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thehub/hub/server/txmempool.cpp
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tomFlowee 0a2e552168 Move more logic over to byte-array based Block 
This introduces a new BlockHeader helper class which Block and
MutableBlock can both produce, which helps a lot of methods to
be ported to no longer be dependent on us using a MutableBlock
object, which is too costly to use when we have no intention
to alter the block.
2026-04-20 22:21:18 +02:00

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/*
* This file is part of the Flowee project
* Copyright (C) 2009-2010 Satoshi Nakamoto
* Copyright (C) 2009-2015 The Bitcoin Core developers
* Copyright (C) 2017-2021 Tom Zander <tom@flowee.org>
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "DoubleSpendProof.h"
#include "DoubleSpendProofStorage.h"
#include "txmempool.h"
#include "consensus/consensus.h"
#include "consensus/validation.h"
#include "main.h"
#include "streaming/streams.h"
#include "timedata.h"
#include "util.h"
#include "utilmoneystr.h"
#include "utiltime.h"
#include <core_memusage.h>
#include <utxo/UnspentOutputDatabase.h>
#include <validation/ValidationException.h>
#include <validationinterface.h>
CTxMemPoolEntry::CTxMemPoolEntry(const Tx &tx)
: tx(tx),
nModFeesWithDescendants(0)
{
oldTx = tx.createOldTransaction();
nTime = ::GetTime();
nTxSize = tx.size();
nModSize = oldTx.CalculateModifiedSize(nTxSize);
nUsageSize = RecursiveDynamicUsage(oldTx);
nCountWithDescendants = 1;
nSizeWithDescendants = nTxSize;
feeDelta = 0;
}
CTxMemPoolEntry::CTxMemPoolEntry(const CTransaction &tx, int64_t _nFee,
int64_t _nTime, double _entryPriority, unsigned int _entryHeight,
bool poolHasNoInputsOf, int64_t _inChainInputValue,
bool _spendsCoinbase, LockPoints lp)
: CTxMemPoolEntry(Tx::fromOldTransaction(tx))
{
nFee = _nFee;
nModFeesWithDescendants = nFee;
nTime = _nTime;
entryPriority = _entryPriority;
entryHeight = _entryHeight;
hadNoDependencies = poolHasNoInputsOf;
inChainInputValue = _inChainInputValue;
spendsCoinbase = _spendsCoinbase;
lockPoints = lp;
assert(inChainInputValue <= oldTx.GetValueOut() + nFee);
}
CTxMemPoolEntry::CTxMemPoolEntry(const CTxMemPoolEntry& other)
{
*this = other;
}
double
CTxMemPoolEntry::GetPriority(unsigned int currentHeight) const
{
double deltaPriority = ((double)(currentHeight-entryHeight)*inChainInputValue)/nModSize;
double dResult = entryPriority + deltaPriority;
if (dResult < 0) // This should only happen if it was called with a height below entry height
dResult = 0;
return dResult;
}
void CTxMemPoolEntry::UpdateFeeDelta(int64_t newFeeDelta)
{
nModFeesWithDescendants += newFeeDelta - feeDelta;
feeDelta = newFeeDelta;
}
void CTxMemPoolEntry::UpdateLockPoints(const LockPoints& lp)
{
lockPoints = lp;
}
// Update the given tx for any in-mempool descendants.
// Assumes that setMemPoolChildren is correct for the given tx and all
// descendants.
bool CTxMemPool::UpdateForDescendants(txiter updateIt, int maxDescendantsToVisit, cacheMap &cachedDescendants, const std::set<uint256> &setExclude)
{
// Track the number of entries (outside setExclude) that we'd need to visit
// (will bail out if it exceeds maxDescendantsToVisit)
int nChildrenToVisit = 0;
setEntries stageEntries, setAllDescendants;
stageEntries = GetMemPoolChildren(updateIt);
while (!stageEntries.empty()) {
const txiter cit = *stageEntries.begin();
if (cit->IsDirty()) {
// Don't consider any more children if any descendant is dirty
return false;
}
setAllDescendants.insert(cit);
stageEntries.erase(cit);
const setEntries &setChildren = GetMemPoolChildren(cit);
for (const txiter childEntry : setChildren) {
cacheMap::iterator cacheIt = cachedDescendants.find(childEntry);
if (cacheIt != cachedDescendants.end()) {
// We've already calculated this one, just add the entries for this set
// but don't traverse again.
