plugeth/core/state/snapshot/difflayer.go
2024-02-05 22:16:32 +01:00

544 lines
20 KiB
Go

// Copyright 2019 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 snapshot
import (
"encoding/binary"
"fmt"
"math"
"math/rand"
"sync"
"sync/atomic"
"time"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/rlp"
bloomfilter "github.com/holiman/bloomfilter/v2"
"golang.org/x/exp/slices"
)
var (
// aggregatorMemoryLimit is the maximum size of the bottom-most diff layer
// that aggregates the writes from above until it's flushed into the disk
// layer.
//
// Note, bumping this up might drastically increase the size of the bloom
// filters that's stored in every diff layer. Don't do that without fully
// understanding all the implications.
aggregatorMemoryLimit = uint64(4 * 1024 * 1024)
// aggregatorItemLimit is an approximate number of items that will end up
// in the aggregator layer before it's flushed out to disk. A plain account
// weighs around 14B (+hash), a storage slot 32B (+hash), a deleted slot
// 0B (+hash). Slots are mostly set/unset in lockstep, so that average at
// 16B (+hash). All in all, the average entry seems to be 15+32=47B. Use a
// smaller number to be on the safe side.
aggregatorItemLimit = aggregatorMemoryLimit / 42
// bloomTargetError is the target false positive rate when the aggregator
// layer is at its fullest. The actual value will probably move around up
// and down from this number, it's mostly a ballpark figure.
//
// Note, dropping this down might drastically increase the size of the bloom
// filters that's stored in every diff layer. Don't do that without fully
// understanding all the implications.
bloomTargetError = 0.02
// bloomSize is the ideal bloom filter size given the maximum number of items
// it's expected to hold and the target false positive error rate.
bloomSize = math.Ceil(float64(aggregatorItemLimit) * math.Log(bloomTargetError) / math.Log(1/math.Pow(2, math.Log(2))))
// bloomFuncs is the ideal number of bits a single entry should set in the
// bloom filter to keep its size to a minimum (given it's size and maximum
// entry count).
bloomFuncs = math.Round((bloomSize / float64(aggregatorItemLimit)) * math.Log(2))
// the bloom offsets are runtime constants which determines which part of the
// account/storage hash the hasher functions looks at, to determine the
// bloom key for an account/slot. This is randomized at init(), so that the
// global population of nodes do not all display the exact same behaviour with
// regards to bloom content
bloomDestructHasherOffset = 0
bloomAccountHasherOffset = 0
bloomStorageHasherOffset = 0
)
func init() {
// Init the bloom offsets in the range [0:24] (requires 8 bytes)
bloomDestructHasherOffset = rand.Intn(25)
bloomAccountHasherOffset = rand.Intn(25)
bloomStorageHasherOffset = rand.Intn(25)
// The destruct and account blooms must be different, as the storage slots
// will check for destruction too for every bloom miss. It should not collide
// with modified accounts.
for bloomAccountHasherOffset == bloomDestructHasherOffset {
bloomAccountHasherOffset = rand.Intn(25)
}
}
// diffLayer represents a collection of modifications made to a state snapshot
// after running a block on top. It contains one sorted list for the account trie
// and one-one list for each storage tries.
//
// The goal of a diff layer is to act as a journal, tracking recent modifications
// made to the state, that have not yet graduated into a semi-immutable state.
type diffLayer struct {
origin *diskLayer // Base disk layer to directly use on bloom misses
parent snapshot // Parent snapshot modified by this one, never nil
memory uint64 // Approximate guess as to how much memory we use
root common.Hash // Root hash to which this snapshot diff belongs to
stale atomic.Bool // Signals that the layer became stale (state progressed)
// destructSet is a very special helper marker. If an account is marked as
// deleted, then it's recorded in this set. However it's allowed that an account
// is included here but still available in other sets(e.g. storageData). The
// reason is the diff layer includes all the changes in a *block*. It can
// happen that in the tx_1, account A is self-destructed while in the tx_2
// it's recreated. But we still need this marker to indicate the "old" A is
// deleted, all data in other set belongs to the "new" A.
