btcd/mempool.go
Dave Collins 6e402deb35 Relicense to the btcsuite developers.
This commit relicenses all code in this repository to the btcsuite
developers.
2015-05-01 12:00:56 -05:00

1503 lines
52 KiB
Go

// Copyright (c) 2013-2014 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package main
import (
"container/list"
"crypto/rand"
"fmt"
"math"
"math/big"
"sync"
"time"
"github.com/btcsuite/btcd/blockchain"
"github.com/btcsuite/btcd/database"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
)
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 = wire.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
// maxSigOpsPerTx is the maximum number of signature operations
// in a single transaction we will relay or mine. It is a fraction
// of the max signature operations for a block.
maxSigOpsPerTx = blockchain.MaxSigOpsPerBlock / 5
// maxStandardTxSize is the maximum size allowed for transactions that
// are considered standard and will therefore be relayed and considered
// for mining.
maxStandardTxSize = 100000
// maxStandardSigScriptSize is the maximum size allowed for a
// transaction input signature script to be considered standard. This
// value allows for a 15-of-15 CHECKMULTISIG pay-to-script-hash with
// compressed keys.
//
// The form of the overall script is: OP_0 <15 signatures> OP_PUSHDATA2
// <2 bytes len> [OP_15 <15 pubkeys> OP_15 OP_CHECKMULTISIG]
//
// For the p2sh script portion, each of the 15 compressed pubkeys are
// 33 bytes (plus one for the OP_DATA_33 opcode), and the thus it totals
// to (15*34)+3 = 513 bytes. Next, each of the 15 signatures is a max
// of 73 bytes (plus one for the OP_DATA_73 opcode). Also, there is one
// extra byte for the initial extra OP_0 push and 3 bytes for the
// OP_PUSHDATA2 needed to specify the 513 bytes for the script push.
// That brings the total to 1+(15*74)+3+513 = 1627. This value also
// adds a few extra bytes to provide a little buffer.
// (1 + 15*74 + 3) + (15*34 + 3) + 23 = 1650
maxStandardSigScriptSize = 1650
// maxStandardMultiSigKeys is the maximum number of public keys allowed
// in a multi-signature transaction output script for it to be
// considered standard.
maxStandardMultiSigKeys = 3
// minTxRelayFee is the minimum fee in satoshi that is required for a
// transaction to be treated as free for relay and mining purposes. It
// is also used to help determine if a transaction is considered dust
// and as a base for calculating minimum required fees for larger
// transactions. This value is in Satoshi/1000 bytes.
minTxRelayFee = 1000
)
// TxDesc is a descriptor containing a transaction in the mempool and the
// metadata we store about it.
type TxDesc struct {
Tx *btcutil.Tx // Transaction.
Added time.Time // Time when added to pool.
Height int64 // Blockheight when added to pool.
Fee int64 // Transaction fees.
startingPriority float64 // Priority when added to the pool.
}
// 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 {
sync.RWMutex
server *server
pool map[wire.ShaHash]*TxDesc
orphans map[wire.ShaHash]*btcutil.Tx
orphansByPrev map[wire.ShaHash]*list.List
addrindex map[string]map[wire.ShaHash]struct{} // maps address to txs
outpoints map[wire.OutPoint]*btcutil.Tx
lastUpdated time.Time // last time pool was updated
pennyTotal float64 // exponentially decaying total for penny spends.
lastPennyUnix int64 // unix time of last ``penny spend''
}
// 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 *wire.TxOut) bool {
// 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 := txOut.SerializeSize() + 148
// The output is considered dust if the cost to the network to spend the
// coins is more than 1/3 of the minimum free transaction relay fee.
// minFreeTxRelayFee is in Satoshi/KB, so multiply by 1000 to
// convert to bytes.
//
// Using the typical values for a pay-to-pubkey-hash transaction from
// the breakdown above and the default minimum free transaction relay
// fee of 1000, this equates to values less than 546 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 maxStandardMultiSigKeys
// public keys.
func checkPkScriptStandard(pkScript []byte, scriptClass txscript.ScriptClass) error {
switch scriptClass {
case txscript.MultiSigTy:
numPubKeys, numSigs, err := txscript.CalcMultiSigStats(pkScript)
if err != nil {
str := fmt.Sprintf("multi-signature script parse "+
"failure: %v", err)
return txRuleError(wire.RejectNonstandard, str)
}
// A standard multi-signature public key script must contain
// from 1 to maxStandardMultiSigKeys public keys.
if numPubKeys < 1 {
str := "multi-signature script with no pubkeys"
return txRuleError(wire.RejectNonstandard, str)
}
if numPubKeys > maxStandardMultiSigKeys {
str := fmt.Sprintf("multi-signature script with %d "+
"public keys which is more than the allowed "+
"max of %d", numPubKeys, maxStandardMultiSigKeys)
return txRuleError(wire.RejectNonstandard, str)
}
// A standard multi-signature public key script must have at
// least 1 signature and no more signatures than available
// public keys.
if numSigs < 1 {
return txRuleError(wire.RejectNonstandard,
"multi-signature script with no signatures")
}
if numSigs > numPubKeys {
str := fmt.Sprintf("multi-signature script with %d "+
"signatures which is more than the available "+
"%d public keys", numSigs, numPubKeys)
return txRuleError(wire.RejectNonstandard, str)
}
case txscript.NonStandardTy:
return txRuleError(wire.RejectNonstandard,
"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 (mp *txMemPool) checkTransactionStandard(tx *btcutil.Tx, height int64) error {
msgTx := tx.MsgTx()
// The transaction must be a currently supported version.
