package pool_test import ( "bytes" crand "crypto/rand" "fmt" "io" "math/rand" "testing" "time" "github.com/lightningnetwork/lnd/buffer" "github.com/lightningnetwork/lnd/pool" ) type workerPoolTest struct { name string newPool func() interface{} numWorkers int } // TestConcreteWorkerPools asserts the behavior of any concrete implementations // of worker pools provided by the pool package. Currently this tests the // pool.Read and pool.Write instances. func TestConcreteWorkerPools(t *testing.T) { const ( gcInterval = time.Second expiryInterval = 250 * time.Millisecond numWorkers = 5 workerTimeout = 500 * time.Millisecond ) tests := []workerPoolTest{ { name: "write pool", newPool: func() interface{} { bp := pool.NewWriteBuffer( gcInterval, expiryInterval, ) return pool.NewWrite( bp, numWorkers, workerTimeout, ) }, numWorkers: numWorkers, }, { name: "read pool", newPool: func() interface{} { bp := pool.NewReadBuffer( gcInterval, expiryInterval, ) return pool.NewRead( bp, numWorkers, workerTimeout, ) }, numWorkers: numWorkers, }, } for _, test := range tests { testWorkerPool(t, test) } } func testWorkerPool(t *testing.T, test workerPoolTest) { t.Run(test.name+" non blocking", func(t *testing.T) { t.Parallel() p := test.newPool() startGeneric(t, p) defer stopGeneric(t, p) submitNonblockingGeneric(t, p, test.numWorkers) }) t.Run(test.name+" blocking", func(t *testing.T) { t.Parallel() p := test.newPool() startGeneric(t, p) defer stopGeneric(t, p) submitBlockingGeneric(t, p, test.numWorkers) }) t.Run(test.name+" partial blocking", func(t *testing.T) { t.Parallel() p := test.newPool() startGeneric(t, p) defer stopGeneric(t, p) submitPartialBlockingGeneric(t, p, test.numWorkers) }) } // submitNonblockingGeneric asserts that queueing tasks to the worker pool and // allowing them all to unblock simultaneously results in all of the tasks being // completed in a timely manner. func submitNonblockingGeneric(t *testing.T, p interface{}, nWorkers int) { // We'll submit 2*nWorkers tasks that will all be unblocked // simultaneously. nUnblocked := 2 * nWorkers // First we'll queue all of the tasks for the pool. errChan := make(chan error) semChan := make(chan struct{}) for i := 0; i < nUnblocked; i++ { go func() { errChan <- submitGeneric(p, semChan) }() } // Since we haven't signaled the semaphore, none of the them should // complete. pullNothing(t, errChan) // Now, unblock them all simultaneously. All of the tasks should then be // processed in parallel. Afterward, no more errors should come through. close(semChan) pullParllel(t, nUnblocked, errChan) pullNothing(t, errChan) } // submitBlockingGeneric asserts that submitting blocking tasks to the pool and // unblocking each sequentially results in a single task being processed at a // time. func submitBlockingGeneric(t *testing.T, p interface{}, nWorkers int) { // We'll submit 2*nWorkers tasks that will be unblocked sequentially. nBlocked := 2 * nWorkers // First, queue all of the blocking tasks for the pool. errChan := make(chan error) semChan := make(chan struct{}) for i := 0; i < nBlocked; i++ { go func() { errChan <- submitGeneric(p, semChan) }() } // Since we haven't signaled the semaphore, none of them should // complete. pullNothing(t, errChan) // Now, pull each blocking task sequentially from the pool. Afterwards, // no more errors should come through. pullSequntial(t, nBlocked, errChan, semChan) pullNothing(t, errChan) } // submitPartialBlockingGeneric tests that so long as one worker is not blocked, // any other non-blocking submitted tasks can still be processed. func submitPartialBlockingGeneric(t *testing.T, p interface{}, nWorkers int) { // We'll submit nWorkers-1 tasks that will be initially blocked, the // remainder will all be unblocked simultaneously. After the unblocked // tasks have finished, we will sequentially unblock the nWorkers-1 // tasks that were first submitted. nBlocked := nWorkers - 1 nUnblocked := 2*nWorkers - nBlocked // First, submit all