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go-ethereum/core/blockchain.go
Marius van der Wijden 87bb5db675
core: allow external processor (#25233)
2022-07-05 10:02:49 +03:00

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// Copyright 2014 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
// Package core implements the Ethereum consensus protocol.
package core
import (
"errors"
"fmt"
"io"
"math/big"
"sort"
"sync"
"sync/atomic"
"time"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/common/mclock"
"github.com/ethereum/go-ethereum/common/prque"
"github.com/ethereum/go-ethereum/consensus"
"github.com/ethereum/go-ethereum/core/rawdb"
"github.com/ethereum/go-ethereum/core/state"
"github.com/ethereum/go-ethereum/core/state/snapshot"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/core/vm"
"github.com/ethereum/go-ethereum/ethdb"
"github.com/ethereum/go-ethereum/event"
"github.com/ethereum/go-ethereum/internal/syncx"
"github.com/ethereum/go-ethereum/log"
"github.com/ethereum/go-ethereum/metrics"
"github.com/ethereum/go-ethereum/params"
"github.com/ethereum/go-ethereum/trie"
lru "github.com/hashicorp/golang-lru"
)
var (
headBlockGauge = metrics.NewRegisteredGauge("chain/head/block", nil)
headHeaderGauge = metrics.NewRegisteredGauge("chain/head/header", nil)
headFastBlockGauge = metrics.NewRegisteredGauge("chain/head/receipt", nil)
headFinalizedBlockGauge = metrics.NewRegisteredGauge("chain/head/finalized", nil)
accountReadTimer = metrics.NewRegisteredTimer("chain/account/reads", nil)
accountHashTimer = metrics.NewRegisteredTimer("chain/account/hashes", nil)
accountUpdateTimer = metrics.NewRegisteredTimer("chain/account/updates", nil)
accountCommitTimer = metrics.NewRegisteredTimer("chain/account/commits", nil)
storageReadTimer = metrics.NewRegisteredTimer("chain/storage/reads", nil)
storageHashTimer = metrics.NewRegisteredTimer("chain/storage/hashes", nil)
storageUpdateTimer = metrics.NewRegisteredTimer("chain/storage/updates", nil)
storageCommitTimer = metrics.NewRegisteredTimer("chain/storage/commits", nil)
snapshotAccountReadTimer = metrics.NewRegisteredTimer("chain/snapshot/account/reads", nil)
snapshotStorageReadTimer = metrics.NewRegisteredTimer("chain/snapshot/storage/reads", nil)
snapshotCommitTimer = metrics.NewRegisteredTimer("chain/snapshot/commits", nil)
blockInsertTimer = metrics.NewRegisteredTimer("chain/inserts", nil)
blockValidationTimer = metrics.NewRegisteredTimer("chain/validation", nil)
blockExecutionTimer = metrics.NewRegisteredTimer("chain/execution", nil)
blockWriteTimer = metrics.NewRegisteredTimer("chain/write", nil)
blockReorgMeter = metrics.NewRegisteredMeter("chain/reorg/executes", nil)
blockReorgAddMeter = metrics.NewRegisteredMeter("chain/reorg/add", nil)
blockReorgDropMeter = metrics.NewRegisteredMeter("chain/reorg/drop", nil)
blockReorgInvalidatedTx = metrics.NewRegisteredMeter("chain/reorg/invalidTx", nil)
blockPrefetchExecuteTimer = metrics.NewRegisteredTimer("chain/prefetch/executes", nil)
blockPrefetchInterruptMeter = metrics.NewRegisteredMeter("chain/prefetch/interrupts", nil)
errInsertionInterrupted = errors.New("insertion is interrupted")
errChainStopped = errors.New("blockchain is stopped")
)
const (
bodyCacheLimit = 256
blockCacheLimit = 256
receiptsCacheLimit = 32
txLookupCacheLimit = 1024
maxFutureBlocks = 256
maxTimeFutureBlocks = 30
TriesInMemory = 128
// BlockChainVersion ensures that an incompatible database forces a resync from scratch.
//
// Changelog:
//
// - Version 4
// The following incompatible database changes were added:
// * the `BlockNumber`, `TxHash`, `TxIndex`, `BlockHash` and `Index` fields of log are deleted
// * the `Bloom` field of receipt is deleted
// * the `BlockIndex` and `TxIndex` fields of txlookup are deleted
// - Version 5
// The following incompatible database changes were added:
// * the `TxHash`, `GasCost`, and `ContractAddress` fields are no longer stored for a receipt
// * the `TxHash`, `GasCost`, and `ContractAddress` fields are computed by looking up the
// receipts' corresponding block
// - Version 6
// The following incompatible database changes were added:
// * Transaction lookup information stores the corresponding block number instead of block hash
// - Version 7
// The following incompatible database changes were added:
// * Use freezer as the ancient database to maintain all ancient data
// - Version 8
// The following incompatible database changes were added:
// * New scheme for contract code in order to separate the codes and trie nodes
BlockChainVersion uint64 = 8
)
// CacheConfig contains the configuration values for the trie caching/pruning
// that's resident in a blockchain.
type CacheConfig struct {
TrieCleanLimit int // Memory allowance (MB) to use for caching trie nodes in memory
TrieCleanJournal string // Disk journal for saving clean cache entries.
TrieCleanRejournal time.Duration // Time interval to dump clean cache to disk periodically
TrieCleanNoPrefetch bool // Whether to disable heuristic state prefetching for followup blocks
TrieDirtyLimit int // Memory limit (MB) at which to start flushing dirty trie nodes to disk
TrieDirtyDisabled bool // Whether to disable trie write caching and GC altogether (archive node)
TrieTimeLimit time.Duration // Time limit after which to flush the current in-memory trie to disk
SnapshotLimit int // Memory allowance (MB) to use for caching snapshot entries in memory
Preimages bool // Whether to store preimage of trie key to the disk
SnapshotWait bool // Wait for snapshot construction on startup. TODO(karalabe): This is a dirty hack for testing, nuke it
}
// defaultCacheConfig are the default caching values if none are specified by the
// user (also used during testing).
var defaultCacheConfig = &CacheConfig{
TrieCleanLimit: 256,
TrieDirtyLimit: 256,
TrieTimeLimit: 5 * time.Minute,
SnapshotLimit: 256,
SnapshotWait: true,
}
// BlockChain represents the canonical chain given a database with a genesis
// block. The Blockchain manages chain imports, reverts, chain reorganisations.
//
// Importing blocks in to the block chain happens according to the set of rules
// defined by the two stage Validator. Processing of blocks is done using the
// Processor which processes the included transaction. The validation of the state
// is done in the second part of the Validator. Failing results in aborting of
// the import.
//
// The BlockChain also helps in returning blocks from **any** chain included
// in the database as well as blocks that represents the canonical chain. It's
// important to note that GetBlock can return any block and does not need to be
// included in the canonical one where as GetBlockByNumber always represents the
// canonical chain.
type BlockChain struct {
chainConfig *params.ChainConfig // Chain & network configuration
cacheConfig *CacheConfig // Cache configuration for pruning
db ethdb.Database // Low level persistent database to store final content in
snaps *snapshot.Tree // Snapshot tree for fast trie leaf access
triegc *prque.Prque // Priority queue mapping block numbers to tries to gc
gcproc time.Duration // Accumulates canonical block processing for trie dumping
// txLookupLimit is the maximum number of blocks from head whose tx indices
// are reserved:
// * 0: means no limit and regenerate any missing indexes
// * N: means N block limit [HEAD-N+1, HEAD] and delete extra indexes
// * nil: disable tx reindexer/deleter, but still index new blocks
txLookupLimit uint64
hc *HeaderChain
rmLogsFeed event.Feed
chainFeed event.Feed
chainSideFeed event.Feed
chainHeadFeed event.Feed
logsFeed event.Feed
blockProcFeed event.Feed
scope event.SubscriptionScope
genesisBlock *types.Block
// This mutex synchronizes chain write operations.
// Readers don't need to take it, they can just read the database.
chainmu *syncx.ClosableMutex
currentBlock atomic.Value // Current head of the block chain
currentFastBlock atomic.Value // Current head of the fast-sync chain (may be above the block chain!)
currentFinalizedBlock atomic.Value // Current finalized head
stateCache state.Database // State database to reuse between imports (contains state cache)
bodyCache *lru.Cache // Cache for the most recent block bodies
bodyRLPCache *lru.Cache // Cache for the most recent block bodies in RLP encoded format
receiptsCache *lru.Cache // Cache for the most recent receipts per block
blockCache *lru.Cache // Cache for the most recent entire blocks
txLookupCache *lru.Cache // Cache for the most recent transaction lookup data.
futureBlocks *lru.Cache // future blocks are blocks added for later processing
wg sync.WaitGroup //
quit chan struct{} // shutdown signal, closed in Stop.
running int32 // 0 if chain is running, 1 when stopped
procInterrupt int32 // interrupt signaler for block processing
engine consensus.Engine
validator Validator // Block and state validator interface
prefetcher Prefetcher
processor Processor // Block transaction processor interface
forker *ForkChoice
vmConfig vm.Config
}
// NewBlockChain returns a fully initialised block chain using information
// available in the database. It initialises the default Ethereum Validator
// and Processor.
func NewBlockChain(db ethdb.Database, cacheConfig *CacheConfig, chainConfig *params.ChainConfig, engine consensus.Engine, vmConfig vm.Config, shouldPreserve func(header *types.Header) bool, txLookupLimit *uint64) (*BlockChain, error) {
if cacheConfig == nil {
cacheConfig = defaultCacheConfig
}
bodyCache, _ := lru.New(bodyCacheLimit)
bodyRLPCache, _ := lru.New(bodyCacheLimit)
receiptsCache, _ := lru.New(receiptsCacheLimit)
blockCache, _ := lru.New(blockCacheLimit)
txLookupCache, _ := lru.New(txLookupCacheLimit)
futureBlocks, _ := lru.New(maxFutureBlocks)
bc := &BlockChain{
chainConfig: chainConfig,
cacheConfig: cacheConfig,
db: db,
triegc: prque.New(nil),
stateCache: state.NewDatabaseWithConfig(db, &trie.Config{
Cache: cacheConfig.TrieCleanLimit,
Journal: cacheConfig.TrieCleanJournal,
Preimages: cacheConfig.Preimages,
}),
quit: make(chan struct{}),
chainmu: syncx.NewClosableMutex(),
bodyCache: bodyCache,
bodyRLPCache: bodyRLPCache,
receiptsCache: receiptsCache,
blockCache: blockCache,
txLookupCache: txLookupCache,
futureBlocks: futureBlocks,
engine: engine,
vmConfig: vmConfig,
}
bc.forker = NewForkChoice(bc, shouldPreserve)
bc.validator = NewBlockValidator(chainConfig, bc, engine)
bc.prefetcher = newStatePrefetcher(chainConfig, bc, engine)
bc.processor = NewStateProcessor(chainConfig, bc, engine)
var err error
bc.hc, err = NewHeaderChain(db, chainConfig, engine, bc.insertStopped)
if err != nil {
return nil, err
}
bc.genesisBlock = bc.GetBlockByNumber(0)
if bc.genesisBlock == nil {
return nil, ErrNoGenesis
}
var nilBlock *types.Block
bc.currentBlock.Store(nilBlock)
bc.currentFastBlock.Store(nilBlock)
bc.currentFinalizedBlock.Store(nilBlock)
// Initialize the chain with ancient data if it isn't empty.
var txIndexBlock uint64
if bc.empty() {
rawdb.InitDatabaseFromFreezer(bc.db)
// If ancient database is not empty, reconstruct all missing
// indices in the background.
