lnd/sweep/sweeper_test.go
yyforyongyu a8f5a09dea
sweep: don't give up an input based on number of attempts
This commit removes the logic where we remove an input when it's been
published more than 10 times. This is needed as in our future fee
bumper, we might start with a low fee and rebroadcast the same input for
hundred of blocks.
2024-04-19 21:33:23 +08:00

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package sweep
import (
"errors"
"os"
"runtime/pprof"
"testing"
"time"
"github.com/btcsuite/btcd/btcec/v2"
"github.com/btcsuite/btcd/btcutil"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/lightningnetwork/lnd/build"
"github.com/lightningnetwork/lnd/chainntnfs"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/fn"
"github.com/lightningnetwork/lnd/input"
"github.com/lightningnetwork/lnd/keychain"
lnmock "github.com/lightningnetwork/lnd/lntest/mock"
"github.com/lightningnetwork/lnd/lnwallet"
"github.com/lightningnetwork/lnd/lnwallet/chainfee"
"github.com/stretchr/testify/mock"
"github.com/stretchr/testify/require"
)
var (
testLog = build.NewSubLogger("SWPR_TEST", nil)
testMaxSweepAttempts = 3
testMaxInputsPerTx = 3
defaultFeePref = Params{Fee: FeeEstimateInfo{ConfTarget: 1}}
)
type sweeperTestContext struct {
t *testing.T
sweeper *UtxoSweeper
notifier *MockNotifier
estimator *mockFeeEstimator
backend *mockBackend
store SweeperStore
publishChan chan wire.MsgTx
}
var (
spendableInputs []*input.BaseInput
testInputCount int
testPubKey, _ = btcec.ParsePubKey([]byte{
0x04, 0x11, 0xdb, 0x93, 0xe1, 0xdc, 0xdb, 0x8a,
0x01, 0x6b, 0x49, 0x84, 0x0f, 0x8c, 0x53, 0xbc, 0x1e,
0xb6, 0x8a, 0x38, 0x2e, 0x97, 0xb1, 0x48, 0x2e, 0xca,
0xd7, 0xb1, 0x48, 0xa6, 0x90, 0x9a, 0x5c, 0xb2, 0xe0,
0xea, 0xdd, 0xfb, 0x84, 0xcc, 0xf9, 0x74, 0x44, 0x64,
0xf8, 0x2e, 0x16, 0x0b, 0xfa, 0x9b, 0x8b, 0x64, 0xf9,
0xd4, 0xc0, 0x3f, 0x99, 0x9b, 0x86, 0x43, 0xf6, 0x56,
0xb4, 0x12, 0xa3,
})
)
func createTestInput(value int64, witnessType input.WitnessType) input.BaseInput {
hash := chainhash.Hash{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
byte(testInputCount + 1)}
input := input.MakeBaseInput(
&wire.OutPoint{
Hash: hash,
},
witnessType,
&input.SignDescriptor{
Output: &wire.TxOut{
Value: value,
},
KeyDesc: keychain.KeyDescriptor{
PubKey: testPubKey,
},
},
0,
nil,
)
testInputCount++
return input
}
func init() {
// Create a set of test spendable inputs.
for i := 0; i < 20; i++ {
input := createTestInput(int64(10000+i*500),
input.CommitmentTimeLock)
spendableInputs = append(spendableInputs, &input)
}
}
func createSweeperTestContext(t *testing.T) *sweeperTestContext {
notifier := NewMockNotifier(t)
// Create new store.
cdb, err := channeldb.MakeTestDB(t)
require.NoError(t, err)
var chain chainhash.Hash
store, err := NewSweeperStore(cdb, &chain)
require.NoError(t, err)
backend := newMockBackend(t, notifier)
backend.walletUtxos = []*lnwallet.Utxo{
{
Value: btcutil.Amount(1_000_000),
AddressType: lnwallet.WitnessPubKey,
},
}
estimator := newMockFeeEstimator(10000, chainfee.FeePerKwFloor)
aggregator := NewSimpleUtxoAggregator(
estimator, DefaultMaxFeeRate.FeePerKWeight(),
)
ctx := &sweeperTestContext{
notifier: notifier,
publishChan: backend.publishChan,
t: t,
estimator: estimator,
backend: backend,
store: store,
}
ctx.sweeper = New(&UtxoSweeperConfig{
Notifier: notifier,
Wallet: backend,
TickerDuration: 100 * time.Millisecond,
Store: store,
Signer: &lnmock.DummySigner{},
GenSweepScript: func() ([]byte, error) {
script := make([]byte, input.P2WPKHSize)
script[0] = 0
script[1] = 20
return script, nil
},
FeeEstimator: estimator,
MaxInputsPerTx: testMaxInputsPerTx,
MaxSweepAttempts: testMaxSweepAttempts,
NextAttemptDeltaFunc: func(attempts int) int32 {
// Use delta func without random factor.
return 1 << uint(attempts-1)
},
MaxFeeRate: DefaultMaxFeeRate,
Aggregator: aggregator,
})
ctx.sweeper.Start()
return ctx
}
func (ctx *sweeperTestContext) restartSweeper() {
ctx.t.Helper()
ctx.sweeper.Stop()
ctx.sweeper = New(ctx.sweeper.cfg)
ctx.sweeper.Start()
}
func (ctx *sweeperTestContext) finish(expectedGoroutineCount int) {
// We assume that when finish is called, sweeper has finished all its
// goroutines. This implies that the waitgroup is empty.
signalChan := make(chan struct{})
go func() {
ctx.sweeper.wg.Wait()
close(signalChan)
}()
// Simulate exits of the expected number of running goroutines.
for i := 0; i < expectedGoroutineCount; i++ {
ctx.sweeper.wg.Done()
}
// We now expect the Wait to succeed.
select {
case <-signalChan:
case <-time.After(time.Second):
pprof.Lookup("goroutine").WriteTo(os.Stdout, 1)
ctx.t.Fatalf("lingering goroutines detected after test " +
"is finished")
}
// Restore waitgroup state to what it was before.
ctx.sweeper.wg.Add(expectedGoroutineCount)
// Stop sweeper.
ctx.sweeper.Stop()
// We should have consumed and asserted all published transactions in
// our unit tests.
ctx.assertNoTx()
if !ctx.backend.isDone() {
ctx.t.Fatal("unconfirmed txes remaining")
}
}
func (ctx *sweeperTestContext) assertNoTx() {
ctx.t.Helper()
select {
case <-ctx.publishChan:
ctx.t.Fatalf("unexpected transactions published")
default:
}
}
func (ctx *sweeperTestContext) receiveTx() wire.MsgTx {
ctx.t.Helper()
var tx wire.MsgTx
select {
case tx = <-ctx.publishChan:
return tx
case <-time.After(5 * time.Second):
pprof.Lookup("goroutine").WriteTo(os.Stdout, 1)
ctx.t.Fatalf("tx not published")
}
return tx
}
func (ctx *sweeperTestContext) expectResult(c chan Result, expected error) {
ctx.t.Helper()
select {
case result := <-c:
if result.Err != expected {
ctx.t.Fatalf("expected %v result, but got %v",
expected, result.Err,
)
}
case <-time.After(defaultTestTimeout):
ctx.t.Fatalf("no result received")
}
}
func (ctx *sweeperTestContext) assertPendingInputs(inputs ...input.Input) {
ctx.t.Helper()
inputSet := make(map[wire.OutPoint]struct{}, len(inputs))
for _, input := range inputs {
inputSet[*input.OutPoint()] = struct{}{}
}
pendingInputs, err := ctx.sweeper.PendingInputs()
if err != nil {
ctx.t.Fatal(err)
}
if len(pendingInputs) != len(inputSet) {
ctx.t.Fatalf("expected %d pending inputs, got %d",
len(inputSet), len(pendingInputs))
}
for input := range pendingInputs {
if _, ok := inputSet[input]; !ok {
ctx.t.Fatalf("found unexpected input %v", input)
}
}
}
// assertTxSweepsInputs ensures that the transaction returned within the value
// received from resultChan spends the given inputs.
func assertTxSweepsInputs(t *testing.T, sweepTx *wire.MsgTx,
inputs ...input.Input) {
t.Helper()
if len(sweepTx.TxIn) != len(inputs) {
t.Fatalf("expected sweep tx to contain %d inputs, got %d",
len(inputs), len(sweepTx.TxIn))
}
m := make(map[wire.OutPoint]struct{}, len(inputs))
for _, input := range inputs {
m[*input.OutPoint()] = struct{}{}
}
for _, txIn := range sweepTx.TxIn {
if _, ok := m[txIn.PreviousOutPoint]; !ok {
t.Fatalf("expected tx %v to spend input %v",
txIn.PreviousOutPoint, sweepTx.TxHash())
}
}
}
// assertTxFeeRate asserts that the transaction was created with the given
// inputs and fee rate.
