// modify time.1462237906 modifier.baed58b98a00e41d
# include "iguana777.h"
# define CENT (SATOSHIDEN / 100)
# define COIN_YEAR_REWARD ((int64_t)5 * CENT) // 5% per year
# define NCOINBASEMATURITY 100
# define STAKE_TIMESTAMP_MASK 15
# define NTARGETSPACING 60 // BitcoinDark - 1 minute
# define NTARGETTIMESPAN (60 * NTARGETSPACING) // BitcoinDark - every 1 hour
# define NINTERVAL_MSPACING (((NTARGETTIMESPAN / NTARGETSPACING) - 1) * NTARGETSPACING)
# define NINTERVAL_PSPACING (((NTARGETTIMESPAN / NTARGETSPACING) + 1) * NTARGETSPACING)
# define NSTAKESPLITAGE (1 * 24 * NTARGETTIMESPAN)
# define NSTAKE_MINAGE (8 * NTARGETTIMESPAN) // BitcoinDark - 8 hours
# define NSTAKEMAXAGE ((int64_t)-1)
# define NMAXSTAKESEARCHINTERVAL 60
# define NSTAKECOMBINETHRESHOLD (1000 * COIN)
// ratio of group interval length between the last group and the first group
# define MODIFIER_INTERVAL_RATIO 3
# define NMODIFIERINTERVAL (10 * NTARGETSPACING) // BitcoinDark - time to elapse before new modifier is
// miner's coin stake reward based on coin age spent (coin-days)
int64_t iguana_POSreward ( int64_t nCoinAge , int64_t nFees )
{
int64_t nSubsidy = ( nCoinAge * COIN_YEAR_REWARD * 33 ) / ( 365 * 33 + 8 ) ;
return ( nSubsidy + nFees ) ;
}
// maximum nBits value could possible be required nTime after
uint32_t iguana_maxbits ( bits256 targetval , uint32_t nBits , int64_t nTime )
{
bits256 bitsval ;
bitsval = bits256_from_compact ( nBits ) ;
bitsval = bits256_lshift ( bitsval ) ;
while ( nTime > 0 & & bits256_cmp ( bitsval , targetval ) < 0 )
{
bitsval = bits256_rshift ( bitsval ) ; // Maximum 200% adjustment per day...
nTime - = 24 * 60 * 60 ;
}
if ( bits256_cmp ( bitsval , targetval ) > 0 )
bitsval = targetval ;
return ( bits256_to_compact ( bitsval ) ) ;
}
bits256 iguana_targetval ( struct iguana_info * coin , int32_t height , int32_t PoSflag )
{
int32_t i ; bits256 targetval ;
if ( PoSflag = = 0 )
return ( coin - > chain - > PoWtarget ) ;
else
{
targetval = coin - > chain - > PoStargets [ 0 ] ;
for ( i = 0 ; i < coin - > chain - > numPoStargets ; i + + )
{
if ( height < coin - > chain - > PoSheights [ i ] )
break ;
targetval = coin - > chain - > PoStargets [ i ] ;
}
}
return ( targetval ) ;
}
// minimum amount of stake that could possibly be required nTime after
// minimum proof-of-stake required was nBase
uint32_t iguana_minstake ( struct iguana_info * coin , int32_t height , uint32_t nBits , int64_t nTime , uint32_t nBlockTime )
{
return ( iguana_maxbits ( iguana_targetval ( coin , height , 1 ) , nBits , nTime ) ) ;
}
uint32_t iguana_targetbits ( struct iguana_info * coin , struct iguana_block * hwmchain , struct iguana_block * prev , struct iguana_block * prev2 , int32_t PoSflag , int32_t targetspacing , int32_t targettimespan )
{
// targetspacing NTARGETSPACING, mspacing NINTERVAL_MSPACING, pspacing NINTERVAL_PSPACING
bits256 mpz_muldivcmp ( bits256 oldval , int32_t mulval , int32_t divval , bits256 cmpval ) ;
bits256 targetval ; int32_t gap , mspacing , pspacing ;
if ( hwmchain - > height < = 2 | | hwmchain - > height < = 0 )
return ( hwmchain - > RO . bits ) ;
mspacing = ( ( ( targettimespan / targetspacing ) - 1 ) * targetspacing ) ;
pspacing = ( ( ( targettimespan / targetspacing ) + 1 ) * targetspacing ) ;
targetval = iguana_targetval ( coin , hwmchain - > height , PoSflag ) ;
if ( prev ! = 0 )
{
if ( prev2 ! = 0 & & prev - > RO . timestamp ! = 0 & & prev2 - > RO . timestamp ! = 0 )
{
//if ( prev->RO.timestamp != 0 && prev2->RO.timestamp != 0 ) skip check for compatiblity
{
if ( ( gap = prev - > RO . timestamp - prev2 - > RO . timestamp ) < 0 )
gap = targetspacing ;
//printf("nBits.%08x gap.%d (%u - %u)\n",prev->RO.bits,gap,prev->RO.timestamp,prev2->RO.timestamp);
targetval = mpz_muldivcmp ( bits256_from_compact ( prev - > RO . bits ) , mspacing + ( gap < < 1 ) , pspacing , targetval ) ;
}
}
}
return ( bits256_to_compact ( targetval ) ) ;
}
# ifdef reference
CBigNum bnProofOfStakeLimit ( ~ uint256 ( 0 ) > > 20 ) ;
CBigNum bnProofOfStakeLimitV2 ( ~ uint256 ( 0 ) > > 48 ) ;
enum
{
BLOCK_PROOF_OF_STAKE = ( 1 < < 0 ) , // is proof-of-stake block
BLOCK_STAKE_ENTROPY = ( 1 < < 1 ) , // entropy bit for stake modifier
BLOCK_STAKE_MODIFIER = ( 1 < < 2 ) , // regenerated stake modifier
} ;
uint64_t nStakeModifier ; // hash modifier for proof-of-stake
uint32_t nStakeModifierChecksum ; // checksum of index; in-memory only
uint256 CBlockIndex : : GetBlockTrust ( ) const
{
CBigNum bnTarget ;
bnTarget . SetCompact ( nBits ) ;
if ( bnTarget < = 0 )
return 0 ;
return ( ( CBigNum ( 1 ) < < 256 ) / ( bnTarget + 1 ) ) . getuint256 ( ) ;
}
uint32_t GetStakeEntropyBit ( ) const
{
return ( ( nFlags & BLOCK_STAKE_ENTROPY ) > > 1 ) ;
}
bool SetStakeEntropyBit ( uint32_t nEntropyBit )
{
if ( nEntropyBit > 1 )
return false ;
nFlags | = ( nEntropyBit ? BLOCK_STAKE_ENTROPY : 0 ) ;
return true ;
}
bool GeneratedStakeModifier ( ) const
{
return ( nFlags & BLOCK_STAKE_MODIFIER ) ;
}
void SetStakeModifier ( uint64_t nModifier , bool fGeneratedStakeModifier )
{
nStakeModifier = nModifier ;
if ( fGeneratedStakeModifier )
nFlags | = BLOCK_STAKE_MODIFIER ;
}
// ppcoin: total coin age spent in transaction, in the unit of coin-days.
