7fac099bee
This does the minimum work necessary to refactor the mempool code into its own package. The idea is that separating this code into its own package will greatly improve its testability, allow independent benchmarking and profiling, and open up some interesting opportunities for future development related to the memory pool. There are likely some areas related to policy that could be further refactored, however it is better to do that in future commits in order to keep the changeset as small as possible during this refactor. Overview of the major changes: - Create the new package - Move several files into the new package: - mempool.go -> mempool/mempool.go - mempoolerror.go -> mempool/error.go - policy.go -> mempool/policy.go - policy_test.go -> mempool/policy_test.go - Update mempool logging to use the new mempool package logger - Rename mempoolPolicy to Policy (so it's now mempool.Policy) - Rename mempoolConfig to Config (so it's now mempool.Config) - Rename mempoolTxDesc to TxDesc (so it's now mempool.TxDesc) - Rename txMemPool to TxPool (so it's now mempool.TxPool) - Move defaultBlockPrioritySize to the new package and export it - Export DefaultMinRelayTxFee from the mempool package - Export the CalcPriority function from the mempool package - Introduce a new RawMempoolVerbose function on the TxPool and update the RPC server to use it - Update all references to the mempool to use the package. - Add a skeleton README.md
430 lines
17 KiB
Go
430 lines
17 KiB
Go
// Copyright (c) 2013-2016 The btcsuite developers
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// Use of this source code is governed by an ISC
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// license that can be found in the LICENSE file.
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package mempool
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import (
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"fmt"
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"github.com/btcsuite/btcd/blockchain"
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"github.com/btcsuite/btcd/txscript"
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"github.com/btcsuite/btcd/wire"
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"github.com/btcsuite/btcutil"
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)
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const (
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// maxStandardTxSize is the maximum size allowed for transactions that
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// are considered standard and will therefore be relayed and considered
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// for mining.
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maxStandardTxSize = 100000
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// maxStandardSigScriptSize is the maximum size allowed for a
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// transaction input signature script to be considered standard. This
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// value allows for a 15-of-15 CHECKMULTISIG pay-to-script-hash with
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// compressed keys.
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//
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// The form of the overall script is: OP_0 <15 signatures> OP_PUSHDATA2
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// <2 bytes len> [OP_15 <15 pubkeys> OP_15 OP_CHECKMULTISIG]
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//
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// For the p2sh script portion, each of the 15 compressed pubkeys are
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// 33 bytes (plus one for the OP_DATA_33 opcode), and the thus it totals
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// to (15*34)+3 = 513 bytes. Next, each of the 15 signatures is a max
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// of 73 bytes (plus one for the OP_DATA_73 opcode). Also, there is one
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// extra byte for the initial extra OP_0 push and 3 bytes for the
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// OP_PUSHDATA2 needed to specify the 513 bytes for the script push.
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// That brings the total to 1+(15*74)+3+513 = 1627. This value also
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// adds a few extra bytes to provide a little buffer.
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// (1 + 15*74 + 3) + (15*34 + 3) + 23 = 1650
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maxStandardSigScriptSize = 1650
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// DefaultMinRelayTxFee is the minimum fee in satoshi that is required
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// for a transaction to be treated as free for relay and mining
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// purposes. It is also used to help determine if a transaction is
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// considered dust and as a base for calculating minimum required fees
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// for larger transactions. This value is in Satoshi/1000 bytes.
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DefaultMinRelayTxFee = btcutil.Amount(1000)
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// maxStandardMultiSigKeys is the maximum number of public keys allowed
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// in a multi-signature transaction output script for it to be
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// considered standard.
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maxStandardMultiSigKeys = 3
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)
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// calcMinRequiredTxRelayFee returns the minimum transaction fee required for a
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// transaction with the passed serialized size to be accepted into the memory
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// pool and relayed.
