// Copyright 2022 The Prometheus 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 chunks import ( "math/rand" "sync" "testing" "time" "github.com/stretchr/testify/require" "go.uber.org/atomic" ) func (q *writeJobQueue) assertInvariants(t *testing.T) { q.mtx.Lock() defer q.mtx.Unlock() totalSize := 0 for s := q.first; s != nil; s = s.nextSegment { require.NotNil(t, s.segment) // Next read index is lower or equal than next write index (we cannot past written jobs) require.LessOrEqual(t, s.nextRead, s.nextWrite) // Number of unread elements in this segment. totalSize += s.nextWrite - s.nextRead // First segment can be partially read, other segments were not read yet. if s == q.first { require.GreaterOrEqual(t, s.nextRead, 0) } else { require.Equal(t, 0, s.nextRead) } // If first shard is empty (everything was read from it already), it must have extra capacity for // additional elements, otherwise it would have been removed. if s == q.first && s.nextRead == s.nextWrite { require.Less(t, s.nextWrite, len(s.segment)) } // Segments in the middle are full. if s != q.first && s != q.last { require.Len(t, s.segment, s.nextWrite) } // Last segment must have at least one element, or we wouldn't have created it. require.Positive(t, s.nextWrite) } require.Equal(t, q.size, totalSize) } func TestQueuePushPopSingleGoroutine(t *testing.T) { seed := time.Now().UnixNano() t.Log("seed:", seed) r := rand.New(rand.NewSource(seed)) const maxSize = 500 const maxIters = 50 for maxCount := 1; maxCount < maxSize; maxCount++ { queue := newWriteJobQueue(maxCount, 1+(r.Int()%maxCount)) elements := 0 // total elements in the queue lastWriteID := 0 lastReadID := 0 for iter := 0; iter < maxIters; iter++ { if elements < maxCount { toWrite := r.Int() % (maxCount - elements) if toWrite == 0 { toWrite = 1 } for i := 0; i < toWrite; i++ { lastWriteID++ require.True(t, queue.push(chunkWriteJob{seriesRef: HeadSeriesRef(lastWriteID)})) elements++ } } if elements > 0 { toRead := r.Int() % elements if toRead == 0 { toRead = 1 } for i := 0; i < toRead; i++ { lastReadID++ j, b := queue.pop() require.True(t, b) require.Equal(t, HeadSeriesRef(lastReadID), j.seriesRef) elements-- } } require.Equal(t, elements, queue.length()) queue.assertInvariants(t) } } } func TestQueuePushBlocksOnFullQueue(t *testing.T) { queue := newWriteJobQueue(5, 5) pushTime := make(chan time.Time) go func() { require.True(t, queue.push(chunkWriteJob{seriesRef: 1})) require.True(t, queue.push(chunkWriteJob{seriesRef: 2})) require.True(t, queue.push(chunkWriteJob{seriesRef: 3})) require.True(t, queue.push(chunkWriteJob{seriesRef: 4})) require.True(t, queue.push(chunkWriteJob{seriesRef: 5})) pushTime <- time.Now() // This will block require.True(t, queue.push(chunkWriteJob{seriesRef: 6})) pushTime <- time.Now() }() timeBeforePush := <-pushTime delay := 100 * time.Millisecond select { case <-time.After(delay): // ok case <-pushTime: require.Fail(t, "didn't expect another push to proceed") } popTime := time.Now() j, b := queue.pop() require.True(t, b) require.Equal(t, HeadSeriesRef(1), j.seriesRef) timeAfterPush := <-pushTime require.GreaterOrEqual(t, timeAfterPush.Sub(popTime), time.Duration(0)) require.GreaterOrEqual(t, timeAfterPush.Sub(timeBeforePush), delay) } func TestQueuePopBlocksOnEmptyQueue(t *testing.T) { queue := newWriteJobQueue(5, 5) popTime := make(chan