package sweepbatcher import ( "context" "strings" "testing" "time" "github.com/btcsuite/btcd/btcutil" "github.com/btcsuite/btcd/chaincfg/chainhash" "github.com/btcsuite/btcd/wire" "github.com/lightninglabs/loop/loopdb" "github.com/lightninglabs/loop/test" "github.com/lightningnetwork/lnd/chainntnfs" "github.com/lightningnetwork/lnd/lntypes" "github.com/stretchr/testify/require" ) const ( swapInvoice = "lntb1230n1pjjszzgpp5j76f03wrkya4sm4gxv6az5nmz5aqsvmn4" + "tpguu2sdvdyygedqjgqdq9xyerxcqzzsxqr23ssp5rwzmwtfjmsgranfk8sr" + "4p4gcgmvyd42uug8pxteg2mkk23ndvkqs9qyyssq44ruk3ex59cmv4dm6k4v" + "0kc6c0gcqjs0gkljfyd6c6uatqa2f67xlx3pcg5tnvcae5p3jju8ra77e87d" + "vhhs0jrx53wnc0fq9rkrhmqqelyx7l" eventuallyCheckFrequency = 100 * time.Millisecond ntfnBufferSize = 1024 ) func testMuSig2SignSweep(ctx context.Context, protocolVersion loopdb.ProtocolVersion, swapHash lntypes.Hash, paymentAddr [32]byte, nonce []byte, sweepTxPsbt []byte, prevoutMap map[wire.OutPoint]*wire.TxOut) ( []byte, []byte, error) { return nil, nil, nil } var dummyNotifier = SpendNotifier{ SpendChan: make(chan *SpendDetail, ntfnBufferSize), SpendErrChan: make(chan error, ntfnBufferSize), QuitChan: make(chan bool, ntfnBufferSize), } // TestSweepBatcherBatchCreation tests that sweep requests enter the expected // batch based on their timeout distance. func TestSweepBatcherBatchCreation(t *testing.T) { defer test.Guard(t)() lnd := test.NewMockLnd() ctx, cancel := context.WithCancel(context.Background()) defer cancel() store := loopdb.NewStoreMock(t) batcherStore := NewStoreMock() batcher := NewBatcher(lnd.WalletKit, lnd.ChainNotifier, lnd.Signer, testMuSig2SignSweep, nil, lnd.ChainParams, batcherStore, store) go func() { err := batcher.Run(ctx) if !strings.Contains(err.Error(), "context canceled") { require.NoError(t, err) } }() // Create a sweep request. sweepReq1 := SweepRequest{ SwapHash: lntypes.Hash{1, 1, 1}, Value: 111, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{1, 1}, Index: 1, }, Notifier: &dummyNotifier, } swap1 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111, AmountRequested: 111, }, SwapInvoice: swapInvoice, } err := store.CreateLoopOut(ctx, sweepReq1.SwapHash, swap1) require.NoError(t, err) store.AssertLoopOutStored() // Deliver sweep request to batcher. batcher.sweepReqs <- sweepReq1 // Since a batch was created we check that it registered for its primary // sweep's spend. <-lnd.RegisterSpendChannel // Insert the same swap twice, this should be a noop. batcher.sweepReqs <- sweepReq1 // Once batcher receives sweep request it will eventually spin up a // batch. require.Eventually(t, func() bool { return len(batcher.batches) == 1 }, test.Timeout, eventuallyCheckFrequency) // Create a second sweep request that has a timeout distance less than // our configured threshold. sweepReq2 := SweepRequest{ SwapHash: lntypes.Hash{2, 2, 2}, Value: 222, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{2, 2}, Index: 2, }, Notifier: &dummyNotifier, } swap2 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111 + defaultMaxTimeoutDistance - 1, AmountRequested: 222, }, SwapInvoice: swapInvoice, } err = store.CreateLoopOut(ctx, sweepReq2.SwapHash, swap2) require.NoError(t, err) store.AssertLoopOutStored() batcher.sweepReqs <- sweepReq2 // Batcher should not create a second batch as timeout distance is small // enough. require.Eventually(t, func() bool { return len(batcher.batches) == 1 }, test.Timeout, eventuallyCheckFrequency) // Create a third sweep request that has more timeout distance than // the default. sweepReq3 := SweepRequest{ SwapHash: lntypes.Hash{3, 3, 3}, Value: 333, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{3, 