// Copyright (c) 2013-2014 The btcsuite developers // Use of this source code is governed by an ISC // license that can be found in the LICENSE file. package ldb import ( "bytes" "encoding/binary" "errors" "github.com/btcsuite/btcd/database" "github.com/btcsuite/btcd/wire" "github.com/btcsuite/btcutil" "github.com/btcsuite/golangcrypto/ripemd160" "github.com/btcsuite/goleveldb/leveldb" "github.com/btcsuite/goleveldb/leveldb/util" ) const ( // Each address index is 34 bytes: // -------------------------------------------------------- // | Prefix | Hash160 | BlkHeight | Tx Offset | Tx Size | // -------------------------------------------------------- // | 3 bytes | 20 bytes | 4 bytes | 4 bytes | 4 bytes | // -------------------------------------------------------- addrIndexKeyLength = 3 + ripemd160.Size + 4 + 4 + 4 batchDeleteThreshold = 10000 addrIndexCurrentVersion = 1 ) var addrIndexMetaDataKey = []byte("addrindex") // All address index entries share this prefix to facilitate the use of // iterators. var addrIndexKeyPrefix = []byte("a+-") // Address index version is required to drop/rebuild address index if version // is older than current as the format of the index may have changed. This is // true when going from no version to version 1 as the address index is stored // as big endian in version 1 and little endian in the original code. Version // is stored as two bytes, little endian (to match all the code but the index). var addrIndexVersionKey = []byte("addrindexversion") type txUpdateObj struct { txSha *wire.ShaHash blkHeight int32 txoff int txlen int ntxout int spentData []byte delete bool } type spentTx struct { blkHeight int32 txoff int txlen int numTxO int delete bool } type spentTxUpdate struct { txl []*spentTx delete bool } type txAddrIndex struct { hash160 [ripemd160.Size]byte blkHeight int32 txoffset int txlen int } // InsertTx inserts a tx hash and its associated data into the database. func (db *LevelDb) InsertTx(txsha *wire.ShaHash, height int32, txoff int, txlen int, spentbuf []byte) (err error) { db.dbLock.Lock() defer db.dbLock.Unlock() return db.insertTx(txsha, height, txoff, txlen, spentbuf) } // insertTx inserts a tx hash and its associated data into the database. // Must be called with db lock held. func (db *LevelDb) insertTx(txSha *wire.ShaHash, height int32, txoff int, txlen int, spentbuf []byte) (err error) { var txU txUpdateObj txU.txSha = txSha txU.blkHeight = height txU.txoff = txoff txU.txlen = txlen txU.spentData = spentbuf db.txUpdateMap[*txSha] = &txU return nil } // formatTx generates the value buffer for the Tx db. func (db *LevelDb) formatTx(txu *txUpdateObj) []byte { blkHeight := uint64(txu.blkHeight) txOff := uint32(txu.txoff) txLen := uint32(txu.txlen) spentbuf := txu.spentData txW := make([]byte, 16+len(spentbuf)) binary.LittleEndian.PutUint64(txW[0:8], blkHeight) binary.LittleEndian.PutUint32(txW[8:12], txOff) binary.LittleEndian.PutUint32(txW[12:16], txLen) copy(txW[16:], spentbuf) return txW[:] } func (db *LevelDb) getTxData(txsha *wire.ShaHash) (int32, int, int, []byte, error) { key := shaTxToKey(txsha) buf, err := db.lDb.Get(key, db.ro) if err != nil { return 0, 0, 0, nil, err } blkHeight := binary.LittleEndian.Uint64(buf[0:8]) txOff := binary.LittleEndian.Uint32(buf[8:12]) txLen := binary.LittleEndian.Uint32(buf[12:16]) spentBuf := make([]byte, len(buf)-16) copy(spentBuf, buf[16:]) return int32(blkHeight), int(txOff), int(txLen), spentBuf, nil } func (db *LevelDb) getTxFullySpent(txsha *wire.ShaHash) ([]*spentTx, error) { var badTxList, spentTxList []*spentTx key := shaSpentTxToKey(txsha) buf, err := db.lDb.Get(key, db.ro) if err == leveldb.ErrNotFound { return badTxList, database.ErrTxShaMissing } else