erigon-pulse/turbo/shards/trie_cache.go
Alex Sharov 0be3044b7e
rename (#1978)
* rename

* rename "make grpc"

* rename "abi bindings templates"

* rename "abi bindings templates"
2021-05-20 19:25:53 +01:00

761 lines
24 KiB
Go

package shards
import (
"bytes"
"fmt"
"math/bits"
"unsafe"
"github.com/google/btree"
"github.com/ledgerwatch/erigon/common"
"github.com/ledgerwatch/erigon/common/dbutils"
"github.com/ledgerwatch/erigon/core/types/accounts"
)
// An optional addition to the state cache, helping to calculate state root
// Sizes of B-tree items for the purposes of keeping track of the size of reads and writes
// The sizes of the nodes of the B-tree are not accounted for, because their are private to the `btree` package
const (
accountHashItemSize = int(unsafe.Sizeof(AccountHashItem{}) + 16)
accountHashWriteItemSize = int(unsafe.Sizeof(AccountHashWriteItem{}) + 16)
storageHashItemSize = int(unsafe.Sizeof(StorageHashItem{}) + 16)
storageHashWriteItemSize = int(unsafe.Sizeof(StorageHashWriteItem{}) + 16)
)
type AccountHashItem struct {
sequence int
queuePos int
flags uint16
hasState, hasTree, hasHash uint16
hashes []common.Hash // TODO: store it as fixed size flat array?
addrHashPrefix []byte
}
type AccountHashWriteItem struct {
ai *AccountHashItem
}
func (awi *AccountHashWriteItem) GetCacheItem() CacheItem { return awi.ai }
func (awi *AccountHashWriteItem) SetCacheItem(item CacheItem) { awi.ai = item.(*AccountHashItem) }
func (awi *AccountHashWriteItem) GetSize() int { return accountHashWriteItemSize }
func (awi *AccountHashWriteItem) Less(than btree.Item) bool {
return awi.ai.Less(than)
}
func (ahi *AccountHashItem) Less(than btree.Item) bool {
switch i := than.(type) {
case *AccountHashItem:
return bytes.Compare(ahi.addrHashPrefix, i.addrHashPrefix) < 0
case *AccountHashWriteItem:
return bytes.Compare(ahi.addrHashPrefix, i.ai.addrHashPrefix) < 0
default:
panic(fmt.Sprintf("unexpected type: %T", than))
}
}
func (ahi *AccountHashItem) GetSequence() int { return ahi.sequence }
func (ahi *AccountHashItem) SetSequence(sequence int) { ahi.sequence = sequence }
func (ahi *AccountHashItem) GetSize() int { return accountHashItemSize + len(ahi.addrHashPrefix) }
func (ahi *AccountHashItem) GetQueuePos() int { return ahi.queuePos }
func (ahi *AccountHashItem) SetQueuePos(pos int) { ahi.queuePos = pos }
func (ahi *AccountHashItem) HasFlag(flag uint16) bool { return ahi.flags&flag != 0 }
func (ahi *AccountHashItem) SetFlags(flags uint16) { ahi.flags |= flags }
func (ahi *AccountHashItem) ClearFlags(flags uint16) { ahi.flags &^= flags }
func (ahi *AccountHashItem) String() string {
return fmt.Sprintf("AccountHashItem(addrHashPrefix=%x)", ahi.addrHashPrefix)
}
func (ahi *AccountHashItem) CopyValueFrom(item CacheItem) {
other, ok := item.(*AccountHashItem)
if !ok {
panic(fmt.Sprintf("expected AccountHashItem, got %T", item))
}
ahi.hashes = make([]common.Hash, len(other.hashes))
for i := 0; i < len(ahi.hashes); i++ {
ahi.hashes[i] = other.hashes[i]
}
ahi.hasState = other.hasState
ahi.hasTree = other.hasTree
ahi.hasHash = other.hasHash
}
type StorageHashWriteItem struct {
i *StorageHashItem
}
type StorageHashItem struct {
flags, hasState, hasTree, hasHash uint16
sequence, queuePos int
addrHash common.Hash
incarnation uint64
locHashPrefix []byte
hashes []common.Hash
}
