neo-go/pkg/core/mempool/mem_pool.go
Roman Khimov 06f3c34981 mempool: replace timeStamp with blockStamp
Time is not really relevant for us here and we don't use this timestamp in any
way. Yet it occupies 24 bytes and we do two clock_gettime calls to get it.

Replace it with blockStamp which is going to be used in the future for
transaction retransmissions.

It allows to improve single-node TPS by another 3%.
2020-11-11 15:48:13 +03:00

374 lines
10 KiB
Go

package mempool
import (
"errors"
"sort"
"sync"
"github.com/nspcc-dev/neo-go/pkg/core/transaction"
"github.com/nspcc-dev/neo-go/pkg/util"
)
var (
// ErrConflict is returned when transaction being added is incompatible
// with the contents of the memory pool (using the same inputs as some
// other transaction in the pool)
ErrConflict = errors.New("conflicts with the memory pool")
// ErrDup is returned when transaction being added is already present
// in the memory pool.
ErrDup = errors.New("already in the memory pool")
// ErrOOM is returned when transaction just doesn't fit in the memory
// pool because of its capacity constraints.
ErrOOM = errors.New("out of memory")
)
// item represents a transaction in the the Memory pool.
type item struct {
txn *transaction.Transaction
blockStamp uint32
perByteFee util.Fixed8
netFee util.Fixed8
isLowPrio bool
}
// items is a slice of item.
type items []*item
// TxWithFee combines transaction and its precalculated network fee.
type TxWithFee struct {
Tx *transaction.Transaction
Fee util.Fixed8
}
// Pool stores the unconfirms transactions.
type Pool struct {
lock sync.RWMutex
verifiedMap map[util.Uint256]*item
verifiedTxes items
inputs []*transaction.Input
claims []*transaction.Input
capacity int
}
func (p items) Len() int { return len(p) }
func (p items) Swap(i, j int) { p[i], p[j] = p[j], p[i] }
func (p items) Less(i, j int) bool { return p[i].CompareTo(p[j]) < 0 }
// CompareTo returns the difference between two items.
// difference < 0 implies p < otherP.
// difference = 0 implies p = otherP.
// difference > 0 implies p > otherP.
func (p *item) CompareTo(otherP *item) int {
if otherP == nil {
return 1
}
if !p.isLowPrio && otherP.isLowPrio {
return 1
}
if p.isLowPrio && !otherP.isLowPrio {
return -1
}
if p.isLowPrio && otherP.isLowPrio {
thisIsClaimTx := p.txn.Type == transaction.ClaimType
otherIsClaimTx := otherP.txn.Type == transaction.ClaimType
if thisIsClaimTx != otherIsClaimTx {
// This is a claim Tx and other isn't.
if thisIsClaimTx {
return 1
}
// The other is claim Tx and this isn't.
return -1
}
}
// Fees sorted ascending.
if ret := p.perByteFee.CompareTo(otherP.perByteFee); ret != 0 {
return ret
}
if ret := p.netFee.CompareTo(otherP.netFee); ret != 0 {
return ret
}
// Transaction hash sorted descending.
return otherP.txn.Hash().CompareTo(p.txn.Hash())
}
// Count returns the total number of uncofirm transactions.
func (mp *Pool) Count() int {
mp.lock.RLock()
defer mp.lock.RUnlock()
return mp.count()
}
// count is an internal unlocked version of Count.
func (mp *Pool) count() int {
return len(mp.verifiedTxes)
}
// ContainsKey checks if a transactions hash is in the Pool.
func (mp *Pool) ContainsKey(hash util.Uint256) bool {
mp.lock.RLock()
defer mp.lock.RUnlock()
return mp.containsKey(hash)
}
// containsKey is an internal unlocked version of ContainsKey.
func (mp *Pool) containsKey(hash util.Uint256) bool {
if _, ok := mp.verifiedMap[hash]; ok {
return true
}
return false
}
// findIndexForInput finds an index in a sorted Input pointers slice that is
// appropriate to place this input into (or which contains an identical Input).
func findIndexForInput(slice []*transaction.Input, input *transaction.Input) int {
return sort.Search(len(slice), func(n int) bool {
return input.Cmp(slice[n]) <= 0
})
}
// pushInputToSortedSlice pushes new Input into the given slice.
