dao: use custom storage prefix

We use 2 prefixes for storing items because of state synchronization.
This commit allows to parametrize dao with the default prefix.

Signed-off-by: Evgeniy Stratonikov <evgeniy@nspcc.ru>
This commit is contained in:
Evgeniy Stratonikov 2021-09-27 16:35:25 +03:00
parent 019af7de46
commit 856385b106
11 changed files with 74 additions and 38 deletions

View file

@ -32,7 +32,7 @@ func batchToMap(index uint32, batch *storage.MemBatch) blockDump {
ops := make([]storageOp, 0, size)
for i := range batch.Put {
key := batch.Put[i].Key
if len(key) == 0 || key[0] != byte(storage.STStorage) {
if len(key) == 0 || key[0] != byte(storage.STStorage) && key[0] != byte(storage.STTempStorage) {
continue
}
@ -50,7 +50,8 @@ func batchToMap(index uint32, batch *storage.MemBatch) blockDump {
for i := range batch.Deleted {
key := batch.Deleted[i].Key
if len(key) == 0 || key[0] != byte(storage.STStorage) || !batch.Deleted[i].Exists {
if len(key) == 0 || !batch.Deleted[i].Exists ||
key[0] != byte(storage.STStorage) && key[0] != byte(storage.STTempStorage) {
continue
}

View file

@ -490,7 +490,7 @@ func (bc *Blockchain) jumpToStateInternal(p uint32, stage stateJumpStage) error
// Replace old storage items by new ones, it should be done step-by step.
// Firstly, remove all old genesis-related items.
b := bc.dao.Store.Batch()
bc.dao.Store.Seek([]byte{byte(storage.STStorage)}, func(k, _ []byte) {
bc.dao.Store.Seek([]byte{byte(bc.dao.StoragePrefix)}, func(k, _ []byte) {
// #1468, but don't need to copy here, because it is done by Store.
b.Delete(k)
})
@ -505,14 +505,16 @@ func (bc *Blockchain) jumpToStateInternal(p uint32, stage stateJumpStage) error
for {
count := 0
b := bc.dao.Store.Batch()
bc.dao.Store.Seek([]byte{byte(storage.STTempStorage)}, func(k, v []byte) {
currPrefix := byte(bc.dao.StoragePrefix)
syncPrefix := byte(statesync.TemporaryPrefix(bc.dao.StoragePrefix))
bc.dao.Store.Seek([]byte{syncPrefix}, func(k, v []byte) {
if count >= maxStorageBatchSize {
return
}
// #1468, but don't need to copy here, because it is done by Store.
b.Delete(k)
key := make([]byte, len(k))
key[0] = byte(storage.STStorage)
key[0] = currPrefix
copy(key[1:], k[1:])
b.Put(key, slice.Copy(v))
count += 2

View file

@ -1765,9 +1765,13 @@ func TestBlockchain_InitWithIncompleteStateJump(t *testing.T) {
// put storage items with STTemp prefix
batch := bcSpout.dao.Store.Batch()
bcSpout.dao.Store.Seek(storage.STStorage.Bytes(), func(k, v []byte) {
tempPrefix := storage.STTempStorage
if bcSpout.dao.StoragePrefix == tempPrefix {
tempPrefix = storage.STStorage
}
bcSpout.dao.Store.Seek(bcSpout.dao.StoragePrefix.Bytes(), func(k, v []byte) {
key := slice.Copy(k)
key[0] = storage.STTempStorage.Bytes()[0]
key[0] = byte(tempPrefix)
value := slice.Copy(v)
batch.Put(key, value)
})