if msgTx.Version > wire.TxVersion || msgTx.Version < 1 {
str := fmt.Sprintf("transaction version %d is not in the "+
"valid range of %d-%d", msgTx.Version, 1,
wire.TxVersion)
return txRuleError(wire.RejectNonstandard, str)
}
// The transaction must be finalized to be standard and therefore
// considered for inclusion in a block.
adjustedTime := mp.server.timeSource.AdjustedTime()
if !blockchain.IsFinalizedTransaction(tx, height, adjustedTime) {
return txRuleError(wire.RejectNonstandard,
"transaction is not finalized")
}
// 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.
serializedLen := msgTx.SerializeSize()
if serializedLen > maxStandardTxSize {
str := fmt.Sprintf("transaction size of %v is larger than max "+
"allowed size of %v", serializedLen, maxStandardTxSize)
return txRuleError(wire.RejectNonstandard, str)
}
for i, txIn := range msgTx.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(wire.RejectNonstandard, str)
}
// Each transaction input signature script must only contain
// opcodes which push data onto the stack.
if !txscript.IsPushOnlyScript(txIn.SignatureScript) {
str := fmt.Sprintf("transaction input %d: signature "+
"script is not push only", i)
return txRuleError(wire.RejectNonstandard, str)
}
}
// None of the output public key scripts can be a non-standard script or
// be "dust" (except when the script is a null data script).
numNullDataOutputs := 0
for i, txOut := range msgTx.TxOut {
scriptClass := txscript.GetScriptClass(txOut.PkScript)
err := checkPkScriptStandard(txOut.PkScript, scriptClass)
if err != nil {
// Attempt to extract a reject code from the error so
// it can be retained. When not possible, fall back to
// a non standard error.
rejectCode, found := extractRejectCode(err)
if !found {
rejectCode = wire.RejectNonstandard
}
str := fmt.Sprintf("transaction output %d: %v", i, err)
return txRuleError(rejectCode, str)
}
// Accumulate the number of outputs which only carry data. For
// all other script types, ensure the output value is not
// "dust".
if scriptClass == txscript.NullDataTy {
numNullDataOutputs++
} else if isDust(txOut) {
str := fmt.Sprintf("transaction output %d: payment "+
"of %d is dust", i, txOut.Value)
return txRuleError(wire.RejectDust, str)
}
}
// A standard transaction must not have more than one output script that
// only carries data.
if numNullDataOutputs > 1 {
str := "more than one transaction output in a nulldata script"
return txRuleError(wire.RejectNonstandard, 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 expected number of elements from the stack and that number
// is the same 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 *btcutil.Tx, txStore blockchain.TxStore) error {
// NOTE: The reference implementation also does a coinbase check here,
// but coinbases have already been rejected prior to calling this
// function so no need to recheck.
for i, txIn := range tx.MsgTx().TxIn {
// It is safe to elide existence and index checks here since
// they have already been checked prior to calling this
// function.
prevOut := txIn.PreviousOutPoint
originTx := txStore[prevOut.Hash].Tx.MsgTx()
originPkScript := originTx.TxOut[prevOut.Index].PkScript
// Calculate stats for the script pair.
scriptInfo, err := txscript.CalcScriptInfo(txIn.SignatureScript,
originPkScript, true)
if err != nil {
str := fmt.Sprintf("transaction input #%d script parse "+
"failure: %v", i, err)
return txRuleError(wire.RejectNonstandard, str)
}
// A negative value for expected inputs indicates the script is
// non-standard in some way.
if scriptInfo.ExpectedInputs < 0 {
str := fmt.Sprintf("transaction input #%d expects %d "+
"inputs", i, scriptInfo.ExpectedInputs)
return txRuleError(wire.RejectNonstandard, str)
}
// The script pair is non-standard if the number of available
// inputs does not match the number of expected inputs.
if scriptInfo.NumInputs != scriptInfo.ExpectedInputs {
str := fmt.Sprintf("transaction input #%d expects %d "+
"inputs, but referenced output script provides "+
"%d", i, scriptInfo.ExpectedInputs,
scriptInfo.NumInputs)
return txRuleError(wire.RejectNonstandard, str)
}
}
return nil
}
// calcMinRequiredTxRelayFee returns the minimum transaction fee required for a
// transaction with the passed serialized size to be accepted into the memory
// pool and relayed.
func calcMinRequiredTxRelayFee(serializedSize int64) int64 {
// Calculate the minimum fee for a transaction to be allowed into the
// mempool and relayed by scaling the base fee (which is the minimum
// free transaction relay fee). minTxRelayFee is in Satoshi/KB, so
// divide the transaction size by 1000 to convert to kilobytes. Also,
// integer division is used so fees only increase on full kilobyte
// boundaries.
minFee := (1 + serializedSize/1000) * minTxRelayFee
// Set the minimum fee to the maximum possible value if the calculated
// fee is not in the valid range for monetary amounts.
if minFee < 0 || minFee > btcutil.MaxSatoshi {
minFee = btcutil.MaxSatoshi
}
return minFee
}
// removeOrphan is the internal function which implements the public
// RemoveOrphan. See the comment for RemoveOrphan for more details.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) removeOrphan(txHash *wire.ShaHash) {
// 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.MsgTx().TxIn {
originTxHash := txIn.PreviousOutPoint.Hash
if orphans, exists := mp.orphansByPrev[originTxHash]; exists {
for e := orphans.Front(); e != nil; e = e.Next() {
if e.Value.(*btcutil.Tx) == 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)
}
// RemoveOrphan removes the passed orphan transaction from the orphan pool and
// previous orphan index.
