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// Copyright (c) 2009-2010 Satoshi Nakamoto
// Copyright (c) 2009-2016 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include "policy/fees.h"
#include "policy/policy.h"
#include "amount.h"
#include "primitives/transaction.h"
#include "random.h"
#include "streams.h"
#include "txmempool.h"
#include "util.h"
void TxConfirmStats::Initialize(std::vector<double>& defaultBuckets,
unsigned int maxConfirms, double _decay)
{
decay = _decay;
for (unsigned int i = 0; i < defaultBuckets.size(); i++) {
buckets.push_back(defaultBuckets[i]);
bucketMap[defaultBuckets[i]] = i;
}
confAvg.resize(maxConfirms);
curBlockConf.resize(maxConfirms);
unconfTxs.resize(maxConfirms);
for (unsigned int i = 0; i < maxConfirms; i++) {
confAvg[i].resize(buckets.size());
curBlockConf[i].resize(buckets.size());
unconfTxs[i].resize(buckets.size());
}
oldUnconfTxs.resize(buckets.size());
curBlockTxCt.resize(buckets.size());
txCtAvg.resize(buckets.size());
curBlockVal.resize(buckets.size());
avg.resize(buckets.size());
}
// Zero out the data for the current block
void TxConfirmStats::ClearCurrent(unsigned int nBlockHeight)
{
for (unsigned int j = 0; j < buckets.size(); j++) {
oldUnconfTxs[j] += unconfTxs[nBlockHeight%unconfTxs.size()][j];
unconfTxs[nBlockHeight%unconfTxs.size()][j] = 0;
for (unsigned int i = 0; i < curBlockConf.size(); i++)
curBlockConf[i][j] = 0;
curBlockTxCt[j] = 0;
curBlockVal[j] = 0;
}
}
void TxConfirmStats::Record(int blocksToConfirm, double val)
{
// blocksToConfirm is 1-based
if (blocksToConfirm < 1)
return;
unsigned int bucketindex = bucketMap.lower_bound(val)->second;
for (size_t i = blocksToConfirm; i <= curBlockConf.size(); i++) {
curBlockConf[i - 1][bucketindex]++;
}
curBlockTxCt[bucketindex]++;
curBlockVal[bucketindex] += val;
}
void TxConfirmStats::UpdateMovingAverages()
{
for (unsigned int j = 0; j < buckets.size(); j++) {
for (unsigned int i = 0; i < confAvg.size(); i++)
confAvg[i][j] = confAvg[i][j] * decay + curBlockConf[i][j];
avg[j] = avg[j] * decay + curBlockVal[j];
txCtAvg[j] = txCtAvg[j] * decay + curBlockTxCt[j];
}
}
// returns -1 on error conditions
double TxConfirmStats::EstimateMedianVal(int confTarget, double sufficientTxVal,
double successBreakPoint, bool requireGreater,
unsigned int nBlockHeight)
{
// Counters for a bucket (or range of buckets)
double nConf = 0; // Number of tx's confirmed within the confTarget
double totalNum = 0; // Total number of tx's that were ever confirmed
int extraNum = 0; // Number of tx's still in mempool for confTarget or longer
int maxbucketindex = buckets.size() - 1;
// requireGreater means we are looking for the lowest feerate such that all higher
// values pass, so we start at maxbucketindex (highest feerate) and look at successively
// smaller buckets until we reach failure. Otherwise, we are looking for the highest
// feerate such that all lower values fail, and we go in the opposite direction.
unsigned int startbucket = requireGreater ? maxbucketindex : 0;
int step = requireGreater ? -1 : 1;
// We'll combine buckets until we have enough samples.
// The near and far variables will define the range we've combined
// The best variables are the last range we saw which still had a high
// enough confirmation rate to count as success.
