lbcd/blockchain/utxoviewpoint.go

612 lines
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blockchain: Rework to use new db interface. This commit is the first stage of several that are planned to convert the blockchain package into a concurrent safe package that will ultimately allow support for multi-peer download and concurrent chain processing. The goal is to update btcd proper after each step so it can take advantage of the enhancements as they are developed. In addition to the aforementioned benefit, this staged approach has been chosen since it is absolutely critical to maintain consensus. Separating the changes into several stages makes it easier for reviewers to logically follow what is happening and therefore helps prevent consensus bugs. Naturally there are significant automated tests to help prevent consensus issues as well. The main focus of this stage is to convert the blockchain package to use the new database interface and implement the chain-related functionality which it no longer handles. It also aims to improve efficiency in various areas by making use of the new database and chain capabilities. The following is an overview of the chain changes: - Update to use the new database interface - Add chain-related functionality that the old database used to handle - Main chain structure and state - Transaction spend tracking - Implement a new pruned unspent transaction output (utxo) set - Provides efficient direct access to the unspent transaction outputs - Uses a domain specific compression algorithm that understands the standard transaction scripts in order to significantly compress them - Removes reliance on the transaction index and paves the way toward eventually enabling block pruning - Modify the New function to accept a Config struct instead of inidividual parameters - Replace the old TxStore type with a new UtxoViewpoint type that makes use of the new pruned utxo set - Convert code to treat the new UtxoViewpoint as a rolling view that is used between connects and disconnects to improve efficiency - Make best chain state always set when the chain instance is created - Remove now unnecessary logic for dealing with unset best state - Make all exported functions concurrent safe - Currently using a single chain state lock as it provides a straight forward and easy to review path forward however this can be improved with more fine grained locking - Optimize various cases where full blocks were being loaded when only the header is needed to help reduce the I/O load - Add the ability for callers to get a snapshot of the current best chain stats in a concurrent safe fashion - Does not block callers while new blocks are being processed - Make error messages that reference transaction outputs consistently use <transaction hash>:<output index> - Introduce a new AssertError type an convert internal consistency checks to use it - Update tests and examples to reflect the changes - Add a full suite of tests to ensure correct functionality of the new code The following is an overview of the btcd changes: - Update to use the new database and chain interfaces - Temporarily remove all code related to the transaction index - Temporarily remove all code related to the address index - Convert all code that uses transaction stores to use the new utxo view - Rework several calls that required the block manager for safe concurrency to use the chain package directly now that it is concurrent safe - Change all calls to obtain the best hash to use the new best state snapshot capability from the chain package - Remove workaround for limits on fetching height ranges since the new database interface no longer imposes them - Correct the gettxout RPC handler to return the best chain hash as opposed the hash the txout was found in - Optimize various RPC handlers: - Change several of the RPC handlers to use the new chain snapshot capability to avoid needlessly loading data - Update several handlers to use new functionality to avoid accessing the block manager so they are able to return the data without blocking when the server is busy processing blocks - Update non-verbose getblock to avoid deserialization and serialization overhead - Update getblockheader to request the block height directly from chain and only load the header - Update getdifficulty to use the new cached data from chain - Update getmininginfo to use the new cached data from chain - Update non-verbose getrawtransaction to avoid deserialization and serialization overhead - Update gettxout to use the new utxo store versus loading full transactions using the transaction index The following is an overview of the utility changes: - Update addblock to use the new database and chain interfaces - Update findcheckpoint to use the new database and chain interfaces - Remove the dropafter utility which is no longer supported NOTE: The transaction index and address index will be reimplemented in another commit.