func (wi *StorageHashWriteItem) GetCacheItem() CacheItem { return wi.i }
func (wi *StorageHashWriteItem) SetCacheItem(item CacheItem) { wi.i = item.(*StorageHashItem) }
func (wi *StorageHashWriteItem) GetSize() int { return storageHashWriteItemSize }
func (wi *StorageHashWriteItem) Less(than btree.Item) bool {
return wi.i.Less(than.(*StorageHashWriteItem).i)
}
func (shi *StorageHashItem) Less(than btree.Item) bool {
i := than.(*StorageHashItem)
c := bytes.Compare(shi.addrHash.Bytes(), i.addrHash.Bytes())
if c != 0 {
return c < 0
}
if shi.incarnation != i.incarnation {
return shi.incarnation < i.incarnation
}
return bytes.Compare(shi.locHashPrefix, i.locHashPrefix) < 0
}
func (shi *StorageHashItem) GetSequence() int { return shi.sequence }
func (shi *StorageHashItem) SetSequence(sequence int) { shi.sequence = sequence }
func (shi *StorageHashItem) GetSize() int { return storageHashItemSize + len(shi.locHashPrefix) }
func (shi *StorageHashItem) GetQueuePos() int { return shi.queuePos }
func (shi *StorageHashItem) SetQueuePos(pos int) { shi.queuePos = pos }
func (shi *StorageHashItem) HasFlag(flag uint16) bool { return shi.flags&flag != 0 }
func (shi *StorageHashItem) SetFlags(flags uint16) { shi.flags |= flags }
func (shi *StorageHashItem) ClearFlags(flags uint16) { shi.flags &^= flags }
func (shi *StorageHashItem) String() string {
return fmt.Sprintf("StorageHashItem(addrHash=%x,incarnation=%d,locHashPrefix=%x)", shi.addrHash, shi.incarnation, shi.locHashPrefix)
}
func (shi *StorageHashItem) CopyValueFrom(item CacheItem) {
other, ok := item.(*StorageHashItem)
if !ok {
panic(fmt.Sprintf("expected StorageHashItem, got %T", item))
}
shi.hashes = make([]common.Hash, len(other.hashes))
for i := 0; i < len(shi.hashes); i++ {
shi.hashes[i] = other.hashes[i]
}
shi.hasState = other.hasState
shi.hasTree = other.hasTree
shi.hasHash = other.hasHash
}
// UnprocessedHeap is a priority queue of items that were modified after the last recalculation of the merkle tree
type UnprocessedHeap struct {
items []CacheItem
}
func (uh UnprocessedHeap) Len() int { return len(uh.items) }
func (uh UnprocessedHeap) Less(i, j int) bool { return uh.items[i].Less(uh.items[j]) }
func (uh UnprocessedHeap) Swap(i, j int) { uh.items[i], uh.items[j] = uh.items[j], uh.items[i] }
func (uh *UnprocessedHeap) Push(x interface{}) {
// Push and Pop use pointer receivers because they modify the slice's length,
// not just its contents.
uh.items = append(uh.items, x.(CacheItem))
}
func (uh *UnprocessedHeap) Pop() interface{} {
cacheItem := uh.items[len(uh.items)-1]
uh.items = uh.items[:len(uh.items)-1]
return cacheItem
}
func (ai *AccountItem) HasPrefix(prefix CacheItem) bool {
switch i := prefix.(type) {
case *AccountItem:
return ai.addrHash == i.addrHash && ai.account.Incarnation == i.account.Incarnation
default:
panic(fmt.Sprintf("unrecognised type of cache item: %T", prefix))
}
}
func (si *StorageItem) HasPrefix(prefix CacheItem) bool {
switch i := prefix.(type) {
case *StorageItem:
return si.addrHash == i.addrHash && si.incarnation == i.incarnation && si.locHash == i.locHash
default:
panic(fmt.Sprintf("unrecognised type of cache item: %T", prefix))
}
}
func (ci *CodeItem) HasPrefix(prefix CacheItem) bool {
switch i := prefix.(type) {
case *CodeItem:
return ci.addrHash == i.addrHash && ci.incarnation == i.incarnation
default:
panic(fmt.Sprintf("unrecognised type of cache item: %T", prefix))
}
}
func (ahi *AccountHashItem) HasPrefix(prefix CacheItem) bool {
switch i := prefix.(type) {
case *AccountHashItem:
return bytes.HasPrefix(ahi.addrHashPrefix, i.addrHashPrefix)
default:
panic(fmt.Sprintf("unrecognised type of cache item: %T", prefix))
}
}
func (shi *StorageHashItem) HasPrefix(prefix CacheItem) bool {
switch i := prefix.(type) {
case *StorageHashItem:
if shi.addrHash != i.addrHash || shi.incarnation != i.incarnation {
return false
}
return bytes.HasPrefix(shi.locHashPrefix, i.locHashPrefix)
default:
panic(fmt.Sprintf("unrecognised type of cache item: %T", prefix))
}
}
func (sc *StateCache) SetAccountHashesRead(prefix []byte, hasState, hasTree, hasHash uint16, hashes []common.Hash) {
if bits.OnesCount16(hasHash) != len(hashes) {
panic(fmt.Errorf("invariant bits.OnesCount16(hasHash) == len(hashes) failed: %d, %d", bits.OnesCount16(hasHash), len(hashes)))
}
assertSubset(hasTree, hasState)
assertSubset(hasHash, hasState)
cpy := make([]common.Hash, len(hashes))
for i := 0; i < len(hashes); i++ {
cpy[i] = hashes[i]
}
ai := AccountHashItem{
addrHashPrefix: common.CopyBytes(prefix),
hasState: hasState,
hasTree: hasTree,
hasHash: hasHash,
hashes: cpy,
}
sc.setRead(&ai, false /* absent */)
}
func (sc *StateCache) SetAccountHashWrite(prefix []byte, hasState, hasTree, hasHash uint16, hashes []common.Hash) {
if bits.OnesCount16(hasHash) != len(hashes) {
panic(fmt.Errorf("invariant bits.OnesCount16(hasHash) == len(hashes) failed: %d, %d", bits.OnesCount16(hasHash), len(hashes)))
}
assertSubset(hasTree, hasState)
assertSubset(hasHash, hasState)
ai := AccountHashItem{
addrHashPrefix: common.CopyBytes(prefix),
hasState: hasState,
hasTree: hasTree,
hasHash: hasHash,
hashes: make([]common.Hash, len(hashes)),
}
for i := 0; i < len(hashes); i++ {
ai.hashes[i] = hashes[i]
}
var awi AccountHashWriteItem
awi.ai = &ai
sc.setWrite(&ai, &awi, false /* delete */)
}
func (sc *StateCache) SetAccountHashDelete(prefix []byte) {
var ai AccountHashItem
var wi AccountHashWriteItem
ai.addrHashPrefix = append(ai.addrHashPrefix[:0], prefix...)
wi.ai = &ai
sc.setWrite(&ai, &wi, true /* delete */)
}
func (sc *StateCache) SetStorageHashRead(addrHash common.Hash, incarnation uint64, locHashPrefix []byte, hasState, hasTree, hasHash uint16, hashes []common.Hash) {
cpy := make([]common.Hash, len(hashes))
for i := 0; i < len(hashes); i++ {
cpy[i] = hashes[i]
}
ai := StorageHashItem{
addrHash: addrHash,
incarnation: incarnation,
locHashPrefix: common.CopyBytes(locHashPrefix),
hasState: hasState,
hasTree: hasTree,
hasHash: hasHash,
hashes: cpy,
}
sc.setRead(&ai, false /* absent */)
}
func (sc *StateCache) SetStorageHashWrite(addrHash common.Hash, incarnation uint64, locHashPrefix []byte, hasState, hasTree, hasHash uint16, hashes []common.Hash) {
cpy := make([]common.Hash, len(hashes))
for i := 0; i < len(hashes); i++ {
cpy[i] = hashes[i]
}
ai := StorageHashItem{
addrHash: addrHash,
incarnation: incarnation,
locHashPrefix: common.CopyBytes(locHashPrefix),
hasState: hasState,
hasTree: hasTree,
hasHash: hasHash,
hashes: cpy,
}
var wi StorageHashWriteItem
wi.i = &ai
sc.setWrite(&ai, &wi, false /* delete */)
}
func (sc *StateCache) SetStorageHashDelete(addrHash common.Hash, incarnation uint64, locHashPrefix []byte, hasState, hasTree, hasHash uint16, hashes []common.Hash) {