frozen, _ := bc.db.Ancients()
if frozen > 0 {
txIndexBlock = frozen
}
}
if err := bc.loadLastState(); err != nil {
return nil, err
}
// Make sure the state associated with the block is available
head := bc.CurrentBlock()
if _, err := state.New(head.Root(), bc.stateCache, bc.snaps); err != nil {
// Head state is missing, before the state recovery, find out the
// disk layer point of snapshot(if it's enabled). Make sure the
// rewound point is lower than disk layer.
var diskRoot common.Hash
if bc.cacheConfig.SnapshotLimit > 0 {
diskRoot = rawdb.ReadSnapshotRoot(bc.db)
}
if diskRoot != (common.Hash{}) {
log.Warn("Head state missing, repairing", "number", head.Number(), "hash", head.Hash(), "snaproot", diskRoot)
snapDisk, err := bc.setHeadBeyondRoot(head.NumberU64(), diskRoot, true)
if err != nil {
return nil, err
}
// Chain rewound, persist old snapshot number to indicate recovery procedure
if snapDisk != 0 {
rawdb.WriteSnapshotRecoveryNumber(bc.db, snapDisk)
}
} else {
log.Warn("Head state missing, repairing", "number", head.Number(), "hash", head.Hash())
if _, err := bc.setHeadBeyondRoot(head.NumberU64(), common.Hash{}, true); err != nil {
return nil, err
}
}
}
// Ensure that a previous crash in SetHead doesn't leave extra ancients
if frozen, err := bc.db.Ancients(); err == nil && frozen > 0 {
var (
needRewind bool
low uint64
)
// The head full block may be rolled back to a very low height due to
// blockchain repair. If the head full block is even lower than the ancient
// chain, truncate the ancient store.
fullBlock := bc.CurrentBlock()
if fullBlock != nil && fullBlock.Hash() != bc.genesisBlock.Hash() && fullBlock.NumberU64() < frozen-1 {
needRewind = true
low = fullBlock.NumberU64()
}
// In fast sync, it may happen that ancient data has been written to the
// ancient store, but the LastFastBlock has not been updated, truncate the
// extra data here.
fastBlock := bc.CurrentFastBlock()
if fastBlock != nil && fastBlock.NumberU64() < frozen-1 {
needRewind = true
if fastBlock.NumberU64() < low || low == 0 {
low = fastBlock.NumberU64()
}
}
if needRewind {
log.Error("Truncating ancient chain", "from", bc.CurrentHeader().Number.Uint64(), "to", low)
if err := bc.SetHead(low); err != nil {
return nil, err
}
}
}
// The first thing the node will do is reconstruct the verification data for
// the head block (ethash cache or clique voting snapshot). Might as well do
// it in advance.
bc.engine.VerifyHeader(bc, bc.CurrentHeader(), true)
// Check the current state of the block hashes and make sure that we do not have any of the bad blocks in our chain
for hash := range BadHashes {
if header := bc.GetHeaderByHash(hash); header != nil {
// get the canonical block corresponding to the offending header's number
headerByNumber := bc.GetHeaderByNumber(header.Number.Uint64())
// make sure the headerByNumber (if present) is in our current canonical chain
if headerByNumber != nil && headerByNumber.Hash() == header.Hash() {
log.Error("Found bad hash, rewinding chain", "number", header.Number, "hash", header.ParentHash)
if err := bc.SetHead(header.Number.Uint64() - 1); err != nil {
return nil, err
}
log.Error("Chain rewind was successful, resuming normal operation")
}
}
}
// Load any existing snapshot, regenerating it if loading failed
if bc.cacheConfig.SnapshotLimit > 0 {
// If the chain was rewound past the snapshot persistent layer (causing
// a recovery block number to be persisted to disk), check if we're still
// in recovery mode and in that case, don't invalidate the snapshot on a
// head mismatch.
var recover bool
head := bc.CurrentBlock()
if layer := rawdb.ReadSnapshotRecoveryNumber(bc.db); layer != nil && *layer > head.NumberU64() {
log.Warn("Enabling snapshot recovery", "chainhead", head.NumberU64(), "diskbase", *layer)
recover = true
}
bc.snaps, _ = snapshot.New(bc.db, bc.stateCache.TrieDB(), bc.cacheConfig.SnapshotLimit, head.Root(), !bc.cacheConfig.SnapshotWait, true, recover)
}
// Start future block processor.
bc.wg.Add(1)
go bc.updateFutureBlocks()
// Start tx indexer/unindexer.
if txLookupLimit != nil {
bc.txLookupLimit = *txLookupLimit
bc.wg.Add(1)
go bc.maintainTxIndex(txIndexBlock)
}
// If periodic cache journal is required, spin it up.
if bc.cacheConfig.TrieCleanRejournal > 0 {
if bc.cacheConfig.TrieCleanRejournal < time.Minute {
log.Warn("Sanitizing invalid trie cache journal time", "provided", bc.cacheConfig.TrieCleanRejournal, "updated", time.Minute)
bc.cacheConfig.TrieCleanRejournal = time.Minute
}
triedb := bc.stateCache.TrieDB()
bc.wg.Add(1)
go func() {
defer bc.wg.Done()
triedb.SaveCachePeriodically(bc.cacheConfig.TrieCleanJournal, bc.cacheConfig.TrieCleanRejournal, bc.quit)
}()
}
return bc, nil
}
// empty returns an indicator whether the blockchain is empty.
// Note, it's a special case that we connect a non-empty ancient
// database with an empty node, so that we can plugin the ancient
// into node seamlessly.
func (bc *BlockChain) empty() bool {
genesis := bc.genesisBlock.Hash()
for _, hash := range []common.Hash{rawdb.ReadHeadBlockHash(bc.db), rawdb.ReadHeadHeaderHash(bc.db), rawdb.ReadHeadFastBlockHash(bc.db)} {
if hash != genesis {
return false
}
}
return true
}
// loadLastState loads the last known chain state from the database. This method
// assumes that the chain manager mutex is held.
func (bc *BlockChain) loadLastState() error {
// Restore the last known head block
head := rawdb.ReadHeadBlockHash(bc.db)
if head == (common.Hash{}) {
// Corrupt or empty database, init from scratch
log.Warn("Empty database, resetting chain")
return bc.Reset()
}
// Make sure the entire head block is available
currentBlock := bc.GetBlockByHash(head)
if currentBlock == nil {
// Corrupt or empty database, init from scratch
log.Warn("Head block missing, resetting chain", "hash", head)
return bc.Reset()
}
// Everything seems to be fine, set as the head block
bc.currentBlock.Store(currentBlock)
headBlockGauge.Update(int64(currentBlock.NumberU64()))
// Restore the last known head header
currentHeader := currentBlock.Header()
if head := rawdb.ReadHeadHeaderHash(bc.db); head != (common.Hash{}) {
if header := bc.GetHeaderByHash(head); header != nil {
currentHeader = header
}
}
bc.hc.SetCurrentHeader(currentHeader)
// Restore the last known head fast block
bc.currentFastBlock.Store(currentBlock)
headFastBlockGauge.Update(int64(currentBlock.NumberU64()))
if head := rawdb.ReadHeadFastBlockHash(bc.db); head != (common.Hash{}) {
if block := bc.GetBlockByHash(head); block != nil {
bc.currentFastBlock.Store(block)
headFastBlockGauge.Update(int64(block.NumberU64()))
}
}
// Restore the last known finalized block
if head := rawdb.ReadFinalizedBlockHash(bc.db); head != (common.Hash{}) {
if block := bc.GetBlockByHash(head); block != nil {
bc.currentFinalizedBlock.Store(block)
headFinalizedBlockGauge.Update(int64(block.NumberU64()))
}
}
// Issue a status log for the user
currentFastBlock := bc.CurrentFastBlock()
currentFinalizedBlock := bc.CurrentFinalizedBlock()
headerTd := bc.GetTd(currentHeader.Hash(), currentHeader.Number.Uint64())
blockTd := bc.GetTd(currentBlock.Hash(), currentBlock.NumberU64())
fastTd := bc.GetTd(currentFastBlock.Hash(), currentFastBlock.NumberU64())
log.Info("Loaded most recent local header", "number", currentHeader.Number, "hash", currentHeader.Hash(), "td", headerTd, "age", common.PrettyAge(time.Unix(int64(currentHeader.Time), 0)))
log.Info("Loaded most recent local full block", "number", currentBlock.Number(), "hash", currentBlock.Hash(), "td", blockTd, "age", common.PrettyAge(time.Unix(int64(currentBlock.Time()), 0)))
log.Info("Loaded most recent local fast block", "number", currentFastBlock.Number(), "hash", currentFastBlock.Hash(), "td", fastTd, "age", common.PrettyAge(time.Unix(int64(currentFastBlock.Time()), 0)))
if currentFinalizedBlock != nil {
finalTd := bc.GetTd(currentFinalizedBlock.Hash(), currentFinalizedBlock.NumberU64())
log.Info("Loaded most recent local finalized block", "number", currentFinalizedBlock.Number(), "hash", currentFinalizedBlock.Hash(), "td", finalTd, "age", common.PrettyAge(time.Unix(int64(currentFinalizedBlock.Time()), 0)))
}
if pivot := rawdb.ReadLastPivotNumber(bc.db); pivot != nil {
log.Info("Loaded last fast-sync pivot marker", "number", *pivot)
}
return nil
}
// SetHead rewinds the local chain to a new head. Depending on whether the node
// was fast synced or full synced and in which state, the method will try to
// delete minimal data from disk whilst retaining chain consistency.
func (bc *BlockChain) SetHead(head uint64) error {
_, err := bc.setHeadBeyondRoot(head, common.Hash{}, false)
return err
}
// SetFinalized sets the finalized block.
func (bc *BlockChain) SetFinalized(block *types.Block) {
bc.currentFinalizedBlock.Store(block)
rawdb.WriteFinalizedBlockHash(bc.db, block.Hash())
headFinalizedBlockGauge.Update(int64(block.NumberU64()))
}
// setHeadBeyondRoot rewinds the local chain to a new head with the extra condition
// that the rewind must pass the specified state root. This method is meant to be
// used when rewinding with snapshots enabled to ensure that we go back further than
// persistent disk layer. Depending on whether the node was fast synced or full, and
// in which state, the method will try to delete minimal data from disk whilst
// retaining chain consistency.