func pushInputToSortedSlice(slice *[]*transaction.Input, input *transaction.Input) {
n := findIndexForInput(*slice, input)
*slice = append(*slice, input)
if n != len(*slice)-1 {
copy((*slice)[n+1:], (*slice)[n:])
(*slice)[n] = input
}
}
// dropInputFromSortedSlice removes given input from the given slice.
func dropInputFromSortedSlice(slice *[]*transaction.Input, input *transaction.Input) {
n := findIndexForInput(*slice, input)
if n == len(*slice) || *input != *(*slice)[n] {
// Not present.
return
}
copy((*slice)[n:], (*slice)[n+1:])
*slice = (*slice)[:len(*slice)-1]
}
// Add tries to add given transaction to the Pool.
func (mp *Pool) Add(t *transaction.Transaction, fee Feer) error {
var pItem = &item{
txn: t,
blockStamp: fee.BlockHeight(),
perByteFee: fee.FeePerByte(t),
netFee: fee.NetworkFee(t),
}
pItem.isLowPrio = fee.IsLowPriority(pItem.netFee)
mp.lock.Lock()
if !mp.checkTxConflicts(t) {
mp.lock.Unlock()
return ErrConflict
}
if mp.containsKey(t.Hash()) {
mp.lock.Unlock()
return ErrDup
}
mp.verifiedMap[t.Hash()] = pItem
// Insert into sorted array (from max to min, that could also be done
// using sort.Sort(sort.Reverse()), but it incurs more overhead. Notice
// also that we're searching for position that is strictly more
// prioritized than our new item because we do expect a lot of
// transactions with the same priority and appending to the end of the
// slice is always more efficient.
n := sort.Search(len(mp.verifiedTxes), func(n int) bool {
return pItem.CompareTo(mp.verifiedTxes[n]) > 0
})
// We've reached our capacity already.
if len(mp.verifiedTxes) == mp.capacity {
// Less prioritized than the least prioritized we already have, won't fit.
if n == len(mp.verifiedTxes) {
mp.lock.Unlock()
return ErrOOM
}
// Ditch the last one.
unlucky := mp.verifiedTxes[len(mp.verifiedTxes)-1]
delete(mp.verifiedMap, unlucky.txn.Hash())
mp.verifiedTxes[len(mp.verifiedTxes)-1] = pItem
} else {
mp.verifiedTxes = append(mp.verifiedTxes, pItem)
}
if n != len(mp.verifiedTxes)-1 {
copy(mp.verifiedTxes[n+1:], mp.verifiedTxes[n:])
mp.verifiedTxes[n] = pItem
}
// For lots of inputs it might be easier to push them all and sort
// afterwards, but that requires benchmarking.
for i := range t.Inputs {
pushInputToSortedSlice(&mp.inputs, &t.Inputs[i])
}
if t.Type == transaction.ClaimType {
claim := t.Data.(*transaction.ClaimTX)
for i := range claim.Claims {
pushInputToSortedSlice(&mp.claims, &claim.Claims[i])
}
}
updateMempoolMetrics(len(mp.verifiedTxes))
mp.lock.Unlock()
return nil
}
// Remove removes an item from the mempool, if it exists there (and does
// nothing if it doesn't).
func (mp *Pool) Remove(hash util.Uint256) {
mp.lock.Lock()
if it, ok := mp.verifiedMap[hash]; ok {
var num int
delete(mp.verifiedMap, hash)
for num = range mp.verifiedTxes {
if hash.Equals(mp.verifiedTxes[num].txn.Hash()) {
break
}
}
if num < len(mp.verifiedTxes)-1 {
mp.verifiedTxes = append(mp.verifiedTxes[:num], mp.verifiedTxes[num+1:]...)
