// Copyright 2015 The etcd Authors // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package mvcc import ( "bytes" "crypto/rand" "encoding/binary" "fmt" "math" mrand "math/rand" "os" "reflect" "sort" "strconv" "sync" "testing" "time" "go.etcd.io/etcd/api/v3/mvccpb" "go.etcd.io/etcd/pkg/v3/schedule" "go.etcd.io/etcd/pkg/v3/testutil" "go.etcd.io/etcd/pkg/v3/traceutil" "go.etcd.io/etcd/v3/lease" "go.etcd.io/etcd/v3/mvcc/backend" "go.uber.org/zap" ) func TestStoreRev(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) defer s.Close() defer os.Remove(tmpPath) for i := 1; i <= 3; i++ { s.Put([]byte("foo"), []byte("bar"), lease.NoLease) if r := s.Rev(); r != int64(i+1) { t.Errorf("#%d: rev = %d, want %d", i, r, i+1) } } } func TestStorePut(t *testing.T) { kv := mvccpb.KeyValue{ Key: []byte("foo"), Value: []byte("bar"), CreateRevision: 1, ModRevision: 2, Version: 1, } kvb, err := kv.Marshal() if err != nil { t.Fatal(err) } tests := []struct { rev revision r indexGetResp rr *rangeResp wrev revision wkey []byte wkv mvccpb.KeyValue wputrev revision }{ { revision{1, 0}, indexGetResp{revision{}, revision{}, 0, ErrRevisionNotFound}, nil, revision{2, 0}, newTestKeyBytes(revision{2, 0}, false), mvccpb.KeyValue{ Key: []byte("foo"), Value: []byte("bar"), CreateRevision: 2, ModRevision: 2, Version: 1, Lease: 1, }, revision{2, 0}, }, { revision{1, 1}, indexGetResp{revision{2, 0}, revision{2, 0}, 1, nil}, &rangeResp{[][]byte{newTestKeyBytes(revision{2, 1}, false)}, [][]byte{kvb}}, revision{2, 0}, newTestKeyBytes(revision{2, 0}, false), mvccpb.KeyValue{ Key: []byte("foo"), Value: []byte("bar"), CreateRevision: 2, ModRevision: 2, Version: 2, Lease: 2, }, revision{2, 0}, }, { revision{2, 0}, indexGetResp{revision{2, 1}, revision{2, 0}, 2, nil}, &rangeResp{[][]byte{newTestKeyBytes(revision{2, 1}, false)}, [][]byte{kvb}}, revision{3, 0}, newTestKeyBytes(revision{3, 0}, false), mvccpb.KeyValue{ Key: []byte("foo"), Value: []byte("bar"), CreateRevision: 2, ModRevision: 3, Version: 3, Lease: 3, }, revision{3, 0}, }, } for i, tt := range tests { s := newFakeStore() b := s.b.(*fakeBackend) fi := s.kvindex.(*fakeIndex) s.currentRev = tt.rev.main fi.indexGetRespc <- tt.r if tt.rr != nil { b.tx.rangeRespc <- *tt.rr } s.Put([]byte("foo"), []byte("bar"), lease.LeaseID(i+1)) data, err := tt.wkv.Marshal() if err != nil { t.Errorf("#%d: marshal err = %v, want nil", i, err) } wact := []testutil.Action{ {Name: "seqput", Params: []interface{}{keyBucketName, tt.wkey, data}}, } if tt.rr != nil { wact = []testutil.Action{ {Name: "seqput", Params: []interface{}{keyBucketName, tt.wkey, data}}, } } if g := b.tx.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("#%d: tx action = %+v, want %+v", i, g, wact) } wact = []testutil.Action{ {Name: "get", Params: []interface{}{[]byte("foo"), tt.wputrev.main}}, {Name: "put", Params: []interface{}{[]byte("foo"), tt.wputrev}}, } if g := fi.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("#%d: index action = %+v, want %+v", i, g, wact) } if s.currentRev != tt.wrev.main { t.Errorf("#%d: rev = %+v, want %+v", i, s.currentRev, tt.wrev) } s.Close() } } func TestStoreRange(t *testing.T) { key := newTestKeyBytes(revision{2, 0}, false) kv := mvccpb.KeyValue{ Key: []byte("foo"), Value: []byte("bar"), CreateRevision: 1, ModRevision: 2, Version: 1, } kvb, err := kv.Marshal() if err != nil { t.Fatal(err) } wrev := int64(2) tests := []struct { idxr indexRangeResp r rangeResp }{ { indexRangeResp{[][]byte{[]byte("foo")}, []revision{{2, 0}}}, rangeResp{[][]byte{key}, [][]byte{kvb}}, }, { indexRangeResp{[][]byte{[]byte("foo"), []byte("foo1")}, []revision{{2, 0}, {3, 0}}}, rangeResp{[][]byte{key}, [][]byte{kvb}}, }, } ro := RangeOptions{Limit: 1, Rev: 0, Count: false} for i, tt := range tests { s := newFakeStore() b := s.b.