go-pulse/core/tx_pool.go
Felix Lange 9489853321
core: check effective tip in txpool pricelimit validation (#23855)
The price limit is supposed to exclude transactions with too low fee
amount. Before EIP-1559, it was sufficient to check the limit against
the gas price of the transaction. After 1559, it is more complicated
because the concept of 'transaction gas price' does not really exist.

When mining, the price limit is used to exclude transactions below a
certain effective fee amount. This change makes it apply the same check
earlier, in tx validation. Transactions below the specified fee amount
cannot enter the pool.

Fixes #23837
2021-11-08 16:25:35 +02:00

1831 lines
62 KiB
Go

// Copyright 2014 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library 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 Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
package core
import (
"errors"
"math"
"math/big"
"sort"
"sync"
"sync/atomic"
"time"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/common/prque"
"github.com/ethereum/go-ethereum/consensus/misc"
"github.com/ethereum/go-ethereum/core/state"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/event"
"github.com/ethereum/go-ethereum/log"
"github.com/ethereum/go-ethereum/metrics"
"github.com/ethereum/go-ethereum/params"
)
const (
// chainHeadChanSize is the size of channel listening to ChainHeadEvent.
chainHeadChanSize = 10
// txSlotSize is used to calculate how many data slots a single transaction
// takes up based on its size. The slots are used as DoS protection, ensuring
// that validating a new transaction remains a constant operation (in reality
// O(maxslots), where max slots are 4 currently).
txSlotSize = 32 * 1024
// txMaxSize is the maximum size a single transaction can have. This field has
// non-trivial consequences: larger transactions are significantly harder and
// more expensive to propagate; larger transactions also take more resources
// to validate whether they fit into the pool or not.
txMaxSize = 4 * txSlotSize // 128KB
)
var (
// ErrAlreadyKnown is returned if the transactions is already contained
// within the pool.
ErrAlreadyKnown = errors.New("already known")
// ErrInvalidSender is returned if the transaction contains an invalid signature.
ErrInvalidSender = errors.New("invalid sender")
// ErrUnderpriced is returned if a transaction's gas price is below the minimum
// configured for the transaction pool.
ErrUnderpriced = errors.New("transaction underpriced")
// ErrTxPoolOverflow is returned if the transaction pool is full and can't accpet
// another remote transaction.
ErrTxPoolOverflow = errors.New("txpool is full")
// ErrReplaceUnderpriced is returned if a transaction is attempted to be replaced
// with a different one without the required price bump.
ErrReplaceUnderpriced = errors.New("replacement transaction underpriced")
// ErrGasLimit is returned if a transaction's requested gas limit exceeds the
// maximum allowance of the current block.
ErrGasLimit = errors.New("exceeds block gas limit")
// ErrNegativeValue is a sanity error to ensure no one is able to specify a
// transaction with a negative value.
ErrNegativeValue = errors.New("negative value")
// ErrOversizedData is returned if the input data of a transaction is greater
// than some meaningful limit a user might use. This is not a consensus error
// making the transaction invalid, rather a DOS protection.
ErrOversizedData = errors.New("oversized data")
)
var (
evictionInterval = time.Minute // Time interval to check for evictable transactions
statsReportInterval = 8 * time.Second // Time interval to report transaction pool stats
)
var (
// Metrics for the pending pool
pendingDiscardMeter = metrics.NewRegisteredMeter("txpool/pending/discard", nil)
pendingReplaceMeter = metrics.NewRegisteredMeter("txpool/pending/replace", nil)
pendingRateLimitMeter = metrics.NewRegisteredMeter("txpool/pending/ratelimit", nil) // Dropped due to rate limiting
pendingNofundsMeter = metrics.NewRegisteredMeter("txpool/pending/nofunds", nil) // Dropped due to out-of-funds
// Metrics for the queued pool
queuedDiscardMeter = metrics.NewRegisteredMeter("txpool/queued/discard", nil)
queuedReplaceMeter = metrics.NewRegisteredMeter("txpool/queued/replace", nil)
queuedRateLimitMeter = metrics.NewRegisteredMeter("txpool/queued/ratelimit", nil) // Dropped due to rate limiting
queuedNofundsMeter = metrics.NewRegisteredMeter("txpool/queued/nofunds", nil) // Dropped due to out-of-funds
queuedEvictionMeter = metrics.NewRegisteredMeter("txpool/queued/eviction", nil) // Dropped due to lifetime
// General tx metrics
knownTxMeter = metrics.NewRegisteredMeter("txpool/known", nil)
validTxMeter = metrics.NewRegisteredMeter("txpool/valid", nil)
invalidTxMeter = metrics.NewRegisteredMeter("txpool/invalid", nil)
underpricedTxMeter = metrics.NewRegisteredMeter("txpool/underpriced", nil)
overflowedTxMeter = metrics.NewRegisteredMeter("txpool/overflowed", nil)
// throttleTxMeter counts how many transactions are rejected due to too-many-changes between
// txpool reorgs.
throttleTxMeter = metrics.NewRegisteredMeter("txpool/throttle", nil)
// reorgDurationTimer measures how long time a txpool reorg takes.
reorgDurationTimer = metrics.NewRegisteredTimer("txpool/reorgtime", nil)
// dropBetweenReorgHistogram counts how many drops we experience between two reorg runs. It is expected
// that this number is pretty low, since txpool reorgs happen very frequently.
dropBetweenReorgHistogram = metrics.NewRegisteredHistogram("txpool/dropbetweenreorg", nil, metrics.NewExpDecaySample(1028, 0.015))
pendingGauge = metrics.NewRegisteredGauge("txpool/pending", nil)
queuedGauge = metrics.NewRegisteredGauge("txpool/queued", nil)
localGauge = metrics.NewRegisteredGauge("txpool/local", nil)
slotsGauge = metrics.NewRegisteredGauge("txpool/slots", nil)
reheapTimer = metrics.NewRegisteredTimer("txpool/reheap", nil)
)
// TxStatus is the current status of a transaction as seen by the pool.
type TxStatus uint
const (
TxStatusUnknown TxStatus = iota
TxStatusQueued
TxStatusPending
TxStatusIncluded
)
// blockChain provides the state of blockchain and current gas limit to do
// some pre checks in tx pool and event subscribers.
type blockChain interface {
CurrentBlock() *types.Block
GetBlock(hash common.Hash, number uint64) *types.Block
StateAt(root common.Hash) (*state.StateDB, error)
SubscribeChainHeadEvent(ch chan<- ChainHeadEvent) event.Subscription
}
// TxPoolConfig are the configuration parameters of the transaction pool.
type TxPoolConfig struct {
Locals []common.Address // Addresses that should be treated by default as local
NoLocals bool // Whether local transaction handling should be disabled
Journal string // Journal of local transactions to survive node restarts
Rejournal time.Duration // Time interval to regenerate the local transaction journal
PriceLimit uint64 // Minimum gas price to enforce for acceptance into the pool
PriceBump uint64 // Minimum price bump percentage to replace an already existing transaction (nonce)
AccountSlots uint64 // Number of executable transaction slots guaranteed per account
GlobalSlots uint64 // Maximum number of executable transaction slots for all accounts
AccountQueue uint64 // Maximum number of non-executable transaction slots permitted per account
GlobalQueue uint64 // Maximum number of non-executable transaction slots for all accounts
Lifetime time.Duration // Maximum amount of time non-executable transaction are queued
}
// DefaultTxPoolConfig contains the default configurations for the transaction
// pool.
var DefaultTxPoolConfig = TxPoolConfig{
Journal: "transactions.rlp",
Rejournal: time.Hour,
PriceLimit: 1,
PriceBump: 10,
AccountSlots: 16,
GlobalSlots: 4096 + 1024, // urgent + floating queue capacity with 4:1 ratio
AccountQueue: 64,
GlobalQueue: 1024,
Lifetime: 3 * time.Hour,
}
// sanitize checks the provided user configurations and changes anything that's
// unreasonable or unworkable.