3}, Index: 3, }, Notifier: &dummyNotifier, } swap3 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111 + defaultMaxTimeoutDistance + 1, AmountRequested: 333, }, SwapInvoice: swapInvoice, } err = store.CreateLoopOut(ctx, sweepReq3.SwapHash, swap3) require.NoError(t, err) store.AssertLoopOutStored() batcher.sweepReqs <- sweepReq3 // Batcher should create a second batch as timeout distance is greater // than the threshold require.Eventually(t, func() bool { return len(batcher.batches) == 2 }, test.Timeout, eventuallyCheckFrequency) // Since the second batch got created we check that it registered its // primary sweep's spend. <-lnd.RegisterSpendChannel require.Eventually(t, func() bool { // Verify that each batch has the correct number of sweeps in it. for _, batch := range batcher.batches { switch batch.primarySweepID { case sweepReq1.SwapHash: if len(batch.sweeps) != 2 { return false } case sweepReq3.SwapHash: if len(batch.sweeps) != 1 { return false } } } return true }, test.Timeout, eventuallyCheckFrequency) // Check that all sweeps were stored. require.True(t, batcherStore.AssertSweepStored(sweepReq1.SwapHash)) require.True(t, batcherStore.AssertSweepStored(sweepReq2.SwapHash)) require.True(t, batcherStore.AssertSweepStored(sweepReq3.SwapHash)) } // TestSweepBatcherSimpleLifecycle tests the simple lifecycle of the batches // that are created and run by the batcher. func TestSweepBatcherSimpleLifecycle(t *testing.T) { defer test.Guard(t)() lnd := test.NewMockLnd() ctx, cancel := context.WithCancel(context.Background()) defer cancel() store := loopdb.NewStoreMock(t) batcherStore := NewStoreMock() batcher := NewBatcher(lnd.WalletKit, lnd.ChainNotifier, lnd.Signer, testMuSig2SignSweep, nil, lnd.ChainParams, batcherStore, store) go func() { err := batcher.Run(ctx) if !strings.Contains(err.Error(), "context canceled") { require.NoError(t, err) } }() // Create a sweep request. sweepReq1 := SweepRequest{ SwapHash: lntypes.Hash{1, 1, 1}, Value: 111, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{1, 1}, Index: 1, }, Notifier: &dummyNotifier, } swap1 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111, AmountRequested: 111, }, SwapInvoice: swapInvoice, SweepConfTarget: 111, } err := store.CreateLoopOut(ctx, sweepReq1.SwapHash, swap1) require.NoError(t, err) store.AssertLoopOutStored() // Deliver sweep request to batcher. batcher.sweepReqs <- sweepReq1 // Eventually request will be consumed and a new batch will spin up. require.Eventually(t, func() bool { return len(batcher.batches) == 1 }, test.Timeout, eventuallyCheckFrequency) // When batch is successfully created it will execute it's first step, // which leads to a spend monitor of the primary sweep. <-lnd.RegisterSpendChannel // Find the batch and assign it to a local variable for easier access. batch := &batch{} for _, btch := range batcher.batches { if btch.primarySweepID == sweepReq1.SwapHash { batch = btch } } require.Eventually(t, func() bool { // Batch should have the sweep stored. return len(batch.sweeps) == 1 }, test.Timeout, eventuallyCheckFrequency) // The primary sweep id should be that of the first inserted sweep. require.Equal(t, batch.primarySweepID, sweepReq1.SwapHash) err = lnd.NotifyHeight(601) require.NoError(t, err) // After receiving a height notification the batch will step again, // leading to a new spend monitoring. require.Eventually(t, func() bool { return batch.currentHeight == 601 }, test.Timeout, eventuallyCheckFrequency) // Create the spending tx that will trigger the spend monitor of the // batch. spendingTx := &wire.MsgTx{ Version: 1, // Since the spend monitor is