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tendermint/internal/mempool/tx.go

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package mempool
import (
"sort"
"sync"
"time"
"github.com/tendermint/tendermint/internal/libs/clist"
"github.com/tendermint/tendermint/types"
)
// TxInfo are parameters that get passed when attempting to add a tx to the
// mempool.
type TxInfo struct {
// SenderID is the internal peer ID used in the mempool to identify the
// sender, storing two bytes with each transaction instead of 20 bytes for
// the types.NodeID.
SenderID uint16
// SenderNodeID is the actual types.NodeID of the sender.
SenderNodeID types.NodeID
}
// WrappedTx defines a wrapper around a raw transaction with additional metadata
// that is used for indexing.
type WrappedTx struct {
// tx represents the raw binary transaction data
tx types.Tx
// hash defines the transaction hash and the primary key used in the mempool
hash types.TxKey
// height defines the height at which the transaction was validated at
height int64
// gasWanted defines the amount of gas the transaction sender requires
gasWanted int64
// priority defines the transaction's priority as specified by the application
// in the ResponseCheckTx response.
priority int64
// sender defines the transaction's sender as specified by the application in
// the ResponseCheckTx response.
sender string
// timestamp is the time at which the node first received the transaction from
// a peer. It is used as a second dimension is prioritizing transactions when
// two transactions have the same priority.
timestamp time.Time
// peers records a mapping of all peers that sent a given transaction
peers map[uint16]struct{}
// heapIndex defines the index of the item in the heap
heapIndex int
// gossipEl references the linked-list element in the gossip index
gossipEl *clist.CElement
// removed marks the transaction as removed from the mempool. This is set
// during RemoveTx and is needed due to the fact that a given existing
// transaction in the mempool can be evicted when it is simultaneously having
// a reCheckTx callback executed.
removed bool
}
func (wtx *WrappedTx) Size() int {
return len(wtx.tx)
}
// TxStore implements a thread-safe mapping of valid transaction(s).
//
// NOTE:
// - Concurrent read-only access to a *WrappedTx object is OK. However, mutative
// access is not allowed. Regardless, it is not expected for the mempool to
// need mutative access.
type TxStore struct {
mtx sync.RWMutex
hashTxs map[types.TxKey]*WrappedTx // primary index
senderTxs map[string]*WrappedTx // sender is defined by the ABCI application
}
func NewTxStore() *TxStore {
return &TxStore{
senderTxs: make(map[string]*WrappedTx),
hashTxs: make(map[types.TxKey]*WrappedTx),
}
}
// Size returns the total number of transactions in the store.
func (txs *TxStore) Size() int {
txs.mtx.RLock()
defer txs.mtx.RUnlock()
return len(txs.hashTxs)
}
// GetAllTxs returns all the transactions currently in the store.
func (txs *TxStore) GetAllTxs() []*WrappedTx {
txs.mtx.RLock()
defer txs.mtx.RUnlock()
wTxs := make([]*WrappedTx, len(txs.hashTxs))
i := 0
for _, wtx := range txs.hashTxs {
wTxs[i] = wtx
i++
}
return wTxs
}
// GetTxBySender returns a *WrappedTx by the transaction's sender property
// defined by the ABCI application.
func (txs *TxStore) GetTxBySender(sender string) *WrappedTx {
txs.mtx.RLock()
defer txs.mtx.RUnlock()
return txs.senderTxs[sender]
}
// GetTxByHash returns a *WrappedTx by the transaction's hash.
func (txs *TxStore) GetTxByHash(hash types.TxKey) *WrappedTx {
txs.mtx.RLock()
defer txs.mtx.RUnlock()
return txs.hashTxs[hash]
}
// IsTxRemoved returns true if a transaction by hash is marked as removed and
// false otherwise.
func (txs *TxStore) IsTxRemoved(hash types.TxKey) bool {
txs.mtx.RLock()
defer txs.mtx.RUnlock()
wtx, ok := txs.hashTxs[hash]
if ok {
return wtx.removed
}
return false
}
// SetTx stores a *WrappedTx by it's hash. If the transaction also contains a
// non-empty sender, we additionally store the transaction by the sender as
// defined by the ABCI application.
func (txs *TxStore) SetTx(wtx *WrappedTx) {
txs.mtx.Lock()
defer txs.mtx.Unlock()
if len(wtx.sender) > 0 {
txs.senderTxs[wtx.sender] = wtx
}
txs.hashTxs[wtx.tx.Key()] = wtx
}
// RemoveTx removes a *WrappedTx from the transaction store. It deletes all
// indexes of the transaction.