//
// The method returns the block number where the requested root cap was found.
func (bc *BlockChain) setHeadBeyondRoot(head uint64, root common.Hash, repair bool) (uint64, error) {
if !bc.chainmu.TryLock() {
return 0, errChainStopped
}
defer bc.chainmu.Unlock()
// Track the block number of the requested root hash
var rootNumber uint64 // (no root == always 0)
// Retrieve the last pivot block to short circuit rollbacks beyond it and the
// current freezer limit to start nuking id underflown
pivot := rawdb.ReadLastPivotNumber(bc.db)
frozen, _ := bc.db.Ancients()
updateFn := func(db ethdb.KeyValueWriter, header *types.Header) (uint64, bool) {
// Rewind the blockchain, ensuring we don't end up with a stateless head
// block. Note, depth equality is permitted to allow using SetHead as a
// chain reparation mechanism without deleting any data!
if currentBlock := bc.CurrentBlock(); currentBlock != nil && header.Number.Uint64() <= currentBlock.NumberU64() {
newHeadBlock := bc.GetBlock(header.Hash(), header.Number.Uint64())
if newHeadBlock == nil {
log.Error("Gap in the chain, rewinding to genesis", "number", header.Number, "hash", header.Hash())
newHeadBlock = bc.genesisBlock
} else {
// Block exists, keep rewinding until we find one with state,
// keeping rewinding until we exceed the optional threshold
// root hash
beyondRoot := (root == common.Hash{}) // Flag whether we're beyond the requested root (no root, always true)
for {
// If a root threshold was requested but not yet crossed, check
if root != (common.Hash{}) && !beyondRoot && newHeadBlock.Root() == root {
beyondRoot, rootNumber = true, newHeadBlock.NumberU64()
}
if _, err := state.New(newHeadBlock.Root(), bc.stateCache, bc.snaps); err != nil {
log.Trace("Block state missing, rewinding further", "number", newHeadBlock.NumberU64(), "hash", newHeadBlock.Hash())
if pivot == nil || newHeadBlock.NumberU64() > *pivot {
parent := bc.GetBlock(newHeadBlock.ParentHash(), newHeadBlock.NumberU64()-1)
if parent != nil {
newHeadBlock = parent
continue
}
log.Error("Missing block in the middle, aiming genesis", "number", newHeadBlock.NumberU64()-1, "hash", newHeadBlock.ParentHash())
newHeadBlock = bc.genesisBlock
} else {
log.Trace("Rewind passed pivot, aiming genesis", "number", newHeadBlock.NumberU64(), "hash", newHeadBlock.Hash(), "pivot", *pivot)
newHeadBlock = bc.genesisBlock
}
}
if beyondRoot || newHeadBlock.NumberU64() == 0 {
if newHeadBlock.NumberU64() == 0 {
// Recommit the genesis state into disk in case the rewinding destination
// is genesis block and the relevant state is gone. In the future this
// rewinding destination can be the earliest block stored in the chain
// if the historical chain pruning is enabled. In that case the logic
// needs to be improved here.
if !bc.HasState(bc.genesisBlock.Root()) {
if err := CommitGenesisState(bc.db, bc.genesisBlock.Hash()); err != nil {
log.Crit("Failed to commit genesis state", "err", err)
}
log.Debug("Recommitted genesis state to disk")
}
}
log.Debug("Rewound to block with state", "number", newHeadBlock.NumberU64(), "hash", newHeadBlock.Hash())
break
}
log.Debug("Skipping block with threshold state", "number", newHeadBlock.NumberU64(), "hash", newHeadBlock.Hash(), "root", newHeadBlock.Root())
newHeadBlock = bc.GetBlock(newHeadBlock.ParentHash(), newHeadBlock.NumberU64()-1) // Keep rewinding
}
}
rawdb.WriteHeadBlockHash(db, newHeadBlock.Hash())
// Degrade the chain markers if they are explicitly reverted.
// In theory we should update all in-memory markers in the
// last step, however the direction of SetHead is from high
// to low, so it's safe to update in-memory markers directly.
bc.currentBlock.Store(newHeadBlock)
headBlockGauge.Update(int64(newHeadBlock.NumberU64()))
}
// Rewind the fast block in a simpleton way to the target head
if currentFastBlock := bc.CurrentFastBlock(); currentFastBlock != nil && header.Number.Uint64() < currentFastBlock.NumberU64() {
newHeadFastBlock := bc.GetBlock(header.Hash(), header.Number.Uint64())
// If either blocks reached nil, reset to the genesis state
if newHeadFastBlock == nil {
newHeadFastBlock = bc.genesisBlock
}
rawdb.WriteHeadFastBlockHash(db, newHeadFastBlock.Hash())
// Degrade the chain markers if they are explicitly reverted.
// In theory we should update all in-memory markers in the
// last step, however the direction of SetHead is from high
// to low, so it's safe the update in-memory markers directly.
bc.currentFastBlock.Store(newHeadFastBlock)
headFastBlockGauge.Update(int64(newHeadFastBlock.NumberU64()))
}
head := bc.CurrentBlock().NumberU64()
// If setHead underflown the freezer threshold and the block processing
// intent afterwards is full block importing, delete the chain segment
// between the stateful-block and the sethead target.
var wipe bool
if head+1 < frozen {
wipe = pivot == nil || head >= *pivot
}
return head, wipe // Only force wipe if full synced
}
// Rewind the header chain, deleting all block bodies until then
delFn := func(db ethdb.KeyValueWriter, hash common.Hash, num uint64) {
// Ignore the error here since light client won't hit this path
frozen, _ := bc.db.Ancients()
if num+1 <= frozen {
// Truncate all relative data(header, total difficulty, body, receipt
// and canonical hash) from ancient store.
if err := bc.db.TruncateHead(num); err != nil {
log.Crit("Failed to truncate ancient data", "number", num, "err", err)
}
// Remove the hash <-> number mapping from the active store.
rawdb.DeleteHeaderNumber(db, hash)
} else {
// Remove relative body and receipts from the active store.
// The header, total difficulty and canonical hash will be
// removed in the hc.SetHead function.
rawdb.DeleteBody(db, hash, num)
rawdb.DeleteReceipts(db, hash, num)
}
// Todo(rjl493456442) txlookup, bloombits, etc
}
// If SetHead was only called as a chain reparation method, try to skip
// touching the header chain altogether, unless the freezer is broken
if repair {
if target, force := updateFn(bc.db, bc.CurrentBlock().Header()); force {
bc.hc.SetHead(target, updateFn, delFn)
}
} else {
// Rewind the chain to the requested head and keep going backwards until a
// block with a state is found or fast sync pivot is passed
log.Warn("Rewinding blockchain", "target", head)
bc.hc.SetHead(head, updateFn, delFn)
}
// Clear out any stale content from the caches
bc.bodyCache.Purge()
bc.bodyRLPCache.Purge()
bc.receiptsCache.Purge()
bc.blockCache.Purge()
bc.txLookupCache.Purge()
bc.futureBlocks.Purge()
return rootNumber, bc.loadLastState()
}
// SnapSyncCommitHead sets the current head block to the one defined by the hash
// irrelevant what the chain contents were prior.
func (bc *BlockChain) SnapSyncCommitHead(hash common.Hash) error {
// Make sure that both the block as well at its state trie exists
block := bc.GetBlockByHash(hash)
if block == nil {
return fmt.Errorf("non existent block [%x..]", hash[:4])
}
if _, err := trie.NewSecure(common.Hash{}, block.Root(), bc.stateCache.TrieDB()); err != nil {
return err
}
// If all checks out, manually set the head block.
if !bc.chainmu.TryLock() {
return errChainStopped
}
bc.currentBlock.Store(block)
headBlockGauge.Update(int64(block.NumberU64()))
bc.chainmu.Unlock()
// Destroy any existing state snapshot and regenerate it in the background,
// also resuming the normal maintenance of any previously paused snapshot.
if bc.snaps != nil {
bc.snaps.Rebuild(block.Root())
}
log.Info("Committed new head block", "number", block.Number(), "hash", hash)
return nil
}
// Reset purges the entire blockchain, restoring it to its genesis state.
func (bc *BlockChain) Reset() error {
return bc.ResetWithGenesisBlock(bc.genesisBlock)
}
// ResetWithGenesisBlock purges the entire blockchain, restoring it to the
// specified genesis state.
func (bc *BlockChain) ResetWithGenesisBlock(genesis *types.Block) error {
// Dump the entire block chain and purge the caches
if err := bc.SetHead(0); err != nil {
return err
}
if !bc.chainmu.TryLock() {
return errChainStopped
}
defer bc.chainmu.Unlock()
// Prepare the genesis block and reinitialise the chain
batch := bc.db.NewBatch()
rawdb.WriteTd(batch, genesis.Hash(), genesis.NumberU64(), genesis.Difficulty())
rawdb.WriteBlock(batch, genesis)
if err := batch.Write(); err != nil {
log.Crit("Failed to write genesis block", "err", err)
}
bc.writeHeadBlock(genesis)
// Last update all in-memory chain markers
bc.genesisBlock = genesis
bc.currentBlock.Store(bc.genesisBlock)
headBlockGauge.Update(int64(bc.genesisBlock.NumberU64()))
bc.hc.SetGenesis(bc.genesisBlock.Header())
bc.hc.SetCurrentHeader(bc.genesisBlock.Header())
bc.currentFastBlock.Store(bc.genesisBlock)
headFastBlockGauge.Update(int64(bc.genesisBlock.NumberU64()))
return nil
}
// Export writes the active chain to the given writer.
func (bc *BlockChain) Export(w io.Writer) error {
return bc.ExportN(w, uint64(0), bc.CurrentBlock().NumberU64())
}
// ExportN writes a subset of the active chain to the given writer.
func (bc *BlockChain) ExportN(w io.Writer, first uint64, last uint64) error {
if !bc.chainmu.TryLock() {
return errChainStopped
}
defer bc.chainmu.Unlock()
if first > last {
return fmt.Errorf("export failed: first (%d) is greater than last (%d)", first, last)
}
log.Info("Exporting batch of blocks", "count", last-first+1)
start, reported := time.Now(), time.Now()
for nr := first; nr <= last; nr++ {
block := bc.GetBlockByNumber(nr)
if block == nil {
return fmt.Errorf("export failed on #%d: not found", nr)
}
if err := block.EncodeRLP(w); err != nil {
return err
}
if time.Since(reported) >= statsReportLimit {
log.Info("Exporting blocks", "exported", block.NumberU64()-first, "elapsed", common.PrettyDuration(time.Since(start)))
reported = time.Now()
}
}
return nil
}
// writeHeadBlock injects a new head block into the current block chain. This method
// assumes that the block is indeed a true head. It will also reset the head
// header and the head fast sync block to this very same block if they are older
// or if they are on a different side chain.
//
// Note, this function assumes that the `mu` mutex is held!
func (bc *BlockChain) writeHeadBlock(block *types.Block) {
// Add the block to the canonical chain number scheme and mark as the head
batch := bc.db.NewBatch()
rawdb.WriteHeadHeaderHash(batch, block.Hash())
rawdb.WriteHeadFastBlockHash(batch, block.Hash())
rawdb.WriteCanonicalHash(batch, block.Hash(), block.NumberU64())
rawdb.WriteTxLookupEntriesByBlock(batch, block)
rawdb.WriteHeadBlockHash(batch, block.Hash())
// Flush the whole batch into the disk, exit the node if failed
if err := batch.Write(); err != nil {
log.Crit("Failed to update chain indexes and markers", "err", err)
}
// Update all in-memory chain markers in the last step
bc.hc.SetCurrentHeader(block.Header())
bc.currentFastBlock.Store(block)
headFastBlockGauge.Update(int64(block.NumberU64()))
bc.currentBlock.Store(block)
headBlockGauge.Update(int64(block.NumberU64()))
}
// Stop stops the blockchain service. If any imports are currently in progress
// it will abort them using the procInterrupt.
func (bc *BlockChain) Stop() {
if !atomic.CompareAndSwapInt32(&bc.running, 0, 1) {
return
}
// Unsubscribe all subscriptions registered from blockchain.
bc.scope.Close()
// Signal shutdown to all goroutines.
close(bc.quit)
bc.StopInsert()
// Now wait for all chain modifications to end and persistent goroutines to exit.
//
// Note: Close waits for the mutex to become available, i.e. any running chain
// modification will have exited when Close returns. Since we also called StopInsert,
// the mutex should become available quickly. It cannot be taken again after Close has
// returned.
bc.chainmu.Close()
bc.wg.Wait()
// Ensure that the entirety of the state snapshot is journalled to disk.
var snapBase common.Hash
if bc.snaps != nil {
var err error
if snapBase, err = bc.snaps.Journal(bc.CurrentBlock().Root()); err != nil {
log.Error("Failed to journal state snapshot", "err", err)
}
}
// Ensure the state of a recent block is also stored to disk before exiting.