//
// NOTE: This assumes that transactions only have one output, as this is the
// only type of transaction the UtxoSweeper can create at the moment.
func assertTxFeeRate(t *testing.T, tx *wire.MsgTx,
expectedFeeRate chainfee.SatPerKWeight, changePk []byte,
inputs ...input.Input) {
t.Helper()
if len(tx.TxIn) != len(inputs) {
t.Fatalf("expected %d inputs, got %d", len(tx.TxIn), len(inputs))
}
m := make(map[wire.OutPoint]input.Input, len(inputs))
for _, input := range inputs {
m[*input.OutPoint()] = input
}
var inputAmt int64
for _, txIn := range tx.TxIn {
input, ok := m[txIn.PreviousOutPoint]
if !ok {
t.Fatalf("expected input %v to be provided",
txIn.PreviousOutPoint)
}
inputAmt += input.SignDesc().Output.Value
}
outputAmt := tx.TxOut[0].Value
fee := btcutil.Amount(inputAmt - outputAmt)
_, estimator, err := getWeightEstimate(inputs, nil, 0, 0, changePk)
require.NoError(t, err)
txWeight := estimator.weight()
expectedFee := expectedFeeRate.FeeForWeight(int64(txWeight))
if fee != expectedFee {
t.Fatalf("expected fee rate %v results in %v fee, got %v fee",
expectedFeeRate, expectedFee, fee)
}
}
// TestSuccess tests the sweeper happy flow.
func TestSuccess(t *testing.T) {
ctx := createSweeperTestContext(t)
// Sweeping an input without a fee preference should result in an error.
_, err := ctx.sweeper.SweepInput(spendableInputs[0], Params{
Fee: &FeeEstimateInfo{},
})
if err != ErrNoFeePreference {
t.Fatalf("expected ErrNoFeePreference, got %v", err)
}
resultChan, err := ctx.sweeper.SweepInput(
spendableInputs[0], defaultFeePref,
)
if err != nil {
t.Fatal(err)
}
sweepTx := ctx.receiveTx()
ctx.backend.mine()
select {
case result := <-resultChan:
if result.Err != nil {
t.Fatalf("expected successful spend, but received "+
"error %v instead", result.Err)
}
if result.Tx.TxHash() != sweepTx.TxHash() {
t.Fatalf("expected sweep tx ")
}
case <-time.After(5 * time.Second):
t.Fatalf("no result received")
}
ctx.finish(1)
}
// TestDust asserts that inputs that are not big enough to raise above the dust
// limit, are held back until the total set does surpass the limit.
func TestDust(t *testing.T) {
ctx := createSweeperTestContext(t)
// Sweeping a single output produces a tx of 486 weight units. With the
// test fee rate, the sweep tx will pay 4860 sat in fees.
//
// Create an input so that the output after paying fees is still
// positive (400 sat), but less than the dust limit (537 sat) for the
// sweep tx output script (P2WPKH).
dustInput := createTestInput(5260, input.CommitmentTimeLock)
_, err := ctx.sweeper.SweepInput(&dustInput, defaultFeePref)
require.NoError(t, err)
// No sweep transaction is expected now. The sweeper should recognize
// that the sweep output will not be relayed and not generate the tx. It
// isn't possible to attach a wallet utxo either, because the added
// weight would create a negatively yielding transaction at this fee
// rate.
// Sweep another input that brings the tx output above the dust limit.
largeInput := createTestInput(100000, input.CommitmentTimeLock)
_, err = ctx.sweeper.SweepInput(&largeInput, defaultFeePref)
require.NoError(t, err)
// The second input brings the sweep output above the dust limit. We
// expect a sweep tx now.
sweepTx := ctx.receiveTx()
require.Len(t, sweepTx.TxIn, 2, "unexpected num of tx inputs")
ctx.backend.mine()
ctx.finish(1)
}
// TestWalletUtxo asserts that inputs that are not big enough to raise above the
// dust limit are accompanied by a wallet utxo to make them sweepable.
func TestWalletUtxo(t *testing.T) {
ctx := createSweeperTestContext(t)
// Sweeping a single output produces a tx of 439 weight units. At the
// fee floor, the sweep tx will pay 439*253/1000 = 111 sat in fees.
//
// Create an input so that the output after paying fees is still
// positive (183 sat), but less than the dust limit (537 sat) for the
// sweep tx output script (P2WPKH).
//
// What we now expect is that the sweeper will attach a utxo from the
// wallet. This increases the tx weight to 712 units with a fee of 180
// sats. The tx yield becomes then 294-180 = 114 sats.
dustInput := createTestInput(294, input.WitnessKeyHash)
_, err := ctx.sweeper.SweepInput(
&dustInput,
Params{Fee: FeeEstimateInfo{FeeRate: chainfee.FeePerKwFloor}},
)
if err != nil {
t.Fatal(err)
}
sweepTx := ctx.receiveTx()
if len(sweepTx.TxIn) != 2 {
t.Fatalf("Expected tx to sweep 2 inputs, but contains %v "+
"inputs instead", len(sweepTx.TxIn))
}
// Calculate expected output value based on wallet utxo of 1_000_000
// sats.
expectedOutputValue := int64(294 + 1_000_000 - 180)
if sweepTx.TxOut[0].Value != expectedOutputValue {
t.Fatalf("Expected output value of %v, but got %v",
expectedOutputValue, sweepTx.TxOut[0].Value)
}
ctx.backend.mine()
ctx.finish(1)
}
// TestNegativeInput asserts that no inputs with a negative yield are swept.
// Negative yield means that the value minus the added fee is negative.
func TestNegativeInput(t *testing.T) {
ctx := createSweeperTestContext(t)
// Sweep an input large enough to cover fees, so in any case the tx
// output will be above the dust limit.
largeInput := createTestInput(100000, input.CommitmentNoDelay)
largeInputResult, err := ctx.sweeper.SweepInput(
&largeInput, defaultFeePref,
)
if err != nil {
t.Fatal(err)
}
// Sweep an additional input with a negative net yield. The weight of
// the HtlcAcceptedRemoteSuccess input type adds more in fees than its
// value at the current fee level.
negInput := createTestInput(2900, input.HtlcOfferedRemoteTimeout)
negInputResult, err := ctx.sweeper.SweepInput(&negInput, defaultFeePref)
if err != nil {
t.Fatal(err)
}
// Sweep a third input that has a smaller output than the previous one,
// but yields positively because of its lower weight.
positiveInput := createTestInput(2800, input.CommitmentNoDelay)
positiveInputResult, err := ctx.sweeper.SweepInput(
&positiveInput, defaultFeePref,
)
if err != nil {
t.Fatal(err)
}
// We expect that a sweep tx is published now, but it should only
// contain the large input. The negative input should stay out of sweeps
// until fees come down to get a positive net yield.
sweepTx1 := ctx.receiveTx()
assertTxSweepsInputs(t, &sweepTx1, &largeInput, &positiveInput)
ctx.backend.mine()
ctx.expectResult(largeInputResult, nil)
ctx.expectResult(positiveInputResult, nil)
// Lower fee rate so that the negative input is no longer negative.
ctx.estimator.updateFees(1000, 1000)
// Create another large input.
secondLargeInput := createTestInput(100000, input.CommitmentNoDelay)
secondLargeInputResult, err := ctx.sweeper.SweepInput(
&secondLargeInput, defaultFeePref,
)
if err != nil {
t.Fatal(err)
}
sweepTx2 := ctx.receiveTx()
assertTxSweepsInputs(t, &sweepTx2, &secondLargeInput, &negInput)
ctx.backend.mine()
ctx.expectResult(secondLargeInputResult, nil)
ctx.expectResult(negInputResult, nil)
ctx.finish(1)
}
// TestChunks asserts that large sets of inputs are split into multiple txes.
func TestChunks(t *testing.T) {
ctx := createSweeperTestContext(t)
// Sweep five inputs.
for _, input := range spendableInputs[:5] {
_, err := ctx.sweeper.SweepInput(input, defaultFeePref)
if err != nil {
t.Fatal(err)
}
}
// We expect two txes to be published because of the max input count of
// three.
sweepTx1 := ctx.receiveTx()
if len(sweepTx1.TxIn) != 3 {
t.Fatalf("Expected first tx to sweep 3 inputs, but contains %v "+
"inputs instead", len(sweepTx1.TxIn))
}
sweepTx2 := ctx.receiveTx()
if len(sweepTx2.TxIn) != 2 {
t.Fatalf("Expected first tx to sweep 2 inputs, but contains %v "+
"inputs instead", len(sweepTx1.TxIn))
}
ctx.backend.mine()
ctx.finish(1)
}
// TestRemoteSpend asserts that remote spends are properly detected and handled
// both before the sweep is published as well as after.
