560305f601
- uses newer version of go-ethereum required for go1.11
968 lines
34 KiB
Go
968 lines
34 KiB
Go
// Copyright (c) 2016 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 indexers
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import (
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"errors"
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"fmt"
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"sync"
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"github.com/btcsuite/btcd/blockchain"
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"github.com/btcsuite/btcd/chaincfg"
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"github.com/btcsuite/btcd/chaincfg/chainhash"
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"github.com/btcsuite/btcd/database"
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"github.com/btcsuite/btcd/txscript"
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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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const (
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// addrIndexName is the human-readable name for the index.
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addrIndexName = "address index"
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// level0MaxEntries is the maximum number of transactions that are
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// stored in level 0 of an address index entry. Subsequent levels store
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// 2^n * level0MaxEntries entries, or in words, double the maximum of
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// the previous level.
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level0MaxEntries = 8
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// addrKeySize is the number of bytes an address key consumes in the
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// index. It consists of 1 byte address type + 20 bytes hash160.
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addrKeySize = 1 + 20
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// levelKeySize is the number of bytes a level key in the address index
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// consumes. It consists of the address key + 1 byte for the level.
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levelKeySize = addrKeySize + 1
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// levelOffset is the offset in the level key which identifes the level.
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levelOffset = levelKeySize - 1
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// addrKeyTypePubKeyHash is the address type in an address key which
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// represents both a pay-to-pubkey-hash and a pay-to-pubkey address.
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// This is done because both are identical for the purposes of the
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// address index.
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addrKeyTypePubKeyHash = 0
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// addrKeyTypeScriptHash is the address type in an address key which
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// represents a pay-to-script-hash address. This is necessary because
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// the hash of a pubkey address might be the same as that of a script
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// hash.
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addrKeyTypeScriptHash = 1
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// addrKeyTypePubKeyHash is the address type in an address key which
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// represents a pay-to-witness-pubkey-hash address. This is required
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// as the 20-byte data push of a p2wkh witness program may be the same
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// data push used a p2pkh address.
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addrKeyTypeWitnessPubKeyHash = 2
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// addrKeyTypeScriptHash is the address type in an address key which
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// represents a pay-to-witness-script-hash address. This is required,
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// as p2wsh are distinct from p2sh addresses since they use a new
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// script template, as well as a 32-byte data push.
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addrKeyTypeWitnessScriptHash = 3
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// Size of a transaction entry. It consists of 4 bytes block id + 4
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// bytes offset + 4 bytes length.
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txEntrySize = 4 + 4 + 4
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)
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var (
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// addrIndexKey is the key of the address index and the db bucket used
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// to house it.
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addrIndexKey = []byte("txbyaddridx")
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// errUnsupportedAddressType is an error that is used to signal an
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// unsupported address type has been used.
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errUnsupportedAddressType = errors.New("address type is not supported " +
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"by the address index")
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)
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// -----------------------------------------------------------------------------
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// The address index maps addresses referenced in the blockchain to a list of
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// all the transactions involving that address. Transactions are stored
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// according to their order of appearance in the blockchain. That is to say
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// first by block height and then by offset inside the block. It is also
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// important to note that this implementation requires the transaction index
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// since it is needed in order to catch up old blocks due to the fact the spent
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// outputs will already be pruned from the utxo set.
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//
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// The approach used to store the index is similar to a log-structured merge
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// tree (LSM tree) and is thus similar to how leveldb works internally.
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//
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// Every address consists of one or more entries identified by a level starting
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// from 0 where each level holds a maximum number of entries such that each
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// subsequent level holds double the maximum of the previous one. In equation
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// form, the number of entries each level holds is 2^n * firstLevelMaxSize.
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//
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// New transactions are appended to level 0 until it becomes full at which point
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// the entire level 0 entry is appended to the level 1 entry and level 0 is
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// cleared. This process continues until level 1 becomes full at which point it
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// will be appended to level 2 and cleared and so on.
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//
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// The result of this is the lower levels contain newer transactions and the
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// transactions within each level are ordered from oldest to newest.
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//
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// The intent of this approach is to provide a balance between space efficiency
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// and indexing cost. Storing one entry per transaction would have the lowest
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// indexing cost, but would waste a lot of space because the same address hash
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// would be duplicated for every transaction key. On the other hand, storing a
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// single entry with all transactions would be the most space efficient, but
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// would cause indexing cost to grow quadratically with the number of
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// transactions involving the same address. The approach used here provides
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// logarithmic insertion and retrieval.
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//
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// The serialized key format is:
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//
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// <addr type><addr hash><level>
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//
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// Field Type Size
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// addr type uint8 1 byte
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// addr hash hash160 20 bytes
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// level uint8 1 byte
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// -----
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// Total: 22 bytes
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//
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// The serialized value format is:
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//
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// [<block id><start offset><tx length>,...]
