// +build rpctest package main import ( "bytes" "fmt" "io" "io/ioutil" "os" "path/filepath" "strings" "testing" "time" "sync/atomic" "encoding/hex" "reflect" "crypto/rand" prand "math/rand" "github.com/btcsuite/btclog" "github.com/davecgh/go-spew/spew" "github.com/go-errors/errors" "github.com/lightningnetwork/lnd/lnrpc" "github.com/lightningnetwork/lnd/lntest" "github.com/lightningnetwork/lnd/lnwire" "github.com/roasbeef/btcd/chaincfg" "github.com/roasbeef/btcd/chaincfg/chainhash" "github.com/roasbeef/btcd/integration/rpctest" "github.com/roasbeef/btcd/rpcclient" "github.com/roasbeef/btcd/wire" "github.com/roasbeef/btcutil" "golang.org/x/net/context" "google.golang.org/grpc" ) var ( harnessNetParams = &chaincfg.SimNetParams ) // harnessTest wraps a regular testing.T providing enhanced error detection // and propagation. All error will be augmented with a full stack-trace in // order to aid in debugging. Additionally, any panics caused by active // test cases will also be handled and represented as fatals. type harnessTest struct { t *testing.T // testCase is populated during test execution and represents the // current test case. testCase *testCase } // newHarnessTest creates a new instance of a harnessTest from a regular // testing.T instance. func newHarnessTest(t *testing.T) *harnessTest { return &harnessTest{t, nil} } // Fatalf causes the current active test case to fail with a fatal error. All // integration tests should mark test failures solely with this method due to // the error stack traces it produces. func (h *harnessTest) Fatalf(format string, a ...interface{}) { stacktrace := errors.Wrap(fmt.Sprintf(format, a...), 1).ErrorStack() if h.testCase != nil { h.t.Fatalf("Failed: (%v): exited with error: \n"+ "%v", h.testCase.name, stacktrace) } else { h.t.Fatalf("Error outside of test: %v", stacktrace) } } // RunTestCase executes a harness test case. Any errors or panics will be // represented as fatal. func (h *harnessTest) RunTestCase(testCase *testCase, net *lntest.NetworkHarness) { h.testCase = testCase defer func() { h.testCase = nil }() defer func() { if err := recover(); err != nil { description := errors.Wrap(err, 2).ErrorStack() h.t.Fatalf("Failed: (%v) panicked with: \n%v", h.testCase.name, description) } }() testCase.test(net, h) return } func (h *harnessTest) Logf(format string, args ...interface{}) { h.t.Logf(format, args...) } func (h *harnessTest) Log(args ...interface{}) { h.t.Log(args...) } func assertTxInBlock(t *harnessTest, block *wire.MsgBlock, txid *chainhash.Hash) { for _, tx := range block.Transactions { sha := tx.TxHash() if bytes.Equal(txid[:], sha[:]) { return } } t.Fatalf("funding tx was not included in block") } // mineBlocks mine 'num' of blocks and check that blocks are present in // node blockchain. func mineBlocks(t *harnessTest, net *lntest.NetworkHarness, num uint32) []*wire.MsgBlock { blocks := make([]*wire.MsgBlock, num) blockHashes, err := net.Miner.Node.Generate(num) if err != nil { t.Fatalf("unable to generate blocks: %v", err) } for i, blockHash := range blockHashes { block, err := net.Miner.Node.GetBlock(blockHash) if err != nil { t.Fatalf("unable to get block: %v", err) } blocks[i] = block } return blocks } // openChannelAndAssert attempts to open a channel with the specified // parameters extended from Alice to Bob. Additionally, two items are asserted // after the channel is considered open: the funding transaction should be // found within a block, and that Alice can report the status of the new // channel. func openChannelAndAssert(ctx context.Context, t *harnessTest, net *lntest.NetworkHarness, alice, bob *lntest.HarnessNode, fundingAmt btcutil.Amount, pushAmt btcutil.Amount) *lnrpc.ChannelPoint { chanOpenUpdate, err := net.OpenChannel(ctx, alice, bob, fundingAmt, pushAmt, false) if err != nil { t.Fatalf("unable to open channel: %v", err) } // Mine 6 blocks, then wait for Alice's node to notify us that the // channel has been opened. The funding transaction should be found // within the first newly mined block. We mine 