2015-08-26 06:03:18 +02:00
// Copyright (c) 2015-2016 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package blockchain
import (
"fmt"
"github.com/btcsuite/btcd/database"
blockchain: Rework to use new db interface. This commit is the first stage of several that are planned to convert the blockchain package into a concurrent safe package that will ultimately allow support for multi-peer download and concurrent chain processing. The goal is to update btcd proper after each step so it can take advantage of the enhancements as they are developed. In addition to the aforementioned benefit, this staged approach has been chosen since it is absolutely critical to maintain consensus. Separating the changes into several stages makes it easier for reviewers to logically follow what is happening and therefore helps prevent consensus bugs. Naturally there are significant automated tests to help prevent consensus issues as well. The main focus of this stage is to convert the blockchain package to use the new database interface and implement the chain-related functionality which it no longer handles. It also aims to improve efficiency in various areas by making use of the new database and chain capabilities. The following is an overview of the chain changes: - Update to use the new database interface - Add chain-related functionality that the old database used to handle - Main chain structure and state - Transaction spend tracking - Implement a new pruned unspent transaction output (utxo) set - Provides efficient direct access to the unspent transaction outputs - Uses a domain specific compression algorithm that understands the standard transaction scripts in order to significantly compress them - Removes reliance on the transaction index and paves the way toward eventually enabling block pruning - Modify the New function to accept a Config struct instead of inidividual parameters - Replace the old TxStore type with a new UtxoViewpoint type that makes use of the new pruned utxo set - Convert code to treat the new UtxoViewpoint as a rolling view that is used between connects and disconnects to improve efficiency - Make best chain state always set when the chain instance is created - Remove now unnecessary logic for dealing with unset best state - Make all exported functions concurrent safe - Currently using a single chain state lock as it provides a straight forward and easy to review path forward however this can be improved with more fine grained locking - Optimize various cases where full blocks were being loaded when only the header is needed to help reduce the I/O load - Add the ability for callers to get a snapshot of the current best chain stats in a concurrent safe fashion - Does not block callers while new blocks are being processed - Make error messages that reference transaction outputs consistently use <transaction hash>:<output index> - Introduce a new AssertError type an convert internal consistency checks to use it - Update tests and examples to reflect the changes - Add a full suite of tests to ensure correct functionality of the new code The following is an overview of the btcd changes: - Update to use the new database and chain interfaces - Temporarily remove all code related to the transaction index - Temporarily remove all code related to the address index - Convert all code that uses transaction stores to use the new utxo view - Rework several calls that required the block manager for safe concurrency to use the chain package directly now that it is concurrent safe - Change all calls to obtain the best hash to use the new best state snapshot capability from the chain package - Remove workaround for limits on fetching height ranges since the new database interface no longer imposes them - Correct the gettxout RPC handler to return the best chain hash as opposed the hash the txout was found in - Optimize various RPC handlers: - Change several of the RPC handlers to use the new chain snapshot capability to avoid needlessly loading data - Update several handlers to use new functionality to avoid accessing the block manager so they are able to return the data without blocking when the server is busy processing blocks - Update non-verbose getblock to avoid deserialization and serialization overhead - Update getblockheader to request the block height directly from chain and only load the header - Update getdifficulty to use the new cached data from chain - Update getmininginfo to use the new cached data from chain - Update non-verbose getrawtransaction to avoid deserialization and serialization overhead - Update gettxout to use the new utxo store versus loading full transactions using the transaction index The following is an overview of the utility changes: - Update addblock to use the new database and chain interfaces - Update findcheckpoint to use the new database and chain interfaces - Remove the dropafter utility which is no longer supported NOTE: The transaction index and address index will be reimplemented in another commit.
2015-08-26 06:03:18 +02:00
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
)
// utxoOutput houses details about an individual unspent transaction output such
// as whether or not it is spent, its public key script, and how much it pays.
//
// Standard public key scripts are stored in the database using a compressed
// format. Since the vast majority of scripts are of the standard form, a fairly
// significant savings is achieved by discarding the portions of the standard
// scripts that can be reconstructed.
//
// Also, since it is common for only a specific output in a given utxo entry to
// be referenced from a redeeming transaction, the script and amount for a given
// output is not uncompressed until the first time it is accessed. This
// provides a mechanism to avoid the overhead of needlessly uncompressing all
// outputs for a given utxo entry at the time of load.
type utxoOutput struct {
spent bool // Output is spent.
compressed bool // The amount and public key script are compressed.
amount int64 // The amount of the output.
pkScript []byte // The public key script for the output.
}
// maybeDecompress decompresses the amount and public key script fields of the
// utxo and marks it decompressed if needed.
func (o *utxoOutput) maybeDecompress(version int32) {
// Nothing to do if it's not compressed.
if !o.compressed {
return
}
o.amount = int64(decompressTxOutAmount(uint64(o.amount)))
o.pkScript = decompressScript(o.pkScript, version)
o.compressed = false
}
// UtxoEntry contains contextual information about an unspent transaction such
// as whether or not it is a coinbase transaction, which block it was found in,
// and the spent status of its outputs.
type UtxoEntry struct {
modified bool // Entry changed since load.
version int32 // The version of this tx.
isCoinBase bool // Whether entry is a coinbase tx.
blockHeight int32 // Height of block containing tx.
sparseOutputs map[uint32]*utxoOutput // Sparse map of unspent outputs.