// We're writing three different states to catch different restart scenarios:
// - HEAD: So we don't need to reprocess any blocks in the general case
// - HEAD-1: So we don't do large reorgs if our HEAD becomes an uncle
// - HEAD-127: So we have a hard limit on the number of blocks reexecuted
if !bc.cacheConfig.TrieDirtyDisabled {
triedb := bc.stateCache.TrieDB()
for _, offset := range []uint64{0, 1, TriesInMemory - 1} {
if number := bc.CurrentBlock().NumberU64(); number > offset {
recent := bc.GetBlockByNumber(number - offset)
log.Info("Writing cached state to disk", "block", recent.Number(), "hash", recent.Hash(), "root", recent.Root())
if err := triedb.Commit(recent.Root(), true, nil); err != nil {
log.Error("Failed to commit recent state trie", "err", err)
}
}
}
if snapBase != (common.Hash{}) {
log.Info("Writing snapshot state to disk", "root", snapBase)
if err := triedb.Commit(snapBase, true, nil); err != nil {
log.Error("Failed to commit recent state trie", "err", err)
}
}
for !bc.triegc.Empty() {
triedb.Dereference(bc.triegc.PopItem().(common.Hash))
}
if size, _ := triedb.Size(); size != 0 {
log.Error("Dangling trie nodes after full cleanup")
}
}
// Ensure all live cached entries be saved into disk, so that we can skip
// cache warmup when node restarts.
if bc.cacheConfig.TrieCleanJournal != "" {
triedb := bc.stateCache.TrieDB()
triedb.SaveCache(bc.cacheConfig.TrieCleanJournal)
}
log.Info("Blockchain stopped")
}
// StopInsert interrupts all insertion methods, causing them to return
// errInsertionInterrupted as soon as possible. Insertion is permanently disabled after
// calling this method.
func (bc *BlockChain) StopInsert() {
atomic.StoreInt32(&bc.procInterrupt, 1)
}
// insertStopped returns true after StopInsert has been called.
func (bc *BlockChain) insertStopped() bool {
return atomic.LoadInt32(&bc.procInterrupt) == 1
}
func (bc *BlockChain) procFutureBlocks() {
blocks := make([]*types.Block, 0, bc.futureBlocks.Len())
for _, hash := range bc.futureBlocks.Keys() {
if block, exist := bc.futureBlocks.Peek(hash); exist {
blocks = append(blocks, block.(*types.Block))
}
}
if len(blocks) > 0 {
sort.Slice(blocks, func(i, j int) bool {
return blocks[i].NumberU64() < blocks[j].NumberU64()
})
// Insert one by one as chain insertion needs contiguous ancestry between blocks
for i := range blocks {
bc.InsertChain(blocks[i : i+1])
}
}
}
// WriteStatus status of write
type WriteStatus byte
const (
NonStatTy WriteStatus = iota
CanonStatTy
SideStatTy
)
// InsertReceiptChain attempts to complete an already existing header chain with
// transaction and receipt data.
func (bc *BlockChain) InsertReceiptChain(blockChain types.Blocks, receiptChain []types.Receipts, ancientLimit uint64) (int, error) {
// We don't require the chainMu here since we want to maximize the
// concurrency of header insertion and receipt insertion.
bc.wg.Add(1)
defer bc.wg.Done()
var (
ancientBlocks, liveBlocks types.Blocks
ancientReceipts, liveReceipts []types.Receipts
)
// Do a sanity check that the provided chain is actually ordered and linked
for i := 0; i < len(blockChain); i++ {
if i != 0 {
if blockChain[i].NumberU64() != blockChain[i-1].NumberU64()+1 || blockChain[i].ParentHash() != blockChain[i-1].Hash() {
log.Error("Non contiguous receipt insert", "number", blockChain[i].Number(), "hash", blockChain[i].Hash(), "parent", blockChain[i].ParentHash(),
"prevnumber", blockChain[i-1].Number(), "prevhash", blockChain[i-1].Hash())
return 0, fmt.Errorf("non contiguous insert: item %d is #%d [%x..], item %d is #%d [%x..] (parent [%x..])", i-1, blockChain[i-1].NumberU64(),
blockChain[i-1].Hash().Bytes()[:4], i, blockChain[i].NumberU64(), blockChain[i].Hash().Bytes()[:4], blockChain[i].ParentHash().Bytes()[:4])
}
}
if blockChain[i].NumberU64() <= ancientLimit {
ancientBlocks, ancientReceipts = append(ancientBlocks, blockChain[i]), append(ancientReceipts, receiptChain[i])
} else {
liveBlocks, liveReceipts = append(liveBlocks, blockChain[i]), append(liveReceipts, receiptChain[i])
}
}
var (
stats = struct{ processed, ignored int32 }{}
start = time.Now()
size = int64(0)
)
// updateHead updates the head fast sync block if the inserted blocks are better
// and returns an indicator whether the inserted blocks are canonical.
updateHead := func(head *types.Block) bool {
if !bc.chainmu.TryLock() {
return false
}
defer bc.chainmu.Unlock()
// Rewind may have occurred, skip in that case.
if bc.CurrentHeader().Number.Cmp(head.Number()) >= 0 {
reorg, err := bc.forker.ReorgNeeded(bc.CurrentFastBlock().Header(), head.Header())
if err != nil {
log.Warn("Reorg failed", "err", err)
return false
} else if !reorg {
return false
}
rawdb.WriteHeadFastBlockHash(bc.db, head.Hash())
bc.currentFastBlock.Store(head)
headFastBlockGauge.Update(int64(head.NumberU64()))
return true
}
return false
}
// writeAncient writes blockchain and corresponding receipt chain into ancient store.
//
// this function only accepts canonical chain data. All side chain will be reverted
// eventually.
writeAncient := func(blockChain types.Blocks, receiptChain []types.Receipts) (int, error) {
first := blockChain[0]
last := blockChain[len(blockChain)-1]
// Ensure genesis is in ancients.
if first.NumberU64() == 1 {
if frozen, _ := bc.db.Ancients(); frozen == 0 {
b := bc.genesisBlock
td := bc.genesisBlock.Difficulty()
writeSize, err := rawdb.WriteAncientBlocks(bc.db, []*types.Block{b}, []types.Receipts{nil}, td)
size += writeSize
if err != nil {
log.Error("Error writing genesis to ancients", "err", err)
return 0, err
}
log.Info("Wrote genesis to ancients")
}
}
// Before writing the blocks to the ancients, we need to ensure that
// they correspond to the what the headerchain 'expects'.
// We only check the last block/header, since it's a contiguous chain.
if !bc.HasHeader(last.Hash(), last.NumberU64()) {
return 0, fmt.Errorf("containing header #%d [%x..] unknown", last.Number(), last.Hash().Bytes()[:4])
}
// Write all chain data to ancients.
td := bc.GetTd(first.Hash(), first.NumberU64())
writeSize, err := rawdb.WriteAncientBlocks(bc.db, blockChain, receiptChain, td)
size += writeSize
if err != nil {
log.Error("Error importing chain data to ancients", "err", err)
return 0, err
}
// Write tx indices if any condition is satisfied:
// * If user requires to reserve all tx indices(txlookuplimit=0)
// * If all ancient tx indices are required to be reserved(txlookuplimit is even higher than ancientlimit)
// * If block number is large enough to be regarded as a recent block
// It means blocks below the ancientLimit-txlookupLimit won't be indexed.
//
// But if the `TxIndexTail` is not nil, e.g. Geth is initialized with
// an external ancient database, during the setup, blockchain will start
// a background routine to re-indexed all indices in [ancients - txlookupLimit, ancients)
// range. In this case, all tx indices of newly imported blocks should be
// generated.
var batch = bc.db.NewBatch()
for i, block := range blockChain {
if bc.txLookupLimit == 0 || ancientLimit <= bc.txLookupLimit || block.NumberU64() >= ancientLimit-bc.txLookupLimit {
rawdb.WriteTxLookupEntriesByBlock(batch, block)
} else if rawdb.ReadTxIndexTail(bc.db) != nil {
rawdb.WriteTxLookupEntriesByBlock(batch, block)
}
stats.processed++
if batch.ValueSize() > ethdb.IdealBatchSize || i == len(blockChain)-1 {
size += int64(batch.ValueSize())
if err = batch.Write(); err != nil {
fastBlock := bc.CurrentFastBlock().NumberU64()
if err := bc.db.TruncateHead(fastBlock + 1); err != nil {
log.Error("Can't truncate ancient store after failed insert", "err", err)
}
return 0, err
}
batch.Reset()
}
}
// Sync the ancient store explicitly to ensure all data has been flushed to disk.
if err := bc.db.Sync(); err != nil {
return 0, err
}
// Update the current fast block because all block data is now present in DB.
previousFastBlock := bc.CurrentFastBlock().NumberU64()
if !updateHead(blockChain[len(blockChain)-1]) {
// We end up here if the header chain has reorg'ed, and the blocks/receipts
// don't match the canonical chain.
if err := bc.db.TruncateHead(previousFastBlock + 1); err != nil {
log.Error("Can't truncate ancient store after failed insert", "err", err)
}
return 0, errSideChainReceipts
}
// Delete block data from the main database.
batch.Reset()
canonHashes := make(map[common.Hash]struct{})
for _, block := range blockChain {
canonHashes[block.Hash()] = struct{}{}
if block.NumberU64() == 0 {
continue
}
rawdb.DeleteCanonicalHash(batch, block.NumberU64())
rawdb.DeleteBlockWithoutNumber(batch, block.Hash(), block.NumberU64())
}
// Delete side chain hash-to-number mappings.
for _, nh := range rawdb.ReadAllHashesInRange(bc.db, first.NumberU64(), last.NumberU64()) {
if _, canon := canonHashes[nh.Hash]; !canon {
rawdb.DeleteHeader(batch, nh.Hash, nh.Number)
}
}
if err := batch.Write(); err != nil {
return 0, err
}
return 0, nil
}
// writeLive writes blockchain and corresponding receipt chain into active store.
writeLive := func(blockChain types.Blocks, receiptChain []types.Receipts) (int, error) {
skipPresenceCheck := false
batch := bc.db.NewBatch()
for i, block := range blockChain {
// Short circuit insertion if shutting down or processing failed
if bc.insertStopped() {
return 0, errInsertionInterrupted
}
// Short circuit if the owner header is unknown
if !bc.HasHeader(block.Hash(), block.NumberU64()) {
return i, fmt.Errorf("containing header #%d [%x..] unknown", block.Number(), block.Hash().Bytes()[:4])
}
if !skipPresenceCheck {
// Ignore if the entire data is already known
if bc.HasBlock(block.Hash(), block.NumberU64()) {
stats.ignored++
continue
} else {
// If block N is not present, neither are the later blocks.
