package htlcswitch import ( prand "math/rand" "reflect" "testing" "time" "github.com/davecgh/go-spew/spew" "github.com/lightningnetwork/lnd/clock" "github.com/lightningnetwork/lnd/lnwire" ) const testExpiry = time.Minute // TestMailBoxCouriers tests that both aspects of the mailBox struct works // properly. Both packets and messages should be able to added to each // respective mailbox concurrently, and also messages/packets should also be // able to be received concurrently. func TestMailBoxCouriers(t *testing.T) { t.Parallel() // First, we'll create new instance of the current default mailbox // type. ctx := newMailboxContext(t, time.Now(), testExpiry) defer ctx.mailbox.Stop() // We'll be adding 10 message of both types to the mailbox. const numPackets = 10 const halfPackets = numPackets / 2 // We'll add a set of random packets to the mailbox. sentPackets := make([]*htlcPacket, numPackets) for i := 0; i < numPackets; i++ { pkt := &htlcPacket{ outgoingChanID: lnwire.NewShortChanIDFromInt(uint64(prand.Int63())), incomingChanID: lnwire.NewShortChanIDFromInt(uint64(prand.Int63())), amount: lnwire.MilliSatoshi(prand.Int63()), htlc: &lnwire.UpdateAddHTLC{ ID: uint64(i), }, } sentPackets[i] = pkt err := ctx.mailbox.AddPacket(pkt) if err != nil { t.Fatalf("unable to add packet: %v", err) } } // Next, we'll do the same, but this time adding wire messages. sentMessages := make([]lnwire.Message, numPackets) for i := 0; i < numPackets; i++ { msg := &lnwire.UpdateAddHTLC{ ID: uint64(prand.Int63()), Amount: lnwire.MilliSatoshi(prand.Int63()), } sentMessages[i] = msg err := ctx.mailbox.AddMessage(msg) if err != nil { t.Fatalf("unable to add message: %v", err) } } // Now we'll attempt to read back the packets/messages we added to the // mailbox. We'll alternative reading from the message outbox vs the // packet outbox to ensure that they work concurrently properly. recvdPackets := make([]*htlcPacket, 0, numPackets) recvdMessages := make([]lnwire.Message, 0, numPackets) for i := 0; i < numPackets*2; i++ { timeout := time.After(time.Second * 5) if i%2 == 0 { select { case <-timeout: t.Fatalf("didn't recv pkt after timeout") case pkt := <-ctx.mailbox.PacketOutBox(): recvdPackets = append(recvdPackets, pkt) } } else { select { case <-timeout: t.Fatalf("didn't recv message after timeout") case msg := <-ctx.mailbox.MessageOutBox(): recvdMessages = append(recvdMessages, msg) } } } // The number of messages/packets we sent, and the number we received // should match exactly. if len(sentPackets) != len(recvdPackets) { t.Fatalf("expected %v packets instead got %v", len(sentPackets), len(recvdPackets)) } if len(sentMessages) != len(recvdMessages) { t.Fatalf("expected %v messages instead got %v", len(sentMessages), len(recvdMessages)) } // Additionally, the set of packets should match exactly, as we should // have received the packets in the exact same ordering that we added. if !reflect.DeepEqual(sentPackets, recvdPackets) { t.Fatalf("recvd packets mismatched: expected %v, got %v", spew.Sdump(sentPackets), spew.Sdump(recvdPackets)) } if !reflect.DeepEqual(recvdMessages, recvdMessages) { t.Fatalf("recvd messages mismatched: expected %v, got %v", spew.Sdump(sentMessages), spew.Sdump(recvdMessages)) } // Now that we've received all of the intended msgs/pkts, ack back half // of the packets. for _, recvdPkt := range recvdPackets[:halfPackets] { ctx.mailbox.AckPacket(recvdPkt.inKey()) } // With the packets drained and partially acked, we reset the mailbox, // simulating a link shutting down and then coming back up. err := ctx.mailbox.ResetMessages() if err != nil { t.Fatalf("unable to reset messages: %v", err) } err = ctx.mailbox.ResetPackets() if err != nil { t.Fatalf("unable to reset packets: %v", err) } // Now, we'll use the same alternating strategy to read from our // mailbox. All wire messages are dropped on startup, but any unacked // packets will be replayed in the same order they were delivered // initially. recvdPackets2 := make([]*htlcPacket, 0, halfPackets) for i := 0; i < 2*halfPackets; i++ { timeout := time.After(time.Second * 5) if i%2 == 0 { select { case <-timeout: t.Fatalf("didn't recv pkt after timeout") case pkt := <-ctx.mailbox.PacketOutBox(): recvdPackets2 = append(recvdPackets2, pkt) } } else { select { case <-ctx.mailbox.MessageOutBox(): t.Fatalf("should not receive wire msg after reset") default: } } } // The number of packets we received should match the number of unacked // packets left in the mailbox. if halfPackets != len(recvdPackets2) { t.Fatalf("expected %v packets instead got %v", halfPackets, len(recvdPackets)) } // Additionally, the set of packets should match exactly with the // unacked packets, and we should have received the packets in the exact // same ordering that we added. if !reflect.DeepEqual(recvdPackets[halfPackets:], recvdPackets2) { t.Fatalf("recvd packets mismatched: expected %v, got %v", spew.Sdump(sentPackets), spew.Sdump(recvdPackets)) } } // TestMailBoxResetAfterShutdown tests that ResetMessages and ResetPackets // return ErrMailBoxShuttingDown after the mailbox has been stopped. func TestMailBoxResetAfterShutdown(t *testing.T) { t.Parallel() ctx := newMailboxContext(t, time.Now(), time.Second) // Stop the mailbox, then try to reset the message and packet couriers. ctx.mailbox.Stop() err := ctx.mailbox.ResetMessages() if err != ErrMailBoxShuttingDown { t.Fatalf("expected ErrMailBoxShuttingDown, got: %v", err) } err = ctx.mailbox.ResetPackets() if err != ErrMailBoxShuttingDown { t.Fatalf("expected ErrMailBoxShuttingDown, got: %v", err) } } type mailboxContext struct { t *testing.T mailbox MailBox clock *clock.TestClock forwards chan *htlcPacket } func newMailboxContext(t *testing.T, startTime time.Time, expiry time.Duration) *mailboxContext { ctx := &mailboxContext{ t: t, clock: clock.NewTestClock(startTime), forwards: make(chan *htlcPacket, 1), } ctx.mailbox = newMemoryMailBox(&mailBoxConfig{ fetchUpdate: func(sid lnwire.ShortChannelID) ( *lnwire.ChannelUpdate, error) { return &lnwire.ChannelUpdate{ ShortChannelID: sid, }, nil }, forwardPackets: ctx.forward, clock: ctx.clock, expiry: expiry, }) ctx.mailbox.Start() return ctx } func (c *mailboxContext) forward(_ chan struct{}, pkts ...*htlcPacket) error { for _, pkt := range pkts { c.forwards <- pkt } return nil } func (c *mailboxContext) sendAdds(start, num int) []*htlcPacket { c.t.Helper() sentPackets := make([]*htlcPacket, num) for i := 0; i < num; i++ { pkt := &htlcPacket{ outgoingChanID: lnwire.NewShortChanIDFromInt( uint64(prand.Int63())), incomingChanID: lnwire.NewShortChanIDFromInt( uint64(prand.Int63())), incomingHTLCID: uint64(start + i), amount: lnwire.MilliSatoshi(prand.Int63()), htlc: &lnwire.UpdateAddHTLC{ ID: uint64(start + i), }, } sentPackets[i] = pkt err := c.mailbox.AddPacket(pkt) if err != nil { c.t.Fatalf("unable to add packet: %v", err) } } return sentPackets } func (c *mailboxContext) receivePkts(pkts []*htlcPacket) { c.t.Helper() for i, expPkt := range pkts { select { case pkt := <-c.mailbox.PacketOutBox(): if reflect.DeepEqual(expPkt, pkt) { continue } c.t.Fatalf("inkey mismatch #%d, want: %v vs "+ "got: %v", i, expPkt.inKey(), pkt.inKey()) case <-time.After(50 * time.Millisecond): c.t.Fatalf("did not receive fail for index %d", i) } } } func (c *mailboxContext) checkFails(adds []*htlcPacket) { c.t.Helper() for