bsc/core/state/snapshot/disklayer_test.go
Eng Zer Jun 8d066f1f42
all: use T.TempDir to create temporary test directories (#24633)
This commit replaces ioutil.TempDir with t.TempDir in tests. The
directory created by t.TempDir is automatically removed when the test
and all its subtests complete.

Prior to this commit, temporary directory created using ioutil.TempDir
had to be removed manually by calling os.RemoveAll, which is omitted in
some tests. The error handling boilerplate e.g.

	defer func() {
		if err := os.RemoveAll(dir); err != nil {
			t.Fatal(err)
		}
	}

is also tedious, but t.TempDir handles this for us nicely.

Reference: https://pkg.go.dev/testing#T.TempDir
Signed-off-by: Eng Zer Jun <engzerjun@gmail.com>
2022-04-08 15:44:55 +02:00

580 lines
23 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 (
"bytes"
"testing"
"github.com/VictoriaMetrics/fastcache"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core/rawdb"
"github.com/ethereum/go-ethereum/ethdb/leveldb"
"github.com/ethereum/go-ethereum/ethdb/memorydb"
"github.com/ethereum/go-ethereum/rlp"
)
// reverse reverses the contents of a byte slice. It's used to update random accs
// with deterministic changes.
func reverse(blob []byte) []byte {
res := make([]byte, len(blob))
for i, b := range blob {
res[len(blob)-1-i] = b
}
return res
}
// Tests that merging something into a disk layer persists it into the database
// and invalidates any previously written and cached values.
func TestDiskMerge(t *testing.T) {
// Create some accounts in the disk layer
db := memorydb.New()
var (
accNoModNoCache = common.Hash{0x1}
accNoModCache = common.Hash{0x2}
accModNoCache = common.Hash{0x3}
accModCache = common.Hash{0x4}
accDelNoCache = common.Hash{0x5}
accDelCache = common.Hash{0x6}
conNoModNoCache = common.Hash{0x7}
conNoModNoCacheSlot = common.Hash{0x70}
conNoModCache = common.Hash{0x8}
conNoModCacheSlot = common.Hash{0x80}
conModNoCache = common.Hash{0x9}
conModNoCacheSlot = common.Hash{0x90}
conModCache = common.Hash{0xa}
conModCacheSlot = common.Hash{0xa0}
conDelNoCache = common.Hash{0xb}
conDelNoCacheSlot = common.Hash{0xb0}
conDelCache = common.Hash{0xc}
conDelCacheSlot = common.Hash{0xc0}
conNukeNoCache = common.Hash{0xd}
conNukeNoCacheSlot = common.Hash{0xd0}
conNukeCache = common.Hash{0xe}
conNukeCacheSlot = common.Hash{0xe0}
baseRoot = randomHash()
diffRoot = randomHash()
)
rawdb.WriteAccountSnapshot(db, accNoModNoCache, accNoModNoCache[:])
rawdb.WriteAccountSnapshot(db, accNoModCache, accNoModCache[:])
rawdb.WriteAccountSnapshot(db, accModNoCache, accModNoCache[:])
rawdb.WriteAccountSnapshot(db, accModCache, accModCache[:])
rawdb.WriteAccountSnapshot(db, accDelNoCache, accDelNoCache[:])
rawdb.WriteAccountSnapshot(db, accDelCache, accDelCache[:])
rawdb.WriteAccountSnapshot(db, conNoModNoCache, conNoModNoCache[:])
rawdb.WriteStorageSnapshot(db, conNoModNoCache, conNoModNoCacheSlot, conNoModNoCacheSlot[:])
rawdb.WriteAccountSnapshot(db, conNoModCache, conNoModCache[:])
rawdb.WriteStorageSnapshot(db, conNoModCache, conNoModCacheSlot, conNoModCacheSlot[:])