//
// This function is safe for concurrent access.
func (mp *txMemPool) RemoveOrphan(txHash *wire.ShaHash) {
mp.Lock()
mp.removeOrphan(txHash)
mp.Unlock()
}
// 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.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) limitNumOrphans() error {
if len(mp.orphans)+1 > maxOrphanTransactions {
// Generate a cryptographically random hash.
randHashBytes := make([]byte, wire.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 *wire.ShaHash
for txHash := range mp.orphans {
if foundHash == nil {
foundHash = &txHash
}
txHashNum := blockchain.ShaHashToBig(&txHash)
if txHashNum.Cmp(randHashNum) > 0 {
foundHash = &txHash
break
}
}
mp.removeOrphan(foundHash)
}
return nil
}
// addOrphan adds an orphan transaction to the orphan pool.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) addOrphan(tx *btcutil.Tx) {
// Limit the number orphan transactions to prevent memory exhaustion. A
// random orphan is evicted to make room if needed.
mp.limitNumOrphans()
mp.orphans[*tx.Sha()] = tx
for _, txIn := range tx.MsgTx().TxIn {
originTxHash := txIn.PreviousOutPoint.Hash
if mp.orphansByPrev[originTxHash] == nil {
mp.orphansByPrev[originTxHash] = list.New()
}
mp.orphansByPrev[originTxHash].PushBack(tx)
}
txmpLog.Debugf("Stored orphan transaction %v (total: %d)", tx.Sha(),
len(mp.orphans))
}
// maybeAddOrphan potentially adds an orphan to the orphan pool.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) maybeAddOrphan(tx *btcutil.Tx) 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).
serializedLen := tx.MsgTx().SerializeSize()
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(wire.RejectNonstandard, str)
}
// Add the orphan if the none of the above disqualified it.
mp.addOrphan(tx)
return nil
}
// isTransactionInPool returns whether or not the passed transaction already
// exists in the main pool.
//
// This function MUST be called with the mempool lock held (for reads).
func (mp *txMemPool) isTransactionInPool(hash *wire.ShaHash) bool {
if _, exists := mp.pool[*hash]; exists {
return true
}
return false
}
// IsTransactionInPool returns whether or not the passed transaction already
// exists in the main pool.
//
// This function is safe for concurrent access.
func (mp *txMemPool) IsTransactionInPool(hash *wire.ShaHash) bool {
// Protect concurrent access.
mp.RLock()
defer mp.RUnlock()
return mp.isTransactionInPool(hash)
}
// isOrphanInPool returns whether or not the passed transaction already exists
// in the orphan pool.
//
// This function MUST be called with the mempool lock held (for reads).
func (mp *txMemPool) isOrphanInPool(hash *wire.ShaHash) bool {
if _, exists := mp.orphans[*hash]; exists {
return true
}
return false
}
// IsOrphanInPool returns whether or not the passed transaction already exists
// in the orphan pool.
//
// This function is safe for concurrent access.
func (mp *txMemPool) IsOrphanInPool(hash *wire.ShaHash) bool {
// Protect concurrent access.
mp.RLock()
defer mp.RUnlock()
return mp.isOrphanInPool(hash)
}
// haveTransaction returns whether or not the passed transaction already exists
// in the main pool or in the orphan pool.
//
// This function MUST be called with the mempool lock held (for reads).
func (mp *txMemPool) haveTransaction(hash *wire.ShaHash) bool {
return mp.isTransactionInPool(hash) || mp.isOrphanInPool(hash)
}
// HaveTransaction returns whether or not the passed transaction already exists
// in the main pool or in the orphan pool.
//
// This function is safe for concurrent access.
func (mp *txMemPool) HaveTransaction(hash *wire.ShaHash) bool {
// Protect concurrent access.
mp.RLock()
defer mp.RUnlock()
return mp.haveTransaction(hash)
}
// removeTransaction is the internal function which implements the public
// RemoveTransaction. See the comment for RemoveTransaction for more details.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) removeTransaction(tx *btcutil.Tx) {
// Remove any transactions which rely on this one.
txHash := tx.Sha()
for i := uint32(0); i < uint32(len(tx.MsgTx().TxOut)); i++ {
outpoint := wire.NewOutPoint(txHash, i)
if txRedeemer, exists := mp.outpoints[*outpoint]; exists {
mp.removeTransaction(txRedeemer)
}
}
// Remove the transaction and mark the referenced outpoints as unspent
// by the pool.
