lbcd/mempool.go

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// Copyright (c) 2013 Conformal Systems LLC.
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package main
import (
"bytes"
"container/list"
"crypto/rand"
"fmt"
"github.com/conformal/btcchain"
"github.com/conformal/btcdb"
"github.com/conformal/btcscript"
"github.com/conformal/btcwire"
"math"
"math/big"
"sync"
"time"
)
// TxRuleError identifies a rule violation. It is used to indicate that
// processing of a transaction failed due to one of the many validation
// rules. The caller can use type assertions to determine if a failure was
// specifically due to a rule violation.
type TxRuleError string
// Error satisfies the error interface to print human-readable errors.
func (e TxRuleError) Error() string {
return string(e)
}
const (
// mempoolHeight is the height used for the "block" height field of the
// contextual transaction information provided in a transaction store.
mempoolHeight = 0x7fffffff
// maxOrphanTransactions is the maximum number of orphan transactions
// that can be queued. At the time this comment was written, this
// equates to 10,000 transactions, but will increase if the max allowed
// block payload increases.
maxOrphanTransactions = btcwire.MaxBlockPayload / 100
// maxOrphanTxSize is the maximum size allowed for orphan transactions.
// This helps prevent memory exhaustion attacks from sending a lot of
// of big orphans.
maxOrphanTxSize = 5000
// maxStandardTxSize is the maximum size allowed for transactions that
// are considered standard and will therefore be relayed and considered
// for mining.
maxStandardTxSize = btcwire.MaxBlockPayload / 10
// maxStandardSigScriptSize is the maximum size allowed for a
// transaction input signature script to be considered standard. This
// value allows for a CHECKMULTISIG pay-to-sript-hash with 3 signatures
// since each signature is about 80-bytes, the 3 corresponding public
// keys are 65-bytes each if uncompressed, and the script opcodes take
// a few extra bytes. This value also adds a few extra bytes for
// prosperity. 3*80 + 3*65 + 65 = 500
maxStandardSigScriptSize = 500
// maxStandardMultiSigs is the maximum number of signatures
// allowed in a multi-signature transaction output script for it to be
// considered standard.
maxStandardMultiSigs = 3
// minTxRelayFee is the minimum fee in satoshi that is required for
// a transaction to be treated as free for relay purposes. It is also
// used to help determine if a transation is considered dust.
minTxRelayFee = 10000
)
// txMemPool is used as a source of transactions that need to be mined into
// blocks and relayed to other peers. It is safe for concurrent access from
// multiple peers.
type txMemPool struct {
server *server
pool map[btcwire.ShaHash]*btcwire.MsgTx
orphans map[btcwire.ShaHash]*btcwire.MsgTx
orphansByPrev map[btcwire.ShaHash]*list.List
outpoints map[btcwire.OutPoint]*btcwire.MsgTx
lock sync.RWMutex
}
// isDust returns whether or not the passed transaction output amount is
// considered dust or not. Dust is defined in terms of the minimum transaction
// relay fee. In particular, if the cost to the network to spend coins is more
// than 1/3 of the minimum transaction relay fee, it is considered dust.
func isDust(txOut *btcwire.TxOut) bool {
// Get the serialized size of the transaction output.
//
// TODO(davec): The serialized size should come from btcwire, but it
// currently doesn't provide a way to do so for transaction outputs, so
// calculate it here based on the current format.
// 8 bytes for value + 1 byte for script length + script length
txOutSize := 9 + len(txOut.PkScript)
// The total serialized size consists of the output and the associated
// input script to redeem it. Since there is no input script
// to redeem it yet, use the minimum size of a typical input script.