// Only those coins meeting minimum age requirement counts. As those
// transactions not in main chain are not currently indexed so we
// might not find out about their coin age. Older transactions are
// guaranteed to be in main chain by sync-checkpoint. This rule is
// introduced to help nodes establish a consistent view of the coin
// age (trust score) of competing branches.
bool CTransaction : : GetCoinAge ( CTxDB & txdb , uint64_t & nCoinAge ) const
{
CBigNum bnCentSecond = 0 ; // coin age in the unit of cent-seconds
nCoinAge = 0 ;
if ( IsCoinBase ( ) )
return true ;
BOOST_FOREACH ( const CTxIn & txin , vin )
{
// First try finding the previous transaction in database
CTransaction txPrev ;
CTxIndex txindex ;
if ( ! txPrev . ReadFromDisk ( txdb , txin . prevout , txindex ) )
continue ; // previous transaction not in main chain
if ( nTime < txPrev . nTime )
return false ; // Transaction timestamp violation
// Read block header
CBlock block ;
if ( ! block . ReadFromDisk ( txindex . pos . nFile , txindex . pos . nBlockPos , false ) )
return false ; // unable to read block of previous transaction
if ( block . GetBlockTime ( ) + NSTAKE_MINAGE > nTime )
continue ; // only count coins meeting min age requirement
int64_t nValueIn = txPrev . vout [ txin . prevout . n ] . nValue ;
bnCentSecond + = CBigNum ( nValueIn ) * ( nTime - txPrev . nTime ) / CENT ;
if ( fDebug & & GetBoolArg ( " -printcoinage " ) )
printf ( " coin age nValueIn=% " PRId64 " nTimeDiff=%d bnCentSecond=%s \n " , nValueIn , nTime - txPrev . nTime , bnCentSecond . ToString ( ) . c_str ( ) ) ;
}
CBigNum bnCoinDay = bnCentSecond * CENT / COIN / ( 24 * 60 * 60 ) ;
if ( fDebug & & GetBoolArg ( " -printcoinage " ) )
printf ( " coin age bnCoinDay=%s \n " , bnCoinDay . ToString ( ) . c_str ( ) ) ;
nCoinAge = bnCoinDay . getuint64 ( ) ;
return true ;
}
// ppcoin: total coin age spent in block, in the unit of coin-days.
bool CBlock : : GetCoinAge ( uint64_t & nCoinAge ) const
{
nCoinAge = 0 ;
CTxDB txdb ( " r " ) ;
BOOST_FOREACH ( const CTransaction & tx , vtx )
{
uint64_t nTxCoinAge ;
if ( tx . GetCoinAge ( txdb , nTxCoinAge ) )
nCoinAge + = nTxCoinAge ;
else
return false ;
}
if ( nCoinAge = = 0 ) // block coin age minimum 1 coin-day
nCoinAge = 1 ;
if ( fDebug & & GetBoolArg ( " -printcoinage " ) )
printf ( " block coin age total nCoinDays=% " PRId64 " \n " , nCoinAge ) ;
return true ;
}
// Get time weight
int64_t GetWeight ( int64_t nIntervalBeginning , int64_t nIntervalEnd )
{
// Kernel hash weight starts from 0 at the min age
// this change increases active coins participating the hash and helps
// to secure the network when proof-of-stake difficulty is low
return min ( nIntervalEnd - nIntervalBeginning - NSTAKE_MINAGE , NSTAKEMAXAGE ) ;
}
// Get the last stake modifier and its generation time from a given block
static bool GetLastStakeModifier ( const CBlockIndex * pindex , uint64_t & nStakeModifier , int64_t & nModifierTime )
{
if ( ! pindex )
return error ( " GetLastStakeModifier: null pindex " ) ;
while ( pindex & & pindex - > pprev & & ! pindex - > GeneratedStakeModifier ( ) )
pindex = pindex - > pprev ;
if ( ! pindex - > GeneratedStakeModifier ( ) )
return error ( " GetLastStakeModifier: no generation at genesis block " ) ;
nStakeModifier = pindex - > nStakeModifier ;
nModifierTime = pindex - > GetBlockTime ( ) ;
return true ;
}
// Get selection interval section (in seconds)
static int64_t GetStakeModifierSelectionIntervalSection ( int32_t nSection )
{
assert ( nSection > = 0 & & nSection < 64 ) ;
return ( NMODIFIERINTERVAL * 63 / ( 63 + ( ( 63 - nSection ) * ( MODIFIER_INTERVAL_RATIO - 1 ) ) ) ) ;
}
// Get stake modifier selection interval (in seconds)
static int64_t GetStakeModifierSelectionInterval ( )
{
int64_t nSelectionInterval = 0 ;
for ( int32_t nSection = 0 ; nSection < 64 ; nSection + + )
nSelectionInterval + = GetStakeModifierSelectionIntervalSection ( nSection ) ;
return nSelectionInterval ;
}
// select a block from the candidate blocks in vSortedByTimestamp, excluding
// already selected blocks in vSelectedBlocks, and with timestamp up to nSelectionIntervalStop.
