0280fa0264
This commit converts all block height references to int32 instead of int64. The current target block production rate is 10 mins per block which means it will take roughly 40,800 years to reach the maximum height an int32 affords. Even if the target rate were lowered to one block per minute, it would still take roughly another 4,080 years to reach the maximum. In the mean time, there is no reason to use a larger type which results in higher memory and disk space usage. However, for now, in order to avoid having to reserialize a bunch of database information, the heights are still serialized to the database as 8-byte uint64s. This is being mainly being done in preparation for further upcoming infrastructure changes which will use the smaller and more efficient 4-byte serialization in the database as well.
744 lines
23 KiB
Go
744 lines
23 KiB
Go
// 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 memdb
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import (
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"errors"
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"fmt"
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"math"
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"sync"
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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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// Errors that the various database functions may return.
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var (
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ErrDbClosed = errors.New("database is closed")
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)
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var (
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zeroHash = wire.ShaHash{}
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// The following two hashes are ones that must be specially handled.
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// See the comments where they're used for more details.
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dupTxHash91842 = newShaHashFromStr("d5d27987d2a3dfc724e359870c6644b40e497bdc0589a033220fe15429d88599")
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dupTxHash91880 = newShaHashFromStr("e3bf3d07d4b0375638d5f1db5255fe07ba2c4cb067cd81b84ee974b6585fb468")
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)
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// tTxInsertData holds information about the location and spent status of
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// a transaction.
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type tTxInsertData struct {
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blockHeight int32
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offset int
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spentBuf []bool
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}
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// newShaHashFromStr converts the passed big-endian hex string into a
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// wire.ShaHash. It only differs from the one available in wire in that it
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// ignores the error since it will only (and must only) be called with
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// hard-coded, and therefore known good, hashes.
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func newShaHashFromStr(hexStr string) *wire.ShaHash {
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sha, _ := wire.NewShaHashFromStr(hexStr)
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return sha
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}
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// isCoinbaseInput returns whether or not the passed transaction input is a
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// coinbase input. A coinbase is a special transaction created by miners that
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// has no inputs. This is represented in the block chain by a transaction with
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// a single input that has a previous output transaction index set to the
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// maximum value along with a zero hash.
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func isCoinbaseInput(txIn *wire.TxIn) bool {
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prevOut := &txIn.PreviousOutPoint
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if prevOut.Index == math.MaxUint32 && prevOut.Hash.IsEqual(&zeroHash) {
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return true
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}
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return false
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}
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// isFullySpent returns whether or not a transaction represented by the passed
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// transaction insert data is fully spent. A fully spent transaction is one
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// where all outputs are spent.
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func isFullySpent(txD *tTxInsertData) bool {
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for _, spent := range txD.spentBuf {
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if !spent {
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return false
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}
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}
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return true
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}
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// MemDb is a concrete implementation of the database.Db interface which provides
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// a memory-only database. Since it is memory-only, it is obviously not
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// persistent and is mostly only useful for testing purposes.
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type MemDb struct {
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// Embed a mutex for safe concurrent access.
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sync.Mutex
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// blocks holds all of the bitcoin blocks that will be in the memory
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// database.
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blocks []*wire.MsgBlock
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// blocksBySha keeps track of block heights by hash. The height can
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// be used as an index into the blocks slice.
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blocksBySha map[wire.ShaHash]int32
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// txns holds information about transactions such as which their
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// block height and spent status of all their outputs.
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txns map[wire.ShaHash][]*tTxInsertData
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// closed indicates whether or not the database has been closed and is
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// therefore invalidated.
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closed bool
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}
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// removeTx removes the passed transaction including unspending it.
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func (db *MemDb) removeTx(msgTx *wire.MsgTx, txHash *wire.ShaHash) {
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// Undo all of the spends for the transaction.
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for _, txIn := range msgTx.TxIn {
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if isCoinbaseInput(txIn) {
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continue
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}
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prevOut := &txIn.PreviousOutPoint
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originTxns, exists := db.txns[prevOut.Hash]
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if !exists {
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log.Warnf("Unable to find input transaction %s to "+
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"unspend %s index %d", prevOut.Hash, txHash,
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prevOut.Index)
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continue
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}
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originTxD := originTxns[len(originTxns)-1]
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originTxD.spentBuf[prevOut.Index] = false
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}
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// Remove the info for the most recent version of the transaction.