// This should be true, but if we are mistaken, the shortcut
// here will only cause overwriting of some existing data
skipPresenceCheck = true
}
}
// Write all the data out into the database
rawdb.WriteBody(batch, block.Hash(), block.NumberU64(), block.Body())
rawdb.WriteReceipts(batch, block.Hash(), block.NumberU64(), receiptChain[i])
rawdb.WriteTxLookupEntriesByBlock(batch, block) // Always write tx indices for live blocks, we assume they are needed
// Write everything belongs to the blocks into the database. So that
// we can ensure all components of body is completed(body, receipts,
// tx indexes)
if batch.ValueSize() >= ethdb.IdealBatchSize {
if err := batch.Write(); err != nil {
return 0, err
}
size += int64(batch.ValueSize())
batch.Reset()
}
stats.processed++
}
// Write everything belongs to the blocks into the database. So that
// we can ensure all components of body is completed(body, receipts,
// tx indexes)
if batch.ValueSize() > 0 {
size += int64(batch.ValueSize())
if err := batch.Write(); err != nil {
return 0, err
}
}
updateHead(blockChain[len(blockChain)-1])
return 0, nil
}
// Write downloaded chain data and corresponding receipt chain data
if len(ancientBlocks) > 0 {
if n, err := writeAncient(ancientBlocks, ancientReceipts); err != nil {
if err == errInsertionInterrupted {
return 0, nil
}
return n, err
}
}
// Write the tx index tail (block number from where we index) before write any live blocks
if len(liveBlocks) > 0 && liveBlocks[0].NumberU64() == ancientLimit+1 {
// The tx index tail can only be one of the following two options:
// * 0: all ancient blocks have been indexed
// * ancient-limit: the indices of blocks before ancient-limit are ignored
if tail := rawdb.ReadTxIndexTail(bc.db); tail == nil {
if bc.txLookupLimit == 0 || ancientLimit <= bc.txLookupLimit {
rawdb.WriteTxIndexTail(bc.db, 0)
} else {
rawdb.WriteTxIndexTail(bc.db, ancientLimit-bc.txLookupLimit)
}
}
}
if len(liveBlocks) > 0 {
if n, err := writeLive(liveBlocks, liveReceipts); err != nil {
if err == errInsertionInterrupted {
return 0, nil
}
return n, err
}
}
head := blockChain[len(blockChain)-1]
context := []interface{}{
"count", stats.processed, "elapsed", common.PrettyDuration(time.Since(start)),
"number", head.Number(), "hash", head.Hash(), "age", common.PrettyAge(time.Unix(int64(head.Time()), 0)),
"size", common.StorageSize(size),
}
if stats.ignored > 0 {
context = append(context, []interface{}{"ignored", stats.ignored}...)
}
log.Info("Imported new block receipts", context...)
return 0, nil
}
var lastWrite uint64
// writeBlockWithoutState writes only the block and its metadata to the database,
// but does not write any state. This is used to construct competing side forks
// up to the point where they exceed the canonical total difficulty.
func (bc *BlockChain) writeBlockWithoutState(block *types.Block, td *big.Int) (err error) {
if bc.insertStopped() {
return errInsertionInterrupted
}
batch := bc.db.NewBatch()
rawdb.WriteTd(batch, block.Hash(), block.NumberU64(), td)
rawdb.WriteBlock(batch, block)
if err := batch.Write(); err != nil {
log.Crit("Failed to write block into disk", "err", err)
}
return nil
}
// writeKnownBlock updates the head block flag with a known block
// and introduces chain reorg if necessary.
func (bc *BlockChain) writeKnownBlock(block *types.Block) error {
current := bc.CurrentBlock()
if block.ParentHash() != current.Hash() {
if err := bc.reorg(current, block); err != nil {
return err
}
}
bc.writeHeadBlock(block)
return nil
}
// writeBlockWithState writes block, metadata and corresponding state data to the
// database.
func (bc *BlockChain) writeBlockWithState(block *types.Block, receipts []*types.Receipt, logs []*types.Log, state *state.StateDB) error {
// Calculate the total difficulty of the block
ptd := bc.GetTd(block.ParentHash(), block.NumberU64()-1)
if ptd == nil {
return consensus.ErrUnknownAncestor
}
// Make sure no inconsistent state is leaked during insertion
externTd := new(big.Int).Add(block.Difficulty(), ptd)
// Irrelevant of the canonical status, write the block itself to the database.
//
// Note all the components of block(td, hash->number map, header, body, receipts)
// should be written atomically. BlockBatch is used for containing all components.
blockBatch := bc.db.NewBatch()
rawdb.WriteTd(blockBatch, block.Hash(), block.NumberU64(), externTd)
rawdb.WriteBlock(blockBatch, block)
rawdb.WriteReceipts(blockBatch, block.Hash(), block.NumberU64(), receipts)
rawdb.WritePreimages(blockBatch, state.Preimages())
if err := blockBatch.Write(); err != nil {
log.Crit("Failed to write block into disk", "err", err)
}
// Commit all cached state changes into underlying memory database.
root, err := state.Commit(bc.chainConfig.IsEIP158(block.Number()))
if err != nil {
return err
}
triedb := bc.stateCache.TrieDB()
// If we're running an archive node, always flush
if bc.cacheConfig.TrieDirtyDisabled {
return triedb.Commit(root, false, nil)
} else {
// Full but not archive node, do proper garbage collection
triedb.Reference(root, common.Hash{}) // metadata reference to keep trie alive
bc.triegc.Push(root, -int64(block.NumberU64()))
if current := block.NumberU64(); current > TriesInMemory {
// If we exceeded our memory allowance, flush matured singleton nodes to disk
var (
nodes, imgs = triedb.Size()
limit = common.StorageSize(bc.cacheConfig.TrieDirtyLimit) * 1024 * 1024
)
if nodes > limit || imgs > 4*1024*1024 {
triedb.Cap(limit - ethdb.IdealBatchSize)
}
// Find the next state trie we need to commit
chosen := current - TriesInMemory
// If we exceeded out time allowance, flush an entire trie to disk
if bc.gcproc > bc.cacheConfig.TrieTimeLimit {
// If the header is missing (canonical chain behind), we're reorging a low
// diff sidechain. Suspend committing until this operation is completed.
header := bc.GetHeaderByNumber(chosen)
if header == nil {
log.Warn("Reorg in progress, trie commit postponed", "number", chosen)
} else {
// If we're exceeding limits but haven't reached a large enough memory gap,
// warn the user that the system is becoming unstable.
if chosen < lastWrite+TriesInMemory && bc.gcproc >= 2*bc.cacheConfig.TrieTimeLimit {
log.Info("State in memory for too long, committing", "time", bc.gcproc, "allowance", bc.cacheConfig.TrieTimeLimit, "optimum", float64(chosen-lastWrite)/TriesInMemory)
}
// Flush an entire trie and restart the counters
triedb.Commit(header.Root, true, nil)
lastWrite = chosen
bc.gcproc = 0
}
}
// Garbage collect anything below our required write retention
for !bc.triegc.Empty() {
root, number := bc.triegc.Pop()
if uint64(-number) > chosen {
bc.triegc.Push(root, number)
break
}
triedb.Dereference(root.(common.Hash))
}
}
}
return nil
}
// WriteBlockAndSetHead writes the given block and all associated state to the database,
// and applies the block as the new chain head.
func (bc *BlockChain) WriteBlockAndSetHead(block *types.Block, receipts []*types.Receipt, logs []*types.Log, state *state.StateDB, emitHeadEvent bool) (status WriteStatus, err error) {
if !bc.chainmu.TryLock() {
return NonStatTy, errChainStopped
}
defer bc.chainmu.Unlock()
return bc.writeBlockAndSetHead(block, receipts, logs, state, emitHeadEvent)
}
// writeBlockAndSetHead is the internal implementation of WriteBlockAndSetHead.
// This function expects the chain mutex to be held.
func (bc *BlockChain) writeBlockAndSetHead(block *types.Block, receipts []*types.Receipt, logs []*types.Log, state *state.StateDB, emitHeadEvent bool) (status WriteStatus, err error) {
if err := bc.writeBlockWithState(block, receipts, logs, state); err != nil {
return NonStatTy, err
}
currentBlock := bc.CurrentBlock()
reorg, err := bc.forker.ReorgNeeded(currentBlock.Header(), block.Header())
if err != nil {
return NonStatTy, err
}
if reorg {
// Reorganise the chain if the parent is not the head block
if block.ParentHash() != currentBlock.Hash() {
if err := bc.reorg(currentBlock, block); err != nil {
return NonStatTy, err
}
}
status = CanonStatTy
} else {
status = SideStatTy
}
// Set new head.
if status == CanonStatTy {
bc.writeHeadBlock(block)
}
bc.futureBlocks.Remove(block.Hash())
if status == CanonStatTy {
bc.chainFeed.Send(ChainEvent{Block: block, Hash: block.Hash(), Logs: logs})
if len(logs) > 0 {
bc.logsFeed.Send(logs)
}
// In theory we should fire a ChainHeadEvent when we inject
// a canonical block, but sometimes we can insert a batch of
// canonicial blocks. Avoid firing too many ChainHeadEvents,
// we will fire an accumulated ChainHeadEvent and disable fire
// event here.
if emitHeadEvent {
bc.chainHeadFeed.Send(ChainHeadEvent{Block: block})
}
} else {
bc.chainSideFeed.Send(ChainSideEvent{Block: block})
}
return status, nil
}
// addFutureBlock checks if the block is within the max allowed window to get
// accepted for future processing, and returns an error if the block is too far
// ahead and was not added.
//
// TODO after the transition, the future block shouldn't be kept. Because
// it's not checked in the Geth side anymore.
func (bc *BlockChain) addFutureBlock(block *types.Block) error {
max := uint64(time.Now().Unix() + maxTimeFutureBlocks)
if block.Time() > max {
return fmt.Errorf("future block timestamp %v > allowed %v", block.Time(), max)
}
if block.Difficulty().Cmp(common.Big0) == 0 {
// Never add PoS blocks into the future queue
return nil
}
bc.futureBlocks.Add(block.Hash(), block)
return nil
}
// InsertChain attempts to insert the given batch of blocks in to the canonical
// chain or, otherwise, create a fork. If an error is returned it will return
// the index number of the failing block as well an error describing what went
// wrong. After insertion is done, all accumulated events will be fired.
func (bc *BlockChain) InsertChain(chain types.Blocks) (int, error) {
// Sanity check that we have something meaningful to import
if len(chain) == 0 {
return 0, nil
}
bc.blockProcFeed.Send(true)
defer bc.blockProcFeed.Send(false)
// Do a sanity check that the provided chain is actually ordered and linked.
for i := 1; i < len(chain); i++ {
block, prev := chain[i], chain[i-1]
if block.NumberU64() != prev.NumberU64()+1 || block.ParentHash() != prev.Hash() {
log.Error("Non contiguous block insert",
"number", block.Number(),
"hash", block.Hash(),
"parent", block.ParentHash(),
"prevnumber", prev.Number(),
"prevhash", prev.Hash(),
)
return 0, fmt.Errorf("non contiguous insert: item %d is #%d [%x..], item %d is #%d [%x..] (parent [%x..])", i-1, prev.NumberU64(),
prev.Hash().Bytes()[:4], i, block.NumberU64(), block.Hash().Bytes()[:4], block.ParentHash().Bytes()[:4])
}
}
// Pre-checks passed, start the full block imports
if !bc.chainmu.TryLock() {
return 0, errChainStopped
}
defer bc.chainmu.Unlock()
return bc.insertChain(chain, true, true)
}
// insertChain is the internal implementation of InsertChain, which assumes that
// 1) chains are contiguous, and 2) The chain mutex is held.
//
// This method is split out so that import batches that require re-injecting
// historical blocks can do so without releasing the lock, which could lead to
// racey behaviour. If a sidechain import is in progress, and the historic state
// is imported, but then new canon-head is added before the actual sidechain
// completes, then the historic state could be pruned again
func (bc *BlockChain) insertChain(chain types.Blocks, verifySeals, setHead bool) (int, error) {
// If the chain is terminating, don't even bother starting up.
if bc.insertStopped() {
return 0, nil
}
// Start a parallel signature recovery (signer will fluke on fork transition, minimal perf loss)
senderCacher.recoverFromBlocks(types.MakeSigner(bc.chainConfig, chain[0].Number()), chain)
var (
stats = insertStats{startTime: mclock.Now()}
lastCanon *types.Block
)
// Fire a single chain head event if we've progressed the chain
defer func() {
if lastCanon != nil && bc.CurrentBlock().Hash() == lastCanon.Hash() {
bc.chainHeadFeed.Send(ChainHeadEvent{lastCanon})
}
}()
// Start the parallel header verifier
headers := make([]*types.Header, len(chain))
seals := make([]bool, len(chain))
for i, block := range chain {
headers[i] = block.Header()
seals[i] = verifySeals
}
abort, results := bc.engine.VerifyHeaders(bc, headers, seals)
defer close(abort)
// Peek the error for the first block to decide the directing import logic
it := newInsertIterator(chain, results, bc.validator)
block, err := it.next()
// Left-trim all the known blocks that don't need to build snapshot
if bc.skipBlock(err, it) {
// First block (and state) is known
// 1. We did a roll-back, and should now do a re-import
// 2. The block is stored as a sidechain, and is lying about it's stateroot, and passes a stateroot
// from the canonical chain, which has not been verified.