//
// Pay-to-pubkey-hash bytes breakdown:
//
// Output to hash (34 bytes):
// 8 value, 1 script len, 25 script [1 OP_DUP, 1 OP_HASH_160,
// 1 OP_DATA_20, 20 hash, 1 OP_EQUALVERIFY, 1 OP_CHECKSIG]
//
// Input with compressed pubkey (148 bytes):
// 36 prev outpoint, 1 script len, 107 script [1 OP_DATA_72, 72 sig,
// 1 OP_DATA_33, 33 compressed pubkey], 4 sequence
//
// Input with uncompressed pubkey (180 bytes):
// 36 prev outpoint, 1 script len, 139 script [1 OP_DATA_72, 72 sig,
// 1 OP_DATA_65, 65 compressed pubkey], 4 sequence
//
// Pay-to-pubkey bytes breakdown:
//
// Output to compressed pubkey (44 bytes):
// 8 value, 1 script len, 35 script [1 OP_DATA_33,
// 33 compressed pubkey, 1 OP_CHECKSIG]
//
// Output to uncompressed pubkey (76 bytes):
// 8 value, 1 script len, 67 script [1 OP_DATA_65, 65 pubkey,
// 1 OP_CHECKSIG]
//
// Input (114 bytes):
// 36 prev outpoint, 1 script len, 73 script [1 OP_DATA_72,
// 72 sig], 4 sequence
//
// Theoretically this could examine the script type of the output script
// and use a different size for the typical input script size for
// pay-to-pubkey vs pay-to-pubkey-hash inputs per the above breakdowns,
// but the only combinination which is less than the value chosen is
// a pay-to-pubkey script with a compressed pubkey, which is not very
// common.
//
// The most common scripts are pay-to-pubkey-hash, and as per the above
// breakdown, the minimum size of a p2pkh input script is 148 bytes. So
// that figure is used.
totalSize := txOutSize + 148
// The output is considered dust if the cost to the network to spend the
// coins is more than 1/3 of the minimum transaction relay fee.
// minTxRelayFee is in Satoshi/KB (kilobyte, not kibibyte), so
// multiply by 1000 to convert bytes.
//
// Using the typical values for a pay-to-pubkey-hash transaction from
// the breakdown above and the default minimum transaction relay fee of
// 10000, this equates to values less than 5460 satoshi being considered
// dust.
//
// The following is equivalent to (value/totalSize) * (1/3) * 1000
// without needing to do floating point math.
return txOut.Value*1000/(3*int64(totalSize)) < minTxRelayFee
}
// checkPkScriptStandard performs a series of checks on a transaction ouput
// script (public key script) to ensure it is a "standard" public key script.
// A standard public key script is one that is a recognized form, and for
// multi-signature scripts, only contains from 1 to 3 signatures.
func checkPkScriptStandard(pkScript []byte) error {
scriptClass := btcscript.GetScriptClass(pkScript)
switch scriptClass {
case btcscript.MultiSigTy:
// TODO(davec): Need to get the actual number of signatures.
numSigs := 1
if numSigs < 1 {
str := fmt.Sprintf("multi-signature script with no " +
"signatures")
return TxRuleError(str)
}
if numSigs > maxStandardMultiSigs {
str := fmt.Sprintf("multi-signature script with %d "+
"signatures which is more than the allowed max "+
"of %d", numSigs, maxStandardMultiSigs)
return TxRuleError(str)
}
case btcscript.NonStandardTy:
return TxRuleError(fmt.Sprintf("non-standard script form"))
}
return nil
}
// checkTransactionStandard performs a series of checks on a transaction to
// ensure it is a "standard" transaction. A standard transaction is one that
// conforms to several additional limiting cases over what is considered a
// "sane" transaction such as having a version in the supported range, being
// finalized, conforming to more stringent size constraints, having scripts
// of recognized forms, and not containing "dust" outputs (those that are
// so small it costs more to process them than they are worth).
func checkTransactionStandard(tx *btcwire.MsgTx, height int64) error {
// The transaction must be a currently supported version.
if tx.Version > btcwire.TxVersion || tx.Version < 1 {
str := fmt.Sprintf("transaction version %d is not in the "+
"valid range of %d-%d", tx.Version, 1,
btcwire.TxVersion)
return TxRuleError(str)
}
// The transaction must be finalized to be standard and therefore
// considered for inclusion in a block.
