088f3c923d
This commit introduces two new functions for MsgBlock and MsgTx named Serialize and Deserialize. The functions provide a stable mechanism for serializing and deserializing blocks and transactions to and from disk without having to worry about the protocol version. Instead these functions use the Version fields in the blocks and transactions. These new functions differ from BtcEncode and BtcDecode in that the latter functions are intended to encode/decode blocks and transaction from the wire which technically can differ depending on the protocol version and don't even really need to use the same format as the stored data. Currently, there is no difference between the two, and due to how intertwined they are in the reference implementaiton, they may not ever diverge, but there is a difference and the goal for btcwire is to provide a stable API that is flexible enough to deal with encoding changes.
435 lines
12 KiB
Go
435 lines
12 KiB
Go
// Copyright (c) 2013 Conformal Systems LLC.
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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 btcwire
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import (
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"bytes"
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"io"
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)
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// TxVersion is the current latest supported transaction version.
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const TxVersion = 1
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// MaxTxInSequenceNum is the maximum sequence number the sequence field
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// of a transaction input can be.
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const MaxTxInSequenceNum uint32 = 0xffffffff
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// OutPoint defines a bitcoin data type that is used to track previous
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// transaction outputs.
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type OutPoint struct {
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Hash ShaHash
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Index uint32
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}
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// NewOutPoint returns a new bitcoin transaction outpoint point with the
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// provided hash and index.
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func NewOutPoint(hash *ShaHash, index uint32) *OutPoint {
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return &OutPoint{
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Hash: *hash,
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Index: index,
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}
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}
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// TxIn defines a bitcoin transaction input.
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type TxIn struct {
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PreviousOutpoint OutPoint
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SignatureScript []byte
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Sequence uint32
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}
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// NewTxIn returns a new bitcoin transaction input with the provided
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// previous outpoint point and signature script with a default sequence of
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// MaxTxInSequenceNum.
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func NewTxIn(prevOut *OutPoint, signatureScript []byte) *TxIn {
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return &TxIn{
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PreviousOutpoint: *prevOut,
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SignatureScript: signatureScript,
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Sequence: MaxTxInSequenceNum,
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}
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}
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// TxOut defines a bitcoin transaction output.
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type TxOut struct {
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Value int64
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PkScript []byte
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}
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// NewTxOut returns a new bitcoin transaction output with the provided
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// transaction value and public key script.
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func NewTxOut(value int64, pkScript []byte) *TxOut {
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return &TxOut{
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Value: value,
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PkScript: pkScript,
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}
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}
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// MsgTx implements the Message interface and represents a bitcoin tx message.
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// It is used to deliver transaction information in response to a getdata
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// message (MsgGetData) for a given transaction.
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//
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// Use the AddTxIn and AddTxOut functions to build up the list of transaction
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// inputs and outputs.
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type MsgTx struct {
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Version uint32
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TxIn []*TxIn
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TxOut []*TxOut
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LockTime uint32
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}
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// AddTxIn adds a transaction input to the message.
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func (msg *MsgTx) AddTxIn(ti *TxIn) {
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msg.TxIn = append(msg.TxIn, ti)
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}
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// AddTxOut adds a transaction output to the message.
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func (msg *MsgTx) AddTxOut(to *TxOut) {
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msg.TxOut = append(msg.TxOut, to)
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}
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// TxSha generates the ShaHash name for the transaction.
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func (tx *MsgTx) TxSha(pver uint32) (ShaHash, error) {
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// Encode the transaction and calculate double sha256 on the result.
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// Ignore the error returns since the only way the encode could fail
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// is being out of memory or due to nil pointers, both of which would
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// cause a run-time panic. Also, SetBytes can't fail here due to the
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// fact DoubleSha256 always returns a []byte of the right size
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// regardless of input.
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var buf bytes.Buffer
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var sha ShaHash
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_ = tx.BtcEncode(&buf, pver)
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_ = sha.SetBytes(DoubleSha256(buf.Bytes()))
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// Even though this function can't currently fail, it still returns
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// a potential error to help future proof the API should a failure
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// become possible.
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return sha, nil
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}
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// Copy creates a deep copy of a transaction so that the original does not get
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// modified when the copy is manipulated.
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func (tx *MsgTx) Copy() *MsgTx {
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// Create new tx and start by copying primitive values.
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newTx := MsgTx{
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Version: tx.Version,
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LockTime: tx.LockTime,
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}
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// Deep copy the old TxIn data.
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for _, oldTxIn := range tx.TxIn {
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// Deep copy the old previous outpoint.