if txDesc, exists := mp.pool[*txHash]; exists {
if cfg.AddrIndex {
mp.removeTransactionFromAddrIndex(tx)
}
for _, txIn := range txDesc.Tx.MsgTx().TxIn {
delete(mp.outpoints, txIn.PreviousOutPoint)
}
delete(mp.pool, *txHash)
mp.lastUpdated = time.Now()
}
}
// removeTransactionFromAddrIndex removes the passed transaction from our
// address based index.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) removeTransactionFromAddrIndex(tx *btcutil.Tx) error {
previousOutputScripts, err := mp.fetchReferencedOutputScripts(tx)
if err != nil {
txmpLog.Errorf("Unable to obtain referenced output scripts for "+
"the passed tx (addrindex): %v", err)
return err
}
for _, pkScript := range previousOutputScripts {
mp.removeScriptFromAddrIndex(pkScript, tx)
}
for _, txOut := range tx.MsgTx().TxOut {
mp.removeScriptFromAddrIndex(txOut.PkScript, tx)
}
return nil
}
// removeScriptFromAddrIndex dissociates the address encoded by the
// passed pkScript from the passed tx in our address based tx index.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) removeScriptFromAddrIndex(pkScript []byte, tx *btcutil.Tx) error {
_, addresses, _, err := txscript.ExtractPkScriptAddrs(pkScript,
activeNetParams.Params)
if err != nil {
txmpLog.Errorf("Unable to extract encoded addresses from script "+
"for addrindex (addrindex): %v", err)
return err
}
for _, addr := range addresses {
delete(mp.addrindex[addr.EncodeAddress()], *tx.Sha())
}
return nil
}
// RemoveTransaction removes the passed transaction and any transactions which
// depend on it from the memory pool.
//
// This function is safe for concurrent access.
func (mp *txMemPool) RemoveTransaction(tx *btcutil.Tx) {
// Protect concurrent access.
mp.Lock()
defer mp.Unlock()
mp.removeTransaction(tx)
}
// RemoveDoubleSpends removes all transactions which spend outputs spent by the
// passed transaction from the memory pool. Removing those transactions then
// leads to removing all transactions which rely on them, recursively. This is
// necessary when a block is connected to the main chain because the block may
// contain transactions which were previously unknown to the memory pool
//
// This function is safe for concurrent access.
func (mp *txMemPool) RemoveDoubleSpends(tx *btcutil.Tx) {
// Protect concurrent access.
mp.Lock()
defer mp.Unlock()
for _, txIn := range tx.MsgTx().TxIn {
if txRedeemer, ok := mp.outpoints[txIn.PreviousOutPoint]; ok {
if !txRedeemer.Sha().IsEqual(tx.Sha()) {
mp.removeTransaction(txRedeemer)
}
}
}
}
// 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.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) addTransaction(tx *btcutil.Tx, height, fee int64) {
// Add the transaction to the pool and mark the referenced outpoints
// as spent by the pool.
mp.pool[*tx.Sha()] = &TxDesc{
Tx: tx,
Added: time.Now(),
Height: height,
Fee: fee,
}
for _, txIn := range tx.MsgTx().TxIn {
mp.outpoints[txIn.PreviousOutPoint] = tx
}
mp.lastUpdated = time.Now()
if cfg.AddrIndex {
mp.addTransactionToAddrIndex(tx)
}
}
// addTransactionToAddrIndex adds all addresses related to the transaction to
// our in-memory address index. Note that this address is only populated when
// we're running with the optional address index activated.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) addTransactionToAddrIndex(tx *btcutil.Tx) error {
previousOutScripts, err := mp.fetchReferencedOutputScripts(tx)
if err != nil {
txmpLog.Errorf("Unable to obtain referenced output scripts for "+
"the passed tx (addrindex): %v", err)
return err
}
// Index addresses of all referenced previous output tx's.
for _, pkScript := range previousOutScripts {
mp.indexScriptAddressToTx(pkScript, tx)
}
// Index addresses of all created outputs.
for _, txOut := range tx.MsgTx().TxOut {
mp.indexScriptAddressToTx(txOut.PkScript, tx)
}
return nil
}
// fetchReferencedOutputScripts looks up and returns all the scriptPubKeys
// referenced by inputs of the passed transaction.
//
// This function MUST be called with the mempool lock held (for reads).
func (mp *txMemPool) fetchReferencedOutputScripts(tx *btcutil.Tx) ([][]byte, error) {
txStore, err := mp.fetchInputTransactions(tx)
if err != nil || len(txStore) == 0 {
return nil, err
}
previousOutScripts := make([][]byte, 0, len(tx.MsgTx().TxIn))
for _, txIn := range tx.MsgTx().TxIn {
outPoint := txIn.PreviousOutPoint
if txStore[outPoint.Hash].Err == nil {
referencedOutPoint := txStore[outPoint.Hash].Tx.MsgTx().TxOut[outPoint.Index]
previousOutScripts = append(previousOutScripts, referencedOutPoint.PkScript)
}
}
return previousOutScripts, nil
}
// indexScriptByAddress alters our address index by indexing the payment address
// encoded by the passed scriptPubKey to the passed transaction.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) indexScriptAddressToTx(pkScript []byte, tx *btcutil.Tx) error {
_, addresses, _, err := txscript.ExtractPkScriptAddrs(pkScript,
activeNetParams.Params)
if err != nil {
txmpLog.Errorf("Unable to extract encoded addresses from script "+
"for addrindex: %v", err)
return err
}
for _, addr := range addresses {
if mp.addrindex[addr.EncodeAddress()] == nil {
mp.addrindex[addr.EncodeAddress()] = make(map[wire.ShaHash]struct{})
}
mp.addrindex[addr.EncodeAddress()][*tx.Sha()] = struct{}{}
}
return nil
}
// calcInputValueAge is a helper function used to calculate the input age of
// a transaction. The input age for a txin is the number of confirmations
// since the referenced txout multiplied by its output value. The total input
// age is the sum of this value for each txin. Any inputs to the transaction
// which are currently in the mempool and hence not mined into a block yet,
// contribute no additional input age to the transaction.