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//
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// Field Type Size
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// block id uint32 4 bytes
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// start offset uint32 4 bytes
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// tx length uint32 4 bytes
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// -----
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// Total: 12 bytes per indexed tx
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// -----------------------------------------------------------------------------
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// fetchBlockHashFunc defines a callback function to use in order to convert a
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// serialized block ID to an associated block hash.
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type fetchBlockHashFunc func(serializedID []byte) (*chainhash.Hash, error)
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// serializeAddrIndexEntry serializes the provided block id and transaction
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// location according to the format described in detail above.
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func serializeAddrIndexEntry(blockID uint32, txLoc wire.TxLoc) []byte {
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// Serialize the entry.
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serialized := make([]byte, 12)
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byteOrder.PutUint32(serialized, blockID)
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byteOrder.PutUint32(serialized[4:], uint32(txLoc.TxStart))
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byteOrder.PutUint32(serialized[8:], uint32(txLoc.TxLen))
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return serialized
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}
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// deserializeAddrIndexEntry decodes the passed serialized byte slice into the
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// provided region struct according to the format described in detail above and
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// uses the passed block hash fetching function in order to conver the block ID
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// to the associated block hash.
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func deserializeAddrIndexEntry(serialized []byte, region *database.BlockRegion, fetchBlockHash fetchBlockHashFunc) error {
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// Ensure there are enough bytes to decode.
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if len(serialized) < txEntrySize {
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return errDeserialize("unexpected end of data")
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}
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hash, err := fetchBlockHash(serialized[0:4])
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if err != nil {
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return err
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}
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region.Hash = hash
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region.Offset = byteOrder.Uint32(serialized[4:8])
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region.Len = byteOrder.Uint32(serialized[8:12])
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return nil
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}
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// keyForLevel returns the key for a specific address and level in the address
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// index entry.
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func keyForLevel(addrKey [addrKeySize]byte, level uint8) [levelKeySize]byte {
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var key [levelKeySize]byte
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copy(key[:], addrKey[:])
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key[levelOffset] = level
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return key
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}
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// dbPutAddrIndexEntry updates the address index to include the provided entry
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// according to the level-based scheme described in detail above.
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func dbPutAddrIndexEntry(bucket internalBucket, addrKey [addrKeySize]byte, blockID uint32, txLoc wire.TxLoc) error {
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// Start with level 0 and its initial max number of entries.
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curLevel := uint8(0)
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maxLevelBytes := level0MaxEntries * txEntrySize
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// Simply append the new entry to level 0 and return now when it will
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// fit. This is the most common path.
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newData := serializeAddrIndexEntry(blockID, txLoc)
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level0Key := keyForLevel(addrKey, 0)
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level0Data := bucket.Get(level0Key[:])
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if len(level0Data)+len(newData) <= maxLevelBytes {
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mergedData := newData
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if len(level0Data) > 0 {
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mergedData = make([]byte, len(level0Data)+len(newData))
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copy(mergedData, level0Data)
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copy(mergedData[len(level0Data):], newData)
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}
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return bucket.Put(level0Key[:], mergedData)
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}
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// At this point, level 0 is full, so merge each level into higher
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// levels as many times as needed to free up level 0.
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prevLevelData := level0Data
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for {
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// Each new level holds twice as much as the previous one.
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curLevel++
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maxLevelBytes *= 2
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// Move to the next level as long as the current level is full.
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curLevelKey := keyForLevel(addrKey, curLevel)
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curLevelData := bucket.Get(curLevelKey[:])
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if len(curLevelData) == maxLevelBytes {
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prevLevelData = curLevelData
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continue
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}
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// The current level has room for the data in the previous one,
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// so merge the data from previous level into it.
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mergedData := prevLevelData
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if len(curLevelData) > 0 {
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mergedData = make([]byte, len(curLevelData)+
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len(prevLevelData))
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copy(mergedData, curLevelData)
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copy(mergedData[len(curLevelData):], prevLevelData)
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}
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err := bucket.Put(curLevelKey[:], mergedData)
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if err != nil {
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return err
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}
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// Move all of the levels before the previous one up a level.
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for mergeLevel := curLevel - 1; mergeLevel > 0; mergeLevel-- {
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mergeLevelKey := keyForLevel(addrKey, mergeLevel)
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prevLevelKey := keyForLevel(addrKey, mergeLevel-1)
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prevData := bucket.Get(prevLevelKey[:])
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err := bucket.Put(mergeLevelKey[:], prevData)
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if err != nil {
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return err
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}
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}
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break
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}
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// Finally, insert the new entry into level 0 now that it is empty.
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return bucket.Put(level0Key[:], newData)
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}
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// dbFetchAddrIndexEntries returns block regions for transactions referenced by
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// the given address key and the number of entries skipped since it could have
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// been less in the case where there are less total entries than the requested
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// number of entries to skip.