for (const txiter cacheEntry : cacheIt->second) {
// update visit count only for new child transactions
// (outside of setExclude and stageEntries)
if (setAllDescendants.insert(cacheEntry).second &&
!setExclude.count(cacheEntry->GetTx().GetHash()) &&
!stageEntries.count(cacheEntry)) {
nChildrenToVisit++;
}
}
} else if (!setAllDescendants.count(childEntry)) {
// Schedule for later processing and update our visit count
if (stageEntries.insert(childEntry).second && !setExclude.count(childEntry->GetTx().GetHash())) {
nChildrenToVisit++;
}
}
if (nChildrenToVisit > maxDescendantsToVisit) {
return false;
}
}
}
// setAllDescendants now contains all in-mempool descendants of updateIt.
// Update and add to cached descendant map
int64_t modifySize = 0;
int64_t modifyFee = 0;
int64_t modifyCount = 0;
for (txiter cit : setAllDescendants) {
if (!setExclude.count(cit->GetTx().GetHash())) {
modifySize += cit->GetTxSize();
modifyFee += cit->GetModifiedFee();
modifyCount++;
cachedDescendants[updateIt].insert(cit);
}
}
mapTx.modify(updateIt, update_descendant_state(modifySize, modifyFee, modifyCount));
return true;
}
// vHashesToUpdate is the set of transaction hashes from a disconnected block
// which has been re-added to the mempool.
// for each entry, look for descendants that are outside hashesToUpdate, and
// add fee/size information for such descendants to the parent.
void CTxMemPool::UpdateTransactionsFromBlock(const std::vector<uint256> &vHashesToUpdate)
{
LOCK(cs);
// For each entry in vHashesToUpdate, store the set of in-mempool, but not
// in-vHashesToUpdate transactions, so that we don't have to recalculate
// descendants when we come across a previously seen entry.
cacheMap mapMemPoolDescendantsToUpdate;
// Use a set for lookups into vHashesToUpdate (these entries are already
// accounted for in the state of their ancestors)
std::set<uint256> setAlreadyIncluded(vHashesToUpdate.begin(), vHashesToUpdate.end());
// Iterate in reverse, so that whenever we are looking at at a transaction
// we are sure that all in-mempool descendants have already been processed.
// This maximizes the benefit of the descendant cache and guarantees that
// setMemPoolChildren will be updated, an assumption made in
// UpdateForDescendants.
BOOST_REVERSE_FOREACH(const uint256 &hash, vHashesToUpdate) {
// we cache the in-mempool children to avoid duplicate updates
setEntries setChildren;
// calculate children from mapNextTx
txiter it = mapTx.find(hash);
if (it == mapTx.end()) {
continue;
}
std::map<COutPoint, CInPoint>::iterator iter = mapNextTx.lower_bound(COutPoint(hash, 0));
// First calculate the children, and update setMemPoolChildren to
// include them, and update their setMemPoolParents to include this tx.
for (; iter != mapNextTx.end() && iter->first.hash == hash; ++iter) {
const uint256 &childHash = iter->second.ptx->GetHash();
txiter childIter = mapTx.find(childHash);
assert(childIter != mapTx.end());
// We can skip updating entries we've encountered before or that
// are in the block (which are already accounted for).
if (setChildren.insert(childIter).second && !setAlreadyIncluded.count(childHash)) {
UpdateChild(it, childIter, true);
UpdateParent(childIter, it, true);
}
}
if (!UpdateForDescendants(it, 100, mapMemPoolDescendantsToUpdate, setAlreadyIncluded)) {
// Mark as dirty if we can't do the calculation.
mapTx.modify(it, set_dirty());
}
}
}
bool CTxMemPool::CalculateMemPoolAncestors(const CTxMemPoolEntry &entry, setEntries &setAncestors, uint64_t limitAncestorCount, uint64_t limitAncestorSize, uint64_t limitDescendantCount, uint64_t limitDescendantSize, std::string &errString, bool fSearchForParents /* = true */)
{
setEntries parentHashes;
const CTransaction &tx = entry.GetTx();
if (fSearchForParents) {
// Get parents of this transaction that are in the mempool
// GetMemPoolParents() is only valid for entries in the mempool, so we
// iterate mapTx to find parents.