if !btcchain.IsFinalizedTransaction(tx, height, time.Now()) {
str := fmt.Sprintf("transaction is not finalized")
return TxRuleError(str)
}
// Since extremely large transactions with a lot of inputs can cost
// almost as much to process as the sender fees, limit the maximum
// size of a transaction. This also helps mitigate CPU exhaustion
// attacks.
var serializedTxBuf bytes.Buffer
err := tx.Serialize(&serializedTxBuf)
if err != nil {
return err
}
serializedLen := serializedTxBuf.Len()
if serializedLen > maxStandardTxSize {
str := fmt.Sprintf("transaction size of %v is larger than max "+
"allowed size of %v", serializedLen, maxStandardTxSize)
return TxRuleError(str)
}
for i, txIn := range tx.TxIn {
// Each transaction input signature script must not exceed the
// maximum size allowed for a standard transaction. See
// the comment on maxStandardSigScriptSize for more details.
sigScriptLen := len(txIn.SignatureScript)
if sigScriptLen > maxStandardSigScriptSize {
str := fmt.Sprintf("transaction input %d: signature "+
"script size of %d bytes is large than max "+
"allowed size of %d bytes", i, sigScriptLen,
maxStandardSigScriptSize)
return TxRuleError(str)
}
// Each transaction input signature script must only contain
// opcodes which push data onto the stack.
if !btcscript.IsPushOnlyScript(txIn.SignatureScript) {
str := fmt.Sprintf("transaction input %d: signature "+
"script is not push only", i)
return TxRuleError(str)
}
}
// None of the output public key scripts can be a non-standard script or
// be "dust".
for i, txOut := range tx.TxOut {
err := checkPkScriptStandard(txOut.PkScript)
if err != nil {
str := fmt.Sprintf("transaction output %d: %v", i, err)
return TxRuleError(str)
}
if isDust(txOut) {
str := fmt.Sprintf("transaction output %d: payment "+
"of %d is dust", i, txOut.Value)
return TxRuleError(str)
}
}
return nil
}
// checkInputsStandard performs a series of checks on a transaction's inputs
// to ensure they are "standard". A standard transaction input is one that
// that consumes the same number of outputs from the stack as the output script
// pushes. This help prevent resource exhaustion attacks by "creative" use of
// scripts that are super expensive to process like OP_DUP OP_CHECKSIG OP_DROP
// repeated a large number of times followed by a final OP_TRUE.
func checkInputsStandard(tx *btcwire.MsgTx) error {
// TODO(davec): Implement
return nil
}
// removeOrphan removes the passed orphan transaction from the orphan pool and
// previous orphan index.
func (mp *txMemPool) removeOrphan(txHash *btcwire.ShaHash) {
// Protect concurrent access.
mp.lock.Lock()
defer mp.lock.Unlock()
// Nothing to do if passed tx is not an orphan.
tx, exists := mp.orphans[*txHash]
if !exists {
return
}
// Remove the reference from the previous orphan index.
for _, txIn := range tx.TxIn {
originTxHash := txIn.PreviousOutpoint.Hash
if orphans, exists := mp.orphansByPrev[originTxHash]; exists {
for e := orphans.Front(); e != nil; e = e.Next() {
if e.Value.(*btcwire.MsgTx) == tx {
orphans.Remove(e)
break
}
}
// Remove the map entry altogether if there are no
// longer any orphans which depend on it.
if orphans.Len() == 0 {
delete(mp.orphansByPrev, originTxHash)
}
}
}
// Remove the transaction from the orphan pool.
delete(mp.orphans, *txHash)
}
// limitNumOrphans limits the number of orphan transactions by evicting a random
// orphan if adding a new one would cause it to overflow the max allowed.
func (mp *txMemPool) limitNumOrphans() error {
// Protect concurrent access.
mp.lock.Lock()
defer mp.lock.Unlock()
if len(mp.orphans)+1 > maxOrphanTransactions {
// Generate a cryptographically random hash.
