forked from TrueCloudLab/neoneo-go
28183b81d6
With the move to a separate package, naming can be simplified: MemPool -> Pool, PoolItem -> Item, PoolItems -> Items.
303 lines
8.7 KiB
Go
303 lines
8.7 KiB
Go
package mempool
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import (
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"sort"
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"sync"
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"time"
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"github.com/CityOfZion/neo-go/pkg/core/transaction"
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"github.com/CityOfZion/neo-go/pkg/util"
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)
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// Item represents a transaction in the the Memory pool.
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type Item struct {
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txn *transaction.Transaction
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timeStamp time.Time
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fee Feer
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}
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// Items is a slice of Item.
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type Items []*Item
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// Pool stores the unconfirms transactions.
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type Pool struct {
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lock *sync.RWMutex
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unsortedTxn map[util.Uint256]*Item
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unverifiedTxn map[util.Uint256]*Item
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sortedHighPrioTxn Items
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sortedLowPrioTxn Items
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unverifiedSortedHighPrioTxn Items
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unverifiedSortedLowPrioTxn Items
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capacity int
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}
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func (p Items) Len() int { return len(p) }
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func (p Items) Swap(i, j int) { p[i], p[j] = p[j], p[i] }
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func (p Items) Less(i, j int) bool { return p[i].CompareTo(p[j]) < 0 }
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// CompareTo returns the difference between two Items.
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// difference < 0 implies p < otherP.
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// difference = 0 implies p = otherP.
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// difference > 0 implies p > otherP.
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func (p Item) CompareTo(otherP *Item) int {
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if otherP == nil {
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return 1
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}
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if p.fee.IsLowPriority(p.txn) && p.fee.IsLowPriority(otherP.txn) {
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thisIsClaimTx := p.txn.Type == transaction.ClaimType
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otherIsClaimTx := otherP.txn.Type == transaction.ClaimType
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if thisIsClaimTx != otherIsClaimTx {
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// This is a claim Tx and other isn't.
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if thisIsClaimTx {
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return 1
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}
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// The other is claim Tx and this isn't.
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return -1
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}
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}
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// Fees sorted ascending.
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pFPB := p.fee.FeePerByte(p.txn)
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otherFPB := p.fee.FeePerByte(otherP.txn)
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if ret := pFPB.CompareTo(otherFPB); ret != 0 {
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return ret
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}
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pNF := p.fee.NetworkFee(p.txn)
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otherNF := p.fee.NetworkFee(otherP.txn)
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if ret := pNF.CompareTo(otherNF); ret != 0 {
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return ret
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}
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// Transaction hash sorted descending.
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return otherP.txn.Hash().CompareTo(p.txn.Hash())
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}
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// Count returns the total number of uncofirm transactions.
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func (mp Pool) Count() int {
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mp.lock.RLock()
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defer mp.lock.RUnlock()
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return len(mp.unsortedTxn) + len(mp.unverifiedTxn)
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}
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// ContainsKey checks if a transactions hash is in the Pool.
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func (mp Pool) ContainsKey(hash util.Uint256) bool {
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mp.lock.RLock()
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defer mp.lock.RUnlock()
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if _, ok := mp.unsortedTxn[hash]; ok {
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return true
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}
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if _, ok := mp.unverifiedTxn[hash]; ok {
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return true
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}
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return false
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}
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// TryAdd try to add the Item to the Pool.