for (unsigned int i = 0; i < tx.vin.size(); i++) {
txiter piter = mapTx.find(tx.vin[i].prevout.hash);
if (piter != mapTx.end()) {
parentHashes.insert(piter);
if (parentHashes.size() + 1 > limitAncestorCount) {
errString = strprintf("too many unconfirmed parents [limit: %u]", limitAncestorCount);
return false;
}
}
}
} else {
// If we're not searching for parents, we require this to be an
// entry in the mempool already.
txiter it = mapTx.iterator_to(entry);
parentHashes = GetMemPoolParents(it);
}
size_t totalSizeWithAncestors = entry.GetTxSize();
while (!parentHashes.empty()) {
txiter stageit = *parentHashes.begin();
setAncestors.insert(stageit);
parentHashes.erase(stageit);
totalSizeWithAncestors += stageit->GetTxSize();
if (stageit->GetSizeWithDescendants() + entry.GetTxSize() > limitDescendantSize) {
errString = strprintf("exceeds descendant size limit for tx %s [limit: %u]", stageit->GetTx().GetHash().ToString(), limitDescendantSize);
return false;
} else if (stageit->GetCountWithDescendants() + 1 > limitDescendantCount) {
errString = strprintf("too many descendants for tx %s [limit: %u]", stageit->GetTx().GetHash().ToString(), limitDescendantCount);
return false;
} else if (totalSizeWithAncestors > limitAncestorSize) {
errString = strprintf("exceeds ancestor size limit [limit: %u]", limitAncestorSize);
return false;
}
const setEntries & setMemPoolParents = GetMemPoolParents(stageit);
for (const txiter &phash : setMemPoolParents) {
// If this is a new ancestor, add it.
if (setAncestors.count(phash) == 0) {
parentHashes.insert(phash);
}
if (parentHashes.size() + setAncestors.size() + 1 > limitAncestorCount) {
errString = strprintf("too many unconfirmed ancestors [limit: %u]", limitAncestorCount);
return false;
}
}
}
return true;
}
void CTxMemPool::UpdateAncestorsOf(bool add, txiter it, const setEntries &setAncestors)
{
setEntries parentIters = GetMemPoolParents(it);
// add or remove this tx as a child of each parent
for (txiter piter : parentIters) {
UpdateChild(piter, it, add);
}
const int64_t updateCount = (add ? 1 : -1);
const int64_t updateSize = updateCount * it->GetTxSize();
const int64_t updateFee = updateCount * it->GetModifiedFee();
for (txiter ancestorIt : setAncestors) {
mapTx.modify(ancestorIt, update_descendant_state(updateSize, updateFee, updateCount));
}
}
void CTxMemPool::UpdateChildrenForRemoval(txiter it)
{
const setEntries &setMemPoolChildren = GetMemPoolChildren(it);
for (txiter updateIt : setMemPoolChildren) {
UpdateParent(updateIt, it, false);
}
}
void CTxMemPool::UpdateForRemoveFromMempool(const setEntries &entriesToRemove)
{
// For each entry, walk back all ancestors and decrement size associated with this
// transaction
const uint64_t nNoLimit = std::numeric_limits<uint64_t>::max();
for (txiter removeIt : entriesToRemove) {
setEntries setAncestors;
const CTxMemPoolEntry &entry = *removeIt;
std::string dummy;
// Since this is a tx that is already in the mempool, we can call CMPA
// with fSearchForParents = false. If the mempool is in a consistent
// state, then using true or false should both be correct, though false
// should be a bit faster.
// However, if we happen to be in the middle of processing a reorg, then
// the mempool can be in an inconsistent state. In this case, the set
// of ancestors reachable via mapLinks will be the same as the set of
// ancestors whose packages include this transaction, because when we
// add a new transaction to the mempool in addUnchecked(), we assume it
// has no children, and in the case of a reorg where that assumption is
// false, the in-mempool children aren't linked to the in-block tx's
// until UpdateTransactionsFromBlock() is called.
// So if we're being called during a reorg, ie before
// UpdateTransactionsFromBlock() has been called, then mapLinks[] will
// differ from the set of mempool parents we'd calculate by searching,
// and it's important that we use the mapLinks[] notion of ancestor
// transactions as the set of things to update for removal.
CalculateMemPoolAncestors(entry, setAncestors, nNoLimit, nNoLimit, nNoLimit, nNoLimit, dummy, false);
// Note that UpdateAncestorsOf severs the child links that point to
// removeIt in the entries for the parents of removeIt. This is
// fine since we don't need to use the mempool children of any entries
// to walk back over our ancestors (but we do need the mempool
// parents!)