func calcInputValueAge(txDesc *TxDesc, txStore blockchain.TxStore, nextBlockHeight int64) float64 {
var totalInputAge float64
for _, txIn := range txDesc.Tx.MsgTx().TxIn {
originHash := &txIn.PreviousOutPoint.Hash
originIndex := txIn.PreviousOutPoint.Index
// Don't attempt to accumulate the total input age if the txIn
// in question doesn't exist.
if txData, exists := txStore[*originHash]; exists && txData.Tx != nil {
// Inputs with dependencies currently in the mempool
// have their block height set to a special constant.
// Their input age should computed as zero since their
// parent hasn't made it into a block yet.
var inputAge int64
if txData.BlockHeight == mempoolHeight {
inputAge = 0
} else {
inputAge = nextBlockHeight - txData.BlockHeight
}
// Sum the input value times age.
originTxOut := txData.Tx.MsgTx().TxOut[originIndex]
inputValue := originTxOut.Value
totalInputAge += float64(inputValue * inputAge)
}
}
return totalInputAge
}
// minInt is a helper function to return the minimum of two ints. This avoids
// a math import and the need to cast to floats.
func minInt(a, b int) int {
if a < b {
return a
}
return b
}
// calcPriority returns a transaction priority given a transaction and the sum
// of each of its input values multiplied by their age (# of confirmations).
// Thus, the final formula for the priority is:
// sum(inputValue * inputAge) / adjustedTxSize
func calcPriority(tx *btcutil.Tx, inputValueAge float64) float64 {
// In order to encourage spending multiple old unspent transaction
// outputs thereby reducing the total set, don't count the constant
// overhead for each input as well as enough bytes of the signature
// script to cover a pay-to-script-hash redemption with a compressed
// pubkey. This makes additional inputs free by boosting the priority
// of the transaction accordingly. No more incentive is given to avoid
// encouraging gaming future transactions through the use of junk
// outputs. This is the same logic used in the reference
// implementation.
//
// The constant overhead for a txin is 41 bytes since the previous
// outpoint is 36 bytes + 4 bytes for the sequence + 1 byte the
// signature script length.
//
// A compressed pubkey pay-to-script-hash redemption with a maximum len
// signature is of the form:
// [OP_DATA_73 <73-byte sig> + OP_DATA_35 + {OP_DATA_33
// <33 byte compresed pubkey> + OP_CHECKSIG}]
//
// Thus 1 + 73 + 1 + 1 + 33 + 1 = 110
overhead := 0
for _, txIn := range tx.MsgTx().TxIn {
// Max inputs + size can't possibly overflow here.
overhead += 41 + minInt(110, len(txIn.SignatureScript))
}
serializedTxSize := tx.MsgTx().SerializeSize()
if overhead >= serializedTxSize {
return 0.0
}
return inputValueAge / float64(serializedTxSize-overhead)
}
// StartingPriority calculates the priority of this tx descriptor's underlying
// transaction relative to when it was first added to the mempool. The result
// is lazily computed and then cached for subsequent function calls.
func (txD *TxDesc) StartingPriority(txStore blockchain.TxStore) float64 {
// Return our cached result.
if txD.startingPriority != float64(0) {
return txD.startingPriority
}
// Compute our starting priority caching the result.
inputAge := calcInputValueAge(txD, txStore, txD.Height)
txD.startingPriority = calcPriority(txD.Tx, inputAge)
return txD.startingPriority
}
// CurrentPriority calculates the current priority of this tx descriptor's
// underlying transaction relative to the next block height.
func (txD *TxDesc) CurrentPriority(txStore blockchain.TxStore, nextBlockHeight int64) float64 {
inputAge := calcInputValueAge(txD, txStore, nextBlockHeight)
return calcPriority(txD.Tx, inputAge)
}
// 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.
//
// This function MUST be called with the mempool lock held (for reads).
func (mp *txMemPool) checkPoolDoubleSpend(tx *btcutil.Tx) error {
for _, txIn := range tx.MsgTx().TxIn {
if txR, exists := mp.outpoints[txIn.PreviousOutPoint]; exists {
str := fmt.Sprintf("output %v already spent by "+
"transaction %v in the memory pool",
txIn.PreviousOutPoint, txR.Sha())
return txRuleError(wire.RejectDuplicate, 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.
//
// This function MUST be called with the mempool lock held (for reads).
func (mp *txMemPool) fetchInputTransactions(tx *btcutil.Tx) (blockchain.TxStore, error) {
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 == database.ErrTxShaMissing || txD.Tx == nil {
if poolTxDesc, exists := mp.pool[*txD.Hash]; exists {
poolTx := poolTxDesc.Tx
txD.Tx = poolTx
txD.BlockHeight = mempoolHeight
txD.Spent = make([]bool, len(poolTx.MsgTx().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.