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oldOutPoint := oldTxIn.PreviousOutpoint
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newOutPoint := OutPoint{}
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newOutPoint.Hash.SetBytes(oldOutPoint.Hash[:])
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newOutPoint.Index = oldOutPoint.Index
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// Deep copy the old signature script.
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var newScript []byte
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oldScript := oldTxIn.SignatureScript
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oldScriptLen := len(oldScript)
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if oldScriptLen > 0 {
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newScript = make([]byte, oldScriptLen, oldScriptLen)
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copy(newScript, oldScript[:oldScriptLen])
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}
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// Create new txIn with the deep copied data and append it to
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// new Tx.
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newTxIn := TxIn{
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PreviousOutpoint: newOutPoint,
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SignatureScript: newScript,
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Sequence: oldTxIn.Sequence,
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}
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newTx.TxIn = append(newTx.TxIn, &newTxIn)
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}
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// Deep copy the old TxOut data.
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for _, oldTxOut := range tx.TxOut {
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// Deep copy the old PkScript
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var newScript []byte
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oldScript := oldTxOut.PkScript
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oldScriptLen := len(oldScript)
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if oldScriptLen > 0 {
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newScript = make([]byte, oldScriptLen, oldScriptLen)
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copy(newScript, oldScript[:oldScriptLen])
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}
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// Create new txOut with the deep copied data and append it to
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// new Tx.
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newTxOut := TxOut{
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Value: oldTxOut.Value,
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PkScript: newScript,
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}
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newTx.TxOut = append(newTx.TxOut, &newTxOut)
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}
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return &newTx
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}
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// BtcDecode decodes r using the bitcoin protocol encoding into the receiver.
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// This is part of the Message interface implementation.
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// See Deserialize for decoding transactions stored to disk, such as in a
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// database, as opposed to decoding transactions from the wire.
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func (msg *MsgTx) BtcDecode(r io.Reader, pver uint32) error {
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err := readElement(r, &msg.Version)
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if err != nil {
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return err
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}
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count, err := readVarInt(r, pver)
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if err != nil {
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return err
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}
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for i := uint64(0); i < count; i++ {
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ti := TxIn{}
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err = readTxIn(r, pver, msg.Version, &ti)
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if err != nil {
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return err
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}
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msg.TxIn = append(msg.TxIn, &ti)
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}
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count, err = readVarInt(r, pver)
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if err != nil {
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return err
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}
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for i := uint64(0); i < count; i++ {
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to := TxOut{}
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err = readTxOut(r, pver, msg.Version, &to)
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if err != nil {
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return err
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}
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msg.TxOut = append(msg.TxOut, &to)
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}
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err = readElement(r, &msg.LockTime)
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if err != nil {
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return err
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}
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return nil
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}
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// Deserialize decodes a transaction from r into the receiver using a format
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// that is suitable for long-term storage such as a database while respecting
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// the Version field in the transaction. This function differs from BtcDecode
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// in that BtcDecode decodes from the bitcoin wire protocol as it was sent
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// across the network. The wire encoding can technically differ depending on
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// the protocol version and doesn't even really need to match the format of a
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// stored transaction at all. As of the time this comment was written, the
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// encoded transaction is the same in both instances, but there is a distinct
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// difference and separating the two allows the API to be flexible enough to
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// deal with changes.
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func (msg *MsgTx) Deserialize(r io.Reader) error {
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// At the current time, there is no difference between the wire encoding
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// at protocol version 0 and the stable long-term storage format. As
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// a result, make use of BtcDecode.
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return msg.BtcDecode(r, 0)
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}
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// BtcEncode encodes the receiver to w using the bitcoin protocol encoding.
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// This is part of the Message interface implementation.
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// See Serialize for encoding transactions to be stored to disk, such as in a
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// database, as opposed to encoding transactions for the wire.
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func (msg *MsgTx) BtcEncode(w io.Writer, pver uint32) error {
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err := writeElement(w, msg.Version)
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if err != nil {
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return err
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}
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count := uint64(len(msg.TxIn))
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err = writeVarInt(w, pver, count)
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if err != nil {
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return err
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}
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for _, ti := range msg.TxIn {
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err = writeTxIn(w, pver, msg.Version, ti)
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if err != nil {
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return err
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}
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}
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count = uint64(len(msg.TxOut))
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err = writeVarInt(w, pver, count)
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if err != nil {
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return err
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}
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for _, to := range msg.TxOut {
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err = writeTxOut(w, pver, to)
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if err != nil {
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return err
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}
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}
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err = writeElement(w, msg.LockTime)
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if err != nil {
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return err
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}
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return nil
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}
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// Serialize encodes the transaction to w using a format that suitable for
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// long-term storage such as a database while respecting the Version field in
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// the transaction. This function differs from BtcEncode in that BtcEncode
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// encodes the transaction to the bitcoin wire protocol in order to be sent
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// across the network. The wire encoding can technically differ depending on
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// the protocol version and doesn't even really need to match the format of a
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// stored transaction at all. As of the time this comment was written, the
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// encoded transaction is the same in both instances, but there is a distinct
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// difference and separating the two allows the API to be flexible enough to
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// deal with changes.