UpdateAncestorsOf(false, removeIt, setAncestors);
}
// After updating all the ancestor sizes, we can now sever the link between each
// transaction being removed and any mempool children (ie, update setMemPoolParents
// for each direct child of a transaction being removed).
for (txiter removeIt : entriesToRemove) {
UpdateChildrenForRemoval(removeIt);
}
}
void CTxMemPoolEntry::SetDirty()
{
nCountWithDescendants = 0;
nSizeWithDescendants = nTxSize;
nModFeesWithDescendants = GetModifiedFee();
}
void CTxMemPoolEntry::UpdateState(int64_t modifySize, int64_t modifyFee, int64_t modifyCount)
{
if (!IsDirty()) {
nSizeWithDescendants += modifySize;
assert(int64_t(nSizeWithDescendants) > 0);
nModFeesWithDescendants += modifyFee;
nCountWithDescendants += modifyCount;
assert(int64_t(nCountWithDescendants) > 0);
}
}
CTxMemPool::CTxMemPool() :
nTransactionsUpdated(0),
m_utxo(nullptr),
m_dspStorage(new DoubleSpendProofStorage())
{
_clear(); //lock free clear
}
CTxMemPool::~CTxMemPool()
{
delete m_dspStorage;
}
unsigned int CTxMemPool::GetTransactionsUpdated() const
{
LOCK(cs);
return nTransactionsUpdated;
}
void CTxMemPool::AddTransactionsUpdated(unsigned int n)
{
LOCK(cs);
nTransactionsUpdated += n;
}
void CTxMemPool::addUnchecked(const uint256& hash, const CTxMemPoolEntry &entry, const setEntries &setAncestors)
{
// Add to memory pool without checking anything.
// Used by insertTx via TxValidationState which DOES do
// all the appropriate checks.
LOCK(cs);
indexed_transaction_set::iterator newit = mapTx.insert(entry).first;
mapLinks.insert(make_pair(newit, TxLinks()));
// Update transaction for any feeDelta created by PrioritiseTransaction
// TODO: refactor so that the fee delta is calculated before inserting
// into mapTx.
std::map<uint256, std::pair<double, int64_t> >::const_iterator pos = mapDeltas.find(hash);
if (pos != mapDeltas.end()) {
const std::pair<double, int64_t> &deltas = pos->second;
if (deltas.second) {
mapTx.modify(newit, update_fee_delta(deltas.second));
}
}
// Update cachedInnerUsage to include contained transaction's usage.
// (When we update the entry for in-mempool parents, memory usage will be
// further updated.)
cachedInnerUsage += entry.DynamicMemoryUsage();
const CTransaction& tx = newit->GetTx();
std::set<uint256> setParentTransactions;
for (unsigned int i = 0; i < tx.vin.size(); i++) {
mapNextTx[tx.vin[i].prevout] = CInPoint(&tx, entry.tx, i);
setParentTransactions.insert(tx.vin[i].prevout.hash);
}
// Don't bother worrying about child transactions of this one.
// Normal case of a new transaction arriving is that there can't be any
// children, because such children would be orphans.
// An exception to that is if a transaction enters that used to be in a block.
// In that case, our disconnect block logic will call UpdateTransactionsFromBlock
// to clean up the mess we're leaving here.
// Update ancestors with information about this tx
for (const uint256 &phash : setParentTransactions) {
txiter pit = mapTx.find(phash);
if (pit != mapTx.end()) {
UpdateParent(newit, pit, true);
}
}
UpdateAncestorsOf(true, newit, setAncestors);
nTransactionsUpdated++;
totalTxSize += entry.GetTxSize();
}
bool CTxMemPool::insertTx(CTxMemPoolEntry &entry)
{
assert(m_utxo);
assert(entry.dsproof == -1);
LOCK(cs);
uint256 hash = entry.tx.createHash();
if (exists(hash))
return false;
std::list<std::pair<int, int> > rescuedOrphans;
for (const CTxIn &txin : entry.oldTx.vin) { // find double spends.
auto orphans = m_dspStorage->findOrphans(txin.prevout);
if (!orphans.empty()) {
for (auto o : orphans)
rescuedOrphans.push_back(o);
// if we find this here, AS AN ORPHAN, then nothing has entered the mempool yet
// that claimed it. As such we don't have to check for conflicts.