// The cur variables are the current range we're counting.
unsigned int curNearBucket = startbucket;
unsigned int bestNearBucket = startbucket;
unsigned int curFarBucket = startbucket;
unsigned int bestFarBucket = startbucket;
bool foundAnswer = false;
unsigned int bins = unconfTxs.size();
// Start counting from highest(default) or lowest feerate transactions
for (int bucket = startbucket; bucket >= 0 && bucket <= maxbucketindex; bucket += step) {
curFarBucket = bucket;
nConf += confAvg[confTarget - 1][bucket];
totalNum += txCtAvg[bucket];
for (unsigned int confct = confTarget; confct < GetMaxConfirms(); confct++)
extraNum += unconfTxs[(nBlockHeight - confct)%bins][bucket];
extraNum += oldUnconfTxs[bucket];
// If we have enough transaction data points in this range of buckets,
// we can test for success
// (Only count the confirmed data points, so that each confirmation count
// will be looking at the same amount of data and same bucket breaks)
if (totalNum >= sufficientTxVal / (1 - decay)) {
double curPct = nConf / (totalNum + extraNum);
// Check to see if we are no longer getting confirmed at the success rate
if (requireGreater && curPct < successBreakPoint)
break;
if (!requireGreater && curPct > successBreakPoint)
break;
// Otherwise update the cumulative stats, and the bucket variables
// and reset the counters
else {
foundAnswer = true;
nConf = 0;
totalNum = 0;
extraNum = 0;
bestNearBucket = curNearBucket;
bestFarBucket = curFarBucket;
curNearBucket = bucket + step;
}
}
}
double median = -1;
double txSum = 0;
// Calculate the "average" feerate of the best bucket range that met success conditions
// Find the bucket with the median transaction and then report the average feerate from that bucket
// This is a compromise between finding the median which we can't since we don't save all tx's
// and reporting the average which is less accurate
unsigned int minBucket = bestNearBucket < bestFarBucket ? bestNearBucket : bestFarBucket;
unsigned int maxBucket = bestNearBucket > bestFarBucket ? bestNearBucket : bestFarBucket;
for (unsigned int j = minBucket; j <= maxBucket; j++) {
txSum += txCtAvg[j];
}
if (foundAnswer && txSum != 0) {
txSum = txSum / 2;
for (unsigned int j = minBucket; j <= maxBucket; j++) {
if (txCtAvg[j] < txSum)
txSum -= txCtAvg[j];
else { // we're in the right bucket
median = avg[j] / txCtAvg[j];
break;
}
}
}
LogPrint("estimatefee", "%3d: For conf success %s %4.2f need feerate %s: %12.5g from buckets %8g - %8g Cur Bucket stats %6.2f%% %8.1f/(%.1f+%d mempool)\n",
confTarget, requireGreater ? ">" : "<", successBreakPoint,
requireGreater ? ">" : "<", median, buckets[minBucket], buckets[maxBucket],
100 * nConf / (totalNum + extraNum), nConf, totalNum, extraNum);
return median;
}
void TxConfirmStats::Write(CAutoFile& fileout)
{
fileout << decay;
fileout << buckets;
fileout << avg;
fileout << txCtAvg;
fileout << confAvg;
}
void TxConfirmStats::Read(CAutoFile& filein)
{
// Read data file into temporary variables and do some very basic sanity checking
std::vector<double> fileBuckets;
std::vector<double> fileAvg;
std::vector<std::vector<double> > fileConfAvg;
std::vector<double> fileTxCtAvg;
double fileDecay;
size_t maxConfirms;
size_t numBuckets;
filein >> fileDecay;
if (fileDecay <= 0 || fileDecay >= 1)
