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mirror of https://github.com/lightninglabs/loop synced 2024-11-19 15:25:33 +00:00
loop/client_test.go
chengehe 0aff202988 chore: make function comments match function names
Signed-off-by: chengehe <hechenge@yeah.net>
2024-06-06 17:39:29 +08:00

440 lines
11 KiB
Go

package loop
import (
"context"
"crypto/sha256"
"errors"
"testing"
"github.com/btcsuite/btcd/btcutil"
"github.com/btcsuite/btcd/chaincfg"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/lightninglabs/lndclient"
"github.com/lightninglabs/loop/loopdb"
"github.com/lightninglabs/loop/swap"
"github.com/lightninglabs/loop/test"
"github.com/lightninglabs/loop/utils"
"github.com/lightningnetwork/lnd/lnrpc"
"github.com/lightningnetwork/lnd/lntypes"
"github.com/stretchr/testify/require"
"google.golang.org/grpc/codes"
"google.golang.org/grpc/status"
)
var (
testAddr, _ = btcutil.NewAddressScriptHash(
[]byte{123}, &chaincfg.TestNet3Params,
)
testRequest = &OutRequest{
Amount: btcutil.Amount(50000),
DestAddr: testAddr,
MaxMinerFee: 50000,
HtlcConfirmations: defaultConfirmations,
SweepConfTarget: 2,
MaxSwapFee: 1050,
MaxPrepayAmount: 100,
MaxPrepayRoutingFee: 75000,
MaxSwapRoutingFee: 70000,
Initiator: "test",
}
swapInvoiceDesc = "swap"
prepayInvoiceDesc = "prepay"
defaultConfirmations = int32(loopdb.DefaultLoopOutHtlcConfirmations)
)
// TestLoopOutSuccess tests the loop out happy flow, using a custom htlc
// confirmation target.
func TestLoopOutSuccess(t *testing.T) {
defer test.Guard(t)()
ctx := createClientTestContext(t, nil)
req := *testRequest
req.HtlcConfirmations = 2
// Initiate loop out.
info, err := ctx.swapClient.LoopOut(context.Background(), &req)
require.NoError(t, err)
ctx.assertStored()
ctx.assertStatus(loopdb.StateInitiated)
signalSwapPaymentResult := ctx.AssertPaid(swapInvoiceDesc)
signalPrepaymentResult := ctx.AssertPaid(prepayInvoiceDesc)
// Expect client to register for conf.
confIntent := ctx.Context.AssertRegisterConf(false, req.HtlcConfirmations)
testLoopOutSuccess(ctx, testRequest.Amount, info.SwapHash,
signalPrepaymentResult, signalSwapPaymentResult, false,
confIntent, swap.HtlcV3,
)
}
// TestLoopOutFailOffchain tests the handling of swap for which the server
// failed the payments.
func TestLoopOutFailOffchain(t *testing.T) {
defer test.Guard(t)()
ctx := createClientTestContext(t, nil)
_, err := ctx.swapClient.LoopOut(context.Background(), testRequest)
require.NoError(t, err)
ctx.assertStored()
ctx.assertStatus(loopdb.StateInitiated)
signalSwapPaymentResult := ctx.AssertPaid(swapInvoiceDesc)
signalPrepaymentResult := ctx.AssertPaid(prepayInvoiceDesc)
ctx.Context.AssertRegisterConf(false, defaultConfirmations)
signalSwapPaymentResult(
errors.New(lndclient.PaymentResultUnknownPaymentHash),
)
signalPrepaymentResult(
errors.New(lndclient.PaymentResultUnknownPaymentHash),
)
<-ctx.serverMock.cancelSwap
ctx.assertStatus(loopdb.StateFailOffchainPayments)
ctx.assertStoreFinished(loopdb.StateFailOffchainPayments)
ctx.finish()
}
// TestLoopOutFailWrongAmount asserts that the client checks the server invoice
// amounts.
func TestLoopOutFailWrongAmount(t *testing.T) {
defer test.Guard(t)()
test := func(t *testing.T, modifier func(*serverMock),
expectedErr error) {
ctx := createClientTestContext(t, nil)
// Modify mock for this subtest.
modifier(ctx.serverMock)
_, err := ctx.swapClient.LoopOut(
context.Background(), testRequest,
)
if err != expectedErr {
t.Fatalf("Expected %v, but got %v", expectedErr, err)
}
ctx.finish()
}
t.Run("swap fee too high", func(t *testing.T) {
test(t, func(m *serverMock) {
m.swapInvoiceAmt += 10
}, ErrSwapFeeTooHigh)
})
t.Run("prepay amount too high", func(t *testing.T) {
test(t, func(m *serverMock) {
// Keep total swap fee unchanged, but increase prepaid
// portion.