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func (mp Pool) TryAdd(hash util.Uint256, pItem *Item) bool {
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var pool Items
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mp.lock.Lock()
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if _, ok := mp.unsortedTxn[hash]; ok {
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mp.lock.Unlock()
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return false
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}
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mp.unsortedTxn[hash] = pItem
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mp.lock.Unlock()
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if pItem.fee.IsLowPriority(pItem.txn) {
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pool = mp.sortedLowPrioTxn
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} else {
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pool = mp.sortedHighPrioTxn
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}
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mp.lock.Lock()
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pool = append(pool, pItem)
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sort.Sort(pool)
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mp.lock.Unlock()
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if mp.Count() > mp.capacity {
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(&mp).RemoveOverCapacity()
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}
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mp.lock.RLock()
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_, ok := mp.unsortedTxn[hash]
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updateMempoolMetrics(len(mp.unsortedTxn), len(mp.unverifiedTxn))
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mp.lock.RUnlock()
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return ok
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}
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// Remove removes an item from the mempool, if it exists there (and does
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// nothing if it doesn't).
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func (mp *Pool) Remove(hash util.Uint256) {
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var mapAndPools = []struct {
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unsortedMap map[util.Uint256]*Item
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sortedPools []*Items
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}{
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{unsortedMap: mp.unsortedTxn, sortedPools: []*Items{&mp.sortedHighPrioTxn, &mp.sortedLowPrioTxn}},
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{unsortedMap: mp.unverifiedTxn, sortedPools: []*Items{&mp.unverifiedSortedHighPrioTxn, &mp.unverifiedSortedLowPrioTxn}},
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}
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mp.lock.Lock()
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for _, mapAndPool := range mapAndPools {
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if _, ok := mapAndPool.unsortedMap[hash]; ok {
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delete(mapAndPool.unsortedMap, hash)
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for _, pool := range mapAndPool.sortedPools {
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var num int
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var item *Item
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for num, item = range *pool {
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if hash.Equals(item.txn.Hash()) {
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break
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}
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}
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if num < len(*pool)-1 {
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*pool = append((*pool)[:num], (*pool)[num+1:]...)
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} else if num == len(*pool)-1 {
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*pool = (*pool)[:num]
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}
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}
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}
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}
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updateMempoolMetrics(len(mp.unsortedTxn), len(mp.unverifiedTxn))
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mp.lock.Unlock()
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}
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// RemoveOverCapacity removes transactions with lowest fees until the total number of transactions
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// in the Pool is within the capacity of the Pool.
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func (mp *Pool) RemoveOverCapacity() {
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for mp.Count()-mp.capacity > 0 {
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mp.lock.Lock()
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if minItem, argPosition := getLowestFeeTransaction(mp.sortedLowPrioTxn, mp.unverifiedSortedLowPrioTxn); minItem != nil {
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if argPosition == 1 {
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// minItem belongs to the mp.sortedLowPrioTxn slice.
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// The corresponding unsorted pool is is mp.unsortedTxn.
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delete(mp.unsortedTxn, minItem.txn.Hash())
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mp.sortedLowPrioTxn = append(mp.sortedLowPrioTxn[:0], mp.sortedLowPrioTxn[1:]...)
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} else {
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// minItem belongs to the mp.unverifiedSortedLowPrioTxn slice.
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// The corresponding unsorted pool is is mp.unverifiedTxn.
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delete(mp.unverifiedTxn, minItem.txn.Hash())
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mp.unverifiedSortedLowPrioTxn = append(mp.unverifiedSortedLowPrioTxn[:0], mp.unverifiedSortedLowPrioTxn[1:]...)
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}
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} else if minItem, argPosition := getLowestFeeTransaction(mp.sortedHighPrioTxn, mp.unverifiedSortedHighPrioTxn); minItem != nil {
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if argPosition == 1 {
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// minItem belongs to the mp.sortedHighPrioTxn slice.
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// The corresponding unsorted pool is is mp.unsortedTxn.
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delete(mp.unsortedTxn, minItem.txn.Hash())
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mp.sortedHighPrioTxn = append(mp.sortedHighPrioTxn[:0], mp.sortedHighPrioTxn[1:]...)
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} else {
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// minItem belongs to the mp.unverifiedSortedHighPrioTxn slice.
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// The corresponding unsorted pool is is mp.unverifiedTxn.