// Skip all known blocks that are behind us.
var (
reorg bool
current = bc.CurrentBlock()
)
for block != nil && bc.skipBlock(err, it) {
reorg, err = bc.forker.ReorgNeeded(current.Header(), block.Header())
if err != nil {
return it.index, err
}
if reorg {
// Switch to import mode if the forker says the reorg is necessary
// and also the block is not on the canonical chain.
// In eth2 the forker always returns true for reorg decision (blindly trusting
// the external consensus engine), but in order to prevent the unnecessary
// reorgs when importing known blocks, the special case is handled here.
if block.NumberU64() > current.NumberU64() || bc.GetCanonicalHash(block.NumberU64()) != block.Hash() {
break
}
}
log.Debug("Ignoring already known block", "number", block.Number(), "hash", block.Hash())
stats.ignored++
block, err = it.next()
}
// The remaining blocks are still known blocks, the only scenario here is:
// During the fast sync, the pivot point is already submitted but rollback
// happens. Then node resets the head full block to a lower height via `rollback`
// and leaves a few known blocks in the database.
//
// When node runs a fast sync again, it can re-import a batch of known blocks via
// `insertChain` while a part of them have higher total difficulty than current
// head full block(new pivot point).
for block != nil && bc.skipBlock(err, it) {
log.Debug("Writing previously known block", "number", block.Number(), "hash", block.Hash())
if err := bc.writeKnownBlock(block); err != nil {
return it.index, err
}
lastCanon = block
block, err = it.next()
}
// Falls through to the block import
}
switch {
// First block is pruned
case errors.Is(err, consensus.ErrPrunedAncestor):
if setHead {
// First block is pruned, insert as sidechain and reorg only if TD grows enough
log.Debug("Pruned ancestor, inserting as sidechain", "number", block.Number(), "hash", block.Hash())
return bc.insertSideChain(block, it)
} else {
// We're post-merge and the parent is pruned, try to recover the parent state
log.Debug("Pruned ancestor", "number", block.Number(), "hash", block.Hash())
_, err := bc.recoverAncestors(block)
return it.index, err
}
// First block is future, shove it (and all children) to the future queue (unknown ancestor)
case errors.Is(err, consensus.ErrFutureBlock) || (errors.Is(err, consensus.ErrUnknownAncestor) && bc.futureBlocks.Contains(it.first().ParentHash())):
for block != nil && (it.index == 0 || errors.Is(err, consensus.ErrUnknownAncestor)) {
log.Debug("Future block, postponing import", "number", block.Number(), "hash", block.Hash())
if err := bc.addFutureBlock(block); err != nil {
return it.index, err
}
block, err = it.next()
}
stats.queued += it.processed()
stats.ignored += it.remaining()
// If there are any still remaining, mark as ignored
return it.index, err
// Some other error(except ErrKnownBlock) occurred, abort.
// ErrKnownBlock is allowed here since some known blocks
// still need re-execution to generate snapshots that are missing
case err != nil && !errors.Is(err, ErrKnownBlock):
bc.futureBlocks.Remove(block.Hash())
stats.ignored += len(it.chain)
bc.reportBlock(block, nil, err)
return it.index, err
}
// No validation errors for the first block (or chain prefix skipped)
var activeState *state.StateDB
defer func() {
// The chain importer is starting and stopping trie prefetchers. If a bad
// block or other error is hit however, an early return may not properly
// terminate the background threads. This defer ensures that we clean up
// and dangling prefetcher, without defering each and holding on live refs.
if activeState != nil {
activeState.StopPrefetcher()
}
}()
for ; block != nil && err == nil || errors.Is(err, ErrKnownBlock); block, err = it.next() {
// If the chain is terminating, stop processing blocks
if bc.insertStopped() {
log.Debug("Abort during block processing")
break
}
// If the header is a banned one, straight out abort
if BadHashes[block.Hash()] {
bc.reportBlock(block, nil, ErrBannedHash)
return it.index, ErrBannedHash
}
// If the block is known (in the middle of the chain), it's a special case for
// Clique blocks where they can share state among each other, so importing an
// older block might complete the state of the subsequent one. In this case,
// just skip the block (we already validated it once fully (and crashed), since
// its header and body was already in the database). But if the corresponding
// snapshot layer is missing, forcibly rerun the execution to build it.
if bc.skipBlock(err, it) {
logger := log.Debug
if bc.chainConfig.Clique == nil {
logger = log.Warn
}
logger("Inserted known block", "number", block.Number(), "hash", block.Hash(),
"uncles", len(block.Uncles()), "txs", len(block.Transactions()), "gas", block.GasUsed(),
"root", block.Root())
// Special case. Commit the empty receipt slice if we meet the known
// block in the middle. It can only happen in the clique chain. Whenever
// we insert blocks via `insertSideChain`, we only commit `td`, `header`
// and `body` if it's non-existent. Since we don't have receipts without
// reexecution, so nothing to commit. But if the sidechain will be adpoted
// as the canonical chain eventually, it needs to be reexecuted for missing
// state, but if it's this special case here(skip reexecution) we will lose
// the empty receipt entry.
if len(block.Transactions()) == 0 {
rawdb.WriteReceipts(bc.db, block.Hash(), block.NumberU64(), nil)
} else {
log.Error("Please file an issue, skip known block execution without receipt",
"hash", block.Hash(), "number", block.NumberU64())
}
if err := bc.writeKnownBlock(block); err != nil {
return it.index, err
}
stats.processed++
// We can assume that logs are empty here, since the only way for consecutive
// Clique blocks to have the same state is if there are no transactions.
lastCanon = block
continue
}
// Retrieve the parent block and it's state to execute on top
start := time.Now()
parent := it.previous()
if parent == nil {
parent = bc.GetHeader(block.ParentHash(), block.NumberU64()-1)
}
statedb, err := state.New(parent.Root, bc.stateCache, bc.snaps)
if err != nil {
return it.index, err
}
// Enable prefetching to pull in trie node paths while processing transactions
statedb.StartPrefetcher("chain")
activeState = statedb
// If we have a followup block, run that against the current state to pre-cache
// transactions and probabilistically some of the account/storage trie nodes.
var followupInterrupt uint32
if !bc.cacheConfig.TrieCleanNoPrefetch {
if followup, err := it.peek(); followup != nil && err == nil {
throwaway, _ := state.New(parent.Root, bc.stateCache, bc.snaps)
go func(start time.Time, followup *types.Block, throwaway *state.StateDB, interrupt *uint32) {
bc.prefetcher.Prefetch(followup, throwaway, bc.vmConfig, &followupInterrupt)
blockPrefetchExecuteTimer.Update(time.Since(start))
if atomic.LoadUint32(interrupt) == 1 {
blockPrefetchInterruptMeter.Mark(1)
}
}(time.Now(), followup, throwaway, &followupInterrupt)
}
}
// Process block using the parent state as reference point
substart := time.Now()
receipts, logs, usedGas, err := bc.processor.Process(block, statedb, bc.vmConfig)
if err != nil {
bc.reportBlock(block, receipts, err)
atomic.StoreUint32(&followupInterrupt, 1)
return it.index, err
}
// Update the metrics touched during block processing
accountReadTimer.Update(statedb.AccountReads) // Account reads are complete, we can mark them
storageReadTimer.Update(statedb.StorageReads) // Storage reads are complete, we can mark them
accountUpdateTimer.Update(statedb.AccountUpdates) // Account updates are complete, we can mark them
storageUpdateTimer.Update(statedb.StorageUpdates) // Storage updates are complete, we can mark them
snapshotAccountReadTimer.Update(statedb.SnapshotAccountReads) // Account reads are complete, we can mark them
snapshotStorageReadTimer.Update(statedb.SnapshotStorageReads) // Storage reads are complete, we can mark them
triehash := statedb.AccountHashes + statedb.StorageHashes // Save to not double count in validation
trieproc := statedb.SnapshotAccountReads + statedb.AccountReads + statedb.AccountUpdates
trieproc += statedb.SnapshotStorageReads + statedb.StorageReads + statedb.StorageUpdates
blockExecutionTimer.Update(time.Since(substart) - trieproc - triehash)
// Validate the state using the default validator
substart = time.Now()
if err := bc.validator.ValidateState(block, statedb, receipts, usedGas); err != nil {
bc.reportBlock(block, receipts, err)
atomic.StoreUint32(&followupInterrupt, 1)
return it.index, err
}
proctime := time.Since(start)
// Update the metrics touched during block validation
accountHashTimer.Update(statedb.AccountHashes) // Account hashes are complete, we can mark them
storageHashTimer.Update(statedb.StorageHashes) // Storage hashes are complete, we can mark them
blockValidationTimer.Update(time.Since(substart) - (statedb.AccountHashes + statedb.StorageHashes - triehash))
// Write the block to the chain and get the status.
substart = time.Now()
var status WriteStatus
if !setHead {
// Don't set the head, only insert the block
err = bc.writeBlockWithState(block, receipts, logs, statedb)
} else {
status, err = bc.writeBlockAndSetHead(block, receipts, logs, statedb, false)
}
atomic.StoreUint32(&followupInterrupt, 1)
if err != nil {
return it.index, err
}
// Update the metrics touched during block commit
accountCommitTimer.Update(statedb.AccountCommits) // Account commits are complete, we can mark them
storageCommitTimer.Update(statedb.StorageCommits) // Storage commits are complete, we can mark them
snapshotCommitTimer.Update(statedb.SnapshotCommits) // Snapshot commits are complete, we can mark them
blockWriteTimer.Update(time.Since(substart) - statedb.AccountCommits - statedb.StorageCommits - statedb.SnapshotCommits)
blockInsertTimer.UpdateSince(start)
// Report the import stats before returning the various results
stats.processed++
stats.usedGas += usedGas
dirty, _ := bc.stateCache.TrieDB().Size()
stats.report(chain, it.index, dirty, setHead)
if !setHead {
return it.index, nil // Direct block insertion of a single block
}
switch status {
case CanonStatTy:
log.Debug("Inserted new block", "number", block.Number(), "hash", block.Hash(),
"uncles", len(block.Uncles()), "txs", len(block.Transactions()), "gas", block.GasUsed(),
"elapsed", common.PrettyDuration(time.Since(start)),
"root", block.Root())
lastCanon = block
// Only count canonical blocks for GC processing time
bc.gcproc += proctime
case SideStatTy:
log.Debug("Inserted forked block", "number", block.Number(), "hash", block.Hash(),
"diff", block.Difficulty(), "elapsed", common.PrettyDuration(time.Since(start)),
"txs", len(block.Transactions()), "gas", block.GasUsed(), "uncles", len(block.Uncles()),
"root", block.Root())
default:
// This in theory is impossible, but lets be nice to our future selves and leave
// a log, instead of trying to track down blocks imports that don't emit logs.
log.Warn("Inserted block with unknown status", "number", block.Number(), "hash", block.Hash(),
"diff", block.Difficulty(), "elapsed", common.PrettyDuration(time.Since(start)),
"txs", len(block.Transactions()), "gas", block.GasUsed(), "uncles", len(block.Uncles()),
"root", block.Root())
}
}
// Any blocks remaining here? The only ones we care about are the future ones
if block != nil && errors.Is(err, consensus.ErrFutureBlock) {
if err := bc.addFutureBlock(block); err != nil {
return it.index, err
}
block, err = it.next()
for ; block != nil && errors.Is(err, consensus.ErrUnknownAncestor); block, err = it.next() {
if err := bc.addFutureBlock(block); err != nil {
return it.index, err
}
stats.queued++
}
}
stats.ignored += it.remaining()
return it.index, err
}
// insertSideChain is called when an import batch hits upon a pruned ancestor
// error, which happens when a sidechain with a sufficiently old fork-block is
// found.