func TestRemoteSpend(t *testing.T) {
t.Run("pre-sweep", func(t *testing.T) {
testRemoteSpend(t, false)
})
t.Run("post-sweep", func(t *testing.T) {
testRemoteSpend(t, true)
})
}
func testRemoteSpend(t *testing.T, postSweep bool) {
ctx := createSweeperTestContext(t)
resultChan1, err := ctx.sweeper.SweepInput(
spendableInputs[0], defaultFeePref,
)
if err != nil {
t.Fatal(err)
}
resultChan2, err := ctx.sweeper.SweepInput(
spendableInputs[1], defaultFeePref,
)
if err != nil {
t.Fatal(err)
}
// Spend the input with an unknown tx.
remoteTx := &wire.MsgTx{
TxIn: []*wire.TxIn{
{
PreviousOutPoint: *(spendableInputs[0].OutPoint()),
},
},
}
err = ctx.backend.publishTransaction(remoteTx)
if err != nil {
t.Fatal(err)
}
if postSweep {
// Tx publication by sweeper returns ErrDoubleSpend. Sweeper
// will retry the inputs without reporting a result. It could be
// spent by the remote party.
ctx.receiveTx()
}
ctx.backend.mine()
select {
case result := <-resultChan1:
if result.Err != ErrRemoteSpend {
t.Fatalf("expected remote spend")
}
if result.Tx.TxHash() != remoteTx.TxHash() {
t.Fatalf("expected remote spend tx")
}
case <-time.After(5 * time.Second):
t.Fatalf("no result received")
}
if !postSweep {
// Assert that the sweeper sweeps the remaining input.
sweepTx := ctx.receiveTx()
if len(sweepTx.TxIn) != 1 {
t.Fatal("expected sweep to only sweep the one remaining output")
}
ctx.backend.mine()
ctx.expectResult(resultChan2, nil)
ctx.finish(1)
} else {
// Expected sweeper to be still listening for spend of the
// error input.
ctx.finish(2)
select {
case <-resultChan2:
t.Fatalf("no result expected for error input")
default:
}
}
}
// TestIdempotency asserts that offering the same input multiple times is
// handled correctly.
func TestIdempotency(t *testing.T) {
ctx := createSweeperTestContext(t)
input := spendableInputs[0]
resultChan1, err := ctx.sweeper.SweepInput(input, defaultFeePref)
if err != nil {
t.Fatal(err)
}
resultChan2, err := ctx.sweeper.SweepInput(input, defaultFeePref)
if err != nil {
t.Fatal(err)
}
ctx.receiveTx()
resultChan3, err := ctx.sweeper.SweepInput(input, defaultFeePref)
if err != nil {
t.Fatal(err)
}
// Spend the input of the sweep tx.
ctx.backend.mine()
ctx.expectResult(resultChan1, nil)
ctx.expectResult(resultChan2, nil)
ctx.expectResult(resultChan3, nil)
// Offer the same input again. The sweeper will register a spend ntfn
// for this input. Because the input has already been spent, it will
// immediately receive the spend notification with a spending tx hash.
// Because the sweeper kept track of all of its sweep txes, it will
// recognize the spend as its own.
resultChan4, err := ctx.sweeper.SweepInput(input, defaultFeePref)
if err != nil {
t.Fatal(err)
}
ctx.expectResult(resultChan4, nil)
// Timer is still running, but spend notification was delivered before
// it expired.
ctx.finish(1)
}
// TestNoInputs asserts that nothing happens if nothing happens.
func TestNoInputs(t *testing.T) {
ctx := createSweeperTestContext(t)
// No tx should appear. This is asserted in finish().
ctx.finish(1)
}
// TestRestart asserts that the sweeper picks up sweeping properly after
// a restart.
func TestRestart(t *testing.T) {
ctx := createSweeperTestContext(t)
// Sweep input and expect sweep tx.
input1 := spendableInputs[0]
_, err := ctx.sweeper.SweepInput(input1, defaultFeePref)
require.NoError(t, err)
ctx.receiveTx()
// Restart sweeper.
ctx.restartSweeper()
// Simulate other subsystem (e.g. contract resolver) re-offering inputs.
spendChan1, err := ctx.sweeper.SweepInput(input1, defaultFeePref)
if err != nil {
t.Fatal(err)
}
input2 := spendableInputs[1]
spendChan2, err := ctx.sweeper.SweepInput(input2, defaultFeePref)
if err != nil {
t.Fatal(err)
}
// Spend inputs of sweep txes and verify that spend channels signal
// spends.
ctx.backend.mine()
// Sweeper should recognize that its sweep tx of the previous run is
// spending the input.
select {
case result := <-spendChan1:
if result.Err != nil {
t.Fatalf("expected successful sweep")
}
case <-time.After(defaultTestTimeout):
t.Fatalf("no result received")
}
// Timer tick should trigger republishing a sweep for the remaining
// input.
ctx.receiveTx()
ctx.backend.mine()
select {
case result := <-spendChan2:
if result.Err != nil {
t.Fatalf("expected successful sweep")
}
case <-time.After(defaultTestTimeout):
t.Fatalf("no result received")
}
// Restart sweeper again. No action is expected.
ctx.restartSweeper()
ctx.finish(1)
}
// TestRestartRemoteSpend asserts that the sweeper picks up sweeping properly
// after a restart with remote spend.
func TestRestartRemoteSpend(t *testing.T) {
ctx := createSweeperTestContext(t)
// Sweep input.
input1 := spendableInputs[0]
_, err := ctx.sweeper.SweepInput(input1, defaultFeePref)
require.NoError(t, err)
// Sweep another input.
input2 := spendableInputs[1]
_, err = ctx.sweeper.SweepInput(input2, defaultFeePref)
require.NoError(t, err)
sweepTx := ctx.receiveTx()
// Restart sweeper.
ctx.restartSweeper()
// Replace the sweep tx with a remote tx spending input 1.
ctx.backend.deleteUnconfirmed(sweepTx.TxHash())
remoteTx := &wire.MsgTx{
TxIn: []*wire.TxIn{
{
PreviousOutPoint: *(input2.OutPoint()),
},
},
}
if err := ctx.backend.publishTransaction(remoteTx); err != nil {
t.Fatal(err)
}
// Mine remote spending tx.
ctx.backend.mine()
// Simulate other subsystem (e.g. contract resolver) re-offering input
// 0.
spendChan, err := ctx.sweeper.SweepInput(input1, defaultFeePref)
if err != nil {
t.Fatal(err)
}
// Expect sweeper to construct a new tx, because input 1 was spend
// remotely.
ctx.receiveTx()
ctx.backend.mine()
ctx.expectResult(spendChan, nil)
ctx.finish(1)
}
// TestRestartConfirmed asserts that the sweeper picks up sweeping properly
// after a restart with a confirm of our own sweep tx.
func TestRestartConfirmed(t *testing.T) {
ctx := createSweeperTestContext(t)
// Sweep input.
input := spendableInputs[0]
if _, err := ctx.sweeper.SweepInput(input, defaultFeePref); err != nil {
t.Fatal(err)
}
ctx.receiveTx()
// Restart sweeper.
ctx.restartSweeper()
// Mine the sweep tx.
ctx.backend.mine()
// Simulate other subsystem (e.g. contract resolver) re-offering input
// 0.
spendChan, err := ctx.sweeper.SweepInput(input, defaultFeePref)
if err != nil {
t.Fatal(err)
}
// Here we expect again a successful sweep.
ctx.expectResult(spendChan, nil)
ctx.finish(1)
}
// TestRetry tests the sweeper retry flow.
func TestRetry(t *testing.T) {
ctx := createSweeperTestContext(t)
resultChan0, err := ctx.sweeper.SweepInput(
spendableInputs[0], defaultFeePref,
)
if err != nil {
t.Fatal(err)
}
// We expect a sweep to be published.
ctx.receiveTx()
// Offer a fresh input.
resultChan1, err := ctx.sweeper.SweepInput(
spendableInputs[1], defaultFeePref,
)
if err != nil {
t.Fatal(err)
}
// A single tx is expected to be published.
ctx.receiveTx()
ctx.backend.mine()
ctx.expectResult(resultChan0, nil)
ctx.expectResult(resultChan1, nil)
ctx.finish(1)
}
// TestDifferentFeePreferences ensures that the sweeper can have different
// transactions for different fee preferences. These transactions should be
// broadcast from highest to lowest fee rate.