assert(mapNextTx.find(txin.prevout) == mapNextTx.end()); // Check anyway
continue;
}
auto oldTx = mapNextTx.find(txin.prevout);
if (oldTx != mapNextTx.end()) { // double spend detected!
auto iter = mapTx.find(oldTx->second.tx.createHash());
assert(mapTx.end() != iter);
int newProofId = -1;
try {
if (iter->dsproof == -1) { // no DS proof exists, lets make one.
auto item = *iter;
logWarning(Log::DSProof) << "Double spend found, creating double spend proof"
<< oldTx->second.tx.createHash()
<< entry.tx.createHash();
item.dsproof = m_dspStorage->add(DoubleSpendProof::create(oldTx->second.tx, entry.tx));
if (item.dsproof == -1) // DSP-hash already known
return false;
mapTx.replace(iter, item);
newProofId = item.dsproof;
#ifndef NDEBUG
auto newIter = mapTx.find(oldTx->second.tx.createHash());
assert(newIter->dsproof == newProofId);
#endif
}
} catch (const std::runtime_error &e) {
// we don't support 100% of the types of transactions yet, failures are possible.
logWarning(Log::DSProof) << "Failed creating a proof:" << e;
throw Validation::Exception("Tx double spends another", 0);
}
throw Validation::DoubleSpendException(oldTx->second.tx, newProofId);
}
auto iter = mapTx.find(txin.prevout.hash);
if (iter != mapTx.end()) {
const CTransaction &prevTx = iter->GetTx();
if (txin.prevout.n < prevTx.vout.size() && !prevTx.vout[txin.prevout.n].IsNull())
continue; // found it in mempool.
}
const UnspentOutput uo = m_utxo->find(txin.prevout.hash, txin.prevout.n);
if (!uo.isValid())
return false;
}
addUnchecked(hash, entry);
for (auto i = rescuedOrphans.begin(); i != rescuedOrphans.end(); ++i) {
const int proofId = i->first;
auto dsp = m_dspStorage->proof(proofId);
logDebug(Log::DSProof) << "Rescued a DSP orphan" << dsp.createHash();
auto rc = dsp.validate(mempool);
// it can't be missing utxo or transaction, assert we are internally consistent.
assert(rc == DoubleSpendProof::Valid
|| rc == DoubleSpendProof::Invalid);
if (rc == DoubleSpendProof::Valid) {
logDebug(Log::DSProof) << " Using it, it validated just fine";
m_dspStorage->claimOrphan(proofId);
entry.dsproof = proofId;
txiter iter = mapTx.find(hash);
mapTx.replace(iter, entry);
while (++i != rescuedOrphans.end()) {
logDebug(Log::DSProof) << "Killing orphans, we don't need more than one";
m_dspStorage->remove(i->first);
}
return true;
} else {
logDebug(Log::DSProof) << " DSP didn't validate!" << dsp.createHash();
m_dspStorage->remove(proofId);
LOCK(cs_main);
Misbehaving(i->second, 10);
}
}
return true;
}
void CTxMemPool::removeUnchecked(txiter it)
{
if (it->dsproof != -1)
m_dspStorage->remove(it->dsproof);
for (const CTxIn& txin : it->GetTx().vin)
mapNextTx.erase(txin.prevout);
totalTxSize -= it->GetTxSize();
cachedInnerUsage -= it->DynamicMemoryUsage();
cachedInnerUsage -= memusage::DynamicUsage(mapLinks[it].parents) + memusage::DynamicUsage(mapLinks[it].children);
mapLinks.erase(it);
mapTx.erase(it);
nTransactionsUpdated++;
}
// Calculates descendants of entry that are not already in setDescendants, and adds to
// setDescendants. Assumes entryit is already a tx in the mempool and setMemPoolChildren
// is correct for tx and all descendants.