if err != nil { return badTxList, err } txListLen := len(buf) / 20 spentTxList = make([]*spentTx, txListLen, txListLen) for i := range spentTxList { offset := i * 20 blkHeight := binary.LittleEndian.Uint64(buf[offset : offset+8]) txOff := binary.LittleEndian.Uint32(buf[offset+8 : offset+12]) txLen := binary.LittleEndian.Uint32(buf[offset+12 : offset+16]) numTxO := binary.LittleEndian.Uint32(buf[offset+16 : offset+20]) sTx := spentTx{ blkHeight: int32(blkHeight), txoff: int(txOff), txlen: int(txLen), numTxO: int(numTxO), } spentTxList[i] = &sTx } return spentTxList, nil } func (db *LevelDb) formatTxFullySpent(sTxList []*spentTx) []byte { txW := make([]byte, 20*len(sTxList)) for i, sTx := range sTxList { blkHeight := uint64(sTx.blkHeight) txOff := uint32(sTx.txoff) txLen := uint32(sTx.txlen) numTxO := uint32(sTx.numTxO) offset := i * 20 binary.LittleEndian.PutUint64(txW[offset:offset+8], blkHeight) binary.LittleEndian.PutUint32(txW[offset+8:offset+12], txOff) binary.LittleEndian.PutUint32(txW[offset+12:offset+16], txLen) binary.LittleEndian.PutUint32(txW[offset+16:offset+20], numTxO) } return txW } // ExistsTxSha returns if the given tx sha exists in the database func (db *LevelDb) ExistsTxSha(txsha *wire.ShaHash) (bool, error) { db.dbLock.Lock() defer db.dbLock.Unlock() return db.existsTxSha(txsha) } // existsTxSha returns if the given tx sha exists in the database.o // Must be called with the db lock held. func (db *LevelDb) existsTxSha(txSha *wire.ShaHash) (bool, error) { key := shaTxToKey(txSha) return db.lDb.Has(key, db.ro) } // FetchTxByShaList returns the most recent tx of the name fully spent or not func (db *LevelDb) FetchTxByShaList(txShaList []*wire.ShaHash) []*database.TxListReply { db.dbLock.Lock() defer db.dbLock.Unlock() // until the fully spent separation of tx is complete this is identical // to FetchUnSpentTxByShaList replies := make([]*database.TxListReply, len(txShaList)) for i, txsha := range txShaList { tx, blockSha, height, txspent, err := db.fetchTxDataBySha(txsha) btxspent := []bool{} if err == nil { btxspent = make([]bool, len(tx.TxOut), len(tx.TxOut)) for idx := range tx.TxOut { byteidx := idx / 8 byteoff := uint(idx % 8) btxspent[idx] = (txspent[byteidx] & (byte(1) << byteoff)) != 0 } } if err == database.ErrTxShaMissing { // if the unspent pool did not have the tx, // look in the fully spent pool (only last instance) sTxList, fSerr := db.getTxFullySpent(txsha) if fSerr == nil && len(sTxList) != 0 { idx := len(sTxList) - 1 stx := sTxList[idx] tx, blockSha, _, _, err = db.fetchTxDataByLoc( stx.blkHeight, stx.txoff, stx.txlen, []byte{}) if err == nil { btxspent = make([]bool, len(tx.TxOut)) for i := range btxspent { btxspent[i] = true } } } } txlre := database.TxListReply{Sha: txsha, Tx: tx, BlkSha: blockSha, Height: height, TxSpent: btxspent, Err: err} replies[i] = &txlre } return replies } // FetchUnSpentTxByShaList given a array of ShaHash, look up the transactions // and return them in a TxListReply array. func (db *LevelDb) FetchUnSpentTxByShaList(txShaList []*wire.ShaHash) []*database.TxListReply { db.dbLock.Lock() defer db.dbLock.Unlock() replies := make([]*database.TxListReply, len(txShaList)) for i, txsha := range txShaList { tx, blockSha, height, txspent, err := db.fetchTxDataBySha(txsha) btxspent := []bool{} if err == nil { btxspent = make([]bool, len(tx.TxOut), len(tx.TxOut)) for idx := range tx.TxOut { byteidx := idx / 8 byteoff := uint(idx % 8) btxspent[idx] = (txspent[byteidx] & (byte(1) << byteoff)) != 0 } } txlre := database.TxListReply{Sha: txsha, Tx: tx, BlkSha: blockSha, Height: height, TxSpent: btxspent, Err: err} replies[i] = &txlre } return replies } // fetchTxDataBySha returns several pieces of data