mirror of
https://github.com/btcsuite/btcd.git
synced 2024-11-20 02:09:04 +01:00
2d6a664d9d
Previously, the code was using big rational numbers for work values which resulted in carrying way too much precision around (and ultimately a lot of extra memory and computation to carry that precision). This commit converts the work values to big integers and calculates them with integer division. This is acceptable because the numerator is multiplied by 2^256 which is higher than the maximum possible proof of work. Therefore anything after the decimal is superfluous precision for the purposes of chain selection. Also, add a check for negative difficulty values when calculating the work value. Negative values won't occur in practice with valid blocks, but it's possible an invalid block could trigger the code path, so be safe and check for it.
749 lines
26 KiB
Go
749 lines
26 KiB
Go
// Copyright (c) 2013 Conformal Systems LLC.
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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 btcchain
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import (
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"container/list"
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"fmt"
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"github.com/conformal/btcdb"
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"github.com/conformal/btcutil"
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"github.com/conformal/btcwire"
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"math/big"
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"sort"
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"time"
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)
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// maxOrphanBlocks is the maximum number of orphan blocks that can be queued.
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const maxOrphanBlocks = 100
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// blockNode represents a block within the block chain and is primarily used to
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// aid in selecting the best chain to be the main chain. The main chain is
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// stored into the block database.
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type blockNode struct {
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// parent is the parent block for this node.
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parent *blockNode
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// children contains the child nodes for this node. Typically there
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// will only be one, but sometimes there can be more than one and that
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// is when the best chain selection algorithm is used.
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children []*blockNode
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// hash is the double sha 256 of the block.
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hash *btcwire.ShaHash
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// height is the position in the block chain.
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height int64
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// workSum is the total amount of work in the chain up to and including
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// this node.
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workSum *big.Int
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// inMainChain denotes whether the block node is currently on the
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// the main chain or not. This is used to help find the common
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// ancestor when switching chains.
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inMainChain bool
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// Some fields from block headers to aid in best chain selection.
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version uint32
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bits uint32
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timestamp time.Time
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}
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// newBlockNode returns a new block node for the given block. It is completely
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// disconnected from the chain and the workSum value is just the work for the
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// passed block. The work sum is updated accordingly when the node is inserted
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// into a chain.
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func newBlockNode(block *btcutil.Block) *blockNode {
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// Get the block sha. It's ok to ignore the error here since
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// sha has already been called and an error there would have caused
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// an exit before this function is called.
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blockSha, _ := block.Sha()
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blockHeader := block.MsgBlock().Header
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node := blockNode{
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hash: blockSha,
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workSum: calcWork(blockHeader.Bits),
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height: block.Height(),
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version: blockHeader.Version,
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bits: blockHeader.Bits,
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timestamp: blockHeader.Timestamp,
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}
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return &node
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}
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// orphanBlock represents a block that we don't yet have the parent for. It
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// is a normal block plus an expiration time to prevent caching the orphan
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// forever.
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type orphanBlock struct {
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block *btcutil.Block
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expiration time.Time
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}
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// addChildrenWork adds the passed work amount to all children all the way
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// down the chain. It is used primarily to allow a new node to be dynamically
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// inserted from the database into the memory chain prior to nodes we already
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// have and update their work values accordingly.
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func addChildrenWork(node *blockNode, work *big.Int) {
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for _, childNode := range node.children {
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childNode.workSum.Add(childNode.workSum, work)
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addChildrenWork(childNode, work)
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}
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}
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// removeChildNode deletes node from the provided slice of child block
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// nodes. It ensures the final pointer reference is set to nil to prevent
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// potential memory leaks. The original slice is returned unmodified if node
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// is invalid or not in the slice.
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func removeChildNode(children []*blockNode, node *blockNode) []*blockNode {
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if node == nil {
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return children
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}
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for i, n := range children {
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if n.hash.IsEqual(node.hash) {
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copy(children[i:], children[i+1:])
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children[len(children)-1] = nil
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return children[:len(children)-1]
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}
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}
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return children
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}
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// BlockChain provides functions for working with the bitcoin block chain.