static bool SelectBlockFromCandidates ( vector < pair < int64_t , uint256 > > & vSortedByTimestamp , map < uint256 , const CBlockIndex * > & mapSelectedBlocks , int64_t nSelectionIntervalStop , uint64_t nStakeModifierPrev , const CBlockIndex * * pindexSelected )
{
bool fSelected = false ; uint256 hashBest = 0 ;
* pindexSelected = ( const CBlockIndex * ) 0 ;
BOOST_FOREACH ( const PAIRTYPE ( int64_t , uint256 ) & item , vSortedByTimestamp )
{
if ( ! mapBlockIndex . count ( item . second ) )
return error ( " SelectBlockFromCandidates: failed to find block index for candidate block %s " , item . second . ToString ( ) . c_str ( ) ) ;
const CBlockIndex * pindex = mapBlockIndex [ item . second ] ;
if ( fSelected & & pindex - > GetBlockTime ( ) > nSelectionIntervalStop )
break ;
if ( mapSelectedBlocks . count ( pindex - > GetBlockHash ( ) ) > 0 )
continue ;
// compute the selection hash by hashing its proof-hash and the previous proof-of-stake modifier
CDataStream ss ( SER_GETHASH , 0 ) ;
ss < < pindex - > hashProof < < nStakeModifierPrev ;
uint256 hashSelection = Hash ( ss . begin ( ) , ss . end ( ) ) ;
// the selection hash is divided by 2**32 so that proof-of-stake block is always favored over proof-of-work block. this is to preserve the energy efficiency property
if ( pindex - > IsProofOfStake ( ) )
hashSelection > > = 32 ;
if ( fSelected & & hashSelection < hashBest )
{
hashBest = hashSelection ;
* pindexSelected = ( const CBlockIndex * ) pindex ;
}
else if ( ! fSelected )
{
fSelected = true ;
hashBest = hashSelection ;
* pindexSelected = ( const CBlockIndex * ) pindex ;
}
}
if ( fDebug & & GetBoolArg ( " -printstakemodifier " ) )
printf ( " SelectBlockFromCandidates: selection hash=%s \n " , hashBest . ToString ( ) . c_str ( ) ) ;
return fSelected ;
}
// Stake Modifier (hash modifier of proof-of-stake):
// The purpose of stake modifier is to prevent a txout (coin) owner from
// computing future proof-of-stake generated by this txout at the time
// of transaction confirmation. To meet kernel protocol, the txout
// must hash with a future stake modifier to generate the proof.
// Stake modifier consists of bits each of which is contributed from a
// selected block of a given block group in the past.
// The selection of a block is based on a hash of the block's proof-hash and
// the previous stake modifier.
// Stake modifier is recomputed at a fixed time interval instead of every
// block. This is to make it difficult for an attacker to gain control of
// additional bits in the stake modifier, even after generating a chain of
// blocks.
bool ComputeNextStakeModifier ( const CBlockIndex * pindexPrev , uint64_t & nStakeModifier , bool & fGeneratedStakeModifier )
{
nStakeModifier = 0 ;
fGeneratedStakeModifier = false ;
if ( ! pindexPrev )
{
fGeneratedStakeModifier = true ;
return true ; // genesis block's modifier is 0
}
// First find current stake modifier and its generation block time
// if it's not old enough, return the same stake modifier
int64_t nModifierTime = 0 ;
if ( ! GetLastStakeModifier ( pindexPrev , nStakeModifier , nModifierTime ) )
return error ( " ComputeNextStakeModifier: unable to get last modifier " ) ;
if ( fDebug )
{
printf ( " ComputeNextStakeModifier: prev modifier=0x%016 " PRIx64 " time=%s \n " , nStakeModifier , DateTimeStrFormat ( nModifierTime ) . c_str ( ) ) ;
}
if ( nModifierTime / NMODIFIERINTERVAL > = pindexPrev - > GetBlockTime ( ) / NMODIFIERINTERVAL )
return true ;
// Sort candidate blocks by timestamp
vector < pair < int64_t , uint256 > > vSortedByTimestamp ;
vSortedByTimestamp . reserve ( 64 * ( NMODIFIERINTERVAL / NTARGETSPACING ) ) ;
int64_t nSelectionInterval = GetStakeModifierSelectionInterval ( ) ;
int64_t nSelectionIntervalStart = ( pindexPrev - > GetBlockTime ( ) / NMODIFIERINTERVAL ) * NMODIFIERINTERVAL - nSelectionInterval ;
const CBlockIndex * pindex = pindexPrev ;
while ( pindex & & pindex - > GetBlockTime ( ) > = nSelectionIntervalStart )
{
vSortedByTimestamp . push_back ( make_pair ( pindex - > GetBlockTime ( ) , pindex - > GetBlockHash ( ) ) ) ;
pindex = pindex - > pprev ;
}
int32_t nHeightFirstCandidate = pindex ? ( pindex - > nHeight + 1 ) : 0 ;
reverse ( vSortedByTimestamp . begin ( ) , vSortedByTimestamp . end ( ) ) ;
sort ( vSortedByTimestamp . begin ( ) , vSortedByTimestamp . end ( ) ) ;
// Select 64 blocks from candidate blocks to generate stake modifier
uint64_t nStakeModifierNew = 0 ;
int64_t nSelectionIntervalStop = nSelectionIntervalStart ;