destructSet map[common.Hash]struct{} // Keyed markers for deleted (and potentially) recreated accounts
accountList []common.Hash // List of account for iteration. If it exists, it's sorted, otherwise it's nil
accountData map[common.Hash][]byte // Keyed accounts for direct retrieval (nil means deleted)
storageList map[common.Hash][]common.Hash // List of storage slots for iterated retrievals, one per account. Any existing lists are sorted if non-nil
storageData map[common.Hash]map[common.Hash][]byte // Keyed storage slots for direct retrieval. one per account (nil means deleted)
diffed *bloomfilter.Filter // Bloom filter tracking all the diffed items up to the disk layer
lock sync.RWMutex
}
// destructBloomHash is used to convert a destruct event into a 64 bit mini hash.
func destructBloomHash(h common.Hash) uint64 {
return binary.BigEndian.Uint64(h[bloomDestructHasherOffset : bloomDestructHasherOffset+8])
}
// accountBloomHash is used to convert an account hash into a 64 bit mini hash.
func accountBloomHash(h common.Hash) uint64 {
return binary.BigEndian.Uint64(h[bloomAccountHasherOffset : bloomAccountHasherOffset+8])
}
// storageBloomHash is used to convert an account hash and a storage hash into a 64 bit mini hash.
func storageBloomHash(h0, h1 common.Hash) uint64 {
return binary.BigEndian.Uint64(h0[bloomStorageHasherOffset:bloomStorageHasherOffset+8]) ^
binary.BigEndian.Uint64(h1[bloomStorageHasherOffset:bloomStorageHasherOffset+8])
}
// newDiffLayer creates a new diff on top of an existing snapshot, whether that's a low
// level persistent database or a hierarchical diff already.
func newDiffLayer(parent snapshot, root common.Hash, destructs map[common.Hash]struct{}, accounts map[common.Hash][]byte, storage map[common.Hash]map[common.Hash][]byte) *diffLayer {
// Create the new layer with some pre-allocated data segments
dl := &diffLayer{
parent: parent,
root: root,
destructSet: destructs,
accountData: accounts,
storageData: storage,
storageList: make(map[common.Hash][]common.Hash),
}
switch parent := parent.(type) {
case *diskLayer:
dl.rebloom(parent)
case *diffLayer:
dl.rebloom(parent.origin)
default:
panic("unknown parent type")
}
// Sanity check that accounts or storage slots are never nil
for accountHash, blob := range accounts {
if blob == nil {
panic(fmt.Sprintf("account %#x nil", accountHash))
}
// Determine memory size and track the dirty writes
dl.memory += uint64(common.HashLength + len(blob))
snapshotDirtyAccountWriteMeter.Mark(int64(len(blob)))
}
for accountHash, slots := range storage {
if slots == nil {
panic(fmt.Sprintf("storage %#x nil", accountHash))
}
// Determine memory size and track the dirty writes
for _, data := range slots {
dl.memory += uint64(common.HashLength + len(data))
snapshotDirtyStorageWriteMeter.Mark(int64(len(data)))
}
}
dl.memory += uint64(len(destructs) * common.HashLength)
return dl
}
// rebloom discards the layer's current bloom and rebuilds it from scratch based
// on the parent's and the local diffs.
func (dl *diffLayer) rebloom(origin *diskLayer) {
dl.lock.Lock()
defer dl.lock.Unlock()
defer func(start time.Time) {
snapshotBloomIndexTimer.Update(time.Since(start))
}(time.Now())
// Inject the new origin that triggered the rebloom
dl.origin = origin
// Retrieve the parent bloom or create a fresh empty one
if parent, ok := dl.parent.(*diffLayer); ok {
parent.lock.RLock()
dl.diffed, _ = parent.diffed.Copy()
parent.lock.RUnlock()
} else {
dl.diffed, _ = bloomfilter.New(uint64(bloomSize), uint64(bloomFuncs))
}
// Iterate over all the accounts and storage slots and index them
for hash := range dl.destructSet {
dl.diffed.AddHash(destructBloomHash(hash))
}
for hash := range dl.accountData {
dl.diffed.AddHash(accountBloomHash(hash))
}
for accountHash, slots := range dl.storageData {
for storageHash := range slots {
dl.diffed.AddHash(storageBloomHash(accountHash, storageHash))
}
}
// Calculate the current false positive rate and update the error rate meter.