func (config *TxPoolConfig) sanitize() TxPoolConfig {
conf := *config
if conf.Rejournal < time.Second {
log.Warn("Sanitizing invalid txpool journal time", "provided", conf.Rejournal, "updated", time.Second)
conf.Rejournal = time.Second
}
if conf.PriceLimit < 1 {
log.Warn("Sanitizing invalid txpool price limit", "provided", conf.PriceLimit, "updated", DefaultTxPoolConfig.PriceLimit)
conf.PriceLimit = DefaultTxPoolConfig.PriceLimit
}
if conf.PriceBump < 1 {
log.Warn("Sanitizing invalid txpool price bump", "provided", conf.PriceBump, "updated", DefaultTxPoolConfig.PriceBump)
conf.PriceBump = DefaultTxPoolConfig.PriceBump
}
if conf.AccountSlots < 1 {
log.Warn("Sanitizing invalid txpool account slots", "provided", conf.AccountSlots, "updated", DefaultTxPoolConfig.AccountSlots)
conf.AccountSlots = DefaultTxPoolConfig.AccountSlots
}
if conf.GlobalSlots < 1 {
log.Warn("Sanitizing invalid txpool global slots", "provided", conf.GlobalSlots, "updated", DefaultTxPoolConfig.GlobalSlots)
conf.GlobalSlots = DefaultTxPoolConfig.GlobalSlots
}
if conf.AccountQueue < 1 {
log.Warn("Sanitizing invalid txpool account queue", "provided", conf.AccountQueue, "updated", DefaultTxPoolConfig.AccountQueue)
conf.AccountQueue = DefaultTxPoolConfig.AccountQueue
}
if conf.GlobalQueue < 1 {
log.Warn("Sanitizing invalid txpool global queue", "provided", conf.GlobalQueue, "updated", DefaultTxPoolConfig.GlobalQueue)
conf.GlobalQueue = DefaultTxPoolConfig.GlobalQueue
}
if conf.Lifetime < 1 {
log.Warn("Sanitizing invalid txpool lifetime", "provided", conf.Lifetime, "updated", DefaultTxPoolConfig.Lifetime)
conf.Lifetime = DefaultTxPoolConfig.Lifetime
}
return conf
}
// TxPool contains all currently known transactions. Transactions
// enter the pool when they are received from the network or submitted
// locally. They exit the pool when they are included in the blockchain.
//
// The pool separates processable transactions (which can be applied to the
// current state) and future transactions. Transactions move between those
// two states over time as they are received and processed.
type TxPool struct {
config TxPoolConfig
chainconfig *params.ChainConfig
chain blockChain
gasPrice *big.Int
txFeed event.Feed
scope event.SubscriptionScope
signer types.Signer
mu sync.RWMutex
istanbul bool // Fork indicator whether we are in the istanbul stage.
eip2718 bool // Fork indicator whether we are using EIP-2718 type transactions.
eip1559 bool // Fork indicator whether we are using EIP-1559 type transactions.
currentState *state.StateDB // Current state in the blockchain head
pendingNonces *txNoncer // Pending state tracking virtual nonces
currentMaxGas uint64 // Current gas limit for transaction caps
locals *accountSet // Set of local transaction to exempt from eviction rules
journal *txJournal // Journal of local transaction to back up to disk
pending map[common.Address]*txList // All currently processable transactions
queue map[common.Address]*txList // Queued but non-processable transactions
beats map[common.Address]time.Time // Last heartbeat from each known account
all *txLookup // All transactions to allow lookups
priced *txPricedList // All transactions sorted by price
chainHeadCh chan ChainHeadEvent
chainHeadSub event.Subscription
reqResetCh chan *txpoolResetRequest
reqPromoteCh chan *accountSet
queueTxEventCh chan *types.Transaction
reorgDoneCh chan chan struct{}
reorgShutdownCh chan struct{} // requests shutdown of scheduleReorgLoop
wg sync.WaitGroup // tracks loop, scheduleReorgLoop
initDoneCh chan struct{} // is closed once the pool is initialized (for tests)
changesSinceReorg int // A counter for how many drops we've performed in-between reorg.
}
type txpoolResetRequest struct {
oldHead, newHead *types.Header
}
// NewTxPool creates a new transaction pool to gather, sort and filter inbound
// transactions from the network.
func NewTxPool(config TxPoolConfig, chainconfig *params.ChainConfig, chain blockChain) *TxPool {
// Sanitize the input to ensure no vulnerable gas prices are set
config = (&config).sanitize()
// Create the transaction pool with its initial settings
pool := &TxPool{
config: config,
chainconfig: chainconfig,
chain: chain,
signer: types.LatestSigner(chainconfig),
pending: make(map[common.Address]*txList),
queue: make(map[common.Address]*txList),
beats: make(map[common.Address]time.Time),
all: newTxLookup(),
chainHeadCh: make(chan ChainHeadEvent, chainHeadChanSize),
reqResetCh: make(chan *txpoolResetRequest),
reqPromoteCh: make(chan *accountSet),
queueTxEventCh: make(chan *types.Transaction),
reorgDoneCh: make(chan chan struct{}),
reorgShutdownCh: make(chan struct{}),
initDoneCh: make(chan struct{}),
gasPrice: new(big.Int).SetUint64(config.PriceLimit),
}
pool.locals = newAccountSet(pool.signer)
for _, addr := range config.Locals {
log.Info("Setting new local account", "address", addr)
pool.locals.add(addr)
}
pool.priced = newTxPricedList(pool.all)
pool.reset(nil, chain.CurrentBlock().Header())
// Start the reorg loop early so it can handle requests generated during journal loading.
pool.wg.Add(1)
go pool.scheduleReorgLoop()
// If local transactions and journaling is enabled, load from disk
if !config.NoLocals && config.Journal != "" {
pool.journal = newTxJournal(config.Journal)
if err := pool.journal.load(pool.AddLocals); err != nil {
log.Warn("Failed to load transaction journal", "err", err)
}
if err := pool.journal.rotate(pool.local()); err != nil {
log.Warn("Failed to rotate transaction journal", "err", err)
}
}
// Subscribe events from blockchain and start the main event loop.
pool.chainHeadSub = pool.chain.SubscribeChainHeadEvent(pool.chainHeadCh)
pool.wg.Add(1)
go pool.loop()
return pool
}
// loop is the transaction pool's main event loop, waiting for and reacting to
// outside blockchain events as well as for various reporting and transaction
// eviction events.
func (pool *TxPool) loop() {
defer pool.wg.Done()
var (
prevPending, prevQueued, prevStales int
// Start the stats reporting and transaction eviction tickers
report = time.NewTicker(statsReportInterval)
evict = time.NewTicker(evictionInterval)
journal = time.NewTicker(pool.config.Rejournal)
// Track the previous head headers for transaction reorgs
head = pool.chain.CurrentBlock()
)
defer report.Stop()
defer evict.Stop()
defer journal.Stop()
// Notify tests that the init phase is done
close(pool.initDoneCh)
for {
select {
// Handle ChainHeadEvent
case ev := <-pool.chainHeadCh:
if ev.Block != nil {
pool.requestReset(head.Header(), ev.Block.Header())
head = ev.Block
}
// System shutdown.
case <-pool.chainHeadSub.Err():
close(pool.reorgShutdownCh)
return
// Handle stats reporting ticks
case <-report.C:
pool.mu.RLock()
pending, queued := pool.stats()
pool.mu.RUnlock()
stales := int(atomic.LoadInt64(&pool.priced.stales))
if pending != prevPending || queued != prevQueued || stales != prevStales {
log.Debug("Transaction pool status report", "executable", pending, "queued", queued, "stales", stales)
prevPending, prevQueued, prevStales = pending, queued, stales
}
// Handle inactive account transaction eviction
case <-evict.C:
pool.mu.Lock()
for addr := range pool.queue {
// Skip local transactions from the eviction mechanism
if pool.locals.contains(addr) {
continue
}
// Any non-locals old enough should be removed
if time.Since(pool.beats[addr]) > pool.config.Lifetime {
list := pool.queue[addr].Flatten()
for _, tx := range list {
pool.removeTx(tx.Hash(), true)
}
queuedEvictionMeter.Mark(int64(len(list)))
}
}
pool.mu.Unlock()
// Handle local transaction journal rotation
case <-journal.C:
if pool.journal != nil {
pool.mu.Lock()
if err := pool.journal.rotate(pool.local()); err != nil {
log.Warn("Failed to rotate local tx journal", "err", err)
}
pool.mu.Unlock()
}
}
}
}
// Stop terminates the transaction pool.