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// It includes functionality such as rejecting duplicate blocks, ensuring blocks
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// follow all rules, orphan handling, checkpoint handling, and best chain
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// selection with reorganization.
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type BlockChain struct {
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db btcdb.Db
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btcnet btcwire.BitcoinNet
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notifications chan *Notification
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root *blockNode
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bestChain *blockNode
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index map[btcwire.ShaHash]*blockNode
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depNodes map[btcwire.ShaHash][]*blockNode
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orphans map[btcwire.ShaHash]*orphanBlock
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prevOrphans map[btcwire.ShaHash][]*orphanBlock
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oldestOrphan *orphanBlock
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blockCache map[btcwire.ShaHash]*btcutil.Block
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noVerify bool
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noCheckpoints bool
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}
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// DisableVerify provides a mechanism to disable transaction script validation
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// which you DO NOT want to do in production as it could allow double spends
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// and othe undesirable things. It is provided only for debug purposes since
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// script validation is extremely intensive and when debugging it is sometimes
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// nice to quickly get the chain.
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func (b *BlockChain) DisableVerify(disable bool) {
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b.noVerify = disable
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}
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// getOrphanRoot returns the head of the chain for the provided hash from the
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// map of orphan blocks.
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func (b *BlockChain) getOrphanRoot(sha *btcwire.ShaHash) *btcwire.ShaHash {
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// Keep looping while the parent of each orphaned block is
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// known and is an orphan itself.
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prevHash := sha
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for {
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orphan, exists := b.orphans[*prevHash]
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if !exists {
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break
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}
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prevHash = &orphan.block.MsgBlock().Header.PrevBlock
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}
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return prevHash
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}
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// removeOrphanBlock removes the passed orphan block from the orphan pool and
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// previous orphan index.
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func (b *BlockChain) removeOrphanBlock(orphan *orphanBlock) {
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// Remove the orphan block from the orphan pool. It's safe to ignore
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// the error on Sha since it's cached.
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orphanHash, _ := orphan.block.Sha()
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delete(b.orphans, *orphanHash)
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// Remove the reference from the previous orphan index too.
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prevHash := &orphan.block.MsgBlock().Header.PrevBlock
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orphans := b.prevOrphans[*prevHash]
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for i, ob := range orphans {
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hash, _ := ob.block.Sha()
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if hash.IsEqual(orphanHash) {
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copy(orphans[i:], orphans[i+1:])
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orphans[len(orphans)-1] = nil
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b.prevOrphans[*prevHash] = orphans[:len(orphans)-1]
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}
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}
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// Remove the map entry altogether if there are no longer any orphans
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// which depend on the parent hash.
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if len(b.prevOrphans[*prevHash]) == 0 {
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delete(b.prevOrphans, *prevHash)
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}
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}
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// addOrphanBlock adds the passed block (which is already determined to be
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// an orphan prior calling this function) to the orphan pool. It lazily cleans
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// up any expired blocks so a separate cleanup poller doesn't need to be run.
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// It also imposes a maximum limit on the number of outstanding orphan
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// blocks and will remove the oldest received orphan block if the limit is
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// exceeded.
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func (b *BlockChain) addOrphanBlock(block *btcutil.Block) {
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// Remove expired orphan blocks.
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for _, oBlock := range b.orphans {
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if time.Now().After(oBlock.expiration) {
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b.removeOrphanBlock(oBlock)
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continue
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}
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// Update the oldest orphan block pointer so it can be discarded
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// in case the orphan pool fills up.
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if b.oldestOrphan == nil || oBlock.expiration.Before(b.oldestOrphan.expiration) {
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b.oldestOrphan = oBlock
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}
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}
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// Limit orphan blocks to prevent memory exhaustion.
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if len(b.orphans)+1 > maxOrphanBlocks {
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// Remove the oldest orphan to make room for the new one.
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b.removeOrphanBlock(b.oldestOrphan)
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b.oldestOrphan = nil
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}
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// Get the block sha. It is safe to ignore the error here since any
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// errors would've been caught prior to calling this function.
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blockSha, _ := block.Sha()
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// Insert the block into the orphan map with an expiration time
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// 1 hour from now.
