxNew . AcceptToMemoryPool ( ) )
{
// This must not fail. The transaction has already been signed and recorded.
printf ( " CommitTransaction() : Error: Transaction not valid " ) ;
return false ;
}
wtxNew . RelayWalletTransaction ( ) ;
}
MainFrameRepaint ( ) ;
return true ;
}
string SendMoney ( CScript scriptPubKey , int64 nValue , CWalletTx & wtxNew , bool fAskFee )
{
CRITICAL_BLOCK ( cs_main )
{
CReserveKey reservekey ;
int64 nFeeRequired ;
if ( ! CreateTransaction ( scriptPubKey , nValue , wtxNew , reservekey , nFeeRequired ) )
{
string strError ;
if ( nValue + nFeeRequired > GetBalance ( ) )
strError = strprintf ( _ ( " Error: This is an oversized transaction that requires a transaction fee of %s " ) , FormatMoney ( nFeeRequired ) . c_str ( ) ) ;
else
strError = _ ( " Error: Transaction creation failed " ) ;
printf ( " SendMoney() : %s " , strError . c_str ( ) ) ;
return strError ;
}
if ( fAskFee & & ! ThreadSafeAskFee ( nFeeRequired , _ ( " Sending... " ) , NULL ) )
return " ABORTED " ;
if ( ! CommitTransaction ( wtxNew , reservekey ) )
return _ ( " Error: The transaction was rejected. This might happen if some of the coins in your wallet were already spent, such as if you used a copy of wallet.dat and coins were spent in the copy but not marked as spent here. " ) ;
}
MainFrameRepaint ( ) ;
return " " ;
}
string SendMoneyToBitcoinAddress ( string strAddress , int64 nValue , CWalletTx & wtxNew , bool fAskFee )
{
// Check amount
if ( nValue < = 0 )
return _ ( " Invalid amount " ) ;
if ( nValue + nTransactionFee > GetBalance ( ) )
return _ ( " Insufficient funds " ) ;
// Parse bitcoin address
CScript scriptPubKey ;
if ( ! scriptPubKey . SetBitcoinAddress ( strAddress ) )
return _ ( " Invalid bitcoin address " ) ;
return SendMoney ( scriptPubKey , nValue , wtxNew , fAskFee ) ;
}