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func dbFetchAddrIndexEntries(bucket internalBucket, addrKey [addrKeySize]byte, numToSkip, numRequested uint32, reverse bool, fetchBlockHash fetchBlockHashFunc) ([]database.BlockRegion, uint32, error) {
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// When the reverse flag is not set, all levels need to be fetched
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// because numToSkip and numRequested are counted from the oldest
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// transactions (highest level) and thus the total count is needed.
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// However, when the reverse flag is set, only enough records to satisfy
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// the requested amount are needed.
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var level uint8
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var serialized []byte
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for !reverse || len(serialized) < int(numToSkip+numRequested)*txEntrySize {
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curLevelKey := keyForLevel(addrKey, level)
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levelData := bucket.Get(curLevelKey[:])
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if levelData == nil {
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// Stop when there are no more levels.
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break
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}
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// Higher levels contain older transactions, so prepend them.
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prepended := make([]byte, len(serialized)+len(levelData))
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copy(prepended, levelData)
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copy(prepended[len(levelData):], serialized)
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serialized = prepended
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level++
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}
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// When the requested number of entries to skip is larger than the
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// number available, skip them all and return now with the actual number
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// skipped.
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numEntries := uint32(len(serialized) / txEntrySize)
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if numToSkip >= numEntries {
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return nil, numEntries, nil
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}
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// Nothing more to do when there are no requested entries.
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if numRequested == 0 {
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return nil, numToSkip, nil
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}
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// Limit the number to load based on the number of available entries,
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// the number to skip, and the number requested.
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numToLoad := numEntries - numToSkip
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if numToLoad > numRequested {
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numToLoad = numRequested
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}
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// Start the offset after all skipped entries and load the calculated
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// number.
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results := make([]database.BlockRegion, numToLoad)
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for i := uint32(0); i < numToLoad; i++ {
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// Calculate the read offset according to the reverse flag.
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var offset uint32
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if reverse {
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offset = (numEntries - numToSkip - i - 1) * txEntrySize
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} else {
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offset = (numToSkip + i) * txEntrySize
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}
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// Deserialize and populate the result.
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err := deserializeAddrIndexEntry(serialized[offset:],
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&results[i], fetchBlockHash)
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if err != nil {
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// Ensure any deserialization errors are returned as
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// database corruption errors.
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if isDeserializeErr(err) {
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err = database.Error{
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ErrorCode: database.ErrCorruption,
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Description: fmt.Sprintf("failed to "+
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"deserialized address index "+
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"for key %x: %v", addrKey, err),
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}
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}
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return nil, 0, err
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}
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}
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return results, numToSkip, nil
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}
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// minEntriesToReachLevel returns the minimum number of entries that are
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// required to reach the given address index level.
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func minEntriesToReachLevel(level uint8) int {
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maxEntriesForLevel := level0MaxEntries
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minRequired := 1
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for l := uint8(1); l <= level; l++ {
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minRequired += maxEntriesForLevel
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maxEntriesForLevel *= 2
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}
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return minRequired
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}
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// maxEntriesForLevel returns the maximum number of entries allowed for the
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// given address index level.
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func maxEntriesForLevel(level uint8) int {
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numEntries := level0MaxEntries
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for l := level; l > 0; l-- {
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numEntries *= 2
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}
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return numEntries
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}
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// dbRemoveAddrIndexEntries removes the specified number of entries from from
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// the address index for the provided key. An assertion error will be returned
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// if the count exceeds the total number of entries in the index.
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func dbRemoveAddrIndexEntries(bucket internalBucket, addrKey [addrKeySize]byte, count int) error {
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// Nothing to do if no entries are being deleted.
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if count <= 0 {
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return nil
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}
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// Make use of a local map to track pending updates and define a closure
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// to apply it to the database. This is done in order to reduce the
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// number of database reads and because there is more than one exit
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// path that needs to apply the updates.
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pendingUpdates := make(map[uint8][]byte)
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applyPending := func() error {
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for level, data := range pendingUpdates {
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curLevelKey := keyForLevel(addrKey, level)
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if len(data) == 0 {
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err := bucket.Delete(curLevelKey[:])
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if err != nil {
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return err
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}
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continue
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}
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err := bucket.Put(curLevelKey[:], data)
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if err != nil {
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return err
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}
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}
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return nil
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}
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// Loop forwards through the levels while removing entries until the
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// specified number has been removed. This will potentially result in
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// entirely empty lower levels which will be backfilled below.
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var highestLoadedLevel uint8
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numRemaining := count
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for level := uint8(0); numRemaining > 0; level++ {
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// Load the data for the level from the database.
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curLevelKey := keyForLevel(addrKey, level)
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curLevelData := bucket.Get(curLevelKey[:])
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if len(curLevelData) == 0 && numRemaining > 0 {
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return AssertError(fmt.Sprintf("dbRemoveAddrIndexEntries "+
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"not enough entries for address key %x to "+
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"delete %d entries", addrKey, count))
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}
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pendingUpdates[level] = curLevelData
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highestLoadedLevel = level
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// Delete the entire level as needed.