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expiration := time.Now().Add(time.Hour)
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oBlock := &orphanBlock{
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block: block,
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expiration: expiration,
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}
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b.orphans[*blockSha] = oBlock
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// Add to previous hash lookup index for faster dependency lookups.
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prevHash := &block.MsgBlock().Header.PrevBlock
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b.prevOrphans[*prevHash] = append(b.prevOrphans[*prevHash], oBlock)
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return
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}
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// loadBlockNode loads the block identified by hash from the block database,
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// creates a block node from it, and updates the memory block chain accordingly.
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// It is used mainly to dynamically load previous blocks from database as they
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// are needed to avoid needing to put the entire block chain in memory.
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func (b *BlockChain) loadBlockNode(hash *btcwire.ShaHash) (*blockNode, error) {
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// Load the block from the db.
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block, err := b.db.FetchBlockBySha(hash)
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if err != nil {
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return nil, err
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}
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// Create the new block node for the block and set the work.
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node := newBlockNode(block)
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node.inMainChain = true
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// Add the node to the chain.
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// There are several possibilities here:
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// 1) This node is a child of an existing block node
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// 2) This node is the parent of one or more nodes
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// 3) Neither 1 or 2 is true, and this is not the first node being
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// added to the tree which implies it's an orphan block and
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// therefore is an error to insert into the chain
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// 4) Neither 1 or 2 is true, but this is the first node being added
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// to the tree, so it's the root.
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prevHash := &block.MsgBlock().Header.PrevBlock
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if parentNode, ok := b.index[*prevHash]; ok {
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// Case 1 -- This node is a child of an existing block node.
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// Update the node's work sum with the sum of the parent node's
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// work sum and this node's work, append the node as a child of
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// the parent node and set this node's parent to the parent
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// node.
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node.workSum = node.workSum.Add(parentNode.workSum, node.workSum)
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parentNode.children = append(parentNode.children, node)
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node.parent = parentNode
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} else if childNodes, ok := b.depNodes[*hash]; ok {
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// Case 2 -- This node is the parent of one or more nodes.
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// Connect this block node to all of its children and update
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// all of the children (and their children) with the new work
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// sums.
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for _, childNode := range childNodes {
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childNode.parent = node
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node.children = append(node.children, childNode)
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addChildrenWork(childNode, node.workSum)
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b.root = node
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}
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} else {
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// Case 3 -- The node does't have a parent and is not the parent
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// of another node. This is only acceptable for the first node
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// inserted into the chain. Otherwise it means an arbitrary
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// orphan block is trying to be loaded which is not allowed.
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if b.root != nil {
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str := "loadBlockNode: attempt to insert orphan block %v"
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return nil, fmt.Errorf(str, hash)
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}
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// Case 4 -- This is the root since it's the first and only node.
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b.root = node
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}
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// Add the new node to the indices for faster lookups.
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b.index[*hash] = node
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b.depNodes[*prevHash] = append(b.depNodes[*prevHash], node)
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return node, nil
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}
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// getPrevNodeFromBlock returns a block node for the block previous to the
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// passed block (the passed block's parent). When it is already in the memory
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// block chain, it simply returns it. Otherwise, it loads the previous block
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// from the block database, creates a new block node from it, and returns it.
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// The returned node will be nil if the genesis block is passed.
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func (b *BlockChain) getPrevNodeFromBlock(block *btcutil.Block) (*blockNode, error) {
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// Genesis block.
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prevHash := &block.MsgBlock().Header.PrevBlock
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if prevHash.IsEqual(zeroHash) {
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return nil, nil
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}
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// Return the existing previous block node if it's already there.
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if bn, ok := b.index[*prevHash]; ok {
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return bn, nil
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}
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// Dynamically load the previous block from the block database, create
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// a new block node for it, and update the memory chain accordingly.
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prevBlockNode, err := b.loadBlockNode(prevHash)
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if err != nil {
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return nil, err
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}
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return prevBlockNode, nil
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}
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// getPrevNodeFromNode returns a block node for the block previous to the
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// passed block node (the passed block node's parent). When the node is already
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// connected to a parent, it simply returns it. Otherwise, it loads the
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// associated block from the database to obtain the previous hash and uses that
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// to dynamically create a new block node and return it. The memory block
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// chain is updated accordingly. The returned node will be nil if the genesis
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// block is passed.