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txns := db.txns[*txHash]
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lastIndex := len(txns) - 1
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txns[lastIndex] = nil
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txns = txns[:lastIndex]
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db.txns[*txHash] = txns
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// Remove the info entry from the map altogether if there not any older
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// versions of the transaction.
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if len(txns) == 0 {
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delete(db.txns, *txHash)
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}
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}
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// Close cleanly shuts down database. This is part of the database.Db interface
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// implementation.
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//
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// All data is purged upon close with this implementation since it is a
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// memory-only database.
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func (db *MemDb) Close() error {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return ErrDbClosed
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}
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db.blocks = nil
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db.blocksBySha = nil
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db.txns = nil
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db.closed = true
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return nil
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}
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// DropAfterBlockBySha removes any blocks from the database after the given
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// block. This is different than a simple truncate since the spend information
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// for each block must also be unwound. This is part of the database.Db interface
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// implementation.
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func (db *MemDb) DropAfterBlockBySha(sha *wire.ShaHash) error {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return ErrDbClosed
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}
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// Begin by attempting to find the height associated with the passed
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// hash.
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height, exists := db.blocksBySha[*sha]
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if !exists {
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return fmt.Errorf("block %v does not exist in the database",
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sha)
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}
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// The spend information has to be undone in reverse order, so loop
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// backwards from the last block through the block just after the passed
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// block. While doing this unspend all transactions in each block and
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// remove the block.
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endHeight := int32(len(db.blocks) - 1)
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for i := endHeight; i > height; i-- {
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// Unspend and remove each transaction in reverse order because
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// later transactions in a block can reference earlier ones.
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transactions := db.blocks[i].Transactions
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for j := len(transactions) - 1; j >= 0; j-- {
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tx := transactions[j]
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txHash := tx.TxSha()
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db.removeTx(tx, &txHash)
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}
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db.blocks[i] = nil
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db.blocks = db.blocks[:i]
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}
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return nil
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}
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// ExistsSha returns whether or not the given block hash is present in the
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// database. This is part of the database.Db interface implementation.
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func (db *MemDb) ExistsSha(sha *wire.ShaHash) (bool, error) {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return false, ErrDbClosed
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}
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if _, exists := db.blocksBySha[*sha]; exists {
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return true, nil
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}
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return false, nil
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}
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// FetchBlockBySha returns a btcutil.Block. The implementation may cache the
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// underlying data if desired. This is part of the database.Db interface
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// implementation.
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//
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// This implementation does not use any additional cache since the entire
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// database is already in memory.
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func (db *MemDb) FetchBlockBySha(sha *wire.ShaHash) (*btcutil.Block, error) {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return nil, ErrDbClosed
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}
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if blockHeight, exists := db.blocksBySha[*sha]; exists {
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block := btcutil.NewBlock(db.blocks[int(blockHeight)])
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block.SetHeight(blockHeight)
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return block, nil
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}
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return nil, fmt.Errorf("block %v is not in database", sha)
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}
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// FetchBlockHeightBySha returns the block height for the given hash. This is
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// part of the database.Db interface implementation.
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func (db *MemDb) FetchBlockHeightBySha(sha *wire.ShaHash) (int32, error) {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return 0, ErrDbClosed
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}
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if blockHeight, exists := db.blocksBySha[*sha]; exists {
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return blockHeight, nil
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}
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return 0, fmt.Errorf("block %v is not in database", sha)
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}
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// FetchBlockHeaderBySha returns a wire.BlockHeader for the given sha. The
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// implementation may cache the underlying data if desired. This is part of the
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// database.Db interface implementation.
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//
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// This implementation does not use any additional cache since the entire
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// database is already in memory.
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func (db *MemDb) FetchBlockHeaderBySha(sha *wire.ShaHash) (*wire.BlockHeader, error) {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return nil, ErrDbClosed
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}
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if blockHeight, exists := db.blocksBySha[*sha]; exists {
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return &db.blocks[int(blockHeight)].Header, nil
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}
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return nil, fmt.Errorf("block header %v is not in database", sha)
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}
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// FetchBlockShaByHeight returns a block hash based on its height in the block
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// chain. This is part of the database.Db interface implementation.