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delete(mp.unverifiedTxn, minItem.txn.Hash())
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mp.unverifiedSortedHighPrioTxn = append(mp.unverifiedSortedHighPrioTxn[:0], mp.unverifiedSortedHighPrioTxn[1:]...)
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}
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}
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updateMempoolMetrics(len(mp.unsortedTxn), len(mp.unverifiedTxn))
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mp.lock.Unlock()
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}
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}
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// NewPoolItem returns a new Item.
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func NewPoolItem(t *transaction.Transaction, fee Feer) *Item {
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return &Item{
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txn: t,
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timeStamp: time.Now().UTC(),
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fee: fee,
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}
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}
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// NewMemPool returns a new Pool struct.
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func NewMemPool(capacity int) Pool {
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return Pool{
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lock: new(sync.RWMutex),
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unsortedTxn: make(map[util.Uint256]*Item),
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unverifiedTxn: make(map[util.Uint256]*Item),
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capacity: capacity,
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}
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}
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// TryGetValue returns a transaction if it exists in the memory pool.
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func (mp Pool) TryGetValue(hash util.Uint256) (*transaction.Transaction, bool) {
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mp.lock.RLock()
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defer mp.lock.RUnlock()
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if pItem, ok := mp.unsortedTxn[hash]; ok {
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return pItem.txn, ok
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}
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if pItem, ok := mp.unverifiedTxn[hash]; ok {
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return pItem.txn, ok
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}
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return nil, false
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}
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// getLowestFeeTransaction returns the Item with the lowest fee amongst the "verifiedTxnSorted"
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// and "unverifiedTxnSorted" Items along with a integer. The integer can assume two values, 1 and 2 which indicate
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// that the Item with the lowest fee was found in "verifiedTxnSorted" respectively in "unverifiedTxnSorted".
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// "verifiedTxnSorted" and "unverifiedTxnSorted" are sorted slice order by transaction fee ascending. This means that
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// the transaction with lowest fee start at index 0.
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// Reference: GetLowestFeeTransaction method in C# (https://github.com/neo-project/neo/blob/master/neo/Ledger/MemoryPool.cs)
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func getLowestFeeTransaction(verifiedTxnSorted Items, unverifiedTxnSorted Items) (*Item, int) {
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minItem := min(unverifiedTxnSorted)
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verifiedMin := min(verifiedTxnSorted)
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if verifiedMin == nil || (minItem != nil && verifiedMin.CompareTo(minItem) >= 0) {
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return minItem, 2
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}
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minItem = verifiedMin
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return minItem, 1
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}
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// min returns the minimum item in a ascending sorted slice of pool items.
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// The function can't be applied to unsorted slice!
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func min(sortedPool Items) *Item {
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if len(sortedPool) == 0 {
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return nil
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}
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return sortedPool[0]
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}
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// GetVerifiedTransactions returns a slice of Input from all the transactions in the memory pool
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// whose hash is not included in excludedHashes.
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func (mp *Pool) GetVerifiedTransactions() []*transaction.Transaction {
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mp.lock.RLock()
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defer mp.lock.RUnlock()
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var t = make([]*transaction.Transaction, len(mp.unsortedTxn))
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var i int
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for _, p := range mp.unsortedTxn {
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t[i] = p.txn
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i++
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}
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return t
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}
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// Verify verifies if the inputs of a transaction tx are already used in any other transaction in the memory pool.
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// If yes, the transaction tx is not a valid transaction and the function return false.
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// If no, the transaction tx is a valid transaction and the function return true.
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func (mp Pool) Verify(tx *transaction.Transaction) bool {
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mp.lock.RLock()
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defer mp.lock.RUnlock()
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for _, item := range mp.unsortedTxn {
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for i := range item.txn.Inputs {
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for j := 0; j < len(tx.Inputs); j++ {
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if item.txn.Inputs[i] == tx.Inputs[j] {
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return false
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}
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}
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}
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}
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return true
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}
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