View file

@ -74,7 +74,8 @@ type DAO interface {
// Simple is memCached wrapper around DB, simple DAO implementation.
type Simple struct {
Store *storage.MemCachedStore
StoragePrefix storage.KeyPrefix
Store *storage.MemCachedStore
// stateRootInHeader specifies if block header contains state root.
stateRootInHeader bool
// p2pSigExtensions denotes whether P2PSignatureExtensions are enabled.
@ -84,7 +85,12 @@ type Simple struct {
// NewSimple creates new simple dao using provided backend store.
func NewSimple(backend storage.Store, stateRootInHeader bool, p2pSigExtensions bool) *Simple {
st := storage.NewMemCachedStore(backend)
return &Simple{Store: st, stateRootInHeader: stateRootInHeader, p2pSigExtensions: p2pSigExtensions}
return &Simple{
StoragePrefix: storage.STStorage,
Store: st,
stateRootInHeader: stateRootInHeader,
p2pSigExtensions: p2pSigExtensions,
}
}
// GetBatch returns currently accumulated DB changeset.
@ -96,6 +102,7 @@ func (dao *Simple) GetBatch() *storage.MemBatch {
// MemCachedStore around the current DAO Store.
func (dao *Simple) GetWrapped() DAO {
d := NewSimple(dao.Store, dao.stateRootInHeader, dao.p2pSigExtensions)
d.StoragePrefix = dao.StoragePrefix
return d
}
@ -277,7 +284,7 @@ func (dao *Simple) PutAppExecResult(aer *state.AppExecResult, buf *io.BufBinWrit
// GetStorageItem returns StorageItem if it exists in the given store.
func (dao *Simple) GetStorageItem(id int32, key []byte) state.StorageItem {
b, err := dao.Store.Get(makeStorageItemKey(id, key))
b, err := dao.Store.Get(makeStorageItemKey(dao.StoragePrefix, id, key))
if err != nil {
return nil
}
@ -287,14 +294,14 @@ func (dao *Simple) GetStorageItem(id int32, key []byte) state.StorageItem {
// PutStorageItem puts given StorageItem for given id with given
// key into the given store.
func (dao *Simple) PutStorageItem(id int32, key []byte, si state.StorageItem) error {
stKey := makeStorageItemKey(id, key)
stKey := makeStorageItemKey(dao.StoragePrefix, id, key)
return dao.Store.Put(stKey, si)
}
// DeleteStorageItem drops storage item for the given id with the
// given key from the store.
func (dao *Simple) DeleteStorageItem(id int32, key []byte) error {
stKey := makeStorageItemKey(id, key)
stKey := makeStorageItemKey(dao.StoragePrefix, id, key)
return dao.Store.Delete(stKey)
}
@ -323,7 +330,7 @@ func (dao *Simple) GetStorageItemsWithPrefix(id int32, prefix []byte) ([]state.S
// Seek executes f for all items with a given prefix.
// If key is to be used outside of f, they may not be copied.
func (dao *Simple) Seek(id int32, prefix []byte, f func(k, v []byte)) {
lookupKey := makeStorageItemKey(id, nil)
lookupKey := makeStorageItemKey(dao.StoragePrefix, id, nil)
if prefix != nil {
lookupKey = append(lookupKey, prefix...)
}
@ -335,7 +342,7 @@ func (dao *Simple) Seek(id int32, prefix []byte, f func(k, v []byte)) {
// SeekAsync sends all storage items matching given prefix to a channel and returns
// the channel. Resulting keys and values may not be copied.
func (dao *Simple) SeekAsync(ctx context.Context, id int32, prefix []byte) chan storage.KeyValue {
lookupKey := makeStorageItemKey(id, nil)
lookupKey := makeStorageItemKey(dao.StoragePrefix, id, nil)
if prefix != nil {
lookupKey = append(lookupKey, prefix...)
}
@ -343,10 +350,10 @@ func (dao *Simple) SeekAsync(ctx context.Context, id int32, prefix []byte) chan
}
// makeStorageItemKey returns a key used to store StorageItem in the DB.
func makeStorageItemKey(id int32, key []byte) []byte {
func makeStorageItemKey(prefix storage.KeyPrefix, id int32, key []byte) []byte {
// 1 for prefix + 4 for Uint32 + len(key) for key
buf := make([]byte, 5+len(key))
buf[0] = byte(storage.STStorage)
buf[0] = byte(prefix)
binary.LittleEndian.PutUint32(buf[1:], uint32(id))
copy(buf[5:], key)
return buf
@ -667,7 +674,7 @@ func (dao *Simple) PersistSync() (int, error) {
// GetMPTBatch storage changes to be applied to MPT.
func (dao *Simple) GetMPTBatch() mpt.Batch {
var b mpt.Batch
dao.Store.MemoryStore.SeekAll([]byte{byte(storage.STStorage)}, func(k, v []byte) {
dao.Store.MemoryStore.SeekAll([]byte{byte(dao.StoragePrefix)}, func(k, v []byte) {
b.Add(k[1:], v)
})
return b

View file

@ -222,11 +222,16 @@ func TestMakeStorageItemKey(t *testing.T) {
expected := []byte{byte(storage.STStorage), 0, 0, 0, 0, 1, 2, 3}
binary.LittleEndian.PutUint32(expected[1:5], uint32(id))
actual := makeStorageItemKey(id, []byte{1, 2, 3})
actual := makeStorageItemKey(storage.STStorage, id, []byte{1, 2, 3})
require.Equal(t, expected, actual)
expected = expected[0:5]
actual = makeStorageItemKey(id, nil)
actual = makeStorageItemKey(storage.STStorage, id, nil)
require.Equal(t, expected, actual)
expected = []byte{byte(storage.STTempStorage), 0, 0, 0, 0, 1, 2, 3}
binary.LittleEndian.PutUint32(expected[1:5], uint32(id))
actual = makeStorageItemKey(storage.STTempStorage, id, []byte{1, 2, 3})
require.Equal(t, expected, actual)
}