func (txs *TxStore) RemoveTx(wtx *WrappedTx) {
txs.mtx.Lock()
defer txs.mtx.Unlock()
if len(wtx.sender) > 0 {
delete(txs.senderTxs, wtx.sender)
}
delete(txs.hashTxs, wtx.tx.Key())
wtx.removed = true
}
// TxHasPeer returns true if a transaction by hash has a given peer ID and false
// otherwise. If the transaction does not exist, false is returned.
func (txs *TxStore) TxHasPeer(hash types.TxKey, peerID uint16) bool {
txs.mtx.RLock()
defer txs.mtx.RUnlock()
wtx := txs.hashTxs[hash]
if wtx == nil {
return false
}
_, ok := wtx.peers[peerID]
return ok
}
// GetOrSetPeerByTxHash looks up a WrappedTx by transaction hash and adds the
// given peerID to the WrappedTx's set of peers that sent us this transaction.
// We return true if we've already recorded the given peer for this transaction
// and false otherwise. If the transaction does not exist by hash, we return
// (nil, false).
func (txs *TxStore) GetOrSetPeerByTxHash(hash types.TxKey, peerID uint16) (*WrappedTx, bool) {
txs.mtx.Lock()
defer txs.mtx.Unlock()
wtx := txs.hashTxs[hash]
if wtx == nil {
return nil, false
}
if wtx.peers == nil {
wtx.peers = make(map[uint16]struct{})
}
if _, ok := wtx.peers[peerID]; ok {
return wtx, true
}
wtx.peers[peerID] = struct{}{}
return wtx, false
}
// WrappedTxList implements a thread-safe list of *WrappedTx objects that can be
// used to build generic transaction indexes in the mempool. It accepts a
// comparator function, less(a, b *WrappedTx) bool, that compares two WrappedTx
// references which is used during Insert in order to determine sorted order. If
// less returns true, a <= b.
type WrappedTxList struct {
mtx sync.RWMutex
txs []*WrappedTx
less func(*WrappedTx, *WrappedTx) bool
}
func NewWrappedTxList(less func(*WrappedTx, *WrappedTx) bool) *WrappedTxList {
return &WrappedTxList{
txs: make([]*WrappedTx, 0),
less: less,
}
}
// Size returns the number of WrappedTx objects in the list.
func (wtl *WrappedTxList) Size() int {
wtl.mtx.RLock()
defer wtl.mtx.RUnlock()
return len(wtl.txs)
}
// Reset resets the list of transactions to an empty list.
func (wtl *WrappedTxList) Reset() {
wtl.mtx.Lock()
defer wtl.mtx.Unlock()
wtl.txs = make([]*WrappedTx, 0)
}
// Insert inserts a WrappedTx reference into the sorted list based on the list's
// comparator function.
func (wtl *WrappedTxList) Insert(wtx *WrappedTx) {
wtl.mtx.Lock()
defer wtl.mtx.Unlock()
i := sort.Search(len(wtl.txs), func(i int) bool {
return wtl.less(wtl.txs[i], wtx)
})
if i == len(wtl.txs) {
// insert at the end
wtl.txs = append(wtl.txs, wtx)
return
}
// Make space for the inserted element by shifting values at the insertion
// index up one index.
//
// NOTE: The call to append does not allocate memory when cap(wtl.txs) > len(wtl.txs).
wtl.txs = append(wtl.txs[:i+1], wtl.txs[i:]...)
wtl.txs[i] = wtx
}
// Remove attempts to remove a WrappedTx from the sorted list.
func (wtl *WrappedTxList) Remove(wtx *WrappedTx) {
wtl.mtx.Lock()
defer wtl.mtx.Unlock()
i := sort.Search(len(wtl.txs), func(i int) bool {
return wtl.less(wtl.txs[i], wtx)
})
// Since the list is sorted, we evaluate all elements starting at i. Note, if
// the element does not exist, we may potentially evaluate the entire remainder
// of the list. However, a caller should not be expected to call Remove with a
// non-existing element.
for i < len(wtl.txs) {
if wtl.txs[i] == wtx {
wtl.txs = append(wtl.txs[:i], wtl.txs[i+1:]...)
return
}
i++
}
}