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320 lines
12 KiB
320 lines
12 KiB
9 years ago
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// Copyright (c) 2013-2014 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 blockchain
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import (
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"fmt"
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"github.com/btcsuite/btcd/database"
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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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// TxData contains contextual information about transactions such as which block
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// they were found in and whether or not the outputs are spent.
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type TxData struct {
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Tx *btcutil.Tx
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Hash *wire.ShaHash
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BlockHeight int64
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Spent []bool
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Err error
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}
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// TxStore is used to store transactions needed by other transactions for things
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// such as script validation and double spend prevention. This also allows the
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// transaction data to be treated as a view since it can contain the information
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// from the point-of-view of different points in the chain.
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type TxStore map[wire.ShaHash]*TxData
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// connectTransactions updates the passed map by applying transaction and
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// spend information for all the transactions in the passed block. Only
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// transactions in the passed map are updated.
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func connectTransactions(txStore TxStore, block *btcutil.Block) error {
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// Loop through all of the transactions in the block to see if any of
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// them are ones we need to update and spend based on the results map.
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for _, tx := range block.Transactions() {
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// Update the transaction store with the transaction information
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// if it's one of the requested transactions.
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msgTx := tx.MsgTx()
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if txD, exists := txStore[*tx.Sha()]; exists {
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txD.Tx = tx
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txD.BlockHeight = block.Height()
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txD.Spent = make([]bool, len(msgTx.TxOut))
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txD.Err = nil
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}
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// Spend the origin transaction output.
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for _, txIn := range msgTx.TxIn {
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originHash := &txIn.PreviousOutPoint.Hash
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originIndex := txIn.PreviousOutPoint.Index
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if originTx, exists := txStore[*originHash]; exists {
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if originIndex > uint32(len(originTx.Spent)) {
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continue
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}
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originTx.Spent[originIndex] = true
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}
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}
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}
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return nil
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}
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// disconnectTransactions updates the passed map by undoing transaction and
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// spend information for all transactions in the passed block. Only
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// transactions in the passed map are updated.
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func disconnectTransactions(txStore TxStore, block *btcutil.Block) error {
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// Loop through all of the transactions in the block to see if any of
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// them are ones that need to be undone based on the transaction store.
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for _, tx := range block.Transactions() {
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// Clear this transaction from the transaction store if needed.
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// Only clear it rather than deleting it because the transaction
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// connect code relies on its presence to decide whether or not
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// to update the store and any transactions which exist on both
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// sides of a fork would otherwise not be updated.
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if txD, exists := txStore[*tx.Sha()]; exists {
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txD.Tx = nil
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txD.BlockHeight = 0
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txD.Spent = nil
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txD.Err = database.ErrTxShaMissing
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}
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// Unspend the origin transaction output.
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for _, txIn := range tx.MsgTx().TxIn {
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originHash := &txIn.PreviousOutPoint.Hash
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originIndex := txIn.PreviousOutPoint.Index
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originTx, exists := txStore[*originHash]
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if exists && originTx.Tx != nil && originTx.Err == nil {
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if originIndex > uint32(len(originTx.Spent)) {
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continue
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}
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originTx.Spent[originIndex] = false
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}
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}
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}
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return nil
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}
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// fetchTxStoreMain fetches transaction data about the provided set of
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// transactions from the point of view of the end of the main chain. It takes
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// a flag which specifies whether or not fully spent transaction should be
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// included in the results.
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func fetchTxStoreMain(db database.Db, txSet map[wire.ShaHash]struct{}, includeSpent bool) TxStore {
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// Just return an empty store now if there are no requested hashes.
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txStore := make(TxStore)
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if len(txSet) == 0 {
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return txStore
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}
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// The transaction store map needs to have an entry for every requested
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// transaction. By default, all the transactions are marked as missing.
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// Each entry will be filled in with the appropriate data below.