time.Time) go func() { j, b := queue.pop() require.True(t, b) require.Equal(t, HeadSeriesRef(1), j.seriesRef) popTime <- time.Now() // This will block j, b = queue.pop() require.True(t, b) require.Equal(t, HeadSeriesRef(2), j.seriesRef) popTime <- time.Now() }() queue.push(chunkWriteJob{seriesRef: 1}) timeBeforePop := <-popTime delay := 100 * time.Millisecond select { case <-time.After(delay): // ok case <-popTime: require.Fail(t, "didn't expect another pop to proceed") } pushTime := time.Now() require.True(t, queue.push(chunkWriteJob{seriesRef: 2})) timeAfterPop := <-popTime require.GreaterOrEqual(t, timeAfterPop.Sub(pushTime), time.Duration(0)) require.Greater(t, timeAfterPop.Sub(timeBeforePop), delay) } func TestQueuePopUnblocksOnClose(t *testing.T) { queue := newWriteJobQueue(5, 5) popTime := make(chan time.Time) go func() { j, b := queue.pop() require.True(t, b) require.Equal(t, HeadSeriesRef(1), j.seriesRef) popTime <- time.Now() // This will block until queue is closed. j, b = queue.pop() require.False(t, b) popTime <- time.Now() }() queue.push(chunkWriteJob{seriesRef: 1}) timeBeforePop := <-popTime delay := 100 * time.Millisecond select { case <-time.After(delay): // ok case <-popTime: require.Fail(t, "didn't expect another pop to proceed") } closeTime := time.Now() queue.close() timeAfterPop := <-popTime require.GreaterOrEqual(t, timeAfterPop.Sub(closeTime), time.Duration(0)) require.GreaterOrEqual(t, timeAfterPop.Sub(timeBeforePop), delay) } func TestQueuePopAfterCloseReturnsAllElements(t *testing.T) { const count = 10 queue := newWriteJobQueue(count, count) for i := 0; i < count; i++ { require.True(t, queue.push(chunkWriteJob{seriesRef: HeadSeriesRef(i)})) } // close the queue before popping all elements. queue.close() // No more pushing allowed after close. require.False(t, queue.push(chunkWriteJob{seriesRef: HeadSeriesRef(11111)})) // Verify that we can still read all pushed elements. for i := 0; i < count; i++ { j, b := queue.pop() require.True(t, b) require.Equal(t, HeadSeriesRef(i), j.seriesRef) } _, b := queue.pop() require.False(t, b) } func TestQueuePushPopManyGoroutines(t *testing.T) { const readGoroutines = 5 const writeGoroutines = 10 const writes = 500 queue := newWriteJobQueue(1024, 64) // Reading goroutine refsMx := sync.Mutex{} refs := map[HeadSeriesRef]bool{} readersWG := sync.WaitGroup{} for i := 0; i < readGoroutines; i++ { readersWG.Add(1) go func() { defer readersWG.Done() for j, ok := queue.pop(); ok; j, ok = queue.pop() { refsMx.Lock() refs[j.seriesRef] = true refsMx.Unlock() } }() } id := atomic.Uint64{} writersWG := sync.WaitGroup{} for i := 0; i < writeGoroutines; i++ { writersWG.Add(1) go func() { defer writersWG.Done() for i := 0; i < writes; i++ { ref := id.Inc() require.True(t, queue.push(chunkWriteJob{seriesRef: HeadSeriesRef(ref)})) } }() } // Wait until all writes are done. writersWG.Wait() // Close the queue and wait for reading to be done. queue.close() readersWG.Wait() // Check if we have all expected values require.Len(t, refs, writeGoroutines*writes) } func TestQueueSegmentIsKeptEvenIfEmpty(t *testing.T) { queue := newWriteJobQueue(1024, 64) require.True(t, queue.push(chunkWriteJob{seriesRef: 1})) _, b := queue.pop() require.True(t, b) require.NotNil(t, queue.first) require.Equal(t, 1, queue.first.nextRead) require.Equal(t, 1, queue.first.nextWrite) }