op-geth/core/state/snapshot/disklayer_test.go

588 lines
24 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"
"io/ioutil"
"os"
"testing"
"github.com/VictoriaMetrics/fastcache"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core/rawdb"
"github.com/ethereum/go-ethereum/ethdb"
"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
var db ethdb.Database
if dir, err := ioutil.TempDir("", "disklayer-test"); err != nil {
t.Fatal(err)
} else {
defer os.RemoveAll(dir)
diskdb, err := leveldb.New(dir, 256, 0, "", false)
if err != nil {
t.Fatal(err)
}
db = rawdb.NewDatabase(diskdb)
}
// 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)
}
}
}
}