map < uint256 , const CBlockIndex * > mapSelectedBlocks ;
for ( int32_t nRound = 0 ; nRound < min ( 64 , ( int ) vSortedByTimestamp . size ( ) ) ; nRound + + )
{
// add an interval section to the current selection round
nSelectionIntervalStop + = GetStakeModifierSelectionIntervalSection ( nRound ) ;
// select a block from the candidates of current round
if ( ! SelectBlockFromCandidates ( vSortedByTimestamp , mapSelectedBlocks , nSelectionIntervalStop , nStakeModifier , & pindex ) )
return error ( " ComputeNextStakeModifier: unable to select block at round %d " , nRound ) ;
// write the entropy bit of the selected block
nStakeModifierNew | = ( ( ( uint64_t ) pindex - > GetStakeEntropyBit ( ) ) < < nRound ) ;
// add the selected block from candidates to selected list
mapSelectedBlocks . insert ( make_pair ( pindex - > GetBlockHash ( ) , pindex ) ) ;
if ( fDebug & & GetBoolArg ( " -printstakemodifier " ) )
printf ( " ComputeNextStakeModifier: selected round %d stop=%s height=%d bit=%d \n " , nRound , DateTimeStrFormat ( nSelectionIntervalStop ) . c_str ( ) , pindex - > nHeight , pindex - > GetStakeEntropyBit ( ) ) ;
}
// Print selection map for visualization of the selected blocks
if ( fDebug & & GetBoolArg ( " -printstakemodifier " ) )
{
string strSelectionMap = " " ;
// '-' indicates proof-of-work blocks not selected
strSelectionMap . insert ( 0 , pindexPrev - > nHeight - nHeightFirstCandidate + 1 , ' - ' ) ;
pindex = pindexPrev ;
while ( pindex & & pindex - > nHeight > = nHeightFirstCandidate )
{
// '=' indicates proof-of-stake blocks not selected
if ( pindex - > IsProofOfStake ( ) )
strSelectionMap . replace ( pindex - > nHeight - nHeightFirstCandidate , 1 , " = " ) ;
pindex = pindex - > pprev ;
}
BOOST_FOREACH ( const PAIRTYPE ( uint256 , const CBlockIndex * ) & item , mapSelectedBlocks )
{
// 'S' indicates selected proof-of-stake blocks
// 'W' indicates selected proof-of-work blocks
strSelectionMap . replace ( item . second - > nHeight - nHeightFirstCandidate , 1 , item . second - > IsProofOfStake ( ) ? " S " : " W " ) ;
}
printf ( " ComputeNextStakeModifier: selection height [%d, %d] map %s \n " , nHeightFirstCandidate , pindexPrev - > nHeight , strSelectionMap . c_str ( ) ) ;
}
if ( fDebug )
{
printf ( " ComputeNextStakeModifier: new modifier=0x%016 " PRIx64 " time=%s \n " , nStakeModifierNew , DateTimeStrFormat ( pindexPrev - > GetBlockTime ( ) ) . c_str ( ) ) ;
}
nStakeModifier = nStakeModifierNew ;
fGeneratedStakeModifier = true ;
return true ;
}
// The stake modifier used to hash for a stake kernel is chosen as the stake
// modifier about a selection interval later than the coin generating the kernel
static bool GetKernelStakeModifier ( uint256 hashBlockFrom , uint64_t & nStakeModifier , int & nStakeModifierHeight , int64_t & nStakeModifierTime , bool fPrintProofOfStake )
{
nStakeModifier = 0 ;
if ( ! mapBlockIndex . count ( hashBlockFrom ) )
return error ( " GetKernelStakeModifier() : block not indexed " ) ;
const CBlockIndex * pindexFrom = mapBlockIndex [ hashBlockFrom ] ;
nStakeModifierHeight = pindexFrom - > nHeight ;
nStakeModifierTime = pindexFrom - > GetBlockTime ( ) ;
int64_t nStakeModifierSelectionInterval = GetStakeModifierSelectionInterval ( ) ;
const CBlockIndex * pindex = pindexFrom ;
// loop to find the stake modifier later by a selection interval
while ( nStakeModifierTime < pindexFrom - > GetBlockTime ( ) + nStakeModifierSelectionInterval )
{
if ( ! pindex - > pnext )
{ // reached best block; may happen if node is behind on block chain
if ( fPrintProofOfStake | | ( pindex - > GetBlockTime ( ) + NSTAKE_MINAGE - nStakeModifierSelectionInterval > GetAdjustedTime ( ) ) )
return error ( " GetKernelStakeModifier() : reached best block % s at height % d from block % s " ,pindex->GetBlockHash().ToString().c_str(), pindex->nHeight, hashBlockFrom.ToString().c_str()) ;
else return false ;
}
pindex = pindex - > pnext ;
if ( pindex - > GeneratedStakeModifier ( ) )
{
nStakeModifierHeight = pindex - > nHeight ;
nStakeModifierTime = pindex - > GetBlockTime ( ) ;
}
}
nStakeModifier = pindex - > nStakeModifier ;
return true ;
}
// ppcoin kernel protocol
// coinstake must meet hash target according to the protocol:
// kernel (input 0) must meet the formula
// hash(nStakeModifier + txPrev.block.nTime + txPrev.offset + txPrev.nTime + txPrev.vout.n + nTime) < bnTarget * nCoinDayWeight
// this ensures that the chance of getting a coinstake is proportional to the
// amount of coin age one owns.