View file

@ -28,7 +28,8 @@ var (
// 3. Pair (node, path) must be restored only once. It's a duty of MPT pool to manage
// MPT paths in order to provide this assumption.
type Billet struct {
Store *storage.MemCachedStore
TempStoragePrefix storage.KeyPrefix
Store *storage.MemCachedStore
root Node
refcountEnabled bool
@ -38,11 +39,12 @@ type Billet struct {
// to decouple storage errors from logic errors so that all storage errors are
// processed during `store.Persist()` at the caller. This also has the benefit,
// that every `Put` can be considered an atomic operation.
func NewBillet(rootHash util.Uint256, enableRefCount bool, store *storage.MemCachedStore) *Billet {
func NewBillet(rootHash util.Uint256, enableRefCount bool, prefix storage.KeyPrefix, store *storage.MemCachedStore) *Billet {
return &Billet{
Store: store,
root: NewHashNode(rootHash),
refcountEnabled: enableRefCount,
TempStoragePrefix: prefix,
Store: store,
root: NewHashNode(rootHash),
refcountEnabled: enableRefCount,
}
}
@ -64,7 +66,7 @@ func (b *Billet) RestoreHashNode(path []byte, node Node) error {
// If it's a leaf, then put into temporary contract storage.
if leaf, ok := node.(*LeafNode); ok {
k := append([]byte{byte(storage.STTempStorage)}, fromNibbles(path)...)
k := append([]byte{byte(b.TempStoragePrefix)}, fromNibbles(path)...)
_ = b.Store.Put(k, leaf.value)
}
return nil

View file

@ -32,7 +32,7 @@ func TestBillet_RestoreHashNode(t *testing.T) {
b.Children[5] = NewExtensionNode([]byte{0x01}, NewLeafNode([]byte{0xAB, 0xDE}))
path := toNibbles([]byte{0xAC})
e := NewExtensionNode(path, NewHashNode(b.Hash()))
tr := NewBillet(e.Hash(), true, newTestStore())
tr := NewBillet(e.Hash(), true, storage.STTempStorage, newTestStore())
tr.root = e
// OK
@ -61,7 +61,7 @@ func TestBillet_RestoreHashNode(t *testing.T) {
l := NewLeafNode([]byte{0xAB, 0xCD})
path := toNibbles([]byte{0xAC})
e := NewExtensionNode(path, NewHashNode(l.Hash()))
tr := NewBillet(e.Hash(), true, newTestStore())
tr := NewBillet(e.Hash(), true, storage.STTempStorage, newTestStore())
tr.root = e
// OK
@ -87,7 +87,7 @@ func TestBillet_RestoreHashNode(t *testing.T) {
h := NewHashNode(util.Uint256{1, 2, 3})
path := toNibbles([]byte{0xAC})
e := NewExtensionNode(path, h)
tr := NewBillet(e.Hash(), true, newTestStore())
tr := NewBillet(e.Hash(), true, storage.STTempStorage, newTestStore())
tr.root = e
// no-op
@ -99,7 +99,7 @@ func TestBillet_RestoreHashNode(t *testing.T) {
t.Run("parent is Leaf", func(t *testing.T) {
l := NewLeafNode([]byte{0xAB, 0xCD})
path := []byte{}
tr := NewBillet(l.Hash(), true, newTestStore())
tr := NewBillet(l.Hash(), true, storage.STTempStorage, newTestStore())
tr.root = l
// Already restored => panic expected
@ -121,7 +121,7 @@ func TestBillet_RestoreHashNode(t *testing.T) {
b := NewBranchNode()
b.Children[5] = NewHashNode(l1.Hash())
b.Children[lastChild] = NewHashNode(l2.Hash())
tr := NewBillet(b.Hash(), true, newTestStore())
tr := NewBillet(b.Hash(), true, storage.STTempStorage, newTestStore())
tr.root = b
// OK
@ -152,7 +152,7 @@ func TestBillet_RestoreHashNode(t *testing.T) {
b := NewBranchNode()
b.Children[5] = NewHashNode(l1.Hash())
b.Children[lastChild] = NewHashNode(l2.Hash())
tr := NewBillet(b.Hash(), true, newTestStore())
tr := NewBillet(b.Hash(), true, storage.STTempStorage, newTestStore())
tr.root = b
// OK
@ -179,7 +179,7 @@ func TestBillet_RestoreHashNode(t *testing.T) {
// two same hashnodes => leaf's refcount expected to be 2 in the end.
b.Children[3] = NewHashNode(l.Hash())
b.Children[4] = NewHashNode(l.Hash())
tr := NewBillet(b.Hash(), true, newTestStore())
tr := NewBillet(b.Hash(), true, storage.STTempStorage, newTestStore())
tr.root = b
// OK
@ -202,7 +202,7 @@ func TestBillet_RestoreHashNode(t *testing.T) {
b := NewBranchNode()
b.Children[3] = NewHashNode(l.Hash())
b.Children[4] = NewHashNode(l.Hash())
tr := NewBillet(b.Hash(), true, newTestStore())
tr := NewBillet(b.Hash(), true, storage.STTempStorage, newTestStore())
// Should fail, because if it's a hash node with non-empty path, then the node
// has already been collapsed.