i, add := range adds { select { case fail := <-c.forwards: if add.inKey() == fail.inKey() { continue } c.t.Fatalf("inkey mismatch #%d, add: %v vs fail: %v", i, add.inKey(), fail.inKey()) case <-time.After(50 * time.Millisecond): c.t.Fatalf("did not receive fail for index %d", i) } } select { case pkt := <-c.forwards: c.t.Fatalf("unexpected forward: %v", pkt) case <-time.After(50 * time.Millisecond): } } // TestMailBoxFailAdd asserts that FailAdd returns a response to the switch // under various interleavings with other operations on the mailbox. func TestMailBoxFailAdd(t *testing.T) { var ( batchDelay = time.Second expiry = time.Minute firstBatchStart = time.Now() secondBatchStart = time.Now().Add(batchDelay) thirdBatchStart = time.Now().Add(2 * batchDelay) thirdBatchExpiry = thirdBatchStart.Add(expiry) ) ctx := newMailboxContext(t, firstBatchStart, expiry) defer ctx.mailbox.Stop() failAdds := func(adds []*htlcPacket) { for _, add := range adds { ctx.mailbox.FailAdd(add) } } const numBatchPackets = 5 // Send 10 adds, and pull them from the mailbox. firstBatch := ctx.sendAdds(0, numBatchPackets) ctx.receivePkts(firstBatch) // Fail all of these adds, simulating an error adding the HTLCs to the // commitment. We should see a failure message for each. go failAdds(firstBatch) ctx.checkFails(firstBatch) // As a sanity check, Fail all of them again and assert that no // duplicate fails are sent. go failAdds(firstBatch) ctx.checkFails(nil) // Now, send a second batch of adds after a short delay and deliver them // to the link. ctx.clock.SetTime(secondBatchStart) secondBatch := ctx.sendAdds(numBatchPackets, numBatchPackets) ctx.receivePkts(secondBatch) // Reset the packet queue w/o changing the current time. This simulates // the link flapping and coming back up before the second batch's // expiries have elapsed. We should see no failures sent back. err := ctx.mailbox.ResetPackets() if err != nil { t.Fatalf("unable to reset packets: %v", err) } ctx.checkFails(nil) // Redeliver the second batch to the link and hold them there. ctx.receivePkts(secondBatch) // Send a third batch of adds shortly after the second batch. ctx.clock.SetTime(thirdBatchStart) thirdBatch := ctx.sendAdds(2*numBatchPackets, numBatchPackets) // Advance the clock so that the third batch expires. We expect to only // see fails for the third batch, since the second batch is still being // held by the link. ctx.clock.SetTime(thirdBatchExpiry) ctx.checkFails(thirdBatch) // Finally, reset the link which should cause the second batch to be // cancelled immediately. err = ctx.mailbox.ResetPackets() if err != nil { t.Fatalf("unable to reset packets: %v", err) } ctx.checkFails(secondBatch) } // TestMailBoxPacketPrioritization asserts that the mailbox will prioritize // delivering Settle and Fail packets over Adds if both are available for // delivery at the same time. func TestMailBoxPacketPrioritization(t *testing.T) { t.Parallel() // First, we'll create new instance of the current default mailbox // type. ctx := newMailboxContext(t, time.Now(), testExpiry) defer ctx.mailbox.Stop() const numPackets = 5 _, _, aliceChanID, bobChanID := genIDs() // Next we'll send the following sequence of packets: // - Settle1 // - Add1 // - Add2 // - Fail // - Settle2 sentPackets := make([]*htlcPacket, numPackets) for i := 0; i < numPackets; i++ { pkt := &htlcPacket{ outgoingChanID: aliceChanID, outgoingHTLCID: uint64(i), incomingChanID: bobChanID, incomingHTLCID: uint64(i), amount: lnwire.MilliSatoshi(prand.Int63()), } switch i { case 0, 4: // First and last packets are a Settle. A non-Add is // sent first to make the test deterministic w/o needing // to