forked from cerc-io/ipld-eth-server
560305f601
- uses newer version of go-ethereum required for go1.11
605 lines
20 KiB
Go
605 lines
20 KiB
Go
// Copyright (c) 2017 The btcsuite developers
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// Use of this source code is governed by an ISC
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// license that can be found in the LICENSE file.
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package blockchain
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import (
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"bytes"
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"container/list"
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"errors"
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"fmt"
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"time"
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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/wire"
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)
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const (
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// blockHdrOffset defines the offsets into a v1 block index row for the
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// block header.
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//
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// The serialized block index row format is:
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// <blocklocation><blockheader>
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blockHdrOffset = 12
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)
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// errInterruptRequested indicates that an operation was cancelled due
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// to a user-requested interrupt.
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var errInterruptRequested = errors.New("interrupt requested")
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// interruptRequested returns true when the provided channel has been closed.
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// This simplifies early shutdown slightly since the caller can just use an if
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// statement instead of a select.
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func interruptRequested(interrupted <-chan struct{}) bool {
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select {
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case <-interrupted:
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return true
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default:
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}
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return false
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}
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// blockChainContext represents a particular block's placement in the block
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// chain. This is used by the block index migration to track block metadata that
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// will be written to disk.
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type blockChainContext struct {
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parent *chainhash.Hash
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children []*chainhash.Hash
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height int32
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mainChain bool
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}
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// migrateBlockIndex migrates all block entries from the v1 block index bucket
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// to the v2 bucket. The v1 bucket stores all block entries keyed by block hash,
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// whereas the v2 bucket stores the exact same values, but keyed instead by
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// block height + hash.
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func migrateBlockIndex(db database.DB) error {
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// Hardcoded bucket names so updates to the global values do not affect
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// old upgrades.
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v1BucketName := []byte("ffldb-blockidx")
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v2BucketName := []byte("blockheaderidx")
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err := db.Update(func(dbTx database.Tx) error {
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v1BlockIdxBucket := dbTx.Metadata().Bucket(v1BucketName)
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if v1BlockIdxBucket == nil {
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return fmt.Errorf("Bucket %s does not exist", v1BucketName)
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}
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log.Info("Re-indexing block information in the database. This might take a while...")
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v2BlockIdxBucket, err :=
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dbTx.Metadata().CreateBucketIfNotExists(v2BucketName)
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if err != nil {
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return err
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}
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// Get tip of the main chain.
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serializedData := dbTx.Metadata().Get(chainStateKeyName)
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state, err := deserializeBestChainState(serializedData)
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if err != nil {
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return err
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}
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tip := &state.hash
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// Scan the old block index bucket and construct a mapping of each block
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// to parent block and all child blocks.
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blocksMap, err := readBlockTree(v1BlockIdxBucket)
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if err != nil {
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return err
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}
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// Use the block graph to calculate the height of each block.
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err = determineBlockHeights(blocksMap)
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if err != nil {
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return err
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}
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// Find blocks on the main chain with the block graph and current tip.
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determineMainChainBlocks(blocksMap, tip)
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// Now that we have heights for all blocks, scan the old block index
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// bucket and insert all rows into the new one.
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return v1BlockIdxBucket.ForEach(func(hashBytes, blockRow []byte) error {
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endOffset := blockHdrOffset + blockHdrSize
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headerBytes := blockRow[blockHdrOffset:endOffset:endOffset]
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var hash chainhash.Hash
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copy(hash[:], hashBytes[0:chainhash.HashSize])
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chainContext := blocksMap[hash]
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if chainContext.height == -1 {
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return fmt.Errorf("Unable to calculate chain height for "+
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"stored block %s", hash)
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}
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// Mark blocks as valid if they are part of the main chain.
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status := statusDataStored
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if chainContext.mainChain {
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status |= statusValid
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}
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// Write header to v2 bucket
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value := make([]byte, blockHdrSize+1)
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copy(value[0:blockHdrSize], headerBytes)
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value[blockHdrSize] = byte(status)
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key := blockIndexKey(&hash, uint32(chainContext.height))
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err := v2BlockIdxBucket.Put(key, value)
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if err != nil {
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return err
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}
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// Delete header from v1 bucket
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truncatedRow := blockRow[0:blockHdrOffset:blockHdrOffset]
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return v1BlockIdxBucket.Put(hashBytes, truncatedRow)
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})
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})
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if err != nil {
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return err
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}
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log.Infof("Block database migration complete")
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return nil
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}
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// readBlockTree reads the old block index bucket and constructs a mapping of
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// each block to its parent block and all child blocks. This mapping represents
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// the full tree of blocks. This function does not populate the height or
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// mainChain fields of the returned blockChainContext values.