View file

@ -566,7 +566,7 @@ func (t *Trie) Find(prefix, from []byte, max int) ([]storage.KeyValue, error) {
res []storage.KeyValue
count int
)
b := NewBillet(t.root.Hash(), false, t.Store)
b := NewBillet(t.root.Hash(), false, 0, t.Store)
process := func(pathToNode []byte, node Node, _ []byte) bool {
if leaf, ok := node.(*LeafNode); ok {
if from == nil || !bytes.Equal(pathToNode, from) { // (*Billet).traverse includes `from` path into result if so. Need to filter out manually.

View file

@ -165,6 +165,19 @@ func (s *Module) Init(currChainHeight uint32) error {
return s.defineSyncStage()
}
// TemporaryPrefix accepts current storage prefix and returns prefix
// to use for storing intermediate items during synchronization.
func TemporaryPrefix(currPrefix storage.KeyPrefix) storage.KeyPrefix {
switch currPrefix {
case storage.STStorage:
return storage.STTempStorage
case storage.STTempStorage:
return storage.STStorage
default:
panic(fmt.Sprintf("invalid storage prefix: %x", currPrefix))
}
}
// defineSyncStage sequentially checks and sets sync state process stage after Module
// initialization. It also performs initialization of MPT Billet if necessary.
func (s *Module) defineSyncStage() error {
@ -194,7 +207,8 @@ func (s *Module) defineSyncStage() error {
if err != nil {
return fmt.Errorf("failed to get header to initialize MPT billet: %w", err)
}
s.billet = mpt.NewBillet(header.PrevStateRoot, s.bc.GetConfig().KeepOnlyLatestState, s.dao.Store)
s.billet = mpt.NewBillet(header.PrevStateRoot, s.bc.GetConfig().KeepOnlyLatestState,
TemporaryPrefix(s.dao.StoragePrefix), s.dao.Store)
s.log.Info("MPT billet initialized",
zap.Uint32("height", s.syncPoint),
zap.String("state root", header.PrevStateRoot.StringBE()))
@ -466,7 +480,7 @@ func (s *Module) Traverse(root util.Uint256, process func(node mpt.Node, nodeByt
s.lock.RLock()
defer s.lock.RUnlock()
b := mpt.NewBillet(root, s.bc.GetConfig().KeepOnlyLatestState, storage.NewMemCachedStore(s.dao.Store))
b := mpt.NewBillet(root, s.bc.GetConfig().KeepOnlyLatestState, 0, storage.NewMemCachedStore(s.dao.Store))
return b.Traverse(func(pathToNode []byte, node mpt.Node, nodeBytes []byte) bool {
return process(node, nodeBytes)
}, false)

View file

@ -56,7 +56,8 @@ func TestModule_PR2019_discussion_r689629704(t *testing.T) {
dao: dao.NewSimple(actualStorage, true, false),
mptpool: NewPool(),
}
stateSync.billet = mpt.NewBillet(sr, true, actualStorage)
stateSync.billet = mpt.NewBillet(sr, true,
TemporaryPrefix(stateSync.dao.StoragePrefix), actualStorage)
stateSync.mptpool.Add(sr, []byte{})
// The test itself: we'll ask state sync module to restore each node exactly once.

View file

@ -421,7 +421,7 @@ func TestStateSyncModule_RestoreBasicChain(t *testing.T) {
// compare storage states
fetchStorage := func(bc *Blockchain) []storage.KeyValue {
var kv []storage.KeyValue
bc.dao.Store.Seek(storage.STStorage.Bytes(), func(k, v []byte) {
bc.dao.Store.Seek(bc.dao.StoragePrefix.Bytes(), func(k, v []byte) {
key := slice.Copy(k)
value := slice.Copy(v)
kv = append(kv, storage.KeyValue{