randHashBytes := make([]byte, btcwire.HashSize)
_, err := rand.Read(randHashBytes)
if err != nil {
return err
}
randHashNum := new(big.Int).SetBytes(randHashBytes)
// Try to find the first entry that is greater than the random
// hash. Use the first entry (which is already pseudorandom due
// to Go's range statement over maps) as a fallback if none of
// the hashes in the orphan pool are larger than the random
// hash.
var foundHash *btcwire.ShaHash
for txHash := range mp.orphans {
if foundHash == nil {
foundHash = &txHash
}
txHashNum := btcchain.ShaHashToBig(&txHash)
if txHashNum.Cmp(randHashNum) > 0 {
foundHash = &txHash
break
}
}
// Need to unlock and relock since removeOrphan has its own
// locking.
mp.lock.Unlock()
mp.removeOrphan(foundHash)
mp.lock.Lock()
}
return nil
}
// addOrphan adds an orphan transaction to the orphan pool.
func (mp *txMemPool) addOrphan(tx *btcwire.MsgTx, txHash *btcwire.ShaHash) {
// Limit the number orphan transactions to prevent memory exhaustion. A
// random orphan is evicted to make room if needed.
mp.limitNumOrphans()
mp.lock.Lock()
defer mp.lock.Unlock()
mp.orphans[*txHash] = tx
for _, txIn := range tx.TxIn {
originTxHash := txIn.PreviousOutpoint.Hash
if mp.orphansByPrev[originTxHash] == nil {
mp.orphansByPrev[originTxHash] = list.New()
}
mp.orphansByPrev[originTxHash].PushBack(tx)
}
log.Debugf("TXMP: Stored orphan transaction %v (total: %d)", txHash,
len(mp.orphans))
}
// maybeAddOrphan potentially adds an orphan to the orphan pool.
func (mp *txMemPool) maybeAddOrphan(tx *btcwire.MsgTx, txHash *btcwire.ShaHash) error {
// Ignore orphan transactions that are too large. This helps avoid
// a memory exhaustion attack based on sending a lot of really large
// orphans. In the case there is a valid transaction larger than this,
// it will ultimtely be rebroadcast after the parent transactions
// have been mined or otherwise received.
//
// Note that the number of orphan transactions in the orphan pool is
// also limited, so this equates to a maximum memory used of
// maxOrphanTxSize * maxOrphanTransactions (which is 500MB as of the
// time this comment was written).
var serializedTxBuf bytes.Buffer
err := tx.Serialize(&serializedTxBuf)
if err != nil {
return err
}
serializedLen := serializedTxBuf.Len()
if serializedLen > maxOrphanTxSize {
str := fmt.Sprintf("orphan transaction size of %d bytes is "+
"larger than max allowed size of %d bytes",
serializedLen, maxOrphanTxSize)
return TxRuleError(str)
}
// Add the orphan if the none of the above disqualified it.
mp.addOrphan(tx, txHash)
return nil
}
// IsTransactionInPool returns whether or not the passed transaction already
// exists in the main pool.
func (mp *txMemPool) IsTransactionInPool(hash *btcwire.ShaHash) bool {
mp.lock.RLock()
defer mp.lock.RUnlock()
if _, exists := mp.pool[*hash]; exists {
return true
}
return false
}
// IsOrphanInPool returns whether or not the passed transaction already exists
// in the orphan pool.
func (mp *txMemPool) IsOrphanInPool(hash *btcwire.ShaHash) bool {
mp.lock.RLock()
defer mp.lock.RUnlock()
if _, exists := mp.orphans[*hash]; exists {
return true
}
return false
}
// HaveTransaction returns whether or not the passed transaction already exists
// in the main pool or in the orphan pool.
func (mp *txMemPool) HaveTransaction(hash *btcwire.ShaHash) bool {
return mp.IsTransactionInPool(hash) || mp.IsOrphanInPool(hash)
}
// removeTransaction removes the passed transaction from the memory pool.
func (mp *txMemPool) removeTransaction(tx *btcwire.MsgTx) {
mp.lock.Lock()
defer mp.lock.Unlock()
// Remove any transactions which rely on this one.