registered on the primary sweep's // outpoint we insert that outpoint here. TxIn: []*wire.TxIn{ { PreviousOutPoint: sweepReq1.Outpoint, }, }, TxOut: []*wire.TxOut{ { PkScript: []byte{3, 2, 1}, }, }, } spendingTxHash := spendingTx.TxHash() // Mock the spend notification that spends the swap. spendDetail := &chainntnfs.SpendDetail{ SpentOutPoint: &sweepReq1.Outpoint, SpendingTx: spendingTx, SpenderTxHash: &spendingTxHash, SpenderInputIndex: 0, SpendingHeight: 601, } // We notify the spend. lnd.SpendChannel <- spendDetail // After receiving the spend, the batch is now monitoring for confs. <-lnd.RegisterConfChannel // The batch should eventually read the spend notification and progress // its state to closed. require.Eventually(t, func() bool { return batch.state == Closed }, test.Timeout, eventuallyCheckFrequency) err = lnd.NotifyHeight(604) require.NoError(t, err) // We mock the tx confirmation notification. lnd.ConfChannel <- &chainntnfs.TxConfirmation{ Tx: spendingTx, } // Eventually the batch receives the confirmation notification and // confirms itself. require.Eventually(t, func() bool { return batch.isComplete() }, test.Timeout, eventuallyCheckFrequency) } // TestSweepBatcherSweepReentry tests that when an old version of the batch tx // gets confirmed the sweep leftovers are sent back to the batcher. func TestSweepBatcherSweepReentry(t *testing.T) { defer test.Guard(t)() lnd := test.NewMockLnd() ctx, cancel := context.WithCancel(context.Background()) defer cancel() store := loopdb.NewStoreMock(t) batcherStore := NewStoreMock() batcher := NewBatcher(lnd.WalletKit, lnd.ChainNotifier, lnd.Signer, testMuSig2SignSweep, nil, lnd.ChainParams, batcherStore, store) go func() { err := batcher.Run(ctx) if !strings.Contains(err.Error(), "context canceled") { require.NoError(t, err) } }() // Create some sweep requests with timeouts not too far away, in order // to enter the same batch. sweepReq1 := SweepRequest{ SwapHash: lntypes.Hash{1, 1, 1}, Value: 111, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{1, 1}, Index: 1, }, Notifier: &dummyNotifier, } swap1 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111, AmountRequested: 111, }, SwapInvoice: swapInvoice, SweepConfTarget: 111, } err := store.CreateLoopOut(ctx, sweepReq1.SwapHash, swap1) require.NoError(t, err) store.AssertLoopOutStored() sweepReq2 := SweepRequest{ SwapHash: lntypes.Hash{2, 2, 2}, Value: 222, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{2, 2}, Index: 2, }, Notifier: &dummyNotifier, } swap2 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111, AmountRequested: 222, }, SwapInvoice: swapInvoice, SweepConfTarget: 111, } err = store.CreateLoopOut(ctx, sweepReq2.SwapHash, swap2) require.NoError(t, err) store.AssertLoopOutStored() sweepReq3 := SweepRequest{ SwapHash: lntypes.Hash{3, 3, 3}, Value: 333, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{3, 3}, Index: 3, }, Notifier: &dummyNotifier, } swap3 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111, AmountRequested: 333, }, SwapInvoice: swapInvoice, SweepConfTarget: 111, } err = store.CreateLoopOut(ctx, sweepReq3.SwapHash, swap3) require.NoError(t, err) store.AssertLoopOutStored() // Feed the sweeps to the batcher. batcher.sweepReqs <- sweepReq1 // After inserting the primary (first) sweep, a spend monitor should be // registered. <-lnd.RegisterSpendChannel batcher.sweepReqs <- sweepReq2 batcher.sweepReqs <- sweepReq3 // Batcher should create a batch for the sweeps. require.Eventually(t, func() bool { return len(batcher.batches) == 1 }, test.Timeout, eventuallyCheckFrequency) // Find the batch and store it in a local variable for easier