m.swapInvoiceAmt -= 10
m.prepayInvoiceAmt += 10
}, ErrPrepayAmountTooHigh)
})
}
// TestLoopOutResume tests that swaps in various states are properly resumed
// after a restart.
func TestLoopOutResume(t *testing.T) {
defaultConfs := loopdb.DefaultLoopOutHtlcConfirmations
storedVersion := []loopdb.ProtocolVersion{
loopdb.ProtocolVersionUnrecorded,
loopdb.ProtocolVersionHtlcV2,
loopdb.ProtocolVersionHtlcV3,
loopdb.ProtocolVersionMuSig2,
}
for _, version := range storedVersion {
version := version
t.Run(version.String(), func(t *testing.T) {
t.Run("not expired", func(t *testing.T) {
testLoopOutResume(
t, defaultConfs, false, false, true,
version,
)
})
t.Run("not expired, custom confirmations",
func(t *testing.T) {
testLoopOutResume(
t, 3, false, false, true,
version,
)
})
t.Run("expired not revealed", func(t *testing.T) {
testLoopOutResume(
t, defaultConfs, true, false, false,
version,
)
})
t.Run("expired revealed", func(t *testing.T) {
testLoopOutResume(
t, defaultConfs, true, true, true,
version,
)
})
})
}
}
func testLoopOutResume(t *testing.T, confs uint32, expired, preimageRevealed,
expectSuccess bool, protocolVersion loopdb.ProtocolVersion) {
defer test.Guard(t)()
preimage := testPreimage
hash := sha256.Sum256(preimage[:])
dest := test.GetDestAddr(t, 0)
amt := btcutil.Amount(50000)
swapPayReq, err := getInvoice(hash, amt, swapInvoiceDesc)
require.NoError(t, err)
prePayReq, err := getInvoice(hash, 100, prepayInvoiceDesc)
require.NoError(t, err)
_, senderPubKey := test.CreateKey(1)
var senderKey [33]byte
copy(senderKey[:], senderPubKey.SerializeCompressed())
_, receiverPubKey := test.CreateKey(2)
var receiverKey [33]byte
copy(receiverKey[:], receiverPubKey.SerializeCompressed())
update := loopdb.LoopEvent{
SwapStateData: loopdb.SwapStateData{
State: loopdb.StateInitiated,
},
}
if preimageRevealed {
update.State = loopdb.StatePreimageRevealed
update.HtlcTxHash = &chainhash.Hash{1, 2, 6}
}
// Create a pending swap with our custom number of confirmations.
pendingSwap := &loopdb.LoopOut{
Contract: &loopdb.LoopOutContract{
DestAddr: dest,
SwapInvoice: swapPayReq,
SweepConfTarget: 2,
HtlcConfirmations: confs,
MaxSwapRoutingFee: 70000,
PrepayInvoice: prePayReq,
SwapContract: loopdb.SwapContract{
Preimage: preimage,
AmountRequested: amt,
CltvExpiry: 744,
HtlcKeys: loopdb.HtlcKeys{
SenderScriptKey: senderKey,
SenderInternalPubKey: senderKey,
ReceiverScriptKey: receiverKey,
ReceiverInternalPubKey: receiverKey,
},
MaxSwapFee: 60000,
MaxMinerFee: 50000,
ProtocolVersion: protocolVersion,
},
},
Loop: loopdb.Loop{
Events: []*loopdb.LoopEvent{&update},
Hash: hash,
},
}
if expired {
// Set cltv expiry so that it has already expired at the test
// block height.
pendingSwap.Contract.CltvExpiry = 610
}
ctx := createClientTestContext(t, []*loopdb.LoopOut{pendingSwap})
if preimageRevealed {
ctx.assertStatus(loopdb.StatePreimageRevealed)
} else {
ctx.assertStatus(loopdb.StateInitiated)
}
signalSwapPaymentResult := ctx.AssertPaid(swapInvoiceDesc)
signalPrepaymentResult := ctx.AssertPaid(prepayInvoiceDesc)
// Expect client to register for our expected number of confirmations.
confIntent := ctx.Context.AssertRegisterConf(
preimageRevealed, int32(confs),
)
htlc, err := utils.GetHtlc(
hash, &pendingSwap.Contract.SwapContract,
&chaincfg.TestNet3Params,
)
require.NoError(t, err)
// Assert that the loopout htlc equals to the expected one.