}
// Version returns the version of the transaction the utxo represents.
func (entry *UtxoEntry) Version() int32 {
return entry.version
}
// IsCoinBase returns whether or not the transaction the utxo entry represents
// is a coinbase.
func (entry *UtxoEntry) IsCoinBase() bool {
return entry.isCoinBase
}
// BlockHeight returns the height of the block containing the transaction the
// utxo entry represents.
func (entry *UtxoEntry) BlockHeight() int32 {
return entry.blockHeight
}
// IsOutputSpent returns whether or not the provided output index has been
// spent based upon the current state of the unspent transaction output view
// the entry was obtained from.
//
// Returns true if the output index references an output that does not exist
// either due to it being invalid or because the output is not part of the view
// due to previously being spent/pruned.
func (entry *UtxoEntry) IsOutputSpent(outputIndex uint32) bool {
output, ok := entry.sparseOutputs[outputIndex]
if !ok {
return true
}
return output.spent
}
// SpendOutput marks the output at the provided index as spent. Specifying an
// output index that does not exist will not have any effect.
func (entry *UtxoEntry) SpendOutput(outputIndex uint32) {
output, ok := entry.sparseOutputs[outputIndex]
if !ok {
return
}
// Nothing to do if the output is already spent.
if output.spent {
return
}
entry.modified = true
output.spent = true
return
}
// IsFullySpent returns whether or not the transaction the utxo entry represents
// is fully spent.
func (entry *UtxoEntry) IsFullySpent() bool {
// The entry is not fully spent if any of the outputs are unspent.
for _, output := range entry.sparseOutputs {
if !output.spent {
return false
}
}
return true
}
// AmountByIndex returns the amount of the provided output index.
//
// Returns 0 if the output index references an output that does not exist
// either due to it being invalid or because the output is not part of the view
// due to previously being spent/pruned.
func (entry *UtxoEntry) AmountByIndex(outputIndex uint32) int64 {
output, ok := entry.sparseOutputs[outputIndex]
if !ok {
return 0
}
// Ensure the output is decompressed before returning the amount.
output.maybeDecompress(entry.version)
return output.amount
}
// PkScriptByIndex returns the public key script for the provided output index.
//
// Returns nil if the output index references an output that does not exist
// either due to it being invalid or because the output is not part of the view
// due to previously being spent/pruned.
func (entry *UtxoEntry) PkScriptByIndex(outputIndex uint32) []byte {
output, ok := entry.sparseOutputs[outputIndex]
if !ok {
return nil
}
// Ensure the output is decompressed before returning the script.
output.maybeDecompress(entry.version)
return output.pkScript
}
// newUtxoEntry returns a new unspent transaction output entry with the provided
// coinbase flag and block height ready to have unspent outputs added.
func newUtxoEntry(version int32, isCoinBase bool, blockHeight int32) *UtxoEntry {
return &UtxoEntry{
version: version,
isCoinBase: isCoinBase,
blockHeight: blockHeight,
sparseOutputs: make(map[uint32]*utxoOutput),
}
}
// UtxoViewpoint represents a view into the set of unspent transaction outputs
// from a specific point of view in the chain. For example, it could be for
// the end of the main chain, some point in the history of the main chain, or
// down a side chain.
//
// The unspent outputs are needed by other transactions for things such as
// script validation and double spend prevention.
type UtxoViewpoint struct {
entries map[wire.ShaHash]*UtxoEntry
bestHash wire.ShaHash
}
// BestHash returns the hash of the best block in the chain the view currently
// respresents.
func (view *UtxoViewpoint) BestHash() *wire.ShaHash {
return &view.bestHash
}
// SetBestHash sets the hash of the best block in the chain the view currently
// respresents.
func (view *UtxoViewpoint) SetBestHash(hash *wire.ShaHash) {
view.bestHash = *hash
}
// LookupEntry returns information about a given transaction according to the
// current state of the view. It will return nil if the passed transaction
// hash does not exist in the view or is otherwise not available such as when
// it has been disconnected during a reorg.
func (view *UtxoViewpoint) LookupEntry(txHash *wire.ShaHash) *UtxoEntry {
entry, ok := view.entries[*txHash]
if !ok {
return nil
}
return entry
}
// AddTxOuts adds all outputs in the passed transaction which are not provably
// unspendable to the view. When the view already has entries for any of the
// outputs, they are simply marked unspent. All fields will be updated for
// existing entries since it's possible it has changed during a reorg.