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func calcMinRequiredTxRelayFee(serializedSize int64, minRelayTxFee btcutil.Amount) int64 {
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// Calculate the minimum fee for a transaction to be allowed into the
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// mempool and relayed by scaling the base fee (which is the minimum
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// free transaction relay fee). minTxRelayFee is in Satoshi/kB so
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// multiply by serializedSize (which is in bytes) and divide by 1000 to
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// get minimum Satoshis.
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minFee := (serializedSize * int64(minRelayTxFee)) / 1000
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if minFee == 0 && minRelayTxFee > 0 {
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minFee = int64(minRelayTxFee)
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}
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// Set the minimum fee to the maximum possible value if the calculated
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// fee is not in the valid range for monetary amounts.
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if minFee < 0 || minFee > btcutil.MaxSatoshi {
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minFee = btcutil.MaxSatoshi
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}
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return minFee
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}
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// CalcPriority returns a transaction priority given a transaction and the sum
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// of each of its input values multiplied by their age (# of confirmations).
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// Thus, the final formula for the priority is:
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// sum(inputValue * inputAge) / adjustedTxSize
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func CalcPriority(tx *wire.MsgTx, utxoView *blockchain.UtxoViewpoint, nextBlockHeight int32) float64 {
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// In order to encourage spending multiple old unspent transaction
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// outputs thereby reducing the total set, don't count the constant
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// overhead for each input as well as enough bytes of the signature
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// script to cover a pay-to-script-hash redemption with a compressed
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// pubkey. This makes additional inputs free by boosting the priority
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// of the transaction accordingly. No more incentive is given to avoid
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// encouraging gaming future transactions through the use of junk
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// outputs. This is the same logic used in the reference
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// implementation.
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//
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// The constant overhead for a txin is 41 bytes since the previous
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// outpoint is 36 bytes + 4 bytes for the sequence + 1 byte the
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// signature script length.
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//
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// A compressed pubkey pay-to-script-hash redemption with a maximum len
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// signature is of the form:
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// [OP_DATA_73 <73-byte sig> + OP_DATA_35 + {OP_DATA_33
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// <33 byte compresed pubkey> + OP_CHECKSIG}]
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//
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// Thus 1 + 73 + 1 + 1 + 33 + 1 = 110
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overhead := 0
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for _, txIn := range tx.TxIn {
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// Max inputs + size can't possibly overflow here.
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overhead += 41 + minInt(110, len(txIn.SignatureScript))
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}
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serializedTxSize := tx.SerializeSize()
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if overhead >= serializedTxSize {
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return 0.0
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}
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inputValueAge := calcInputValueAge(tx, utxoView, nextBlockHeight)
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return inputValueAge / float64(serializedTxSize-overhead)
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}
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// calcInputValueAge is a helper function used to calculate the input age of
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// a transaction. The input age for a txin is the number of confirmations
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// since the referenced txout multiplied by its output value. The total input
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// age is the sum of this value for each txin. Any inputs to the transaction
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// which are currently in the mempool and hence not mined into a block yet,
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// contribute no additional input age to the transaction.
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func calcInputValueAge(tx *wire.MsgTx, utxoView *blockchain.UtxoViewpoint, nextBlockHeight int32) float64 {
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var totalInputAge float64
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for _, txIn := range tx.TxIn {
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// Don't attempt to accumulate the total input age if the
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// referenced transaction output doesn't exist.
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originHash := &txIn.PreviousOutPoint.Hash
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originIndex := txIn.PreviousOutPoint.Index
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txEntry := utxoView.LookupEntry(originHash)
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if txEntry != nil && !txEntry.IsOutputSpent(originIndex) {
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// Inputs with dependencies currently in the mempool
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// have their block height set to a special constant.
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// Their input age should be computed as zero since
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// their parent hasn't made it into a block yet.
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var inputAge int32
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originHeight := txEntry.BlockHeight()
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if originHeight == mempoolHeight {
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inputAge = 0
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} else {
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inputAge = nextBlockHeight - originHeight
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}
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// Sum the input value times age.