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func (b *BlockChain) getPrevNodeFromNode(node *blockNode) (*blockNode, error) {
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// Return the existing previous block node if it's already there.
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if node.parent != nil {
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return node.parent, nil
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}
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// Genesis block.
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if node.hash.IsEqual(b.chainParams().GenesisHash) {
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return nil, nil
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}
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// Load the actual block for this block node from the db to ascertain
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// the previous hash.
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block, err := b.db.FetchBlockBySha(node.hash)
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if err != nil {
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return nil, err
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}
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// Dynamically load the previous block from the block database, create
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// a new block node for it, and update the memory chain accordingly.
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prevHash := &block.MsgBlock().Header.PrevBlock
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prevBlockNode, err := b.loadBlockNode(prevHash)
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if err != nil {
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return nil, err
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}
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return prevBlockNode, nil
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}
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// isMajorityVersion determines if a previous number of blocks in the chain
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// starting with startNode are at least the minimum passed version.
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func (b *BlockChain) isMajorityVersion(minVer uint32, startNode *blockNode, numRequired, numToCheck uint64) bool {
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numFound := uint64(0)
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iterNode := startNode
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for i := uint64(0); i < numToCheck && iterNode != nil; i++ {
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// This node has a version that is at least the minimum version.
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if iterNode.version >= minVer {
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numFound++
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}
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// Get the previous block node. This function is used over
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// simply accessing iterNode.parent directly as it will
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// dynamically create previous block nodes as needed. This
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// helps allow only the pieces of the chain that are needed
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// to remain in memory.
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var err error
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iterNode, err = b.getPrevNodeFromNode(iterNode)
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if err != nil {
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break
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}
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}
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return numFound >= numRequired
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}
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// calcPastMedianTime calculates the median time of the previous few blocks
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// prior to, and including, the passed block node. It is primarily used to
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// validate new blocks have sane timestamps.
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func (b *BlockChain) calcPastMedianTime(startNode *blockNode) (time.Time, error) {
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// Genesis block.
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if startNode == nil {
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return b.chainParams().GenesisBlock.Header.Timestamp, nil
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}
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// Create a slice of the previous few block timestamps used to calculate
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// the median per the number defined by the constant medianTimeBlocks.
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timestamps := make([]time.Time, medianTimeBlocks)
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numNodes := 0
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iterNode := startNode
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for i := 0; i < medianTimeBlocks && iterNode != nil; i++ {
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timestamps[i] = iterNode.timestamp
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numNodes++
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// Get the previous block node. This function is used over
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// simply accessing iterNode.parent directly as it will
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// dynamically create previous block nodes as needed. This
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// helps allow only the pieces of the chain that are needed
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// to remain in memory.
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var err error
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iterNode, err = b.getPrevNodeFromNode(iterNode)
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if err != nil {
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log.Errorf("getPrevNodeFromNode: %v", err)
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return time.Time{}, err
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}
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}
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// Prune the slice to the actual number of available timestamps which
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// will be fewer than desired near the beginning of the block chain
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// and sort them.
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timestamps = timestamps[:numNodes]
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sort.Sort(timeSorter(timestamps))
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// NOTE: bitcoind incorrectly calculates the median for even numbers of
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// blocks. A true median averages the middle two elements for a set
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// with an even number of elements in it. Since the constant for the
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// previous number of blocks to be used is odd, this is only an issue
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// for a few blocks near the beginning of the chain. I suspect this is
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// an optimization even though the result is slightly wrong for a few
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// of the first blocks since after the first few blocks, there will
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// always be an odd number of blocks in the set per the constant.
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//
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// This code follows suit to ensure the same rules are used as bitcoind
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// however, be aware that should the medianTimeBlocks constant ever be
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// changed to an even number, this code will be wrong.