func TestDifferentFeePreferences(t *testing.T) {
ctx := createSweeperTestContext(t)
// Throughout this test, we'll be attempting to sweep three inputs, two
// with the higher fee preference, and the last with the lower. We do
// this to ensure the sweeper can broadcast distinct transactions for
// each sweep with a different fee preference.
lowFeePref := FeeEstimateInfo{ConfTarget: 12}
lowFeeRate := chainfee.SatPerKWeight(5000)
ctx.estimator.blocksToFee[lowFeePref.ConfTarget] = lowFeeRate
highFeePref := FeeEstimateInfo{ConfTarget: 6}
highFeeRate := chainfee.SatPerKWeight(10000)
ctx.estimator.blocksToFee[highFeePref.ConfTarget] = highFeeRate
input1 := spendableInputs[0]
resultChan1, err := ctx.sweeper.SweepInput(
input1, Params{Fee: highFeePref},
)
if err != nil {
t.Fatal(err)
}
input2 := spendableInputs[1]
resultChan2, err := ctx.sweeper.SweepInput(
input2, Params{Fee: highFeePref},
)
if err != nil {
t.Fatal(err)
}
input3 := spendableInputs[2]
resultChan3, err := ctx.sweeper.SweepInput(
input3, Params{Fee: lowFeePref},
)
if err != nil {
t.Fatal(err)
}
// Generate the same type of sweep script that was used for weight
// estimation.
changePk, err := ctx.sweeper.cfg.GenSweepScript()
require.NoError(t, err)
// The first transaction broadcast should be the one spending the higher
// fee rate inputs.
sweepTx1 := ctx.receiveTx()
assertTxFeeRate(t, &sweepTx1, highFeeRate, changePk, input1, input2)
// The second should be the one spending the lower fee rate inputs.
sweepTx2 := ctx.receiveTx()
assertTxFeeRate(t, &sweepTx2, lowFeeRate, changePk, input3)
// With the transactions broadcast, we'll mine a block to so that the
// result is delivered to each respective client.
ctx.backend.mine()
resultChans := []chan Result{resultChan1, resultChan2, resultChan3}
for _, resultChan := range resultChans {
ctx.expectResult(resultChan, nil)
}
ctx.finish(1)
}
// TestPendingInputs ensures that the sweeper correctly determines the inputs
// pending to be swept.
func TestPendingInputs(t *testing.T) {
ctx := createSweeperTestContext(t)
// Throughout this test, we'll be attempting to sweep three inputs, two
// with the higher fee preference, and the last with the lower. We do
// this to ensure the sweeper can return all pending inputs, even those
// with different fee preferences.
const (
lowFeeRate = 5000
highFeeRate = 10000
)
lowFeePref := FeeEstimateInfo{
ConfTarget: 12,
}
ctx.estimator.blocksToFee[lowFeePref.ConfTarget] = lowFeeRate
highFeePref := FeeEstimateInfo{
ConfTarget: 6,
}
ctx.estimator.blocksToFee[highFeePref.ConfTarget] = highFeeRate
input1 := spendableInputs[0]
resultChan1, err := ctx.sweeper.SweepInput(
input1, Params{Fee: highFeePref},
)
if err != nil {
t.Fatal(err)
}
input2 := spendableInputs[1]
_, err = ctx.sweeper.SweepInput(
input2, Params{Fee: highFeePref},
)
if err != nil {
t.Fatal(err)
}
input3 := spendableInputs[2]
resultChan3, err := ctx.sweeper.SweepInput(
input3, Params{Fee: lowFeePref},
)
if err != nil {
t.Fatal(err)
}
// We should expect to see all inputs pending.
ctx.assertPendingInputs(input1, input2, input3)
// We should expect to see both sweep transactions broadcast - one for
// the higher feerate, the other for the lower.
ctx.receiveTx()
ctx.receiveTx()
// Mine these txns, and we should expect to see the results delivered.
ctx.backend.mine()
ctx.expectResult(resultChan1, nil)
ctx.expectResult(resultChan3, nil)
ctx.assertPendingInputs()
ctx.finish(1)
}
// TestBumpFeeRBF ensures that the UtxoSweeper can properly handle a fee bump
// request for an input it is currently attempting to sweep. When sweeping the
// input with the higher fee rate, a replacement transaction is created.
func TestBumpFeeRBF(t *testing.T) {
ctx := createSweeperTestContext(t)
lowFeePref := FeeEstimateInfo{ConfTarget: 144}
lowFeeRate := chainfee.FeePerKwFloor
ctx.estimator.blocksToFee[lowFeePref.ConfTarget] = lowFeeRate
// We'll first try to bump the fee of an output currently unknown to the
// UtxoSweeper. Doing so should result in a lnwallet.ErrNotMine error.
_, err := ctx.sweeper.UpdateParams(
wire.OutPoint{}, ParamsUpdate{Fee: lowFeePref},
)
if err != lnwallet.ErrNotMine {
t.Fatalf("expected error lnwallet.ErrNotMine, got \"%v\"", err)
}
// We'll then attempt to sweep an input, which we'll use to bump its fee
// later on.
input := createTestInput(
btcutil.SatoshiPerBitcoin, input.CommitmentTimeLock,
)
sweepResult, err := ctx.sweeper.SweepInput(
&input, Params{Fee: lowFeePref},
)
if err != nil {
t.Fatal(err)
}
// Generate the same type of change script used so we can have accurate
// weight estimation.
changePk, err := ctx.sweeper.cfg.GenSweepScript()
require.NoError(t, err)
// Ensure that a transaction is broadcast with the lower fee preference.
lowFeeTx := ctx.receiveTx()
assertTxFeeRate(t, &lowFeeTx, lowFeeRate, changePk, &input)
// We'll then attempt to bump its fee rate.
highFeePref := FeeEstimateInfo{ConfTarget: 6}
highFeeRate := DefaultMaxFeeRate.FeePerKWeight()
ctx.estimator.blocksToFee[highFeePref.ConfTarget] = highFeeRate
// We should expect to see an error if a fee preference isn't provided.
_, err = ctx.sweeper.UpdateParams(*input.OutPoint(), ParamsUpdate{
Fee: &FeeEstimateInfo{},
})
if err != ErrNoFeePreference {
t.Fatalf("expected ErrNoFeePreference, got %v", err)
}
bumpResult, err := ctx.sweeper.UpdateParams(
*input.OutPoint(), ParamsUpdate{Fee: highFeePref},
)
require.NoError(t, err, "unable to bump input's fee")
// A higher fee rate transaction should be immediately broadcast.
highFeeTx := ctx.receiveTx()
assertTxFeeRate(t, &highFeeTx, highFeeRate, changePk, &input)
// We'll finish our test by mining the sweep transaction.
ctx.backend.mine()
ctx.expectResult(sweepResult, nil)
ctx.expectResult(bumpResult, nil)
ctx.finish(1)
}
// TestExclusiveGroup tests the sweeper exclusive group functionality.
func TestExclusiveGroup(t *testing.T) {
ctx := createSweeperTestContext(t)
// Sweep three inputs in the same exclusive group.
var results []chan Result
for i := 0; i < 3; i++ {
exclusiveGroup := uint64(1)
result, err := ctx.sweeper.SweepInput(
spendableInputs[i], Params{
Fee: FeeEstimateInfo{ConfTarget: 6},
ExclusiveGroup: &exclusiveGroup,
},
)
if err != nil {
t.Fatal(err)
}
results = append(results, result)
}
// We expect all inputs to be published in separate transactions, even
// though they share the same fee preference.
for i := 0; i < 3; i++ {
sweepTx := ctx.receiveTx()
if len(sweepTx.TxOut) != 1 {
t.Fatal("expected a single tx out in the sweep tx")
}
// Remove all txes except for the one that sweeps the first
// input. This simulates the sweeps being conflicting.
if sweepTx.TxIn[0].PreviousOutPoint !=
*spendableInputs[0].OutPoint() {
ctx.backend.deleteUnconfirmed(sweepTx.TxHash())
}
}
// Mine the first sweep tx.
ctx.backend.mine()
// Expect the first input to be swept by the confirmed sweep tx.
result0 := <-results[0]
if result0.Err != nil {
t.Fatal("expected first input to be swept")
}
// Expect the other two inputs to return an error. They have no chance
// of confirming.
result1 := <-results[1]
if result1.Err != ErrExclusiveGroupSpend {
t.Fatal("expected second input to be canceled")
}
result2 := <-results[2]
if result2.Err != ErrExclusiveGroupSpend {
t.Fatal("expected third input to be canceled")
}
}
// TestCpfp tests that the sweeper spends cpfp inputs at a fee rate that exceeds
// the parent tx fee rate.