// Also assumes that if an entry is in setDescendants already, then all
// in-mempool descendants of it are already in setDescendants as well, so that we
// can save time by not iterating over those entries.
void CTxMemPool::CalculateDescendants(txiter entryit, setEntries &setDescendants)
{
setEntries stage;
if (setDescendants.count(entryit) == 0) {
stage.insert(entryit);
}
// Traverse down the children of entry, only adding children that are not
// accounted for in setDescendants already (because those children have either
// already been walked, or will be walked in this iteration).
while (!stage.empty()) {
txiter it = *stage.begin();
setDescendants.insert(it);
stage.erase(it);
const setEntries &setChildren = GetMemPoolChildren(it);
for (const txiter &childiter : setChildren) {
if (!setDescendants.count(childiter)) {
stage.insert(childiter);
}
}
}
}
void CTxMemPool::remove(const CTransaction &origTx, std::list<CTransaction>& removed, bool fRecursive)
{
// Remove transaction from memory pool
{
LOCK(cs);
setEntries txToRemove;
txiter origit = mapTx.find(origTx.GetHash());
if (origit != mapTx.end()) {
txToRemove.insert(origit);
} else if (fRecursive) {
// If recursively removing but origTx isn't in the mempool
// be sure to remove any children that are in the pool. This can
// happen during chain re-orgs if origTx isn't re-accepted into
// the mempool for any reason.
for (unsigned int i = 0; i < origTx.vout.size(); i++) {
std::map<COutPoint, CInPoint>::iterator it = mapNextTx.find(COutPoint(origTx.GetHash(), i));
if (it == mapNextTx.end())
continue;
txiter nextit = mapTx.find(it->second.ptx->GetHash());
assert(nextit != mapTx.end());
txToRemove.insert(nextit);
}
}
setEntries setAllRemoves;
if (fRecursive) {
for (txiter it : txToRemove) {
CalculateDescendants(it, setAllRemoves);
}
} else {
setAllRemoves.swap(txToRemove);
}
for (txiter it : setAllRemoves) {
removed.push_back(it->GetTx());
}
RemoveStaged(setAllRemoves);
}
}
void CTxMemPool::removeForReorg(unsigned int nMemPoolHeight, int flags)
{
// Remove transactions spending a coinbase which are now immature and no-longer-final transactions
LOCK(cs);
std::list<CTransaction> transactionsToRemove;
for (indexed_transaction_set::const_iterator it = mapTx.begin(); it != mapTx.end(); it++) {
const CTransaction& tx = it->GetTx();
LockPoints lp = it->GetLockPoints();
bool validLP = TestLockPointValidity(&lp);
if (!CheckFinalTx(it->tx, flags) || !CheckSequenceLocks(*this, tx, flags, &lp, validLP)) {
// Note if CheckSequenceLocks fails the LockPoints may still be invalid
// So it's critical that we remove the tx and not depend on the LockPoints.
transactionsToRemove.push_back(tx);
} else if (it->GetSpendsCoinbase()) {
for (const CTxIn& txin : tx.vin) {
indexed_transaction_set::const_iterator it2 = mapTx.find(txin.prevout.hash);
if (it2 != mapTx.end())
continue;
const UnspentOutput uo = m_utxo->find(txin.prevout.hash, txin.prevout.n);
if (!uo.isValid() || (uo.isCoinbase() && ((signed long)nMemPoolHeight) - uo.blockHeight() < COINBASE_MATURITY)) {
transactionsToRemove.push_back(tx);
break;
}
}
}
if (!validLP) {
mapTx.modify(it, update_lock_points(lp));
}
}
for (const CTransaction& tx : transactionsToRemove) {
std::list<CTransaction> removed;
remove(tx, removed, true);
}
}
void CTxMemPool::removeConflicts(const CTransaction &tx, std::list<CTransaction>& removed)
{
// Remove transactions which depend on inputs of tx, recursively
LOCK(cs);
for (const CTxIn &txin : tx.vin) {
std::map<COutPoint, CInPoint>::iterator it = mapNextTx.find(txin.prevout);
if (it != mapNextTx.end()) {
const CTransaction &txConflict = *it->second.ptx;
if (txConflict != tx) {
remove(txConflict, removed, true);
ClearPrioritisation(txConflict.GetHash());
}
}
}
}
/**
* Called when a block is connected. Removes from mempool and updates the miner fee estimator.