func (view *UtxoViewpoint) AddTxOuts(tx *btcutil.Tx, blockHeight int32) {
// When there are not already any utxos associated with the transaction,
// add a new entry for it to the view.
entry := view.LookupEntry(tx.Sha())
if entry == nil {
entry = newUtxoEntry(tx.MsgTx().Version, IsCoinBase(tx),
blockHeight)
view.entries[*tx.Sha()] = entry
} else {
entry.blockHeight = blockHeight
}
entry.modified = true
// Loop all of the transaction outputs and add those which are not
// provably unspendable.
for txOutIdx, txOut := range tx.MsgTx().TxOut {
if txscript.IsUnspendable(txOut.PkScript) {
continue
}
// Update existing entries. All fields are updated because it's
// possible (although extremely unlikely) that the existing
// entry is being replaced by a different transaction with the
// same hash. This is allowed so long as the previous
// transaction is fully spent.
if output, ok := entry.sparseOutputs[uint32(txOutIdx)]; ok {
output.spent = false
output.compressed = false
output.amount = txOut.Value
output.pkScript = txOut.PkScript
continue
}
// Add the unspent transaction output.
entry.sparseOutputs[uint32(txOutIdx)] = &utxoOutput{
spent: false,
compressed: false,
amount: txOut.Value,
pkScript: txOut.PkScript,
}
}
return
}
// connectTransaction updates the view by adding all new utxos created by the
// passed transaction and marking all utxos that the transactions spend as
// spent. In addition, when the 'stxos' argument is not nil, it will be updated
// to append an entry for each spent txout. An error will be returned if the
// view does not contain the required utxos.
func (view *UtxoViewpoint) connectTransaction(tx *btcutil.Tx, blockHeight int32, stxos *[]spentTxOut) error {
// Coinbase transactions don't have any inputs to spend.
if IsCoinBase(tx) {
// Add the transaction's outputs as available utxos.
view.AddTxOuts(tx, blockHeight)
return nil
}
// Spend the referenced utxos by marking them spent in the view and,
// if a slice was provided for the spent txout details, append an entry
// to it.
for _, txIn := range tx.MsgTx().TxIn {
originIndex := txIn.PreviousOutPoint.Index
entry := view.entries[txIn.PreviousOutPoint.Hash]
// Ensure the referenced utxo exists in the view. This should
// never happen unless there is a bug is introduced in the code.
if entry == nil {
return AssertError(fmt.Sprintf("view missing input %v",
txIn.PreviousOutPoint))
}
entry.SpendOutput(originIndex)
// Don't create the stxo details if not requested.
if stxos == nil {
continue
}
// Populate the stxo details using the utxo entry. When the
// transaction is fully spent, set the additional stxo fields
// accordingly since those details will no longer be available
// in the utxo set.
var stxo = spentTxOut{
compressed: false,
version: entry.Version(),
amount: entry.AmountByIndex(originIndex),
pkScript: entry.PkScriptByIndex(originIndex),
}
if entry.IsFullySpent() {
stxo.height = entry.BlockHeight()
stxo.isCoinBase = entry.IsCoinBase()
}
// Append the entry to the provided spent txouts slice.
*stxos = append(*stxos, stxo)
}
// Add the transaction's outputs as available utxos.
view.AddTxOuts(tx, blockHeight)
return nil
}
// connectTransactions updates the view by adding all new utxos created by all
// of the transactions in the passed block, marking all utxos the transactions
// spend as spent, and setting the best hash for the view to the passed block.
// In addition, when the 'stxos' argument is not nil, it will be updated to
// append an entry for each spent txout.
func (view *UtxoViewpoint) connectTransactions(block *btcutil.Block, stxos *[]spentTxOut) error {
for _, tx := range block.Transactions() {
err := view.connectTransaction(tx, block.Height(), stxos)
if err != nil {
return err
}
}
// Update the best hash for view to include this block since all of its
// transactions have been connected.
view.SetBestHash(block.Sha())
return nil
}
// disconnectTransactions updates the view by removing all of the transactions
// created by the passed block, restoring all utxos the transactions spent by
// using the provided spent txo information, and setting the best hash for the
// view to the block before the passed block.
func (view *UtxoViewpoint) disconnectTransactions(block *btcutil.Block, stxos []spentTxOut) error {
// Sanity check the correct number of stxos are provided.
if len(stxos) != countSpentOutputs(block) {
return AssertError("disconnectTransactions called with bad " +
"spent transaction out information")
}
// Loop backwards through all transactions so everything is unspent in
// reverse order. This is necessary since transactions later in a block
// can spend from previous ones.