throw std::runtime_error("Corrupt estimates file. Decay must be between 0 and 1 (non-inclusive)");
filein >> fileBuckets;
numBuckets = fileBuckets.size();
if (numBuckets <= 1 || numBuckets > 1000)
throw std::runtime_error("Corrupt estimates file. Must have between 2 and 1000 feerate buckets");
filein >> fileAvg;
if (fileAvg.size() != numBuckets)
throw std::runtime_error("Corrupt estimates file. Mismatch in feerate average bucket count");
filein >> fileTxCtAvg;
if (fileTxCtAvg.size() != numBuckets)
throw std::runtime_error("Corrupt estimates file. Mismatch in tx count bucket count");
filein >> fileConfAvg;
maxConfirms = fileConfAvg.size();
if (maxConfirms <= 0 || maxConfirms > 6 * 24 * 7) // one week
throw std::runtime_error("Corrupt estimates file. Must maintain estimates for between 1 and 1008 (one week) confirms");
for (unsigned int i = 0; i < maxConfirms; i++) {
if (fileConfAvg[i].size() != numBuckets)
throw std::runtime_error("Corrupt estimates file. Mismatch in feerate conf average bucket count");
}
// Now that we've processed the entire feerate estimate data file and not
// thrown any errors, we can copy it to our data structures
decay = fileDecay;
buckets = fileBuckets;
avg = fileAvg;
confAvg = fileConfAvg;
txCtAvg = fileTxCtAvg;
bucketMap.clear();
// Resize the current block variables which aren't stored in the data file
// to match the number of confirms and buckets
curBlockConf.resize(maxConfirms);
for (unsigned int i = 0; i < maxConfirms; i++) {
curBlockConf[i].resize(buckets.size());
}
curBlockTxCt.resize(buckets.size());
curBlockVal.resize(buckets.size());
unconfTxs.resize(maxConfirms);
for (unsigned int i = 0; i < maxConfirms; i++) {
unconfTxs[i].resize(buckets.size());
}
oldUnconfTxs.resize(buckets.size());
for (unsigned int i = 0; i < buckets.size(); i++)
bucketMap[buckets[i]] = i;
LogPrint("estimatefee", "Reading estimates: %u buckets counting confirms up to %u blocks\n",
numBuckets, maxConfirms);
}
unsigned int TxConfirmStats::NewTx(unsigned int nBlockHeight, double val)
{
unsigned int bucketindex = bucketMap.lower_bound(val)->second;
unsigned int blockIndex = nBlockHeight % unconfTxs.size();
unconfTxs[blockIndex][bucketindex]++;
return bucketindex;
}
void TxConfirmStats::removeTx(unsigned int entryHeight, unsigned int nBestSeenHeight, unsigned int bucketindex)
{
//nBestSeenHeight is not updated yet for the new block
int blocksAgo = nBestSeenHeight - entryHeight;
if (nBestSeenHeight == 0) // the BlockPolicyEstimator hasn't seen any blocks yet
blocksAgo = 0;
if (blocksAgo < 0) {
LogPrint("estimatefee", "Blockpolicy error, blocks ago is negative for mempool tx\n");
return; //This can't happen because we call this with our best seen height, no entries can have higher
}
if (blocksAgo >= (int)unconfTxs.size()) {
if (oldUnconfTxs[bucketindex] > 0)
oldUnconfTxs[bucketindex]--;
else
LogPrint("estimatefee", "Blockpolicy error, mempool tx removed from >25 blocks,bucketIndex=%u already\n",
bucketindex);
}
else {
unsigned int blockIndex = entryHeight % unconfTxs.size();
if (unconfTxs[blockIndex][bucketindex] > 0)
unconfTxs[blockIndex][bucketindex]--;
else
LogPrint("estimatefee", "Blockpolicy error, mempool tx removed from blockIndex=%u,bucketIndex=%u already\n",
blockIndex, bucketindex);
}
}
