package chainntnfs_test import ( "sync" "testing" "github.com/btcsuite/btcd/chaincfg/chainhash" "github.com/btcsuite/btcd/wire" "github.com/btcsuite/btcutil" "github.com/lightningnetwork/lnd/chainntnfs" ) var ( zeroHash chainhash.Hash zeroOutPoint wire.OutPoint ) type mockHintCache struct { mu sync.Mutex confHints map[chainhash.Hash]uint32 spendHints map[wire.OutPoint]uint32 } var _ chainntnfs.SpendHintCache = (*mockHintCache)(nil) var _ chainntnfs.ConfirmHintCache = (*mockHintCache)(nil) func (c *mockHintCache) CommitSpendHint(heightHint uint32, ops ...wire.OutPoint) error { c.mu.Lock() defer c.mu.Unlock() for _, op := range ops { c.spendHints[op] = heightHint } return nil } func (c *mockHintCache) QuerySpendHint(op wire.OutPoint) (uint32, error) { c.mu.Lock() defer c.mu.Unlock() hint, ok := c.spendHints[op] if !ok { return 0, chainntnfs.ErrSpendHintNotFound } return hint, nil } func (c *mockHintCache) PurgeSpendHint(ops ...wire.OutPoint) error { c.mu.Lock() defer c.mu.Unlock() for _, op := range ops { delete(c.spendHints, op) } return nil } func (c *mockHintCache) CommitConfirmHint(heightHint uint32, txids ...chainhash.Hash) error { c.mu.Lock() defer c.mu.Unlock() for _, txid := range txids { c.confHints[txid] = heightHint } return nil } func (c *mockHintCache) QueryConfirmHint(txid chainhash.Hash) (uint32, error) { c.mu.Lock() defer c.mu.Unlock() hint, ok := c.confHints[txid] if !ok { return 0, chainntnfs.ErrConfirmHintNotFound } return hint, nil } func (c *mockHintCache) PurgeConfirmHint(txids ...chainhash.Hash) error { c.mu.Lock() defer c.mu.Unlock() for _, txid := range txids { delete(c.confHints, txid) } return nil } func newMockHintCache() *mockHintCache { return &mockHintCache{ confHints: make(map[chainhash.Hash]uint32), spendHints: make(map[wire.OutPoint]uint32), } } // TestTxNotifierFutureConfDispatch tests that the TxNotifier dispatches // registered notifications when a transaction confirms after registration. func TestTxNotifierFutureConfDispatch(t *testing.T) { t.Parallel() const ( tx1NumConfs uint32 = 1 tx2NumConfs uint32 = 2 ) var ( tx1 = wire.MsgTx{Version: 1} tx2 = wire.MsgTx{Version: 2} tx3 = wire.MsgTx{Version: 3} ) hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(10, 100, hintCache, hintCache) // Create the test transactions and register them with the TxNotifier // before including them in a block to receive future // notifications. tx1Hash := tx1.TxHash() ntfn1 := chainntnfs.ConfNtfn{ TxID: &tx1Hash, NumConfirmations: tx1NumConfs, Event: chainntnfs.NewConfirmationEvent(tx1NumConfs), } if _, err := n.RegisterConf(&ntfn1); err != nil { t.Fatalf("unable to register ntfn: %v", err) } tx2Hash := tx2.TxHash() ntfn2 := chainntnfs.ConfNtfn{ TxID: &tx2Hash, NumConfirmations: tx2NumConfs, Event: chainntnfs.NewConfirmationEvent(tx2NumConfs), } if _, err := n.RegisterConf(&ntfn2); err != nil { t.Fatalf("unable to register ntfn: %v", err) } // We should not receive any notifications from both transactions // since they have not been included in a block yet. select { case <-ntfn1.Event.Updates: t.Fatal("Received unexpected confirmation update for tx1") case txConf := <-ntfn1.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx1: %v", txConf) default: } select { case <-ntfn2.Event.Updates: t.Fatal("Received unexpected confirmation update for tx2") case txConf := <-ntfn2.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx2: %v", txConf) default: } // Include the transactions in a block and add it to the TxNotifier. // This should confirm tx1, but not tx2. block1 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{&tx1, &tx2, &tx3}, }) err := n.ConnectTip( block1.Hash(), 11, block1.Transactions(), ) if err != nil { t.Fatalf("Failed to connect block: %v", err) } // We should only receive one update for tx1 since it only requires // one confirmation and it already met it. select { case numConfsLeft := <-ntfn1.Event.Updates: const expected = 0 if numConfsLeft != expected { t.Fatalf("Received incorrect confirmation update: tx1 "+ "expected %d confirmations left, got %d", expected, numConfsLeft) } default: t.Fatal("Expected confirmation update for tx1") } // A confirmation notification for this tranaction should be dispatched, // as it only required one confirmation. select { case txConf := <-ntfn1.Event.Confirmed: expectedConf := chainntnfs.TxConfirmation{ BlockHash: block1.Hash(), BlockHeight: 11, TxIndex: 0, } assertConfDetails(t, txConf, &expectedConf) default: t.Fatalf("Expected confirmation for tx1") } // We should only receive one update for tx2 since it only has one // confirmation so far and it requires two. select { case numConfsLeft := <-ntfn2.Event.Updates: const expected = 1 if numConfsLeft != expected { t.Fatalf("Received incorrect confirmation update: tx2 "+ "expected %d confirmations left, got %d", expected, numConfsLeft) } default: t.Fatal("Expected confirmation update for tx2") } // A confirmation notification for tx2 should not be dispatched yet, as // it requires one more confirmation. select { case txConf := <-ntfn2.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx2: %v", txConf) default: } // Create a new block and add it to the TxNotifier at the next height. // This should confirm tx2. block2 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{&tx3}, }) err = n.ConnectTip(block2.Hash(), 12, block2.Transactions()) if err != nil { t.Fatalf("Failed to connect block: %v", err) } // We should not receive any event notifications for tx1 since it has // already been confirmed. select { case <-ntfn1.Event.Updates: t.Fatal("Received unexpected confirmation update for tx1") case txConf := <-ntfn1.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx1: %v", txConf) default: } // We should only receive one update since the last at the new height, // indicating how many confirmations are still left. select { case numConfsLeft := <-ntfn2.Event.Updates: const expected = 0 if numConfsLeft != expected { t.Fatalf("Received incorrect confirmation update: tx2 "+ "expected %d confirmations left, got %d", expected, numConfsLeft) } default: t.Fatal("Expected confirmation update for tx2") } // A confirmation notification for tx2 should be dispatched, since it // now meets its required number of confirmations. select { case txConf := <-ntfn2.Event.Confirmed: expectedConf := chainntnfs.TxConfirmation{ BlockHash: block1.Hash(), BlockHeight: 11, TxIndex: 1, } assertConfDetails(t, txConf, &expectedConf) default: t.Fatalf("Expected confirmation for tx2") } } // TestTxNotifierHistoricalConfDispatch tests that the TxNotifier dispatches // registered notifications when the transaction is confirmed before // registration. func TestTxNotifierHistoricalConfDispatch(t *testing.T) { t.Parallel() const ( tx1NumConfs uint32 = 1 tx2NumConfs uint32 = 3 ) var ( tx1 = wire.MsgTx{Version: 1} tx2 = wire.MsgTx{Version: 2} tx3 = wire.MsgTx{Version: 3} ) hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(10, 100, hintCache, hintCache) // Create the test transactions at a height before the TxNotifier's // starting height so that they are confirmed once registering them. tx1Hash := tx1.TxHash() ntfn1 := chainntnfs.ConfNtfn{ ConfID: 0, TxID: &tx1Hash, NumConfirmations: tx1NumConfs, Event: chainntnfs.NewConfirmationEvent(tx1NumConfs), } if _, err := n.RegisterConf(&ntfn1); err != nil { t.Fatalf("unable to register ntfn: %v", err) } tx2Hash := tx2.TxHash() ntfn2 := chainntnfs.ConfNtfn{ ConfID: 1, TxID: &tx2Hash, NumConfirmations: tx2NumConfs, Event: chainntnfs.NewConfirmationEvent(tx2NumConfs), } if _, err := n.RegisterConf(&ntfn2); err != nil { t.Fatalf("unable to register ntfn: %v", err) } // Update tx1 with its confirmation details. We should only receive one // update since it only requires one confirmation and it already met it. txConf1 := chainntnfs.TxConfirmation{ BlockHash: &zeroHash, BlockHeight: 9, TxIndex: 1, } err := n.UpdateConfDetails(tx1Hash, &txConf1) if err != nil { t.Fatalf("unable to update conf details: %v", err) } select { case numConfsLeft := <-ntfn1.Event.Updates: const expected = 0 if numConfsLeft != expected { t.Fatalf("Received incorrect confirmation update: tx1 "+ "expected %d confirmations left, got %d", expected, numConfsLeft) } default: t.Fatal("Expected confirmation update for tx1") } // A confirmation notification for tx1 should also be dispatched. select { case txConf := <-ntfn1.Event.Confirmed: assertConfDetails(t, txConf, &txConf1) default: t.Fatalf("Expected confirmation for tx1") } // Update tx2 with its confirmation details. This should not trigger a // confirmation notification since it hasn't reached its required number // of confirmations, but we should receive a confirmation update // indicating how many confirmation are left. txConf2 := chainntnfs.TxConfirmation{ BlockHash: &zeroHash, BlockHeight: 9, TxIndex: 2, } err = n.UpdateConfDetails(tx2Hash, &txConf2) if err != nil { t.Fatalf("unable to update conf details: %v", err) } select { case numConfsLeft := <-ntfn2.Event.Updates: const expected = 1 if numConfsLeft != expected { t.Fatalf("Received incorrect confirmation update: tx2 "+ "expected %d confirmations left, got %d", expected, numConfsLeft) } default: t.Fatal("Expected confirmation update for tx2") } select { case txConf := <-ntfn2.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx2: %v", txConf) default: } // Create a new block and add it to the TxNotifier at the next height. // This should confirm tx2. block := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{&tx3}, }) err = n.ConnectTip(block.Hash(), 11, block.Transactions()) if err != nil { t.Fatalf("Failed to connect block: %v", err) } // We should not receive any event notifications for tx1 since it has // already been confirmed. select { case <-ntfn1.Event.Updates: t.Fatal("Received unexpected confirmation update for tx1") case txConf := <-ntfn1.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx1: %v", txConf) default: } // We should only receive one update for tx2 since the last one, // indicating how many confirmations are still left. select { case numConfsLeft := <-ntfn2.Event.Updates: const expected = 0 if numConfsLeft != expected { t.Fatalf("Received incorrect confirmation update: tx2 "+ "expected %d confirmations left, got %d", expected, numConfsLeft) } default: t.Fatal("Expected confirmation update for tx2") } // A confirmation notification for tx2 should be dispatched, as it met // its required number of confirmations. select { case txConf := <-ntfn2.Event.Confirmed: assertConfDetails(t, txConf, &txConf2) default: t.Fatalf("Expected confirmation for tx2") } } // TestTxNotifierFutureSpendDispatch tests that the TxNotifier dispatches // registered notifications when an outpoint is spent after registration. func TestTxNotifierFutureSpendDispatch(t *testing.T) { t.Parallel() hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(10, 100, hintCache, hintCache) // We'll start off by registering for a spend notification of an // outpoint. ntfn := &chainntnfs.SpendNtfn{ OutPoint: zeroOutPoint, Event: chainntnfs.NewSpendEvent(nil), } if _, err := n.RegisterSpend(ntfn); err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } // We should not receive a notification as the outpoint has not been // spent yet. select { case <-ntfn.Event.Spend: t.Fatal("received unexpected spend notification") default: } // Construct the details of the spending transaction of the outpoint // above. We'll include it in the next block, which should trigger a // spend notification. spendTx := wire.NewMsgTx(2) spendTx.AddTxIn(&wire.TxIn{PreviousOutPoint: zeroOutPoint}) spendTxHash := spendTx.TxHash() block := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{spendTx}, }) err := n.ConnectTip(block.Hash(), 11, block.Transactions()) if err != nil { t.Fatalf("unable to connect block: %v", err) } expectedSpendDetails := &chainntnfs.SpendDetail{ SpentOutPoint: &ntfn.OutPoint, SpenderTxHash: &spendTxHash, SpendingTx: spendTx, SpenderInputIndex: 0, SpendingHeight: 11, } // Ensure that the details of the notification match as expected. select { case spendDetails := <-ntfn.Event.Spend: assertSpendDetails(t, spendDetails, expectedSpendDetails) default: t.Fatal("expected to receive spend details") } // Finally, we'll ensure that if the spending transaction has also been // spent, then we don't receive another spend notification. prevOut := wire.OutPoint{Hash: spendTxHash, Index: 0} spendOfSpend := wire.NewMsgTx(2) spendOfSpend.AddTxIn(&wire.TxIn{PreviousOutPoint: prevOut}) block = btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{spendOfSpend}, }) err = n.ConnectTip(block.Hash(), 12, block.Transactions()) if err != nil { t.Fatalf("unable to connect block: %v", err) } select { case <-ntfn.Event.Spend: t.Fatal("received unexpected spend notification") default: } } // TestTxNotifierHistoricalSpendDispatch tests that the TxNotifier dispatches // registered notifications when an outpoint is spent before registration. func TestTxNotifierHistoricalSpendDispatch(t *testing.T) { t.Parallel() const startingHeight = 10 hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(startingHeight, 100, hintCache, hintCache) // We'll start by constructing the spending details of the outpoint // below. spentOutpoint := zeroOutPoint spendTx := wire.NewMsgTx(2) spendTx.AddTxIn(&wire.TxIn{PreviousOutPoint: zeroOutPoint}) spendTxHash := spendTx.TxHash() expectedSpendDetails := &chainntnfs.SpendDetail{ SpentOutPoint: &spentOutpoint, SpenderTxHash: &spendTxHash, SpendingTx: spendTx, SpenderInputIndex: 0, SpendingHeight: startingHeight - 1, } // We'll register for a spend notification