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func readBlockTree(v1BlockIdxBucket database.Bucket) (map[chainhash.Hash]*blockChainContext, error) {
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blocksMap := make(map[chainhash.Hash]*blockChainContext)
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err := v1BlockIdxBucket.ForEach(func(_, blockRow []byte) error {
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var header wire.BlockHeader
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endOffset := blockHdrOffset + blockHdrSize
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headerBytes := blockRow[blockHdrOffset:endOffset:endOffset]
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err := header.Deserialize(bytes.NewReader(headerBytes))
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if err != nil {
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return err
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}
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blockHash := header.BlockHash()
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prevHash := header.PrevBlock
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if blocksMap[blockHash] == nil {
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blocksMap[blockHash] = &blockChainContext{height: -1}
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}
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if blocksMap[prevHash] == nil {
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blocksMap[prevHash] = &blockChainContext{height: -1}
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}
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blocksMap[blockHash].parent = &prevHash
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blocksMap[prevHash].children =
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append(blocksMap[prevHash].children, &blockHash)
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return nil
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})
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return blocksMap, err
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}
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// determineBlockHeights takes a map of block hashes to a slice of child hashes
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// and uses it to compute the height for each block. The function assigns a
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// height of 0 to the genesis hash and explores the tree of blocks
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// breadth-first, assigning a height to every block with a path back to the
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// genesis block. This function modifies the height field on the blocksMap
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// entries.
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func determineBlockHeights(blocksMap map[chainhash.Hash]*blockChainContext) error {
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queue := list.New()
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// The genesis block is included in blocksMap as a child of the zero hash
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// because that is the value of the PrevBlock field in the genesis header.
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preGenesisContext, exists := blocksMap[zeroHash]
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if !exists || len(preGenesisContext.children) == 0 {
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return fmt.Errorf("Unable to find genesis block")
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}
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for _, genesisHash := range preGenesisContext.children {
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blocksMap[*genesisHash].height = 0
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queue.PushBack(genesisHash)
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}
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for e := queue.Front(); e != nil; e = queue.Front() {
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queue.Remove(e)
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hash := e.Value.(*chainhash.Hash)
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height := blocksMap[*hash].height
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// For each block with this one as a parent, assign it a height and
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// push to queue for future processing.
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for _, childHash := range blocksMap[*hash].children {
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blocksMap[*childHash].height = height + 1
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queue.PushBack(childHash)
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}
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}
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return nil
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}
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// determineMainChainBlocks traverses the block graph down from the tip to
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// determine which block hashes that are part of the main chain. This function
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// modifies the mainChain field on the blocksMap entries.
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func determineMainChainBlocks(blocksMap map[chainhash.Hash]*blockChainContext, tip *chainhash.Hash) {
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for nextHash := tip; *nextHash != zeroHash; nextHash = blocksMap[*nextHash].parent {
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blocksMap[*nextHash].mainChain = true
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}
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}
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// deserializeUtxoEntryV0 decodes a utxo entry from the passed serialized byte
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// slice according to the legacy version 0 format into a map of utxos keyed by
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// the output index within the transaction. The map is necessary because the
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// previous format encoded all unspent outputs for a transaction using a single
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// entry, whereas the new format encodes each unspent output individually.
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//
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// The legacy format is as follows:
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//
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// <version><height><header code><unspentness bitmap>[<compressed txouts>,...]
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//
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// Field Type Size
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// version VLQ variable
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// block height VLQ variable
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// header code VLQ variable
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// unspentness bitmap []byte variable
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// compressed txouts
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// compressed amount VLQ variable
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// compressed script []byte variable
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//
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// The serialized header code format is:
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// bit 0 - containing transaction is a coinbase
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// bit 1 - output zero is unspent
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// bit 2 - output one is unspent
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// bits 3-x - number of bytes in unspentness bitmap. When both bits 1 and 2
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// are unset, it encodes N-1 since there must be at least one unspent
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// output.
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//
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// The rationale for the header code scheme is as follows:
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// - Transactions which only pay to a single output and a change output are
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// extremely common, thus an extra byte for the unspentness bitmap can be
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// avoided for them by encoding those two outputs in the low order bits.