// This is a bit cheating because subsequent layers will overwrite it, but it
// should be fine, we're only interested in ballpark figures.
k := float64(dl.diffed.K())
n := float64(dl.diffed.N())
m := float64(dl.diffed.M())
snapshotBloomErrorGauge.Update(math.Pow(1.0-math.Exp((-k)*(n+0.5)/(m-1)), k))
}
// Root returns the root hash for which this snapshot was made.
func (dl *diffLayer) Root() common.Hash {
return dl.root
}
// Parent returns the subsequent layer of a diff layer.
func (dl *diffLayer) Parent() snapshot {
dl.lock.RLock()
defer dl.lock.RUnlock()
return dl.parent
}
// Stale return whether this layer has become stale (was flattened across) or if
// it's still live.
func (dl *diffLayer) Stale() bool {
return dl.stale.Load()
}
// Account directly retrieves the account associated with a particular hash in
// the snapshot slim data format.
func (dl *diffLayer) Account(hash common.Hash) (*types.SlimAccount, error) {
data, err := dl.AccountRLP(hash)
if err != nil {
return nil, err
}
if len(data) == 0 { // can be both nil and []byte{}
return nil, nil
}
account := new(types.SlimAccount)
if err := rlp.DecodeBytes(data, account); err != nil {
panic(err)
}
return account, nil
}
// AccountRLP directly retrieves the account RLP associated with a particular
// hash in the snapshot slim data format.
//
// Note the returned account is not a copy, please don't modify it.
func (dl *diffLayer) AccountRLP(hash common.Hash) ([]byte, error) {
// Check staleness before reaching further.
dl.lock.RLock()
if dl.Stale() {
dl.lock.RUnlock()
return nil, ErrSnapshotStale
}
// Check the bloom filter first whether there's even a point in reaching into
// all the maps in all the layers below
hit := dl.diffed.ContainsHash(accountBloomHash(hash))
if !hit {
hit = dl.diffed.ContainsHash(destructBloomHash(hash))
}
var origin *diskLayer
if !hit {
origin = dl.origin // extract origin while holding the lock
}
dl.lock.RUnlock()
// If the bloom filter misses, don't even bother with traversing the memory
// diff layers, reach straight into the bottom persistent disk layer
if origin != nil {
snapshotBloomAccountMissMeter.Mark(1)
return origin.AccountRLP(hash)
}
// The bloom filter hit, start poking in the internal maps
return dl.accountRLP(hash, 0)
}
// accountRLP is an internal version of AccountRLP that skips the bloom filter
// checks and uses the internal maps to try and retrieve the data. It's meant
// to be used if a higher layer's bloom filter hit already.
func (dl *diffLayer) accountRLP(hash common.Hash, depth int) ([]byte, error) {
dl.lock.RLock()
defer dl.lock.RUnlock()
// If the layer was flattened into, consider it invalid (any live reference to
// the original should be marked as unusable).
if dl.Stale() {
return nil, ErrSnapshotStale
}
// If the account is known locally, return it
if data, ok := dl.accountData[hash]; ok {
snapshotDirtyAccountHitMeter.Mark(1)
snapshotDirtyAccountHitDepthHist.Update(int64(depth))
snapshotDirtyAccountReadMeter.Mark(int64(len(data)))
snapshotBloomAccountTrueHitMeter.Mark(1)
return data, nil
}
// If the account is known locally, but deleted, return it
if _, ok := dl.destructSet[hash]; ok {
snapshotDirtyAccountHitMeter.Mark(1)
snapshotDirtyAccountHitDepthHist.Update(int64(depth))
snapshotDirtyAccountInexMeter.Mark(1)
snapshotBloomAccountTrueHitMeter.Mark(1)
return nil, nil
}
// Account unknown to this diff, resolve from parent
if diff, ok := dl.parent.(*diffLayer); ok {
return diff.accountRLP(hash, depth+1)
}
// Failed to resolve through diff layers, mark a bloom error and use the disk
snapshotBloomAccountFalseHitMeter.Mark(1)
return dl.parent.AccountRLP(hash)
}
// Storage directly retrieves the storage data associated with a particular hash,
// within a particular account. If the slot is unknown to this diff, it's parent
// is consulted.