func (pool *TxPool) Stop() {
// Unsubscribe all subscriptions registered from txpool
pool.scope.Close()
// Unsubscribe subscriptions registered from blockchain
pool.chainHeadSub.Unsubscribe()
pool.wg.Wait()
if pool.journal != nil {
pool.journal.close()
}
log.Info("Transaction pool stopped")
}
// SubscribeNewTxsEvent registers a subscription of NewTxsEvent and
// starts sending event to the given channel.
func (pool *TxPool) SubscribeNewTxsEvent(ch chan<- NewTxsEvent) event.Subscription {
return pool.scope.Track(pool.txFeed.Subscribe(ch))
}
// GasPrice returns the current gas price enforced by the transaction pool.
func (pool *TxPool) GasPrice() *big.Int {
pool.mu.RLock()
defer pool.mu.RUnlock()
return new(big.Int).Set(pool.gasPrice)
}
// SetGasPrice updates the minimum price required by the transaction pool for a
// new transaction, and drops all transactions below this threshold.
func (pool *TxPool) SetGasPrice(price *big.Int) {
pool.mu.Lock()
defer pool.mu.Unlock()
old := pool.gasPrice
pool.gasPrice = price
// if the min miner fee increased, remove transactions below the new threshold
if price.Cmp(old) > 0 {
// pool.priced is sorted by GasFeeCap, so we have to iterate through pool.all instead
drop := pool.all.RemotesBelowTip(price)
for _, tx := range drop {
pool.removeTx(tx.Hash(), false)
}
pool.priced.Removed(len(drop))
}
log.Info("Transaction pool price threshold updated", "price", price)
}
// Nonce returns the next nonce of an account, with all transactions executable
// by the pool already applied on top.
func (pool *TxPool) Nonce(addr common.Address) uint64 {
pool.mu.RLock()
defer pool.mu.RUnlock()
return pool.pendingNonces.get(addr)
}
// Stats retrieves the current pool stats, namely the number of pending and the
// number of queued (non-executable) transactions.
func (pool *TxPool) Stats() (int, int) {
pool.mu.RLock()
defer pool.mu.RUnlock()
return pool.stats()
}
// stats retrieves the current pool stats, namely the number of pending and the
// number of queued (non-executable) transactions.
func (pool *TxPool) stats() (int, int) {
pending := 0
for _, list := range pool.pending {
pending += list.Len()
}
queued := 0
for _, list := range pool.queue {
queued += list.Len()
}
return pending, queued
}
// Content retrieves the data content of the transaction pool, returning all the
// pending as well as queued transactions, grouped by account and sorted by nonce.
func (pool *TxPool) Content() (map[common.Address]types.Transactions, map[common.Address]types.Transactions) {
pool.mu.Lock()
defer pool.mu.Unlock()
pending := make(map[common.Address]types.Transactions)
for addr, list := range pool.pending {
pending[addr] = list.Flatten()
}
queued := make(map[common.Address]types.Transactions)
for addr, list := range pool.queue {
queued[addr] = list.Flatten()
}
return pending, queued
}
// ContentFrom retrieves the data content of the transaction pool, returning the
// pending as well as queued transactions of this address, grouped by nonce.
func (pool *TxPool) ContentFrom(addr common.Address) (types.Transactions, types.Transactions) {
pool.mu.RLock()
defer pool.mu.RUnlock()
var pending types.Transactions
if list, ok := pool.pending[addr]; ok {
pending = list.Flatten()
}
var queued types.Transactions
if list, ok := pool.queue[addr]; ok {
queued = list.Flatten()
}
return pending, queued
}
// Pending retrieves all currently processable transactions, grouped by origin
// account and sorted by nonce. The returned transaction set is a copy and can be
// freely modified by calling code.
//
// The enforceTips parameter can be used to do an extra filtering on the pending
// transactions and only return those whose **effective** tip is large enough in
// the next pending execution environment.
func (pool *TxPool) Pending(enforceTips bool) map[common.Address]types.Transactions {
pool.mu.Lock()
defer pool.mu.Unlock()
pending := make(map[common.Address]types.Transactions)
for addr, list := range pool.pending {
txs := list.Flatten()
// If the miner requests tip enforcement, cap the lists now
if enforceTips && !pool.locals.contains(addr) {
for i, tx := range txs {
if tx.EffectiveGasTipIntCmp(pool.gasPrice, pool.priced.urgent.baseFee) < 0 {
txs = txs[:i]
break
}
}
}
if len(txs) > 0 {
pending[addr] = txs
}
}
return pending
}
// Locals retrieves the accounts currently considered local by the pool.
func (pool *TxPool) Locals() []common.Address {
pool.mu.Lock()
defer pool.mu.Unlock()
return pool.locals.flatten()
}
// local retrieves all currently known local transactions, grouped by origin
// account and sorted by nonce. The returned transaction set is a copy and can be
// freely modified by calling code.
func (pool *TxPool) local() map[common.Address]types.Transactions {
txs := make(map[common.Address]types.Transactions)
for addr := range pool.locals.accounts {
if pending := pool.pending[addr]; pending != nil {
txs[addr] = append(txs[addr], pending.Flatten()...)
}
if queued := pool.queue[addr]; queued != nil {
txs[addr] = append(txs[addr], queued.Flatten()...)
}
}
return txs
}
// validateTx checks whether a transaction is valid according to the consensus
// rules and adheres to some heuristic limits of the local node (price and size).
func (pool *TxPool) validateTx(tx *types.Transaction, local bool) error {
// Accept only legacy transactions until EIP-2718/2930 activates.
if !pool.eip2718 && tx.Type() != types.LegacyTxType {
return ErrTxTypeNotSupported
}
// Reject dynamic fee transactions until EIP-1559 activates.
if !pool.eip1559 && tx.Type() == types.DynamicFeeTxType {
return ErrTxTypeNotSupported
}
// Reject transactions over defined size to prevent DOS attacks
if uint64(tx.Size()) > txMaxSize {
return ErrOversizedData
}
// Transactions can't be negative. This may never happen using RLP decoded
// transactions but may occur if you create a transaction using the RPC.
if tx.Value().Sign() < 0 {
return ErrNegativeValue
}
// Ensure the transaction doesn't exceed the current block limit gas.
if pool.currentMaxGas < tx.Gas() {
return ErrGasLimit
}
// Sanity check for extremely large numbers
if tx.GasFeeCap().BitLen() > 256 {
return ErrFeeCapVeryHigh
}
if tx.GasTipCap().BitLen() > 256 {
return ErrTipVeryHigh
}
// Ensure gasFeeCap is greater than or equal to gasTipCap.
if tx.GasFeeCapIntCmp(tx.GasTipCap()) < 0 {
return ErrTipAboveFeeCap
}
// Make sure the transaction is signed properly.
from, err := types.Sender(pool.signer, tx)
if err != nil {
return ErrInvalidSender
}
// Drop non-local transactions under our own minimal accepted gas price or tip.
pendingBaseFee := pool.priced.urgent.baseFee
if !local && tx.EffectiveGasTipIntCmp(pool.gasPrice, pendingBaseFee) < 0 {
return ErrUnderpriced
}
// Ensure the transaction adheres to nonce ordering
if pool.currentState.GetNonce(from) > tx.Nonce() {
return ErrNonceTooLow
}
// Transactor should have enough funds to cover the costs
// cost == V + GP * GL
if pool.currentState.GetBalance(from).Cmp(tx.Cost()) < 0 {
return ErrInsufficientFunds
}
// Ensure the transaction has more gas than the basic tx fee.
intrGas, err := IntrinsicGas(tx.Data(), tx.AccessList(), tx.To() == nil, true, pool.istanbul)
if err != nil {
return err
}
if tx.Gas() < intrGas {
return ErrIntrinsicGas
}
return nil
}
// add validates a transaction and inserts it into the non-executable queue for later
// pending promotion and execution. If the transaction is a replacement for an already
// pending or queued one, it overwrites the previous transaction if its price is higher.