//
// The method writes all (header-and-body-valid) blocks to disk, then tries to
// switch over to the new chain if the TD exceeded the current chain.
// insertSideChain is only used pre-merge.
func (bc *BlockChain) insertSideChain(block *types.Block, it *insertIterator) (int, error) {
var (
externTd *big.Int
lastBlock = block
current = bc.CurrentBlock()
)
// The first sidechain block error is already verified to be ErrPrunedAncestor.
// Since we don't import them here, we expect ErrUnknownAncestor for the remaining
// ones. Any other errors means that the block is invalid, and should not be written
// to disk.
err := consensus.ErrPrunedAncestor
for ; block != nil && errors.Is(err, consensus.ErrPrunedAncestor); block, err = it.next() {
// Check the canonical state root for that number
if number := block.NumberU64(); current.NumberU64() >= number {
canonical := bc.GetBlockByNumber(number)
if canonical != nil && canonical.Hash() == block.Hash() {
// Not a sidechain block, this is a re-import of a canon block which has it's state pruned
// Collect the TD of the block. Since we know it's a canon one,
// we can get it directly, and not (like further below) use
// the parent and then add the block on top
externTd = bc.GetTd(block.Hash(), block.NumberU64())
continue
}
if canonical != nil && canonical.Root() == block.Root() {
// This is most likely a shadow-state attack. When a fork is imported into the
// database, and it eventually reaches a block height which is not pruned, we
// just found that the state already exist! This means that the sidechain block
// refers to a state which already exists in our canon chain.
//
// If left unchecked, we would now proceed importing the blocks, without actually
// having verified the state of the previous blocks.
log.Warn("Sidechain ghost-state attack detected", "number", block.NumberU64(), "sideroot", block.Root(), "canonroot", canonical.Root())
// If someone legitimately side-mines blocks, they would still be imported as usual. However,
// we cannot risk writing unverified blocks to disk when they obviously target the pruning
// mechanism.
return it.index, errors.New("sidechain ghost-state attack")
}
}
if externTd == nil {
externTd = bc.GetTd(block.ParentHash(), block.NumberU64()-1)
}
externTd = new(big.Int).Add(externTd, block.Difficulty())
if !bc.HasBlock(block.Hash(), block.NumberU64()) {
start := time.Now()
if err := bc.writeBlockWithoutState(block, externTd); err != nil {
return it.index, err
}
log.Debug("Injected sidechain block", "number", block.Number(), "hash", block.Hash(),
"diff", block.Difficulty(), "elapsed", common.PrettyDuration(time.Since(start)),
"txs", len(block.Transactions()), "gas", block.GasUsed(), "uncles", len(block.Uncles()),
"root", block.Root())
}
lastBlock = block
}
// At this point, we've written all sidechain blocks to database. Loop ended
// either on some other error or all were processed. If there was some other
// error, we can ignore the rest of those blocks.
//
// If the externTd was larger than our local TD, we now need to reimport the previous
// blocks to regenerate the required state
reorg, err := bc.forker.ReorgNeeded(current.Header(), lastBlock.Header())
if err != nil {
return it.index, err
}
if !reorg {
localTd := bc.GetTd(current.Hash(), current.NumberU64())
log.Info("Sidechain written to disk", "start", it.first().NumberU64(), "end", it.previous().Number, "sidetd", externTd, "localtd", localTd)
return it.index, err
}
// Gather all the sidechain hashes (full blocks may be memory heavy)
var (
hashes []common.Hash
numbers []uint64
)
parent := it.previous()
for parent != nil && !bc.HasState(parent.Root) {
hashes = append(hashes, parent.Hash())
numbers = append(numbers, parent.Number.Uint64())
parent = bc.GetHeader(parent.ParentHash, parent.Number.Uint64()-1)
}
if parent == nil {
return it.index, errors.New("missing parent")
}
// Import all the pruned blocks to make the state available
var (
blocks []*types.Block
memory common.StorageSize
)
for i := len(hashes) - 1; i >= 0; i-- {
// Append the next block to our batch
block := bc.GetBlock(hashes[i], numbers[i])
blocks = append(blocks, block)
memory += block.Size()
// If memory use grew too large, import and continue. Sadly we need to discard
// all raised events and logs from notifications since we're too heavy on the
// memory here.
if len(blocks) >= 2048 || memory > 64*1024*1024 {
log.Info("Importing heavy sidechain segment", "blocks", len(blocks), "start", blocks[0].NumberU64(), "end", block.NumberU64())
if _, err := bc.insertChain(blocks, false, true); err != nil {
return 0, err
}
blocks, memory = blocks[:0], 0
// If the chain is terminating, stop processing blocks
if bc.insertStopped() {
log.Debug("Abort during blocks processing")
return 0, nil
}
}
}
if len(blocks) > 0 {
log.Info("Importing sidechain segment", "start", blocks[0].NumberU64(), "end", blocks[len(blocks)-1].NumberU64())
return bc.insertChain(blocks, false, true)
}
return 0, nil
}
// recoverAncestors finds the closest ancestor with available state and re-execute
// all the ancestor blocks since that.
// recoverAncestors is only used post-merge.
// We return the hash of the latest block that we could correctly validate.
func (bc *BlockChain) recoverAncestors(block *types.Block) (common.Hash, error) {
// Gather all the sidechain hashes (full blocks may be memory heavy)
var (
hashes []common.Hash
numbers []uint64
parent = block
)
for parent != nil && !bc.HasState(parent.Root()) {
hashes = append(hashes, parent.Hash())
numbers = append(numbers, parent.NumberU64())
parent = bc.GetBlock(parent.ParentHash(), parent.NumberU64()-1)
// If the chain is terminating, stop iteration
if bc.insertStopped() {
log.Debug("Abort during blocks iteration")
return common.Hash{}, errInsertionInterrupted
}
}
if parent == nil {
return common.Hash{}, errors.New("missing parent")
}
// Import all the pruned blocks to make the state available
for i := len(hashes) - 1; i >= 0; i-- {
// If the chain is terminating, stop processing blocks
if bc.insertStopped() {
log.Debug("Abort during blocks processing")
return common.Hash{}, errInsertionInterrupted
}
var b *types.Block
if i == 0 {
b = block
} else {
b = bc.GetBlock(hashes[i], numbers[i])
}
if _, err := bc.insertChain(types.Blocks{b}, false, false); err != nil {
return b.ParentHash(), err
}
}
return block.Hash(), nil
}
// collectLogs collects the logs that were generated or removed during
// the processing of the block that corresponds with the given hash.
// These logs are later announced as deleted or reborn.
func (bc *BlockChain) collectLogs(hash common.Hash, removed bool) []*types.Log {
number := bc.hc.GetBlockNumber(hash)
if number == nil {
return nil
}
receipts := rawdb.ReadReceipts(bc.db, hash, *number, bc.chainConfig)
var logs []*types.Log
for _, receipt := range receipts {
for _, log := range receipt.Logs {
l := *log
if removed {
l.Removed = true
}
logs = append(logs, &l)
}
}
return logs
}
// mergeLogs returns a merged log slice with specified sort order.
func mergeLogs(logs [][]*types.Log, reverse bool) []*types.Log {
var ret []*types.Log
if reverse {
for i := len(logs) - 1; i >= 0; i-- {
ret = append(ret, logs[i]...)
}
} else {
for i := 0; i < len(logs); i++ {
ret = append(ret, logs[i]...)
}
}
return ret
}
// reorg takes two blocks, an old chain and a new chain and will reconstruct the
// blocks and inserts them to be part of the new canonical chain and accumulates
// potential missing transactions and post an event about them.
// Note the new head block won't be processed here, callers need to handle it
// externally.
func (bc *BlockChain) reorg(oldBlock, newBlock *types.Block) error {
var (
newChain types.Blocks
oldChain types.Blocks
commonBlock *types.Block
deletedTxs []common.Hash
addedTxs []common.Hash
deletedLogs [][]*types.Log
rebirthLogs [][]*types.Log
)
// Reduce the longer chain to the same number as the shorter one
if oldBlock.NumberU64() > newBlock.NumberU64() {
// Old chain is longer, gather all transactions and logs as deleted ones
for ; oldBlock != nil && oldBlock.NumberU64() != newBlock.NumberU64(); oldBlock = bc.GetBlock(oldBlock.ParentHash(), oldBlock.NumberU64()-1) {
oldChain = append(oldChain, oldBlock)
for _, tx := range oldBlock.Transactions() {
deletedTxs = append(deletedTxs, tx.Hash())
}
// Collect deleted logs for notification
logs := bc.collectLogs(oldBlock.Hash(), true)
if len(logs) > 0 {
deletedLogs = append(deletedLogs, logs)
}
}
} else {
// New chain is longer, stash all blocks away for subsequent insertion
for ; newBlock != nil && newBlock.NumberU64() != oldBlock.NumberU64(); newBlock = bc.GetBlock(newBlock.ParentHash(), newBlock.NumberU64()-1) {
newChain = append(newChain, newBlock)
}
}
if oldBlock == nil {
return fmt.Errorf("invalid old chain")
}
if newBlock == nil {
return fmt.Errorf("invalid new chain")
}
// Both sides of the reorg are at the same number, reduce both until the common
// ancestor is found
for {
// If the common ancestor was found, bail out
if oldBlock.Hash() == newBlock.Hash() {
commonBlock = oldBlock
break
}
// Remove an old block as well as stash away a new block
oldChain = append(oldChain, oldBlock)
for _, tx := range oldBlock.Transactions() {
deletedTxs = append(deletedTxs, tx.Hash())
}
// Collect deleted logs for notification
logs := bc.collectLogs(oldBlock.Hash(), true)
if len(logs) > 0 {
deletedLogs = append(deletedLogs, logs)
}
newChain = append(newChain, newBlock)
// Step back with both chains
oldBlock = bc.GetBlock(oldBlock.ParentHash(), oldBlock.NumberU64()-1)
if oldBlock == nil {
return fmt.Errorf("invalid old chain")
}
newBlock = bc.GetBlock(newBlock.ParentHash(), newBlock.NumberU64()-1)
if newBlock == nil {
return fmt.Errorf("invalid new chain")
}
}
// Ensure the user sees large reorgs
if len(oldChain) > 0 && len(newChain) > 0 {
logFn := log.Info
msg := "Chain reorg detected"
if len(oldChain) > 63 {
msg = "Large chain reorg detected"
logFn = log.Warn
}
logFn(msg, "number", commonBlock.Number(), "hash", commonBlock.Hash(),
"drop", len(oldChain), "dropfrom", oldChain[0].Hash(), "add", len(newChain), "addfrom", newChain[0].Hash())
blockReorgAddMeter.Mark(int64(len(newChain)))
blockReorgDropMeter.Mark(int64(len(oldChain)))
blockReorgMeter.Mark(1)
} else if len(newChain) > 0 {
// Special case happens in the post merge stage that current head is
// the ancestor of new head while these two blocks are not consecutive
log.Info("Extend chain", "add", len(newChain), "number", newChain[0].Number(), "hash", newChain[0].Hash())
blockReorgAddMeter.Mark(int64(len(newChain)))
} else {
// len(newChain) == 0 && len(oldChain) > 0
// rewind the canonical chain to a lower point.
log.Error("Impossible reorg, please file an issue", "oldnum", oldBlock.Number(), "oldhash", oldBlock.Hash(), "oldblocks", len(oldChain), "newnum", newBlock.Number(), "newhash", newBlock.Hash(), "newblocks", len(newChain))
}
// Insert the new chain(except the head block(reverse order)),
// taking care of the proper incremental order.
for i := len(newChain) - 1; i >= 1; i-- {
// Insert the block in the canonical way, re-writing history
bc.writeHeadBlock(newChain[i])
// Collect the new added transactions.
for _, tx := range newChain[i].Transactions() {
addedTxs = append(addedTxs, tx.Hash())
}
}
// Delete useless indexes right now which includes the non-canonical
// transaction indexes, canonical chain indexes which above the head.
indexesBatch := bc.db.NewBatch()
for _, tx := range types.HashDifference(deletedTxs, addedTxs) {
rawdb.DeleteTxLookupEntry(indexesBatch, tx)
}
// Delete all hash markers that are not part of the new canonical chain.