of the outpoint and ensure // that a notification isn't dispatched. ntfn := &chainntnfs.SpendNtfn{ OutPoint: spentOutpoint, Event: chainntnfs.NewSpendEvent(nil), } if _, err := n.RegisterSpend(ntfn); err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } select { case <-ntfn.Event.Spend: t.Fatal("received unexpected spend notification") default: } // Because we're interested in testing the case of a historical spend, // we'll hand off the spending details of the outpoint to the notifier // as it is not possible for it to view historical events in the chain. // By doing this, we replicate the functionality of the ChainNotifier. err := n.UpdateSpendDetails(ntfn.OutPoint, expectedSpendDetails) if err != nil { t.Fatalf("unable to update spend details: %v", err) } // Now that we have the spending details, we should receive a spend // notification. We'll ensure that the details match as intended. select { case spendDetails := <-ntfn.Event.Spend: assertSpendDetails(t, spendDetails, expectedSpendDetails) default: t.Fatalf("expected to receive spend details") } // Finally, we'll ensure that if the spending transaction has also been // spent, then we don't receive another spend notification. prevOut := wire.OutPoint{Hash: spendTxHash, Index: 0} spendOfSpend := wire.NewMsgTx(2) spendOfSpend.AddTxIn(&wire.TxIn{PreviousOutPoint: prevOut}) block := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{spendOfSpend}, }) err = n.ConnectTip(block.Hash(), startingHeight+1, block.Transactions()) if err != nil { t.Fatalf("unable to connect block: %v", err) } select { case <-ntfn.Event.Spend: t.Fatal("received unexpected spend notification") default: } } // TestTxNotifierMultipleHistoricalRescans ensures that we don't attempt to // request multiple historical confirmation rescans per transactions. func TestTxNotifierMultipleHistoricalConfRescans(t *testing.T) { t.Parallel() const startingHeight = 10 hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(startingHeight, 100, hintCache, hintCache) // The first registration for a transaction in the notifier should // request a historical confirmation rescan as it does not have a // historical view of the chain. confNtfn1 := &chainntnfs.ConfNtfn{ ConfID: 0, TxID: &zeroHash, Event: chainntnfs.NewConfirmationEvent(1), } historicalConfDispatch1, err := n.RegisterConf(confNtfn1) if err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } if historicalConfDispatch1 == nil { t.Fatal("expected to receive historical dispatch request") } // We'll register another confirmation notification for the same // transaction. This should not request a historical confirmation rescan // since the first one is still pending. confNtfn2 := &chainntnfs.ConfNtfn{ ConfID: 1, TxID: &zeroHash, Event: chainntnfs.NewConfirmationEvent(1), } historicalConfDispatch2, err := n.RegisterConf(confNtfn2) if err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } if historicalConfDispatch2 != nil { t.Fatal("received unexpected historical rescan request") } // Finally, we'll mark the ongoing historical rescan as complete and // register another notification. We should also expect not to see a // historical rescan request since the confirmation details should be // cached. confDetails := &chainntnfs.TxConfirmation{ BlockHeight: startingHeight - 1, } if err := n.UpdateConfDetails(*confNtfn2.TxID, confDetails); err != nil { t.Fatalf("unable to update conf details: %v", err) } confNtfn3 := &chainntnfs.ConfNtfn{ ConfID: 2, TxID: &zeroHash, Event: chainntnfs.NewConfirmationEvent(1), } historicalConfDispatch3, err := n.RegisterConf(confNtfn3) if err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } if historicalConfDispatch3 != nil { t.Fatal("received unexpected historical rescan request") } } // TestTxNotifierMultipleHistoricalRescans ensures that we don't attempt to // request multiple historical spend rescans per outpoints. func TestTxNotifierMultipleHistoricalSpendRescans(t *testing.T) { t.Parallel() const startingHeight = 10 hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(startingHeight, 100, hintCache, hintCache) // The first registration for an outpoint in the notifier should request // a historical spend rescan as it does not have a historical view of // the chain. ntfn1 := &chainntnfs.SpendNtfn{ SpendID: 0, OutPoint: zeroOutPoint, Event: chainntnfs.NewSpendEvent(nil), } historicalDispatch1, err := n.RegisterSpend(ntfn1) if err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } if historicalDispatch1 == nil { t.Fatal("expected to receive historical dispatch request") } // We'll register another spend notification for the same outpoint. This // should not request a historical spend rescan since the first one is // still pending. ntfn2 := &chainntnfs.SpendNtfn{ SpendID: 1, OutPoint: zeroOutPoint, Event: chainntnfs.NewSpendEvent(nil), } historicalDispatch2, err := n.RegisterSpend(ntfn2) if err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } if historicalDispatch2 != nil { t.Fatal("received unexpected historical rescan request") } // Finally, we'll mark the ongoing historical rescan as complete and // register another notification. We should also expect not to see a // historical rescan request since the confirmation details should be // cached. spendDetails := &chainntnfs.SpendDetail{ SpentOutPoint: &ntfn2.OutPoint, SpenderTxHash: &zeroHash, SpendingTx: wire.NewMsgTx(2), SpenderInputIndex: 0, SpendingHeight: startingHeight - 1, } err = n.UpdateSpendDetails(ntfn2.OutPoint, spendDetails) if err != nil { t.Fatalf("unable to update spend details: %v", err) } ntfn3 := &chainntnfs.SpendNtfn{ SpendID: 2, OutPoint: zeroOutPoint, Event: chainntnfs.NewSpendEvent(nil), } historicalDispatch3, err := n.RegisterSpend(ntfn3) if err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } if historicalDispatch3 != nil { t.Fatal("received unexpected historical rescan request") } } // TestTxNotifierMultipleHistoricalNtfns ensures that the TxNotifier will only // request one rescan for a transaction/outpoint when having multiple client // registrations. Once the rescan has completed and retrieved the // confirmation/spend details, a notification should be dispatched to _all_ // clients. func TestTxNotifierMultipleHistoricalNtfns(t *testing.T) { t.Parallel() const ( numNtfns = 5 startingHeight = 10 ) hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(startingHeight, 100, hintCache, hintCache) // We'll start off by registered 5 clients for a confirmation // notification on the same transaction. confNtfns := make([]*chainntnfs.ConfNtfn, numNtfns) for i := uint64(0); i < numNtfns; i++ { confNtfns[i] = &chainntnfs.ConfNtfn{ ConfID: i, TxID: &zeroHash, Event: chainntnfs.NewConfirmationEvent(1), } if _, err := n.RegisterConf(confNtfns[i]); err != nil { t.Fatalf("unable to register conf ntfn #%d: %v", i, err) } } // Ensure none of them have received the confirmation details. for i, ntfn := range confNtfns { select { case <-ntfn.Event.Confirmed: t.Fatalf("request #%d received unexpected confirmation "+ "notification", i) default: } } // We'll assume a historical rescan was dispatched and found the // following confirmation details. We'll let the notifier know so that // it can stop watching at tip. expectedConfDetails := &chainntnfs.TxConfirmation{ BlockHeight: startingHeight - 1, } err := n.UpdateConfDetails(*confNtfns[0].TxID, expectedConfDetails) if err != nil { t.Fatalf("unable to update conf details: %v", err) } // With the confirmation details retrieved, each client should now have // been notified of the confirmation. for i, ntfn := range confNtfns { select { case confDetails := <-ntfn.Event.Confirmed: assertConfDetails(t, confDetails, expectedConfDetails) default: t.Fatalf("request #%d expected to received "+ "confirmation notification", i) } } // In order to ensure that the confirmation details are properly cached, // we'll register another client for the same transaction. We should not // see a historical rescan request and the confirmation notification // should come through immediately. extraConfNtfn := &chainntnfs.ConfNtfn{ ConfID: numNtfns + 1, TxID: &zeroHash, Event: chainntnfs.NewConfirmationEvent(1), } historicalConfRescan, err := n.RegisterConf(extraConfNtfn) if err != nil { t.Fatalf("unable to register conf ntfn: %v", err) } if historicalConfRescan != nil { t.Fatal("received unexpected historical rescan request") } select { case confDetails := <-extraConfNtfn.Event.Confirmed: assertConfDetails(t, confDetails, expectedConfDetails) default: t.Fatal("expected to receive spend notification") } // Similarly, we'll do the same thing but for spend notifications. spendNtfns := make([]*chainntnfs.SpendNtfn, numNtfns) for i := uint64(0); i < numNtfns; i++ { spendNtfns[i] = &chainntnfs.SpendNtfn{ SpendID: i, OutPoint: zeroOutPoint, Event: chainntnfs.NewSpendEvent(nil), } if _, err := n.RegisterSpend(spendNtfns[i]); err != nil { t.Fatalf("unable to register spend ntfn #%d: %v", i, err) } } // Ensure none of them have received the spend details. for i, ntfn := range spendNtfns { select { case <-ntfn.Event.Spend: t.Fatalf("request #%d received unexpected spend "+ "notification", i) default: } } // We'll assume a historical rescan was dispatched and found the // following spend details. We'll let the notifier know so that it can // stop watching at tip. expectedSpendDetails := &chainntnfs.SpendDetail{ SpentOutPoint: &spendNtfns[0].OutPoint, SpenderTxHash: &zeroHash, SpendingTx: wire.NewMsgTx(2), SpenderInputIndex: 0, SpendingHeight: startingHeight - 1, } err = n.UpdateSpendDetails(spendNtfns[0].OutPoint, expectedSpendDetails) if err != nil { t.Fatalf("unable to update spend details: %v", err) } // With the spend details retrieved, each client should now have been // notified of the spend. for i, ntfn := range spendNtfns { select { case spendDetails := <-ntfn.Event.Spend: assertSpendDetails(t, spendDetails, expectedSpendDetails) default: t.Fatalf("request #%d expected to received spend "+ "notification", i) } } // Finally, in order to ensure that the spend details are properly // cached, we'll register another client for the same outpoint. We // should not see a historical rescan request and the spend notification // should come through immediately. extraSpendNtfn := &chainntnfs.SpendNtfn{ SpendID: numNtfns + 1, OutPoint: zeroOutPoint, Event: chainntnfs.NewSpendEvent(nil), } historicalSpendRescan, err := n.RegisterSpend(extraSpendNtfn) if err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } if historicalSpendRescan != nil { t.Fatal("received unexpected historical rescan request") } select { case spendDetails := <-extraSpendNtfn.Event.Spend: assertSpendDetails(t, spendDetails, expectedSpendDetails) default: t.Fatal("expected to receive spend notification") } } // TestTxNotifierCancelSpend ensures that a spend notification after a client // has canceled their intent to receive one. func TestTxNotifierCancelSpend(t *testing.T) { t.Parallel() const startingHeight = 10 hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(startingHeight, 100, hintCache, hintCache) // We'll register two notification requests. Only the second one will be // canceled. ntfn1 := &chainntnfs.SpendNtfn{ SpendID: 0, OutPoint: zeroOutPoint, Event: chainntnfs.NewSpendEvent(nil), } if _, err := n.RegisterSpend(ntfn1); err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } ntfn2 := &chainntnfs.SpendNtfn{ SpendID: 1, OutPoint: zeroOutPoint, Event: chainntnfs.NewSpendEvent(nil), } if _, err := n.RegisterSpend(ntfn2); err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } // Construct the spending details of the outpoint and create a dummy // block containing it. spendTx := wire.NewMsgTx(2) spendTx.AddTxIn(&wire.TxIn{PreviousOutPoint: ntfn1.OutPoint}) spendTxHash := spendTx.TxHash() expectedSpendDetails := &chainntnfs.SpendDetail{ SpentOutPoint: &ntfn1.OutPoint, SpenderTxHash: &spendTxHash, SpendingTx: spendTx, SpenderInputIndex: 0, SpendingHeight: startingHeight + 1, } block := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{spendTx}, }) // Before extending the notifier's tip with the dummy block above, we'll // cancel the second request. n.CancelSpend(ntfn2.OutPoint, ntfn2.SpendID) err := n.ConnectTip(block.Hash(), startingHeight+1, block.Transactions()) if err != nil { t.Fatalf("unable to connect block: %v", err) } // The first request should still be active, so we should receive a // spend notification with the correct spending details. select { case spendDetails := <-ntfn1.Event.Spend: assertSpendDetails(t, spendDetails, expectedSpendDetails) default: t.Fatalf("expected to receive spend notification") } // The second one, however, should not have. The event's Spend channel // must have also been closed to indicate the caller that the TxNotifier // can no longer fulfill their canceled request. select { case _, ok := <-ntfn2.Event.Spend: if ok { t.Fatal("expected Spend channel to be closed") } default: t.Fatal("expected Spend channel to be closed") } } // TestTxNotifierConfReorg ensures that clients are notified of a reorg when a // transaction for which they registered a confirmation notification has been // reorged out of the chain. func TestTxNotifierConfReorg(t *testing.T) { t.Parallel() const ( tx1NumConfs uint32 = 2 tx2NumConfs uint32 = 1 tx3NumConfs uint32 = 2 ) var ( tx1 = wire.MsgTx{Version: 1} tx2 = wire.MsgTx{Version: 2} tx3 = wire.MsgTx{Version: 3} ) hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(7, 100, hintCache, hintCache) // Tx 1 will be confirmed in block 9 and requires 2 confs. tx1Hash := tx1.TxHash() ntfn1 := chainntnfs.ConfNtfn{ TxID: &tx1Hash, NumConfirmations: tx1NumConfs, Event: chainntnfs.NewConfirmationEvent(tx1NumConfs), } if _, err := n.RegisterConf(&ntfn1); err != nil { t.Fatalf("unable to register ntfn: %v", err) } if err := n.UpdateConfDetails(*ntfn1.TxID, nil); err != nil { t.Fatalf("unable to deliver conf details: %v", err) } // Tx 2 will be confirmed in block 10 and requires 1 conf. tx2Hash := tx2.TxHash() ntfn2 := chainntnfs.ConfNtfn{ TxID: &tx2Hash, NumConfirmations: tx2NumConfs, Event: chainntnfs.NewConfirmationEvent(tx2NumConfs), } if _, err := n.RegisterConf(&ntfn2); err != nil { t.Fatalf("unable to register ntfn: %v", err) } if err := n.UpdateConfDetails(*ntfn2.TxID, nil); err != nil { t.Fatalf("unable to deliver conf details: %v", err) } // Tx 3 will be confirmed in block 10 and requires 2 confs. tx3Hash := tx3.TxHash() ntfn3 := chainntnfs.ConfNtfn{ TxID: &tx3Hash, NumConfirmations: tx3NumConfs, Event: chainntnfs.NewConfirmationEvent(tx3NumConfs), } if _, err := n.RegisterConf(&ntfn3); err != nil { t.Fatalf("unable to register ntfn: %v", err) } if err := n.UpdateConfDetails(*ntfn3.TxID, nil); err != nil { t.Fatalf("unable to deliver conf details: %v", err) } // Sync chain to block 10. Txs 1 & 2 should be confirmed. block1 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{&tx1}, }) err := n.ConnectTip(nil, 8, block1.Transactions()) if err != nil { t.Fatalf("Failed to connect block: %v", err) } err = n.ConnectTip(nil, 9, nil) if err != nil { t.Fatalf("Failed to connect block: %v", err) } block2 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{&tx2, &tx3}, }) err = n.ConnectTip(nil, 10, block2.Transactions()) if err != nil { t.Fatalf("Failed to connect block: %v", err) } // We should receive two updates for tx1 since it requires two // confirmations and it has already met them. for i := 0; i < 2; i++ { select { case <-ntfn1.Event.Updates: default: t.Fatal("Expected confirmation update for tx1") } } // A confirmation notification for tx1 should be dispatched, as it met // its required number of confirmations. select { case <-ntfn1.Event.Confirmed: default: t.Fatalf("Expected confirmation for tx1") } // We should only receive one update for tx2 since it only requires // one confirmation and it already met it. select { case <-ntfn2.Event.Updates: default: t.Fatal("Expected confirmation update for tx2") } // A confirmation notification for tx2 should be dispatched, as it met // its required number of confirmations. select { case <-ntfn2.Event.Confirmed: default: t.Fatalf("Expected confirmation for tx2") } // We should only receive one update for tx3 since it only has one // confirmation so far and it requires two. select { case <-ntfn3.Event.Updates: default: t.Fatal("Expected confirmation update for tx3") } // A confirmation notification for tx3 should not be dispatched yet, as // it requires one more confirmation. select { case txConf := <-ntfn3.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx3: %v", txConf) default: } // The block that included tx2 and tx3 is disconnected and two next // blocks without them are connected. err = n.DisconnectTip(10) if err != nil { t.Fatalf("Failed to connect block: %v", err) } err = n.ConnectTip(nil, 10, nil) if err != nil { t.Fatalf("Failed to connect block: %v", err) } err = n.ConnectTip(nil, 11, nil) if err != nil { t.Fatalf("Failed to connect block: %v", err) } select { case reorgDepth := <-ntfn2.Event.NegativeConf: if reorgDepth != 1 { t.Fatalf("Incorrect value for negative conf notification: "+ "expected %d, got %d", 1, reorgDepth) } default: t.Fatalf("Expected negative conf notification for tx1") } // We should not receive any event notifications from all of the // transactions because tx1 has already been confirmed and tx2 and tx3 // have not been included in the chain since the reorg. select { case <-ntfn1.Event.Updates: t.Fatal("Received unexpected confirmation update for tx1") case txConf := <-ntfn1.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx1: %v", txConf) default: } select { case <-ntfn2.Event.Updates: t.Fatal("Received unexpected confirmation update for tx2") case txConf := <-ntfn2.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx2: %v", txConf) default: } select { case <-ntfn3.Event.Updates: t.Fatal("Received unexpected confirmation update for tx3") case txConf := <-ntfn3.Event.Confirmed: t.Fatalf("Received unexpected confirmation for tx3: %v", txConf) default: } // Now transactions 2 & 3 are re-included in a new block. block3 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{&tx2, &tx3}, }) block4 := btcutil.NewBlock(&wire.MsgBlock{}) err = n.ConnectTip(block3.Hash(), 12, block3.Transactions()) if err != nil { t.Fatalf("Failed to connect block: %v", err) } err = n.ConnectTip(block4.Hash(), 13, block4.Transactions()) if err != nil { t.Fatalf("Failed to connect block: %v", err) } // We should only receive one update for tx2 since it only requires // one confirmation and it already met it. select { case numConfsLeft := <-ntfn2.Event.Updates: const expected = 0 if numConfsLeft != expected { t.Fatalf("Received incorrect confirmation update: tx2 "+ "expected %d confirmations left, got %d", expected, numConfsLeft) } default: t.Fatal("Expected confirmation update for tx2") } // A confirmation notification for tx2 should be dispatched, as it met // its required number of confirmations. select { case txConf := <-ntfn2.Event.Confirmed: expectedConf := chainntnfs.TxConfirmation{ BlockHash: block3.Hash(), BlockHeight: 12, TxIndex: 0, } assertConfDetails(t, txConf, &expectedConf) default: t.Fatalf("Expected confirmation for tx2") } // We should receive two updates for tx3 since it requires two // confirmations and it has already met them. for i := uint32(1); i <= 2; i++ { select { case numConfsLeft := <-ntfn3.Event.Updates: expected := tx3NumConfs - i if numConfsLeft != expected { t.Fatalf("Received incorrect confirmation update: tx3 "+ "expected %d confirmations left, got %d", expected, numConfsLeft) } default: t.Fatal("Expected confirmation update for tx2") } } // A confirmation notification for tx3 should be dispatched, as it met // its required number of confirmations. select { case txConf := <-ntfn3.Event.Confirmed: expectedConf := chainntnfs.TxConfirmation{ BlockHash: block3.Hash(), BlockHeight: 12, TxIndex: 1, } assertConfDetails(t, txConf, &expectedConf) default: t.Fatalf("Expected confirmation for tx3") } } // TestTxNotifierSpendReorg ensures that clients are notified of a reorg when // the spending transaction of an outpoint for which they registered a spend // notification for has been reorged out of the chain. func TestTxNotifierSpendReorg(t *testing.T) { t.Parallel() const startingHeight = 10 hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(startingHeight, 100, hintCache, hintCache) // We'll have two outpoints