txHash, _ := tx.TxSha()
for i := uint32(0); i < uint32(len(tx.TxOut)); i++ {
outpoint := btcwire.NewOutPoint(&txHash, i)
if txRedeemer, exists := mp.outpoints[*outpoint]; exists {
mp.lock.Unlock()
mp.removeTransaction(txRedeemer)
mp.lock.Lock()
}
}
// Remove the transaction and mark the referenced outpoints as unspent
// by the pool.
if tx, exists := mp.pool[txHash]; exists {
for _, txIn := range tx.TxIn {
delete(mp.outpoints, txIn.PreviousOutpoint)
}
delete(mp.pool, txHash)
}
}
// addTransaction adds the passed transaction to the memory pool. It should
// not be called directly as it doesn't perform any validation. This is a
// helper for maybeAcceptTransaction.
func (mp *txMemPool) addTransaction(tx *btcwire.MsgTx, txHash *btcwire.ShaHash) {
mp.lock.Lock()
defer mp.lock.Unlock()
// Add the transaction to the pool and mark the referenced outpoints
// as spent by the pool.
mp.pool[*txHash] = tx
for _, txIn := range tx.TxIn {
mp.outpoints[txIn.PreviousOutpoint] = tx
}
}
// checkPoolDoubleSpend checks whether or not the passed transaction is
// attempting to spend coins already spent by other transactions in the pool.
// Note it does not check for double spends against transactions already in the
// main chain.
func (mp *txMemPool) checkPoolDoubleSpend(tx *btcwire.MsgTx) error {
mp.lock.RLock()
defer mp.lock.RUnlock()
for _, txIn := range tx.TxIn {
if txR, exists := mp.outpoints[txIn.PreviousOutpoint]; exists {
hash, _ := txR.TxSha()
str := fmt.Sprintf("transaction %v in the pool "+
"already spends the same coins", hash)
return TxRuleError(str)
}
}
return nil
}
// fetchInputTransactions fetches the input transactions referenced by the
// passed transaction. First, it fetches from the main chain, then it tries to
// fetch any missing inputs from the transaction pool.
func (mp *txMemPool) fetchInputTransactions(tx *btcwire.MsgTx) (btcchain.TxStore, error) {
mp.lock.RLock()
defer mp.lock.RUnlock()
txStore, err := mp.server.blockManager.blockChain.FetchTransactionStore(tx)
if err != nil {
return nil, err
}
// Attempt to populate any missing inputs from the transaction pool.
for _, txD := range txStore {
if txD.Err == btcdb.TxShaMissing || txD.Tx == nil {
if poolTx, exists := mp.pool[*txD.Hash]; exists {
txD.Tx = poolTx
txD.BlockHeight = mempoolHeight
txD.Spent = make([]bool, len(poolTx.TxOut))
txD.Err = nil
}
}
}
return txStore, nil
}
// FetchTransaction returns the requested transaction from the transaction pool.
// This only fetches from the main transaction pool and does not include
// orphans.
func (mp *txMemPool) FetchTransaction(txHash *btcwire.ShaHash) (*btcwire.MsgTx, error) {
mp.lock.RLock()
defer mp.lock.RUnlock()
if tx, exists := mp.pool[*txHash]; exists {
return tx, nil
}
return nil, fmt.Errorf("transaction is not in the pool")
}
// maybeAcceptTransaction is the main workhorse for handling insertion of new
// free-standing transactions into a memory pool. It includes functionality
// such as rejecting duplicate transactions, ensuring transactions follow all
// rules, orphan transaction handling, and insertion into the memory pool.
func (mp *txMemPool) maybeAcceptTransaction(tx *btcwire.MsgTx, isOrphan *bool) error {
*isOrphan = false
txHash, err := tx.TxSha()
if err != nil {
return err
}
// Don't accept the transaction if it already exists in the pool. This
// applies to orphan transactions as well. This check is intended to
// be a quick check to weed out duplicates.