*/
void CTxMemPool::removeForBlock(const std::vector<CTransaction> &vtx, std::list<CTransaction> &conflicts)
{
LOCK(cs);
for (const CTransaction& tx : vtx) {
std::list<CTransaction> dummy;
remove(tx, dummy, false);
removeConflicts(tx, conflicts);
ClearPrioritisation(tx.GetHash());
}
}
void CTxMemPool::_clear()
{
mapLinks.clear();
mapTx.clear();
mapNextTx.clear();
totalTxSize = 0;
cachedInnerUsage = 0;
++nTransactionsUpdated;
}
void CTxMemPool::clear()
{
LOCK(cs);
_clear();
}
void CTxMemPool::queryHashes(std::vector<uint256>& vtxid)
{
vtxid.clear();
LOCK(cs);
vtxid.reserve(mapTx.size());
for (indexed_transaction_set::iterator mi = mapTx.begin(); mi != mapTx.end(); ++mi)
vtxid.push_back(mi->GetTx().GetHash());
}
bool CTxMemPool::lookup(const uint256 &hash, CTransaction &result) const
{
LOCK(cs);
indexed_transaction_set::const_iterator i = mapTx.find(hash);
if (i == mapTx.end()) return false;
result = i->GetTx();
return true;
}
bool CTxMemPool::lookup(const uint256 &hash, Tx& result) const
{
LOCK(cs);
indexed_transaction_set::const_iterator i = mapTx.find(hash);
if (i == mapTx.end()) return false;
result = i->tx;
return true;
}
bool CTxMemPool::lookup(const COutPoint &outpoint, Tx& result) const
{
LOCK(cs);
auto oldTx = mapNextTx.find(outpoint);
if (oldTx == mapNextTx.end())
return false;
result = oldTx->second.tx;
return true;
}
void CTxMemPool::PrioritiseTransaction(const uint256 hash, const std::string strHash, double dPriorityDelta, const int64_t& nFeeDelta)
{
{
LOCK(cs);
std::pair<double, int64_t> &deltas = mapDeltas[hash];
deltas.first += dPriorityDelta;
deltas.second += nFeeDelta;
txiter it = mapTx.find(hash);
if (it != mapTx.end()) {
mapTx.modify(it, update_fee_delta(deltas.second));
// Now update all ancestors' modified fees with descendants
setEntries setAncestors;
uint64_t nNoLimit = std::numeric_limits<uint64_t>::max();
std::string dummy;
CalculateMemPoolAncestors(*it, setAncestors, nNoLimit, nNoLimit, nNoLimit, nNoLimit, dummy, false);
for (txiter ancestorIt : setAncestors) {
mapTx.modify(ancestorIt, update_descendant_state(0, nFeeDelta, 0));
}
}
}
LogPrintf("PrioritiseTransaction: %s priority += %f, fee += %d\n", strHash, dPriorityDelta, FormatMoney(nFeeDelta));
}
void CTxMemPool::ApplyDeltas(const uint256 hash, double &dPriorityDelta, int64_t &nFeeDelta) const
{
LOCK(cs);
std::map<uint256, std::pair<double, int64_t> >::const_iterator pos = mapDeltas.find(hash);
if (pos == mapDeltas.end())
return;
const std::pair<double, int64_t> &deltas = pos->second;
dPriorityDelta += deltas.first;
nFeeDelta += deltas.second;
}
void CTxMemPool::ClearPrioritisation(const uint256 hash)
{
LOCK(cs);
mapDeltas.erase(hash);
}
bool CTxMemPool::HasNoInputsOf(const CTransaction &tx) const
{
for (unsigned int i = 0; i < tx.vin.size(); i++)
if (exists(tx.vin[i].prevout.hash))
return false;
return true;
}
size_t CTxMemPool::DynamicMemoryUsage() const {
LOCK(cs);
// Estimate the overhead of mapTx to be 12 pointers + an allocation, as no exact formula for boost::multi_index_contained is implemented.