sleep. pkt.htlc = &lnwire.UpdateFulfillHTLC{ID: uint64(i)} case 1, 2: // Next two packets are Adds. pkt.htlc = &lnwire.UpdateAddHTLC{ID: uint64(i)} case 3: // Last packet is a Fail. pkt.htlc = &lnwire.UpdateFailHTLC{ID: uint64(i)} } sentPackets[i] = pkt err := ctx.mailbox.AddPacket(pkt) if err != nil { t.Fatalf("failed to add packet: %v", err) } } // When dequeueing the packets, we expect the following sequence: // - Settle1 // - Fail // - Settle2 // - Add1 // - Add2 // // We expect to see Fail and Settle2 to be delivered before either Add1 // or Add2 due to the prioritization between the split queue. for i := 0; i < numPackets; i++ { select { case pkt := <-ctx.mailbox.PacketOutBox(): var expPkt *htlcPacket switch i { case 0: // First packet should be Settle1. expPkt = sentPackets[0] case 1: // Second packet should be Fail. expPkt = sentPackets[3] case 2: // Third packet should be Settle2. expPkt = sentPackets[4] case 3: // Fourth packet should be Add1. expPkt = sentPackets[1] case 4: // Last packet should be Add2. expPkt = sentPackets[2] } if !reflect.DeepEqual(expPkt, pkt) { t.Fatalf("recvd packet mismatch %d, want: %v, got: %v", i, spew.Sdump(expPkt), spew.Sdump(pkt)) } case <-time.After(50 * time.Millisecond): t.Fatalf("didn't receive packet %d before timeout", i) } } } // TestMailBoxAddExpiry asserts that the mailbox will cancel back Adds that have // reached their expiry time. func TestMailBoxAddExpiry(t *testing.T) { var ( expiry = time.Minute batchDelay = time.Second firstBatchStart = time.Now() firstBatchExpiry = firstBatchStart.Add(expiry) secondBatchStart = firstBatchStart.Add(batchDelay) secondBatchExpiry = secondBatchStart.Add(expiry) ) ctx := newMailboxContext(t, firstBatchStart, expiry) defer ctx.mailbox.Stop() // Each batch will consist of 10 messages. const numBatchPackets = 10 firstBatch := ctx.sendAdds(0, numBatchPackets) ctx.clock.SetTime(secondBatchStart) ctx.checkFails(nil) secondBatch := ctx.sendAdds(numBatchPackets, numBatchPackets) ctx.clock.SetTime(firstBatchExpiry) ctx.checkFails(firstBatch) ctx.clock.SetTime(secondBatchExpiry) ctx.checkFails(secondBatch) } // TestMailBoxDuplicateAddPacket asserts that the mailbox returns an // ErrPacketAlreadyExists failure when two htlcPackets are added with identical // incoming circuit keys. func TestMailBoxDuplicateAddPacket(t *testing.T) { t.Parallel() ctx := newMailboxContext(t, time.Now(), testExpiry) ctx.mailbox.Start() defer ctx.mailbox.Stop() addTwice := func(t *testing.T, pkt *htlcPacket) { // The first add should succeed. err := ctx.mailbox.AddPacket(pkt) if err != nil { t.Fatalf("unable to add packet: %v", err) } // Adding again with the same incoming circuit key should fail. err = ctx.mailbox.AddPacket(pkt) if err != ErrPacketAlreadyExists { t.Fatalf("expected ErrPacketAlreadyExists, got: %v", err) } } // Assert duplicate AddPacket calls fail for all types of HTLCs. addTwice(t, &htlcPacket{ incomingHTLCID: 0, htlc: &lnwire.UpdateAddHTLC{}, }) addTwice(t, &htlcPacket{ incomingHTLCID: 1, htlc: &lnwire.UpdateFulfillHTLC{}, }) addTwice(t, &htlcPacket{ incomingHTLCID: 2, htlc: &lnwire.UpdateFailHTLC{}, }) } // TestMailOrchestrator asserts that the orchestrator properly buffers packets // for channels that haven't been made live, such that they are delivered // immediately after BindLiveShortChanID. It also tests that packets are delivered // readily to mailboxes for channels that are already in the live state. func TestMailOrchestrator(t *testing.T) { t.Parallel() // First, we'll create a new instance of our orchestrator. mo := newMailOrchestrator(&mailOrchConfig{ fetchUpdate: func(sid lnwire.ShortChannelID) ( *lnwire.ChannelUpdate, error) { return &lnwire.ChannelUpdate{ ShortChannelID: sid, }, nil }, forwardPackets: func(_ chan struct{}, pkts ...