bool CBlockPolicyEstimator::removeTx(uint256 hash)
{
std::map<uint256, TxStatsInfo>::iterator pos = mapMemPoolTxs.find(hash);
if (pos != mapMemPoolTxs.end()) {
feeStats.removeTx(pos->second.blockHeight, nBestSeenHeight, pos->second.bucketIndex);
mapMemPoolTxs.erase(hash);
return true;
} else {
return false;
}
}
CBlockPolicyEstimator::CBlockPolicyEstimator(const CFeeRate& _minRelayFee)
: nBestSeenHeight(0)
{
static_assert(MIN_FEERATE > 0, "Min feerate must be nonzero");
minTrackedFee = _minRelayFee < CFeeRate(MIN_FEERATE) ? CFeeRate(MIN_FEERATE) : _minRelayFee;
std::vector<double> vfeelist;
for (double bucketBoundary = minTrackedFee.GetFeePerK(); bucketBoundary <= MAX_FEERATE; bucketBoundary *= FEE_SPACING) {
vfeelist.push_back(bucketBoundary);
}
vfeelist.push_back(INF_FEERATE);
feeStats.Initialize(vfeelist, MAX_BLOCK_CONFIRMS, DEFAULT_DECAY);
}
void CBlockPolicyEstimator::processTransaction(const CTxMemPoolEntry& entry, bool fCurrentEstimate)
{
unsigned int txHeight = entry.GetHeight();
uint256 hash = entry.GetTx().GetHash();
if (mapMemPoolTxs.count(hash)) {
LogPrint("estimatefee", "Blockpolicy error mempool tx %s already being tracked\n",
hash.ToString().c_str());
return;
}
if (txHeight < nBestSeenHeight) {
// Ignore side chains and re-orgs; assuming they are random they don't
// affect the estimate. We'll potentially double count transactions in 1-block reorgs.
return;
}
// Only want to be updating estimates when our blockchain is synced,
// otherwise we'll miscalculate how many blocks its taking to get included.
if (!fCurrentEstimate)
return;
if (!entry.WasClearAtEntry()) {
// This transaction depends on other transactions in the mempool to
// be included in a block before it will be able to be included, so
// we shouldn't include it in our calculations
return;
}
// Feerates are stored and reported as BTC-per-kb:
CFeeRate feeRate(entry.GetFee(), entry.GetTxSize());
mapMemPoolTxs[hash].blockHeight = txHeight;
mapMemPoolTxs[hash].bucketIndex = feeStats.NewTx(txHeight, (double)feeRate.GetFeePerK());
}
void CBlockPolicyEstimator::processBlockTx(unsigned int nBlockHeight, const CTxMemPoolEntry& entry)
{
if (!entry.WasClearAtEntry()) {
// This transaction depended on other transactions in the mempool to
// be included in a block before it was able to be included, so
// we shouldn't include it in our calculations
return;
}
// How many blocks did it take for miners to include this transaction?
// blocksToConfirm is 1-based, so a transaction included in the earliest
// possible block has confirmation count of 1
int blocksToConfirm = nBlockHeight - entry.GetHeight();
if (blocksToConfirm <= 0) {
// This can't happen because we don't process transactions from a block with a height
// lower than our greatest seen height
LogPrint("estimatefee", "Blockpolicy error Transaction had negative blocksToConfirm\n");
return;
}
// Feerates are stored and reported as BTC-per-kb:
CFeeRate feeRate(entry.GetFee(), entry.GetTxSize());
feeStats.Record(blocksToConfirm, (double)feeRate.GetFeePerK());
}
void CBlockPolicyEstimator::processBlock(unsigned int nBlockHeight,
std::vector<CTxMemPoolEntry>& entries, bool fCurrentEstimate)
{
if (nBlockHeight <= nBestSeenHeight) {
// Ignore side chains and re-orgs; assuming they are random
// they don't affect the estimate.