(*fakeBackend) fi := s.kvindex.(*fakeIndex) s.currentRev = 2 b.tx.rangeRespc <- tt.r fi.indexRangeRespc <- tt.idxr ret, err := s.Range([]byte("foo"), []byte("goo"), ro) if err != nil { t.Errorf("#%d: err = %v, want nil", i, err) } if w := []mvccpb.KeyValue{kv}; !reflect.DeepEqual(ret.KVs, w) { t.Errorf("#%d: kvs = %+v, want %+v", i, ret.KVs, w) } if ret.Rev != wrev { t.Errorf("#%d: rev = %d, want %d", i, ret.Rev, wrev) } wstart := newRevBytes() revToBytes(tt.idxr.revs[0], wstart) wact := []testutil.Action{ {Name: "range", Params: []interface{}{keyBucketName, wstart, []byte(nil), int64(0)}}, } if g := b.tx.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("#%d: tx action = %+v, want %+v", i, g, wact) } wact = []testutil.Action{ {Name: "range", Params: []interface{}{[]byte("foo"), []byte("goo"), wrev}}, } if g := fi.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("#%d: index action = %+v, want %+v", i, g, wact) } if s.currentRev != 2 { t.Errorf("#%d: current rev = %+v, want %+v", i, s.currentRev, 2) } s.Close() } } func TestStoreDeleteRange(t *testing.T) { key := newTestKeyBytes(revision{2, 0}, false) kv := mvccpb.KeyValue{ Key: []byte("foo"), Value: []byte("bar"), CreateRevision: 1, ModRevision: 2, Version: 1, } kvb, err := kv.Marshal() if err != nil { t.Fatal(err) } tests := []struct { rev revision r indexRangeResp rr rangeResp wkey []byte wrev revision wrrev int64 wdelrev revision }{ { revision{2, 0}, indexRangeResp{[][]byte{[]byte("foo")}, []revision{{2, 0}}}, rangeResp{[][]byte{key}, [][]byte{kvb}}, newTestKeyBytes(revision{3, 0}, true), revision{3, 0}, 2, revision{3, 0}, }, } for i, tt := range tests { s := newFakeStore() b := s.b.(*fakeBackend) fi := s.kvindex.(*fakeIndex) s.currentRev = tt.rev.main fi.indexRangeRespc <- tt.r b.tx.rangeRespc <- tt.rr n, _ := s.DeleteRange([]byte("foo"), []byte("goo")) if n != 1 { t.Errorf("#%d: n = %d, want 1", i, n) } data, err := (&mvccpb.KeyValue{ Key: []byte("foo"), }).Marshal() if err != nil { t.Errorf("#%d: marshal err = %v, want nil", i, err) } wact := []testutil.Action{ {Name: "seqput", Params: []interface{}{keyBucketName, tt.wkey, data}}, } if g := b.tx.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("#%d: tx action = %+v, want %+v", i, g, wact) } wact = []testutil.Action{ {Name: "range", Params: []interface{}{[]byte("foo"), []byte("goo"), tt.wrrev}}, {Name: "tombstone", Params: []interface{}{[]byte("foo"), tt.wdelrev}}, } if g := fi.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("#%d: index action = %+v, want %+v", i, g, wact) } if s.currentRev != tt.wrev.main { t.Errorf("#%d: rev = %+v, want %+v", i, s.currentRev, tt.wrev) } } } func TestStoreCompact(t *testing.T) { s := newFakeStore() defer s.Close() b := s.b.(*fakeBackend) fi := s.kvindex.(*fakeIndex) s.currentRev = 3 fi.indexCompactRespc <- map[revision]struct{}{{1, 0}: {}} key1 := newTestKeyBytes(revision{1, 0}, false) key2 := newTestKeyBytes(revision{2, 0}, false) b.tx.rangeRespc <- rangeResp{[][]byte{key1, key2}, nil} s.Compact(traceutil.TODO(), 3) s.fifoSched.WaitFinish(1) if s.compactMainRev != 3 { t.Errorf("compact main rev = %d, want 3", s.compactMainRev) } end := make([]byte, 8) binary.BigEndian.PutUint64(end, uint64(4)) wact := []testutil.Action{ {Name: "put", Params: []interface{}{metaBucketName, scheduledCompactKeyName, newTestRevBytes(revision{3, 0})}}, {Name: "range", Params: []interface{}{keyBucketName, make([]byte, 17), end, int64(10000)}}, {Name: "delete", Params: []interface{}{keyBucketName, key2}}, {Name: "put", Params: []interface{}{metaBucketName, finishedCompactKeyName, newTestRevBytes(revision{3, 0})}}, } if g := b.tx.