func TestCpfp(t *testing.T) {
ctx := createSweeperTestContext(t)
ctx.estimator.updateFees(1000, chainfee.FeePerKwFloor)
// Offer an input with an unconfirmed parent tx to the sweeper. The
// parent tx pays 3000 sat/kw.
hash := chainhash.Hash{1}
input := input.MakeBaseInput(
&wire.OutPoint{Hash: hash},
input.CommitmentTimeLock,
&input.SignDescriptor{
Output: &wire.TxOut{
Value: 330,
},
KeyDesc: keychain.KeyDescriptor{
PubKey: testPubKey,
},
},
0,
&input.TxInfo{
Weight: 300,
Fee: 900,
},
)
feePref := FeeEstimateInfo{ConfTarget: 6}
result, err := ctx.sweeper.SweepInput(
&input, Params{Fee: feePref, Force: true},
)
require.NoError(t, err)
// Increase the fee estimate to above the parent tx fee rate.
ctx.estimator.updateFees(5000, chainfee.FeePerKwFloor)
// Signal a new block. This is a trigger for the sweeper to refresh fee
// estimates.
ctx.notifier.NotifyEpoch(1000)
// Now we do expect a sweep transaction to be published with our input
// and an attached wallet utxo.
tx := ctx.receiveTx()
require.Len(t, tx.TxIn, 2)
require.Len(t, tx.TxOut, 1)
// As inputs we have 10000 sats from the wallet and 330 sats from the
// cpfp input. The sweep tx is weight expected to be 759 units. There is
// an additional 300 weight units from the parent to include in the
// package, making a total of 1059. At 5000 sat/kw, the required fee for
// the package is 5295 sats. The parent already paid 900 sats, so there
// is 4395 sat remaining to be paid. The expected output value is
// therefore: 1_000_000 + 330 - 4395 = 995 935.
require.Equal(t, int64(995_935), tx.TxOut[0].Value)
// Mine the tx and assert that the result is passed back.
ctx.backend.mine()
ctx.expectResult(result, nil)
ctx.finish(1)
}
type testInput struct {
*input.BaseInput
locktime *uint32
reqTxOut *wire.TxOut
}
func (i *testInput) RequiredLockTime() (uint32, bool) {
if i.locktime != nil {
return *i.locktime, true
}
return 0, false
}
func (i *testInput) RequiredTxOut() *wire.TxOut {
return i.reqTxOut
}
// CraftInputScript is a custom sign method for the testInput type that will
// encode the spending outpoint and the tx input index as part of the returned
// witness.
func (i *testInput) CraftInputScript(_ input.Signer, txn *wire.MsgTx,
hashCache *txscript.TxSigHashes,
prevOutputFetcher txscript.PrevOutputFetcher,
txinIdx int) (*input.Script, error) {
// We'll encode the outpoint in the witness, so we can assert that the
// expected input was signed at the correct index.
op := i.OutPoint()
return &input.Script{
Witness: [][]byte{
// We encode the hash of the outpoint...
op.Hash[:],
// ..the outpoint index...
{byte(op.Index)},
// ..and finally the tx input index.
{byte(txinIdx)},
},
}, nil
}
// assertSignedIndex goes through all inputs to the tx and checks that all
// testInputs have witnesses corresponding to the outpoints they are spending,
// and are signed at the correct tx input index. All found testInputs are
// returned such that we can sum up and sanity check that all testInputs were
// part of the sweep.
func assertSignedIndex(t *testing.T, tx *wire.MsgTx,
testInputs map[wire.OutPoint]*testInput) map[wire.OutPoint]struct{} {
found := make(map[wire.OutPoint]struct{})
for idx, txIn := range tx.TxIn {
op := txIn.PreviousOutPoint
// Not a testInput, it won't have the test encoding we require
// to check outpoint and index.
if _, ok := testInputs[op]; !ok {
continue
}
if _, ok := found[op]; ok {
t.Fatalf("input already used")
}
// Check it was signes spending the correct outpoint, and at
// the expected tx input index.
require.Equal(t, txIn.Witness[0], op.Hash[:])
require.Equal(t, txIn.Witness[1], []byte{byte(op.Index)})
require.Equal(t, txIn.Witness[2], []byte{byte(idx)})
found[op] = struct{}{}
}
return found
}
// TestLockTimes checks that the sweeper properly groups inputs requiring the
// same locktime together into sweep transactions.
func TestLockTimes(t *testing.T) {
ctx := createSweeperTestContext(t)
// We increase the number of max inputs to a tx so that won't
// impact our test.
ctx.sweeper.cfg.MaxInputsPerTx = 100
// We will set up the lock times in such a way that we expect the
// sweeper to divide the inputs into 4 diffeerent transactions.
const numSweeps = 4
// Sweep 8 inputs, using 4 different lock times.
var (
results []chan Result
inputs = make(map[wire.OutPoint]input.Input)
)
for i := 0; i < numSweeps*2; i++ {
lt := uint32(10 + (i % numSweeps))
inp := &testInput{
BaseInput: spendableInputs[i],
locktime: &lt,
}
result, err := ctx.sweeper.SweepInput(
inp, Params{
Fee: FeeEstimateInfo{ConfTarget: 6},
},
)
if err != nil {
t.Fatal(err)
}
results = append(results, result)
op := inp.OutPoint()
inputs[*op] = inp
}
// We also add 3 regular inputs that don't require any specific lock
// time.
for i := 0; i < 3; i++ {
inp := spendableInputs[i+numSweeps*2]
result, err := ctx.sweeper.SweepInput(
inp, Params{
Fee: FeeEstimateInfo{ConfTarget: 6},
},
)
if err != nil {
t.Fatal(err)
}
results = append(results, result)
op := inp.OutPoint()
inputs[*op] = inp
}
// Check the sweeps transactions, ensuring all inputs are there, and
// all the locktimes are satisfied.
for i := 0; i < numSweeps; i++ {
sweepTx := ctx.receiveTx()
if len(sweepTx.TxOut) != 1 {
t.Fatal("expected a single tx out in the sweep tx")
}
for _, txIn := range sweepTx.TxIn {
op := txIn.PreviousOutPoint
inp, ok := inputs[op]
if !ok {
t.Fatalf("Unexpected outpoint: %v", op)
}
delete(inputs, op)
// If this input had a required locktime, ensure the tx
// has that set correctly.
lt, ok := inp.RequiredLockTime()
if !ok {
continue
}
if lt != sweepTx.LockTime {
t.Fatalf("Input required locktime %v, sweep "+
"tx had locktime %v", lt, sweepTx.LockTime)
}
}
}
// The should be no inputs not foud in any of the sweeps.
if len(inputs) != 0 {
t.Fatalf("had unsweeped inputs")
}
// Mine the first sweeps
ctx.backend.mine()
// Results should all come back.
for i := range results {
result := <-results[i]
if result.Err != nil {
t.Fatal("expected input to be swept")
}
}
}
// TestRequiredTxOuts checks that inputs having a required TxOut gets swept with
// sweep transactions paying into these outputs.
func TestRequiredTxOuts(t *testing.T) {
// Create some test inputs and locktime vars.
var inputs []*input.BaseInput
for i := 0; i < 20; i++ {
input := createTestInput(
int64(btcutil.SatoshiPerBitcoin+i*500),
input.CommitmentTimeLock,
)
inputs = append(inputs, &input)
}
locktime1 := uint32(51)
locktime2 := uint32(52)
locktime3 := uint32(53)
aPkScript := make([]byte, input.P2WPKHSize)
aPkScript[0] = 'a'
bPkScript := make([]byte, input.P2WSHSize)
bPkScript[0] = 'b'
cPkScript := make([]byte, input.P2PKHSize)
cPkScript[0] = 'c'
dPkScript := make([]byte, input.P2SHSize)
dPkScript[0] = 'd'
ePkScript := make([]byte, input.UnknownWitnessSize)
ePkScript[0] = 'e'
fPkScript := make([]byte, input.P2WSHSize)
fPkScript[0] = 'f'
testCases := []struct {
name string
inputs []*testInput
assertSweeps func(*testing.T, map[wire.OutPoint]*testInput,
[]*wire.MsgTx)
}{
{
// Single input with a required TX out that is smaller.