//
// Note the returned slot is not a copy, please don't modify it.
func (dl *diffLayer) Storage(accountHash, storageHash common.Hash) ([]byte, error) {
// Check the bloom filter first whether there's even a point in reaching into
// all the maps in all the layers below
dl.lock.RLock()
// Check staleness before reaching further.
if dl.Stale() {
dl.lock.RUnlock()
return nil, ErrSnapshotStale
}
hit := dl.diffed.ContainsHash(storageBloomHash(accountHash, storageHash))
if !hit {
hit = dl.diffed.ContainsHash(destructBloomHash(accountHash))
}
var origin *diskLayer
if !hit {
origin = dl.origin // extract origin while holding the lock
}
dl.lock.RUnlock()
// If the bloom filter misses, don't even bother with traversing the memory
// diff layers, reach straight into the bottom persistent disk layer
if origin != nil {
snapshotBloomStorageMissMeter.Mark(1)
return origin.Storage(accountHash, storageHash)
}
// The bloom filter hit, start poking in the internal maps
return dl.storage(accountHash, storageHash, 0)
}
// storage is an internal version of Storage that skips the bloom filter checks
// and uses the internal maps to try and retrieve the data. It's meant to be
// used if a higher layer's bloom filter hit already.
func (dl *diffLayer) storage(accountHash, storageHash common.Hash, depth int) ([]byte, error) {
dl.lock.RLock()
defer dl.lock.RUnlock()
// If the layer was flattened into, consider it invalid (any live reference to
// the original should be marked as unusable).
if dl.Stale() {
return nil, ErrSnapshotStale
}
// If the account is known locally, try to resolve the slot locally
if storage, ok := dl.storageData[accountHash]; ok {
if data, ok := storage[storageHash]; ok {
snapshotDirtyStorageHitMeter.Mark(1)
snapshotDirtyStorageHitDepthHist.Update(int64(depth))
if n := len(data); n > 0 {
snapshotDirtyStorageReadMeter.Mark(int64(n))
} else {
snapshotDirtyStorageInexMeter.Mark(1)
}
snapshotBloomStorageTrueHitMeter.Mark(1)
return data, nil
}
}
// If the account is known locally, but deleted, return an empty slot
if _, ok := dl.destructSet[accountHash]; ok {
snapshotDirtyStorageHitMeter.Mark(1)
snapshotDirtyStorageHitDepthHist.Update(int64(depth))
snapshotDirtyStorageInexMeter.Mark(1)
snapshotBloomStorageTrueHitMeter.Mark(1)
return nil, nil
}
// Storage slot unknown to this diff, resolve from parent
if diff, ok := dl.parent.(*diffLayer); ok {
return diff.storage(accountHash, storageHash, depth+1)
}
// Failed to resolve through diff layers, mark a bloom error and use the disk
snapshotBloomStorageFalseHitMeter.Mark(1)
return dl.parent.Storage(accountHash, storageHash)
}
// Update creates a new layer on top of the existing snapshot diff tree with
// the specified data items.
func (dl *diffLayer) Update(blockRoot common.Hash, destructs map[common.Hash]struct{}, accounts map[common.Hash][]byte, storage map[common.Hash]map[common.Hash][]byte) *diffLayer {
return newDiffLayer(dl, blockRoot, destructs, accounts, storage)
}
// flatten pushes all data from this point downwards, flattening everything into
// a single diff at the bottom. Since usually the lowermost diff is the largest,
// the flattening builds up from there in reverse.
func (dl *diffLayer) flatten() snapshot {
// If the parent is not diff, we're the first in line, return unmodified
parent, ok := dl.parent.(*diffLayer)
if !ok {
return dl
}
// Parent is a diff, flatten it first (note, apart from weird corned cases,
// flatten will realistically only ever merge 1 layer, so there's no need to
// be smarter about grouping flattens together).