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medianTimestamp := timestamps[numNodes/2]
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return medianTimestamp, nil
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}
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// getReorganizeNodes finds the fork point between the main chain and the passed
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// node and returns a list of block nodes that would need to be detached from
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// the main chain and a list of block nodes that would need to be attached to
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// the fork point (which will be the end of the main chain after detaching the
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// returned list of block nodes) in order to reorganize the chain such that the
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// passed node is the new end of the main chain. The lists will be empty if the
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// passed node is not on a side chain.
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func (b *BlockChain) getReorganizeNodes(node *blockNode) (*list.List, *list.List) {
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// Nothing to detach or attach if there is no node.
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attachNodes := list.New()
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detachNodes := list.New()
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if node == nil {
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return detachNodes, attachNodes
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}
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// Find the fork point (if any) adding each block to the list of nodes
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// to attach to the main tree. Push them onto the list in reverse order
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// so they are attached in the appropriate order when iterating the list
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// later.
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ancestor := node
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for ; ancestor.parent != nil; ancestor = ancestor.parent {
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if ancestor.inMainChain {
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break
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}
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attachNodes.PushFront(ancestor)
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}
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// TODO(davec): Use prevNodeFromNode function in case the requested
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// node is further back than the what is in memory. This shouldn't
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// happen in the normal course of operation, but the ability to fetch
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// input transactions of arbitrary blocks will likely to be exposed at
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// some point and that could lead to an issue here.
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// Start from the end of the main chain and work backwards until the
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// common ancestor adding each block to the list of nodes to detach from
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// the main chain.
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for n := b.bestChain; n != nil && n.parent != nil; n = n.parent {
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if n.hash.IsEqual(ancestor.hash) {
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break
|
|
}
|
|
detachNodes.PushBack(n)
|
|
}
|
|
|
|
return detachNodes, attachNodes
|
|
}
|
|
|
|
// connectBlock handles connecting the passed node/block to the end of the main
|
|
// (best) chain.
|
|
func (b *BlockChain) connectBlock(node *blockNode, block *btcutil.Block) error {
|
|
// Make sure it's extending the end of the best chain.
|
|
prevHash := &block.MsgBlock().Header.PrevBlock
|
|
if b.bestChain != nil && !prevHash.IsEqual(b.bestChain.hash) {
|
|
return fmt.Errorf("connectBlock must be called with a block " +
|
|
"that extends the main chain")
|
|
}
|
|
|
|
// Insert the block into the database which houses the main chain.
|
|
_, err := b.db.InsertBlock(block)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
// TODO(davec): Remove transactions from memory transaction pool.
|
|
|
|
// Add the new node to the memory main chain indices for faster
|
|
// lookups.
|
|
node.inMainChain = true
|
|
b.index[*node.hash] = node
|
|
b.depNodes[*prevHash] = append(b.depNodes[*prevHash], node)
|
|
|
|
// This node is now the end of the best chain.
|
|
b.bestChain = node
|
|
|
|
// Notify the caller that the block was connected to the main chain.
|
|
// The caller would typically want to react with actions such as
|
|
// updating wallets.
|
|
b.sendNotification(NTBlockConnected, block)
|
|
|
|
return nil
|
|
}
|
|
|
|
// disconnectBlock handles disconnecting the passed node/block from the end of
|
|
// the main (best) chain.
|
|
func (b *BlockChain) disconnectBlock(node *blockNode, block *btcutil.Block) error {
|
|
// Make sure the node being disconnected is the end of the best chain.
|
|
if b.bestChain == nil || !node.hash.IsEqual(b.bestChain.hash) {
|
|
return fmt.Errorf("disconnectBlock must be called with the " +
|
|
"block at the end of the main chain")
|
|
}
|
|
|
|
// Remove the block from the database which houses the main chain.
|
|
prevNode, err := b.getPrevNodeFromNode(node)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
err = b.db.DropAfterBlockBySha(prevNode.hash)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
// TODO(davec): Put transactions back in memory transaction pool.
|
|
|
|
// Put block in the side chain cache.
|
|
node.inMainChain = false
|
|
b.blockCache[*node.hash] = block
|
|
|
|
// This node's parent is now the end of the best chain.
|
|
b.bestChain = node.parent
|
|
|
|
// Notify the caller that the block was disconnect from the main chain.