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func (db *MemDb) FetchBlockShaByHeight(height int32) (*wire.ShaHash, error) {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return nil, ErrDbClosed
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}
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numBlocks := int32(len(db.blocks))
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if height < 0 || height > numBlocks-1 {
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return nil, fmt.Errorf("unable to fetch block height %d since "+
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"it is not within the valid range (%d-%d)", height, 0,
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numBlocks-1)
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}
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msgBlock := db.blocks[height]
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blockHash := msgBlock.BlockSha()
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return &blockHash, nil
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}
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// FetchHeightRange looks up a range of blocks by the start and ending heights.
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// Fetch is inclusive of the start height and exclusive of the ending height.
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// To fetch all hashes from the start height until no more are present, use the
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// special id `AllShas'. This is part of the database.Db interface implementation.
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func (db *MemDb) FetchHeightRange(startHeight, endHeight int32) ([]wire.ShaHash, error) {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return nil, ErrDbClosed
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}
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// When the user passes the special AllShas id, adjust the end height
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// accordingly.
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if endHeight == database.AllShas {
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endHeight = int32(len(db.blocks))
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}
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// Ensure requested heights are sane.
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if startHeight < 0 {
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return nil, fmt.Errorf("start height of fetch range must not "+
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"be less than zero - got %d", startHeight)
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}
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if endHeight < startHeight {
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return nil, fmt.Errorf("end height of fetch range must not "+
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"be less than the start height - got start %d, end %d",
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startHeight, endHeight)
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}
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// Fetch as many as are availalbe within the specified range.
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lastBlockIndex := int32(len(db.blocks) - 1)
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hashList := make([]wire.ShaHash, 0, endHeight-startHeight)
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for i := startHeight; i < endHeight; i++ {
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if i > lastBlockIndex {
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break
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}
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msgBlock := db.blocks[i]
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blockHash := msgBlock.BlockSha()
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hashList = append(hashList, blockHash)
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}
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return hashList, nil
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}
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// ExistsTxSha returns whether or not the given transaction hash is present in
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// the database and is not fully spent. This is part of the database.Db interface
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// implementation.
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func (db *MemDb) ExistsTxSha(sha *wire.ShaHash) (bool, error) {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return false, ErrDbClosed
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}
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if txns, exists := db.txns[*sha]; exists {
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return !isFullySpent(txns[len(txns)-1]), nil
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}
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return false, nil
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}
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// FetchTxBySha returns some data for the given transaction hash. The
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// implementation may cache the underlying data if desired. This is part of the
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// database.Db interface implementation.
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//
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// This implementation does not use any additional cache since the entire
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// database is already in memory.
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func (db *MemDb) FetchTxBySha(txHash *wire.ShaHash) ([]*database.TxListReply, error) {
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db.Lock()
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defer db.Unlock()
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if db.closed {
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return nil, ErrDbClosed
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}
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txns, exists := db.txns[*txHash]
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if !exists {
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log.Warnf("FetchTxBySha: requested hash of %s does not exist",
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txHash)
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return nil, database.ErrTxShaMissing
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}
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txHashCopy := *txHash
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replyList := make([]*database.TxListReply, len(txns))
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for i, txD := range txns {
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msgBlock := db.blocks[txD.blockHeight]
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blockSha := msgBlock.BlockSha()
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spentBuf := make([]bool, len(txD.spentBuf))
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copy(spentBuf, txD.spentBuf)
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reply := database.TxListReply{
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Sha: &txHashCopy,
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Tx: msgBlock.Transactions[txD.offset],
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BlkSha: &blockSha,
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Height: txD.blockHeight,
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TxSpent: spentBuf,
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Err: nil,
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}
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replyList[i] = &reply
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}
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return replyList, nil
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}
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// fetchTxByShaList fetches transactions and information about them given an
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// array of transaction hashes. The result is a slice of of TxListReply objects
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// which contain the transaction and information about it such as what block and
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// block height it's contained in and which outputs are spent.
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//
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// The includeSpent flag indicates whether or not information about transactions
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// which are fully spent should be returned. When the flag is not set, the
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// corresponding entry in the TxListReply slice for fully spent transactions
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// will indicate the transaction does not exist.
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//
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// This function must be called with the db lock held.
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func (db *MemDb) fetchTxByShaList(txShaList []*wire.ShaHash, includeSpent bool) []*database.TxListReply {
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replyList := make([]*database.TxListReply, 0, len(txShaList))
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for i, hash := range txShaList {
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// Every requested entry needs a response, so start with nothing
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// more than a response with the requested hash marked missing.