require.Equal(t, htlc.PkScript, confIntent.PkScript)
signalSwapPaymentResult(nil)
signalPrepaymentResult(nil)
if !expectSuccess {
ctx.assertStatus(loopdb.StateFailTimeout)
ctx.assertStoreFinished(loopdb.StateFailTimeout)
ctx.finish()
return
}
// Because there is no reliable payment yet, an invoice is assumed to be
// paid after resume.
testLoopOutSuccess(ctx, amt, hash,
func(r error) {},
func(r error) {},
preimageRevealed,
confIntent, utils.GetHtlcScriptVersion(protocolVersion),
)
}
func testLoopOutSuccess(ctx *testContext, amt btcutil.Amount, hash lntypes.Hash,
signalPrepaymentResult, signalSwapPaymentResult func(error),
preimageRevealed bool, confIntent *test.ConfRegistration,
scriptVersion swap.ScriptVersion) {
htlcOutpoint := ctx.publishHtlc(confIntent.PkScript, amt)
signalPrepaymentResult(nil)
// Assert that a call to track payment was sent, and respond with status
// in flight so that our swap will push its preimage to the server.
ctx.trackPayment(lnrpc.Payment_IN_FLIGHT)
// We need to notify the height, as the loopout is going to attempt a
// sweep when a new block is received.
err := ctx.Lnd.NotifyHeight(ctx.Lnd.Height + 1)
require.NoError(ctx.Context.T, err)
// Publish tick.
ctx.expiryChan <- testTime
// One spend notifier is registered by batch to watch primary sweep.
ctx.AssertRegisterSpendNtfn(confIntent.PkScript)
ctx.AssertEpochListeners(2)
// Mock the blockheight again as that's when the batch will broadcast
// the tx.
err = ctx.Lnd.NotifyHeight(ctx.Lnd.Height + 1)
require.NoError(ctx.Context.T, err)
// Expect a signing request in the non taproot case.
if scriptVersion != swap.HtlcV3 {
<-ctx.Context.Lnd.SignOutputRawChannel
}
if !preimageRevealed {
ctx.assertStatus(loopdb.StatePreimageRevealed)
ctx.assertStorePreimageReveal()
}
// When using taproot htlcs the flow is different as we do reveal the
// preimage before sweeping in order for the server to trust us with
// our MuSig2 signing attempts.
if scriptVersion == swap.HtlcV3 {
ctx.assertPreimagePush(ctx.store.LoopOutSwaps[hash].Preimage)
<-ctx.Context.Lnd.SignOutputRawChannel
}
// Expect client on-chain sweep of HTLC.
sweepTx := ctx.ReceiveTx()
require.Equal(
ctx.Context.T, htlcOutpoint.Hash[:],
sweepTx.TxIn[0].PreviousOutPoint.Hash[:],
"client not sweeping from htlc tx",
)
var preImageIndex int
switch scriptVersion {
case swap.HtlcV2:
preImageIndex = 0
case swap.HtlcV3:
preImageIndex = 0
}
// Check preimage.
clientPreImage := sweepTx.TxIn[0].Witness[preImageIndex]
clientPreImageHash := sha256.Sum256(clientPreImage)
require.Equal(ctx.Context.T, hash, lntypes.Hash(clientPreImageHash))
// Since we successfully published our sweep, we expect the preimage to
// have been pushed to our mock server.
preimage, err := lntypes.MakePreimage(clientPreImage)
require.NoError(ctx.Context.T, err)
if scriptVersion != swap.HtlcV3 {
ctx.assertPreimagePush(preimage)
}
// Simulate server pulling payment.
signalSwapPaymentResult(nil)
ctx.NotifySpend(sweepTx, 0)
ctx.AssertRegisterConf(true, 3)
ctx.assertStatus(loopdb.StateSuccess)
ctx.assertStoreFinished(loopdb.StateSuccess)
ctx.finish()
}
// TestWrapGrpcError tests grpc error wrapping in the case where a grpc error
// code is present, and when it is absent.
func TestWrapGrpcError(t *testing.T) {
tests := []struct {
name string
original error
expectedCode codes.Code
}{
{
name: "out of range error",
original: status.Error(
codes.OutOfRange, "err string",
),
expectedCode: codes.OutOfRange,
},
{
name: "no grpc code",
original: errors.New("no error code"),
expectedCode: codes.Unknown,
},
}
for _, testCase := range tests {
testCase := testCase
t.Run(testCase.name, func(t *testing.T) {
err := wrapGrpcError("", testCase.original)
require.Error(t, err, "test only expects errors")
status, ok := status.FromError(err)
require.True(t, ok, "test expects grpc code")
require.Equal(t, testCase.expectedCode, status.Code())
})
}
}