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numEntries := len(curLevelData) / txEntrySize
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if numRemaining >= numEntries {
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pendingUpdates[level] = nil
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numRemaining -= numEntries
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continue
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}
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// Remove remaining entries to delete from the level.
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offsetEnd := len(curLevelData) - (numRemaining * txEntrySize)
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pendingUpdates[level] = curLevelData[:offsetEnd]
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break
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}
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// When all elements in level 0 were not removed there is nothing left
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// to do other than updating the database.
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if len(pendingUpdates[0]) != 0 {
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return applyPending()
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}
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// At this point there are one or more empty levels before the current
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// level which need to be backfilled and the current level might have
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// had some entries deleted from it as well. Since all levels after
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// level 0 are required to either be empty, half full, or completely
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// full, the current level must be adjusted accordingly by backfilling
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// each previous levels in a way which satisfies the requirements. Any
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// entries that are left are assigned to level 0 after the loop as they
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// are guaranteed to fit by the logic in the loop. In other words, this
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// effectively squashes all remaining entries in the current level into
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// the lowest possible levels while following the level rules.
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//
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// Note that the level after the current level might also have entries
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// and gaps are not allowed, so this also keeps track of the lowest
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// empty level so the code below knows how far to backfill in case it is
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// required.
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lowestEmptyLevel := uint8(255)
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curLevelData := pendingUpdates[highestLoadedLevel]
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curLevelMaxEntries := maxEntriesForLevel(highestLoadedLevel)
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for level := highestLoadedLevel; level > 0; level-- {
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// When there are not enough entries left in the current level
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// for the number that would be required to reach it, clear the
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// the current level which effectively moves them all up to the
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// previous level on the next iteration. Otherwise, there are
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// are sufficient entries, so update the current level to
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// contain as many entries as possible while still leaving
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// enough remaining entries required to reach the level.
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numEntries := len(curLevelData) / txEntrySize
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prevLevelMaxEntries := curLevelMaxEntries / 2
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minPrevRequired := minEntriesToReachLevel(level - 1)
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if numEntries < prevLevelMaxEntries+minPrevRequired {
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lowestEmptyLevel = level
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pendingUpdates[level] = nil
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} else {
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// This level can only be completely full or half full,
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// so choose the appropriate offset to ensure enough
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// entries remain to reach the level.
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var offset int
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if numEntries-curLevelMaxEntries >= minPrevRequired {
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offset = curLevelMaxEntries * txEntrySize
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} else {
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offset = prevLevelMaxEntries * txEntrySize
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}
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pendingUpdates[level] = curLevelData[:offset]
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curLevelData = curLevelData[offset:]
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}
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curLevelMaxEntries = prevLevelMaxEntries
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}
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pendingUpdates[0] = curLevelData
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if len(curLevelData) == 0 {
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lowestEmptyLevel = 0
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}
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// When the highest loaded level is empty, it's possible the level after
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// it still has data and thus that data needs to be backfilled as well.
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for len(pendingUpdates[highestLoadedLevel]) == 0 {
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// When the next level is empty too, the is no data left to
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// continue backfilling, so there is nothing left to do.
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// Otherwise, populate the pending updates map with the newly
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// loaded data and update the highest loaded level accordingly.
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level := highestLoadedLevel + 1
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curLevelKey := keyForLevel(addrKey, level)
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levelData := bucket.Get(curLevelKey[:])
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if len(levelData) == 0 {
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break
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}
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pendingUpdates[level] = levelData
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highestLoadedLevel = level
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|
|
// At this point the highest level is not empty, but it might
|
|
// be half full. When that is the case, move it up a level to
|
|
// simplify the code below which backfills all lower levels that
|
|
// are still empty. This also means the current level will be
|
|
// empty, so the loop will perform another another iteration to
|
|
// potentially backfill this level with data from the next one.
|
|
curLevelMaxEntries := maxEntriesForLevel(level)
|
|
if len(levelData)/txEntrySize != curLevelMaxEntries {
|
|
pendingUpdates[level] = nil
|
|
pendingUpdates[level-1] = levelData
|
|
level--
|
|
curLevelMaxEntries /= 2
|
|
}
|
|
|
|
// Backfill all lower levels that are still empty by iteratively
|
|
// halfing the data until the lowest empty level is filled.
|
|
for level > lowestEmptyLevel {
|
|
offset := (curLevelMaxEntries / 2) * txEntrySize
|
|
pendingUpdates[level] = levelData[:offset]
|
|
levelData = levelData[offset:]
|
|
pendingUpdates[level-1] = levelData
|
|
level--
|
|
curLevelMaxEntries /= 2
|
|
}
|
|
|
|
// The lowest possible empty level is now the highest loaded
|
|
// level.
|
|
lowestEmptyLevel = highestLoadedLevel
|
|
}
|
|
|
|
// Apply the pending updates.