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// The reply will be updated below with the appropriate
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// information if the transaction exists.
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reply := database.TxListReply{
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Sha: txShaList[i],
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Err: database.ErrTxShaMissing,
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}
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replyList = append(replyList, &reply)
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if db.closed {
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reply.Err = ErrDbClosed
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continue
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}
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if txns, exists := db.txns[*hash]; exists {
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// A given transaction may have duplicates so long as the
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// previous one is fully spent. We are only interested
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// in the most recent version of the transaction for
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// this function. The FetchTxBySha function can be
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// used to get all versions of a transaction.
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txD := txns[len(txns)-1]
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if !includeSpent && isFullySpent(txD) {
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continue
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}
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// Look up the referenced block and get its hash. Set
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// the reply error appropriately and go to the next
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// requested transaction if anything goes wrong.
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msgBlock := db.blocks[txD.blockHeight]
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blockSha := msgBlock.BlockSha()
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// Make a copy of the spent buf to return so the caller
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// can't accidentally modify it.
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spentBuf := make([]bool, len(txD.spentBuf))
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copy(spentBuf, txD.spentBuf)
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// Populate the reply.
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reply.Tx = msgBlock.Transactions[txD.offset]
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reply.BlkSha = &blockSha
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reply.Height = txD.blockHeight
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reply.TxSpent = spentBuf
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reply.Err = nil
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}
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}
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return replyList
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}
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// FetchTxByShaList returns a TxListReply given an array of transaction hashes.
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// The implementation may cache the underlying data if desired. This is part of
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// the database.Db interface implementation.
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//
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// This implementation does not use any additional cache since the entire
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// database is already in memory.
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// FetchTxByShaList returns a TxListReply given an array of transaction
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// hashes. This function differs from FetchUnSpentTxByShaList in that it
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// returns the most recent version of fully spent transactions. Due to the
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// increased number of transaction fetches, this function is typically more
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// expensive than the unspent counterpart, however the specific performance
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// details depend on the concrete implementation. The implementation may cache
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// the underlying data if desired. This is part of the database.Db interface
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// implementation.
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//
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// To fetch all versions of a specific transaction, call FetchTxBySha.
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//
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// This implementation does not use any additional cache since the entire
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// database is already in memory.
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func (db *MemDb) FetchTxByShaList(txShaList []*wire.ShaHash) []*database.TxListReply {
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db.Lock()
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defer db.Unlock()
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return db.fetchTxByShaList(txShaList, true)
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}
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// FetchUnSpentTxByShaList returns a TxListReply given an array of transaction
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// hashes. Any transactions which are fully spent will indicate they do not
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// exist by setting the Err field to TxShaMissing. The implementation may cache
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// the underlying data if desired. This is part of the database.Db interface
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// implementation.
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//
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// To obtain results which do contain the most recent version of a fully spent
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// transactions, call FetchTxByShaList. To fetch all versions of a specific
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// transaction, call FetchTxBySha.
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//
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// This implementation does not use any additional cache since the entire
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// database is already in memory.
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func (db *MemDb) FetchUnSpentTxByShaList(txShaList []*wire.ShaHash) []*database.TxListReply {
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db.Lock()
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|
defer db.Unlock()
|
|
|
|
return db.fetchTxByShaList(txShaList, false)
|
|
}
|
|
|
|
// InsertBlock inserts raw block and transaction data from a block into the
|
|
// database. The first block inserted into the database will be treated as the
|
|
// genesis block. Every subsequent block insert requires the referenced parent
|
|
// block to already exist. This is part of the database.Db interface
|
|
// implementation.
|
|
func (db *MemDb) InsertBlock(block *btcutil.Block) (int32, error) {
|
|
db.Lock()
|
|
defer db.Unlock()
|
|
|
|
if db.closed {
|
|
return 0, ErrDbClosed
|
|
}
|
|
|
|
// Reject the insert if the previously reference block does not exist
|
|
// except in the case there are no blocks inserted yet where the first
|
|
// inserted block is assumed to be a genesis block.