regarding the given sha. func (db *LevelDb) fetchTxDataBySha(txsha *wire.ShaHash) (rtx *wire.MsgTx, rblksha *wire.ShaHash, rheight int32, rtxspent []byte, err error) { var blkHeight int32 var txspent []byte var txOff, txLen int blkHeight, txOff, txLen, txspent, err = db.getTxData(txsha) if err != nil { if err == leveldb.ErrNotFound { err = database.ErrTxShaMissing } return } return db.fetchTxDataByLoc(blkHeight, txOff, txLen, txspent) } // fetchTxDataByLoc returns several pieces of data regarding the given tx // located by the block/offset/size location func (db *LevelDb) fetchTxDataByLoc(blkHeight int32, txOff int, txLen int, txspent []byte) (rtx *wire.MsgTx, rblksha *wire.ShaHash, rheight int32, rtxspent []byte, err error) { var blksha *wire.ShaHash var blkbuf []byte blksha, blkbuf, err = db.getBlkByHeight(blkHeight) if err != nil { if err == leveldb.ErrNotFound { err = database.ErrTxShaMissing } return } //log.Trace("transaction %v is at block %v %v txoff %v, txlen %v\n", // txsha, blksha, blkHeight, txOff, txLen) if len(blkbuf) < txOff+txLen { err = database.ErrTxShaMissing return } rbuf := bytes.NewReader(blkbuf[txOff : txOff+txLen]) var tx wire.MsgTx err = tx.Deserialize(rbuf) if err != nil { log.Warnf("unable to decode tx block %v %v txoff %v txlen %v", blkHeight, blksha, txOff, txLen) return } return &tx, blksha, blkHeight, txspent, nil } // FetchTxBySha returns some data for the given Tx Sha. func (db *LevelDb) FetchTxBySha(txsha *wire.ShaHash) ([]*database.TxListReply, error) { db.dbLock.Lock() defer db.dbLock.Unlock() replylen := 0 replycnt := 0 tx, blksha, height, txspent, txerr := db.fetchTxDataBySha(txsha) if txerr == nil { replylen++ } else { if txerr != database.ErrTxShaMissing { return []*database.TxListReply{}, txerr } } sTxList, fSerr := db.getTxFullySpent(txsha) if fSerr != nil { if fSerr != database.ErrTxShaMissing { return []*database.TxListReply{}, fSerr } } else { replylen += len(sTxList) } replies := make([]*database.TxListReply, replylen) if fSerr == nil { for _, stx := range sTxList { tx, blksha, _, _, err := db.fetchTxDataByLoc( stx.blkHeight, stx.txoff, stx.txlen, []byte{}) if err != nil { if err != leveldb.ErrNotFound { return []*database.TxListReply{}, err } continue } btxspent := make([]bool, len(tx.TxOut), len(tx.TxOut)) for i := range btxspent { btxspent[i] = true } txlre := database.TxListReply{Sha: txsha, Tx: tx, BlkSha: blksha, Height: stx.blkHeight, TxSpent: btxspent, Err: nil} replies[replycnt] = &txlre replycnt++ } } if txerr == nil { btxspent := make([]bool, len(tx.TxOut), len(tx.TxOut)) for idx := range tx.TxOut { byteidx := idx / 8 byteoff := uint(idx % 8) btxspent[idx] = (txspent[byteidx] & (byte(1) << byteoff)) != 0 } txlre := database.TxListReply{Sha: txsha, Tx: tx, BlkSha: blksha, Height: height, TxSpent: btxspent, Err: nil} replies[replycnt] = &txlre replycnt++ } return replies, nil } // addrIndexToKey serializes the passed txAddrIndex for storage within the DB. // We want to use BigEndian to store at least block height and TX offset // in order to ensure that the transactions are sorted in the index. // This gives us the ability to use the index in more client-side // applications that are order-dependent (specifically by dependency). func addrIndexToKey(index *txAddrIndex) []byte { record := make([]byte, addrIndexKeyLength, addrIndexKeyLength) copy(record[0:3], addrIndexKeyPrefix) copy(record[3:23], index.hash160[:]) // The index itself. binary.BigEndian.PutUint32(record[23:27], uint32(index.blkHeight)) binary.BigEndian.PutUint32(record[27:31], uint32(index.txoffset)) binary.BigEndian.PutUint32(record[31:35], uint32(index.txlen)) return record } // unpackTxIndex deserializes the raw bytes of a address