|
|
return applyPending()
|
|
}
|
|
|
|
// addrToKey converts known address types to an addrindex key. An error is
|
|
// returned for unsupported types.
|
|
func addrToKey(addr btcutil.Address) ([addrKeySize]byte, error) {
|
|
switch addr := addr.(type) {
|
|
case *btcutil.AddressPubKeyHash:
|
|
var result [addrKeySize]byte
|
|
result[0] = addrKeyTypePubKeyHash
|
|
copy(result[1:], addr.Hash160()[:])
|
|
return result, nil
|
|
|
|
case *btcutil.AddressScriptHash:
|
|
var result [addrKeySize]byte
|
|
result[0] = addrKeyTypeScriptHash
|
|
copy(result[1:], addr.Hash160()[:])
|
|
return result, nil
|
|
|
|
case *btcutil.AddressPubKey:
|
|
var result [addrKeySize]byte
|
|
result[0] = addrKeyTypePubKeyHash
|
|
copy(result[1:], addr.AddressPubKeyHash().Hash160()[:])
|
|
return result, nil
|
|
|
|
case *btcutil.AddressWitnessScriptHash:
|
|
var result [addrKeySize]byte
|
|
result[0] = addrKeyTypeWitnessScriptHash
|
|
|
|
// P2WSH outputs utilize a 32-byte data push created by hashing
|
|
// the script with sha256 instead of hash160. In order to keep
|
|
// all address entries within the database uniform and compact,
|
|
// we use a hash160 here to reduce the size of the salient data
|
|
// push to 20-bytes.
|
|
copy(result[1:], btcutil.Hash160(addr.ScriptAddress()))
|
|
return result, nil
|
|
|
|
case *btcutil.AddressWitnessPubKeyHash:
|
|
var result [addrKeySize]byte
|
|
result[0] = addrKeyTypeWitnessPubKeyHash
|
|
copy(result[1:], addr.Hash160()[:])
|
|
return result, nil
|
|
}
|
|
|
|
return [addrKeySize]byte{}, errUnsupportedAddressType
|
|
}
|
|
|
|
// AddrIndex implements a transaction by address index. That is to say, it
|
|
// supports querying all transactions that reference a given address because
|
|
// they are either crediting or debiting the address. The returned transactions
|
|
// are ordered according to their order of appearance in the blockchain. In
|
|
// other words, first by block height and then by offset inside the block.
|
|
//
|
|
// In addition, support is provided for a memory-only index of unconfirmed
|
|
// transactions such as those which are kept in the memory pool before inclusion
|
|
// in a block.
|
|
type AddrIndex struct {
|
|
// The following fields are set when the instance is created and can't
|
|
// be changed afterwards, so there is no need to protect them with a
|
|
// separate mutex.
|
|
db database.DB
|
|
chainParams *chaincfg.Params
|
|
|
|
// The following fields are used to quickly link transactions and
|
|
// addresses that have not been included into a block yet when an
|
|
// address index is being maintained. The are protected by the
|
|
// unconfirmedLock field.
|
|
//
|
|
// The txnsByAddr field is used to keep an index of all transactions
|
|
// which either create an output to a given address or spend from a
|
|
// previous output to it keyed by the address.
|
|
//
|
|
// The addrsByTx field is essentially the reverse and is used to
|
|
// keep an index of all addresses which a given transaction involves.
|
|
// This allows fairly efficient updates when transactions are removed
|
|
// once they are included into a block.
|
|
unconfirmedLock sync.RWMutex
|
|
txnsByAddr map[[addrKeySize]byte]map[chainhash.Hash]*btcutil.Tx
|
|
addrsByTx map[chainhash.Hash]map[[addrKeySize]byte]struct{}
|
|
}
|
|
|
|
// Ensure the AddrIndex type implements the Indexer interface.
|
|
var _ Indexer = (*AddrIndex)(nil)
|
|
|
|
// Ensure the AddrIndex type implements the NeedsInputser interface.
|
|
var _ NeedsInputser = (*AddrIndex)(nil)
|
|
|
|
// NeedsInputs signals that the index requires the referenced inputs in order
|
|
// to properly create the index.
|
|
//
|
|
// This implements the NeedsInputser interface.
|
|
func (idx *AddrIndex) NeedsInputs() bool {
|
|
return true
|
|
}
|
|
|
|
// Init is only provided to satisfy the Indexer interface as there is nothing to
|
|
// initialize for this index.
|
|
//
|
|
// This is part of the Indexer interface.
|
|
func (idx *AddrIndex) Init() error {
|
|
// Nothing to do.
|
|
return nil
|
|
}
|
|
|
|
// Key returns the database key to use for the index as a byte slice.
|
|
//
|
|
// This is part of the Indexer interface.
|
|
func (idx *AddrIndex) Key() []byte {
|
|
return addrIndexKey
|
|
}
|
|
|
|
// Name returns the human-readable name of the index.