cpy := make([]common.Hash, len(hashes))
for i := 0; i < len(hashes); i++ {
cpy[i] = hashes[i]
}
ai := StorageHashItem{
addrHash: addrHash,
incarnation: incarnation,
locHashPrefix: common.CopyBytes(locHashPrefix),
hasState: hasState,
hasTree: hasTree,
hasHash: hasHash,
hashes: cpy,
}
var wi StorageHashWriteItem
wi.i = &ai
sc.setWrite(&ai, &wi, true /* delete */)
}
func (sc *StateCache) AccountHashCount() int {
var key AccountSeek
return sc.readWrites[id(key)].Len()
}
func (sc *StateCache) HasAccountHashWithPrefix(addrHashPrefix []byte) bool {
seek := &AccountHashItem{addrHashPrefix: addrHashPrefix}
var found bool
sc.readWrites[id(seek)].AscendGreaterOrEqual(seek, func(i btree.Item) bool {
found = bytes.HasPrefix(i.(*AccountHashItem).addrHashPrefix, addrHashPrefix)
return false
})
return found
}
func (sc *StateCache) GetAccountHash(prefix []byte) ([]byte, uint16, uint16, uint16, []common.Hash, bool) {
var key AccountHashItem
key.addrHashPrefix = prefix
if item, ok := sc.get(&key); ok {
if item != nil {
i := item.(*AccountHashItem)
return i.addrHashPrefix, i.hasState, i.hasTree, i.hasHash, i.hashes, true
}
return nil, 0, 0, 0, nil, true
}
return nil, 0, 0, 0, nil, false
}
func (sc *StateCache) GetStorageHash(addrHash common.Hash, incarnation uint64, prefix []byte) ([]byte, uint16, uint16, uint16, []common.Hash, bool) {
key := StorageHashItem{addrHash: addrHash, incarnation: incarnation, locHashPrefix: prefix}
if item, ok := sc.get(&key); ok {
if item != nil {
i := item.(*StorageHashItem)
return i.locHashPrefix, i.hasState, i.hasTree, i.hasHash, i.hashes, true
}
return nil, 0, 0, 0, nil, true
}
return nil, 0, 0, 0, nil, false
}
func (sc *StateCache) DebugPrintAccounts() error {
var cur *AccountHashItem
id := id(cur)
rw := sc.writes[id]
rw.Ascend(func(i btree.Item) bool {
it := i.(*AccountHashWriteItem)
if it.ai.HasFlag(AbsentFlag) || it.ai.HasFlag(DeletedFlag) {
fmt.Printf("deleted: %x\n", it.ai.addrHashPrefix)
} else if it.ai.HasFlag(ModifiedFlag) {
fmt.Printf("modified: %x\n", it.ai.addrHashPrefix)
} else {
fmt.Printf("normal: %x\n", it.ai.addrHashPrefix)
}
return true
})
return nil
}
func (sc *StateCache) AccountTree(prefix []byte, walker func(k []byte, h common.Hash, hasTree, hasHash bool) (toChild bool, err error), onMiss func(k []byte)) error {
var cur []byte
seek := make([]byte, 0, 64)
buf := make([]byte, 0, 64)
next := make([]byte, 0, 64)
seek = append(seek, prefix...)
var k [64][]byte
var hasTree, hasState, hasHash [64]uint16
var id, hashID [64]int16
var hashes [64][]common.Hash
var lvl int
var ok bool
var (
ihK []byte
hasStateItem, hasTreeItem, hasHashItem uint16
hashItem []common.Hash
)
var _hasChild = func() bool { return (1<<id[lvl])&hasState[lvl] != 0 }
var _hasTree = func() bool { return (1<<id[lvl])&hasTree[lvl] != 0 }
var _hasHash = func() bool { return (1<<id[lvl])&hasHash[lvl] != 0 }
var _unmarshal = func() {
from, to := lvl+1, len(k)
if lvl >= len(k) {
from, to = len(k)+1, lvl+2
}
for i := from; i < to; i++ { // if first meet key is not 0 length, then nullify all shorter metadata
k[i], hasState[i], hasTree[i], hasHash[i], hashID[i], id[i], hashes[i] = nil, 0, 0, 0, 0, 0, nil
}
lvl = len(ihK)
k[lvl], hasState[lvl], hasTree[lvl], hasHash[lvl], hashes[lvl] = ihK, hasStateItem, hasTreeItem, hasHashItem, hashItem
hashID[lvl], id[lvl] = -1, int16(bits.TrailingZeros16(hasStateItem))-1