rawdb.WriteAccountSnapshot(db, conModNoCache, conModNoCache[:])
rawdb.WriteStorageSnapshot(db, conModNoCache, conModNoCacheSlot, conModNoCacheSlot[:])
rawdb.WriteAccountSnapshot(db, conModCache, conModCache[:])
rawdb.WriteStorageSnapshot(db, conModCache, conModCacheSlot, conModCacheSlot[:])
rawdb.WriteAccountSnapshot(db, conDelNoCache, conDelNoCache[:])
rawdb.WriteStorageSnapshot(db, conDelNoCache, conDelNoCacheSlot, conDelNoCacheSlot[:])
rawdb.WriteAccountSnapshot(db, conDelCache, conDelCache[:])
rawdb.WriteStorageSnapshot(db, conDelCache, conDelCacheSlot, conDelCacheSlot[:])
rawdb.WriteAccountSnapshot(db, conNukeNoCache, conNukeNoCache[:])
rawdb.WriteStorageSnapshot(db, conNukeNoCache, conNukeNoCacheSlot, conNukeNoCacheSlot[:])
rawdb.WriteAccountSnapshot(db, conNukeCache, conNukeCache[:])
rawdb.WriteStorageSnapshot(db, conNukeCache, conNukeCacheSlot, conNukeCacheSlot[:])
rawdb.WriteSnapshotRoot(db, baseRoot)
// Create a disk layer based on the above and cache in some data
snaps := &Tree{
layers: map[common.Hash]snapshot{
baseRoot: &diskLayer{
diskdb: db,
cache: fastcache.New(500 * 1024),
root: baseRoot,
},
},
}
base := snaps.Snapshot(baseRoot)
base.AccountRLP(accNoModCache)
base.AccountRLP(accModCache)
base.AccountRLP(accDelCache)
base.Storage(conNoModCache, conNoModCacheSlot)
base.Storage(conModCache, conModCacheSlot)
base.Storage(conDelCache, conDelCacheSlot)
base.Storage(conNukeCache, conNukeCacheSlot)
// Modify or delete some accounts, flatten everything onto disk
if err := snaps.Update(diffRoot, baseRoot, map[common.Hash]struct{}{
accDelNoCache: {},
accDelCache: {},
conNukeNoCache: {},
conNukeCache: {},
}, map[common.Hash][]byte{
accModNoCache: reverse(accModNoCache[:]),
accModCache: reverse(accModCache[:]),
}, map[common.Hash]map[common.Hash][]byte{
conModNoCache: {conModNoCacheSlot: reverse(conModNoCacheSlot[:])},
conModCache: {conModCacheSlot: reverse(conModCacheSlot[:])},
conDelNoCache: {conDelNoCacheSlot: nil},
conDelCache: {conDelCacheSlot: nil},
}); err != nil {
t.Fatalf("failed to update snapshot tree: %v", err)
}
if err := snaps.Cap(diffRoot, 0); err != nil {
t.Fatalf("failed to flatten snapshot tree: %v", err)
}
// Retrieve all the data through the disk layer and validate it
base = snaps.Snapshot(diffRoot)
if _, ok := base.(*diskLayer); !ok {
t.Fatalf("update not flattend into the disk layer")
}
// assertAccount ensures that an account matches the given blob.
assertAccount := func(account common.Hash, data []byte) {
t.Helper()
blob, err := base.AccountRLP(account)
if err != nil {
t.Errorf("account access (%x) failed: %v", account, err)
} else if !bytes.Equal(blob, data) {
t.Errorf("account access (%x) mismatch: have %x, want %x", account, blob, data)
}
}
assertAccount(accNoModNoCache, accNoModNoCache[:])
assertAccount(accNoModCache, accNoModCache[:])
assertAccount(accModNoCache, reverse(accModNoCache[:]))
assertAccount(accModCache, reverse(accModCache[:]))
assertAccount(accDelNoCache, nil)
assertAccount(accDelCache, nil)
// assertStorage ensures that a storage slot matches the given blob.