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inputValue := txEntry.AmountByIndex(originIndex)
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totalInputAge += float64(inputValue * int64(inputAge))
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}
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}
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return totalInputAge
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}
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// checkInputsStandard performs a series of checks on a transaction's inputs
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// to ensure they are "standard". A standard transaction input is one that
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// that consumes the expected number of elements from the stack and that number
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// is the same as the output script pushes. This help prevent resource
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// exhaustion attacks by "creative" use of scripts that are super expensive to
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// process like OP_DUP OP_CHECKSIG OP_DROP repeated a large number of times
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// followed by a final OP_TRUE.
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func checkInputsStandard(tx *btcutil.Tx, utxoView *blockchain.UtxoViewpoint) error {
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// NOTE: The reference implementation also does a coinbase check here,
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// but coinbases have already been rejected prior to calling this
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// function so no need to recheck.
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for i, txIn := range tx.MsgTx().TxIn {
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// It is safe to elide existence and index checks here since
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// they have already been checked prior to calling this
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// function.
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prevOut := txIn.PreviousOutPoint
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entry := utxoView.LookupEntry(&prevOut.Hash)
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originPkScript := entry.PkScriptByIndex(prevOut.Index)
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// Calculate stats for the script pair.
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scriptInfo, err := txscript.CalcScriptInfo(txIn.SignatureScript,
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originPkScript, true)
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if err != nil {
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str := fmt.Sprintf("transaction input #%d script parse "+
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"failure: %v", i, err)
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return txRuleError(wire.RejectNonstandard, str)
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}
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// A negative value for expected inputs indicates the script is
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// non-standard in some way.
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if scriptInfo.ExpectedInputs < 0 {
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str := fmt.Sprintf("transaction input #%d expects %d "+
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"inputs", i, scriptInfo.ExpectedInputs)
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return txRuleError(wire.RejectNonstandard, str)
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}
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// The script pair is non-standard if the number of available
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// inputs does not match the number of expected inputs.
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if scriptInfo.NumInputs != scriptInfo.ExpectedInputs {
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str := fmt.Sprintf("transaction input #%d expects %d "+
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"inputs, but referenced output script provides "+
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"%d", i, scriptInfo.ExpectedInputs,
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scriptInfo.NumInputs)
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return txRuleError(wire.RejectNonstandard, str)
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}
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}
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return nil
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}
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// checkPkScriptStandard performs a series of checks on a transaction output
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// script (public key script) to ensure it is a "standard" public key script.
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// A standard public key script is one that is a recognized form, and for
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// multi-signature scripts, only contains from 1 to maxStandardMultiSigKeys
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// public keys.
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func checkPkScriptStandard(pkScript []byte, scriptClass txscript.ScriptClass) error {
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switch scriptClass {
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case txscript.MultiSigTy:
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numPubKeys, numSigs, err := txscript.CalcMultiSigStats(pkScript)
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if err != nil {
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str := fmt.Sprintf("multi-signature script parse "+
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"failure: %v", err)
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return txRuleError(wire.RejectNonstandard, str)
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}
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// A standard multi-signature public key script must contain
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// from 1 to maxStandardMultiSigKeys public keys.
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if numPubKeys < 1 {
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str := "multi-signature script with no pubkeys"
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return txRuleError(wire.RejectNonstandard, str)
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}
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if numPubKeys > maxStandardMultiSigKeys {
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str := fmt.Sprintf("multi-signature script with %d "+
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"public keys which is more than the allowed "+
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"max of %d", numPubKeys, maxStandardMultiSigKeys)
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return txRuleError(wire.RejectNonstandard, str)
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}
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// A standard multi-signature public key script must have at
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// least 1 signature and no more signatures than available
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// public keys.