// The reason this hash is chosen is the following:
// nStakeModifier: scrambles computation to make it very difficult to precompute
// future proof-of-stake at the time of the coin's confirmation
// txPrev.block.nTime: prevent nodes from guessing a good timestamp to
// generate transaction for future advantage
// txPrev.offset: offset of txPrev inside block, to reduce the chance of
// nodes generating coinstake at the same time
// txPrev.nTime: reduce the chance of nodes generating coinstake at the same
// time
// txPrev.vout.n: output number of txPrev, to reduce the chance of nodes
// generating coinstake at the same time
// block/tx hash should not be used here as they can be generated in vast
// quantities so as to generate blocks faster, degrading the system back into
// a proof-of-work situation.
//
bool CheckStakeKernelHashV1 ( uint32_t nBits , const CBlock & blockFrom , uint32_t nTxPrevOffset , const CTransaction & txPrev , const COutPoint & prevout , uint32_t nTimeTx , uint256 & hashProofOfStake , uint256 & targetProofOfStake , bool fPrintProofOfStake )
{
if ( nTimeTx < txPrev . nTime ) // Transaction timestamp violation
return error ( " CheckStakeKernelHash() : nTime violation " ) ;
uint32_t nTimeBlockFrom = blockFrom . GetBlockTime ( ) ;
if ( nTimeBlockFrom + NSTAKE_MINAGE > nTimeTx ) // Min age requirement
return error ( " CheckStakeKernelHash() : min age violation " ) ;
CBigNum bnTargetPerCoinDay ;
bnTargetPerCoinDay . SetCompact ( nBits ) ;
int64_t nValueIn = txPrev . vout [ prevout . n ] . nValue ;
uint256 hashBlockFrom = blockFrom . GetHash ( ) ;
CBigNum bnCoinDayWeight = CBigNum ( nValueIn ) * GetWeight ( ( int64_t ) txPrev . nTime , ( int64_t ) nTimeTx ) / COIN / ( 24 * 60 * 60 ) ;
targetProofOfStake = ( bnCoinDayWeight * bnTargetPerCoinDay ) . getuint256 ( ) ;
// Calculate hash
CDataStream ss ( SER_GETHASH , 0 ) ;
uint64_t nStakeModifier = 0 ;
int32_t nStakeModifierHeight = 0 ;
int64_t nStakeModifierTime = 0 ;
if ( ! GetKernelStakeModifier ( hashBlockFrom , nStakeModifier , nStakeModifierHeight , nStakeModifierTime , fPrintProofOfStake ) )
return false ;
ss < < nStakeModifier < < nTimeBlockFrom < < nTxPrevOffset < < txPrev . nTime < < prevout . n < < nTimeTx ;
hashProofOfStake = Hash ( ss . begin ( ) , ss . end ( ) ) ;
if ( fPrintProofOfStake )
{
printf ( " CheckStakeKernelHash() : using modifier 0x%016 " PRIx64 " at height=%d timestamp=%s for block from height=%d timestamp=%s \n " ,
nStakeModifier , nStakeModifierHeight ,
DateTimeStrFormat ( nStakeModifierTime ) . c_str ( ) ,
mapBlockIndex [ hashBlockFrom ] - > nHeight ,
DateTimeStrFormat ( blockFrom . GetBlockTime ( ) ) . c_str ( ) ) ;
printf ( " CheckStakeKernelHash() : check modifier=0x%016 " PRIx64 " nTimeBlockFrom=%u nTxPrevOffset=%u nTimeTxPrev=%u nPrevout=%u nTimeTx=%u hashProof=%s \n " ,
nStakeModifier ,
nTimeBlockFrom , nTxPrevOffset , txPrev . nTime , prevout . n , nTimeTx ,
hashProofOfStake . ToString ( ) . c_str ( ) ) ;
}
// Now check if proof-of-stake hash meets target protocol
if ( CBigNum ( hashProofOfStake ) > bnCoinDayWeight * bnTargetPerCoinDay )
return false ;
if ( fDebug & & ! fPrintProofOfStake )
{
printf ( " CheckStakeKernelHash() : using modifier 0x%016 " PRIx64 " at height=%d timestamp=%s for block from height=%d timestamp=%s \n " ,
nStakeModifier , nStakeModifierHeight ,
DateTimeStrFormat ( nStakeModifierTime ) . c_str ( ) ,
mapBlockIndex [ hashBlockFrom ] - > nHeight ,
DateTimeStrFormat ( blockFrom . GetBlockTime ( ) ) . c_str ( ) ) ;
printf ( " CheckStakeKernelHash() : pass modifier=0x%016 " PRIx64 " nTimeBlockFrom=%u nTxPrevOffset=%u nTimeTxPrev=%u nPrevout=%u nTimeTx=%u hashProof=%s \n " ,
nStakeModifier ,
nTimeBlockFrom , nTxPrevOffset , txPrev . nTime , prevout . n , nTimeTx ,
hashProofOfStake . ToString ( ) . c_str ( ) ) ;
}
return true ;
}
bool CheckStakeKernelHash ( CBlockIndex * pindexPrev , uint32_t nBits , const CBlock & blockFrom , uint32_t nTxPrevOffset , const CTransaction & txPrev , const COutPoint & prevout , uint32_t nTimeTx , uint256 & hashProofOfStake , uint256 & targetProofOfStake , bool fPrintProofOfStake )
{
if ( IsPoSV2 ( pindexPrev - > nHeight + 1 ) )
return CheckStakeKernelHashV2 ( pindexPrev , nBits , blockFrom . GetBlockTime ( ) , txPrev , prevout , nTimeTx , hashProofOfStake , targetProofOfStake , fPrintProofOfStake ) ;