|
|
msgBlock := block.MsgBlock()
|
|
if _, exists := db.blocksBySha[msgBlock.Header.PrevBlock]; !exists {
|
|
if len(db.blocks) > 0 {
|
|
return 0, database.ErrPrevShaMissing
|
|
}
|
|
}
|
|
|
|
// 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 transactions and inputs to ensure there are no error
|
|
// conditions that would prevent them from be inserted into the db.
|
|
// Although these checks could could be done in the loop below, checking
|
|
// for error conditions up front means the code below doesn't have to
|
|
// deal with rollback on errors.
|
|
newHeight := int32(len(db.blocks))
|
|
for i, tx := range transactions {
|
|
// Two old blocks contain duplicate transactions due to being
|
|
// mined by faulty miners and accepted by the origin Satoshi
|
|
// client. Rules have since been added to the ensure this
|
|
// problem can no longer happen, but the two duplicate
|
|
// transactions which were originally accepted are forever in
|
|
// the block chain history and must be dealth with specially.
|
|
// http://blockexplorer.com/b/91842
|
|
// http://blockexplorer.com/b/91880
|
|
if newHeight == 91842 && tx.Sha().IsEqual(dupTxHash91842) {
|
|
continue
|
|
}
|
|
|
|
if newHeight == 91880 && tx.Sha().IsEqual(dupTxHash91880) {
|
|
continue
|
|
}
|
|
|
|
for _, txIn := range tx.MsgTx().TxIn {
|
|
if isCoinbaseInput(txIn) {
|
|
continue
|
|
}
|
|
|
|
// 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.
|
|
prevOut := &txIn.PreviousOutPoint
|
|
if inFlightIndex, ok := txInFlight[prevOut.Hash]; ok {
|
|
if i <= inFlightIndex {
|
|
log.Warnf("InsertBlock: requested hash "+
|
|
" of %s does not exist in-flight",
|
|
tx.Sha())
|
|
return 0, database.ErrTxShaMissing
|
|
}
|
|
} else {
|
|
originTxns, exists := db.txns[prevOut.Hash]
|
|
if !exists {
|
|
log.Warnf("InsertBlock: requested hash "+
|
|
"of %s by %s does not exist",
|
|
prevOut.Hash, tx.Sha())
|
|
return 0, database.ErrTxShaMissing
|
|
}
|
|
originTxD := originTxns[len(originTxns)-1]
|
|
if prevOut.Index > uint32(len(originTxD.spentBuf)) {
|
|
log.Warnf("InsertBlock: requested hash "+
|
|
"of %s with index %d does not "+
|
|
"exist", tx.Sha(), prevOut.Index)
|
|
return 0, database.ErrTxShaMissing
|
|
}
|
|
}
|
|
}
|
|
|
|
// Prevent duplicate transactions in the same block.
|
|
if inFlightIndex, exists := txInFlight[*tx.Sha()]; exists &&
|
|
inFlightIndex < i {
|
|
log.Warnf("Block contains duplicate transaction %s",
|
|
tx.Sha())
|
|
return 0, database.ErrDuplicateSha
|
|
}
|
|
|
|
// Prevent duplicate transactions unless the old one is fully
|
|
// spent.
|
|
if txns, exists := db.txns[*tx.Sha()]; exists {
|
|
txD := txns[len(txns)-1]
|
|
if !isFullySpent(txD) {
|
|
log.Warnf("Attempt to insert duplicate "+
|
|
"transaction %s", tx.Sha())
|
|
return 0, database.ErrDuplicateSha
|
|
}
|
|
}
|
|
}
|
|
|
|
db.blocks = append(db.blocks, msgBlock)
|
|
db.blocksBySha[*block.Sha()] = newHeight
|
|
|
|
// Insert information about eacj transaction and spend all of the
|
|
// outputs referenced by the inputs to the transactions.
|
|
for i, tx := range block.Transactions() {
|
|
// Insert the transaction data.
|
|
txD := tTxInsertData{
|
|
blockHeight: newHeight,
|
|
offset: i,
|
|
spentBuf: make([]bool, len(tx.MsgTx().TxOut)),
|
|
}
|
|
db.txns[*tx.Sha()] = append(db.txns[*tx.Sha()], &txD)
|
|
|
|
// Spend all of the inputs.
|
|
for _, txIn := range tx.MsgTx().TxIn {
|
|
// Coinbase transaction has no inputs.