access. b := &batch{} for _, btch := range batcher.batches { if btch.primarySweepID == sweepReq1.SwapHash { b = btch } } // Batcher should contain all sweeps. require.Eventually(t, func() bool { return len(b.sweeps) == 3 }, test.Timeout, eventuallyCheckFrequency) // Verify that the batch has a primary sweep id that matches the first // inserted sweep, sweep1. require.Equal(t, b.primarySweepID, sweepReq1.SwapHash) // Create the spending tx. In order to simulate an older version of the // batch transaction being confirmed, we only insert the primary sweep's // outpoint as a TxIn. This means that the other two sweeps did not // appear in the spending transaction. (This simulates a possible // scenario caused by RBF replacements.) spendingTx := &wire.MsgTx{ Version: 1, TxIn: []*wire.TxIn{ { PreviousOutPoint: sweepReq1.Outpoint, }, }, TxOut: []*wire.TxOut{ { Value: int64(sweepReq1.Value.ToUnit(btcutil.AmountSatoshi)), PkScript: []byte{3, 2, 1}, }, }, } spendingTxHash := spendingTx.TxHash() spendDetail := &chainntnfs.SpendDetail{ SpentOutPoint: &sweepReq1.Outpoint, SpendingTx: spendingTx, SpenderTxHash: &spendingTxHash, SpenderInputIndex: 0, SpendingHeight: 601, } // Send the spending notification to the mock channel. lnd.SpendChannel <- spendDetail // After receiving the spend notification the batch should progress to // the next step, which is monitoring for confirmations. <-lnd.RegisterConfChannel // Eventually the batch reads the notification and proceeds to a closed // state. require.Eventually(t, func() bool { return b.state == Closed }, test.Timeout, eventuallyCheckFrequency) // While handling the spend notification the batch should detect that // some sweeps did not appear in the spending tx, therefore it redirects // them back to the batcher and the batcher inserts them in a new batch. require.Eventually(t, func() bool { return len(batcher.batches) == 2 }, test.Timeout, eventuallyCheckFrequency) // Since second batch was created we check that it registered for its // primary sweep's spend. <-lnd.RegisterSpendChannel // We mock the confirmation notification. lnd.ConfChannel <- &chainntnfs.TxConfirmation{ Tx: spendingTx, } // Eventually the batch receives the confirmation notification, // gracefully exits and the batcher deletes it. require.Eventually(t, func() bool { return len(batcher.batches) == 1 }, test.Timeout, eventuallyCheckFrequency) // Find the other batch, which includes the sweeps that did not appear // in the spending tx. b = &batch{} for _, btch := range batcher.batches { b = btch } // After all the sweeps enter, it should contain 2 sweeps. require.Eventually(t, func() bool { return len(b.sweeps) == 2 }, test.Timeout, eventuallyCheckFrequency) // The batch should be in an open state. require.Equal(t, b.state, Open) } // TestSweepBatcherNonWalletAddr tests that sweep requests that sweep to a non // wallet address enter individual batches. func TestSweepBatcherNonWalletAddr(t *testing.T) { defer test.Guard(t)() lnd := test.NewMockLnd() ctx, cancel := context.WithCancel(context.Background()) defer cancel() store := loopdb.NewStoreMock(t) batcherStore := NewStoreMock() batcher := NewBatcher(lnd.WalletKit, lnd.ChainNotifier, lnd.Signer, testMuSig2SignSweep, nil, lnd.ChainParams, batcherStore, store) go func() { err := batcher.Run(ctx) if !strings.Contains(err.Error(), "context canceled") { require.NoError(t, err) } }() // Create a sweep request. sweepReq1 := SweepRequest{ SwapHash: lntypes.Hash{1, 1, 1}, Value: 111, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{1, 1}, Index: 1, }, Notifier: &dummyNotifier, } swap1 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111, AmountRequested: 