// We expect a change output to be added.
name: "single input, leftover change",
inputs: []*testInput{
{
BaseInput: inputs[0],
reqTxOut: &wire.TxOut{
PkScript: aPkScript,
Value: 100000,
},
},
},
// Since the required output value is small, we expect
// the rest after fees to go into a change output.
assertSweeps: func(t *testing.T,
_ map[wire.OutPoint]*testInput,
txs []*wire.MsgTx) {
require.Equal(t, 1, len(txs))
tx := txs[0]
require.Equal(t, 1, len(tx.TxIn))
// We should have two outputs, the required
// output must be the first one.
require.Equal(t, 2, len(tx.TxOut))
out := tx.TxOut[0]
require.Equal(t, aPkScript, out.PkScript)
require.Equal(t, int64(100000), out.Value)
},
},
{
// An input committing to a slightly smaller output, so
// it will pay its own fees.
name: "single input, no change",
inputs: []*testInput{
{
BaseInput: inputs[0],
reqTxOut: &wire.TxOut{
PkScript: aPkScript,
// Fee will be about 5340 sats.
// Subtract a bit more to
// ensure no dust change output
// is manifested.
Value: inputs[0].SignDesc().Output.Value - 6300,
},
},
},
// We expect this single input/output pair.
assertSweeps: func(t *testing.T,
_ map[wire.OutPoint]*testInput,
txs []*wire.MsgTx) {
require.Equal(t, 1, len(txs))
tx := txs[0]
require.Equal(t, 1, len(tx.TxIn))
require.Equal(t, 1, len(tx.TxOut))
out := tx.TxOut[0]
require.Equal(t, aPkScript, out.PkScript)
require.Equal(
t,
inputs[0].SignDesc().Output.Value-6300,
out.Value,
)
},
},
{
// Two inputs, where the first one required no tx out.
name: "two inputs, one with required tx out",
inputs: []*testInput{
{
// We add a normal, non-requiredTxOut
// input. We use test input 10, to make
// sure this has a higher yield than
// the other input, and will be
// attempted added first to the sweep
// tx.
BaseInput: inputs[10],
},
{
// The second input requires a TxOut.
BaseInput: inputs[0],
reqTxOut: &wire.TxOut{
PkScript: aPkScript,
Value: inputs[0].SignDesc().Output.Value,
},
},
},
// We expect the inputs to have been reordered.
assertSweeps: func(t *testing.T,
_ map[wire.OutPoint]*testInput,
txs []*wire.MsgTx) {
require.Equal(t, 1, len(txs))
tx := txs[0]
require.Equal(t, 2, len(tx.TxIn))
require.Equal(t, 2, len(tx.TxOut))
// The required TxOut should be the first one.
out := tx.TxOut[0]
require.Equal(t, aPkScript, out.PkScript)
require.Equal(
t, inputs[0].SignDesc().Output.Value,
out.Value,
)
// The first input should be the one having the
// required TxOut.
require.Len(t, tx.TxIn, 2)
require.Equal(
t, inputs[0].OutPoint(),
&tx.TxIn[0].PreviousOutPoint,
)
// Second one is the one without a required tx
// out.
require.Equal(
t, inputs[10].OutPoint(),
&tx.TxIn[1].PreviousOutPoint,
)
},
},
{
// An input committing to an output of equal value, just
// add input to pay fees.
name: "single input, extra fee input",
inputs: []*testInput{
{
BaseInput: inputs[0],
reqTxOut: &wire.TxOut{
PkScript: aPkScript,
Value: inputs[0].SignDesc().Output.Value,
},
},
},
// We expect an extra input and output.
assertSweeps: func(t *testing.T,
_ map[wire.OutPoint]*testInput,
txs []*wire.MsgTx) {
require.Equal(t, 1, len(txs))
tx := txs[0]
require.Equal(t, 2, len(tx.TxIn))
require.Equal(t, 2, len(tx.TxOut))
out := tx.TxOut[0]
require.Equal(t, aPkScript, out.PkScript)
require.Equal(
t, inputs[0].SignDesc().Output.Value,
out.Value,
)
},
},
{
// Three inputs added, should be combined into a single
// sweep.
name: "three inputs",
inputs: []*testInput{
{
BaseInput: inputs[0],
reqTxOut: &wire.TxOut{
PkScript: aPkScript,
Value: inputs[0].SignDesc().Output.Value,
},
},
{
BaseInput: inputs[1],
reqTxOut: &wire.TxOut{
PkScript: bPkScript,
Value: inputs[1].SignDesc().Output.Value,
},
},
{
BaseInput: inputs[2],
reqTxOut: &wire.TxOut{
PkScript: cPkScript,
Value: inputs[2].SignDesc().Output.Value,
},
},
},
// We expect an extra input and output to pay fees.
assertSweeps: func(t *testing.T,
testInputs map[wire.OutPoint]*testInput,
txs []*wire.MsgTx) {
require.Equal(t, 1, len(txs))
tx := txs[0]
require.Equal(t, 4, len(tx.TxIn))
require.Equal(t, 4, len(tx.TxOut))
// The inputs and outputs must be in the same
// order.
for i, in := range tx.TxIn {
// Last one is the change input/output
// pair, so we'll skip it.
if i == 3 {
continue
}
// Get this input to ensure the output
// on index i coresponsd to this one.
inp := testInputs[in.PreviousOutPoint]
require.NotNil(t, inp)
require.Equal(
t, tx.TxOut[i].Value,
inp.SignDesc().Output.Value,
)
}
},
},
{
// Six inputs added, which 3 different locktimes.
// Should result in 3 sweeps.
name: "six inputs",
inputs: []*testInput{
{
BaseInput: inputs[0],
locktime: &locktime1,
reqTxOut: &wire.TxOut{
PkScript: aPkScript,
Value: inputs[0].SignDesc().Output.Value,
},
},
{
BaseInput: inputs[1],
locktime: &locktime1,
reqTxOut: &wire.TxOut{
PkScript: bPkScript,
Value: inputs[1].SignDesc().Output.Value,
},
},
{
BaseInput: inputs[2],
locktime: &locktime2,
reqTxOut: &wire.TxOut{
PkScript: cPkScript,
Value: inputs[2].SignDesc().Output.Value,
},
},
{
BaseInput: inputs[3],
locktime: &locktime2,
reqTxOut: &wire.TxOut{
PkScript: dPkScript,
Value: inputs[3].SignDesc().Output.Value,
},
},
{
BaseInput: inputs[4],
locktime: &locktime3,
reqTxOut: &wire.TxOut{
PkScript: ePkScript,
Value: inputs[4].SignDesc().Output.Value,
},
},
{
BaseInput: inputs[5],
locktime: &locktime3,
reqTxOut: &wire.TxOut{
PkScript: fPkScript,
Value: inputs[5].SignDesc().Output.Value,
},
},
},
// We expect three sweeps, each having two of our
// inputs, one extra input and output to pay fees.
assertSweeps: func(t *testing.T,
testInputs map[wire.OutPoint]*testInput,
txs []*wire.MsgTx) {
require.Equal(t, 3, len(txs))
for _, tx := range txs {
require.Equal(t, 3, len(tx.TxIn))
require.Equal(t, 3, len(tx.TxOut))
// The inputs and outputs must be in
// the same order.
for i, in := range tx.TxIn {
// Last one is the change
// output, so we'll skip it.
if i == 2 {
continue
}
// Get this input to ensure the
// output on index i coresponsd
// to this one.
inp := testInputs[in.PreviousOutPoint]
require.NotNil(t, inp)
require.Equal(
t, tx.TxOut[i].Value,
inp.SignDesc().Output.Value,
)
// Check that the locktimes are
// kept intact.
require.Equal(
t, tx.LockTime,
*inp.locktime,
)
}
}
},
},
}
for _, testCase := range testCases {
testCase := testCase
t.Run(testCase.name, func(t *testing.T) {
ctx := createSweeperTestContext(t)
// We increase the number of max inputs to a tx so that
// won't impact our test.
ctx.sweeper.cfg.MaxInputsPerTx = 100
// Sweep all test inputs.
var (
inputs = make(map[wire.OutPoint]*testInput)
results = make(map[wire.OutPoint]chan Result)
)
for _, inp := range testCase.inputs {
result, err := ctx.sweeper.SweepInput(
inp, Params{
Fee: FeeEstimateInfo{
ConfTarget: 6,
},
},
)
if err != nil {
t.Fatal(err)
}
op := inp.OutPoint()
results[*op] = result
inputs[*op] = inp
}
// Check the sweeps transactions, ensuring all inputs
// are there, and all the locktimes are satisfied.
var sweeps []*wire.MsgTx
Loop:
for {
select {
case tx := <-ctx.publishChan:
sweeps = append(sweeps, &tx)
case <-time.After(200 * time.Millisecond):
break Loop
}
}
// Mine the sweeps.
ctx.backend.mine()
// Results should all come back.
for _, resultChan := range results {
result := <-resultChan
if result.Err != nil {
t.Fatalf("expected input to be "+
"swept: %v", result.Err)
}
}
// Assert the transactions are what we expect.