return memusage::MallocUsage(sizeof(CTxMemPoolEntry) + 12 * sizeof(void*)) * mapTx.size() + memusage::DynamicUsage(mapNextTx) + memusage::DynamicUsage(mapDeltas) + memusage::DynamicUsage(mapLinks) + cachedInnerUsage;
}
void CTxMemPool::RemoveStaged(setEntries &stage) {
AssertLockHeld(cs);
UpdateForRemoveFromMempool(stage);
for (const txiter& it : stage) {
removeUnchecked(it);
}
}
int CTxMemPool::Expire(int64_t time) {
LOCK(cs);
indexed_transaction_set::nth_index<2>::type::iterator it = mapTx.get<2>().begin();
setEntries toremove;
while (it != mapTx.get<2>().end() && it->GetTime() < time) {
toremove.insert(mapTx.project<0>(it));
it++;
}
setEntries stage;
for (txiter removeit : toremove) {
CalculateDescendants(removeit, stage);
}
RemoveStaged(stage);
return stage.size();
}
void CTxMemPool::addUnchecked(const uint256&hash, const CTxMemPoolEntry &entry)
{
LOCK(cs);
setEntries setAncestors;
uint64_t nNoLimit = std::numeric_limits<uint64_t>::max();
std::string dummy;
CalculateMemPoolAncestors(entry, setAncestors, nNoLimit, nNoLimit, nNoLimit, nNoLimit, dummy);
addUnchecked(hash, entry, setAncestors);
}
void CTxMemPool::UpdateChild(txiter entry, txiter child, bool add)
{
setEntries s;
if (add && mapLinks[entry].children.insert(child).second) {
cachedInnerUsage += memusage::IncrementalDynamicUsage(s);
} else if (!add && mapLinks[entry].children.erase(child)) {
cachedInnerUsage -= memusage::IncrementalDynamicUsage(s);
}
}
void CTxMemPool::UpdateParent(txiter entry, txiter parent, bool add)
{
setEntries s;
if (add && mapLinks[entry].parents.insert(parent).second) {
cachedInnerUsage += memusage::IncrementalDynamicUsage(s);
} else if (!add && mapLinks[entry].parents.erase(parent)) {
cachedInnerUsage -= memusage::IncrementalDynamicUsage(s);
}
}
const CTxMemPool::setEntries & CTxMemPool::GetMemPoolParents(txiter entry) const
{
assert (entry != mapTx.end());
txlinksMap::const_iterator it = mapLinks.find(entry);
assert(it != mapLinks.end());
return it->second.parents;
}
const CTxMemPool::setEntries & CTxMemPool::GetMemPoolChildren(txiter entry) const
{
assert (entry != mapTx.end());
txlinksMap::const_iterator it = mapLinks.find(entry);
assert(it != mapLinks.end());
return it->second.children;
}
void CTxMemPool::setUtxo(UnspentOutputDatabase *utxo)
{
assert(utxo);
m_utxo = utxo;
}
Tx CTxMemPool::addDoubleSpendProof(const DoubleSpendProof &proof)
{
LOCK(cs);
auto oldTx = mapNextTx.find(COutPoint(proof.prevTxId(), proof.prevOutIndex()));
if (oldTx == mapNextTx.end())
return Tx();
auto iter = mapTx.find(oldTx->second.tx.createHash());
assert(mapTx.end() != iter);
if (iter->dsproof != -1) // A DSProof already exists for this tx.
return Tx(); // don't propagate new one.
auto item = *iter;
item.dsproof = m_dspStorage->add(proof);
mapTx.replace(iter, item);
return oldTx->second.tx;
}
DoubleSpendProofStorage *CTxMemPool::doubleSpendProofStorage() const
{
return m_dspStorage;
}
bool CTxMemPool::doubleSpendProofFor(const uint256 &txid, DoubleSpendProof &dsp)
{
LOCK(cs);
indexed_transaction_set::const_iterator i = mapTx.find(txid);
if (i == mapTx.end())
return false;
if (i->dsproof == -1)
return false;
dsp = doubleSpendProofStorage()->proof(i->dsproof);
return true;
}
CFeeRate CTxMemPool::GetMinFee() const
{
return CFeeRate();
}
void CTxMemPool::TrimToSize(size_t sizelimit, std::vector<uint256>* pvNoSpendsRemaining) {
LOCK(cs);
unsigned nTxnRemoved = 0;
while (DynamicMemoryUsage() > sizelimit) {
indexed_transaction_set::nth_index<1>::type::iterator it = mapTx.get<1>().begin();
setEntries stage;
CalculateDescendants(mapTx.project<0>(it), stage);
nTxnRemoved += stage.size();
std::vector<CTransaction> txn;
if (pvNoSpendsRemaining) {
txn.reserve(stage.size());
for (txiter it : stage)
txn.push_back(it->GetTx());
}
RemoveStaged(stage);
if (pvNoSpendsRemaining) {
for (const CTransaction& tx : txn) {
for (const CTxIn& txin : tx.vin) {
if (exists(txin.prevout.hash))
continue;
std::map<COutPoint, CInPoint>::iterator it = mapNextTx.lower_bound(COutPoint(txin.prevout.hash, 0));
if (it == mapNextTx.end() || it->first.hash != txin.prevout.hash)
pvNoSpendsRemaining->push_back(txin.prevout.hash);
}
}
}
}
}
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