111, }, IsExternalAddr: true, SwapInvoice: swapInvoice, } err := store.CreateLoopOut(ctx, sweepReq1.SwapHash, swap1) require.NoError(t, err) store.AssertLoopOutStored() // Deliver sweep request to batcher. batcher.sweepReqs <- sweepReq1 // Once batcher receives sweep request it will eventually spin up a // batch. require.Eventually(t, func() bool { return len(batcher.batches) == 1 }, test.Timeout, eventuallyCheckFrequency) // Since a batch was created we check that it registered for its primary // sweep's spend. <-lnd.RegisterSpendChannel // Insert the same swap twice, this should be a noop. batcher.sweepReqs <- sweepReq1 // Create a second sweep request that has a timeout distance less than // our configured threshold. sweepReq2 := SweepRequest{ SwapHash: lntypes.Hash{2, 2, 2}, Value: 222, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{2, 2}, Index: 2, }, Notifier: &dummyNotifier, } swap2 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111 + defaultMaxTimeoutDistance - 1, AmountRequested: 222, }, SwapInvoice: swapInvoice, IsExternalAddr: true, } err = store.CreateLoopOut(ctx, sweepReq2.SwapHash, swap2) require.NoError(t, err) store.AssertLoopOutStored() batcher.sweepReqs <- sweepReq2 // Batcher should create a second batch as first batch is a non wallet // addr batch. require.Eventually(t, func() bool { return len(batcher.batches) == 2 }, test.Timeout, eventuallyCheckFrequency) // Since a batch was created we check that it registered for its primary // sweep's spend. <-lnd.RegisterSpendChannel // Create a third sweep request that has more timeout distance than // the default. sweepReq3 := SweepRequest{ SwapHash: lntypes.Hash{3, 3, 3}, Value: 333, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{3, 3}, Index: 3, }, Notifier: &dummyNotifier, } swap3 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111 + defaultMaxTimeoutDistance + 1, AmountRequested: 333, }, SwapInvoice: swapInvoice, IsExternalAddr: true, } err = store.CreateLoopOut(ctx, sweepReq3.SwapHash, swap3) require.NoError(t, err) store.AssertLoopOutStored() batcher.sweepReqs <- sweepReq3 // Batcher should create a new batch as timeout distance is greater than // the threshold require.Eventually(t, func() bool { return len(batcher.batches) == 3 }, test.Timeout, eventuallyCheckFrequency) // Since a batch was created we check that it registered for its primary // sweep's spend. <-lnd.RegisterSpendChannel require.Eventually(t, func() bool { // Verify that each batch has the correct number of sweeps in it. for _, batch := range batcher.batches { switch batch.primarySweepID { case sweepReq1.SwapHash: if len(batch.sweeps) != 1 { return false } case sweepReq2.SwapHash: if len(batch.sweeps) != 1 { return false } case sweepReq3.SwapHash: if len(batch.sweeps) != 1 { return false } } } return true }, test.Timeout, eventuallyCheckFrequency) // Check that all sweeps were stored. require.True(t, batcherStore.AssertSweepStored(sweepReq1.SwapHash)) require.True(t, batcherStore.AssertSweepStored(sweepReq2.SwapHash)) require.True(t, batcherStore.AssertSweepStored(sweepReq3.SwapHash)) } // TestSweepBatcherComposite tests that sweep requests that sweep to both wallet // addresses and non-wallet addresses enter the correct batches. func TestSweepBatcherComposite(t *testing.T) { defer test.Guard(t)() lnd := test.NewMockLnd() ctx, cancel := context.WithCancel(context.Background()) defer cancel() store := loopdb.NewStoreMock(t) batcherStore := NewStoreMock() batcher := NewBatcher(lnd.WalletKit, lnd.ChainNotifier, lnd.Signer, testMuSig2SignSweep, nil, lnd.ChainParams, batcherStore, store) go func() { err := batcher.Run(ctx) if !strings.Contains(err.Error(), "context canceled") { require.NoError(t, err) } }() // Create a sweep request. sweepReq1 := SweepRequest{ SwapHash: lntypes.Hash{1, 1, 1}, Value: 111, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{1, 1}, Index: 1, }, Notifier: &dummyNotifier, } swap1 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111, AmountRequested: 111, }, SwapInvoice: swapInvoice, } err := store.CreateLoopOut(ctx, sweepReq1.SwapHash, swap1) require.NoError(t, err) store.AssertLoopOutStored() // Create a second sweep request that has a timeout distance less than // our configured threshold. sweepReq2 := SweepRequest{ SwapHash: lntypes.Hash{2, 2, 2}, Value: 222, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{2, 2}, Index: 2, }, Notifier: &dummyNotifier, } swap2 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111 + defaultMaxTimeoutDistance - 1, AmountRequested: 222, }, SwapInvoice: swapInvoice, } err = store.CreateLoopOut(ctx, sweepReq2.SwapHash, swap2) require.NoError(t, err) store.AssertLoopOutStored() // Create a third sweep request that has less timeout distance than the // default max, but is not spending to a wallet address. sweepReq3 := SweepRequest{ SwapHash: lntypes.Hash{3, 3, 3}, Value: 333, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{3, 3}, Index: 3, }, Notifier: &dummyNotifier, } swap3 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111 + defaultMaxTimeoutDistance - 3, AmountRequested: 333, }, SwapInvoice: swapInvoice, IsExternalAddr: true, } err = store.CreateLoopOut(ctx, sweepReq3.SwapHash, swap3) require.NoError(t, err) store.AssertLoopOutStored() // Create a fourth sweep request that has a timeout which is not valid // for the first batch, so it will cause it to create a new batch. sweepReq4 := SweepRequest{ SwapHash: lntypes.Hash{4, 4, 4}, Value: 444, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{4, 4}, Index: 4, }, Notifier: &dummyNotifier, } swap4 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111 + defaultMaxTimeoutDistance + 1, AmountRequested: 444, }, SwapInvoice: swapInvoice, } err = store.CreateLoopOut(ctx, sweepReq4.SwapHash, swap4) require.NoError(t, err) store.AssertLoopOutStored() // Create a fifth sweep request that has a timeout which is not valid // for the first batch, but a valid timeout for the new batch. sweepReq5 := SweepRequest{ SwapHash: lntypes.Hash{5, 5, 5}, Value: 555, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{5, 5}, Index: 5, }, Notifier: &dummyNotifier, } swap5 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111 + defaultMaxTimeoutDistance + 5, AmountRequested: 555, }, SwapInvoice: swapInvoice, } err = store.CreateLoopOut(ctx, sweepReq5.SwapHash, swap5) require.NoError(t, err) store.AssertLoopOutStored() // Create a sixth sweep request that has a valid timeout for the new // batch, but is paying to a non-wallet address. sweepReq6 := SweepRequest{ SwapHash: lntypes.Hash{6, 6, 6}, Value: 666, Outpoint: wire.OutPoint{ Hash: chainhash.Hash{6, 6}, Index: 6, }, Notifier: &dummyNotifier, } swap6 := &loopdb.LoopOutContract{ SwapContract: loopdb.SwapContract{ CltvExpiry: 111 + defaultMaxTimeoutDistance + 6, AmountRequested: 666, }, SwapInvoice: swapInvoice, IsExternalAddr: true, } err = store.CreateLoopOut(ctx, sweepReq6.SwapHash, swap6) require.NoError(t, err) store.AssertLoopOutStored() // Deliver sweep request to batcher. batcher.sweepReqs <- sweepReq1 // Once batcher receives sweep request it will eventually spin up a // batch. require.Eventually(t, func() bool { return len(batcher.batches) == 1 }, test.Timeout, eventuallyCheckFrequency) // Since a