testCase.assertSweeps(t, inputs, sweeps)
// Finally we assert that all our test inputs were part
// of the sweeps, and that they were signed correctly.
sweptInputs := make(map[wire.OutPoint]struct{})
for _, sweep := range sweeps {
swept := assertSignedIndex(t, sweep, inputs)
for op := range swept {
if _, ok := sweptInputs[op]; ok {
t.Fatalf("outpoint %v part of "+
"previous sweep", op)
}
sweptInputs[op] = struct{}{}
}
}
require.Equal(t, len(inputs), len(sweptInputs))
for op := range sweptInputs {
_, ok := inputs[op]
if !ok {
t.Fatalf("swept input %v not part of "+
"test inputs", op)
}
}
})
}
}
// TestSweeperShutdownHandling tests that we notify callers when the sweeper
// cannot handle requests since it's in the process of shutting down.
func TestSweeperShutdownHandling(t *testing.T) {
ctx := createSweeperTestContext(t)
// Make the backing notifier break down. This is what happens during
// lnd shut down, since the notifier is stopped before the sweeper.
require.Len(t, ctx.notifier.epochChan, 1)
for epochChan := range ctx.notifier.epochChan {
close(epochChan)
}
// Give the collector some time to exit.
time.Sleep(50 * time.Millisecond)
// Now trying to sweep inputs should return an error on the error
// channel.
resultChan, err := ctx.sweeper.SweepInput(
spendableInputs[0], defaultFeePref,
)
require.NoError(t, err)
select {
case res := <-resultChan:
require.Equal(t, ErrSweeperShuttingDown, res.Err)
case <-time.After(defaultTestTimeout):
t.Fatalf("no result arrived")
}
// Stop the sweeper properly.
err = ctx.sweeper.Stop()
require.NoError(t, err)
// Now attempting to sweep an input should error out immediately.
_, err = ctx.sweeper.SweepInput(
spendableInputs[0], defaultFeePref,
)
require.Error(t, err)
}
// TestGetInputLists checks that the expected input sets are returned based on
// whether there are retried inputs or not.
func TestGetInputLists(t *testing.T) {
t.Parallel()
// Create a test param with a dummy fee preference. This is needed so
// `feeRateForPreference` won't throw an error.
param := Params{Fee: FeeEstimateInfo{ConfTarget: 1}}
// Create a mock input and mock all the methods used in this test.
testInput := &input.MockInput{}
testInput.On("RequiredLockTime").Return(0, false)
testInput.On("WitnessType").Return(input.CommitmentAnchor)
testInput.On("OutPoint").Return(&wire.OutPoint{Index: 1})
testInput.On("RequiredTxOut").Return(nil)
testInput.On("UnconfParent").Return(nil)
testInput.On("SignDesc").Return(&input.SignDescriptor{
Output: &wire.TxOut{Value: 100_000},
})
// Create a new and a retried input.
//
// NOTE: we use the same input.Input for both pending inputs as we only
// test the logic of returning the correct non-nil input sets, and not
// the content the of sets. To validate the content of the sets, we
// should test `generateInputPartitionings` instead.
newInput := &pendingInput{
Input: testInput,
params: param,
}
oldInput := &pendingInput{
Input: testInput,
params: param,
publishAttempts: 1,
}
// clusterNew contains only new inputs.
clusterNew := pendingInputs{
wire.OutPoint{Index: 1}: newInput,
}
// clusterMixed contains a mixed of new and retried inputs.
clusterMixed := pendingInputs{
wire.OutPoint{Index: 1}: newInput,
wire.OutPoint{Index: 2}: oldInput,
}
// clusterOld contains only retried inputs.
clusterOld := pendingInputs{
wire.OutPoint{Index: 2}: oldInput,
}
// Create a test sweeper.
s := New(&UtxoSweeperConfig{
MaxInputsPerTx: DefaultMaxInputsPerTx,
})
testCases := []struct {
name string
cluster inputCluster
expectedNilAllSet bool
expectNilNewSet bool
}{
{
// When there are only new inputs, we'd expect the
// first returned set(allSets) to be empty.
name: "new inputs only",
cluster: inputCluster{inputs: clusterNew},
expectedNilAllSet: true,
expectNilNewSet: false,
},
{
// When there are only retried inputs, we'd expect the
// second returned set(newSet) to be empty.
name: "retried inputs only",
cluster: inputCluster{inputs: clusterOld},
expectedNilAllSet: false,
expectNilNewSet: true,
},
{
// When there are mixed inputs, we'd expect two sets
// are returned.
name: "mixed inputs",
cluster: inputCluster{inputs: clusterMixed},
expectedNilAllSet: false,
expectNilNewSet: false,
},
}
for _, tc := range testCases {
tc := tc
t.Run(tc.name, func(t *testing.T) {
t.Parallel()
allSets, newSets, err := s.getInputLists(tc.cluster)
require.NoError(t, err)
if tc.expectNilNewSet {
require.Nil(t, newSets)
}
if tc.expectedNilAllSet {
require.Nil(t, allSets)
}
})
}
}
// TestMarkInputsPublished checks that given a list of inputs with different
// states, only the state `StatePendingPublish` will be marked as `Published`.
func TestMarkInputsPublished(t *testing.T) {
t.Parallel()
require := require.New(t)
// Create a mock sweeper store.
mockStore := NewMockSweeperStore()
// Create a test TxRecord and a dummy error.
dummyTR := &TxRecord{}
dummyErr := errors.New("dummy error")
// Create a test sweeper.
s := New(&UtxoSweeperConfig{
Store: mockStore,
})
// Create three testing inputs.
//
// inputNotExist specifies an input that's not found in the sweeper's
// `pendingInputs` map.
inputNotExist := &wire.TxIn{
PreviousOutPoint: wire.OutPoint{Index: 1},
}
// inputInit specifies a newly created input. When marking this as
// published, we should see an error log as this input hasn't been
// published yet.
inputInit := &wire.TxIn{
PreviousOutPoint: wire.OutPoint{Index: 2},
}
s.pendingInputs[inputInit.PreviousOutPoint] = &pendingInput{
state: StateInit,
}
// inputPendingPublish specifies an input that's about to be published.
inputPendingPublish := &wire.TxIn{
PreviousOutPoint: wire.OutPoint{Index: 3},
}
s.pendingInputs[inputPendingPublish.PreviousOutPoint] = &pendingInput{
state: StatePendingPublish,
}
// First, check that when an error is returned from db, it's properly
// returned here.
mockStore.On("StoreTx", dummyTR).Return(dummyErr).Once()
err := s.markInputsPublished(dummyTR, nil)
require.ErrorIs(err, dummyErr)
// We also expect the record has been marked as published.
require.True(dummyTR.Published)
// Then, check that the target input has will be correctly marked as
// published.
//
// Mock the store to return nil
mockStore.On("StoreTx", dummyTR).Return(nil).Once()
// Mark the test inputs. We expect the non-exist input and the
// inputInit to be skipped, and the final input to be marked as
// published.
err = s.markInputsPublished(dummyTR, []*wire.TxIn{
inputNotExist, inputInit, inputPendingPublish,
})
require.NoError(err)
// We expect unchanged number of pending inputs.
require.Len(s.pendingInputs, 2)
// We expect the init input's state to stay unchanged.
require.Equal(StateInit,
s.pendingInputs[inputInit.PreviousOutPoint].state)
// We expect the pending-publish input's is now marked as published.
require.Equal(StatePublished,
s.pendingInputs[inputPendingPublish.PreviousOutPoint].state)
// Assert mocked statements are executed as expected.
mockStore.AssertExpectations(t)
}
// TestMarkInputsPublishFailed checks that given a list of inputs with
// different states, only the state `StatePendingPublish` will be marked as
// `PublishFailed`.
func TestMarkInputsPublishFailed(t *testing.T) {
t.Parallel()
require := require.New(t)
// Create a mock sweeper store.
mockStore := NewMockSweeperStore()
// Create a test sweeper.
s := New(&UtxoSweeperConfig{
Store: mockStore,
})
// Create three testing inputs.
