// 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" "os" "reflect" "testing" "time" "github.com/coreos/etcd/lease" "github.com/coreos/etcd/mvcc/backend" "github.com/coreos/etcd/mvcc/mvccpb" ) func TestWatch(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := newWatchableStore(b, &lease.FakeLessor{}, nil) defer func() { s.store.Close() os.Remove(tmpPath) }() testKey := []byte("foo") testValue := []byte("bar") s.Put(testKey, testValue, lease.NoLease) w := s.NewWatchStream() w.Watch(testKey, nil, 0) if !s.synced.contains(string(testKey)) { // the key must have had an entry in synced t.Errorf("existence = false, want true") } } func TestNewWatcherCancel(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := newWatchableStore(b, &lease.FakeLessor{}, nil) defer func() { s.store.Close() os.Remove(tmpPath) }() testKey := []byte("foo") testValue := []byte("bar") s.Put(testKey, testValue, lease.NoLease) w := s.NewWatchStream() wt := w.Watch(testKey, nil, 0) if err := w.Cancel(wt); err != nil { t.Error(err) } if s.synced.contains(string(testKey)) { // the key shoud have been deleted t.Errorf("existence = true, want false") } } // TestCancelUnsynced tests if running CancelFunc removes watchers from unsynced. func TestCancelUnsynced(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() // manually create watchableStore instead of newWatchableStore // because newWatchableStore automatically calls syncWatchers // method to sync watchers in unsynced map. We want to keep watchers // in unsynced to test if syncWatchers works as expected. s := &watchableStore{ store: NewStore(b, &lease.FakeLessor{}, nil), unsynced: newWatcherGroup(), // to make the test not crash from assigning to nil map. // 'synced' doesn't get populated in this test. synced: newWatcherGroup(), } defer func() { s.store.Close() os.Remove(tmpPath) }() // Put a key so that we can spawn watchers on that key. // (testKey in this test). This increases the rev to 1, // and later we can we set the watcher's startRev to 1, // and force watchers to be in unsynced. testKey := []byte("foo") testValue := []byte("bar") s.Put(testKey, testValue, lease.NoLease) w := s.NewWatchStream() // arbitrary number for watchers watcherN := 100 // create watcherN of watch ids to cancel watchIDs := make([]WatchID, watcherN) for i := 0; i < watcherN; i++ { // use 1 to keep watchers in unsynced watchIDs[i] = w.Watch(testKey, nil, 1) } for _, idx := range watchIDs { if err := w.Cancel(idx); err != nil { t.Error(err) } } // After running CancelFunc // // unsynced should be empty // because cancel removes watcher from unsynced if size := s.unsynced.size(); size != 0 { t.Errorf("unsynced size = %d, want 0", size) } } // TestSyncWatchers populates unsynced watcher map and tests syncWatchers // method to see if it correctly sends events to channel of unsynced watchers // and moves these watchers to synced. func TestSyncWatchers(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := &watchableStore{ store: NewStore(b, &lease.FakeLessor{}, nil), unsynced: newWatcherGroup(), synced: newWatcherGroup(), } defer func() { s.store.Close() os.Remove(tmpPath) }() testKey := []byte("foo") testValue := []byte("bar") s.Put(testKey, testValue, lease.NoLease) w := s.NewWatchStream() // arbitrary number for watchers watcherN := 100 for i := 0; i < watcherN; i++ { // specify rev as 1 to keep watchers in unsynced w.Watch(testKey, nil, 1) } // Before running s.syncWatchers() synced should be empty because we manually // populate unsynced only sws := s.synced.watcherSetByKey(string(testKey)) uws := s.unsynced.watcherSetByKey(string(testKey)) if len(sws) != 0 { t.Fatalf("synced[string(testKey)] size = %d, want 0", len(sws)) } // unsynced should not be empty because we manually populated unsynced only if len(uws) != watcherN { t.Errorf("unsynced size = %d, want %d", len(uws), watcherN) } // this should move all unsynced watchers to synced ones s.syncWatchers() sws = s.synced.watcherSetByKey(string(testKey)) uws = s.unsynced.watcherSetByKey(string(testKey)) // After running s.syncWatchers(), synced should not be empty because syncwatchers // populates synced in this test case if len(sws) != watcherN { t.Errorf("synced[string(testKey)] size = %d, want %d", len(sws), watcherN) } // unsynced should be empty because syncwatchers is expected to move all watchers // from unsynced to synced in this test case if len(uws) != 0 { t.Errorf("unsynced size = %d, want 0", len(uws)) } for w := range sws { if w.minRev != s.Rev()+1 { t.Errorf("w.minRev = %d, want %d", w.minRev, s.Rev()+1) } } if len(w.