//
// If a newly added transaction is marked as local, its sending account will be
// be added to the allowlist, preventing any associated transaction from being dropped
// out of the pool due to pricing constraints.
func (pool *TxPool) add(tx *types.Transaction, local bool) (replaced bool, err error) {
// If the transaction is already known, discard it
hash := tx.Hash()
if pool.all.Get(hash) != nil {
log.Trace("Discarding already known transaction", "hash", hash)
knownTxMeter.Mark(1)
return false, ErrAlreadyKnown
}
// Make the local flag. If it's from local source or it's from the network but
// the sender is marked as local previously, treat it as the local transaction.
isLocal := local || pool.locals.containsTx(tx)
// If the transaction fails basic validation, discard it
if err := pool.validateTx(tx, isLocal); err != nil {
log.Trace("Discarding invalid transaction", "hash", hash, "err", err)
invalidTxMeter.Mark(1)
return false, err
}
// If the transaction pool is full, discard underpriced transactions
if uint64(pool.all.Slots()+numSlots(tx)) > pool.config.GlobalSlots+pool.config.GlobalQueue {
// If the new transaction is underpriced, don't accept it
if !isLocal && pool.priced.Underpriced(tx) {
log.Trace("Discarding underpriced transaction", "hash", hash, "gasTipCap", tx.GasTipCap(), "gasFeeCap", tx.GasFeeCap())
underpricedTxMeter.Mark(1)
return false, ErrUnderpriced
}
// We're about to replace a transaction. The reorg does a more thorough
// analysis of what to remove and how, but it runs async. We don't want to
// do too many replacements between reorg-runs, so we cap the number of
// replacements to 25% of the slots
if pool.changesSinceReorg > int(pool.config.GlobalSlots/4) {
throttleTxMeter.Mark(1)
return false, ErrTxPoolOverflow
}
// New transaction is better than our worse ones, make room for it.
// If it's a local transaction, forcibly discard all available transactions.
// Otherwise if we can't make enough room for new one, abort the operation.
drop, success := pool.priced.Discard(pool.all.Slots()-int(pool.config.GlobalSlots+pool.config.GlobalQueue)+numSlots(tx), isLocal)
// Special case, we still can't make the room for the new remote one.
if !isLocal && !success {
log.Trace("Discarding overflown transaction", "hash", hash)
overflowedTxMeter.Mark(1)
return false, ErrTxPoolOverflow
}
// Bump the counter of rejections-since-reorg
pool.changesSinceReorg += len(drop)
// Kick out the underpriced remote transactions.
for _, tx := range drop {
log.Trace("Discarding freshly underpriced transaction", "hash", tx.Hash(), "gasTipCap", tx.GasTipCap(), "gasFeeCap", tx.GasFeeCap())
underpricedTxMeter.Mark(1)
pool.removeTx(tx.Hash(), false)
}
}
// Try to replace an existing transaction in the pending pool
from, _ := types.Sender(pool.signer, tx) // already validated
if list := pool.pending[from]; list != nil && list.Overlaps(tx) {
// Nonce already pending, check if required price bump is met
inserted, old := list.Add(tx, pool.config.PriceBump)
if !inserted {
pendingDiscardMeter.Mark(1)
return false, ErrReplaceUnderpriced
}
// New transaction is better, replace old one
if old != nil {
pool.all.Remove(old.Hash())
pool.priced.Removed(1)
pendingReplaceMeter.Mark(1)
}
pool.all.Add(tx, isLocal)
pool.priced.Put(tx, isLocal)
pool.journalTx(from, tx)
pool.queueTxEvent(tx)
log.Trace("Pooled new executable transaction", "hash", hash, "from", from, "to", tx.To())
// Successful promotion, bump the heartbeat
pool.beats[from] = time.Now()
return old != nil, nil
}
// New transaction isn't replacing a pending one, push into queue
replaced, err = pool.enqueueTx(hash, tx, isLocal, true)
if err != nil {
return false, err
}
// Mark local addresses and journal local transactions
if local && !pool.locals.contains(from) {
log.Info("Setting new local account", "address", from)
pool.locals.add(from)
pool.priced.Removed(pool.all.RemoteToLocals(pool.locals)) // Migrate the remotes if it's marked as local first time.
}
if isLocal {
localGauge.Inc(1)
}
pool.journalTx(from, tx)
log.Trace("Pooled new future transaction", "hash", hash, "from", from, "to", tx.To())
return replaced, nil
}
// enqueueTx inserts a new transaction into the non-executable transaction queue.
//
// Note, this method assumes the pool lock is held!
func (pool *TxPool) enqueueTx(hash common.Hash, tx *types.Transaction, local bool, addAll bool) (bool, error) {
// Try to insert the transaction into the future queue
from, _ := types.Sender(pool.signer, tx) // already validated
if pool.queue[from] == nil {
pool.queue[from] = newTxList(false)
}
inserted, old := pool.queue[from].Add(tx, pool.config.PriceBump)
if !inserted {
// An older transaction was better, discard this
queuedDiscardMeter.Mark(1)
return false, ErrReplaceUnderpriced
}
// Discard any previous transaction and mark this
if old != nil {
pool.all.Remove(old.Hash())
pool.priced.Removed(1)
queuedReplaceMeter.Mark(1)
} else {
// Nothing was replaced, bump the queued counter
queuedGauge.Inc(1)
}
// If the transaction isn't in lookup set but it's expected to be there,
// show the error log.
if pool.all.Get(hash) == nil && !addAll {
log.Error("Missing transaction in lookup set, please report the issue", "hash", hash)
}
if addAll {
pool.all.Add(tx, local)
pool.priced.Put(tx, local)
}
// If we never record the heartbeat, do it right now.
if _, exist := pool.beats[from]; !exist {
pool.beats[from] = time.Now()
}
return old != nil, nil
}
// journalTx adds the specified transaction to the local disk journal if it is
// deemed to have been sent from a local account.
func (pool *TxPool) journalTx(from common.Address, tx *types.Transaction) {
// Only journal if it's enabled and the transaction is local
if pool.journal == nil || !pool.locals.contains(from) {
return
}
if err := pool.journal.insert(tx); err != nil {
log.Warn("Failed to journal local transaction", "err", err)
}
}
// promoteTx adds a transaction to the pending (processable) list of transactions
// and returns whether it was inserted or an older was better.
//
// Note, this method assumes the pool lock is held!
func (pool *TxPool) promoteTx(addr common.Address, hash common.Hash, tx *types.Transaction) bool {
// Try to insert the transaction into the pending queue
if pool.pending[addr] == nil {
pool.pending[addr] = newTxList(true)
}
list := pool.pending[addr]
inserted, old := list.Add(tx, pool.config.PriceBump)
if !inserted {
// An older transaction was better, discard this
pool.all.Remove(hash)
pool.priced.Removed(1)
pendingDiscardMeter.Mark(1)
return false
}
// Otherwise discard any previous transaction and mark this
if old != nil {
pool.all.Remove(old.Hash())
pool.priced.Removed(1)
pendingReplaceMeter.Mark(1)
} else {
// Nothing was replaced, bump the pending counter
pendingGauge.Inc(1)
}
// Set the potentially new pending nonce and notify any subsystems of the new tx
pool.pendingNonces.set(addr, tx.Nonce()+1)
// Successful promotion, bump the heartbeat
pool.beats[addr] = time.Now()
return true
}
// AddLocals enqueues a batch of transactions into the pool if they are valid, marking the
// senders as a local ones, ensuring they go around the local pricing constraints.
//
// This method is used to add transactions from the RPC API and performs synchronous pool
// reorganization and event propagation.
func (pool *TxPool) AddLocals(txs []*types.Transaction) []error {
return pool.addTxs(txs, !pool.config.NoLocals, true)
}
// AddLocal enqueues a single local transaction into the pool if it is valid. This is
// a convenience wrapper aroundd AddLocals.
func (pool *TxPool) AddLocal(tx *types.Transaction) error {
errs := pool.AddLocals([]*types.Transaction{tx})
return errs[0]
}
// AddRemotes enqueues a batch of transactions into the pool if they are valid. If the
// senders are not among the locally tracked ones, full pricing constraints will apply.