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// - Given it is encoded as a VLQ which can encode values up to 127 with a
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// single byte, that leaves 4 bits to represent the number of bytes in the
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// unspentness bitmap while still only consuming a single byte for the
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// header code. In other words, an unspentness bitmap with up to 120
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// transaction outputs can be encoded with a single-byte header code.
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// This covers the vast majority of transactions.
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// - Encoding N-1 bytes when both bits 1 and 2 are unset allows an additional
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// 8 outpoints to be encoded before causing the header code to require an
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// additional byte.
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//
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// Example 1:
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// From tx in main blockchain:
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// Blk 1, 0e3e2357e806b6cdb1f70b54c3a3a17b6714ee1f0e68bebb44a74b1efd512098
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//
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// 010103320496b538e853519c726a2c91e61ec11600ae1390813a627c66fb8be7947be63c52
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// <><><><------------------------------------------------------------------>
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// | | \--------\ |
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// | height | compressed txout 0
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// version header code
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//
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// - version: 1
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// - height: 1
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// - header code: 0x03 (coinbase, output zero unspent, 0 bytes of unspentness)
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// - unspentness: Nothing since it is zero bytes
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// - compressed txout 0:
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// - 0x32: VLQ-encoded compressed amount for 5000000000 (50 BTC)
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// - 0x04: special script type pay-to-pubkey
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// - 0x96...52: x-coordinate of the pubkey
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//
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// Example 2:
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// From tx in main blockchain:
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// Blk 113931, 4a16969aa4764dd7507fc1de7f0baa4850a246de90c45e59a3207f9a26b5036f
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//
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// 0185f90b0a011200e2ccd6ec7c6e2e581349c77e067385fa8236bf8a800900b8025be1b3efc63b0ad48e7f9f10e87544528d58
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// <><----><><><------------------------------------------><-------------------------------------------->
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// | | | \-------------------\ | |
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// version | \--------\ unspentness | compressed txout 2
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// height header code compressed txout 0
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//
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// - version: 1
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// - height: 113931
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// - header code: 0x0a (output zero unspent, 1 byte in unspentness bitmap)
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// - unspentness: [0x01] (bit 0 is set, so output 0+2 = 2 is unspent)
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// NOTE: It's +2 since the first two outputs are encoded in the header code
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// - compressed txout 0:
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// - 0x12: VLQ-encoded compressed amount for 20000000 (0.2 BTC)
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// - 0x00: special script type pay-to-pubkey-hash
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// - 0xe2...8a: pubkey hash
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// - compressed txout 2:
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// - 0x8009: VLQ-encoded compressed amount for 15000000 (0.15 BTC)
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// - 0x00: special script type pay-to-pubkey-hash
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// - 0xb8...58: pubkey hash
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//
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// Example 3:
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// From tx in main blockchain:
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// Blk 338156, 1b02d1c8cfef60a189017b9a420c682cf4a0028175f2f563209e4ff61c8c3620
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//
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// 0193d06c100000108ba5b9e763011dd46a006572d820e448e12d2bbb38640bc718e6
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// <><----><><----><-------------------------------------------------->
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// | | | \-----------------\ |
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// version | \--------\ unspentness |
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// height header code compressed txout 22
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//
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// - version: 1
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// - height: 338156
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// - header code: 0x10 (2+1 = 3 bytes in unspentness bitmap)
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// NOTE: It's +1 since neither bit 1 nor 2 are set, so N-1 is encoded.
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// - unspentness: [0x00 0x00 0x10] (bit 20 is set, so output 20+2 = 22 is unspent)
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// NOTE: It's +2 since the first two outputs are encoded in the header code
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// - compressed txout 22:
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// - 0x8ba5b9e763: VLQ-encoded compressed amount for 366875659 (3.66875659 BTC)
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// - 0x01: special script type pay-to-script-hash
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// - 0x1d...e6: script hash
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func deserializeUtxoEntryV0(serialized []byte) (map[uint32]*UtxoEntry, error) {
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// Deserialize the version.
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//
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// NOTE: Ignore version since it is no longer used in the new format.
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_, bytesRead := deserializeVLQ(serialized)
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offset := bytesRead
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if offset >= len(serialized) {
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return nil, errDeserialize("unexpected end of data after version")
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}
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// Deserialize the block height.