assertStorage := func(account common.Hash, slot common.Hash, data []byte) {
t.Helper()
blob, err := base.Storage(account, slot)
if err != nil {
t.Errorf("storage access (%x:%x) failed: %v", account, slot, err)
} else if !bytes.Equal(blob, data) {
t.Errorf("storage access (%x:%x) mismatch: have %x, want %x", account, slot, blob, data)
}
}
assertStorage(conNoModNoCache, conNoModNoCacheSlot, conNoModNoCacheSlot[:])
assertStorage(conNoModCache, conNoModCacheSlot, conNoModCacheSlot[:])
assertStorage(conModNoCache, conModNoCacheSlot, reverse(conModNoCacheSlot[:]))
assertStorage(conModCache, conModCacheSlot, reverse(conModCacheSlot[:]))
assertStorage(conDelNoCache, conDelNoCacheSlot, nil)
assertStorage(conDelCache, conDelCacheSlot, nil)
assertStorage(conNukeNoCache, conNukeNoCacheSlot, nil)
assertStorage(conNukeCache, conNukeCacheSlot, nil)
// Retrieve all the data directly from the database and validate it
// assertDatabaseAccount ensures that an account from the database matches the given blob.
assertDatabaseAccount := func(account common.Hash, data []byte) {
t.Helper()
if blob := rawdb.ReadAccountSnapshot(db, account); !bytes.Equal(blob, data) {
t.Errorf("account database access (%x) mismatch: have %x, want %x", account, blob, data)
}
}
assertDatabaseAccount(accNoModNoCache, accNoModNoCache[:])
assertDatabaseAccount(accNoModCache, accNoModCache[:])
assertDatabaseAccount(accModNoCache, reverse(accModNoCache[:]))
assertDatabaseAccount(accModCache, reverse(accModCache[:]))
assertDatabaseAccount(accDelNoCache, nil)
assertDatabaseAccount(accDelCache, nil)
// assertDatabaseStorage ensures that a storage slot from the database matches the given blob.
assertDatabaseStorage := func(account common.Hash, slot common.Hash, data []byte) {
t.Helper()
if blob := rawdb.ReadStorageSnapshot(db, account, slot); !bytes.Equal(blob, data) {
t.Errorf("storage database access (%x:%x) mismatch: have %x, want %x", account, slot, blob, data)
}
}
assertDatabaseStorage(conNoModNoCache, conNoModNoCacheSlot, conNoModNoCacheSlot[:])
assertDatabaseStorage(conNoModCache, conNoModCacheSlot, conNoModCacheSlot[:])
assertDatabaseStorage(conModNoCache, conModNoCacheSlot, reverse(conModNoCacheSlot[:]))
assertDatabaseStorage(conModCache, conModCacheSlot, reverse(conModCacheSlot[:]))
assertDatabaseStorage(conDelNoCache, conDelNoCacheSlot, nil)
assertDatabaseStorage(conDelCache, conDelCacheSlot, nil)
assertDatabaseStorage(conNukeNoCache, conNukeNoCacheSlot, nil)
assertDatabaseStorage(conNukeCache, conNukeCacheSlot, nil)
}
// Tests that merging something into a disk layer persists it into the database
// and invalidates any previously written and cached values, discarding anything
// after the in-progress generation marker.
func TestDiskPartialMerge(t *testing.T) {
// Iterate the test a few times to ensure we pick various internal orderings
// for the data slots as well as the progress marker.
for i := 0; i < 1024; i++ {
// Create some accounts in the disk layer
db := memorydb.New()
var (
accNoModNoCache = randomHash()
accNoModCache = randomHash()
accModNoCache = randomHash()
accModCache = randomHash()
accDelNoCache = randomHash()
accDelCache = randomHash()
conNoModNoCache = randomHash()
conNoModNoCacheSlot = randomHash()
conNoModCache = randomHash()
conNoModCacheSlot = randomHash()
conModNoCache = randomHash()
conModNoCacheSlot = randomHash()
conModCache = randomHash()
conModCacheSlot = randomHash()
conDelNoCache = randomHash()
conDelNoCacheSlot = randomHash()
conDelCache = randomHash()
conDelCacheSlot = randomHash()
conNukeNoCache = randomHash()
conNukeNoCacheSlot = randomHash()
conNukeCache = randomHash()
conNukeCacheSlot = randomHash()
baseRoot = randomHash()
diffRoot = randomHash()
genMarker = append(randomHash().Bytes(), randomHash().Bytes()...)