else
return CheckStakeKernelHashV1 ( nBits , blockFrom , nTxPrevOffset , txPrev , prevout , nTimeTx , hashProofOfStake , targetProofOfStake , fPrintProofOfStake ) ;
}
bool CWallet : : CreateCoinStake ( const CKeyStore & keystore , uint32_t nBits , int64_t nSearchInterval , int64_t nFees , CTransaction & txNew , CKey & key )
{
CBigNum bnTargetPerCoinDay ; CBlockIndex * pindexPrev = pindexBest ;
bnTargetPerCoinDay . SetCompact ( nBits ) ;
txNew . vin . clear ( ) ;
txNew . vout . clear ( ) ;
// Mark coin stake transaction
CScript scriptEmpty ;
scriptEmpty . clear ( ) ;
txNew . vout . push_back ( CTxOut ( 0 , scriptEmpty ) ) ;
// Choose coins to use
int64_t nBalance = GetBalance ( ) ;
if ( nBalance < = nReserveBalance )
return false ;
vector < const CWalletTx * > vwtxPrev ;
set < pair < const CWalletTx * , unsigned int > > setCoins ;
int64_t nValueIn = 0 ;
// Select coins with suitable depth
if ( ! SelectCoinsSimple ( nBalance - nReserveBalance , txNew . nTime , nCoinbaseMaturity + 10 , setCoins , nValueIn ) )
return false ;
if ( setCoins . empty ( ) )
return false ;
int64_t nCredit = 0 ;
CScript scriptPubKeyKernel ;
CTxDB txdb ( " r " ) ;
BOOST_FOREACH ( PAIRTYPE ( const CWalletTx * , unsigned int ) pcoin , setCoins )
{
CTxIndex txindex ;
{
LOCK2 ( cs_main , cs_wallet ) ;
if ( ! txdb . ReadTxIndex ( pcoin . first - > GetHash ( ) , txindex ) )
continue ;
}
// Read block header
CBlock block ;
{
LOCK2 ( cs_main , cs_wallet ) ;
if ( ! block . ReadFromDisk ( txindex . pos . nFile , txindex . pos . nBlockPos , false ) )
continue ;
}
if ( block . GetBlockTime ( ) + NSTAKE_MINAGE > txNew . nTime - NMAXSTAKESEARCHINTERVAL )
continue ; // only count coins meeting min age requirement
bool fKernelFound = false ;
for ( uint32_t n = 0 ; n < min ( nSearchInterval , ( int64_t ) NMAXSTAKESEARCHINTERVAL ) & & ! fKernelFound & & ! fShutdown & & pindexPrev = = pindexBest ; n + + )
{
// Search backward in time from the given txNew timestamp
// Search nSearchInterval seconds back up to NMAXSTAKESEARCHINTERVAL
uint256 hashProofOfStake = 0 , targetProofOfStake = 0 ;
COutPoint prevoutStake = COutPoint ( pcoin . first - > GetHash ( ) , pcoin . second ) ;
if ( CheckStakeKernelHash ( pindexPrev , nBits , block , txindex . pos . nTxPos - txindex . pos . nBlockPos , * pcoin . first , prevoutStake , txNew . nTime - n , hashProofOfStake , targetProofOfStake ) )
{
// Found a kernel
if ( fDebug & & GetBoolArg ( " -printcoinstake " ) )
printf ( " CreateCoinStake : kernel found \n " ) ;
vector < valtype > vSolutions ;
txnouttype whichType ;
CScript scriptPubKeyOut ;
scriptPubKeyKernel = pcoin . first - > vout [ pcoin . second ] . scriptPubKey ;
if ( ! Solver ( scriptPubKeyKernel , whichType , vSolutions ) )
{
if ( fDebug & & GetBoolArg ( " -printcoinstake " ) )
printf ( " CreateCoinStake : failed to parse kernel \n " ) ;
break ;
}
if ( fDebug & & GetBoolArg ( " -printcoinstake " ) )
printf ( " CreateCoinStake : parsed kernel type=%d \n " , whichType ) ;
if ( whichType ! = TX_PUBKEY & & whichType ! = TX_PUBKEYHASH )
{
if ( fDebug & & GetBoolArg ( " -printcoinstake " ) )
printf ( " CreateCoinStake : no support for kernel type=%d \n " , whichType ) ;
break ; // only support pay to public key and pay to address
}
if ( whichType = = TX_PUBKEYHASH ) // pay to address type
{
// convert to pay to public key type
if ( ! keystore . GetKey ( uint160 ( vSolutions [ 0 ] ) , key ) )
{
if ( fDebug & & GetBoolArg ( " -printcoinstake " ) )
printf ( " CreateCoinStake : failed to get key for kernel type=%d \n " , whichType ) ;
break ; // unable to find corresponding public key
}
scriptPubKeyOut < < key . GetPubKey ( ) < < OP_CHECKSIG ;
}
if ( whichType = = TX_PUBKEY )
{
valtype & vchPubKey = vSolutions [ 0 ] ;
if ( ! keystore . GetKey ( Hash160 ( vchPubKey ) , key ) )
{
if ( fDebug & & GetBoolArg ( " -printcoinstake " ) )
printf ( " CreateCoinStake : failed to get key for kernel type=%d \n " , whichType ) ;
break ; // unable to find corresponding public key
}
if ( key . GetPubKey ( ) ! = vchPubKey )
{
if ( fDebug & & GetBoolArg ( " -printcoinstake " ) )
printf ( " CreateCoinStake : invalid key for kernel type=%d \n " , whichType ) ;