}
var _nextSiblingInMem = func() bool {
for id[lvl]++; id[lvl] < int16(bits.Len16(hasState[lvl])); id[lvl]++ { // go to sibling
if !_hasChild() {
continue
}
if _hasHash() {
hashID[lvl]++
return true
}
if _hasTree() {
return true
}
}
return false
}
var _seek = func(seek []byte, withinPrefix []byte) bool {
ihK, hasStateItem, hasTreeItem, hasHashItem, hashItem = sc.AccountHashesSeek(seek)
if ihK == nil || !bytes.HasPrefix(ihK, withinPrefix) || !bytes.HasPrefix(ihK, prefix) {
k[lvl] = nil
return false
}
_unmarshal()
_nextSiblingInMem()
return true
}
var _nextSiblingOfParentInMem = func() bool {
for lvl > 1 { // go to parent sibling in mem
if k[lvl-1] == nil {
nonNilLvl := lvl - 1
for ; k[nonNilLvl] == nil && nonNilLvl > 1; nonNilLvl-- {
}
next = append(append(next[:0], k[lvl]...), uint8(id[lvl]))
buf = append(append(buf[:0], k[nonNilLvl]...), uint8(id[nonNilLvl]))
if _seek(next, buf) {
return true
}
lvl = nonNilLvl + 1
continue
}
lvl--
// END of _nextSiblingOfParentInMem
if _nextSiblingInMem() {
return true
}
}
return false
}
var _nextSiblingInDB = func() bool {
if ok = dbutils.NextNibblesSubtree(k[lvl], &seek); !ok {
k[lvl] = nil
return false
}
_seek(seek, []byte{})
return k[lvl] != nil
}
_seek(prefix, []byte{})
for k[lvl] != nil && bytes.HasPrefix(k[lvl], prefix) { // go to sibling in cache
cur = append(append(cur[:0], k[lvl]...), uint8(id[lvl]))
toChild, err := walker(cur, hashes[lvl][hashID[lvl]], _hasTree(), _hasHash())
if err != nil {
return err
}
// preOrderTraversalStep
if toChild && _hasTree() {
next = append(append(next[:0], k[lvl]...), uint8(id[lvl]))
ihK, hasStateItem, hasTreeItem, hasHashItem, hashItem, ok = sc.GetAccountHash(next)
if ok {
_unmarshal()
_nextSiblingInMem()
continue
}
onMiss(cur)
}
_ = _nextSiblingInMem() || _nextSiblingOfParentInMem() || _nextSiblingInDB()
}
if _, err := walker(nil, common.Hash{}, false, false); err != nil {
return err
}
return nil
}
func (sc *StateCache) StorageTree(prefix []byte, accHash common.Hash, incarnation uint64, walker func(k []byte, h common.Hash, hasTree, hasHash bool) (toChild bool, err error), onMiss func(k []byte)) error {
var cur []byte
seek := make([]byte, 0, 64)
buf := make([]byte, 0, 64)
next := make([]byte, 0, 64)
seek = append(seek, prefix...)
var k [64][]byte
var hasTree, hasState, hasHash [64]uint16
var id, hashID [64]int16
var hashes [64][]common.Hash
var lvl int
var ok bool
var (
ihK []byte
hasStateItem, hasTreeItem, hasHashItem uint16
hashItem []common.Hash
)
var _hasChild = func() bool { return (1<<id[lvl])&hasState[lvl] != 0 }
var _hasBranch = func() bool { return (1<<id[lvl])&hasTree[lvl] != 0 }
var _hasHash = func() bool { return (1<<id[lvl])&hasHash[lvl] != 0 }
var _unmarshal = func() {
from, to := lvl+1, len(k)
if lvl >= len(k) {
from, to = len(k)+1, lvl+2
}
for i := from; i < to; i++ { // if first meet key is not 0 length, then nullify all shorter metadata
k[i], hasState[i], hasTree[i], hasHash[i], hashID[i], id[i], hashes[i] = nil, 0, 0, 0, 0, 0, nil
}
lvl = len(ihK)
k[lvl], hasState[lvl], hasTree[lvl], hasHash[lvl], hashes[lvl] = ihK, hasStateItem, hasTreeItem, hasHashItem, hashItem
hashID[lvl], id[lvl] = -1, int16(bits.TrailingZeros16(hasStateItem))-1
}
var _nextSiblingInMem = func() bool {
for id[lvl]++; id[lvl] < int16(bits.Len16(hasState[lvl])); id[lvl]++ { // go to sibling