that will be spent throughout the test. The // first will be spent and will not experience a reorg, while the second // one will. op1 := zeroOutPoint op1.Index = 1 spendTx1 := wire.NewMsgTx(2) spendTx1.AddTxIn(&wire.TxIn{PreviousOutPoint: op1}) spendTxHash1 := spendTx1.TxHash() expectedSpendDetails1 := &chainntnfs.SpendDetail{ SpentOutPoint: &op1, SpenderTxHash: &spendTxHash1, SpendingTx: spendTx1, SpenderInputIndex: 0, SpendingHeight: startingHeight + 1, } op2 := zeroOutPoint op2.Index = 2 spendTx2 := wire.NewMsgTx(2) spendTx2.AddTxIn(&wire.TxIn{PreviousOutPoint: zeroOutPoint}) spendTx2.AddTxIn(&wire.TxIn{PreviousOutPoint: op2}) spendTxHash2 := spendTx2.TxHash() // The second outpoint will experience a reorg and get re-spent at a // different height, so we'll need to construct the spend details for // before and after the reorg. expectedSpendDetails2BeforeReorg := chainntnfs.SpendDetail{ SpentOutPoint: &op2, SpenderTxHash: &spendTxHash2, SpendingTx: spendTx2, SpenderInputIndex: 1, SpendingHeight: startingHeight + 2, } // The spend details after the reorg will be exactly the same, except // for the spend confirming at the next height. expectedSpendDetails2AfterReorg := expectedSpendDetails2BeforeReorg expectedSpendDetails2AfterReorg.SpendingHeight++ // We'll register for a spend notification for each outpoint above. ntfn1 := &chainntnfs.SpendNtfn{ SpendID: 78, OutPoint: op1, Event: chainntnfs.NewSpendEvent(nil), } if _, err := n.RegisterSpend(ntfn1); err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } ntfn2 := &chainntnfs.SpendNtfn{ SpendID: 21, OutPoint: op2, Event: chainntnfs.NewSpendEvent(nil), } if _, err := n.RegisterSpend(ntfn2); err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } // We'll extend the chain by connecting a new block at tip. This block // will only contain the spending transaction of the first outpoint. block1 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{spendTx1}, }) err := n.ConnectTip( block1.Hash(), startingHeight+1, block1.Transactions(), ) if err != nil { t.Fatalf("unable to connect block: %v", err) } // We should receive a spend notification for the first outpoint with // its correct spending details. select { case spendDetails := <-ntfn1.Event.Spend: assertSpendDetails(t, spendDetails, expectedSpendDetails1) default: t.Fatal("expected to receive spend details") } // We should not, however, receive one for the second outpoint as it has // yet to be spent. select { case <-ntfn2.Event.Spend: t.Fatal("received unexpected spend notification") default: } // Now, we'll extend the chain again, this time with a block containing // the spending transaction of the second outpoint. block2 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{spendTx2}, }) err = n.ConnectTip( block2.Hash(), startingHeight+2, block2.Transactions(), ) if err != nil { t.Fatalf("unable to connect block: %v", err) } // We should not receive another spend notification for the first // outpoint. select { case <-ntfn1.Event.Spend: t.Fatal("received unexpected spend notification") default: } // We should receive one for the second outpoint. select { case spendDetails := <-ntfn2.Event.Spend: assertSpendDetails( t, spendDetails, &expectedSpendDetails2BeforeReorg, ) default: t.Fatal("expected to receive spend details") } // Now, to replicate a chain reorg, we'll disconnect the block that // contained the spending transaction of the second outpoint. if err := n.DisconnectTip(startingHeight + 2); err != nil { t.Fatalf("unable to disconnect block: %v", err) } // No notifications should be dispatched for the first outpoint as it // was spent at a previous height. select { case <-ntfn1.Event.Spend: t.Fatal("received unexpected spend notification") case <-ntfn1.Event.Reorg: t.Fatal("received unexpected spend reorg notification") default: } // We should receive a reorg notification for the second outpoint. select { case <-ntfn2.Event.Spend: t.Fatal("received unexpected spend notification") case <-ntfn2.Event.Reorg: default: t.Fatal("expected spend reorg notification") } // We'll now extend the chain with an empty block, to ensure that we can // properly detect when an outpoint has been re-spent at a later height. emptyBlock := btcutil.NewBlock(&wire.MsgBlock{}) err = n.ConnectTip( emptyBlock.Hash(), startingHeight+2, emptyBlock.Transactions(), ) if err != nil { t.Fatalf("unable to disconnect block: %v", err) } // We shouldn't receive notifications for either of the outpoints. select { case <-ntfn1.Event.Spend: t.Fatal("received unexpected spend notification") case <-ntfn1.Event.Reorg: t.Fatal("received unexpected spend reorg notification") case <-ntfn2.Event.Spend: t.Fatal("received unexpected spend notification") case <-ntfn2.Event.Reorg: t.Fatal("received unexpected spend reorg notification") default: } // Finally, extend the chain with another block containing the same // spending transaction of the second outpoint. err = n.ConnectTip( block2.Hash(), startingHeight+3, block2.Transactions(), ) if err != nil { t.Fatalf("unable to connect block: %v", err) } // We should now receive a spend notification once again for the second // outpoint containing the new spend details. select { case spendDetails := <-ntfn2.Event.Spend: assertSpendDetails( t, spendDetails, &expectedSpendDetails2AfterReorg, ) default: t.Fatalf("expected to receive spend notification") } // Once again, we should not receive one for the first outpoint. select { case <-ntfn1.Event.Spend: t.Fatal("received unexpected spend notification") default: } } // TestTxNotifierConfirmHintCache ensures that the height hints for transactions // are kept track of correctly with each new block connected/disconnected. This // test also asserts that the height hints are not updated until the simulated // historical dispatches have returned, and we know the transactions aren't // already in the chain. func TestTxNotifierConfirmHintCache(t *testing.T) { t.Parallel() const ( startingHeight = 200 txDummyHeight = 201 tx1Height = 202 tx2Height = 203 ) // Initialize our TxNotifier instance backed by a height hint cache. hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(startingHeight, 100, hintCache, hintCache) // Create two test transactions and register them for notifications. tx1 := wire.MsgTx{Version: 1} tx1Hash := tx1.TxHash() ntfn1 := &chainntnfs.ConfNtfn{ TxID: &tx1Hash, NumConfirmations: 1, Event: chainntnfs.NewConfirmationEvent(1), } tx2 := wire.MsgTx{Version: 2} tx2Hash := tx2.TxHash() ntfn2 := &chainntnfs.ConfNtfn{ TxID: &tx2Hash, NumConfirmations: 2, Event: chainntnfs.NewConfirmationEvent(2), } if _, err := n.RegisterConf(ntfn1); err != nil { t.Fatalf("unable to register tx1: %v", err) } if _, err := n.RegisterConf(ntfn2); err != nil { t.Fatalf("unable to register tx2: %v", err) } // Both transactions should not