)
// insertAccount injects an account into the database if it's after the
// generator marker, drops the op otherwise. This is needed to seed the
// database with a valid starting snapshot.
insertAccount := func(account common.Hash, data []byte) {
if bytes.Compare(account[:], genMarker) <= 0 {
rawdb.WriteAccountSnapshot(db, account, data[:])
}
}
insertAccount(accNoModNoCache, accNoModNoCache[:])
insertAccount(accNoModCache, accNoModCache[:])
insertAccount(accModNoCache, accModNoCache[:])
insertAccount(accModCache, accModCache[:])
insertAccount(accDelNoCache, accDelNoCache[:])
insertAccount(accDelCache, accDelCache[:])
// insertStorage injects a storage slot into the database if it's after
// the generator marker, drops the op otherwise. This is needed to seed
// the database with a valid starting snapshot.
insertStorage := func(account common.Hash, slot common.Hash, data []byte) {
if bytes.Compare(append(account[:], slot[:]...), genMarker) <= 0 {
rawdb.WriteStorageSnapshot(db, account, slot, data[:])
}
}
insertAccount(conNoModNoCache, conNoModNoCache[:])
insertStorage(conNoModNoCache, conNoModNoCacheSlot, conNoModNoCacheSlot[:])
insertAccount(conNoModCache, conNoModCache[:])
insertStorage(conNoModCache, conNoModCacheSlot, conNoModCacheSlot[:])
insertAccount(conModNoCache, conModNoCache[:])
insertStorage(conModNoCache, conModNoCacheSlot, conModNoCacheSlot[:])
insertAccount(conModCache, conModCache[:])
insertStorage(conModCache, conModCacheSlot, conModCacheSlot[:])
insertAccount(conDelNoCache, conDelNoCache[:])
insertStorage(conDelNoCache, conDelNoCacheSlot, conDelNoCacheSlot[:])
insertAccount(conDelCache, conDelCache[:])
insertStorage(conDelCache, conDelCacheSlot, conDelCacheSlot[:])
insertAccount(conNukeNoCache, conNukeNoCache[:])
insertStorage(conNukeNoCache, conNukeNoCacheSlot, conNukeNoCacheSlot[:])
insertAccount(conNukeCache, conNukeCache[:])
insertStorage(conNukeCache, conNukeCacheSlot, conNukeCacheSlot[:])
rawdb.WriteSnapshotRoot(db, baseRoot)
// Create a disk layer based on the above using a random progress marker
// and cache in some data.
snaps := &Tree{
layers: map[common.Hash]snapshot{
baseRoot: &diskLayer{
diskdb: db,
cache: fastcache.New(500 * 1024),
root: baseRoot,
},
},
}
snaps.layers[baseRoot].(*diskLayer).genMarker = genMarker
base := snaps.Snapshot(baseRoot)
// assertAccount ensures that an account matches the given blob if it's
// already covered by the disk snapshot, and errors out otherwise.
assertAccount := func(account common.Hash, data []byte) {
t.Helper()
blob, err := base.AccountRLP(account)
if bytes.Compare(account[:], genMarker) > 0 && err != ErrNotCoveredYet {
t.Fatalf("test %d: post-marker (%x) account access (%x) succeeded: %x", i, genMarker, account, blob)
}
if bytes.Compare(account[:], genMarker) <= 0 && !bytes.Equal(blob, data) {
t.Fatalf("test %d: pre-marker (%x) account access (%x) mismatch: have %x, want %x", i, genMarker, account, blob, data)
}
}
assertAccount(accNoModCache, accNoModCache[:])
assertAccount(accModCache, accModCache[:])
assertAccount(accDelCache, accDelCache[:])
// assertStorage ensures that a storage slot matches the given blob if
// it's already covered by the disk snapshot, and errors out otherwise.