if !_hasChild() {
continue
}
if _hasHash() {
hashID[lvl]++
return true
}
if _hasBranch() {
return true
}
}
return false
}
var _seek = func(seek []byte, withinPrefix []byte) bool {
ihK, hasStateItem, hasTreeItem, hasHashItem, hashItem = sc.StorageHashesSeek(accHash, incarnation, seek)
if ihK == nil || !bytes.HasPrefix(ihK, withinPrefix) || !bytes.HasPrefix(ihK, prefix) {
k[lvl] = nil
return false
}
_unmarshal()
_nextSiblingInMem()
return true
}
var _nextSiblingOfParentInMem = func() bool {
for lvl > 0 { // go to parent sibling in mem
if k[lvl-1] == nil {
nonNilLvl := lvl - 1
for ; k[nonNilLvl] == nil && nonNilLvl > 1; nonNilLvl-- {
}
next = append(append(next[:0], k[lvl]...), uint8(id[lvl]))
buf = append(append(buf[:0], k[nonNilLvl]...), uint8(id[nonNilLvl]))
if _seek(next, buf) {
return true
}
lvl = nonNilLvl + 1
continue
}
lvl--
// END of _nextSiblingOfParentInMem
if _nextSiblingInMem() {
return true
}
}
return false
}
var _nextSiblingInDB = func() bool {
if ok = dbutils.NextNibblesSubtree(k[lvl], &seek); !ok {
k[lvl] = nil
return false
}
_seek(seek, []byte{})
return k[lvl] != nil
}
_seek(prefix, []byte{})
for k[lvl] != nil && bytes.HasPrefix(k[lvl], prefix) { // go to sibling in cache
cur = append(append(cur[:0], k[lvl]...), uint8(id[lvl]))
toChild, err := walker(cur, hashes[lvl][hashID[lvl]], _hasBranch(), _hasHash())
if err != nil {
return err
}
if toChild && _hasBranch() {
next = append(append(next[:0], k[lvl]...), uint8(id[lvl]))
ihK, hasStateItem, hasTreeItem, hasHashItem, hashItem, ok = sc.GetStorageHash(accHash, incarnation, next)
if ok {
_unmarshal()
_nextSiblingInMem()
continue
}
onMiss(cur)
}
_ = _nextSiblingInMem() || _nextSiblingOfParentInMem() || _nextSiblingInDB()
}
if _, err := walker(nil, common.Hash{}, false, false); err != nil {
return err
}
return nil
}
func (sc *StateCache) AccountHashesSeek(prefix []byte) ([]byte, uint16, uint16, uint16, []common.Hash) {
var cur *AccountHashItem
seek := &AccountHashItem{}
id := id(seek)
seek.addrHashPrefix = append(seek.addrHashPrefix[:0], prefix...)
sc.readWrites[id].AscendGreaterOrEqual(seek, func(i btree.Item) bool {
it := i.(*AccountHashItem)
if it.HasFlag(AbsentFlag) || it.HasFlag(DeletedFlag) {
return true
}
cur = it // found
return false
})
if cur == nil {
return nil, 0, 0, 0, nil
}
return cur.addrHashPrefix, cur.hasState, cur.hasTree, cur.hasHash, cur.hashes
}
func (sc *StateCache) StorageHashesSeek(addrHash common.Hash, incarnation uint64, prefix []byte) ([]byte, uint16, uint16, uint16, []common.Hash) {
var cur *StorageHashItem
seek := &StorageHashItem{}
id := id(seek)
seek.addrHash.SetBytes(addrHash.Bytes())
seek.incarnation = incarnation
seek.locHashPrefix = prefix
sc.readWrites[id].AscendGreaterOrEqual(seek, func(i btree.Item) bool {
it := i.(*StorageHashItem)
if it.HasFlag(AbsentFlag) || it.HasFlag(DeletedFlag) {
return true
}
if it.addrHash != addrHash {
return false
}
if it.incarnation != incarnation {
return false
}
cur = it
return false
})
if cur == nil {
return nil, 0, 0, 0, nil
}
return cur.locHashPrefix, cur.hasState, cur.hasTree, cur.hasHash, cur.hashes
}
func WalkAccountHashesWrites(writes [5]*btree.BTree, update func(prefix []byte, hasState, hasTree, hasHash uint16, h []common.Hash), del func(prefix []byte, hasState, hasTree, hasHash uint16, h []common.Hash)) {
id := id(&AccountHashWriteItem{})