// And if an attacker can re-org the chain at will, then
// you've got much bigger problems than "attacker can influence
// transaction fees."
return;
}
nBestSeenHeight = nBlockHeight;
// Only want to be updating estimates when our blockchain is synced,
// otherwise we'll miscalculate how many blocks its taking to get included.
if (!fCurrentEstimate)
return;
// Clear the current block state
feeStats.ClearCurrent(nBlockHeight);
// Repopulate the current block states
for (unsigned int i = 0; i < entries.size(); i++)
processBlockTx(nBlockHeight, entries[i]);
// Update all exponential averages with the current block state
feeStats.UpdateMovingAverages();
LogPrint("estimatefee", "Blockpolicy after updating estimates for %u confirmed entries, new mempool map size %u\n",
entries.size(), mapMemPoolTxs.size());
}
CFeeRate CBlockPolicyEstimator::estimateFee(int confTarget)
{
// Return failure if trying to analyze a target we're not tracking
// It's not possible to get reasonable estimates for confTarget of 1
if (confTarget <= 1 || (unsigned int)confTarget > feeStats.GetMaxConfirms())
return CFeeRate(0);
double median = feeStats.EstimateMedianVal(confTarget, SUFFICIENT_FEETXS, MIN_SUCCESS_PCT, true, nBestSeenHeight);
if (median < 0)
return CFeeRate(0);
return CFeeRate(median);
}
CFeeRate CBlockPolicyEstimator::estimateSmartFee(int confTarget, int *answerFoundAtTarget, const CTxMemPool& pool)
{
if (answerFoundAtTarget)
*answerFoundAtTarget = confTarget;
// Return failure if trying to analyze a target we're not tracking
if (confTarget <= 0 || (unsigned int)confTarget > feeStats.GetMaxConfirms())
return CFeeRate(0);
// It's not possible to get reasonable estimates for confTarget of 1
if (confTarget == 1)
confTarget = 2;
double median = -1;
while (median < 0 && (unsigned int)confTarget <= feeStats.GetMaxConfirms()) {
median = feeStats.EstimateMedianVal(confTarget++, SUFFICIENT_FEETXS, MIN_SUCCESS_PCT, true, nBestSeenHeight);
}
if (answerFoundAtTarget)
*answerFoundAtTarget = confTarget - 1;
// 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)
return CFeeRate(minPoolFee);
if (median < 0)
return CFeeRate(0);
return CFeeRate(median);
}
double CBlockPolicyEstimator::estimatePriority(int confTarget)
{
return -1;
}
double CBlockPolicyEstimator::estimateSmartPriority(int confTarget, int *answerFoundAtTarget, const CTxMemPool& pool)
{
if (answerFoundAtTarget)
*answerFoundAtTarget = confTarget;
// If mempool is limiting txs, no priority txs are allowed
CAmount minPoolFee = pool.GetMinFee(GetArg("-maxmempool", DEFAULT_MAX_MEMPOOL_SIZE) * 1000000).GetFeePerK();
if (minPoolFee > 0)
return INF_PRIORITY;
return -1;
}
void CBlockPolicyEstimator::Write(CAutoFile& fileout)
{
fileout << nBestSeenHeight;
feeStats.Write(fileout);
}
void CBlockPolicyEstimator::Read(CAutoFile& filein, int nFileVersion)
{
int nFileBestSeenHeight;
filein >> nFileBestSeenHeight;
feeStats.Read(filein);
nBestSeenHeight = nFileBestSeenHeight;
if (nFileVersion < 139900) {
TxConfirmStats priStats;
priStats.Read(filein);
}
}
FeeFilterRounder::FeeFilterRounder(const CFeeRate& minIncrementalFee)
{
CAmount minFeeLimit = std::max(CAmount(1), minIncrementalFee.GetFeePerK() / 2);
feeset.insert(0);
for (double bucketBoundary = minFeeLimit; bucketBoundary <= MAX_FEERATE; bucketBoundary *= FEE_SPACING) {
feeset.insert(bucketBoundary);
}
}
CAmount FeeFilterRounder::round(CAmount currentMinFee)
{
std::set<double>::iterator it = feeset.lower_bound(currentMinFee);
if ((it != feeset.begin() && insecure_rand.rand32() % 3 != 0) || it == feeset.end()) {
it--;
}
return *it;
}
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