//
// This method is used to add transactions from the p2p network and does not wait for pool
// reorganization and internal event propagation.
func (pool *TxPool) AddRemotes(txs []*types.Transaction) []error {
return pool.addTxs(txs, false, false)
}
// This is like AddRemotes, but waits for pool reorganization. Tests use this method.
func (pool *TxPool) AddRemotesSync(txs []*types.Transaction) []error {
return pool.addTxs(txs, false, true)
}
// This is like AddRemotes with a single transaction, but waits for pool reorganization. Tests use this method.
func (pool *TxPool) addRemoteSync(tx *types.Transaction) error {
errs := pool.AddRemotesSync([]*types.Transaction{tx})
return errs[0]
}
// AddRemote enqueues a single transaction into the pool if it is valid. This is a convenience
// wrapper around AddRemotes.
//
// Deprecated: use AddRemotes
func (pool *TxPool) AddRemote(tx *types.Transaction) error {
errs := pool.AddRemotes([]*types.Transaction{tx})
return errs[0]
}
// addTxs attempts to queue a batch of transactions if they are valid.
func (pool *TxPool) addTxs(txs []*types.Transaction, local, sync bool) []error {
// Filter out known ones without obtaining the pool lock or recovering signatures
var (
errs = make([]error, len(txs))
news = make([]*types.Transaction, 0, len(txs))
)
for i, tx := range txs {
// If the transaction is known, pre-set the error slot
if pool.all.Get(tx.Hash()) != nil {
errs[i] = ErrAlreadyKnown
knownTxMeter.Mark(1)
continue
}
// Exclude transactions with invalid signatures as soon as
// possible and cache senders in transactions before
// obtaining lock
_, err := types.Sender(pool.signer, tx)
if err != nil {
errs[i] = ErrInvalidSender
invalidTxMeter.Mark(1)
continue
}
// Accumulate all unknown transactions for deeper processing
news = append(news, tx)
}
if len(news) == 0 {
return errs
}
// Process all the new transaction and merge any errors into the original slice
pool.mu.Lock()
newErrs, dirtyAddrs := pool.addTxsLocked(news, local)
pool.mu.Unlock()
var nilSlot = 0
for _, err := range newErrs {
for errs[nilSlot] != nil {
nilSlot++
}
errs[nilSlot] = err
nilSlot++
}
// Reorg the pool internals if needed and return
done := pool.requestPromoteExecutables(dirtyAddrs)
if sync {
<-done
}
return errs
}
// addTxsLocked attempts to queue a batch of transactions if they are valid.
// The transaction pool lock must be held.
func (pool *TxPool) addTxsLocked(txs []*types.Transaction, local bool) ([]error, *accountSet) {
dirty := newAccountSet(pool.signer)
errs := make([]error, len(txs))
for i, tx := range txs {
replaced, err := pool.add(tx, local)
errs[i] = err
if err == nil && !replaced {
dirty.addTx(tx)
}
}
validTxMeter.Mark(int64(len(dirty.accounts)))
return errs, dirty
}
// Status returns the status (unknown/pending/queued) of a batch of transactions
// identified by their hashes.
func (pool *TxPool) Status(hashes []common.Hash) []TxStatus {
status := make([]TxStatus, len(hashes))
for i, hash := range hashes {
tx := pool.Get(hash)
if tx == nil {
continue
}
from, _ := types.Sender(pool.signer, tx) // already validated
pool.mu.RLock()
if txList := pool.pending[from]; txList != nil && txList.txs.items[tx.Nonce()] != nil {
status[i] = TxStatusPending
} else if txList := pool.queue[from]; txList != nil && txList.txs.items[tx.Nonce()] != nil {
status[i] = TxStatusQueued
}
// implicit else: the tx may have been included into a block between
// checking pool.Get and obtaining the lock. In that case, TxStatusUnknown is correct
pool.mu.RUnlock()
}
return status
}
// Get returns a transaction if it is contained in the pool and nil otherwise.
func (pool *TxPool) Get(hash common.Hash) *types.Transaction {
return pool.all.Get(hash)
}
// Has returns an indicator whether txpool has a transaction cached with the
// given hash.
func (pool *TxPool) Has(hash common.Hash) bool {
return pool.all.Get(hash) != nil
}
// removeTx removes a single transaction from the queue, moving all subsequent
// transactions back to the future queue.
func (pool *TxPool) removeTx(hash common.Hash, outofbound bool) {
// Fetch the transaction we wish to delete
tx := pool.all.Get(hash)
if tx == nil {
return
}
addr, _ := types.Sender(pool.signer, tx) // already validated during insertion
// Remove it from the list of known transactions
pool.all.Remove(hash)
if outofbound {
pool.priced.Removed(1)
}
if pool.locals.contains(addr) {
localGauge.Dec(1)
}
// Remove the transaction from the pending lists and reset the account nonce
if pending := pool.pending[addr]; pending != nil {
if removed, invalids := pending.Remove(tx); removed {
// If no more pending transactions are left, remove the list
if pending.Empty() {
delete(pool.pending, addr)
}
// Postpone any invalidated transactions
for _, tx := range invalids {
// Internal shuffle shouldn't touch the lookup set.
pool.enqueueTx(tx.Hash(), tx, false, false)
}
// Update the account nonce if needed
pool.pendingNonces.setIfLower(addr, tx.Nonce())
// Reduce the pending counter
pendingGauge.Dec(int64(1 + len(invalids)))
return
}
}
// Transaction is in the future queue
if future := pool.queue[addr]; future != nil {
if removed, _ := future.Remove(tx); removed {
// Reduce the queued counter
queuedGauge.Dec(1)
}
if future.Empty() {
delete(pool.queue, addr)
delete(pool.beats, addr)
}
}
}
// requestReset requests a pool reset to the new head block.
// The returned channel is closed when the reset has occurred.
func (pool *TxPool) requestReset(oldHead *types.Header, newHead *types.Header) chan struct{} {
select {
case pool.reqResetCh <- &txpoolResetRequest{oldHead, newHead}:
return <-pool.reorgDoneCh
case <-pool.reorgShutdownCh:
return pool.reorgShutdownCh
}
}
// requestPromoteExecutables requests transaction promotion checks for the given addresses.
// The returned channel is closed when the promotion checks have occurred.
func (pool *TxPool) requestPromoteExecutables(set *accountSet) chan struct{} {
select {
case pool.reqPromoteCh <- set:
return <-pool.reorgDoneCh
case <-pool.reorgShutdownCh:
return pool.reorgShutdownCh
}
}
// queueTxEvent enqueues a transaction event to be sent in the next reorg run.
func (pool *TxPool) queueTxEvent(tx *types.Transaction) {
select {
case pool.queueTxEventCh <- tx:
case <-pool.reorgShutdownCh:
}
}
// scheduleReorgLoop schedules runs of reset and promoteExecutables. Code above should not
// call those methods directly, but request them being run using requestReset and
// requestPromoteExecutables instead.
func (pool *TxPool) scheduleReorgLoop() {
defer pool.wg.Done()
var (
curDone chan struct{} // non-nil while runReorg is active
nextDone = make(chan struct{})
launchNextRun bool
reset *txpoolResetRequest
dirtyAccounts *accountSet
queuedEvents = make(map[common.Address]*txSortedMap)
)
for {
// Launch next background reorg if needed
if curDone == nil && launchNextRun {
// Run the background reorg and announcements
go pool.runReorg(nextDone, reset, dirtyAccounts, queuedEvents)
// Prepare everything for the next round of reorg
curDone, nextDone = nextDone, make(chan struct{})
launchNextRun = false
reset, dirtyAccounts = nil, nil
queuedEvents = make(map[common.Address]*txSortedMap)
}
select {
case req := <-pool.reqResetCh:
// Reset request: update head if request is already pending.