assertStorage := func(account common.Hash, slot common.Hash, data []byte) {
t.Helper()
blob, err := base.Storage(account, slot)
if bytes.Compare(append(account[:], slot[:]...), genMarker) > 0 && err != ErrNotCoveredYet {
t.Fatalf("test %d: post-marker (%x) storage access (%x:%x) succeeded: %x", i, genMarker, account, slot, blob)
}
if bytes.Compare(append(account[:], slot[:]...), genMarker) <= 0 && !bytes.Equal(blob, data) {
t.Fatalf("test %d: pre-marker (%x) storage access (%x:%x) mismatch: have %x, want %x", i, genMarker, account, slot, blob, data)
}
}
assertStorage(conNoModCache, conNoModCacheSlot, conNoModCacheSlot[:])
assertStorage(conModCache, conModCacheSlot, conModCacheSlot[:])
assertStorage(conDelCache, conDelCacheSlot, conDelCacheSlot[:])
assertStorage(conNukeCache, conNukeCacheSlot, conNukeCacheSlot[:])
// Modify or delete some accounts, flatten everything onto disk
if err := snaps.Update(diffRoot, baseRoot, map[common.Hash]struct{}{
accDelNoCache: {},
accDelCache: {},
conNukeNoCache: {},
conNukeCache: {},
}, map[common.Hash][]byte{
accModNoCache: reverse(accModNoCache[:]),
accModCache: reverse(accModCache[:]),
}, map[common.Hash]map[common.Hash][]byte{
conModNoCache: {conModNoCacheSlot: reverse(conModNoCacheSlot[:])},
conModCache: {conModCacheSlot: reverse(conModCacheSlot[:])},
conDelNoCache: {conDelNoCacheSlot: nil},
conDelCache: {conDelCacheSlot: nil},
}); err != nil {
t.Fatalf("test %d: failed to update snapshot tree: %v", i, err)
}
if err := snaps.Cap(diffRoot, 0); err != nil {
t.Fatalf("test %d: failed to flatten snapshot tree: %v", i, err)
}
// Retrieve all the data through the disk layer and validate it
base = snaps.Snapshot(diffRoot)
if _, ok := base.(*diskLayer); !ok {
t.Fatalf("test %d: update not flattend into the disk layer", i)
}
assertAccount(accNoModNoCache, accNoModNoCache[:])
assertAccount(accNoModCache, accNoModCache[:])
assertAccount(accModNoCache, reverse(accModNoCache[:]))
assertAccount(accModCache, reverse(accModCache[:]))
assertAccount(accDelNoCache, nil)
assertAccount(accDelCache, nil)
assertStorage(conNoModNoCache, conNoModNoCacheSlot, conNoModNoCacheSlot[:])
assertStorage(conNoModCache, conNoModCacheSlot, conNoModCacheSlot[:])
assertStorage(conModNoCache, conModNoCacheSlot, reverse(conModNoCacheSlot[:]))
assertStorage(conModCache, conModCacheSlot, reverse(conModCacheSlot[:]))
assertStorage(conDelNoCache, conDelNoCacheSlot, nil)
assertStorage(conDelCache, conDelCacheSlot, nil)
assertStorage(conNukeNoCache, conNukeNoCacheSlot, nil)
assertStorage(conNukeCache, conNukeCacheSlot, nil)
// Retrieve all the data directly from the database and validate it
// assertDatabaseAccount ensures that an account inside the database matches
// the given blob if it's already covered by the disk snapshot, and does not
// exist otherwise.