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blockHeight, bytesRead := deserializeVLQ(serialized[offset:])
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offset += bytesRead
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if offset >= len(serialized) {
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return nil, errDeserialize("unexpected end of data after height")
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}
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// Deserialize the header code.
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code, bytesRead := deserializeVLQ(serialized[offset:])
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offset += bytesRead
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if offset >= len(serialized) {
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return nil, errDeserialize("unexpected end of data after header")
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}
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// Decode the header code.
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//
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// Bit 0 indicates whether the containing transaction is a coinbase.
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// Bit 1 indicates output 0 is unspent.
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// Bit 2 indicates output 1 is unspent.
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// Bits 3-x encodes the number of non-zero unspentness bitmap bytes that
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// follow. When both output 0 and 1 are spent, it encodes N-1.
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isCoinBase := code&0x01 != 0
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output0Unspent := code&0x02 != 0
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output1Unspent := code&0x04 != 0
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numBitmapBytes := code >> 3
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if !output0Unspent && !output1Unspent {
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numBitmapBytes++
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}
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// Ensure there are enough bytes left to deserialize the unspentness
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// bitmap.
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if uint64(len(serialized[offset:])) < numBitmapBytes {
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return nil, errDeserialize("unexpected end of data for " +
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"unspentness bitmap")
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}
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// Add sparse output for unspent outputs 0 and 1 as needed based on the
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// details provided by the header code.
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var outputIndexes []uint32
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if output0Unspent {
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outputIndexes = append(outputIndexes, 0)
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}
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if output1Unspent {
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outputIndexes = append(outputIndexes, 1)
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}
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// Decode the unspentness bitmap adding a sparse output for each unspent
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// output.
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for i := uint32(0); i < uint32(numBitmapBytes); i++ {
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unspentBits := serialized[offset]
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for j := uint32(0); j < 8; j++ {
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if unspentBits&0x01 != 0 {
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// The first 2 outputs are encoded via the
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// header code, so adjust the output number
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// accordingly.
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outputNum := 2 + i*8 + j
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outputIndexes = append(outputIndexes, outputNum)
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}
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unspentBits >>= 1
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}
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offset++
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}
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// Map to hold all of the converted outputs.
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entries := make(map[uint32]*UtxoEntry)
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// All entries will need to potentially be marked as a coinbase.
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var packedFlags txoFlags
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if isCoinBase {
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packedFlags |= tfCoinBase
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}
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// Decode and add all of the utxos.
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for i, outputIndex := range outputIndexes {
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// Decode the next utxo.
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amount, pkScript, bytesRead, err := decodeCompressedTxOut(
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serialized[offset:])
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if err != nil {
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return nil, errDeserialize(fmt.Sprintf("unable to "+
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"decode utxo at index %d: %v", i, err))
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}
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offset += bytesRead
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// Create a new utxo entry with the details deserialized above.
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entries[outputIndex] = &UtxoEntry{
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amount: int64(amount),
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pkScript: pkScript,
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blockHeight: int32(blockHeight),
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packedFlags: packedFlags,
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}
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}
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return entries, nil
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}
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// upgradeUtxoSetToV2 migrates the utxo set entries from version 1 to 2 in
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// batches. It is guaranteed to updated if this returns without failure.
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func upgradeUtxoSetToV2(db database.DB, interrupt <-chan struct{}) error {
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// Hardcoded bucket names so updates to the global values do not affect
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// old upgrades.
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var (
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v1BucketName = []byte("utxoset")
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v2BucketName = []byte("utxosetv2")
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)
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log.Infof("Upgrading utxo set to v2. This will take a while...")
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start := time.Now()
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// Create the new utxo set bucket as needed.
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err := db.Update(func(dbTx database.Tx) error {
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_, err := dbTx.Metadata().CreateBucketIfNotExists(v2BucketName)
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return err
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})
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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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// doBatch contains the primary logic for upgrading the utxo set from
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// version 1 to 2 in batches. This is done because the utxo set can be
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// huge and thus attempting to migrate in a single database transaction
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// would result in massive memory usage and could potentially crash on
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// many systems due to ulimits.
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//
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// It returns the number of utxos processed.
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const maxUtxos = 200000
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doBatch := func(dbTx database.Tx) (uint32, error) {
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v1Bucket := dbTx.Metadata().Bucket(v1BucketName)
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v2Bucket := dbTx.Metadata().Bucket(v2BucketName)
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v1Cursor := v1Bucket.Cursor()
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// Migrate utxos so long as the max number of utxos for this
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// batch has not been exceeded.