tx index. func unpackTxIndex(rawIndex [12]byte) *txAddrIndex { return &txAddrIndex{ blkHeight: int32(binary.BigEndian.Uint32(rawIndex[0:4])), txoffset: int(binary.BigEndian.Uint32(rawIndex[4:8])), txlen: int(binary.BigEndian.Uint32(rawIndex[8:12])), } } // bytesPrefix returns key range that satisfy the given prefix. // This only applicable for the standard 'bytes comparer'. func bytesPrefix(prefix []byte) *util.Range { var limit []byte for i := len(prefix) - 1; i >= 0; i-- { c := prefix[i] if c < 0xff { limit = make([]byte, i+1) copy(limit, prefix) limit[i] = c + 1 break } } return &util.Range{Start: prefix, Limit: limit} } // FetchTxsForAddr looks up and returns all transactions which either // spend from a previously created output of the passed address, or // create a new output locked to the passed address. The, `limit` parameter // should be the max number of transactions to be returned. Additionally, if the // caller wishes to seek forward in the results some amount, the 'seek' // represents how many results to skip. func (db *LevelDb) FetchTxsForAddr(addr btcutil.Address, skip int, limit int) ([]*database.TxListReply, int, error) { db.dbLock.Lock() defer db.dbLock.Unlock() // Enforce constraints for skip and limit. if skip < 0 { return nil, 0, errors.New("offset for skip must be positive") } if limit < 0 { return nil, 0, errors.New("value for limit must be positive") } // Parse address type, bailing on an unknown type. var addrKey []byte switch addr := addr.(type) { case *btcutil.AddressPubKeyHash: hash160 := addr.Hash160() addrKey = hash160[:] case *btcutil.AddressScriptHash: hash160 := addr.Hash160() addrKey = hash160[:] case *btcutil.AddressPubKey: hash160 := addr.AddressPubKeyHash().Hash160() addrKey = hash160[:] default: return nil, 0, database.ErrUnsupportedAddressType } // Create the prefix for our search. addrPrefix := make([]byte, 23, 23) copy(addrPrefix[0:3], addrIndexKeyPrefix) copy(addrPrefix[3:23], addrKey) iter := db.lDb.NewIterator(bytesPrefix(addrPrefix), nil) skipped := 0 for skip != 0 && iter.Next() { skip-- skipped++ } // Iterate through all address indexes that match the targeted prefix. var replies []*database.TxListReply var rawIndex [12]byte for iter.Next() && limit != 0 { copy(rawIndex[:], iter.Key()[23:35]) addrIndex := unpackTxIndex(rawIndex) tx, blkSha, blkHeight, _, err := db.fetchTxDataByLoc(addrIndex.blkHeight, addrIndex.txoffset, addrIndex.txlen, []byte{}) if err != nil { // Eat a possible error due to a potential re-org. continue } txSha := tx.TxSha() txReply := &database.TxListReply{Sha: &txSha, Tx: tx, BlkSha: blkSha, Height: blkHeight, TxSpent: []bool{}, Err: err} replies = append(replies, txReply) limit-- } iter.Release() if err := iter.Error(); err != nil { return nil, 0, err } return replies, skipped, nil } // UpdateAddrIndexForBlock updates the stored addrindex with passed // index information for a particular block height. Additionally, it // will update the stored meta-data related to the curent tip of the // addr index. These two operations are performed in an atomic // transaction which is commited before the function returns. // Transactions indexed by address are stored with the following format: // * prefix || hash160 || blockHeight || txoffset || txlen // Indexes are stored purely in the key, with blank data for the actual value // in order to facilitate ease of iteration by their shared prefix and // also to allow limiting the number of returned transactions (RPC). // Alternatively, indexes for each address could be stored as an // append-only list for the stored value. However, this add unnecessary // overhead when storing and retrieving since the entire list must // be fetched each time. func (db *LevelDb) UpdateAddrIndexForBlock(blkSha *wire.ShaHash, blkHeight int32, addrIndex database.BlockAddrIndex) error { db.dbLock.Lock() defer db.dbLock.Unlock() var blankData []byte batch := db.lBatch() defer db.lbatch.Reset() // Write all data for the new address indexes in a single batch // transaction. for addrKey, indexes := range addrIndex { for _, txLoc := range indexes { index := &txAddrIndex{ hash160: addrKey, blkHeight: blkHeight, txoffset: txLoc.TxStart, txlen: txLoc.TxLen, } // The index is stored purely in the key. packedIndex := addrIndexToKey(index) batch.Put(packedIndex, blankData) } } // Update tip of addrindex. newIndexTip := make([]byte, 40, 40) copy(newIndexTip[0:32], blkSha[:]) binary.LittleEndian.PutUint64(newIndexTip[32:40], uint64(blkHeight)) batch.Put(addrIndexMetaDataKey, newIndexTip) // Ensure we're writing an address index version newIndexVersion := make([]byte, 2, 2) binary.LittleEndian.PutUint16(newIndexVersion[0:2], uint16(addrIndexCurrentVersion)) batch.Put(addrIndexVersionKey, newIndexVersion) if err := db.lDb.Write(batch, db.wo); err != nil { return err } db.lastAddrIndexBlkIdx = blkHeight db.lastAddrIndexBlkSha = *blkSha return nil } // DeleteAddrIndex deletes the entire addrindex stored within the DB. // It also resets the cached in-memory metadata about the addr index. func (db *LevelDb) DeleteAddrIndex() error { db.dbLock.Lock() defer db.dbLock.Unlock() batch := db.lBatch() defer batch.Reset() // Delete the entire index along with any metadata about it. iter := db.lDb.NewIterator(bytesPrefix(addrIndexKeyPrefix), db.ro) numInBatch := 0 for iter.Next() { key := iter.Key() // With a 24-bit index key prefix, 1 in every 2^24 keys is a collision. // We check the length to make sure we only delete address index keys. if len(key) == addrIndexKeyLength { batch.Delete(key) numInBatch++ } // Delete in chunks to potentially avoid very large batches. if numInBatch >= batchDeleteThreshold { if err := db.lDb.Write(batch, db.wo); err != nil { iter.Release() return err } batch.Reset() numInBatch = 0 } } iter.Release() if err := iter.Error(); err != nil { return err } batch.Delete(addrIndexMetaDataKey) batch.Delete(addrIndexVersionKey) if err := db.lDb.Write(batch, db.wo); err != nil { return err } db.lastAddrIndexBlkIdx = -1 db.lastAddrIndexBlkSha = wire.ShaHash{} return nil } // deleteOldAddrIndex deletes the entire addrindex stored within the DB for a // 2-byte addrIndexKeyPrefix. It also resets the cached in-memory metadata about // the addr index. func (db *LevelDb) deleteOldAddrIndex() error { db.dbLock.Lock() defer db.dbLock.Unlock() batch := db.lBatch() defer batch.Reset() // Delete the entire index along with any metadata about it. iter := db.lDb.NewIterator(bytesPrefix([]byte("a-")), db.ro) numInBatch := 0 for iter.Next() { key := iter.Key() // With a 24-bit index key prefix, 1 in every 2^24 keys is a collision. // We check the length to make sure we only delete address index keys. // We also check the last two bytes to make sure the suffix doesn't // match other types of index that are 34 bytes long. if len(key) == 34 && !bytes.HasSuffix(key, recordSuffixTx) && !bytes.HasSuffix(key, recordSuffixSpentTx) { batch.Delete(key) numInBatch++ } // Delete in chunks to potentially avoid very large batches. if numInBatch >= batchDeleteThreshold { if err := db.lDb.Write(batch, db.wo); err != nil { iter.Release() return err } batch.Reset() numInBatch = 0 } } iter.Release() if err := iter.Error(); err != nil { return err } batch.Delete(addrIndexMetaDataKey) batch.Delete(addrIndexVersionKey) if err := db.lDb.Write(batch, db.wo); err != nil { return err } db.lastAddrIndexBlkIdx = -1 db.lastAddrIndexBlkSha = wire.ShaHash{} return nil }