|
|
// The caller would typically want to react with actions such as
|
|
// updating wallets.
|
|
b.sendNotification(NTBlockDisconnected, block)
|
|
|
|
return nil
|
|
}
|
|
|
|
// reorganizeChain reorganizes the block chain by disconnecting the nodes in the
|
|
// detachNodes list and connecting the nodes in the attach list. It expects
|
|
// that the lists are already in the correct order and are in sync with the
|
|
// end of the current best chain. Specifically, nodes that are being
|
|
// disconnected must be in reverse order (think of popping them off
|
|
// the end of the chain) and nodes the are being attached must be in forwards
|
|
// order (think pushing them onto the end of the chain).
|
|
func (b *BlockChain) reorganizeChain(detachNodes, attachNodes *list.List) error {
|
|
// Ensure all of the needed side chain blocks are in the cache.
|
|
for e := attachNodes.Front(); e != nil; e = e.Next() {
|
|
n := e.Value.(*blockNode)
|
|
if _, exists := b.blockCache[*n.hash]; !exists {
|
|
return fmt.Errorf("block %v is missing from the side "+
|
|
"chain block cache", n.hash)
|
|
}
|
|
}
|
|
|
|
// Perform several checks to verify each block that needs to be attached
|
|
// to the main chain can be connected without violating any rules and
|
|
// without actually connecting the block.
|
|
//
|
|
// NOTE: bitcoind does these checks directly when it connects a block.
|
|
// The downside to that approach is that if any of these checks fail
|
|
// after disconneting some blocks or attaching others, all of the
|
|
// operations have to be rolled back to get the chain back into the
|
|
// state it was before the rule violation (or other failure). There are
|
|
// at least a couple of ways accomplish that rollback, but both involve
|
|
// tweaking the chain. This approach catches these issues before ever
|
|
// modifying the chain.
|
|
for e := attachNodes.Front(); e != nil; e = e.Next() {
|
|
n := e.Value.(*blockNode)
|
|
block := b.blockCache[*n.hash]
|
|
err := b.checkConnectBlock(n, block)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
}
|
|
|
|
// Disconnect blocks from the main chain.
|
|
for e := detachNodes.Front(); e != nil; e = e.Next() {
|
|
n := e.Value.(*blockNode)
|
|
block, err := b.db.FetchBlockBySha(n.hash)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
err = b.disconnectBlock(n, block)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
}
|
|
|
|
// Connect the new best chain blocks.
|
|
for e := attachNodes.Front(); e != nil; e = e.Next() {
|
|
n := e.Value.(*blockNode)
|
|
block := b.blockCache[*n.hash]
|
|
err := b.connectBlock(n, block)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
delete(b.blockCache, *n.hash)
|
|
}
|
|
|
|
// Log the point where the chain forked.
|
|
firstAttachNode := attachNodes.Front().Value.(*blockNode)
|
|
forkNode, err := b.getPrevNodeFromNode(firstAttachNode)
|
|
if err == nil {
|
|
log.Infof("REORGANIZE: Chain forks at %v", forkNode.hash)
|
|
}
|
|
|
|
// Log the old and new best chain heads.
|
|
firstDetachNode := detachNodes.Front().Value.(*blockNode)
|
|
lastAttachNode := attachNodes.Back().Value.(*blockNode)
|
|
log.Infof("REORGANIZE: Old best chain head was %v", firstDetachNode.hash)
|
|
log.Infof("REORGANIZE: New best chain head is %v", lastAttachNode.hash)
|
|
|
|
return nil
|
|
}
|
|
|
|
// connectBestChain handles connecting the passed block to the chain while
|
|
// respecting proper chain selection according to the chain with the most
|
|
// proof of work. In the typical case, the new block simply extends the main
|
|
// chain. However, it may also be extending (or creating) a side chain (fork)
|
|
// which may or may not end up becoming the main chain depending on which fork
|
|
// cumulatively has the most proof of work.
|
|
func (b *BlockChain) connectBestChain(node *blockNode, block *btcutil.Block) error {
|
|
// We haven't selected a best chain yet or we are extending the main
|
|
// (best) chain with a new block. This is the most common case.