if reset == nil {
reset = req
} else {
reset.newHead = req.newHead
}
launchNextRun = true
pool.reorgDoneCh <- nextDone
case req := <-pool.reqPromoteCh:
// Promote request: update address set if request is already pending.
if dirtyAccounts == nil {
dirtyAccounts = req
} else {
dirtyAccounts.merge(req)
}
launchNextRun = true
pool.reorgDoneCh <- nextDone
case tx := <-pool.queueTxEventCh:
// Queue up the event, but don't schedule a reorg. It's up to the caller to
// request one later if they want the events sent.
addr, _ := types.Sender(pool.signer, tx)
if _, ok := queuedEvents[addr]; !ok {
queuedEvents[addr] = newTxSortedMap()
}
queuedEvents[addr].Put(tx)
case <-curDone:
curDone = nil
case <-pool.reorgShutdownCh:
// Wait for current run to finish.
if curDone != nil {
<-curDone
}
close(nextDone)
return
}
}
}
// runReorg runs reset and promoteExecutables on behalf of scheduleReorgLoop.
func (pool *TxPool) runReorg(done chan struct{}, reset *txpoolResetRequest, dirtyAccounts *accountSet, events map[common.Address]*txSortedMap) {
defer func(t0 time.Time) {
reorgDurationTimer.Update(time.Since(t0))
}(time.Now())
defer close(done)
var promoteAddrs []common.Address
if dirtyAccounts != nil && reset == nil {
// Only dirty accounts need to be promoted, unless we're resetting.
// For resets, all addresses in the tx queue will be promoted and
// the flatten operation can be avoided.
promoteAddrs = dirtyAccounts.flatten()
}
pool.mu.Lock()
if reset != nil {
// Reset from the old head to the new, rescheduling any reorged transactions
pool.reset(reset.oldHead, reset.newHead)
// Nonces were reset, discard any events that became stale
for addr := range events {
events[addr].Forward(pool.pendingNonces.get(addr))
if events[addr].Len() == 0 {
delete(events, addr)
}
}
// Reset needs promote for all addresses
promoteAddrs = make([]common.Address, 0, len(pool.queue))
for addr := range pool.queue {
promoteAddrs = append(promoteAddrs, addr)
}
}
// Check for pending transactions for every account that sent new ones
promoted := pool.promoteExecutables(promoteAddrs)
// If a new block appeared, validate the pool of pending transactions. This will
// remove any transaction that has been included in the block or was invalidated
// because of another transaction (e.g. higher gas price).
if reset != nil {
pool.demoteUnexecutables()
if reset.newHead != nil && pool.chainconfig.IsLondon(new(big.Int).Add(reset.newHead.Number, big.NewInt(1))) {
pendingBaseFee := misc.CalcBaseFee(pool.chainconfig, reset.newHead)
pool.priced.SetBaseFee(pendingBaseFee)
}
// Update all accounts to the latest known pending nonce
nonces := make(map[common.Address]uint64, len(pool.pending))
for addr, list := range pool.pending {
highestPending := list.LastElement()
nonces[addr] = highestPending.Nonce() + 1
}
pool.pendingNonces.setAll(nonces)
}
// Ensure pool.queue and pool.pending sizes stay within the configured limits.
pool.truncatePending()
pool.truncateQueue()
dropBetweenReorgHistogram.Update(int64(pool.changesSinceReorg))
pool.changesSinceReorg = 0 // Reset change counter
pool.mu.Unlock()
// Notify subsystems for newly added transactions
for _, tx := range promoted {
addr, _ := types.Sender(pool.signer, tx)
if _, ok := events[addr]; !ok {
events[addr] = newTxSortedMap()
}
events[addr].Put(tx)
}
if len(events) > 0 {
var txs []*types.Transaction
for _, set := range events {
txs = append(txs, set.Flatten()...)
}
pool.txFeed.Send(NewTxsEvent{txs})
}
}
// reset retrieves the current state of the blockchain and ensures the content
// of the transaction pool is valid with regard to the chain state.
func (pool *TxPool) reset(oldHead, newHead *types.Header) {
// If we're reorging an old state, reinject all dropped transactions
var reinject types.Transactions
if oldHead != nil && oldHead.Hash() != newHead.ParentHash {
// If the reorg is too deep, avoid doing it (will happen during fast sync)
oldNum := oldHead.Number.Uint64()
newNum := newHead.Number.Uint64()
if depth := uint64(math.Abs(float64(oldNum) - float64(newNum))); depth > 64 {
log.Debug("Skipping deep transaction reorg", "depth", depth)
} else {
// Reorg seems shallow enough to pull in all transactions into memory
var discarded, included types.Transactions
var (
rem = pool.chain.GetBlock(oldHead.Hash(), oldHead.Number.Uint64())
add = pool.chain.GetBlock(newHead.Hash(), newHead.Number.Uint64())
)
if rem == nil {
// This can happen if a setHead is performed, where we simply discard the old
// head from the chain.
// If that is the case, we don't have the lost transactions any more, and
// there's nothing to add
if newNum >= oldNum {
// If we reorged to a same or higher number, then it's not a case of setHead
log.Warn("Transaction pool reset with missing oldhead",
"old", oldHead.Hash(), "oldnum", oldNum, "new", newHead.Hash(), "newnum", newNum)
return
}
// If the reorg ended up on a lower number, it's indicative of setHead being the cause
log.Debug("Skipping transaction reset caused by setHead",
"old", oldHead.Hash(), "oldnum", oldNum, "new", newHead.Hash(), "newnum", newNum)
// We still need to update the current state s.th. the lost transactions can be readded by the user
} else {
for rem.NumberU64() > add.NumberU64() {
discarded = append(discarded, rem.Transactions()...)
if rem = pool.chain.GetBlock(rem.ParentHash(), rem.NumberU64()-1); rem == nil {
log.Error("Unrooted old chain seen by tx pool", "block", oldHead.Number, "hash", oldHead.Hash())
return
}
}
for add.NumberU64() > rem.NumberU64() {
included = append(included, add.Transactions()...)
if add = pool.chain.GetBlock(add.ParentHash(), add.NumberU64()-1); add == nil {
log.Error("Unrooted new chain seen by tx pool", "block", newHead.Number, "hash", newHead.Hash())
return
}
}
for rem.Hash() != add.Hash() {
discarded = append(discarded, rem.Transactions()...)
if rem = pool.chain.GetBlock(rem.ParentHash(), rem.NumberU64()-1); rem == nil {
log.Error("Unrooted old chain seen by tx pool", "block", oldHead.Number, "hash", oldHead.Hash())
return
}
included = append(included, add.Transactions()...)
if add = pool.chain.GetBlock(add.ParentHash(), add.NumberU64()-1); add == nil {
log.Error("Unrooted new chain seen by tx pool", "block", newHead.Number, "hash", newHead.Hash())
return
}
}
reinject = types.TxDifference(discarded, included)
}
}
}
// Initialize the internal state to the current head
if newHead == nil {
newHead = pool.chain.CurrentBlock().Header() // Special case during testing
}
statedb, err := pool.chain.StateAt(newHead.Root)
if err != nil {
log.Error("Failed to reset txpool state", "err", err)
return
}
pool.currentState = statedb
pool.pendingNonces = newTxNoncer(statedb)
pool.currentMaxGas = newHead.GasLimit
// Inject any transactions discarded due to reorgs
log.Debug("Reinjecting stale transactions", "count", len(reinject))
senderCacher.recover(pool.signer, reinject)
pool.addTxsLocked(reinject, false)
// Update all fork indicator by next pending block number.
next := new(big.Int).Add(newHead.Number, big.NewInt(1))
pool.istanbul = pool.chainconfig.IsIstanbul(next)
pool.eip2718 = pool.chainconfig.IsBerlin(next)
pool.eip1559 = pool.chainconfig.IsLondon(next)
}
// promoteExecutables moves transactions that have become processable from the
// future queue to the set of pending transactions. During this process, all
// invalidated transactions (low nonce, low balance) are deleted.