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func (msg *MsgTx) Serialize(w io.Writer) error {
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// At the current time, there is no difference between the wire encoding
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// at protocol version 0 and the stable long-term storage format. As
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// a result, make use of BtcEncode.
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return msg.BtcEncode(w, 0)
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}
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// Command returns the protocol command string for the message. This is part
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// of the Message interface implementation.
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func (msg *MsgTx) Command() string {
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return cmdTx
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}
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// MaxPayloadLength returns the maximum length the payload can be for the
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// receiver. This is part of the Message interface implementation.
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func (msg *MsgTx) MaxPayloadLength(pver uint32) uint32 {
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return maxMessagePayload
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}
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// NewMsgTx returns a new bitcoin tx message that conforms to the Message
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// interface. The return instance has a default version of TxVersion and there
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// are no transaction inputs or outputs. Also, the lock time is set to zero
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// to indicate the transaction is valid immediately as opposed to some time in
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// future.
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func NewMsgTx() *MsgTx {
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return &MsgTx{Version: TxVersion}
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}
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// readOutPoint reads the next sequence of bytes from r as an OutPoint.
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func readOutPoint(r io.Reader, pver uint32, version uint32, op *OutPoint) error {
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err := readElements(r, &op.Hash, &op.Index)
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if err != nil {
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return err
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}
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return nil
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}
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// writeOutPoint encodes op to the bitcoin protocol encoding for an OutPoint
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// to w.
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func writeOutPoint(w io.Writer, pver uint32, version uint32, op *OutPoint) error {
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err := writeElements(w, op.Hash, op.Index)
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if err != nil {
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return err
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}
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return nil
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}
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// readTxIn reads the next sequence of bytes from r as a transaction input
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// (TxIn).
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func readTxIn(r io.Reader, pver uint32, version uint32, ti *TxIn) error {
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op := OutPoint{}
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err := readOutPoint(r, pver, version, &op)
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if err != nil {
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return err
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}
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ti.PreviousOutpoint = op
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count, err := readVarInt(r, pver)
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if err != nil {
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return err
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}
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b := make([]byte, count)
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err = readElement(r, b)
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if err != nil {
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return err
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}
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ti.SignatureScript = b
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err = readElement(r, &ti.Sequence)
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if err != nil {
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return err
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}
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return nil
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}
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// writeTxIn encodes ti to the bitcoin protocol encoding for a transaction
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// input (TxIn) to w.
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func writeTxIn(w io.Writer, pver uint32, version uint32, ti *TxIn) error {
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err := writeOutPoint(w, pver, version, &ti.PreviousOutpoint)
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if err != nil {
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return err
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}
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slen := uint64(len(ti.SignatureScript))
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err = writeVarInt(w, pver, slen)
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if err != nil {
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return err
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}
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b := []byte(ti.SignatureScript)
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_, err = w.Write(b)
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if err != nil {
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return err
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}
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err = writeElement(w, &ti.Sequence)
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if err != nil {
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return err
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}
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return nil
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}
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// readTxOut reads the next sequence of bytes from r as a transaction output
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// (TxOut).
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func readTxOut(r io.Reader, pver uint32, version uint32, to *TxOut) error {
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err := readElement(r, &to.Value)
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if err != nil {
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return err
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}
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slen, err := readVarInt(r, pver)
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if err != nil {
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return err
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}
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b := make([]byte, slen)
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err = readElement(r, b)
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if err != nil {
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return err
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}
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to.PkScript = b
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return nil
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}
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// writeTxOut encodes to into the bitcoin protocol encoding for a transaction
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// output (TxOut) to w.
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func writeTxOut(w io.Writer, pver uint32, to *TxOut) error {
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err := writeElement(w, to.Value)
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if err != nil {
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return err
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}
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pkLen := uint64(len(to.PkScript))
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err = writeVarInt(w, pver, pkLen)
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if err != nil {
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return err
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}
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err = writeElement(w, to.PkScript)
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if err != nil {
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return err
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}
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return nil
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}
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