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if numSigs < 1 {
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return txRuleError(wire.RejectNonstandard,
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"multi-signature script with no signatures")
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}
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if numSigs > numPubKeys {
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str := fmt.Sprintf("multi-signature script with %d "+
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"signatures which is more than the available "+
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"%d public keys", numSigs, numPubKeys)
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return txRuleError(wire.RejectNonstandard, str)
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}
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case txscript.NonStandardTy:
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return txRuleError(wire.RejectNonstandard,
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"non-standard script form")
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}
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return nil
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}
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// isDust returns whether or not the passed transaction output amount is
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// considered dust or not based on the passed minimum transaction relay fee.
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// Dust is defined in terms of the minimum transaction relay fee. In
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// particular, if the cost to the network to spend coins is more than 1/3 of the
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// minimum transaction relay fee, it is considered dust.
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func isDust(txOut *wire.TxOut, minRelayTxFee btcutil.Amount) bool {
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// Unspendable outputs are considered dust.
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if txscript.IsUnspendable(txOut.PkScript) {
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return true
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}
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// The total serialized size consists of the output and the associated
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// input script to redeem it. Since there is no input script
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// to redeem it yet, use the minimum size of a typical input script.
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//
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// Pay-to-pubkey-hash bytes breakdown:
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//
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// Output to hash (34 bytes):
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// 8 value, 1 script len, 25 script [1 OP_DUP, 1 OP_HASH_160,
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// 1 OP_DATA_20, 20 hash, 1 OP_EQUALVERIFY, 1 OP_CHECKSIG]
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//
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// Input with compressed pubkey (148 bytes):
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// 36 prev outpoint, 1 script len, 107 script [1 OP_DATA_72, 72 sig,
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// 1 OP_DATA_33, 33 compressed pubkey], 4 sequence
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//
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// Input with uncompressed pubkey (180 bytes):
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// 36 prev outpoint, 1 script len, 139 script [1 OP_DATA_72, 72 sig,
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// 1 OP_DATA_65, 65 compressed pubkey], 4 sequence
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//
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// Pay-to-pubkey bytes breakdown:
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//
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// Output to compressed pubkey (44 bytes):
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// 8 value, 1 script len, 35 script [1 OP_DATA_33,
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// 33 compressed pubkey, 1 OP_CHECKSIG]
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//
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// Output to uncompressed pubkey (76 bytes):
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// 8 value, 1 script len, 67 script [1 OP_DATA_65, 65 pubkey,
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// 1 OP_CHECKSIG]
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//
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// Input (114 bytes):
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// 36 prev outpoint, 1 script len, 73 script [1 OP_DATA_72,
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// 72 sig], 4 sequence
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//
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// Theoretically this could examine the script type of the output script
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// and use a different size for the typical input script size for
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// pay-to-pubkey vs pay-to-pubkey-hash inputs per the above breakdowns,
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// but the only combinination which is less than the value chosen is
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// a pay-to-pubkey script with a compressed pubkey, which is not very
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// common.
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//
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// The most common scripts are pay-to-pubkey-hash, and as per the above
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// breakdown, the minimum size of a p2pkh input script is 148 bytes. So
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// that figure is used.
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totalSize := txOut.SerializeSize() + 148
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// The output is considered dust if the cost to the network to spend the
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// coins is more than 1/3 of the minimum free transaction relay fee.
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// minFreeTxRelayFee is in Satoshi/KB, so multiply by 1000 to
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// convert to bytes.
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//
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// Using the typical values for a pay-to-pubkey-hash transaction from
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// the breakdown above and the default minimum free transaction relay
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// fee of 1000, this equates to values less than 546 satoshi being
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// considered dust.
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//
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// The following is equivalent to (value/totalSize) * (1/3) * 1000
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// without needing to do floating point math.
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return txOut.Value*1000/(3*int64(totalSize)) < int64(minRelayTxFee)
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}
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// checkTransactionStandard performs a series of checks on a transaction to
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// ensure it is a "standard" transaction. A standard transaction is one that
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// conforms to several additional limiting cases over what is considered a
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// "sane" transaction such as having a version in the supported range, being
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// finalized, conforming to more stringent size constraints, having scripts
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// of recognized forms, and not containing "dust" outputs (those that are
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// so small it costs more to process them than they are worth).