|
|
if isCoinbaseInput(txIn) {
|
|
continue
|
|
}
|
|
|
|
// Already checked for existing and valid ranges above.
|
|
prevOut := &txIn.PreviousOutPoint
|
|
originTxns := db.txns[prevOut.Hash]
|
|
originTxD := originTxns[len(originTxns)-1]
|
|
originTxD.spentBuf[prevOut.Index] = true
|
|
}
|
|
}
|
|
|
|
return newHeight, nil
|
|
}
|
|
|
|
// NewestSha returns the hash and block height of the most recent (end) block of
|
|
// the block chain. It will return the zero hash, -1 for the block height, and
|
|
// no error (nil) if there are not any blocks in the database yet. This is part
|
|
// of the database.Db interface implementation.
|
|
func (db *MemDb) NewestSha() (*wire.ShaHash, int32, error) {
|
|
db.Lock()
|
|
defer db.Unlock()
|
|
|
|
if db.closed {
|
|
return nil, 0, ErrDbClosed
|
|
}
|
|
|
|
// When the database has not had a genesis block inserted yet, return
|
|
// values specified by interface contract.
|
|
numBlocks := len(db.blocks)
|
|
if numBlocks == 0 {
|
|
return &zeroHash, -1, nil
|
|
}
|
|
|
|
blockSha := db.blocks[numBlocks-1].BlockSha()
|
|
return &blockSha, int32(numBlocks - 1), nil
|
|
}
|
|
|
|
// FetchAddrIndexTip isn't currently implemented. This is a part of the
|
|
// database.Db interface implementation.
|
|
func (db *MemDb) FetchAddrIndexTip() (*wire.ShaHash, int32, error) {
|
|
return nil, 0, database.ErrNotImplemented
|
|
}
|
|
|
|
// UpdateAddrIndexForBlock isn't currently implemented. This is a part of the
|
|
// database.Db interface implementation.
|
|
func (db *MemDb) UpdateAddrIndexForBlock(*wire.ShaHash, int32,
|
|
database.BlockAddrIndex) error {
|
|
return database.ErrNotImplemented
|
|
}
|
|
|
|
// FetchTxsForAddr isn't currently implemented. This is a part of the database.Db
|
|
// interface implementation.
|
|
func (db *MemDb) FetchTxsForAddr(btcutil.Address, int, int) ([]*database.TxListReply, error) {
|
|
return nil, database.ErrNotImplemented
|
|
}
|
|
|
|
// DeleteAddrIndex isn't currently implemented. This is a part of the database.Db
|
|
// interface implementation.
|
|
func (db *MemDb) DeleteAddrIndex() error {
|
|
return database.ErrNotImplemented
|
|
}
|
|
|
|
// RollbackClose discards the recent database changes to the previously saved
|
|
// data at last Sync and closes the database. This is part of the database.Db
|
|
// interface implementation.
|
|
//
|
|
// The database is completely purged on close with this implementation since the
|
|
// entire database is only in memory. As a result, this function behaves no
|
|
// differently than Close.
|
|
func (db *MemDb) RollbackClose() error {
|
|
// Rollback doesn't apply to a memory database, so just call Close.
|
|
// Close handles the mutex locks.
|
|
return db.Close()
|
|
}
|
|
|
|
// Sync verifies that the database is coherent on disk and no outstanding
|
|
// transactions are in flight. This is part of the database.Db interface
|
|
// implementation.
|
|
//
|
|
// This implementation does not write any data to disk, so this function only
|
|
// grabs a lock to ensure it doesn't return until other operations are complete.
|
|
func (db *MemDb) Sync() error {
|
|
db.Lock()
|
|
defer db.Unlock()
|
|
|
|
if db.closed {
|
|
return ErrDbClosed
|
|
}
|
|
|
|
// There is nothing extra to do to sync the memory database. However,
|
|
// the lock is still grabbed to ensure the function does not return
|
|
// until other operations are complete.
|
|
return nil
|
|
}
|
|
|
|
// newMemDb returns a new memory-only database ready for block inserts.
|
|
func newMemDb() *MemDb {
|
|
db := MemDb{
|
|
blocks: make([]*wire.MsgBlock, 0, 200000),
|
|
blocksBySha: make(map[wire.ShaHash]int32),
|
|
txns: make(map[wire.ShaHash][]*tTxInsertData),
|
|
}
|
|
return &db
|
|
}
|