|
|
//
|
|
// This is part of the Indexer interface.
|
|
func (idx *AddrIndex) Name() string {
|
|
return addrIndexName
|
|
}
|
|
|
|
// Create is invoked when the indexer manager determines the index needs
|
|
// to be created for the first time. It creates the bucket for the address
|
|
// index.
|
|
//
|
|
// This is part of the Indexer interface.
|
|
func (idx *AddrIndex) Create(dbTx database.Tx) error {
|
|
_, err := dbTx.Metadata().CreateBucket(addrIndexKey)
|
|
return err
|
|
}
|
|
|
|
// writeIndexData represents the address index data to be written for one block.
|
|
// It consists of the address mapped to an ordered list of the transactions
|
|
// that involve the address in block. It is ordered so the transactions can be
|
|
// stored in the order they appear in the block.
|
|
type writeIndexData map[[addrKeySize]byte][]int
|
|
|
|
// indexPkScript extracts all standard addresses from the passed public key
|
|
// script and maps each of them to the associated transaction using the passed
|
|
// map.
|
|
func (idx *AddrIndex) indexPkScript(data writeIndexData, pkScript []byte, txIdx int) {
|
|
// Nothing to index if the script is non-standard or otherwise doesn't
|
|
// contain any addresses.
|
|
_, addrs, _, err := txscript.ExtractPkScriptAddrs(pkScript,
|
|
idx.chainParams)
|
|
if err != nil || len(addrs) == 0 {
|
|
return
|
|
}
|
|
|
|
for _, addr := range addrs {
|
|
addrKey, err := addrToKey(addr)
|
|
if err != nil {
|
|
// Ignore unsupported address types.
|
|
continue
|
|
}
|
|
|
|
// Avoid inserting the transaction more than once. Since the
|
|
// transactions are indexed serially any duplicates will be
|
|
// indexed in a row, so checking the most recent entry for the
|
|
// address is enough to detect duplicates.
|
|
indexedTxns := data[addrKey]
|
|
numTxns := len(indexedTxns)
|
|
if numTxns > 0 && indexedTxns[numTxns-1] == txIdx {
|
|
continue
|
|
}
|
|
indexedTxns = append(indexedTxns, txIdx)
|
|
data[addrKey] = indexedTxns
|
|
}
|
|
}
|
|
|
|
// indexBlock extract all of the standard addresses from all of the transactions
|
|
// in the passed block and maps each of them to the associated transaction using
|
|
// the passed map.
|
|
func (idx *AddrIndex) indexBlock(data writeIndexData, block *btcutil.Block,
|
|
stxos []blockchain.SpentTxOut) {
|
|
|
|
stxoIndex := 0
|
|
for txIdx, tx := range block.Transactions() {
|
|
// Coinbases do not reference any inputs. Since the block is
|
|
// required to have already gone through full validation, it has
|
|
// already been proven on the first transaction in the block is
|
|
// a coinbase.
|
|
if txIdx != 0 {
|
|
for range tx.MsgTx().TxIn {
|
|
// We'll access the slice of all the
|
|
// transactions spent in this block properly
|
|
// ordered to fetch the previous input script.
|
|
pkScript := stxos[stxoIndex].PkScript
|
|
idx.indexPkScript(data, pkScript, txIdx)
|
|
|
|
// With an input indexed, we'll advance the
|
|
// stxo coutner.
|
|
stxoIndex++
|
|
}
|
|
}
|
|
|
|
for _, txOut := range tx.MsgTx().TxOut {
|
|
idx.indexPkScript(data, txOut.PkScript, txIdx)
|
|
}
|
|
}
|
|
}
|
|
|
|
// ConnectBlock is invoked by the index manager when a new block has been
|
|
// connected to the main chain. This indexer adds a mapping for each address
|
|
// the transactions in the block involve.
|
|
//
|
|
// This is part of the Indexer interface.
|
|
func (idx *AddrIndex) ConnectBlock(dbTx database.Tx, block *btcutil.Block,
|
|
stxos []blockchain.SpentTxOut) error {
|
|
|
|
// The offset and length of the transactions within the serialized
|
|
// block.
|
|
txLocs, err := block.TxLoc()
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
// Get the internal block ID associated with the block.
|
|
blockID, err := dbFetchBlockIDByHash(dbTx, block.Hash())
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
// Build all of the address to transaction mappings in a local map.
|
|
addrsToTxns := make(writeIndexData)
|
|
idx.indexBlock(addrsToTxns, block, stxos)
|
|
|
|
// Add all of the index entries for each address.