(*watchStream).ch) != watcherN { t.Errorf("watched event size = %d, want %d", len(w.(*watchStream).ch), watcherN) } evs := (<-w.(*watchStream).ch).Events if len(evs) != 1 { t.Errorf("len(evs) got = %d, want = 1", len(evs)) } if evs[0].Type != mvccpb.PUT { t.Errorf("got = %v, want = %v", evs[0].Type, mvccpb.PUT) } if !bytes.Equal(evs[0].Kv.Key, testKey) { t.Errorf("got = %s, want = %s", evs[0].Kv.Key, testKey) } if !bytes.Equal(evs[0].Kv.Value, testValue) { t.Errorf("got = %s, want = %s", evs[0].Kv.Value, testValue) } } // TestWatchCompacted tests a watcher that watches on a compacted revision. func TestWatchCompacted(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := newWatchableStore(b, &lease.FakeLessor{}, nil) defer func() { s.store.Close() os.Remove(tmpPath) }() testKey := []byte("foo") testValue := []byte("bar") maxRev := 10 compactRev := int64(5) for i := 0; i < maxRev; i++ { s.Put(testKey, testValue, lease.NoLease) } _, err := s.Compact(compactRev) if err != nil { t.Fatalf("failed to compact kv (%v)", err) } w := s.NewWatchStream() wt := w.Watch(testKey, nil, compactRev-1) select { case resp := <-w.Chan(): if resp.WatchID != wt { t.Errorf("resp.WatchID = %x, want %x", resp.WatchID, wt) } if resp.CompactRevision == 0 { t.Errorf("resp.Compacted = %v, want %v", resp.CompactRevision, compactRev) } case <-time.After(1 * time.Second): t.Fatalf("failed to receive response (timeout)") } } func TestWatchFutureRev(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := newWatchableStore(b, &lease.FakeLessor{}, nil) defer func() { s.store.Close() os.Remove(tmpPath) }() testKey := []byte("foo") testValue := []byte("bar") w := s.NewWatchStream() wrev := int64(10) w.Watch(testKey, nil, wrev) for i := 0; i < 10; i++ { rev := s.Put(testKey, testValue, lease.NoLease) if rev >= wrev { break } } select { case resp := <-w.Chan(): if resp.Revision != wrev { t.Fatalf("rev = %d, want %d", resp.Revision, wrev) } if len(resp.Events) != 1 { t.Fatalf("failed to get events from the response") } if resp.Events[0].Kv.ModRevision != wrev { t.Fatalf("kv.rev = %d, want %d", resp.Events[0].Kv.ModRevision, wrev) } case <-time.After(time.Second): t.Fatal("failed to receive event in 1 second.") } } func TestWatchRestore(t *testing.T) { test := func(delay time.Duration) func(t *testing.T) { return func(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := newWatchableStore(b, &lease.FakeLessor{}, nil) defer cleanup(s, b, tmpPath) testKey := []byte("foo") testValue := []byte("bar") rev := s.Put(testKey, testValue, lease.NoLease) newBackend, newPath := backend.NewDefaultTmpBackend() newStore := newWatchableStore(newBackend, &lease.FakeLessor{}, nil) defer cleanup(newStore, newBackend, newPath) w := newStore.NewWatchStream() w.Watch(testKey, nil, rev-1) time.Sleep(delay) newStore.Restore(b) select { case resp := <-w.Chan(): if resp.Revision != rev { t.Fatalf("rev = %d, want %d", resp.Revision, rev) } if len(resp.Events) != 1 { t.Fatalf("failed to get events from the response") } if resp.Events[0].Kv.ModRevision != rev { t.Fatalf("kv.rev = %d, want %d", resp.Events[0].Kv.ModRevision, rev) } case <-time.After(time.Second): t.Fatal("failed to receive event in 1 second.") } } } t.Run("Normal", test(0)) t.Run("RunSyncWatchLoopBeforeRestore", test(time.Millisecond*120)) // longer than default waitDuration } // TestWatchRestoreSyncedWatcher tests such a case that: // 1. watcher is created with a future revision "math.MaxInt64 - 2" // 2. watcher with a future revision is added to "synced" watcher group // 3. restore/overwrite storage with snapshot of a higher lasat revision // 4. restore operation moves "synced" to "unsynced" watcher group // 5. choose the watcher from step 1, without panic func TestWatchRestoreSyncedWatcher(t *testing.T) { b1, b1Path := backend.NewDefaultTmpBackend() s1 := newWatchableStore(b1, &lease.FakeLessor{}, nil) defer cleanup(s1, b1, b1Path) b2, b2Path := backend.NewDefaultTmpBackend() s2 := newWatchableStore(b2, &lease.FakeLessor{}, nil) defer cleanup(s2, b2, b2Path) testKey, testValue := []byte("foo"), []byte("bar") rev := s1.Put(testKey, testValue, lease.NoLease) startRev := rev + 2 // create a watcher with a future revision // add to "synced" watcher group (startRev > s.store.currentRev) w1 := s1.NewWatchStream() w1.Watch(testKey, nil, startRev) // make "s2" ends up with a higher last revision s2.Put(testKey, testValue, lease.NoLease) s2.Put(testKey, testValue, lease.NoLease) // overwrite storage with higher revisions if err := s1.Restore(b2); err != nil { t.Fatal(err) } // wait for next "syncWatchersLoop" iteration // and the unsynced watcher should be chosen time.Sleep(2 * time.Second) // trigger events for "startRev" s1.Put(testKey, testValue, lease.NoLease) select { case resp := <-w1.Chan(): if resp.Revision != startRev { t.Fatalf("resp.Revision expect %d, got %d", startRev, resp.Revision) } if len(resp.Events) != 1 { t.Fatalf("len(resp.Events) expect 1, got %d", len(resp.Events)) } if resp.Events[0].Kv.ModRevision != startRev { t.Fatalf("resp.Events[0].Kv.ModRevision expect %d, got %d", startRev, resp.Events[0].Kv.ModRevision) } case <-time.After(time.Second): t.Fatal("failed to receive event in 1 second") } } // TestWatchBatchUnsynced tests batching on unsynced watchers func TestWatchBatchUnsynced(t *testing.T) { b, tmpPath := backend.NewDefaultTmpBackend() s := newWatchableStore(b, &lease.FakeLessor{}, nil) oldMaxRevs := watchBatchMaxRevs defer func() { watchBatchMaxRevs = oldMaxRevs s.store.Close() os.Remove(tmpPath) }() batches := 3 watchBatchMaxRevs = 4 v := []byte("foo") for i := 0; i < watchBatchMaxRevs*batches; i++ { s.Put(v, v, lease.NoLease) } w := s.NewWatchStream() w.Watch(v, nil, 1) for i := 0; i < batches; i++ { if resp := <-w.Chan(); len(resp.Events) != watchBatchMaxRevs { t.Fatalf("len(events) = %d, want %d", len(resp.Events), watchBatchMaxRevs) } } s.store.mu.Lock() defer s.store.mu.Unlock() if size := s.synced.size(); size != 1 { t.Errorf("synced size = %d, want 1", size) } } func TestNewMapwatcherToEventMap(t *testing.T) { k0, k1, k2 := []byte("foo0"), []byte("foo1"), []byte("foo2") v0, v1, v2 := []byte("bar0"), []byte("bar1"), []byte("bar2") ws := []*watcher{{key: k0}, {key: k1}, {key: k2}} evs := []mvccpb.Event{ { Type: mvccpb.PUT, Kv: &mvccpb.KeyValue{Key: k0, Value: v0}, }, { Type: mvccpb.PUT, Kv: &mvccpb.KeyValue{Key: k1, Value: v1}, }, { Type: mvccpb.PUT, Kv: &mvccpb.KeyValue{Key: k2, Value: v2}, }, } tests := []struct { sync []*watcher evs []mvccpb.Event wwe map[*watcher][]mvccpb.Event }{ // no watcher in sync, some events should return empty wwe { nil, evs, map[*watcher][]mvccpb.Event{}, }, // one watcher in sync, one event that does not match the key of that // watcher should return empty wwe { []*watcher{ws[2]}, evs[:1], map[*watcher][]mvccpb.Event{}, }, // one watcher in sync, one event that matches the key of that // watcher should return wwe with that matching watcher { []*watcher{ws[1]}, evs[1:2], map[*watcher][]mvccpb.Event{ ws[1]: evs[1:2], }, }, // two watchers in sync that watches two different keys, one event // that matches the key of only one of the watcher should return wwe // with the matching watcher { []*watcher{ws[0], ws[2]}, evs[2:], map[*watcher][]mvccpb.Event{ ws[2]: evs[2:], }, }, // two watchers in sync that watches the same key, two events that // match the keys should return wwe with those two watchers { []*watcher{ws[0], ws[1]}, evs[:2], map[*watcher][]mvccpb.Event{ ws[0]: evs[:1], ws[1]: evs[1:2], }, }, } for i, tt := range tests { wg := newWatcherGroup() for _, w := range tt.sync { wg.add(w) } gwe := newWatcherBatch(&wg, tt.evs) if len(gwe) != len(tt.wwe) { t.Errorf("#%d: len(gwe) got = %d, want = %d", i, len(gwe), len(tt.wwe)) } // compare gwe and tt.wwe for w, eb := range gwe { if len(eb.evs) != len(tt.wwe[w]) { t.Errorf("#%d: len(eb.evs) got = %d, want = %d", i, len(eb.evs), len(tt.wwe[w])) } if !reflect.DeepEqual(eb.evs, tt.wwe[w]) { t.Errorf("#%d: reflect.DeepEqual events got = %v, want = true", i, false) } } } }