|
|
if b.bestChain == nil || node.parent.hash.IsEqual(b.bestChain.hash) {
|
|
// Perform several checks to verify the block can be connected
|
|
// to the main chain (including whatever reorganization might
|
|
// be necessary to get this node to the main chain) without
|
|
// violating any rules and without actually connecting the
|
|
// block.
|
|
err := b.checkConnectBlock(node, block)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
// Connect the block to the main chain.
|
|
err = b.connectBlock(node, block)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
// Connect the parent node to this node.
|
|
if node.parent != nil {
|
|
node.parent.children = append(node.parent.children, node)
|
|
}
|
|
|
|
return nil
|
|
}
|
|
|
|
// We're extending (or creating) a side chain which may or may not
|
|
// become the main chain, but in either case we need the block stored
|
|
// for future processing, so add the block to the side chain holding
|
|
// cache.
|
|
log.Debugf("Adding block %v to side chain cache", node.hash)
|
|
b.blockCache[*node.hash] = block
|
|
b.index[*node.hash] = node
|
|
|
|
// We're extending (or creating) a side chain, but the cumulative
|
|
// work for this new side chain is not enough to make it the new chain.
|
|
if node.workSum.Cmp(b.bestChain.workSum) <= 0 {
|
|
// Connect the parent node to this node.
|
|
node.inMainChain = false
|
|
node.parent.children = append(node.parent.children, node)
|
|
|
|
// Find the fork point.
|
|
fork := node
|
|
for ; fork.parent != nil; fork = fork.parent {
|
|
if fork.inMainChain {
|
|
break
|
|
}
|
|
}
|
|
|
|
// Log information about how the block is forking the chain.
|
|
if fork.hash.IsEqual(node.parent.hash) {
|
|
log.Infof("FORK: Block %v forks the chain at height %d"+
|
|
"/block %v, but does not cause a reorganize",
|
|
node.hash, fork.height, fork.hash)
|
|
} else {
|
|
log.Infof("EXTEND FORK: Block %v extends a side chain "+
|
|
"which forks the chain at height %d/block %v",
|
|
node.hash, fork.height, fork.hash)
|
|
}
|
|
return nil
|
|
}
|
|
|
|
// We're extending (or creating) a side chain and the cumulative work
|
|
// for this new side chain is more than the old best chain, so this side
|
|
// chain needs to become the main chain. In order to accomplish that,
|
|
// find the common ancestor of both sides of the fork, disconnect the
|
|
// blocks that form the (now) old fork from the main chain, and attach
|
|
// the blocks that form the new chain to the main chain starting at the
|
|
// common ancenstor (the point where the chain forked).
|
|
detachNodes, attachNodes := b.getReorganizeNodes(node)
|
|
|
|
// Reorganize the chain.
|
|
log.Infof("REORGANIZE: Block %v is causing a reorganize.", node.hash)
|
|
err := b.reorganizeChain(detachNodes, attachNodes)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
return nil
|
|
}
|
|
|
|
// New returns a BlockChain instance for the passed bitcoin network using the
|
|
// provided backing database. It accepts a channel on which asynchronous
|
|
// notifications will be sent when various events take place. See the
|
|
// documentation for Notification and NotificationType for details on the
|
|
// types and contents of notifications. The provided channel can be nil if the
|
|
// caller is not interested in receiving notifications.
|
|
func New(db btcdb.Db, btcnet btcwire.BitcoinNet, c chan *Notification) *BlockChain {
|
|
b := BlockChain{
|
|
db: db,
|
|
btcnet: btcnet,
|
|
notifications: c,
|
|
root: nil,
|
|
bestChain: nil,
|
|
index: make(map[btcwire.ShaHash]*blockNode),
|
|
depNodes: make(map[btcwire.ShaHash][]*blockNode),
|
|
orphans: make(map[btcwire.ShaHash]*orphanBlock),
|
|
prevOrphans: make(map[btcwire.ShaHash][]*orphanBlock),
|
|
blockCache: make(map[btcwire.ShaHash]*btcutil.Block),
|
|
}
|
|
return &b
|
|
}
|