//
// This function is safe for concurrent access.
func (mp *txMemPool) FetchTransaction(txHash *wire.ShaHash) (*btcutil.Tx, error) {
// Protect concurrent access.
mp.RLock()
defer mp.RUnlock()
if txDesc, exists := mp.pool[*txHash]; exists {
return txDesc.Tx, nil
}
return nil, fmt.Errorf("transaction is not in the pool")
}
// FilterTransactionsByAddress returns all transactions currently in the
// mempool that either create an output to the passed address or spend a
// previously created ouput to the address.
func (mp *txMemPool) FilterTransactionsByAddress(addr btcutil.Address) ([]*btcutil.Tx, error) {
// Protect concurrent access.
mp.RLock()
defer mp.RUnlock()
if txs, exists := mp.addrindex[addr.EncodeAddress()]; exists {
addressTxs := make([]*btcutil.Tx, 0, len(txs))
for txHash := range txs {
if tx, exists := mp.pool[txHash]; exists {
addressTxs = append(addressTxs, tx.Tx)
}
}
return addressTxs, nil
}
return nil, fmt.Errorf("address does not have any transactions in the pool")
}
// maybeAcceptTransaction is the internal function which implements the public
// MaybeAcceptTransaction. See the comment for MaybeAcceptTransaction for
// more details.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) maybeAcceptTransaction(tx *btcutil.Tx, isNew, rateLimit bool) ([]*wire.ShaHash, error) {
txHash := tx.Sha()
// 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 nil, txRuleError(wire.RejectDuplicate, 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 := blockchain.CheckTransactionSanity(tx)
if err != nil {
if cerr, ok := err.(blockchain.RuleError); ok {
return nil, chainRuleError(cerr)
}
return nil, err
}
// A standalone transaction must not be a coinbase transaction.
if blockchain.IsCoinBase(tx) {
str := fmt.Sprintf("transaction %v is an individual coinbase",
txHash)
return nil, txRuleError(wire.RejectInvalid, 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.MsgTx().LockTime > math.MaxInt32 {
str := fmt.Sprintf("transaction %v has a lock time after "+
"2038 which is not accepted yet", txHash)
return nil, txRuleError(wire.RejectNonstandard, str)
}
// Get the current height of the main chain. A standalone transaction
// will be mined into the next block at best, so it's height is at least
// one more than the current height.
_, curHeight, err := mp.server.db.NewestSha()
if err != nil {
// This is an unexpected error so don't turn it into a rule
// error.
return nil, err
}
nextBlockHeight := curHeight + 1
// Don't allow non-standard transactions if the network parameters
// forbid their relaying.
if !activeNetParams.RelayNonStdTxs {
err := mp.checkTransactionStandard(tx, nextBlockHeight)
if err != nil {
// Attempt to extract a reject code from the error so
// it can be retained. When not possible, fall back to
// a non standard error.
rejectCode, found := extractRejectCode(err)
if !found {
rejectCode = wire.RejectNonstandard
}
str := fmt.Sprintf("transaction %v is not standard: %v",
txHash, err)
return nil, txRuleError(rejectCode, 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 nil, 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 {
if cerr, ok := err.(blockchain.RuleError); ok {
return nil, chainRuleError(cerr)
}
return nil, 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 {
return nil, txRuleError(wire.RejectDuplicate,
"transaction already exists")
}
}
}
delete(txStore, *txHash)
// Transaction is an orphan if any of the referenced input transactions
// don't exist. Adding orphans to the orphan pool is not handled by
// this function, and the caller should use maybeAddOrphan if this
// behavior is desired.
var missingParents []*wire.ShaHash
for _, txD := range txStore {
if txD.Err == database.ErrTxShaMissing {
missingParents = append(missingParents, txD.Hash)
}
}
if len(missingParents) != 0 {
return missingParents, 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 := blockchain.CheckTransactionInputs(tx, nextBlockHeight, txStore)
if err != nil {
if cerr, ok := err.(blockchain.RuleError); ok {
return nil, chainRuleError(cerr)
}
return nil, err
}
// Don't allow transactions with non-standard inputs if the network
// parameters forbid their relaying.
if !activeNetParams.RelayNonStdTxs {
err := checkInputsStandard(tx, txStore)
if err != nil {
// Attempt to extract a reject code from the error so
// it can be retained. When not possible, fall back to
// a non standard error.
rejectCode, found := extractRejectCode(err)
if !found {
rejectCode = wire.RejectNonstandard
}
str := fmt.Sprintf("transaction %v has a non-standard "+
"input: %v", txHash, err)
return nil, txRuleError(rejectCode, 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.
// Don't allow transactions with an excessive number of signature
// operations which would result in making it impossible to mine. Since
// the coinbase address itself can contain signature operations, the
// maximum allowed signature operations per transaction is less than
// the maximum allowed signature operations per block.
numSigOps, err := blockchain.CountP2SHSigOps(tx, false, txStore)
if err != nil {
if cerr, ok := err.(blockchain.RuleError); ok {
return nil, chainRuleError(cerr)
}
return nil, err
}
numSigOps += blockchain.CountSigOps(tx)
if numSigOps > maxSigOpsPerTx {
str := fmt.Sprintf("transaction %v has too many sigops: %d > %d",
txHash, numSigOps, maxSigOpsPerTx)
return nil, txRuleError(wire.RejectNonstandard, str)
}
// Don't allow transactions with fees too low to get into a mined block.