*htlcPacket) error { return nil }, clock: clock.NewTestClock(time.Now()), expiry: testExpiry, }) defer mo.Stop() // We'll be delivering 10 htlc packets via the orchestrator. const numPackets = 10 const halfPackets = numPackets / 2 // Before any mailbox is created or made live, we will deliver half of // the htlcs via the orchestrator. chanID1, chanID2, aliceChanID, bobChanID := genIDs() sentPackets := make([]*htlcPacket, halfPackets) for i := 0; i < halfPackets; i++ { pkt := &htlcPacket{ outgoingChanID: aliceChanID, outgoingHTLCID: uint64(i), incomingChanID: bobChanID, incomingHTLCID: uint64(i), amount: lnwire.MilliSatoshi(prand.Int63()), htlc: &lnwire.UpdateAddHTLC{ ID: uint64(i), }, } sentPackets[i] = pkt mo.Deliver(pkt.outgoingChanID, pkt) } // Now, initialize a new mailbox for Alice's chanid. mailbox := mo.GetOrCreateMailBox(chanID1, aliceChanID) // Verify that no messages are received, since Alice's mailbox has not // been made live. for i := 0; i < halfPackets; i++ { timeout := time.After(50 * time.Millisecond) select { case <-mailbox.MessageOutBox(): t.Fatalf("should not receive wire msg after reset") case <-timeout: } } // Assign a short chan id to the existing mailbox, make it available for // capturing incoming HTLCs. The HTLCs added above should be delivered // immediately. mo.BindLiveShortChanID(mailbox, chanID1, aliceChanID) // Verify that all of the packets are queued and delivered to Alice's // mailbox. recvdPackets := make([]*htlcPacket, 0, len(sentPackets)) for i := 0; i < halfPackets; i++ { timeout := time.After(5 * time.Second) select { case <-timeout: t.Fatalf("didn't recv pkt %d after timeout", i) case pkt := <-mailbox.PacketOutBox(): recvdPackets = append(recvdPackets, pkt) } } // We should have received half of the total number of packets. if len(recvdPackets) != halfPackets { t.Fatalf("expected %v packets instead got %v", halfPackets, len(recvdPackets)) } // Check that the received packets are equal to the sent packets. if !reflect.DeepEqual(recvdPackets, sentPackets) { t.Fatalf("recvd packets mismatched: expected %v, got %v", spew.Sdump(sentPackets), spew.Sdump(recvdPackets)) } // For the second half of the test, create a new mailbox for Bob and // immediately make it live with an assigned short chan id. mailbox = mo.GetOrCreateMailBox(chanID2, bobChanID) mo.BindLiveShortChanID(mailbox, chanID2, bobChanID) // Create the second half of our htlcs, and deliver them via the // orchestrator. We should be able to receive each of these in order. recvdPackets = make([]*htlcPacket, 0, len(sentPackets)) for i := 0; i < halfPackets; i++ { pkt := &htlcPacket{ outgoingChanID: aliceChanID, outgoingHTLCID: uint64(halfPackets + i), incomingChanID: bobChanID, incomingHTLCID: uint64(halfPackets + i), amount: lnwire.MilliSatoshi(prand.Int63()), htlc: &lnwire.UpdateAddHTLC{ ID: uint64(halfPackets + i), }, } sentPackets[i] = pkt mo.Deliver(pkt.incomingChanID, pkt) timeout := time.After(50 * time.Millisecond) select { case <-timeout: t.Fatalf("didn't recv pkt %d after timeout", halfPackets+i) case pkt := <-mailbox.PacketOutBox(): recvdPackets = append(recvdPackets, pkt) } } // Again, we should have received half of the total number of packets. if len(recvdPackets) != halfPackets { t.Fatalf("expected %v packets instead got %v", halfPackets, len(recvdPackets)) } // Check that the received packets are equal to the sent packets. if !reflect.DeepEqual(recvdPackets, sentPackets) { t.Fatalf("recvd packets mismatched: expected %v, got %v", spew.Sdump(sentPackets), spew.Sdump(recvdPackets)) } }