@ -826,8 +826,10 @@ double CBlockPolicyEstimator::estimateConservativeFee(unsigned int doubleTarget,
@@ -826,8 +826,10 @@ double CBlockPolicyEstimator::estimateConservativeFee(unsigned int doubleTarget,
* estimates , however , required the 95 % threshold at 2 * target be met for any
* longer time horizons also .
*/
CFeeRate CBlockPolicyEstimator : : estimateSmartFee ( int confTarget , FeeCalculation * feeCalc , const CTxMemPool & pool , bool conservative ) const
CFeeRate CBlockPolicyEstimator : : estimateSmartFee ( int confTarget , FeeCalculation * feeCalc , bool conservative ) const
{
LOCK ( cs_feeEstimator ) ;
if ( feeCalc ) {
feeCalc - > desiredTarget = confTarget ;
feeCalc - > returnedTarget = confTarget ;
@ -835,80 +837,70 @@ CFeeRate CBlockPolicyEstimator::estimateSmartFee(int confTarget, FeeCalculation
@@ -835,80 +837,70 @@ CFeeRate CBlockPolicyEstimator::estimateSmartFee(int confTarget, FeeCalculation
double median = - 1 ;
EstimationResult tempResult ;
{
LOCK ( cs_feeEstimator ) ;
// Return failure if trying to analyze a target we're not tracking
if ( confTarget < = 0 | | ( unsigned int ) confTarget > longStats - > GetMaxConfirms ( ) )
return CFeeRate ( 0 ) ;
// Return failure if trying to analyze a target we're not tracking
if ( confTarget < = 0 | | ( unsigned int ) confTarget > longStats - > GetMaxConfirms ( ) )
return CFeeRate ( 0 ) ;
// It's not possible to get reasonable estimates for confTarget of 1
if ( confTarget = = 1 )
confTarget = 2 ;
// It's not possible to get reasonable estimates for confTarget of 1
if ( confTarget = = 1 )
confTarget = 2 ;
unsigned int maxUsableEstimate = MaxUsableEstimate ( ) ;
if ( maxUsableEstimate < = 1 )
return CFeeRate ( 0 ) ;
unsigned int maxUsableEstimate = MaxUsableEstimate ( ) ;
if ( maxUsableEstimate < = 1 )
return CFeeRate ( 0 ) ;
if ( ( unsigned int ) confTarget > maxUsableEstimate ) {
confTarget = maxUsableEstimate ;
}
if ( ( unsigned int ) confTarget > maxUsableEstimate ) {
confTarget = maxUsableEstimate ;
}
assert ( confTarget > 0 ) ; //estimateCombinedFee and estimateConservativeFee take unsigned ints
/** true is passed to estimateCombined fee for target/2 and target so
* that we check the max confirms for shorter time horizons as well .
* This is necessary to preserve monotonically increasing estimates .
* For non - conservative estimates we do the same thing for 2 * target , but
* for conservative estimates we want to skip these shorter horizons
* checks for 2 * target because we are taking the max over all time
* horizons so we already have monotonically increasing estimates and
* the purpose of conservative estimates is not to let short term
* fluctuations lower our estimates by too much .
*/
double halfEst = estimateCombinedFee ( confTarget / 2 , HALF_SUCCESS_PCT , true , & tempResult ) ;
assert ( confTarget > 0 ) ; //estimateCombinedFee and estimateConservativeFee take unsigned ints
/** true is passed to estimateCombined fee for target/2 and target so
* that we check the max confirms for shorter time horizons as well .
* This is necessary to preserve monotonically increasing estimates .
* For non - conservative estimates we do the same thing for 2 * target , but
* for conservative estimates we want to skip these shorter horizons
* checks for 2 * target because we are taking the max over all time
* horizons so we already have monotonically increasing estimates and
* the purpose of conservative estimates is not to let short term
* fluctuations lower our estimates by too much .
*/
double halfEst = estimateCombinedFee ( confTarget / 2 , HALF_SUCCESS_PCT , true , & tempResult ) ;
if ( feeCalc ) {
feeCalc - > est = tempResult ;
feeCalc - > reason = FeeReason : : HALF_ESTIMATE ;
}
median = halfEst ;
double actualEst = estimateCombinedFee ( confTarget , SUCCESS_PCT , true , & tempResult ) ;
if ( actualEst > median ) {
median = actualEst ;
if ( feeCalc ) {
feeCalc - > est = tempResult ;
feeCalc - > reason = FeeReason : : HALF_ESTIMATE ;
feeCalc - > reason = FeeReason : : FULL _ESTIMATE ;
}
median = halfEst ;
double actualEst = estimateCombinedFee ( confTarget , SUCCESS_PCT , true , & tempResult ) ;
if ( actualEst > median ) {
median = actualEst ;
if ( feeCalc ) {
feeCalc - > est = tempResult ;
feeCalc - > reason = FeeReason : : FULL_ESTIMATE ;
}
}
double doubleEst = estimateCombinedFee ( 2 * confTarget , DOUBLE_SUCCESS_PCT , ! conservative , & tempResult ) ;
if ( doubleEst > median ) {
median = doubleEst ;
if ( feeCalc ) {
feeCalc - > est = tempResult ;
feeCalc - > reason = FeeReason : : DOUBLE_ESTIMATE ;
}
double doubleEst = estimateCombinedFee ( 2 * confTarget , DOUBLE_SUCCESS_PCT , ! conservative , & tempResult ) ;
if ( doubleEst > median ) {
median = doubleEst ;
}
if ( conservative | | median = = - 1 ) {
double consEst = estimateConservativeFee ( 2 * confTarget , & tempResult ) ;
if ( consEst > median ) {
median = consEst ;
if ( feeCalc ) {
feeCalc - > est = tempResult ;
feeCalc - > reason = FeeReason : : DOUBLE_ESTIMATE ;
feeCalc - > reason = FeeReason : : CONSERVATIV E;
}
}
if ( conservative | | median = = - 1 ) {
double consEst = estimateConservativeFee ( 2 * confTarget , & tempResult ) ;
if ( consEst > median ) {
median = consEst ;
if ( feeCalc ) {
feeCalc - > est = tempResult ;
feeCalc - > reason = FeeReason : : CONSERVATIVE ;
}
}
}
} // Must unlock cs_feeEstimator before taking mempool locks
}
if ( feeCalc ) feeCalc - > returnedTarget = confTarget ;
// If mempool is limiting txs , return at least the min feerate from the mempool
CAmount minPoolFee = pool . GetMinFee ( GetArg ( " -maxmempool " , DEFAULT_MAX_MEMPOOL_SIZE ) * 1000000 ) . GetFeePerK ( ) ;
if ( minPoolFee > 0 & & minPoolFee > median ) {
if ( feeCalc ) feeCalc - > reason = FeeReason : : MEMPOOL_MIN ;
return CFeeRate ( minPoolFee ) ;
}
if ( median < 0 )
return CFeeRate ( 0 ) ;