break ; // keys mismatch
}
scriptPubKeyOut = scriptPubKeyKernel ;
}
txNew . nTime - = n ;
txNew . vin . push_back ( CTxIn ( pcoin . first - > GetHash ( ) , pcoin . second ) ) ;
nCredit + = pcoin . first - > vout [ pcoin . second ] . nValue ;
vwtxPrev . push_back ( pcoin . first ) ;
txNew . vout . push_back ( CTxOut ( 0 , scriptPubKeyOut ) ) ;
if ( GetWeight ( block . GetBlockTime ( ) , ( int64_t ) txNew . nTime ) < nStakeSplitAge )
txNew . vout . push_back ( CTxOut ( 0 , scriptPubKeyOut ) ) ; //split stake
if ( fDebug & & GetBoolArg ( " -printcoinstake " ) )
printf ( " CreateCoinStake : added kernel type=%d \n " , whichType ) ;
fKernelFound = true ;
break ;
}
}
if ( fKernelFound | | fShutdown )
break ; // if kernel is found stop searching
}
if ( nCredit = = 0 | | nCredit > nBalance - nReserveBalance )
return false ;
BOOST_FOREACH ( PAIRTYPE ( const CWalletTx * , unsigned int ) pcoin , setCoins )
{
// Attempt to add more inputs: Only add coins of the same key/address as kernel
if ( txNew . vout . size ( ) = = 2 & & ( ( pcoin . first - > vout [ pcoin . second ] . scriptPubKey = = scriptPubKeyKernel | | pcoin . first - > vout [ pcoin . second ] . scriptPubKey = = txNew . vout [ 1 ] . scriptPubKey ) )
& & pcoin . first - > GetHash ( ) ! = txNew . vin [ 0 ] . prevout . hash )
{
int64_t nTimeWeight = GetWeight ( ( int64_t ) pcoin . first - > nTime , ( int64_t ) txNew . nTime ) ;
// Stop adding more inputs if already too many inputs
if ( txNew . vin . size ( ) > = 100 )
break ;
// Stop adding more inputs if value is already pretty significant
if ( nCredit > = NSTAKECOMBINETHRESHOLD )
break ;
// Stop adding inputs if reached reserve limit
if ( nCredit + pcoin . first - > vout [ pcoin . second ] . nValue > nBalance - nReserveBalance )
break ;
// Do not add additional significant input
if ( pcoin . first - > vout [ pcoin . second ] . nValue > = NSTAKECOMBINETHRESHOLD )
continue ;
// Do not add input that is still too young
if ( nTimeWeight < NSTAKE_MINAGE )
continue ;
txNew . vin . push_back ( CTxIn ( pcoin . first - > GetHash ( ) , pcoin . second ) ) ;
nCredit + = pcoin . first - > vout [ pcoin . second ] . nValue ;
vwtxPrev . push_back ( pcoin . first ) ;
}
}
// Calculate coin age reward
{
uint64_t nCoinAge ;
CTxDB txdb ( " r " ) ;
if ( ! txNew . GetCoinAge ( txdb , nCoinAge ) )
return error ( " CreateCoinStake : failed to calculate coin age " ) ;
int64_t nReward = iguana_POSreward ( nCoinAge , nFees ) ;
if ( nReward < = 0 )
return false ;
nCredit + = nReward ;
}
// Set output amount
if ( txNew . vout . size ( ) = = 3 )
{
txNew . vout [ 1 ] . nValue = ( nCredit / 2 / CENT ) * CENT ;
txNew . vout [ 2 ] . nValue = nCredit - txNew . vout [ 1 ] . nValue ;
} else txNew . vout [ 1 ] . nValue = nCredit ;
// Sign
int32_t nIn = 0 ;
BOOST_FOREACH ( const CWalletTx * pcoin , vwtxPrev )
{
if ( ! SignSignature ( * this , * pcoin , txNew , nIn + + ) )
return error ( " CreateCoinStake : failed to sign coinstake " ) ;
}
// Limit size
uint32_t nBytes = : : GetSerializeSize ( txNew , SER_NETWORK , PROTOCOL_VERSION ) ;
if ( nBytes > = MAX_BLOCK_SIZE_GEN / 5 )
return error ( " CreateCoinStake : exceeded coinstake size limit " ) ;
// Successfully generated coinstake
return true ;
}
// Check kernel hash target and coinstake signature
bool CheckProofOfStake ( CBlockIndex * pindexPrev , const CTransaction & tx , uint32_t nBits , uint256 & hashProofOfStake , uint256 & targetProofOfStake )
{
if ( ! tx . IsCoinStake ( ) )
return error ( " CheckProofOfStake() : called on non - coinstake % s " , tx.GetHash().ToString().c_str()) ;
// Kernel (input 0) must match the stake hash target per coin age (nBits)
const CTxIn & txin = tx . vin [ 0 ] ;
// First try finding the previous transaction in database
CTxDB txdb ( " r " ) ;
CTransaction txPrev ;
CTxIndex txindex ;
if ( ! txPrev . ReadFromDisk ( txdb , txin . prevout , txindex ) )
return tx . DoS ( 1 , error ( " CheckProofOfStake() : INFO: read txPrev failed " ) ) ; // previous transaction not in main chain, may occur during initial download
// Verify signature
if ( ! VerifySignature ( txPrev , tx , 0 , 0 ) )
return tx . DoS ( 100 , error ( " CheckProofOfStake() : VerifySignature failed on coinstake %s " , tx . GetHash ( ) . ToString ( ) . c_str ( ) ) ) ;