parent = parent.flatten().(*diffLayer)
parent.lock.Lock()
defer parent.lock.Unlock()
// Before actually writing all our data to the parent, first ensure that the
// parent hasn't been 'corrupted' by someone else already flattening into it
if parent.stale.Swap(true) {
panic("parent diff layer is stale") // we've flattened into the same parent from two children, boo
}
// Overwrite all the updated accounts blindly, merge the sorted list
for hash := range dl.destructSet {
parent.destructSet[hash] = struct{}{}
delete(parent.accountData, hash)
delete(parent.storageData, hash)
}
for hash, data := range dl.accountData {
parent.accountData[hash] = data
}
// Overwrite all the updated storage slots (individually)
for accountHash, storage := range dl.storageData {
// If storage didn't exist (or was deleted) in the parent, overwrite blindly
if _, ok := parent.storageData[accountHash]; !ok {
parent.storageData[accountHash] = storage
continue
}
// Storage exists in both parent and child, merge the slots
comboData := parent.storageData[accountHash]
for storageHash, data := range storage {
comboData[storageHash] = data
}
}
// Return the combo parent
return &diffLayer{
parent: parent.parent,
origin: parent.origin,
root: dl.root,
destructSet: parent.destructSet,
accountData: parent.accountData,
storageData: parent.storageData,
storageList: make(map[common.Hash][]common.Hash),
diffed: dl.diffed,
memory: parent.memory + dl.memory,
}
}
// AccountList returns a sorted list of all accounts in this diffLayer, including
// the deleted ones.
//
// Note, the returned slice is not a copy, so do not modify it.
func (dl *diffLayer) AccountList() []common.Hash {
// If an old list already exists, return it
dl.lock.RLock()
list := dl.accountList
dl.lock.RUnlock()
if list != nil {
return list
}
// No old sorted account list exists, generate a new one
dl.lock.Lock()
defer dl.lock.Unlock()
dl.accountList = make([]common.Hash, 0, len(dl.destructSet)+len(dl.accountData))
for hash := range dl.accountData {
dl.accountList = append(dl.accountList, hash)
}
for hash := range dl.destructSet {
if _, ok := dl.accountData[hash]; !ok {
dl.accountList = append(dl.accountList, hash)
}
}
slices.SortFunc(dl.accountList, common.Hash.Cmp)
dl.memory += uint64(len(dl.accountList) * common.HashLength)
return dl.accountList
}
// StorageList returns a sorted list of all storage slot hashes in this diffLayer
// for the given account. If the whole storage is destructed in this layer, then
// an additional flag *destructed = true* will be returned, otherwise the flag is
// false. Besides, the returned list will include the hash of deleted storage slot.
// Note a special case is an account is deleted in a prior tx but is recreated in
// the following tx with some storage slots set. In this case the returned list is
// not empty but the flag is true.
//
// Note, the returned slice is not a copy, so do not modify it.
func (dl *diffLayer) StorageList(accountHash common.Hash) ([]common.Hash, bool) {
dl.lock.RLock()
_, destructed := dl.destructSet[accountHash]
if _, ok := dl.storageData[accountHash]; !ok {
// Account not tracked by this layer
dl.lock.RUnlock()
return nil, destructed
}
// If an old list already exists, return it
if list, exist := dl.storageList[accountHash]; exist {
dl.lock.RUnlock()
return list, destructed // the cached list can't be nil
}
dl.lock.RUnlock()
// No old sorted account list exists, generate a new one
dl.lock.Lock()
defer dl.lock.Unlock()
storageMap := dl.storageData[accountHash]
storageList := make([]common.Hash, 0, len(storageMap))
for k := range storageMap {
storageList = append(storageList, k)
}
slices.SortFunc(storageList, common.Hash.Cmp)
dl.storageList[accountHash] = storageList
dl.memory += uint64(len(dl.storageList)*common.HashLength + common.HashLength)
return storageList, destructed
}