} else if num == len(mp.verifiedTxes)-1 {
mp.verifiedTxes = mp.verifiedTxes[:num]
}
for i := range it.txn.Inputs {
dropInputFromSortedSlice(&mp.inputs, &it.txn.Inputs[i])
}
if it.txn.Type == transaction.ClaimType {
claim := it.txn.Data.(*transaction.ClaimTX)
for i := range claim.Claims {
dropInputFromSortedSlice(&mp.claims, &claim.Claims[i])
}
}
}
updateMempoolMetrics(len(mp.verifiedTxes))
mp.lock.Unlock()
}
// RemoveStale filters verified transactions through the given function keeping
// only the transactions for which it returns a true result. It's used to quickly
// drop part of the mempool that is now invalid after the block acceptance.
func (mp *Pool) RemoveStale(isOK func(*transaction.Transaction) bool) {
mp.lock.Lock()
// We can reuse already allocated slice
// because items are iterated one-by-one in increasing order.
newVerifiedTxes := mp.verifiedTxes[:0]
newInputs := mp.inputs[:0]
newClaims := mp.claims[:0]
for _, itm := range mp.verifiedTxes {
if isOK(itm.txn) {
newVerifiedTxes = append(newVerifiedTxes, itm)
for i := range itm.txn.Inputs {
newInputs = append(newInputs, &itm.txn.Inputs[i])
}
if itm.txn.Type == transaction.ClaimType {
claim := itm.txn.Data.(*transaction.ClaimTX)
for i := range claim.Claims {
newClaims = append(newClaims, &claim.Claims[i])
}
}
} else {
delete(mp.verifiedMap, itm.txn.Hash())
}
}
sort.Slice(newInputs, func(i, j int) bool {
return newInputs[i].Cmp(newInputs[j]) < 0
})
sort.Slice(newClaims, func(i, j int) bool {
return newClaims[i].Cmp(newClaims[j]) < 0
})
mp.verifiedTxes = newVerifiedTxes
mp.inputs = newInputs
mp.claims = newClaims
mp.lock.Unlock()
}
// NewMemPool returns a new Pool struct.
func NewMemPool(capacity int) Pool {
return Pool{
verifiedMap: make(map[util.Uint256]*item),
verifiedTxes: make([]*item, 0, capacity),
capacity: capacity,
}
}
// TryGetValue returns a transaction and its fee if it exists in the memory pool.
func (mp *Pool) TryGetValue(hash util.Uint256) (*transaction.Transaction, util.Fixed8, bool) {
mp.lock.RLock()
defer mp.lock.RUnlock()
if pItem, ok := mp.verifiedMap[hash]; ok {
return pItem.txn, pItem.netFee, ok
}
return nil, 0, false
}
// GetVerifiedTransactions returns a slice of Input from all the transactions in the memory pool
// whose hash is not included in excludedHashes.
func (mp *Pool) GetVerifiedTransactions() []TxWithFee {
mp.lock.RLock()
defer mp.lock.RUnlock()
var t = make([]TxWithFee, len(mp.verifiedTxes))
for i := range mp.verifiedTxes {
t[i].Tx = mp.verifiedTxes[i].txn
t[i].Fee = mp.verifiedTxes[i].netFee
}
return t
}
// areInputsInPool tries to find inputs in a given sorted pool and returns true
// if it finds any.
func areInputsInPool(inputs []transaction.Input, pool []*transaction.Input) bool {
for i := range inputs {
n := findIndexForInput(pool, &inputs[i])
if n < len(pool) && *pool[n] == inputs[i] {
return true
}
}
return false
}
// checkTxConflicts is an internal unprotected version of Verify.
func (mp *Pool) checkTxConflicts(tx *transaction.Transaction) bool {
if areInputsInPool(tx.Inputs, mp.inputs) {
return false
}
switch tx.Type {
case transaction.ClaimType:
claim := tx.Data.(*transaction.ClaimTX)
if areInputsInPool(claim.Claims, mp.claims) {
return false
}
case transaction.IssueType:
// It's a hack, because technically we could check for
// available asset amount, but these transactions are so rare
// that no one really cares about this restriction.
for i := range mp.verifiedTxes {
if mp.verifiedTxes[i].txn.Type == transaction.IssueType {
return false
}
}
}
return true
}
// Verify verifies if the inputs of a transaction tx are already used in any other transaction in the memory pool.
// If yes, the transaction tx is not a valid transaction and the function return false.
// If no, the transaction tx is a valid transaction and the function return true.
func (mp *Pool) Verify(tx *transaction.Transaction) bool {
mp.lock.RLock()
defer mp.lock.RUnlock()
return mp.checkTxConflicts(tx)
}