if mp.HaveTransaction(&txHash) {
str := fmt.Sprintf("already have transaction %v", txHash)
return TxRuleError(str)
}
// Perform preliminary sanity checks on the transaction. This makes
// use of btcchain which contains the invariant rules for what
// transactions are allowed into blocks.
err = btcchain.CheckTransactionSanity(tx)
if err != nil {
if _, ok := err.(btcchain.RuleError); ok {
return TxRuleError(err.Error())
}
return err
}
// A standalone transaction must not be a coinbase transaction.
if btcchain.IsCoinBase(tx) {
str := fmt.Sprintf("transaction %v is an individual coinbase",
txHash)
return TxRuleError(str)
}
// Don't accept transactions with a lock time after the maximum int32
// value for now. This is an artifact of older bitcoind clients which
// treated this field as an int32 and would treat anything larger
// incorrectly (as negative).
if tx.LockTime > math.MaxInt32 {
str := fmt.Sprintf("transaction %v is has a lock time after "+
"2038 which is not accepted yet", txHash)
return TxRuleError(str)
}
// Get the current height of the main chain. A standalone transaction
// will be mined into the next block at best, so
_, curHeight, err := mp.server.db.NewestSha()
if err != nil {
return err
}
nextBlockHeight := curHeight + 1
// Don't allow non-standard transactions on the main network.
if activeNetParams.btcnet == btcwire.MainNet {
err := checkTransactionStandard(tx, nextBlockHeight)
if err != nil {
str := fmt.Sprintf("transaction %v is not a standard "+
"transaction: %v", txHash, err)
return TxRuleError(str)
}
}
// The transaction may not use any of the same outputs as other
// transactions already in the pool as that would ultimately result in a
// double spend. This check is intended to be quick and therefore only
// detects double spends within the transaction pool itself. The
// transaction could still be double spending coins from the main chain
// at this point. There is a more in-depth check that happens later
// after fetching the referenced transaction inputs from the main chain
// which examines the actual spend data and prevents double spends.
err = mp.checkPoolDoubleSpend(tx)
if err != nil {
return err
}
// Fetch all of the transactions referenced by the inputs to this
// transaction. This function also attempts to fetch the transaction
// itself to be used for detecting a duplicate transaction without
// needing to do a separate lookup.
txStore, err := mp.fetchInputTransactions(tx)
if err != nil {
return err
}
// Don't allow the transaction if it exists in the main chain and is not
// not already fully spent.
if txD, exists := txStore[txHash]; exists && txD.Err == nil {
for _, isOutputSpent := range txD.Spent {
if !isOutputSpent {
str := fmt.Sprintf("transaction already exists")
return TxRuleError(str)
}
}
}
delete(txStore, txHash)
// Transaction is an orphan if any of the inputs don't exist.
for _, txD := range txStore {
if txD.Err == btcdb.TxShaMissing {
*isOrphan = true
return nil
}
}
// Perform several checks on the transaction inputs using the invariant
// rules in btcchain for what transactions are allowed into blocks.
// Also returns the fees associated with the transaction which will be
// used later.
txFee, err := btcchain.CheckTransactionInputs(tx, nextBlockHeight, txStore)
if err != nil {
return err
}
// Don't allow transactions with non-standard inputs on the main
// network.
if activeNetParams.btcnet == btcwire.MainNet {
err := checkInputsStandard(tx)
if err != nil {
str := fmt.Sprintf("transaction %v has a non-standard "+
"input: %v", txHash, err)
return TxRuleError(str)
}
}
// Note: if you modify this code to accept non-standard transactions,
// you should add code here to check that the transaction does a
// reasonable number of ECDSA signature verifications.
// TODO(davec): Don't allow the transaction if the transation fee
// would be too low to get into an empty block.