//
// inputNotExist specifies an input that's not found in the sweeper's
// `pendingInputs` map.
inputNotExist := &wire.TxIn{
PreviousOutPoint: wire.OutPoint{Index: 1},
}
// inputInit specifies a newly created input. When marking this as
// published, we should see an error log as this input hasn't been
// published yet.
inputInit := &wire.TxIn{
PreviousOutPoint: wire.OutPoint{Index: 2},
}
s.pendingInputs[inputInit.PreviousOutPoint] = &pendingInput{
state: StateInit,
}
// inputPendingPublish specifies an input that's about to be published.
inputPendingPublish := &wire.TxIn{
PreviousOutPoint: wire.OutPoint{Index: 3},
}
s.pendingInputs[inputPendingPublish.PreviousOutPoint] = &pendingInput{
state: StatePendingPublish,
}
// Mark the test inputs. We expect the non-exist input and the
// inputInit to be skipped, and the final input to be marked as
// published.
s.markInputsPublishFailed([]*wire.TxIn{
inputNotExist, inputInit, inputPendingPublish,
})
// We expect unchanged number of pending inputs.
require.Len(s.pendingInputs, 2)
// We expect the init input's state to stay unchanged.
require.Equal(StateInit,
s.pendingInputs[inputInit.PreviousOutPoint].state)
// We expect the pending-publish input's is now marked as publish
// failed.
require.Equal(StatePublishFailed,
s.pendingInputs[inputPendingPublish.PreviousOutPoint].state)
// Assert mocked statements are executed as expected.
mockStore.AssertExpectations(t)
}
// TestMempoolLookup checks that the method `mempoolLookup` works as expected.
func TestMempoolLookup(t *testing.T) {
t.Parallel()
require := require.New(t)
// Create a test outpoint.
op := wire.OutPoint{Index: 1}
// Create a mock mempool watcher.
mockMempool := chainntnfs.NewMockMempoolWatcher()
// Create a test sweeper without a mempool.
s := New(&UtxoSweeperConfig{})
// Since we don't have a mempool, we expect the call to return an empty
// transaction plus a false value indicating it's not found.
tx, found := s.mempoolLookup(op)
require.Nil(tx)
require.False(found)
// Re-create the sweeper with the mocked mempool watcher.
s = New(&UtxoSweeperConfig{
Mempool: mockMempool,
})
// Create a mempool spend event to be returned by the mempool watcher.
spendChan := make(chan *chainntnfs.SpendDetail, 1)
spendEvent := &chainntnfs.MempoolSpendEvent{
Spend: spendChan,
}
// Mock the cancel subscription calls.
mockMempool.On("CancelMempoolSpendEvent", spendEvent)
// Mock the mempool watcher to return an error.
dummyErr := errors.New("dummy err")
mockMempool.On("SubscribeMempoolSpent", op).Return(nil, dummyErr).Once()
// We expect a nil tx and a false value to be returned.
//
// TODO(yy): this means the behavior of not having a mempool is the
// same as an erroneous mempool. The question is should we
// differentiate the two from their returned values?
tx, found = s.mempoolLookup(op)
require.Nil(tx)
require.False(found)
// Mock the mempool to subscribe to the outpoint.
mockMempool.On("SubscribeMempoolSpent", op).Return(
spendEvent, nil).Once()
// Without sending a spending details to the `spendChan`, we still
// expect a nil tx and a false value to be returned.
tx, found = s.mempoolLookup(op)
require.Nil(tx)
require.False(found)
// Send a dummy spending details to the `spendChan`.
dummyTx := &wire.MsgTx{}
spendChan <- &chainntnfs.SpendDetail{
SpendingTx: dummyTx,
}
// Mock the mempool to subscribe to the outpoint.
mockMempool.On("SubscribeMempoolSpent", op).Return(
spendEvent, nil).Once()
// Calling the loopup again, we expect the dummyTx to be returned.
tx, found = s.mempoolLookup(op)
require.Equal(dummyTx, tx)
require.True(found)
mockMempool.AssertExpectations(t)
}
// TestUpdateSweeperInputs checks that the method `updateSweeperInputs` will
// properly update the inputs based on their states.
func TestUpdateSweeperInputs(t *testing.T) {
t.Parallel()
require := require.New(t)
// Create a test sweeper.
s := New(nil)
// Create a list of inputs using all the states.
input0 := &pendingInput{state: StateInit}
input1 := &pendingInput{state: StatePendingPublish}
input2 := &pendingInput{state: StatePublished}
input3 := &pendingInput{state: StatePublishFailed}
input4 := &pendingInput{state: StateSwept}
input5 := &pendingInput{state: StateExcluded}
input6 := &pendingInput{state: StateFailed}
// Add the inputs to the sweeper. After the update, we should see the
// terminated inputs being removed.
s.pendingInputs = map[wire.OutPoint]*pendingInput{
{Index: 0}: input0,
{Index: 1}: input1,
{Index: 2}: input2,
{Index: 3}: input3,
{Index: 4}: input4,
{Index: 5}: input5,
{Index: 6}: input6,
}
// We expect the inputs with `StateSwept`, `StateExcluded`, and
// `StateFailed` to be removed.
expectedInputs := map[wire.OutPoint]*pendingInput{
{Index: 0}: input0,
{Index: 1}: input1,
{Index: 2}: input2,
{Index: 3}: input3,
}
// We expect only the inputs with `StateInit` and `StatePublishFailed`
// to be returned.
expectedReturn := map[wire.OutPoint]*pendingInput{
{Index: 0}: input0,
{Index: 3}: input3,
}
// Update the sweeper inputs.
inputs := s.updateSweeperInputs()
// Assert the returned inputs are as expected.
require.Equal(expectedReturn, inputs)
// Assert the sweeper inputs are as expected.
require.Equal(expectedInputs, s.pendingInputs)
}
// TestAttachAvailableRBFInfo checks that the RBF info is attached to the
// pending input, along with the state being marked as published, when this
// input can be found both in mempool and the sweeper store.
func TestAttachAvailableRBFInfo(t *testing.T) {
t.Parallel()
require := require.New(t)
// Create a test outpoint.
op := wire.OutPoint{Index: 1}
// Create a mock input.
testInput := &input.MockInput{}
testInput.On("OutPoint").Return(&op)
pi := &pendingInput{
Input: testInput,
state: StateInit,
}
// Create a mock mempool watcher and a mock sweeper store.
mockMempool := chainntnfs.NewMockMempoolWatcher()
mockStore := NewMockSweeperStore()
// Create a mempool spend event to be returned by the mempool watcher.
spendChan := make(chan *chainntnfs.SpendDetail, 1)
spendEvent := &chainntnfs.MempoolSpendEvent{
Spend: spendChan,
}
// Mock the cancel subscription calls.
mockMempool.On("CancelMempoolSpendEvent", spendEvent)
// Create a test sweeper.
s := New(&UtxoSweeperConfig{
Store: mockStore,
Mempool: mockMempool,
})
// First, mock the mempool to return an error.
dummyErr := errors.New("dummy err")
mockMempool.On("SubscribeMempoolSpent", op).Return(nil, dummyErr).Once()
// Since the mempool lookup failed, we exepect the original pending
// input to stay unchanged.
result := s.attachAvailableRBFInfo(pi)
require.True(result.rbf.IsNone())
require.Equal(StateInit, result.state)
// Mock the mempool lookup to return a tx three times.
tx := &wire.MsgTx{}
mockMempool.On("SubscribeMempoolSpent", op).Return(
spendEvent, nil).Times(3).Run(func(_ mock.Arguments) {
// Eeac time the method is called, we send a tx to the spend
// channel.
spendChan <- &chainntnfs.SpendDetail{
SpendingTx: tx,
}
})
// Mock the store to return an error saying the tx cannot be found.
mockStore.On("GetTx", tx.TxHash()).Return(nil, ErrTxNotFound).Once()
// Although the db lookup failed, the pending input should have been
// marked as published without attaching any RBF info.
result = s.attachAvailableRBFInfo(pi)
require.True(result.rbf.IsNone())
require.Equal(StatePublished, result.state)
// Mock the store to return a db error.
mockStore.On("GetTx", tx.TxHash()).Return(nil, dummyErr).Once()
// Although the db lookup failed, the pending input should have been
// marked as published without attaching any RBF info.
result = s.attachAvailableRBFInfo(pi)
require.True(result.rbf.IsNone())
require.Equal(StatePublished, result.state)
// Mock the store to return a record.
tr := &TxRecord{
Fee: 100,
FeeRate: 100,
}
mockStore.On("GetTx", tx.TxHash()).Return(tr, nil).Once()
// Call the method again.
result = s.attachAvailableRBFInfo(pi)
// Assert that the RBF info is attached to the pending input.
rbfInfo := fn.Some(RBFInfo{
Txid: tx.TxHash(),
Fee: btcutil.Amount(tr.Fee),
FeeRate: chainfee.SatPerKWeight(tr.FeeRate),
})
require.Equal(rbfInfo, result.rbf)
// Assert the state is updated.
require.Equal(StatePublished, result.state)
// Assert mocked statements.
testInput.AssertExpectations(t)
mockMempool.AssertExpectations(t)
mockStore.AssertExpectations(t)
}