assertDatabaseAccount := func(account common.Hash, data []byte) {
t.Helper()
blob := rawdb.ReadAccountSnapshot(db, account)
if bytes.Compare(account[:], genMarker) > 0 && blob != nil {
t.Fatalf("test %d: post-marker (%x) account database access (%x) succeeded: %x", i, genMarker, account, blob)
}
if bytes.Compare(account[:], genMarker) <= 0 && !bytes.Equal(blob, data) {
t.Fatalf("test %d: pre-marker (%x) account database access (%x) mismatch: have %x, want %x", i, genMarker, account, blob, data)
}
}
assertDatabaseAccount(accNoModNoCache, accNoModNoCache[:])
assertDatabaseAccount(accNoModCache, accNoModCache[:])
assertDatabaseAccount(accModNoCache, reverse(accModNoCache[:]))
assertDatabaseAccount(accModCache, reverse(accModCache[:]))
assertDatabaseAccount(accDelNoCache, nil)
assertDatabaseAccount(accDelCache, nil)
// assertDatabaseStorage ensures that a storage slot inside the database
// matches the given blob if it's already covered by the disk snapshot,
// and does not exist otherwise.
assertDatabaseStorage := func(account common.Hash, slot common.Hash, data []byte) {
t.Helper()
blob := rawdb.ReadStorageSnapshot(db, account, slot)
if bytes.Compare(append(account[:], slot[:]...), genMarker) > 0 && blob != nil {
t.Fatalf("test %d: post-marker (%x) storage database access (%x:%x) succeeded: %x", i, genMarker, account, slot, blob)
}
if bytes.Compare(append(account[:], slot[:]...), genMarker) <= 0 && !bytes.Equal(blob, data) {
t.Fatalf("test %d: pre-marker (%x) storage database access (%x:%x) mismatch: have %x, want %x", i, genMarker, account, slot, blob, data)
}
}
assertDatabaseStorage(conNoModNoCache, conNoModNoCacheSlot, conNoModNoCacheSlot[:])
assertDatabaseStorage(conNoModCache, conNoModCacheSlot, conNoModCacheSlot[:])
assertDatabaseStorage(conModNoCache, conModNoCacheSlot, reverse(conModNoCacheSlot[:]))
assertDatabaseStorage(conModCache, conModCacheSlot, reverse(conModCacheSlot[:]))
assertDatabaseStorage(conDelNoCache, conDelNoCacheSlot, nil)
assertDatabaseStorage(conDelCache, conDelCacheSlot, nil)
assertDatabaseStorage(conNukeNoCache, conNukeNoCacheSlot, nil)
assertDatabaseStorage(conNukeCache, conNukeCacheSlot, nil)
}
}
// Tests that when the bottom-most diff layer is merged into the disk
// layer whether the corresponding generator is persisted correctly.
func TestDiskGeneratorPersistence(t *testing.T) {
var (
accOne = randomHash()
accTwo = randomHash()
accOneSlotOne = randomHash()
accOneSlotTwo = randomHash()
accThree = randomHash()
accThreeSlot = randomHash()
baseRoot = randomHash()
diffRoot = randomHash()
diffTwoRoot = randomHash()
genMarker = append(randomHash().Bytes(), randomHash().Bytes()...)
)
// Testing scenario 1, the disk layer is still under the construction.