stxoIdx := len(stxos) - 1
transactions := block.Transactions()
for txIdx := len(transactions) - 1; txIdx > -1; txIdx-- {
tx := transactions[txIdx]
// Clear this transaction from the view if it already exists or
// create a new empty entry for when it does not. This is done
// because the code relies on its existence in the view in order
// to signal modifications have happened.
isCoinbase := txIdx == 0
entry := view.entries[*tx.Sha()]
if entry == nil {
entry = newUtxoEntry(tx.MsgTx().Version, isCoinbase,
block.Height())
view.entries[*tx.Sha()] = entry
}
entry.modified = true
entry.sparseOutputs = make(map[uint32]*utxoOutput)
// Loop backwards through all of the transaction inputs (except
// for the coinbase which has no inputs) and unspend the
// referenced txos. This is necessary to match the order of the
// spent txout entries.
if isCoinbase {
continue
}
for txInIdx := len(tx.MsgTx().TxIn) - 1; txInIdx > -1; txInIdx-- {
// Ensure the spent txout index is decremented to stay
// in sync with the transaction input.
stxo := &stxos[stxoIdx]
stxoIdx--
// When there is not already an entry for the referenced
// transaction in the view, it means it was fully spent,
// so create a new utxo entry in order to resurrect it.
txIn := tx.MsgTx().TxIn[txInIdx]
originHash := &txIn.PreviousOutPoint.Hash
originIndex := txIn.PreviousOutPoint.Index
entry := view.entries[*originHash]
if entry == nil {
entry = newUtxoEntry(stxo.version,
stxo.isCoinBase, stxo.height)
view.entries[*originHash] = entry
}
// Mark the entry as modified since it is either new
// or will be changed below.
entry.modified = true
// Restore the specific utxo using the stxo data from
// the spend journal if it doesn't already exist in the
// view.
output, ok := entry.sparseOutputs[originIndex]
if !ok {
// Add the unspent transaction output.
entry.sparseOutputs[originIndex] = &utxoOutput{
spent: false,
compressed: stxo.compressed,
amount: stxo.amount,
pkScript: stxo.pkScript,
}
continue
}
// Mark the existing referenced transaction output as
// unspent.
output.spent = false
}
}
// Update the best hash for view to the previous block since all of the
// transactions for the current block have been disconnected.
view.SetBestHash(&block.MsgBlock().Header.PrevBlock)
return nil
}
// Entries returns the underlying map that stores of all the utxo entries.
func (view *UtxoViewpoint) Entries() map[wire.ShaHash]*UtxoEntry {
return view.entries
}
// commit prunes all entries marked modified that are now fully spent and marks
// all entries as unmodified.
func (view *UtxoViewpoint) commit() {
for txHash, entry := range view.entries {
if entry == nil || (entry.modified && entry.IsFullySpent()) {
delete(view.entries, txHash)
continue
}
entry.modified = false
}
}
// fetchUtxosMain fetches unspent transaction output data about the provided
// set of transactions from the point of view of the end of the main chain at
// the time of the call.
//
// Upon completion of this function, the view will contain an entry for each
// requested transaction. Fully spent transactions, or those which otherwise
// don't exist, will result in a nil entry in the view.
func (view *UtxoViewpoint) fetchUtxosMain(db database.DB, txSet map[wire.ShaHash]struct{}) error {
// Nothing to do if there are no requested hashes.
if len(txSet) == 0 {
return nil
}
// Load the unspent transaction output information for the requested set
// of transactions from the point of view of the end of the main chain.
//
// NOTE: Missing entries are not considered an error here and instead
// will result in nil entries in the view. This is intentionally done
// since other code uses the presence of an entry in the store as a way
// to optimize spend and unspend updates to apply only to the specific
// utxos that the caller needs access to.
return db.View(func(dbTx database.Tx) error {
for hash := range txSet {
hashCopy := hash
entry, err := dbFetchUtxoEntry(dbTx, &hashCopy)
if err != nil {
return err
}
view.entries[hash] = entry
}
return nil
})
}
// fetchUtxos loads utxo details about provided set of transaction hashes into
// the view from the database as needed unless they already exist in the view in
// which case they are ignored.
func (view *UtxoViewpoint) fetchUtxos(db database.DB, txSet map[wire.ShaHash]struct{}) error {
// Nothing to do if there are no requested hashes.
if len(txSet) == 0 {
return nil
}
// Filter entries that are already in the view.