// Because the reorg function does not handle new chain head, all hash
// markers greater than or equal to new chain head should be deleted.
number := commonBlock.NumberU64()
if len(newChain) > 1 {
number = newChain[1].NumberU64()
}
for i := number + 1; ; i++ {
hash := rawdb.ReadCanonicalHash(bc.db, i)
if hash == (common.Hash{}) {
break
}
rawdb.DeleteCanonicalHash(indexesBatch, i)
}
if err := indexesBatch.Write(); err != nil {
log.Crit("Failed to delete useless indexes", "err", err)
}
// Collect the logs
for i := len(newChain) - 1; i >= 1; i-- {
// Collect reborn logs due to chain reorg
logs := bc.collectLogs(newChain[i].Hash(), false)
if len(logs) > 0 {
rebirthLogs = append(rebirthLogs, logs)
}
}
// If any logs need to be fired, do it now. In theory we could avoid creating
// this goroutine if there are no events to fire, but realistcally that only
// ever happens if we're reorging empty blocks, which will only happen on idle
// networks where performance is not an issue either way.
if len(deletedLogs) > 0 {
bc.rmLogsFeed.Send(RemovedLogsEvent{mergeLogs(deletedLogs, true)})
}
if len(rebirthLogs) > 0 {
bc.logsFeed.Send(mergeLogs(rebirthLogs, false))
}
if len(oldChain) > 0 {
for i := len(oldChain) - 1; i >= 0; i-- {
bc.chainSideFeed.Send(ChainSideEvent{Block: oldChain[i]})
}
}
return nil
}
// InsertBlockWithoutSetHead executes the block, runs the necessary verification
// upon it and then persist the block and the associate state into the database.
// The key difference between the InsertChain is it won't do the canonical chain
// updating. It relies on the additional SetCanonical call to finalize the entire
// procedure.
func (bc *BlockChain) InsertBlockWithoutSetHead(block *types.Block) error {
if !bc.chainmu.TryLock() {
return errChainStopped
}
defer bc.chainmu.Unlock()
_, err := bc.insertChain(types.Blocks{block}, true, false)
return err
}
// SetCanonical rewinds the chain to set the new head block as the specified
// block. It's possible that the state of the new head is missing, and it will
// be recovered in this function as well.
func (bc *BlockChain) SetCanonical(head *types.Block) (common.Hash, error) {
if !bc.chainmu.TryLock() {
return common.Hash{}, errChainStopped
}
defer bc.chainmu.Unlock()
// Re-execute the reorged chain in case the head state is missing.
if !bc.HasState(head.Root()) {
if latestValidHash, err := bc.recoverAncestors(head); err != nil {
return latestValidHash, err
}
log.Info("Recovered head state", "number", head.Number(), "hash", head.Hash())
}
// Run the reorg if necessary and set the given block as new head.
start := time.Now()
if head.ParentHash() != bc.CurrentBlock().Hash() {
if err := bc.reorg(bc.CurrentBlock(), head); err != nil {
return common.Hash{}, err
}
}
bc.writeHeadBlock(head)
// Emit events
logs := bc.collectLogs(head.Hash(), false)
bc.chainFeed.Send(ChainEvent{Block: head, Hash: head.Hash(), Logs: logs})
if len(logs) > 0 {
bc.logsFeed.Send(logs)
}
bc.chainHeadFeed.Send(ChainHeadEvent{Block: head})
context := []interface{}{
"number", head.Number(),
"hash", head.Hash(),
"root", head.Root(),
"elapsed", time.Since(start),
}
if timestamp := time.Unix(int64(head.Time()), 0); time.Since(timestamp) > time.Minute {
context = append(context, []interface{}{"age", common.PrettyAge(timestamp)}...)
}
log.Info("Chain head was updated", context...)
return head.Hash(), nil
}
func (bc *BlockChain) updateFutureBlocks() {
futureTimer := time.NewTicker(5 * time.Second)
defer futureTimer.Stop()
defer bc.wg.Done()
for {
select {
case <-futureTimer.C:
bc.procFutureBlocks()
case <-bc.quit:
return
}
}
}
// skipBlock returns 'true', if the block being imported can be skipped over, meaning
// that the block does not need to be processed but can be considered already fully 'done'.
func (bc *BlockChain) skipBlock(err error, it *insertIterator) bool {
// We can only ever bypass processing if the only error returned by the validator
// is ErrKnownBlock, which means all checks passed, but we already have the block
// and state.
if !errors.Is(err, ErrKnownBlock) {
return false
}
// If we're not using snapshots, we can skip this, since we have both block
// and (trie-) state
if bc.snaps == nil {
return true
}
var (
header = it.current() // header can't be nil
parentRoot common.Hash
)
// If we also have the snapshot-state, we can skip the processing.
if bc.snaps.Snapshot(header.Root) != nil {
return true
}
// In this case, we have the trie-state but not snapshot-state. If the parent
// snapshot-state exists, we need to process this in order to not get a gap
// in the snapshot layers.
// Resolve parent block
if parent := it.previous(); parent != nil {
parentRoot = parent.Root
} else if parent = bc.GetHeaderByHash(header.ParentHash); parent != nil {
parentRoot = parent.Root
}
if parentRoot == (common.Hash{}) {
return false // Theoretically impossible case
}
// Parent is also missing snapshot: we can skip this. Otherwise process.
if bc.snaps.Snapshot(parentRoot) == nil {
return true
}
return false
}
// maintainTxIndex is responsible for the construction and deletion of the
// transaction index.
//
// User can use flag `txlookuplimit` to specify a "recentness" block, below
// which ancient tx indices get deleted. If `txlookuplimit` is 0, it means
// all tx indices will be reserved.
//
// The user can adjust the txlookuplimit value for each launch after fast
// sync, Geth will automatically construct the missing indices and delete
// the extra indices.
func (bc *BlockChain) maintainTxIndex(ancients uint64) {
defer bc.wg.Done()
// Before starting the actual maintenance, we need to handle a special case,
// where user might init Geth with an external ancient database. If so, we
// need to reindex all necessary transactions before starting to process any
// pruning requests.
if ancients > 0 {
var from = uint64(0)
if bc.txLookupLimit != 0 && ancients > bc.txLookupLimit {
from = ancients - bc.txLookupLimit
}
rawdb.IndexTransactions(bc.db, from, ancients, bc.quit)
}
// indexBlocks reindexes or unindexes transactions depending on user configuration
indexBlocks := func(tail *uint64, head uint64, done chan struct{}) {
defer func() { done <- struct{}{} }()
// If the user just upgraded Geth to a new version which supports transaction
// index pruning, write the new tail and remove anything older.
if tail == nil {
if bc.txLookupLimit == 0 || head < bc.txLookupLimit {
// Nothing to delete, write the tail and return
rawdb.WriteTxIndexTail(bc.db, 0)
} else {
// Prune all stale tx indices and record the tx index tail
rawdb.UnindexTransactions(bc.db, 0, head-bc.txLookupLimit+1, bc.quit)
}
return
}
// If a previous indexing existed, make sure that we fill in any missing entries
if bc.txLookupLimit == 0 || head < bc.txLookupLimit {
if *tail > 0 {
// It can happen when chain is rewound to a historical point which
// is even lower than the indexes tail, recap the indexing target
// to new head to avoid reading non-existent block bodies.
end := *tail
if end > head+1 {
end = head + 1
}
rawdb.IndexTransactions(bc.db, 0, end, bc.quit)
}
return
}
// Update the transaction index to the new chain state
if head-bc.txLookupLimit+1 < *tail {
// Reindex a part of missing indices and rewind index tail to HEAD-limit
rawdb.IndexTransactions(bc.db, head-bc.txLookupLimit+1, *tail, bc.quit)
} else {
// Unindex a part of stale indices and forward index tail to HEAD-limit
rawdb.UnindexTransactions(bc.db, *tail, head-bc.txLookupLimit+1, bc.quit)
}
}
// Any reindexing done, start listening to chain events and moving the index window
var (
done chan struct{} // Non-nil if background unindexing or reindexing routine is active.
headCh = make(chan ChainHeadEvent, 1) // Buffered to avoid locking up the event feed
)
sub := bc.SubscribeChainHeadEvent(headCh)
if sub == nil {
return
}
defer sub.Unsubscribe()
for {
select {
case head := <-headCh:
if done == nil {
done = make(chan struct{})
go indexBlocks(rawdb.ReadTxIndexTail(bc.db), head.Block.NumberU64(), done)
}
case <-done:
done = nil
case <-bc.quit:
if done != nil {
log.Info("Waiting background transaction indexer to exit")
<-done
}
return
}
}
}
// reportBlock logs a bad block error.
func (bc *BlockChain) reportBlock(block *types.Block, receipts types.Receipts, err error) {
rawdb.WriteBadBlock(bc.db, block)
var receiptString string
for i, receipt := range receipts {
receiptString += fmt.Sprintf("\t %d: cumulative: %v gas: %v contract: %v status: %v tx: %v logs: %v bloom: %x state: %x\n",
i, receipt.CumulativeGasUsed, receipt.GasUsed, receipt.ContractAddress.Hex(),
receipt.Status, receipt.TxHash.Hex(), receipt.Logs, receipt.Bloom, receipt.PostState)
}
log.Error(fmt.Sprintf(`
########## BAD BLOCK #########
Chain config: %v
Number: %v
Hash: %#x
%v
Error: %v
##############################
`, bc.chainConfig, block.Number(), block.Hash(), receiptString, err))
}
// InsertHeaderChain attempts to insert the given header chain in to the local
// chain, possibly creating a reorg. If an error is returned, it will return the
// index number of the failing header as well an error describing what went wrong.
//
// The verify parameter can be used to fine tune whether nonce verification
// should be done or not. The reason behind the optional check is because some
// of the header retrieval mechanisms already need to verify nonces, as well as
// because nonces can be verified sparsely, not needing to check each.
func (bc *BlockChain) InsertHeaderChain(chain []*types.Header, checkFreq int) (int, error) {
if len(chain) == 0 {
return 0, nil
}
start := time.Now()
if i, err := bc.hc.ValidateHeaderChain(chain, checkFreq); err != nil {
return i, err
}
if !bc.chainmu.TryLock() {
return 0, errChainStopped
}
defer bc.chainmu.Unlock()
_, err := bc.hc.InsertHeaderChain(chain, start, bc.forker)
return 0, err
}
// SetBlockValidatorAndProcessorForTesting sets the current validator and processor.
// This method can be used to force an invalid blockchain to be verified for tests.
// This method is unsafe and should only be used before block import starts.
func (bc *BlockChain) SetBlockValidatorAndProcessorForTesting(v Validator, p Processor) {
bc.validator = v
bc.processor = p
}
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