_ = txFee
// Verify crypto signatures for each input and reject the transaction if
// any don't verify.
err = btcchain.ValidateTransactionScripts(tx, &txHash, time.Now(), txStore)
if err != nil {
return err
}
// TODO(davec): Rate-limit free transactions
// Add to transaction pool.
mp.addTransaction(tx, &txHash)
mp.lock.RLock()
log.Debugf("TXMP: Accepted transaction %v (pool size: %v)", txHash,
len(mp.pool))
mp.lock.RUnlock()
// TODO(davec): Notifications
// Generate the inventory vector and relay it.
iv := btcwire.NewInvVect(btcwire.InvTypeTx, &txHash)
mp.server.RelayInventory(iv)
return nil
}
// processOrphans determines if there are any orphans which depend on the passed
// transaction hash (they are no longer orphans if true) and potentially accepts
// them. It repeats the process for the newly accepted transactions (to detect
// further orphans which may no longer be orphans) until there are no more.
func (mp *txMemPool) processOrphans(hash *btcwire.ShaHash) error {
// Start with processing at least the passed hash.
processHashes := list.New()
processHashes.PushBack(hash)
for processHashes.Len() > 0 {
// Pop the first hash to process.
firstElement := processHashes.Remove(processHashes.Front())
processHash := firstElement.(*btcwire.ShaHash)
// Look up all orphans that are referenced by the transaction we
// just accepted. This will typically only be one, but it could
// be multiple if the referenced transaction contains multiple
// outputs. Skip to the next item on the list of hashes to
// process if there are none.
orphans, exists := mp.orphansByPrev[*processHash]
if !exists || orphans == nil {
continue
}
var enext *list.Element
for e := orphans.Front(); e != nil; e = enext {
enext = e.Next()
tx := e.Value.(*btcwire.MsgTx)
// Remove the orphan from the orphan pool.
orphanHash, err := tx.TxSha()
if err != nil {
return err
}
mp.removeOrphan(&orphanHash)
// Potentially accept the transaction into the
// transaction pool.
var isOrphan bool
err = mp.maybeAcceptTransaction(tx, &isOrphan)
if err != nil {
return err
}
if isOrphan {
mp.removeOrphan(&orphanHash)
}
// Add this transaction to the list of transactions to
// process so any orphans that depend on this one are
// handled too.
processHashes.PushBack(&orphanHash)
}
}
return nil
}
// ProcessTransaction is the main workhorse for handling insertion of new
// free-standing transactions into a memory pool. It includes functionality
// such as rejecting duplicate transactions, ensuring transactions follow all
// rules, orphan transaction handling, and insertion into the memory pool.
func (mp *txMemPool) ProcessTransaction(tx *btcwire.MsgTx) error {
txHash, err := tx.TxSha()
if err != nil {
return err
}
log.Tracef("TXMP: Processing transaction %v", txHash)
// Potentially accept the transaction to the memory pool.
var isOrphan bool
err = mp.maybeAcceptTransaction(tx, &isOrphan)
if err != nil {
return err
}
if !isOrphan {
// Accept any orphan transactions that depend on this
// transaction (they are no longer orphans) and repeat for those
// accepted transactions until there are no more.
err = mp.processOrphans(&txHash)
if err != nil {
return err
}
} else {
// When the transaction is an orphan (has inputs missing),
// potentially add it to the orphan pool.
err := mp.maybeAddOrphan(tx, &txHash)
if err != nil {
return err
}
}
return nil
}
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// TxShas returns a slice of hashes for all of the transactions in the memory
// pool.
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func (mp *txMemPool) TxShas() []*btcwire.ShaHash {
mp.lock.Lock()
defer mp.lock.Unlock()
hashes := make([]*btcwire.ShaHash, len(mp.pool))
i := 0
for hash := range mp.pool {
hashCopy := hash
hashes[i] = &hashCopy
i++
}
return hashes
}
// newTxMemPool returns a new memory pool for validating and storing standalone
// transactions until they are mined into a block.
func newTxMemPool(server *server) *txMemPool {
return &txMemPool{
server: server,
pool: make(map[btcwire.ShaHash]*btcwire.MsgTx),
orphans: make(map[btcwire.ShaHash]*btcwire.MsgTx),
orphansByPrev: make(map[btcwire.ShaHash]*list.List),
outpoints: make(map[btcwire.OutPoint]*btcwire.MsgTx),
}
}