|
|
addrIdxBucket := dbTx.Metadata().Bucket(addrIndexKey)
|
|
for addrKey, txIdxs := range addrsToTxns {
|
|
for _, txIdx := range txIdxs {
|
|
err := dbPutAddrIndexEntry(addrIdxBucket, addrKey,
|
|
blockID, txLocs[txIdx])
|
|
if err != nil {
|
|
return err
|
|
}
|
|
}
|
|
}
|
|
|
|
return nil
|
|
}
|
|
|
|
// DisconnectBlock is invoked by the index manager when a block has been
|
|
// disconnected from the main chain. This indexer removes the address mappings
|
|
// each transaction in the block involve.
|
|
//
|
|
// This is part of the Indexer interface.
|
|
func (idx *AddrIndex) DisconnectBlock(dbTx database.Tx, block *btcutil.Block,
|
|
stxos []blockchain.SpentTxOut) error {
|
|
|
|
// Build all of the address to transaction mappings in a local map.
|
|
addrsToTxns := make(writeIndexData)
|
|
idx.indexBlock(addrsToTxns, block, stxos)
|
|
|
|
// Remove all of the index entries for each address.
|
|
bucket := dbTx.Metadata().Bucket(addrIndexKey)
|
|
for addrKey, txIdxs := range addrsToTxns {
|
|
err := dbRemoveAddrIndexEntries(bucket, addrKey, len(txIdxs))
|
|
if err != nil {
|
|
return err
|
|
}
|
|
}
|
|
|
|
return nil
|
|
}
|
|
|
|
// TxRegionsForAddress returns a slice of block regions which identify each
|
|
// transaction that involves the passed address according to the specified
|
|
// number to skip, number requested, and whether or not the results should be
|
|
// reversed. It also returns the number actually skipped since it could be less
|
|
// in the case where there are not enough entries.
|
|
//
|
|
// NOTE: These results only include transactions confirmed in blocks. See the
|
|
// UnconfirmedTxnsForAddress method for obtaining unconfirmed transactions
|
|
// that involve a given address.
|
|
//
|
|
// This function is safe for concurrent access.
|
|
func (idx *AddrIndex) TxRegionsForAddress(dbTx database.Tx, addr btcutil.Address, numToSkip, numRequested uint32, reverse bool) ([]database.BlockRegion, uint32, error) {
|
|
addrKey, err := addrToKey(addr)
|
|
if err != nil {
|
|
return nil, 0, err
|
|
}
|
|
|
|
var regions []database.BlockRegion
|
|
var skipped uint32
|
|
err = idx.db.View(func(dbTx database.Tx) error {
|
|
// Create closure to lookup the block hash given the ID using
|
|
// the database transaction.
|
|
fetchBlockHash := func(id []byte) (*chainhash.Hash, error) {
|
|
// Deserialize and populate the result.
|
|
return dbFetchBlockHashBySerializedID(dbTx, id)
|
|
}
|
|
|
|
var err error
|
|
addrIdxBucket := dbTx.Metadata().Bucket(addrIndexKey)
|
|
regions, skipped, err = dbFetchAddrIndexEntries(addrIdxBucket,
|
|
addrKey, numToSkip, numRequested, reverse,
|
|
fetchBlockHash)
|
|
return err
|
|
})
|
|
|
|
return regions, skipped, err
|
|
}
|
|
|
|
// indexUnconfirmedAddresses modifies the unconfirmed (memory-only) address
|
|
// index to include mappings for the addresses encoded by the passed public key
|
|
// script to the transaction.
|
|
//
|
|
// This function is safe for concurrent access.
|
|
func (idx *AddrIndex) indexUnconfirmedAddresses(pkScript []byte, tx *btcutil.Tx) {
|
|
// The error is ignored here since the only reason it can fail is if the
|
|
// script fails to parse and it was already validated before being
|
|
// admitted to the mempool.
|
|
_, addresses, _, _ := txscript.ExtractPkScriptAddrs(pkScript,
|
|
idx.chainParams)
|
|
for _, addr := range addresses {
|
|
// Ignore unsupported address types.
|
|
addrKey, err := addrToKey(addr)
|
|
if err != nil {
|
|
continue
|
|
}
|
|
|
|
// Add a mapping from the address to the transaction.
|
|
idx.unconfirmedLock.Lock()
|
|
addrIndexEntry := idx.txnsByAddr[addrKey]
|
|
if addrIndexEntry == nil {
|
|
addrIndexEntry = make(map[chainhash.Hash]*btcutil.Tx)
|
|
idx.txnsByAddr[addrKey] = addrIndexEntry
|
|
}
|
|
addrIndexEntry[*tx.Hash()] = tx
|
|
|
|
// Add a mapping from the transaction to the address.
|
|
addrsByTxEntry := idx.addrsByTx[*tx.Hash()]
|
|
if addrsByTxEntry == nil {
|
|
addrsByTxEntry = make(map[[addrKeySize]byte]struct{})
|
|
idx.addrsByTx[*tx.Hash()] = addrsByTxEntry
|
|
}
|
|
addrsByTxEntry[addrKey] = struct{}{}
|
|
idx.unconfirmedLock.Unlock()
|
|
}
|
|
}
|
|
|
|
// AddUnconfirmedTx adds all addresses related to the transaction to the
|
|
// unconfirmed (memory-only) address index.