func (pool *TxPool) promoteExecutables(accounts []common.Address) []*types.Transaction {
// Track the promoted transactions to broadcast them at once
var promoted []*types.Transaction
// Iterate over all accounts and promote any executable transactions
for _, addr := range accounts {
list := pool.queue[addr]
if list == nil {
continue // Just in case someone calls with a non existing account
}
// Drop all transactions that are deemed too old (low nonce)
forwards := list.Forward(pool.currentState.GetNonce(addr))
for _, tx := range forwards {
hash := tx.Hash()
pool.all.Remove(hash)
}
log.Trace("Removed old queued transactions", "count", len(forwards))
// Drop all transactions that are too costly (low balance or out of gas)
drops, _ := list.Filter(pool.currentState.GetBalance(addr), pool.currentMaxGas)
for _, tx := range drops {
hash := tx.Hash()
pool.all.Remove(hash)
}
log.Trace("Removed unpayable queued transactions", "count", len(drops))
queuedNofundsMeter.Mark(int64(len(drops)))
// Gather all executable transactions and promote them
readies := list.Ready(pool.pendingNonces.get(addr))
for _, tx := range readies {
hash := tx.Hash()
if pool.promoteTx(addr, hash, tx) {
promoted = append(promoted, tx)
}
}
log.Trace("Promoted queued transactions", "count", len(promoted))
queuedGauge.Dec(int64(len(readies)))
// Drop all transactions over the allowed limit
var caps types.Transactions
if !pool.locals.contains(addr) {
caps = list.Cap(int(pool.config.AccountQueue))
for _, tx := range caps {
hash := tx.Hash()
pool.all.Remove(hash)
log.Trace("Removed cap-exceeding queued transaction", "hash", hash)
}
queuedRateLimitMeter.Mark(int64(len(caps)))
}
// Mark all the items dropped as removed
pool.priced.Removed(len(forwards) + len(drops) + len(caps))
queuedGauge.Dec(int64(len(forwards) + len(drops) + len(caps)))
if pool.locals.contains(addr) {
localGauge.Dec(int64(len(forwards) + len(drops) + len(caps)))
}
// Delete the entire queue entry if it became empty.
if list.Empty() {
delete(pool.queue, addr)
delete(pool.beats, addr)
}
}
return promoted
}
// truncatePending removes transactions from the pending queue if the pool is above the
// pending limit. The algorithm tries to reduce transaction counts by an approximately
// equal number for all for accounts with many pending transactions.
func (pool *TxPool) truncatePending() {
pending := uint64(0)
for _, list := range pool.pending {
pending += uint64(list.Len())
}
if pending <= pool.config.GlobalSlots {
return
}
pendingBeforeCap := pending
// Assemble a spam order to penalize large transactors first
spammers := prque.New(nil)
for addr, list := range pool.pending {
// Only evict transactions from high rollers
if !pool.locals.contains(addr) && uint64(list.Len()) > pool.config.AccountSlots {
spammers.Push(addr, int64(list.Len()))
}
}
// Gradually drop transactions from offenders
offenders := []common.Address{}
for pending > pool.config.GlobalSlots && !spammers.Empty() {
// Retrieve the next offender if not local address
offender, _ := spammers.Pop()
offenders = append(offenders, offender.(common.Address))
// Equalize balances until all the same or below threshold
if len(offenders) > 1 {
// Calculate the equalization threshold for all current offenders
threshold := pool.pending[offender.(common.Address)].Len()
// Iteratively reduce all offenders until below limit or threshold reached
for pending > pool.config.GlobalSlots && pool.pending[offenders[len(offenders)-2]].Len() > threshold {
for i := 0; i < len(offenders)-1; i++ {
list := pool.pending[offenders[i]]
caps := list.Cap(list.Len() - 1)
for _, tx := range caps {
// Drop the transaction from the global pools too
hash := tx.Hash()
pool.all.Remove(hash)
// Update the account nonce to the dropped transaction
pool.pendingNonces.setIfLower(offenders[i], tx.Nonce())
log.Trace("Removed fairness-exceeding pending transaction", "hash", hash)
}
pool.priced.Removed(len(caps))
pendingGauge.Dec(int64(len(caps)))
if pool.locals.contains(offenders[i]) {
localGauge.Dec(int64(len(caps)))
}
pending--
}
}
}
}
// If still above threshold, reduce to limit or min allowance
if pending > pool.config.GlobalSlots && len(offenders) > 0 {
for pending > pool.config.GlobalSlots && uint64(pool.pending[offenders[len(offenders)-1]].Len()) > pool.config.AccountSlots {
for _, addr := range offenders {
list := pool.pending[addr]
caps := list.Cap(list.Len() - 1)
for _, tx := range caps {
// Drop the transaction from the global pools too
hash := tx.Hash()
pool.all.Remove(hash)
// Update the account nonce to the dropped transaction
pool.pendingNonces.setIfLower(addr, tx.Nonce())
log.Trace("Removed fairness-exceeding pending transaction", "hash", hash)
}
pool.priced.Removed(len(caps))
pendingGauge.Dec(int64(len(caps)))
if pool.locals.contains(addr) {
localGauge.Dec(int64(len(caps)))
}
pending--
}
}
}
pendingRateLimitMeter.Mark(int64(pendingBeforeCap - pending))
}
// truncateQueue drops the oldes transactions in the queue if the pool is above the global queue limit.
func (pool *TxPool) truncateQueue() {
queued := uint64(0)
for _, list := range pool.queue {
queued += uint64(list.Len())
}
if queued <= pool.config.GlobalQueue {
return
}
// Sort all accounts with queued transactions by heartbeat
addresses := make(addressesByHeartbeat, 0, len(pool.queue))
for addr := range pool.queue {
if !pool.locals.contains(addr) { // don't drop locals
addresses = append(addresses, addressByHeartbeat{addr, pool.beats[addr]})
}
}
sort.Sort(addresses)
// Drop transactions until the total is below the limit or only locals remain
for drop := queued - pool.config.GlobalQueue; drop > 0 && len(addresses) > 0; {
addr := addresses[len(addresses)-1]
list := pool.queue[addr.address]
addresses = addresses[:len(addresses)-1]
// Drop all transactions if they are less than the overflow
if size := uint64(list.Len()); size <= drop {
for _, tx := range list.Flatten() {
pool.removeTx(tx.Hash(), true)
}
drop -= size
queuedRateLimitMeter.Mark(int64(size))
continue
}
// Otherwise drop only last few transactions
txs := list.Flatten()
for i := len(txs) - 1; i >= 0 && drop > 0; i-- {
pool.removeTx(txs[i].Hash(), true)
drop--
queuedRateLimitMeter.Mark(1)
}
}
}
// demoteUnexecutables removes invalid and processed transactions from the pools
// executable/pending queue and any subsequent transactions that become unexecutable
// are moved back into the future queue.
//
// Note: transactions are not marked as removed in the priced list because re-heaping
// is always explicitly triggered by SetBaseFee and it would be unnecessary and wasteful
// to trigger a re-heap is this function
func (pool *TxPool) demoteUnexecutables() {
// Iterate over all accounts and demote any non-executable transactions
for addr, list := range pool.pending {
nonce := pool.currentState.GetNonce(addr)
// Drop all transactions that are deemed too old (low nonce)
olds := list.Forward(nonce)
for _, tx := range olds {
hash := tx.Hash()
pool.all.Remove(hash)
log.Trace("Removed old pending transaction", "hash", hash)
}
// Drop all transactions that are too costly (low balance or out of gas), and queue any invalids back for later
drops, invalids := list.Filter(pool.currentState.GetBalance(addr), pool.currentMaxGas)
for _, tx := range drops {
hash := tx.Hash()
log.Trace("Removed unpayable pending transaction", "hash", hash)
pool.all.Remove(hash)
}
pendingNofundsMeter.Mark(int64(len(drops)))
for _, tx := range invalids {
hash := tx.Hash()
log.Trace("Demoting pending transaction", "hash", hash)
// Internal shuffle shouldn't touch the lookup set.