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txList := make([]*wire.ShaHash, 0, len(txSet))
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for hash := range txSet {
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hashCopy := hash
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txStore[hash] = &TxData{Hash: &hashCopy, Err: database.ErrTxShaMissing}
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txList = append(txList, &hashCopy)
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}
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// Ask the database (main chain) for the list of transactions. This
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// will return the information from the point of view of the end of the
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// main chain. Choose whether or not to include fully spent
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// transactions depending on the passed flag.
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var txReplyList []*database.TxListReply
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if includeSpent {
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txReplyList = db.FetchTxByShaList(txList)
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} else {
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txReplyList = db.FetchUnSpentTxByShaList(txList)
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}
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for _, txReply := range txReplyList {
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// Lookup the existing results entry to modify. Skip
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// this reply if there is no corresponding entry in
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// the transaction store map which really should not happen, but
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// be safe.
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txD, ok := txStore[*txReply.Sha]
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if !ok {
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continue
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}
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// Fill in the transaction details. A copy is used here since
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// there is no guarantee the returned data isn't cached and
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// this code modifies the data. A bug caused by modifying the
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// cached data would likely be difficult to track down and could
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// cause subtle errors, so avoid the potential altogether.
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txD.Err = txReply.Err
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if txReply.Err == nil {
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txD.Tx = btcutil.NewTx(txReply.Tx)
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txD.BlockHeight = txReply.Height
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txD.Spent = make([]bool, len(txReply.TxSpent))
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copy(txD.Spent, txReply.TxSpent)
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}
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}
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return txStore
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}
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// fetchTxStore fetches transaction data about the provided set of transactions
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// from the point of view of the given node. For example, a given node might
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// be down a side chain where a transaction hasn't been spent from its point of
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// view even though it might have been spent in the main chain (or another side
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// chain). Another scenario is where a transaction exists from the point of
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// view of the main chain, but doesn't exist in a side chain that branches
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// before the block that contains the transaction on the main chain.
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func (b *BlockChain) fetchTxStore(node *blockNode, txSet map[wire.ShaHash]struct{}) (TxStore, error) {
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// Get the previous block node. This function is used over simply
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// accessing node.parent directly as it will dynamically create previous
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// block nodes as needed. This helps allow only the pieces of the chain
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// that are needed to remain in memory.
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prevNode, err := b.getPrevNodeFromNode(node)
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if err != nil {
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return nil, err
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}
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// If we haven't selected a best chain yet or we are extending the main
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// (best) chain with a new block, fetch the requested set from the point
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// of view of the end of the main (best) chain without including fully
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// spent transactions in the results. This is a little more efficient
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// since it means less transaction lookups are needed.
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if b.bestChain == nil || (prevNode != nil && prevNode.hash.IsEqual(b.bestChain.hash)) {
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txStore := fetchTxStoreMain(b.db, txSet, false)
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return txStore, nil
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}
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// Fetch the requested set from the point of view of the end of the
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// main (best) chain including fully spent transactions. The fully
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// spent transactions are needed because the following code unspends
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// them to get the correct point of view.
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txStore := fetchTxStoreMain(b.db, txSet, true)
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// The requested node is either on a side chain or is a node on the main
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// chain before the end of it. In either case, we need to undo the
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// transactions and spend information for the blocks which would be
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// disconnected during a reorganize to the point of view of the
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// node just before the requested node.
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detachNodes, attachNodes := b.getReorganizeNodes(prevNode)
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for e := detachNodes.Front(); e != nil; e = e.Next() {
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n := e.Value.(*blockNode)
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block, err := b.db.FetchBlockBySha(n.hash)
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if err != nil {
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return nil, err
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}
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disconnectTransactions(txStore, block)
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}
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// The transaction store is now accurate to either the node where the
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// requested node forks off the main chain (in the case where the
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// requested node is on a side chain), or the requested node itself if
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// the requested node is an old node on the main chain. Entries in the
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// attachNodes list indicate the requested node is on a side chain, so
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// if there are no nodes to attach, we're done.