batch was created we check that it registered for its primary // sweep's spend. <-lnd.RegisterSpendChannel // Insert the same swap twice, this should be a noop. batcher.sweepReqs <- sweepReq1 batcher.sweepReqs <- sweepReq2 // Batcher should not create a second batch as timeout distance is small // enough. require.Eventually(t, func() bool { return len(batcher.batches) == 1 }, test.Timeout, eventuallyCheckFrequency) batcher.sweepReqs <- sweepReq3 // Batcher should create a second batch as this sweep pays to a non // wallet address. require.Eventually(t, func() bool { return len(batcher.batches) == 2 }, test.Timeout, eventuallyCheckFrequency) // Since a batch was created we check that it registered for its primary // sweep's spend. <-lnd.RegisterSpendChannel batcher.sweepReqs <- sweepReq4 // Batcher should create a third batch as timeout distance is greater // than the threshold. require.Eventually(t, func() bool { return len(batcher.batches) == 3 }, test.Timeout, eventuallyCheckFrequency) // Since a batch was created we check that it registered for its primary // sweep's spend. <-lnd.RegisterSpendChannel batcher.sweepReqs <- sweepReq5 // Batcher should not create a fourth batch as timeout distance is small // enough for it to join the last batch. require.Eventually(t, func() bool { return len(batcher.batches) == 3 }, test.Timeout, eventuallyCheckFrequency) batcher.sweepReqs <- sweepReq6 // Batcher should create a fourth batch as this sweep pays to a non // wallet address. require.Eventually(t, func() bool { return len(batcher.batches) == 4 }, test.Timeout, eventuallyCheckFrequency) // Since a batch was created we check that it registered for its primary // sweep's spend. <-lnd.RegisterSpendChannel require.Eventually(t, func() bool { // Verify that each batch has the correct number of sweeps in // it. for _, batch := range batcher.batches { switch batch.primarySweepID { case sweepReq1.SwapHash: if len(batch.sweeps) != 2 { return false } case sweepReq3.SwapHash: if len(batch.sweeps) != 1 { return false } case sweepReq4.SwapHash: if len(batch.sweeps) != 2 { return false } case sweepReq6.SwapHash: if len(batch.sweeps) != 1 { return false } } } return true }, test.Timeout, eventuallyCheckFrequency) // Check that all sweeps were stored. require.True(t, batcherStore.AssertSweepStored(sweepReq1.SwapHash)) require.True(t, batcherStore.AssertSweepStored(sweepReq2.SwapHash)) require.True(t, batcherStore.AssertSweepStored(sweepReq3.SwapHash)) require.True(t, batcherStore.AssertSweepStored(sweepReq4.SwapHash)) require.True(t, batcherStore.AssertSweepStored(sweepReq5.SwapHash)) require.True(t, batcherStore.AssertSweepStored(sweepReq6.SwapHash)) } // makeTestTx creates a test transaction with a single output of the given // value. func makeTestTx(value int64) *wire.MsgTx { tx := wire.NewMsgTx(wire.TxVersion) tx.AddTxOut(wire.NewTxOut(value, nil)) return tx } // TestGetFeePortionForSweep tests that the fee portion for a sweep is correctly // calculated. func TestGetFeePortionForSweep(t *testing.T) { tests := []struct { name string spendTxValue int64 numSweeps int totalSweptAmt btcutil.Amount expectedFeePortion btcutil.Amount expectedRoundingDiff btcutil.Amount }{ { "Even Split", 100, 5, 200, 20, 0, }, { "Single Sweep", 100, 1, 200, 100, 0, }, { "With Rounding Diff", 200, 4, 350, 37, 2, }, } for _, tt := range tests { t.Run(tt.name, func(t *testing.T) { spendTx := makeTestTx(tt.spendTxValue) feePortion, roundingDiff := getFeePortionForSweep( spendTx, tt.numSweeps, tt.totalSweptAmt, ) require.Equal(t, tt.expectedFeePortion, feePortion) require.Equal(t, tt.expectedRoundingDiff, roundingDiff) }) } }