have a height hint set, as RegisterConf // should not alter the cache state. _, err := hintCache.QueryConfirmHint(tx1Hash) if err != chainntnfs.ErrConfirmHintNotFound { t.Fatalf("unexpected error when querying for height hint "+ "want: %v, got %v", chainntnfs.ErrConfirmHintNotFound, err) } _, err = hintCache.QueryConfirmHint(tx2Hash) if err != chainntnfs.ErrConfirmHintNotFound { t.Fatalf("unexpected error when querying for height hint "+ "want: %v, got %v", chainntnfs.ErrConfirmHintNotFound, err) } // Create a new block that will include the dummy transaction and extend // the chain. txDummy := wire.MsgTx{Version: 3} block1 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{&txDummy}, }) err = n.ConnectTip( block1.Hash(), txDummyHeight, block1.Transactions(), ) if err != nil { t.Fatalf("Failed to connect block: %v", err) } // Since UpdateConfDetails has not been called for either transaction, // the height hints should remain unchanged. This simulates blocks // confirming while the historical dispatch is processing the // registration. hint, err := hintCache.QueryConfirmHint(tx1Hash) if err != chainntnfs.ErrConfirmHintNotFound { t.Fatalf("unexpected error when querying for height hint "+ "want: %v, got %v", chainntnfs.ErrConfirmHintNotFound, err) } hint, err = hintCache.QueryConfirmHint(tx2Hash) if err != chainntnfs.ErrConfirmHintNotFound { t.Fatalf("unexpected error when querying for height hint "+ "want: %v, got %v", chainntnfs.ErrConfirmHintNotFound, err) } // Now, update the conf details reporting that the neither txn was found // in the historical dispatch. if err := n.UpdateConfDetails(tx1Hash, nil); err != nil { t.Fatalf("unable to update conf details: %v", err) } if err := n.UpdateConfDetails(tx2Hash, nil); err != nil { t.Fatalf("unable to update conf details: %v", err) } // We'll create another block that will include the first transaction // and extend the chain. block2 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{&tx1}, }) err = n.ConnectTip( block2.Hash(), tx1Height, block2.Transactions(), ) if err != nil { t.Fatalf("Failed to connect block: %v", err) } // Now that both notifications are waiting at tip for confirmations, // they should have their height hints updated to the latest block // height. hint, err = hintCache.QueryConfirmHint(tx1Hash) if err != nil { t.Fatalf("unable to query for hint: %v", err) } if hint != tx1Height { t.Fatalf("expected hint %d, got %d", tx1Height, hint) } hint, err = hintCache.QueryConfirmHint(tx2Hash) if err != nil { t.Fatalf("unable to query for hint: %v", err) } if hint != tx1Height { t.Fatalf("expected hint %d, got %d", tx2Height, hint) } // Next, we'll create another block that will include the second // transaction and extend the chain. block3 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{&tx2}, }) err = n.ConnectTip( block3.Hash(), tx2Height, block3.Transactions(), ) if err != nil { t.Fatalf("Failed to connect block: %v", err) } // The height hint for the first transaction should remain the same. hint, err = hintCache.QueryConfirmHint(tx1Hash) if err != nil { t.Fatalf("unable to query for hint: %v", err) } if hint != tx1Height { t.Fatalf("expected hint %d, got %d", tx1Height, hint) } // The height hint for the second transaction should now be updated to // reflect its confirmation. hint, err = hintCache.QueryConfirmHint(tx2Hash) if err != nil { t.Fatalf("unable to query for hint: %v", err) } if hint != tx2Height { t.Fatalf("expected hint %d, got %d", tx2Height, hint) } // Finally, we'll attempt do disconnect the last block in order to // simulate a chain reorg. if err := n.DisconnectTip(tx2Height); err != nil { t.Fatalf("Failed to disconnect block: %v", err) } // This should update the second transaction's height hint within the // cache to the previous height. hint, err = hintCache.QueryConfirmHint(tx2Hash) if err != nil { t.Fatalf("unable to query for hint: %v", err) } if hint != tx1Height { t.Fatalf("expected hint %d, got %d", tx1Height, hint) } // The first transaction's height hint should remain at the original // confirmation height. hint, err = hintCache.QueryConfirmHint(tx2Hash) if err != nil { t.Fatalf("unable to query for hint: %v", err) } if hint != tx1Height { t.Fatalf("expected hint %d, got %d", tx1Height, hint) } } // TestTxNotifierSpendHintCache ensures that the height hints for outpoints are // kept track of correctly with each new block connected/disconnected. This test // also asserts that the height hints are not updated until the simulated // historical dispatches have returned, and we know the outpoints haven't // already been spent in the chain. func TestTxNotifierSpendHintCache(t *testing.T) { t.Parallel() const ( startingHeight = 200 dummyHeight = 201 op1Height = 202 op2Height = 203 ) // Intiialize our TxNotifier instance backed by a height hint cache. hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(startingHeight, 100, hintCache, hintCache) // Create two test outpoints and register them for spend notifications. op1 := wire.OutPoint{Hash: zeroHash, Index: 1} ntfn1 := &chainntnfs.SpendNtfn{ OutPoint: op1, Event: chainntnfs.NewSpendEvent(nil), } op2 := wire.OutPoint{Hash: zeroHash, Index: 2} ntfn2 := &chainntnfs.SpendNtfn{ OutPoint: op2, Event: chainntnfs.NewSpendEvent(nil), } if _, err := n.RegisterSpend(ntfn1); err != nil { t.Fatalf("unable to register spend for op1: %v", err) } if _, err := n.RegisterSpend(ntfn2); err != nil { t.Fatalf("unable to register spend for op2: %v", err) } // Both outpoints should not have a spend hint set upon registration, as // we must first determine whether they have already been spent in the // chain. _, err := hintCache.QuerySpendHint(op1) if err != chainntnfs.ErrSpendHintNotFound { t.Fatalf("unexpected error when querying for height hint "+ "expected: %v, got %v", chainntnfs.ErrSpendHintNotFound, err) } _, err = hintCache.QuerySpendHint(op2) if err != chainntnfs.ErrSpendHintNotFound { t.Fatalf("unexpected error when querying for height hint "+ "expected: %v, got %v", chainntnfs.ErrSpendHintNotFound, err) } // Create a new empty block and extend the chain. emptyBlock := btcutil.NewBlock(&wire.MsgBlock{}) err = n.ConnectTip( emptyBlock.Hash(), dummyHeight, emptyBlock.Transactions(), ) if err != nil { t.Fatalf("unable to connect block: %v", err) } // Since we haven't called UpdateSpendDetails on any of the test // outpoints, this implies that there is a still a pending historical // rescan for them, so their spend hints should not be created/updated. _, err = hintCache.QuerySpendHint(op1) if err != chainntnfs.ErrSpendHintNotFound { t.Fatalf("unexpected error when querying for height hint "+ "expected: %v, got %v", chainntnfs.ErrSpendHintNotFound, err) } _, err = hintCache.QuerySpendHint(op2) if err != chainntnfs.ErrSpendHintNotFound { t.Fatalf("unexpected error when querying for height hint "+ "expected: %v, got %v", chainntnfs.ErrSpendHintNotFound, err) } // Now, we'll simulate that their historical rescans have finished by // calling UpdateSpendDetails. This should allow their spend hints to be // updated upon every block connected/disconnected. if err := n.UpdateSpendDetails(ntfn1.OutPoint, nil); err != nil { t.Fatalf("unable to update spend details: %v", err) } if err := n.UpdateSpendDetails(ntfn2.OutPoint, nil); err != nil { t.Fatalf("unable to update spend details: %v", err) } // We'll create a new block that only contains the spending transaction // of the first outpoint. spendTx1 := wire.NewMsgTx(2) spendTx1.AddTxIn(&wire.TxIn{PreviousOutPoint: ntfn1.OutPoint}) block1 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{spendTx1}, }) err = n.ConnectTip(block1.Hash(), op1Height, block1.Transactions()) if err != nil { t.Fatalf("unable to connect block: %v", err) } // Both outpoints should have their spend hints reflect the height of // the new block being connected due to the first outpoint being spent // at this height, and the second outpoint still being unspent. op1Hint, err := hintCache.QuerySpendHint(ntfn1.OutPoint) if err != nil { t.Fatalf("unable to query for spend hint of op1: %v", err) } if op1Hint != op1Height { t.Fatalf("expected hint %d, got %d", op1Height, op1Hint) } op2Hint, err := hintCache.QuerySpendHint(ntfn2.OutPoint) if err != nil { t.Fatalf("unable to query for spend hint of op2: %v", err) } if op2Hint != op1Height { t.Fatalf("expected hint %d, got %d", op1Height, op2Hint) } // Then, we'll create another block that spends the second outpoint. spendTx2 := wire.NewMsgTx(2) spendTx2.AddTxIn(&wire.TxIn{PreviousOutPoint: ntfn2.OutPoint}) block2 := btcutil.NewBlock(&wire.MsgBlock{ Transactions: []*wire.MsgTx{spendTx2}, }) err = n.ConnectTip(block2.Hash(), op2Height, block2.Transactions()) if err != nil { t.Fatalf("unable to connect block: %v", err) } // Only the second outpoint should have its spend hint updated due to // being spent within the new block. The first outpoint's spend hint // should remain the same as it's already been spent before. op1Hint, err = hintCache.QuerySpendHint(ntfn1.OutPoint) if err != nil { t.Fatalf("unable to query for spend hint of op1: %v", err) } if op1Hint != op1Height { t.Fatalf("expected hint %d, got %d", op1Height, op1Hint) } op2Hint, err = hintCache.QuerySpendHint(ntfn2.OutPoint) if err != nil { t.Fatalf("unable to query for spend hint of op2: %v", err) } if op2Hint != op2Height { t.Fatalf("expected hint %d, got %d", op2Height, op2Hint) } // Finally, we'll attempt do disconnect the last block in order to // simulate a chain reorg. if err := n.DisconnectTip(op2Height); err != nil { t.Fatalf("unable to disconnect block: %v", err) } // This should update the second outpoint's spend hint within the cache // to the previous height, as that's where its spending transaction was // included in within the chain. The first outpoint's spend hint should // remain the same. op1Hint, err = hintCache.QuerySpendHint(ntfn1.OutPoint) if err != nil { t.Fatalf("unable to query for spend hint of op1: %v", err) } if op1Hint != op1Height { t.Fatalf("expected hint %d, got %d", op1Height, op1Hint) } op2Hint, err = hintCache.QuerySpendHint(ntfn2.OutPoint) if err != nil { t.Fatalf("unable to query for spend hint of op2: %v", err) } if op2Hint != op1Height { t.Fatalf("expected hint %d, got %d", op1Height, op2Hint) } } // TestTxNotifierTearDown ensures that the TxNotifier properly alerts clients // that it is shutting down and will be unable to deliver notifications. func TestTxNotifierTearDown(t *testing.T) { t.Parallel() hintCache := newMockHintCache() n := chainntnfs.NewTxNotifier(10, 100, hintCache, hintCache) // To begin the test, we'll register for a confirmation and spend // notification. confNtfn := &chainntnfs.ConfNtfn{ TxID: &zeroHash, NumConfirmations: 1, Event: chainntnfs.NewConfirmationEvent(1), } if _, err := n.RegisterConf(confNtfn); err != nil { t.Fatalf("unable to register conf ntfn: %v", err) } spendNtfn := &chainntnfs.SpendNtfn{ OutPoint: zeroOutPoint, Event: chainntnfs.NewSpendEvent(nil), } if _, err := n.RegisterSpend(spendNtfn); err != nil { t.Fatalf("unable to register spend ntfn: %v", err) } // With the notifications registered, we'll now tear down the notifier. // The notification channels should be closed for notifications, whether // they have been dispatched or not, so we should not expect to receive // any more updates. n.TearDown() select { case _, ok := <-confNtfn.Event.Confirmed: if ok { t.Fatal("expected closed Confirmed channel for conf ntfn") } case _, ok := <-confNtfn.Event.Updates: if ok { t.Fatal("expected closed Updates channel for conf ntfn") } case _, ok := <-confNtfn.Event.NegativeConf: if ok { t.Fatal("expected closed NegativeConf channel for conf ntfn") } case _, ok := <-spendNtfn.Event.Spend: if ok { t.Fatal("expected closed Spend channel for spend ntfn") } case _, ok := <-spendNtfn.Event.Reorg: if ok { t.Fatalf("expected closed Reorg channel for spend ntfn") } default: t.Fatalf("expected closed notification channels for all ntfns") } // Now that the notifier is torn down, we should no longer be able to // register notification requests. if _, err := n.RegisterConf(confNtfn); err == nil { t.Fatal("expected confirmation registration to fail") } if _, err := n.RegisterSpend(spendNtfn); err == nil { t.Fatal("expected spend registration to fail") } } func assertConfDetails(t *testing.T, result, expected *chainntnfs.TxConfirmation) { t.Helper() if result.BlockHeight != expected.BlockHeight { t.Fatalf("Incorrect block height in confirmation details: "+ "expected %d, got %d", expected.BlockHeight, result.BlockHeight) } if !result.BlockHash.IsEqual(expected.BlockHash) { t.Fatalf("Incorrect block hash in confirmation details: "+ "expected %d, got %d", expected.BlockHash, result.BlockHash) } if result.TxIndex != expected.TxIndex { t.Fatalf("Incorrect tx index in confirmation details: "+ "expected %d, got %d", expected.TxIndex, result.TxIndex) } } func assertSpendDetails(t *testing.T, result, expected *chainntnfs.SpendDetail) { t.Helper() if *result.SpentOutPoint != *expected.SpentOutPoint { t.Fatalf("expected spent outpoint %v, got %v", expected.SpentOutPoint, result.SpentOutPoint) } if !result.SpenderTxHash.IsEqual(expected.SpenderTxHash) { t.Fatalf("expected spender tx hash %v, got %v", expected.SpenderTxHash, result.SpenderTxHash) } if result.SpenderInputIndex != expected.SpenderInputIndex { t.Fatalf("expected spender input index %d, got %d", expected.SpenderInputIndex, result.SpenderInputIndex) } if result.SpendingHeight != expected.SpendingHeight { t.Fatalf("expected spending height %d, got %d", expected.SpendingHeight, result.SpendingHeight) } }