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var numUtxos uint32
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for ok := v1Cursor.First(); ok && numUtxos < maxUtxos; ok =
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v1Cursor.Next() {
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// Old key was the transaction hash.
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oldKey := v1Cursor.Key()
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var txHash chainhash.Hash
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copy(txHash[:], oldKey)
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// Deserialize the old entry which included all utxos
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|
// for the given transaction.
|
|
utxos, err := deserializeUtxoEntryV0(v1Cursor.Value())
|
|
if err != nil {
|
|
return 0, err
|
|
}
|
|
|
|
// Add an entry for each utxo into the new bucket using
|
|
// the new format.
|
|
for txOutIdx, utxo := range utxos {
|
|
reserialized, err := serializeUtxoEntry(utxo)
|
|
if err != nil {
|
|
return 0, err
|
|
}
|
|
|
|
key := outpointKey(wire.OutPoint{
|
|
Hash: txHash,
|
|
Index: txOutIdx,
|
|
})
|
|
err = v2Bucket.Put(*key, reserialized)
|
|
// NOTE: The key is intentionally not recycled
|
|
// here since the database interface contract
|
|
// prohibits modifications. It will be garbage
|
|
// collected normally when the database is done
|
|
// with it.
|
|
if err != nil {
|
|
return 0, err
|
|
}
|
|
}
|
|
|
|
// Remove old entry.
|
|
err = v1Bucket.Delete(oldKey)
|
|
if err != nil {
|
|
return 0, err
|
|
}
|
|
|
|
numUtxos += uint32(len(utxos))
|
|
|
|
if interruptRequested(interrupt) {
|
|
// No error here so the database transaction
|
|
// is not cancelled and therefore outstanding
|
|
// work is written to disk.
|
|
break
|
|
}
|
|
}
|
|
|
|
return numUtxos, nil
|
|
}
|
|
|
|
// Migrate all entries in batches for the reasons mentioned above.
|
|
var totalUtxos uint64
|
|
for {
|
|
var numUtxos uint32
|
|
err := db.Update(func(dbTx database.Tx) error {
|
|
var err error
|
|
numUtxos, err = doBatch(dbTx)
|
|
return err
|
|
})
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
if interruptRequested(interrupt) {
|
|
return errInterruptRequested
|
|
}
|
|
|
|
if numUtxos == 0 {
|
|
break
|
|
}
|
|
|
|
totalUtxos += uint64(numUtxos)
|
|
log.Infof("Migrated %d utxos (%d total)", numUtxos, totalUtxos)
|
|
}
|
|
|
|
// Remove the old bucket and update the utxo set version once it has
|
|
// been fully migrated.
|
|
err = db.Update(func(dbTx database.Tx) error {
|
|
err := dbTx.Metadata().DeleteBucket(v1BucketName)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
return dbPutVersion(dbTx, utxoSetVersionKeyName, 2)
|
|
})
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
seconds := int64(time.Since(start) / time.Second)
|
|
log.Infof("Done upgrading utxo set. Total utxos: %d in %d seconds",
|
|
totalUtxos, seconds)
|
|
return nil
|
|
}
|
|
|
|
// maybeUpgradeDbBuckets checks the database version of the buckets used by this
|
|
// package and performs any needed upgrades to bring them to the latest version.
|
|
//
|
|
// All buckets used by this package are guaranteed to be the latest version if
|
|
// this function returns without error.
|
|
func (b *BlockChain) maybeUpgradeDbBuckets(interrupt <-chan struct{}) error {
|
|
// Load or create bucket versions as needed.
|
|
var utxoSetVersion uint32
|
|
err := b.db.Update(func(dbTx database.Tx) error {
|
|
// Load the utxo set version from the database or create it and
|
|
// initialize it to version 1 if it doesn't exist.
|
|
var err error
|
|
utxoSetVersion, err = dbFetchOrCreateVersion(dbTx,
|
|
utxoSetVersionKeyName, 1)
|
|
return err
|
|
})
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
// Update the utxo set to v2 if needed.
|
|
if utxoSetVersion < 2 {
|
|
if err := upgradeUtxoSetToV2(b.db, interrupt); err != nil {
|
|
return err
|
|
}
|
|
}
|
|
|
|
return nil
|
|
}
|