db := rawdb.NewMemoryDatabase()
rawdb.WriteAccountSnapshot(db, accOne, accOne[:])
rawdb.WriteStorageSnapshot(db, accOne, accOneSlotOne, accOneSlotOne[:])
rawdb.WriteStorageSnapshot(db, accOne, accOneSlotTwo, accOneSlotTwo[:])
rawdb.WriteSnapshotRoot(db, baseRoot)
// Create a disk layer based on all above updates
snaps := &Tree{
layers: map[common.Hash]snapshot{
baseRoot: &diskLayer{
diskdb: db,
cache: fastcache.New(500 * 1024),
root: baseRoot,
genMarker: genMarker,
},
},
}
// Modify or delete some accounts, flatten everything onto disk
if err := snaps.Update(diffRoot, baseRoot, nil, map[common.Hash][]byte{
accTwo: accTwo[:],
}, nil); err != nil {
t.Fatalf("failed to update snapshot tree: %v", err)
}
if err := snaps.Cap(diffRoot, 0); err != nil {
t.Fatalf("failed to flatten snapshot tree: %v", err)
}
blob := rawdb.ReadSnapshotGenerator(db)
var generator journalGenerator
if err := rlp.DecodeBytes(blob, &generator); err != nil {
t.Fatalf("Failed to decode snapshot generator %v", err)
}
if !bytes.Equal(generator.Marker, genMarker) {
t.Fatalf("Generator marker is not matched")
}
// Test scenario 2, the disk layer is fully generated
// Modify or delete some accounts, flatten everything onto disk
if err := snaps.Update(diffTwoRoot, diffRoot, nil, map[common.Hash][]byte{
accThree: accThree.Bytes(),
}, map[common.Hash]map[common.Hash][]byte{
accThree: {accThreeSlot: accThreeSlot.Bytes()},
}); err != nil {
t.Fatalf("failed to update snapshot tree: %v", err)
}
diskLayer := snaps.layers[snaps.diskRoot()].(*diskLayer)
diskLayer.genMarker = nil // Construction finished
if err := snaps.Cap(diffTwoRoot, 0); err != nil {
t.Fatalf("failed to flatten snapshot tree: %v", err)
}
blob = rawdb.ReadSnapshotGenerator(db)
if err := rlp.DecodeBytes(blob, &generator); err != nil {
t.Fatalf("Failed to decode snapshot generator %v", err)
}
if len(generator.Marker) != 0 {
t.Fatalf("Failed to update snapshot generator")
}
}
// Tests that merging something into a disk layer persists it into the database
// and invalidates any previously written and cached values, discarding anything
// after the in-progress generation marker.
//
// This test case is a tiny specialized case of TestDiskPartialMerge, which tests
// some very specific cornercases that random tests won't ever trigger.
func TestDiskMidAccountPartialMerge(t *testing.T) {
// TODO(@karalabe) ?
}
// TestDiskSeek tests that seek-operations work on the disk layer
func TestDiskSeek(t *testing.T) {
// Create some accounts in the disk layer
diskdb, err := leveldb.New(t.TempDir(), 256, 0, "", false)
if err != nil {
t.Fatal(err)
}
db := rawdb.NewDatabase(diskdb)
defer db.Close()
// Fill even keys [0,2,4...]
for i := 0; i < 0xff; i += 2 {
acc := common.Hash{byte(i)}
rawdb.WriteAccountSnapshot(db, acc, acc[:])
}
// Add an 'higher' key, with incorrect (higher) prefix
highKey := []byte{rawdb.SnapshotAccountPrefix[0] + 1}
db.Put(highKey, []byte{0xff, 0xff})
baseRoot := randomHash()
rawdb.WriteSnapshotRoot(db, baseRoot)
snaps := &Tree{
layers: map[common.Hash]snapshot{
baseRoot: &diskLayer{
diskdb: db,
cache: fastcache.New(500 * 1024),
root: baseRoot,
},
},
}
// Test some different seek positions
type testcase struct {
pos byte
expkey byte
}
var cases = []testcase{
{0xff, 0x55}, // this should exit immediately without checking key
{0x01, 0x02},
{0xfe, 0xfe},
{0xfd, 0xfe},
{0x00, 0x00},
}
for i, tc := range cases {
it, err := snaps.AccountIterator(baseRoot, common.Hash{tc.pos})
if err != nil {
t.Fatalf("case %d, error: %v", i, err)
}
count := 0
for it.Next() {
k, v, err := it.Hash()[0], it.Account()[0], it.Error()
if err != nil {
t.Fatalf("test %d, item %d, error: %v", i, count, err)
}
// First item in iterator should have the expected key
if count == 0 && k != tc.expkey {
t.Fatalf("test %d, item %d, got %v exp %v", i, count, k, tc.expkey)
}
count++
if v != k {
t.Fatalf("test %d, item %d, value wrong, got %v exp %v", i, count, v, k)
}
}
}
}