pool.enqueueTx(hash, tx, false, false)
}
pendingGauge.Dec(int64(len(olds) + len(drops) + len(invalids)))
if pool.locals.contains(addr) {
localGauge.Dec(int64(len(olds) + len(drops) + len(invalids)))
}
// If there's a gap in front, alert (should never happen) and postpone all transactions
if list.Len() > 0 && list.txs.Get(nonce) == nil {
gapped := list.Cap(0)
for _, tx := range gapped {
hash := tx.Hash()
log.Error("Demoting invalidated transaction", "hash", hash)
// Internal shuffle shouldn't touch the lookup set.
pool.enqueueTx(hash, tx, false, false)
}
pendingGauge.Dec(int64(len(gapped)))
// This might happen in a reorg, so log it to the metering
blockReorgInvalidatedTx.Mark(int64(len(gapped)))
}
// Delete the entire pending entry if it became empty.
if list.Empty() {
delete(pool.pending, addr)
}
}
}
// addressByHeartbeat is an account address tagged with its last activity timestamp.
type addressByHeartbeat struct {
address common.Address
heartbeat time.Time
}
type addressesByHeartbeat []addressByHeartbeat
func (a addressesByHeartbeat) Len() int { return len(a) }
func (a addressesByHeartbeat) Less(i, j int) bool { return a[i].heartbeat.Before(a[j].heartbeat) }
func (a addressesByHeartbeat) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
// accountSet is simply a set of addresses to check for existence, and a signer
// capable of deriving addresses from transactions.
type accountSet struct {
accounts map[common.Address]struct{}
signer types.Signer
cache *[]common.Address
}
// newAccountSet creates a new address set with an associated signer for sender
// derivations.
func newAccountSet(signer types.Signer, addrs ...common.Address) *accountSet {
as := &accountSet{
accounts: make(map[common.Address]struct{}),
signer: signer,
}
for _, addr := range addrs {
as.add(addr)
}
return as
}
// contains checks if a given address is contained within the set.
func (as *accountSet) contains(addr common.Address) bool {
_, exist := as.accounts[addr]
return exist
}
func (as *accountSet) empty() bool {
return len(as.accounts) == 0
}
// containsTx checks if the sender of a given tx is within the set. If the sender
// cannot be derived, this method returns false.
func (as *accountSet) containsTx(tx *types.Transaction) bool {
if addr, err := types.Sender(as.signer, tx); err == nil {
return as.contains(addr)
}
return false
}
// add inserts a new address into the set to track.
func (as *accountSet) add(addr common.Address) {
as.accounts[addr] = struct{}{}
as.cache = nil
}
// addTx adds the sender of tx into the set.
func (as *accountSet) addTx(tx *types.Transaction) {
if addr, err := types.Sender(as.signer, tx); err == nil {
as.add(addr)
}
}
// flatten returns the list of addresses within this set, also caching it for later
// reuse. The returned slice should not be changed!
func (as *accountSet) flatten() []common.Address {
if as.cache == nil {
accounts := make([]common.Address, 0, len(as.accounts))
for account := range as.accounts {
accounts = append(accounts, account)
}
as.cache = &accounts
}
return *as.cache
}
// merge adds all addresses from the 'other' set into 'as'.
func (as *accountSet) merge(other *accountSet) {
for addr := range other.accounts {
as.accounts[addr] = struct{}{}
}
as.cache = nil
}
// txLookup is used internally by TxPool to track transactions while allowing
// lookup without mutex contention.
//
// Note, although this type is properly protected against concurrent access, it
// is **not** a type that should ever be mutated or even exposed outside of the
// transaction pool, since its internal state is tightly coupled with the pools
// internal mechanisms. The sole purpose of the type is to permit out-of-bound
// peeking into the pool in TxPool.Get without having to acquire the widely scoped
// TxPool.mu mutex.
//
// This lookup set combines the notion of "local transactions", which is useful
// to build upper-level structure.
type txLookup struct {
slots int
lock sync.RWMutex
locals map[common.Hash]*types.Transaction
remotes map[common.Hash]*types.Transaction
}
// newTxLookup returns a new txLookup structure.
func newTxLookup() *txLookup {
return &txLookup{
locals: make(map[common.Hash]*types.Transaction),
remotes: make(map[common.Hash]*types.Transaction),
}
}
// Range calls f on each key and value present in the map. The callback passed
// should return the indicator whether the iteration needs to be continued.
// Callers need to specify which set (or both) to be iterated.
func (t *txLookup) Range(f func(hash common.Hash, tx *types.Transaction, local bool) bool, local bool, remote bool) {
t.lock.RLock()
defer t.lock.RUnlock()
if local {
for key, value := range t.locals {
if !f(key, value, true) {
return
}
}
}
if remote {
for key, value := range t.remotes {
if !f(key, value, false) {
return
}
}
}
}
// Get returns a transaction if it exists in the lookup, or nil if not found.
func (t *txLookup) Get(hash common.Hash) *types.Transaction {
t.lock.RLock()
defer t.lock.RUnlock()
if tx := t.locals[hash]; tx != nil {
return tx
}
return t.remotes[hash]
}
// GetLocal returns a transaction if it exists in the lookup, or nil if not found.
func (t *txLookup) GetLocal(hash common.Hash) *types.Transaction {
t.lock.RLock()
defer t.lock.RUnlock()
return t.locals[hash]
}
// GetRemote returns a transaction if it exists in the lookup, or nil if not found.
func (t *txLookup) GetRemote(hash common.Hash) *types.Transaction {
t.lock.RLock()
defer t.lock.RUnlock()
return t.remotes[hash]
}
// Count returns the current number of transactions in the lookup.
func (t *txLookup) Count() int {
t.lock.RLock()
defer t.lock.RUnlock()
return len(t.locals) + len(t.remotes)
}
// LocalCount returns the current number of local transactions in the lookup.
func (t *txLookup) LocalCount() int {
t.lock.RLock()
defer t.lock.RUnlock()
return len(t.locals)
}
// RemoteCount returns the current number of remote transactions in the lookup.
func (t *txLookup) RemoteCount() int {
t.lock.RLock()
defer t.lock.RUnlock()
return len(t.remotes)
}
// Slots returns the current number of slots used in the lookup.
func (t *txLookup) Slots() int {
t.lock.RLock()
defer t.lock.RUnlock()
return t.slots
}
// Add adds a transaction to the lookup.
func (t *txLookup) Add(tx *types.Transaction, local bool) {
t.lock.Lock()
defer t.lock.Unlock()
t.slots += numSlots(tx)
slotsGauge.Update(int64(t.slots))
if local {
t.locals[tx.Hash()] = tx
} else {
t.remotes[tx.Hash()] = tx
}
}
// Remove removes a transaction from the lookup.
func (t *txLookup) Remove(hash common.Hash) {
t.lock.Lock()
defer t.lock.Unlock()
tx, ok := t.locals[hash]
if !ok {
tx, ok = t.remotes[hash]
}
if !ok {
log.Error("No transaction found to be deleted", "hash", hash)
return
}
t.slots -= numSlots(tx)
slotsGauge.Update(int64(t.slots))
delete(t.locals, hash)
delete(t.remotes, hash)
}
// RemoteToLocals migrates the transactions belongs to the given locals to locals
// set. The assumption is held the locals set is thread-safe to be used.
func (t *txLookup) RemoteToLocals(locals *accountSet) int {
t.lock.Lock()
defer t.lock.Unlock()
var migrated int
for hash, tx := range t.remotes {
if locals.containsTx(tx) {
t.locals[hash] = tx
delete(t.remotes, hash)
migrated += 1
}
}
return migrated
}
// RemotesBelowTip finds all remote transactions below the given tip threshold.
func (t *txLookup) RemotesBelowTip(threshold *big.Int) types.Transactions {
found := make(types.Transactions, 0, 128)
t.Range(func(hash common.Hash, tx *types.Transaction, local bool) bool {
if tx.GasTipCapIntCmp(threshold) < 0 {
found = append(found, tx)
}
return true
}, false, true) // Only iterate remotes
return found
}
// numSlots calculates the number of slots needed for a single transaction.
func numSlots(tx *types.Transaction) int {
return int((tx.Size() + txSlotSize - 1) / txSlotSize)
}