//
// Most miners allow a free transaction area in blocks they mine to go
// alongside the area used for high-priority transactions as well as
// transactions with fees. A transaction size of up to 1000 bytes is
// considered safe to go into this section. Further, the minimum fee
// calculated below on its own would encourage several small
// transactions to avoid fees rather than one single larger transaction
// which is more desirable. Therefore, as long as the size of the
// transaction does not exceeed 1000 less than the reserved space for
// high-priority transactions, don't require a fee for it.
serializedSize := int64(tx.MsgTx().SerializeSize())
minFee := calcMinRequiredTxRelayFee(serializedSize)
if serializedSize >= (defaultBlockPrioritySize-1000) && txFee < minFee {
str := fmt.Sprintf("transaction %v has %d fees which is under "+
"the required amount of %d", txHash, txFee,
minFee)
return nil, txRuleError(wire.RejectInsufficientFee, str)
}
// Require that free transactions have sufficient priority to be mined
// in the next block. Transactions which are being added back to the
// memory pool from blocks that have been disconnected during a reorg
// are exempted.
if isNew && !cfg.NoRelayPriority && txFee < minFee {
txD := &TxDesc{
Tx: tx,
Added: time.Now(),
Height: curHeight,
Fee: txFee,
}
currentPriority := txD.CurrentPriority(txStore, nextBlockHeight)
if currentPriority <= minHighPriority {
str := fmt.Sprintf("transaction %v has insufficient "+
"priority (%g <= %g)", txHash,
currentPriority, minHighPriority)
return nil, txRuleError(wire.RejectInsufficientFee, str)
}
}
// Free-to-relay transactions are rate limited here to prevent
// penny-flooding with tiny transactions as a form of attack.
if rateLimit && txFee < minFee {
nowUnix := time.Now().Unix()
// we decay passed data with an exponentially decaying ~10
// minutes window - matches bitcoind handling.
mp.pennyTotal *= math.Pow(1.0-1.0/600.0,
float64(nowUnix-mp.lastPennyUnix))
mp.lastPennyUnix = nowUnix
// Are we still over the limit?
if mp.pennyTotal >= cfg.FreeTxRelayLimit*10*1000 {
str := fmt.Sprintf("transaction %v has been rejected "+
"by the rate limiter due to low fees", txHash)
return nil, txRuleError(wire.RejectInsufficientFee, str)
}
oldTotal := mp.pennyTotal
mp.pennyTotal += float64(serializedSize)
txmpLog.Tracef("rate limit: curTotal %v, nextTotal: %v, "+
"limit %v", oldTotal, mp.pennyTotal,
cfg.FreeTxRelayLimit*10*1000)
}
// Verify crypto signatures for each input and reject the transaction if
// any don't verify.
err = blockchain.ValidateTransactionScripts(tx, txStore,
txscript.StandardVerifyFlags)
if err != nil {
if cerr, ok := err.(blockchain.RuleError); ok {
return nil, chainRuleError(cerr)
}
return nil, err
}
// Add to transaction pool.
mp.addTransaction(tx, curHeight, txFee)
txmpLog.Debugf("Accepted transaction %v (pool size: %v)", txHash,
len(mp.pool))
if mp.server.rpcServer != nil {
// Notify websocket clients about mempool transactions.
mp.server.rpcServer.ntfnMgr.NotifyMempoolTx(tx, isNew)
// Potentially notify any getblocktemplate long poll clients
// about stale block templates due to the new transaction.
mp.server.rpcServer.gbtWorkState.NotifyMempoolTx(mp.lastUpdated)
}
return nil, nil
}
// 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, detecting orphan transactions, and insertion into the memory pool.
//
// If the transaction is an orphan (missing parent transactions), the
// transaction is NOT added to the orphan pool, but each unknown referenced
// parent is returned. Use ProcessTransaction instead if new orphans should
// be added to the orphan pool.
//
// This function is safe for concurrent access.
func (mp *txMemPool) MaybeAcceptTransaction(tx *btcutil.Tx, isNew, rateLimit bool) ([]*wire.ShaHash, error) {
// Protect concurrent access.
mp.Lock()
defer mp.Unlock()
return mp.maybeAcceptTransaction(tx, isNew, rateLimit)
}
// processOrphans is the internal function which implements the public
// ProcessOrphans. See the comment for ProcessOrphans for more details.
//
// This function MUST be called with the mempool lock held (for writes).
func (mp *txMemPool) processOrphans(hash *wire.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.(*wire.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.(*btcutil.Tx)
// Remove the orphan from the orphan pool. Current
// behavior requires that all saved orphans with
// a newly accepted parent are removed from the orphan
// pool and potentially added to the memory pool, but
// transactions which cannot be added to memory pool
// (including due to still being orphans) are expunged
// from the orphan pool.
//
// TODO(jrick): The above described behavior sounds
// like a bug, and I think we should investigate
// potentially moving orphans to the memory pool, but
// leaving them in the orphan pool if not all parent
// transactions are known yet.
orphanHash := tx.Sha()
mp.removeOrphan(orphanHash)
// Potentially accept the transaction into the
// transaction pool.
missingParents, err := mp.maybeAcceptTransaction(tx,
true, true)
if err != nil {
return err
}
if len(missingParents) == 0 {
// Generate and relay the inventory vector for the
// newly accepted transaction.
iv := wire.NewInvVect(wire.InvTypeTx, tx.Sha())
mp.server.RelayInventory(iv, tx)
} else {
// Transaction is still an orphan.