writes[id].Ascend(func(i btree.Item) bool {
it := i.(*AccountHashWriteItem)
if it.ai.HasFlag(AbsentFlag) || it.ai.HasFlag(DeletedFlag) {
del(it.ai.addrHashPrefix, it.ai.hasState, it.ai.hasTree, it.ai.hasHash, it.ai.hashes)
return true
}
update(it.ai.addrHashPrefix, it.ai.hasState, it.ai.hasTree, it.ai.hasHash, it.ai.hashes)
return true
})
}
func (sc *StateCache) WalkStorageHashes(walker func(addrHash common.Hash, incarnation uint64, prefix []byte, hasStat, hasTree, hasHash uint16, h []common.Hash) error) error {
id := id(&StorageHashItem{})
sc.readWrites[id].Ascend(func(i btree.Item) bool {
it, ok := i.(*StorageHashItem)
if !ok {
return true
}
if it.HasFlag(AbsentFlag) || it.HasFlag(DeletedFlag) {
return true
}
if err := walker(it.addrHash, it.incarnation, it.locHashPrefix, it.hasState, it.hasTree, it.hasHash, it.hashes); err != nil {
panic(err)
}
return true
})
return nil
}
func WalkStorageHashesWrites(writes [5]*btree.BTree, update func(addrHash common.Hash, incarnation uint64, locHashPrefix []byte, hasState, hasTree, hasHash uint16, h []common.Hash), del func(addrHash common.Hash, incarnation uint64, locHashPrefix []byte, hasStat, hasTree, hasHash uint16, h []common.Hash)) {
id := id(&StorageWriteItem{})
writes[id].Ascend(func(i btree.Item) bool {
it := i.(*StorageHashWriteItem)
if it.i.HasFlag(AbsentFlag) || it.i.HasFlag(DeletedFlag) {
del(it.i.addrHash, it.i.incarnation, it.i.locHashPrefix, it.i.hasState, it.i.hasTree, it.i.hasHash, it.i.hashes)
return true
}
update(it.i.addrHash, it.i.incarnation, it.i.locHashPrefix, it.i.hasState, it.i.hasTree, it.i.hasHash, it.i.hashes)
return true
})
}
func (sc *StateCache) WalkStorage(addrHash common.Hash, incarnation uint64, prefix []byte, walker func(locHash common.Hash, val []byte) error) error {
seek := &StorageSeek{seek: prefix}
id := id(seek)
sc.readWrites[id].AscendGreaterOrEqual(seek, func(i btree.Item) bool {
switch it := i.(type) {
case *StorageItem:
if it.HasFlag(AbsentFlag) || it.HasFlag(DeletedFlag) {
return true
}
if it.addrHash != addrHash || it.incarnation != incarnation {
return false
}
if err := walker(it.locHash, it.value.Bytes()); err != nil {
panic(err)
}
case *StorageWriteItem:
if it.si.HasFlag(AbsentFlag) || it.si.HasFlag(DeletedFlag) {
return true
}
if it.si.addrHash != addrHash || it.si.incarnation != incarnation {
return false
}
if err := walker(it.si.locHash, it.si.value.Bytes()); err != nil {
panic(err)
}
}
return true
})
return nil
}
func (sc *StateCache) WalkAccounts(prefix []byte, walker func(addrHash common.Hash, acc *accounts.Account) (bool, error)) error {
seek := &AccountSeek{seek: prefix}
id := id(seek)
sc.readWrites[id].AscendGreaterOrEqual(seek, func(i btree.Item) bool {
switch it := i.(type) {
case *AccountItem:
if it.HasFlag(AbsentFlag) || it.HasFlag(DeletedFlag) {
return true
}
if goOn, err := walker(it.addrHash, &it.account); err != nil {
panic(err)
} else if !goOn {
return false
}
case *AccountWriteItem:
if it.ai.HasFlag(AbsentFlag) || it.ai.HasFlag(DeletedFlag) {
return true
}
if goOn, err := walker(it.ai.addrHash, &it.ai.account); err != nil {
panic(err)
} else if !goOn {
return false
}
}
return true
})
return nil
}
func assertSubset(a, b uint16) {
if (a & b) != a { // a & b == a - checks whether a is subset of b
panic(fmt.Errorf("invariant 'is subset' failed: %b, %b", a, b))
}
}