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func checkTransactionStandard(tx *btcutil.Tx, height int32, timeSource blockchain.MedianTimeSource, minRelayTxFee btcutil.Amount) error {
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// The transaction must be a currently supported version.
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msgTx := tx.MsgTx()
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if msgTx.Version > wire.TxVersion || msgTx.Version < 1 {
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str := fmt.Sprintf("transaction version %d is not in the "+
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"valid range of %d-%d", msgTx.Version, 1,
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wire.TxVersion)
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return txRuleError(wire.RejectNonstandard, str)
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}
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// The transaction must be finalized to be standard and therefore
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// considered for inclusion in a block.
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adjustedTime := timeSource.AdjustedTime()
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if !blockchain.IsFinalizedTransaction(tx, height, adjustedTime) {
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return txRuleError(wire.RejectNonstandard,
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"transaction is not finalized")
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}
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// Since extremely large transactions with a lot of inputs can cost
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// almost as much to process as the sender fees, limit the maximum
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// size of a transaction. This also helps mitigate CPU exhaustion
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// attacks.
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serializedLen := msgTx.SerializeSize()
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if serializedLen > maxStandardTxSize {
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str := fmt.Sprintf("transaction size of %v is larger than max "+
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"allowed size of %v", serializedLen, maxStandardTxSize)
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return txRuleError(wire.RejectNonstandard, str)
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}
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for i, txIn := range msgTx.TxIn {
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// Each transaction input signature script must not exceed the
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// maximum size allowed for a standard transaction. See
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// the comment on maxStandardSigScriptSize for more details.
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sigScriptLen := len(txIn.SignatureScript)
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if sigScriptLen > maxStandardSigScriptSize {
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str := fmt.Sprintf("transaction input %d: signature "+
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"script size of %d bytes is large than max "+
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"allowed size of %d bytes", i, sigScriptLen,
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maxStandardSigScriptSize)
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return txRuleError(wire.RejectNonstandard, str)
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}
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// Each transaction input signature script must only contain
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// opcodes which push data onto the stack.
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if !txscript.IsPushOnlyScript(txIn.SignatureScript) {
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str := fmt.Sprintf("transaction input %d: signature "+
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"script is not push only", i)
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return txRuleError(wire.RejectNonstandard, str)
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}
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}
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// None of the output public key scripts can be a non-standard script or
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// be "dust" (except when the script is a null data script).
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numNullDataOutputs := 0
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for i, txOut := range msgTx.TxOut {
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scriptClass := txscript.GetScriptClass(txOut.PkScript)
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err := checkPkScriptStandard(txOut.PkScript, scriptClass)
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if err != nil {
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// Attempt to extract a reject code from the error so
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// it can be retained. When not possible, fall back to
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// a non standard error.
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rejectCode := wire.RejectNonstandard
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if rejCode, found := extractRejectCode(err); found {
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rejectCode = rejCode
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}
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str := fmt.Sprintf("transaction output %d: %v", i, err)
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return txRuleError(rejectCode, str)
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}
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// Accumulate the number of outputs which only carry data. For
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// all other script types, ensure the output value is not
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// "dust".
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if scriptClass == txscript.NullDataTy {
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numNullDataOutputs++
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} else if isDust(txOut, minRelayTxFee) {
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str := fmt.Sprintf("transaction output %d: payment "+
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"of %d is dust", i, txOut.Value)
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return txRuleError(wire.RejectDust, str)
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}
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}
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// A standard transaction must not have more than one output script that
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// only carries data.
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if numNullDataOutputs > 1 {
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str := "more than one transaction output in a nulldata script"
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return txRuleError(wire.RejectNonstandard, str)
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}
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return nil
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}
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// minInt is a helper function to return the minimum of two ints. This avoids
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// a math import and the need to cast to floats.
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func minInt(a, b int) int {
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if a < b {
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return a
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}
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return b
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}
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