of the blocking tasks to the pool. errChan := make(chan error) semChan := make(chan struct{}) for i := 0; i < nBlocked; i++ { go func() { errChan <- submitGeneric(p, semChan) }() } // Since these are all blocked, no errors should be returned yet. pullNothing(t, errChan) // Now, add all of the non-blocking task to the pool. semChanNB := make(chan struct{}) for i := 0; i < nUnblocked; i++ { go func() { errChan <- submitGeneric(p, semChanNB) }() } // Since we haven't unblocked the second batch, we again expect no tasks // to finish. pullNothing(t, errChan) // Now, unblock the unblocked task and pull all of them. After they have // been pulled, we should see no more tasks. close(semChanNB) pullParllel(t, nUnblocked, errChan) pullNothing(t, errChan) // Finally, unblock each the blocked tasks we added initially, and // assert that no further errors come through. pullSequntial(t, nBlocked, errChan, semChan) pullNothing(t, errChan) } func pullNothing(t *testing.T, errChan chan error) { t.Helper() select { case err := <-errChan: t.Fatalf("received unexpected error before semaphore "+ "release: %v", err) case <-time.After(time.Second): } } func pullParllel(t *testing.T, n int, errChan chan error) { t.Helper() for i := 0; i < n; i++ { select { case err := <-errChan: if err != nil { t.Fatal(err) } case <-time.After(time.Second): t.Fatalf("task %d was not processed in time", i) } } } func pullSequntial(t *testing.T, n int, errChan chan error, semChan chan struct{}) { t.Helper() for i := 0; i < n; i++ { // Signal for another task to unblock. select { case semChan <- struct{}{}: case <-time.After(time.Second): t.Fatalf("task %d was not unblocked", i) } // Wait for the error to arrive, we expect it to be non-nil. select { case err := <-errChan: if err != nil { t.Fatal(err) } case <-time.After(time.Second): t.Fatalf("task %d was not processed in time", i) } } } func startGeneric(t *testing.T, p interface{}) { t.Helper() var err error switch pp := p.(type) { case *pool.Write: err = pp.Start() case *pool.Read: err = pp.Start() default: t.Fatalf("unknown worker pool type: %T", p) } if err != nil { t.Fatalf("unable to start worker pool: %v", err) } } func stopGeneric(t *testing.T, p interface{}) { t.Helper() var err error switch pp := p.(type) { case *pool.Write: err = pp.Stop() case *pool.Read: err = pp.Stop() default: t.Fatalf("unknown worker pool type: %T", p) } if err != nil { t.Fatalf("unable to stop worker pool: %v", err) } } func submitGeneric(p interface{}, sem <-chan struct{}) error { var err error switch pp := p.(type) { case *pool.Write: err = pp.Submit(func(buf *bytes.Buffer) error { // Verify that the provided buffer has been reset to be // zero length. if buf.Len() != 0 { return fmt.Errorf("buf should be length zero, "+ "instead has length %d", buf.Len()) } // Verify that the capacity of the buffer has the // correct underlying size of a buffer.WriteSize. if buf.Cap() != buffer.WriteSize { return fmt.Errorf("buf should have capacity "+ "%d, instead has capacity %d", buffer.WriteSize, buf.Cap()) } // Sample some random bytes that we'll use to dirty the // buffer. b := make([]byte, rand.Intn(buf.Cap())) _, err := io.ReadFull(crand.Reader, b) if err != nil { return err } // Write the random bytes the buffer. _, err = buf.Write(b) // Wait until this task is signaled to exit. <-sem return err }) case *pool.Read: err = pp.Submit(func(buf *buffer.Read) error { // Assert that all of the bytes in the provided array // are zero, indicating that the buffer was reset // between uses. for i := range buf[:] { if buf[i] != 0x00 { return fmt.Errorf("byte %d of "+ "buffer.Read should be "+ "0, instead is %d", i, buf[i]) } } // Sample some random bytes to read into the buffer. _, err := io.ReadFull(crand.Reader, buf[:]) // Wait until this task is signaled to exit. <-sem return err }) default: return fmt.Errorf("unknown worker pool type: %T", p) } if err != nil { return fmt.Errorf("unable to submit task: %v", err) } return nil }