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("tx actions = %+v, want %+v", g, wact) } wact = []testutil.Action{ {Name: "compact", Params: []interface{}{int64(3)}}, } if g := fi.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("index action = %+v, want %+v", g, wact) } } func TestStoreRestore(t *testing.T) { s := newFakeStore() b := s.b.(*fakeBackend) fi := s.kvindex.(*fakeIndex) putkey := newTestKeyBytes(revision{3, 0}, false) putkv := mvccpb.KeyValue{ Key: []byte("foo"), Value: []byte("bar"), CreateRevision: 4, ModRevision: 4, Version: 1, } putkvb, err := putkv.Marshal() if err != nil { t.Fatal(err) } delkey := newTestKeyBytes(revision{5, 0}, true) delkv := mvccpb.KeyValue{ Key: []byte("foo"), } delkvb, err := delkv.Marshal() if err != nil { t.Fatal(err) } b.tx.rangeRespc <- rangeResp{[][]byte{finishedCompactKeyName}, [][]byte{newTestRevBytes(revision{3, 0})}} b.tx.rangeRespc <- rangeResp{[][]byte{scheduledCompactKeyName}, [][]byte{newTestRevBytes(revision{3, 0})}} b.tx.rangeRespc <- rangeResp{[][]byte{putkey, delkey}, [][]byte{putkvb, delkvb}} b.tx.rangeRespc <- rangeResp{nil, nil} s.restore() if s.compactMainRev != 3 { t.Errorf("compact rev = %d, want 3", s.compactMainRev) } if s.currentRev != 5 { t.Errorf("current rev = %v, want 5", s.currentRev) } wact := []testutil.Action{ {Name: "range", Params: []interface{}{metaBucketName, finishedCompactKeyName, []byte(nil), int64(0)}}, {Name: "range", Params: []interface{}{metaBucketName, scheduledCompactKeyName, []byte(nil), int64(0)}}, {Name: "range", Params: []interface{}{keyBucketName, newTestRevBytes(revision{1, 0}), newTestRevBytes(revision{math.MaxInt64, math.MaxInt64}), int64(restoreChunkKeys)}}, } if g := b.tx.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("tx actions = %+v, want %+v", g, wact) } gens := []generation{ {created: revision{4, 0}, ver: 2, revs: []revision{{3, 0}, {5, 0}}}, {created: revision{0, 0}, ver: 0, revs: nil}, } ki := &keyIndex{key: []byte("foo"), modified: revision{5, 0}, generations: gens} wact = []testutil.Action{ {Name: "keyIndex", Params: []interface{}{ki}}, {Name: "insert", Params: []interface{}{ki}}, } if g := fi.Action(); !reflect.DeepEqual(g, wact) { t.Errorf("index action = %+v, want %+v", g, wact) } } func TestRestoreDelete(t *testing.T) { oldChunk := restoreChunkKeys restoreChunkKeys = mrand.Intn(3) + 2 defer func() { restoreChunkKeys = oldChunk }() b, tmpPath := backend.NewDefaultTmpBackend() s := NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) defer os.Remove(tmpPath) keys := make(map[string]struct{}) for i := 0; i < 20; i++ { ks := fmt.Sprintf("foo-%d", i) k := []byte(ks) s.Put(k, []byte("bar"), lease.NoLease) keys[ks] = struct{}{} switch mrand.Intn(3) { case 0: // put random key from past via random range on map ks = fmt.Sprintf("foo-%d", mrand.Intn(i+1)) s.Put([]byte(ks), []byte("baz"), lease.NoLease) keys[ks] = struct{}{} case 1: // delete random key via random range on map for k := range keys { s.DeleteRange([]byte(k), nil) delete(keys, k) break } } } s.Close() s = NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) defer s.Close() for i := 0; i < 20; i++ { ks := fmt.Sprintf("foo-%d", i) r, err := s.Range([]byte(ks), nil, RangeOptions{}) if err != nil { t.Fatal(err) } if _, ok := keys[ks]; ok { if len(r.KVs) == 0 { t.Errorf("#%d: expected %q, got deleted", i, ks) } } else if len(r.KVs) != 0 { t.Errorf("#%d: expected deleted, got %q", i, ks) } } } func TestRestoreContinueUnfinishedCompaction(t *testing.T) { tests := []string{"recreate", "restore"} for _, test := range tests { b, tmpPath := backend.NewDefaultTmpBackend() s0 := NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) defer os.Remove(tmpPath) s0.Put([]byte("foo"), []byte("bar"), lease.NoLease) s0.Put([]byte("foo"), []byte("bar1"), lease.NoLease) s0.Put([]byte("foo"), []byte("bar2"), lease.NoLease) // write scheduled compaction, but not do compaction rbytes := newRevBytes() revToBytes(revision{main: 2}, rbytes) tx := s0.b.BatchTx() tx.Lock() tx.UnsafePut(metaBucketName, scheduledCompactKeyName, rbytes) tx.Unlock() s0.Close() var s *store switch test { case "recreate": s = NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) case "restore": s0.Restore(b) s = s0 } // wait for scheduled compaction to be finished time.Sleep(100 * time.Millisecond) if _, err := s.Range([]byte("foo"), nil, RangeOptions{Rev: 1}); err != ErrCompacted { t.Errorf("range on compacted rev error = %v, want %v", err, ErrCompacted) } // check the key in backend is deleted revbytes := newRevBytes() revToBytes(revision{main: 1}, revbytes) // The disk compaction is done asynchronously and requires more time on slow disk. // try 5 times for CI with slow IO. for i := 0; i < 5; i++ { tx = s.b.BatchTx() tx.Lock() ks, _ := tx.UnsafeRange(keyBucketName, revbytes, nil, 0) tx.Unlock() if len(ks) != 0 { time.Sleep(100 * time.Millisecond) continue } return } t.Errorf("key for rev %+v still exists, want deleted", bytesToRev(revbytes)) } } type hashKVResult struct { hash uint32 compactRev int64 } // TestHashKVWhenCompacting ensures that HashKV returns correct hash when compacting. func TestHashKVWhenCompacting(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) defer os.Remove(tmpPath) rev := 10000 for i := 2; i <= rev; i++ { s.Put([]byte("foo"), []byte(fmt.Sprintf("bar%d", i)), lease.NoLease) } hashCompactc := make(chan hashKVResult, 1) donec := make(chan struct{}) var wg sync.WaitGroup for i := 0; i < 10; i++ { wg.Add(1) go func() { defer wg.Done() for { hash, _, compactRev, err := s.HashByRev(int64(rev)) if err != nil { t.Error(err) } select { case <-donec: return case hashCompactc <- hashKVResult{hash, compactRev}: } } }() } go func() { defer close(donec) revHash := make(map[int64]uint32) for round := 0; round < 1000; round++ { r := <-hashCompactc if revHash[r.compactRev] == 0 { revHash[r.compactRev] = r.hash } if r.hash != revHash[r.compactRev] { t.Errorf("Hashes differ (current %v) != (saved %v)", r.hash, revHash[r.compactRev]) } } }() wg.Add(1) go func() { defer wg.Done() for i := 100; i >= 0; i-- { _, err := s.Compact(traceutil.TODO(), int64(rev-1-i)) if err != nil { t.Error(err) } time.Sleep(10 * time.Millisecond) } }() select { case <-donec: wg.Wait() case <-time.After(10 * time.Second): testutil.FatalStack(t, "timeout") } } // TestHashKVZeroRevision ensures that "HashByRev(0)" computes // correct hash value with latest revision. func TestHashKVZeroRevision(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) defer os.Remove(tmpPath) rev := 10000 for i := 2; i <= rev; i++ { s.Put([]byte("foo"), []byte(fmt.Sprintf("bar%d", i)), lease.NoLease) } if _, err := s.Compact(traceutil.TODO(), int64(rev/2)); err != nil { t.Fatal(err) } hash1, _, _, err := s.HashByRev(int64(rev)) if err != nil { t.Fatal(err) } var hash2 uint32 hash2, _, _, err = s.HashByRev(0) if err != nil { t.Fatal(err) } if hash1 != hash2 { t.Errorf("hash %d (rev %d) != hash %d (rev 0)", hash1, rev, hash2) } } func TestTxnPut(t *testing.T) { // assign arbitrary size bytesN := 30 sliceN := 100 keys := createBytesSlice(bytesN, sliceN) vals := createBytesSlice(bytesN, sliceN) b, tmpPath := backend.NewDefaultTmpBackend() s := NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) defer cleanup(s, b, tmpPath) for i := 0; i < sliceN; i++ { txn := s.Write(traceutil.TODO()) base := int64(i + 2) if rev := txn.Put(keys[i], vals[i], lease.NoLease); rev != base { t.Errorf("#%d: rev = %d, want %d", i, rev, base) } txn.End() } } // TestConcurrentReadNotBlockingWrite ensures Read does not blocking Write after its creation func TestConcurrentReadNotBlockingWrite(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) defer os.Remove(tmpPath) // write something to read later s.Put([]byte("foo"), []byte("bar"), lease.NoLease) // readTx simulates a long read request readTx1 := s.Read(traceutil.TODO()) // write should not be blocked by reads done := make(chan struct{}, 1) go func() { s.Put([]byte("foo"), []byte("newBar"), lease.NoLease) // this is a write Txn done <- struct{}{} }() select { case <-done: case <-time.After(1 * time.Second): t.Fatalf("write should not be blocked by read") } // readTx2 simulates a short read request readTx2 := s.Read(traceutil.TODO()) ro := RangeOptions{Limit: 1, Rev: 0, Count: false} ret, err := readTx2.Range([]byte("foo"), nil, ro) if err != nil { t.Fatalf("failed to range: %v", err) } // readTx2 should see the result of new write w := mvccpb.KeyValue{ Key: []byte("foo"), Value: []byte("newBar"), CreateRevision: 2, ModRevision: 3, Version: 2, } if !reflect.DeepEqual(ret.KVs[0], w) { t.Fatalf("range result = %+v, want = %+v", ret.KVs[0], w) } readTx2.End() ret, err = readTx1.Range([]byte("foo"), nil, ro) if err != nil { t.Fatalf("failed to range: %v", err) } // readTx1 should not see the result of new write w = mvccpb.KeyValue{ Key: []byte("foo"), Value: []byte("bar"), CreateRevision: 2, ModRevision: 2, Version: 1, } if !reflect.DeepEqual(ret.KVs[0], w) { t.Fatalf("range result = %+v, want = %+v", ret.KVs[0], w) } readTx1.End() } // TestConcurrentReadTxAndWrite creates random concurrent Reads and Writes, and ensures Reads always see latest Writes func TestConcurrentReadTxAndWrite(t *testing.T) { var ( numOfReads = 100 numOfWrites = 100 maxNumOfPutsPerWrite = 10 committedKVs kvs // committedKVs records the key-value pairs written by the finished Write Txns mu sync.Mutex // mu protects committedKVs ) b, tmpPath := backend.NewDefaultTmpBackend() s := NewStore(zap.NewExample(), b, &lease.FakeLessor{}, nil, StoreConfig{}) defer os.Remove(tmpPath) var wg sync.WaitGroup wg.Add(numOfWrites) for i := 0; i < numOfWrites; i++ { go func() { defer wg.Done() time.Sleep(time.Duration(mrand.Intn(100)) * time.Millisecond) // random starting time tx := s.Write(traceutil.TODO()) numOfPuts := mrand.Intn(maxNumOfPutsPerWrite) + 1 var pendingKvs kvs for j := 0; j < numOfPuts; j++ { k := []byte(strconv.Itoa(mrand.Int())) v := []byte(strconv.Itoa(mrand.Int())) tx.Put(k, v, lease.NoLease) pendingKvs = append(pendingKvs, kv{k, v}) } // reads should not see above Puts until write is finished mu.Lock() committedKVs = merge(committedKVs, pendingKvs) // update shared data structure tx.End() mu.Unlock() }() } wg.Add(numOfReads) for i := 0; i < numOfReads; i++ { go func() { defer wg.Done() time.Sleep(time.Duration(mrand.Intn(100)) * time.Millisecond) // random starting time mu.Lock() wKVs := make(kvs, len(committedKVs)) copy(wKVs, committedKVs) tx := s.Read(traceutil.TODO()) mu.Unlock() // get all keys in backend store, and compare with wKVs ret, err := tx.Range([]byte("\x00000000"), []byte("\xffffffff"), RangeOptions{}) tx.End() if err != nil { t.Errorf("failed to range keys: %v", err) return } if len(wKVs) == 0 && len(ret.KVs) == 0 { // no committed KVs yet return } var result kvs for _, keyValue := range ret.KVs { result = append(result, kv{keyValue.Key, keyValue.Value}) } if !reflect.DeepEqual(wKVs, result) { t.Errorf("unexpected range result") // too many key value pairs, skip printing them } }() } // wait until goroutines finish or timeout doneC := make(chan struct{}) go func() { wg.Wait() close(doneC) }() select { case <-doneC: case <-time.After(5 * time.Minute): testutil.FatalStack(t, "timeout") } } type kv struct { key []byte val []byte } type kvs []kv func (kvs kvs) Len() int { return len(kvs) } func (kvs kvs) Less(i, j int) bool { return bytes.Compare(kvs[i].key, kvs[j].key) < 0 } func (kvs kvs) Swap(i, j int) { kvs[i], kvs[j] = kvs[j], kvs[i] } func merge(dst, src kvs) kvs { dst = append(dst, src...) sort.Stable(dst) // remove duplicates, using only the newest value // ref: tx_buffer.go widx := 0 for ridx := 1; ridx < len(dst); ridx++ { if !bytes.Equal(dst[widx].key, dst[ridx].key) { widx++ } dst[widx] = dst[ridx] } return dst[:widx+1] } // TODO: test attach key to lessor func newTestRevBytes(rev revision) []byte { bytes := newRevBytes() revToBytes(rev, bytes) return bytes } func newTestKeyBytes(rev revision, tombstone bool) []byte { bytes := newRevBytes() revToBytes(rev, bytes) if tombstone { bytes = appendMarkTombstone(zap.NewExample(), bytes) } return bytes } func newFakeStore() *store { b := &fakeBackend{&fakeBatchTx{ Recorder: &testutil.RecorderBuffered{}, rangeRespc: make(chan rangeResp, 5)}} fi := &fakeIndex{ Recorder: &testutil.RecorderBuffered{}, indexGetRespc: make(chan indexGetResp, 1), indexRangeRespc: make(chan indexRangeResp, 1), indexRangeEventsRespc: make(chan indexRangeEventsResp, 1), indexCompactRespc: make(chan map[revision]struct{}, 1), } s := &store{ cfg: StoreConfig{CompactionBatchLimit: 10000}, b: b, le: &lease.FakeLessor{}, kvindex: fi, currentRev: 0, compactMainRev: -1, fifoSched: schedule.NewFIFOScheduler(), stopc: make(chan struct{}), lg: zap.NewExample(), } s.ReadView, s.WriteView = &readView{s}, &writeView{s} return s } type rangeResp struct { keys [][]byte vals [][]byte } type fakeBatchTx struct { testutil.Recorder rangeRespc chan rangeResp } func (b *fakeBatchTx) Lock() {} func (b *fakeBatchTx) Unlock() {} func (b *fakeBatchTx) RLock() {} func (b *fakeBatchTx) RUnlock() {} func (b *fakeBatchTx) UnsafeCreateBucket(name []byte) {} func (b *fakeBatchTx) UnsafePut(bucketName []byte, key []byte, value []byte) { b.Recorder.Record(testutil.Action{Name: "put", Params: []interface{}{bucketName, key, value}}) } func (b *fakeBatchTx) UnsafeSeqPut(bucketName []byte, key []byte, value []byte) { b.Recorder.Record(testutil.Action{Name: "seqput", Params: []interface{}{bucketName, key, value}}) } func (b *fakeBatchTx) UnsafeRange(bucketName []byte, key, endKey []byte, limit int64) (keys [][]byte, vals [][]byte) { b.Recorder.Record(testutil.Action{Name: "range", Params: []interface{}{bucketName, key, endKey, limit}}) r := <-b.rangeRespc return r.keys, r.vals } func (b *fakeBatchTx) UnsafeDelete(bucketName []byte, key []byte) { b.Recorder.Record(testutil.Action{Name: "delete", Params: []interface{}{bucketName, key}}) } func (b *fakeBatchTx) UnsafeForEach(bucketName []byte, visitor func(k, v []byte) error) error { return nil } func (b *fakeBatchTx) Commit() {} func (b *fakeBatchTx) CommitAndStop() {} type fakeBackend struct { tx *fakeBatchTx } func (b *fakeBackend) BatchTx() backend.BatchTx { return b.tx } func (b *fakeBackend) ReadTx() backend.ReadTx { return b.tx } func (b *fakeBackend) ConcurrentReadTx() backend.ReadTx { return b.tx } func (b *fakeBackend) Hash(ignores map[backend.IgnoreKey]struct{}) (uint32, error) { return 0, nil } func (b *fakeBackend) Size() int64 { return 0 } func (b *fakeBackend) SizeInUse() int64 { return 0 } func (b *fakeBackend) OpenReadTxN() int64 { return 0 } func (b *fakeBackend) Snapshot() backend.Snapshot { return nil } func (b *fakeBackend) ForceCommit() {} func (b *fakeBackend) Defrag() error { return nil } func (b *fakeBackend) Close() error { return nil } type indexGetResp struct { rev revision created revision ver int64 err error } type indexRangeResp struct { keys [][]byte revs []revision } type indexRangeEventsResp struct { revs []revision } type fakeIndex struct { testutil.Recorder indexGetRespc chan indexGetResp indexRangeRespc chan indexRangeResp indexRangeEventsRespc chan indexRangeEventsResp indexCompactRespc chan map[revision]struct{} } func (i *fakeIndex) Revisions(key, end []byte, atRev int64, limit int) []revision { _, rev := i.Range(key, end, atRev) return rev } func (i *fakeIndex) CountRevisions(key, end []byte, atRev int64, limit int) int { _, rev := i.Range(key, end, atRev) return len(rev) } func (i *fakeIndex) Get(key []byte, atRev int64) (rev, created revision, ver int64, err error) { i.Recorder.Record(testutil.Action{Name: "get", Params: []interface{}{key, atRev}}) r := <-i.indexGetRespc return r.rev, r.created, r.ver, r.err } func (i *fakeIndex) Range(key, end []byte, atRev int64) ([][]byte, []revision) { i.Recorder.Record(testutil.Action{Name: "range", Params: []interface{}{key, end, atRev}}) r := <-i.indexRangeRespc return r.keys, r.revs } func (i *fakeIndex) Put(key []byte, rev revision) { i.Recorder.Record(testutil.Action{Name: "put", Params: []interface{}{key, rev}}) } func (i *fakeIndex) Tombstone(key []byte, rev revision) error { i.Recorder.Record(testutil.Action{Name: "tombstone", Params: []interface{}{key, rev}}) return nil } func (i *fakeIndex) RangeSince(key, end []byte, rev int64) []revision { i.Recorder.Record(testutil.Action{Name: "rangeEvents", Params: []interface{}{key, end, rev}}) r := <-i.indexRangeEventsRespc return r.revs } func (i *fakeIndex) Compact(rev int64) map[revision]struct{} { i.Recorder.Record(testutil.Action{Name: "compact", Params: []interface{}{rev}}) return <-i.indexCompactRespc } func (i *fakeIndex) Keep(rev int64) map[revision]struct{} { i.Recorder.Record(testutil.Action{Name: "keep", Params: []interface{}{rev}}) return <-i.indexCompactRespc } func (i *fakeIndex) Equal(b index) bool { return false } func (i *fakeIndex) Insert(ki *keyIndex) { i.Recorder.Record(testutil.Action{Name: "insert", Params: []interface{}{ki}}) } func (i *fakeIndex) KeyIndex(ki *keyIndex) *keyIndex { i.Recorder.Record(testutil.Action{Name: "keyIndex", Params: []interface{}{ki}}) return nil } func createBytesSlice(bytesN, sliceN int) [][]byte { rs := [][]byte{} for len(rs) != sliceN { v := make([]byte, bytesN) if _, err := rand.Read(v); err != nil { panic(err) } rs = append(rs, v) } return rs }