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if attachNodes.Len() == 0 {
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return txStore, nil
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}
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// The requested node is on a side chain, so we need to apply the
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// transactions and spend information from each of the nodes to attach.
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for e := attachNodes.Front(); e != nil; e = e.Next() {
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n := e.Value.(*blockNode)
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block, exists := b.blockCache[*n.hash]
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if !exists {
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return nil, fmt.Errorf("unable to find block %v in "+
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"side chain cache for transaction search",
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n.hash)
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}
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connectTransactions(txStore, block)
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}
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return txStore, nil
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}
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// fetchInputTransactions fetches the input transactions referenced by the
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// transactions in the given block from its point of view. See fetchTxList
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// for more details on what the point of view entails.
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func (b *BlockChain) fetchInputTransactions(node *blockNode, block *btcutil.Block) (TxStore, error) {
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// Build a map of in-flight transactions because some of the inputs in
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// this block could be referencing other transactions earlier in this
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// block which are not yet in the chain.
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txInFlight := map[wire.ShaHash]int{}
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transactions := block.Transactions()
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for i, tx := range transactions {
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txInFlight[*tx.Sha()] = i
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}
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// Loop through all of the transaction inputs (except for the coinbase
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// which has no inputs) collecting them into sets of what is needed and
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// what is already known (in-flight).
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txNeededSet := make(map[wire.ShaHash]struct{})
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txStore := make(TxStore)
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for i, tx := range transactions[1:] {
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for _, txIn := range tx.MsgTx().TxIn {
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// Add an entry to the transaction store for the needed
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// transaction with it set to missing by default.
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originHash := &txIn.PreviousOutPoint.Hash
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txD := &TxData{Hash: originHash, Err: database.ErrTxShaMissing}
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txStore[*originHash] = txD
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// It is acceptable for a transaction input to reference
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// the output of another transaction in this block only
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// if the referenced transaction comes before the
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// current one in this block. Update the transaction
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// store acccordingly when this is the case. Otherwise,
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// we still need the transaction.
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//
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// NOTE: The >= is correct here because i is one less
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// than the actual position of the transaction within
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// the block due to skipping the coinbase.
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if inFlightIndex, ok := txInFlight[*originHash]; ok &&
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i >= inFlightIndex {
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originTx := transactions[inFlightIndex]
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txD.Tx = originTx
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txD.BlockHeight = node.height
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txD.Spent = make([]bool, len(originTx.MsgTx().TxOut))
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txD.Err = nil
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} else {
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txNeededSet[*originHash] = struct{}{}
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}
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}
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}
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// Request the input transactions from the point of view of the node.
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txNeededStore, err := b.fetchTxStore(node, txNeededSet)
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if err != nil {
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return nil, err
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}
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// Merge the results of the requested transactions and the in-flight
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// transactions.
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for _, txD := range txNeededStore {
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txStore[*txD.Hash] = txD
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}
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return txStore, nil
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}
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// FetchTransactionStore fetches the input transactions referenced by the
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// passed transaction from the point of view of the end of the main chain. It
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// also attempts to fetch the transaction itself so the returned TxStore can be
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// examined for duplicate transactions.
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func (b *BlockChain) FetchTransactionStore(tx *btcutil.Tx) (TxStore, error) {
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// Create a set of needed transactions from the transactions referenced
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// by the inputs of the passed transaction. Also, add the passed
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// transaction itself as a way for the caller to detect duplicates.
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txNeededSet := make(map[wire.ShaHash]struct{})
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txNeededSet[*tx.Sha()] = struct{}{}
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for _, txIn := range tx.MsgTx().TxIn {
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txNeededSet[txIn.PreviousOutPoint.Hash] = struct{}{}
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}
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// Request the input transactions from the point of view of the end of
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// the main chain without including fully spent trasactions in the
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// results. Fully spent transactions are only needed for chain
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// reorganization which does not apply here.
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txStore := fetchTxStoreMain(b.db, txNeededSet, false)
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return txStore, nil
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}
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