|
|
//
|
|
// NOTE: This transaction MUST have already been validated by the memory pool
|
|
// before calling this function with it and have all of the inputs available in
|
|
// the provided utxo view. Failure to do so could result in some or all
|
|
// addresses not being indexed.
|
|
//
|
|
// This function is safe for concurrent access.
|
|
func (idx *AddrIndex) AddUnconfirmedTx(tx *btcutil.Tx, utxoView *blockchain.UtxoViewpoint) {
|
|
// Index addresses of all referenced previous transaction outputs.
|
|
//
|
|
// The existence checks are elided since this is only called after the
|
|
// transaction has already been validated and thus all inputs are
|
|
// already known to exist.
|
|
for _, txIn := range tx.MsgTx().TxIn {
|
|
entry := utxoView.LookupEntry(txIn.PreviousOutPoint)
|
|
if entry == nil {
|
|
// Ignore missing entries. This should never happen
|
|
// in practice since the function comments specifically
|
|
// call out all inputs must be available.
|
|
continue
|
|
}
|
|
idx.indexUnconfirmedAddresses(entry.PkScript(), tx)
|
|
}
|
|
|
|
// Index addresses of all created outputs.
|
|
for _, txOut := range tx.MsgTx().TxOut {
|
|
idx.indexUnconfirmedAddresses(txOut.PkScript, tx)
|
|
}
|
|
}
|
|
|
|
// RemoveUnconfirmedTx removes the passed transaction from the unconfirmed
|
|
// (memory-only) address index.
|
|
//
|
|
// This function is safe for concurrent access.
|
|
func (idx *AddrIndex) RemoveUnconfirmedTx(hash *chainhash.Hash) {
|
|
idx.unconfirmedLock.Lock()
|
|
defer idx.unconfirmedLock.Unlock()
|
|
|
|
// Remove all address references to the transaction from the address
|
|
// index and remove the entry for the address altogether if it no longer
|
|
// references any transactions.
|
|
for addrKey := range idx.addrsByTx[*hash] {
|
|
delete(idx.txnsByAddr[addrKey], *hash)
|
|
if len(idx.txnsByAddr[addrKey]) == 0 {
|
|
delete(idx.txnsByAddr, addrKey)
|
|
}
|
|
}
|
|
|
|
// Remove the entry from the transaction to address lookup map as well.
|
|
delete(idx.addrsByTx, *hash)
|
|
}
|
|
|
|
// UnconfirmedTxnsForAddress returns all transactions currently in the
|
|
// unconfirmed (memory-only) address index that involve the passed address.
|
|
// Unsupported address types are ignored and will result in no results.
|
|
//
|
|
// This function is safe for concurrent access.
|
|
func (idx *AddrIndex) UnconfirmedTxnsForAddress(addr btcutil.Address) []*btcutil.Tx {
|
|
// Ignore unsupported address types.
|
|
addrKey, err := addrToKey(addr)
|
|
if err != nil {
|
|
return nil
|
|
}
|
|
|
|
// Protect concurrent access.
|
|
idx.unconfirmedLock.RLock()
|
|
defer idx.unconfirmedLock.RUnlock()
|
|
|
|
// Return a new slice with the results if there are any. This ensures
|
|
// safe concurrency.
|
|
if txns, exists := idx.txnsByAddr[addrKey]; exists {
|
|
addressTxns := make([]*btcutil.Tx, 0, len(txns))
|
|
for _, tx := range txns {
|
|
addressTxns = append(addressTxns, tx)
|
|
}
|
|
return addressTxns
|
|
}
|
|
|
|
return nil
|
|
}
|
|
|
|
// NewAddrIndex returns a new instance of an indexer that is used to create a
|
|
// mapping of all addresses in the blockchain to the respective transactions
|
|
// that involve them.
|
|
//
|
|
// It implements the Indexer interface which plugs into the IndexManager that in
|
|
// turn is used by the blockchain package. This allows the index to be
|
|
// seamlessly maintained along with the chain.
|
|
func NewAddrIndex(db database.DB, chainParams *chaincfg.Params) *AddrIndex {
|
|
return &AddrIndex{
|
|
db: db,
|
|
chainParams: chainParams,
|
|
txnsByAddr: make(map[[addrKeySize]byte]map[chainhash.Hash]*btcutil.Tx),
|
|
addrsByTx: make(map[chainhash.Hash]map[[addrKeySize]byte]struct{}),
|
|
}
|
|
}
|
|
|
|
// DropAddrIndex drops the address index from the provided database if it
|
|
// exists.
|
|
func DropAddrIndex(db database.DB, interrupt <-chan struct{}) error {
|
|
return dropIndex(db, addrIndexKey, addrIndexName, interrupt)
|
|
}
|