// TODO(jrick): This removeOrphan call is
// likely unnecessary as it was unconditionally
// removed above and maybeAcceptTransaction won't
// add it back.
mp.removeOrphan(orphanHash)
}
// Add this transaction to the list of transactions to
// process so any orphans that depend on this one are
// handled too.
//
// TODO(jrick): In the case that this is still an orphan,
// we know that any other transactions in the orphan
// pool with this orphan as their parent are still
// orphans as well, and should be removed. While
// recursively calling removeOrphan and
// maybeAcceptTransaction on these transactions is not
// wrong per se, it is overkill if all we care about is
// recursively removing child transactions of this
// orphan.
processHashes.PushBack(orphanHash)
}
}
return nil
}
// ProcessOrphans determines if there are any orphans which depend on the passed
// transaction hash (it is possible that they are no longer orphans) and
// potentially accepts them to the memory pool. It repeats the process for the
// newly accepted transactions (to detect further orphans which may no longer be
// orphans) until there are no more.
//
// This function is safe for concurrent access.
func (mp *txMemPool) ProcessOrphans(hash *wire.ShaHash) error {
mp.Lock()
defer mp.Unlock()
return mp.processOrphans(hash)
}
// ProcessTransaction is the main workhorse for handling insertion of new
// free-standing transactions into the memory pool. It includes functionality
// such as rejecting duplicate transactions, ensuring transactions follow all
// rules, orphan transaction handling, and insertion into the memory pool.
//
// This function is safe for concurrent access.
func (mp *txMemPool) ProcessTransaction(tx *btcutil.Tx, allowOrphan, rateLimit bool) error {
// Protect concurrent access.
mp.Lock()
defer mp.Unlock()
txmpLog.Tracef("Processing transaction %v", tx.Sha())
// Potentially accept the transaction to the memory pool.
missingParents, err := mp.maybeAcceptTransaction(tx, true, rateLimit)
if err != nil {
return err
}
if len(missingParents) == 0 {
// Generate the inventory vector and relay it.
iv := wire.NewInvVect(wire.InvTypeTx, tx.Sha())
mp.server.RelayInventory(iv, tx)
// Accept any orphan transactions that depend on this
// transaction (they may no longer be orphans if all inputs
// are now available) and repeat for those accepted
// transactions until there are no more.
err := mp.processOrphans(tx.Sha())
if err != nil {
return err
}
} else {
// The transaction is an orphan (has inputs missing). Reject
// it if the flag to allow orphans is not set.
if !allowOrphan {
// Only use the first missing parent transaction in
// the error message.
//
// NOTE: RejectDuplicate is really not an accurate
// reject code here, but it matches the reference
// implementation and there isn't a better choice due
// to the limited number of reject codes. Missing
// inputs is assumed to mean they are already spent
// which is not really always the case.
str := fmt.Sprintf("orphan transaction %v references "+
"outputs of unknown or fully-spent "+
"transaction %v", tx.Sha(), missingParents[0])
return txRuleError(wire.RejectDuplicate, str)
}
// Potentially add the orphan transaction to the orphan pool.
err := mp.maybeAddOrphan(tx)
if err != nil {
return err
}
}
return nil
}
// Count returns the number of transactions in the main pool. It does not
// include the orphan pool.
//
// This function is safe for concurrent access.
func (mp *txMemPool) Count() int {
mp.RLock()
defer mp.RUnlock()
return len(mp.pool)
}
// TxShas returns a slice of hashes for all of the transactions in the memory
// pool.
//
// This function is safe for concurrent access.
func (mp *txMemPool) TxShas() []*wire.ShaHash {
mp.RLock()
defer mp.RUnlock()
hashes := make([]*wire.ShaHash, len(mp.pool))
i := 0
for hash := range mp.pool {
hashCopy := hash
hashes[i] = &hashCopy
i++
}
return hashes
}
// TxDescs returns a slice of descriptors for all the transactions in the pool.
// The descriptors are to be treated as read only.
//
// This function is safe for concurrent access.
func (mp *txMemPool) TxDescs() []*TxDesc {
mp.RLock()
defer mp.RUnlock()
descs := make([]*TxDesc, len(mp.pool))
i := 0
for _, desc := range mp.pool {
descs[i] = desc
i++
}
return descs
}
// LastUpdated returns the last time a transaction was added to or removed from
// the main pool. It does not include the orphan pool.
//
// This function is safe for concurrent access.
func (mp *txMemPool) LastUpdated() time.Time {
mp.RLock()
defer mp.RUnlock()
return mp.lastUpdated
}
// newTxMemPool returns a new memory pool for validating and storing standalone
// transactions until they are mined into a block.
func newTxMemPool(server *server) *txMemPool {
memPool := &txMemPool{
server: server,
pool: make(map[wire.ShaHash]*TxDesc),
orphans: make(map[wire.ShaHash]*btcutil.Tx),
orphansByPrev: make(map[wire.ShaHash]*list.List),
outpoints: make(map[wire.OutPoint]*btcutil.Tx),
}
if cfg.AddrIndex {
memPool.addrindex = make(map[string]map[wire.ShaHash]struct{})
}
return memPool
}