// Read block header
CBlock block ;
if ( ! block . ReadFromDisk ( txindex . pos . nFile , txindex . pos . nBlockPos , false ) )
return fDebug ? error ( " CheckProofOfStake() : read block failed " ) : false ; // unable to read block of previous transaction
if ( ! CheckStakeKernelHash ( pindexPrev , nBits , block , txindex . pos . nTxPos - txindex . pos . nBlockPos , txPrev , txin . prevout , tx . nTime , hashProofOfStake , targetProofOfStake , fDebug ) )
return tx . DoS ( 1 , error ( " CheckProofOfStake() : INFO: check kernel failed on coinstake %s, hashProof=%s " , tx . GetHash ( ) . ToString ( ) . c_str ( ) , hashProofOfStake . ToString ( ) . c_str ( ) ) ) ; // may occur during initial download or if behind on block chain sync
return true ;
}
// Check whether the coinstake timestamp meets protocol
bool CheckCoinStakeTimestamp ( int64_t nTimeBlock , int64_t nTimeTx )
{
// v0.3 protocol
return ( nTimeBlock = = nTimeTx ) ;
}
// Get stake modifier checksum
uint32_t GetStakeModifierChecksum ( const CBlockIndex * pindex )
{
//assert (pindex->pprev || pindex->GetBlockHash() == (!fTestNet ? hashGenesisBlock : hashGenesisBlockTestNet));
// Hash previous checksum with flags, hashProofOfStake and nStakeModifier
CDataStream ss ( SER_GETHASH , 0 ) ;
if ( pindex - > pprev )
ss < < pindex - > pprev - > nStakeModifierChecksum ;
ss < < pindex - > nFlags < < ( pindex - > IsProofOfStake ( ) ? pindex - > hashProof : 0 ) < < pindex - > nStakeModifier ;
uint256 hashChecksum = Hash ( ss . begin ( ) , ss . end ( ) ) ;
hashChecksum > > = ( 256 - 32 ) ;
return hashChecksum . Get64 ( ) ;
}
// Check stake modifier hard checkpoints
bool CheckStakeModifierCheckpoints ( int32_t nHeight , uint32_t nStakeModifierChecksum )
{
MapModifierCheckpoints & checkpoints = ( fTestNet ? mapStakeModifierCheckpointsTestNet : mapStakeModifierCheckpoints ) ;
if ( checkpoints . count ( nHeight ) )
return nStakeModifierChecksum = = checkpoints [ nHeight ] ;
return true ;
}
// novacoin: attempt to generate suitable proof-of-stake
bool CBlock : : SignBlock ( CWallet & wallet , int64_t nFees )
{
// if we are trying to sign something except proof-of-stake block template
if ( ! vtx [ 0 ] . vout [ 0 ] . IsEmpty ( ) )
return false ;
// if we are trying to sign a complete proof-of-stake block
if ( IsProofOfStake ( ) )
return true ;
static int64_t nLastCoinStakeSearchTime = GetAdjustedTime ( ) ; // startup timestamp
CKey key ; CTransaction txCoinStake ; int64_t nSearchTime = txCoinStake . nTime ; // search to current time
if ( nSearchTime > nLastCoinStakeSearchTime )
{
if ( wallet . CreateCoinStake ( wallet , nBits , nSearchTime - nLastCoinStakeSearchTime , nFees , txCoinStake , key ) )
{
if ( txCoinStake . nTime > = max ( pindexBest - > GetPastTimeLimit ( ) + 1 , PastDrift ( pindexBest - > GetBlockTime ( ) ) ) )
{
// make sure coinstake would meet timestamp protocol as it would be the same as the block timestamp
vtx [ 0 ] . nTime = nTime = txCoinStake . nTime ;
nTime = max ( pindexBest - > GetPastTimeLimit ( ) + 1 , GetMaxTransactionTime ( ) ) ;
nTime = max ( GetBlockTime ( ) , PastDrift ( pindexBest - > GetBlockTime ( ) ) ) ;
// we have to make sure that we have no future timestamps in our transactions set
for ( vector < CTransaction > : : iterator it = vtx . begin ( ) ; it ! = vtx . end ( ) ; )
if ( it - > nTime > nTime ) { it = vtx . erase ( it ) ; } else { + + it ; }
vtx . insert ( vtx . begin ( ) + 1 , txCoinStake ) ;
hashMerkleRoot = BuildMerkleTree ( ) ;
// append a signature to our block
return key . Sign ( GetHash ( ) , vchBlockSig ) ;
}
}
nLastCoinStakeSearchInterval = nSearchTime - nLastCoinStakeSearchTime ;
nLastCoinStakeSearchTime = nSearchTime ;
}
return false ;
}
bool CBlock : : CheckBlockSignature ( ) const
{
if ( IsProofOfWork ( ) )
return vchBlockSig . empty ( ) ;
vector < valtype > vSolutions ;
txnouttype whichType ;
const CTxOut & txout = vtx [ 1 ] . vout [ 1 ] ;
if ( ! Solver ( txout . scriptPubKey , whichType , vSolutions ) )
return false ;
if ( whichType = = TX_PUBKEY )
{
valtype & vchPubKey = vSolutions [ 0 ] ;
CKey key ;
if ( ! key . SetPubKey ( vchPubKey ) )
return false ;
if ( vchBlockSig . empty ( ) )
return false ;
return key . Verify ( GetHash ( ) , vchBlockSig ) ;
}
return false ;
}
# endif