txNeededSet := make(map[wire.ShaHash]struct{})
for hash := range txSet {
// Already loaded into the current view.
if _, ok := view.entries[hash]; ok {
continue
}
txNeededSet[hash] = struct{}{}
}
// Request the input utxos from the database.
return view.fetchUtxosMain(db, txNeededSet)
}
// fetchInputUtxos loads utxo details about the input transactions referenced
// by the transactions in the given block into the view from the database as
// needed. In particular, referenced entries that are earlier in the block are
// added to the view and entries that are already in the view are not modified.
func (view *UtxoViewpoint) fetchInputUtxos(db database.DB, block *btcutil.Block) error {
// Build a map of in-flight transactions because some of the inputs in
// this block could be referencing other transactions earlier in this
// block which are not yet in the chain.
txInFlight := map[wire.ShaHash]int{}
transactions := block.Transactions()
for i, tx := range transactions {
txInFlight[*tx.Sha()] = i
}
// Loop through all of the transaction inputs (except for the coinbase
// which has no inputs) collecting them into sets of what is needed and
// what is already known (in-flight).
txNeededSet := make(map[wire.ShaHash]struct{})
for i, tx := range transactions[1:] {
for _, txIn := range tx.MsgTx().TxIn {
// It is acceptable for a transaction input to reference
// the output of another transaction in this block only
// if the referenced transaction comes before the
// current one in this block. Add the outputs of the
// referenced transaction as available utxos when this
// is the case. Otherwise, the utxo details are still
// needed.
//
// NOTE: The >= is correct here because i is one less
// than the actual position of the transaction within
// the block due to skipping the coinbase.
originHash := &txIn.PreviousOutPoint.Hash
if inFlightIndex, ok := txInFlight[*originHash]; ok &&
i >= inFlightIndex {
originTx := transactions[inFlightIndex]
view.AddTxOuts(originTx, block.Height())
continue
}
// Don't request entries that are already in the view
// from the database.
if _, ok := view.entries[*originHash]; ok {
continue
}
txNeededSet[*originHash] = struct{}{}
}
}
// Request the input utxos from the database.
return view.fetchUtxosMain(db, txNeededSet)
}
// NewUtxoViewpoint returns a new empty unspent transaction output view.
func NewUtxoViewpoint() *UtxoViewpoint {
return &UtxoViewpoint{
entries: make(map[wire.ShaHash]*UtxoEntry),
}
}
// FetchUtxoView loads utxo details about the input transactions referenced by
// the passed transaction from the point of view of the end of the main chain.
// It also attempts to fetch the utxo details for the transaction itself so the
// returned view can be examined for duplicate unspent transaction outputs.
//
// This function is safe for concurrent access however the returned view is NOT.
func (b *BlockChain) FetchUtxoView(tx *btcutil.Tx) (*UtxoViewpoint, error) {
b.chainLock.RLock()
defer b.chainLock.RUnlock()
// Create a set of needed transactions based on those referenced by the
// inputs of the passed transaction. Also, add the passed transaction
// itself as a way for the caller to detect duplicates that are not
// fully spent.
txNeededSet := make(map[wire.ShaHash]struct{})
txNeededSet[*tx.Sha()] = struct{}{}
if !IsCoinBase(tx) {
for _, txIn := range tx.MsgTx().TxIn {
txNeededSet[txIn.PreviousOutPoint.Hash] = struct{}{}
}
}
// Request the utxos from the point of view of the end of the main
// chain.
view := NewUtxoViewpoint()
err := view.fetchUtxosMain(b.db, txNeededSet)
return view, err
}
// FetchUtxoEntry loads and returns the unspent transaction output entry for the
// passed hash from the point of view of the end of the main chain.
//
// NOTE: Requesting a hash for which there is no data will NOT return an error.
// Instead both the entry and the error will be nil. This is done to allow
// pruning of fully spent transactions. In practice this means the caller must
// check if the returned entry is nil before invoking methods on it.
//
// This function is safe for concurrent access however the returned entry (if
// any) is NOT.
func (b *BlockChain) FetchUtxoEntry(txHash *wire.ShaHash) (*UtxoEntry, error) {
b.chainLock.RLock()
defer b.chainLock.RUnlock()
var entry *UtxoEntry
err := b.db.View(func(dbTx database.Tx) error {
var err error
entry, err = dbFetchUtxoEntry(dbTx, txHash)
return err
})
if err != nil {
return nil, err
}
return entry, nil
}