6 blocks to make sure // the channel is public, as it will not be announced to the network // before the funding transaction is 6 blocks deep. block := mineBlocks(t, net, 6)[0] fundingChanPoint, err := net.WaitForChannelOpen(ctx, chanOpenUpdate) if err != nil { t.Fatalf("error while waiting for channel open: %v", err) } txidHash, err := getChanPointFundingTxid(fundingChanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } fundingTxID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } assertTxInBlock(t, block, fundingTxID) // The channel should be listed in the peer information returned by // both peers. chanPoint := wire.OutPoint{ Hash: *fundingTxID, Index: fundingChanPoint.OutputIndex, } if err := net.AssertChannelExists(ctx, alice, &chanPoint); err != nil { t.Fatalf("unable to assert channel existence: %v", err) } if err := net.AssertChannelExists(ctx, bob, &chanPoint); err != nil { t.Fatalf("unable to assert channel existence: %v", err) } return fundingChanPoint } // closeChannelAndAssert attempts to close a channel identified by the passed // channel point owned by the passed Lightning node. A fully blocking channel // closure is attempted, therefore the passed context should be a child derived // via timeout from a base parent. Additionally, once the channel has been // detected as closed, an assertion checks that the transaction is found within // a block. func closeChannelAndAssert(ctx context.Context, t *harnessTest, net *lntest.NetworkHarness, node *lntest.HarnessNode, fundingChanPoint *lnrpc.ChannelPoint, force bool) *chainhash.Hash { closeUpdates, _, err := net.CloseChannel(ctx, node, fundingChanPoint, force) if err != nil { t.Fatalf("unable to close channel: %v", err) } txidHash, err := getChanPointFundingTxid(fundingChanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } txid, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to convert to chainhash: %v", err) } chanPointStr := fmt.Sprintf("%v:%v", txid, fundingChanPoint.OutputIndex) // If we didn't force close the transaction, at this point, the channel // should now be marked as being in the state of "pending close". if !force { pendingChansRequest := &lnrpc.PendingChannelsRequest{} pendingChanResp, err := node.PendingChannels(ctx, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } var found bool for _, pendingClose := range pendingChanResp.PendingClosingChannels { if pendingClose.Channel.ChannelPoint == chanPointStr { found = true break } } if !found { t.Fatalf("channel not marked as pending close") } } // Finally, generate a single block, wait for the final close status // update, then ensure that the closing transaction was included in the // block. block := mineBlocks(t, net, 1)[0] closingTxid, err := net.WaitForChannelClose(ctx, closeUpdates) if err != nil { t.Fatalf("error while waiting for channel close: %v", err) } assertTxInBlock(t, block, closingTxid) return closingTxid } // numOpenChannelsPending sends an RPC request to a node to get a count of the // node's channels that are currently in a pending state (with a broadcast, but // not confirmed funding transaction). func numOpenChannelsPending(ctxt context.Context, node *lntest.HarnessNode) (int, error) { pendingChansRequest := &lnrpc.PendingChannelsRequest{} resp, err := node.PendingChannels(ctxt, pendingChansRequest) if err != nil { return 0, err } return len(resp.PendingOpenChannels), nil } // assertNumOpenChannelsPending asserts that a pair of nodes have the expected // number of pending channels between them. func assertNumOpenChannelsPending(ctxt context.Context, t *harnessTest, alice, bob *lntest.HarnessNode, expected int) { const nPolls = 10 ticker := time.NewTicker(200 * time.Millisecond) defer ticker.Stop() for i := 0; i < nPolls; i++ { aliceNumChans, err := numOpenChannelsPending(ctxt, alice) if err != nil { t.Fatalf("error fetching alice's node (%v) pending channels %v", alice.NodeID, err) } bobNumChans, err := numOpenChannelsPending(ctxt, bob) if err != nil { t.Fatalf("error fetching bob's node (%v) pending channels %v", bob.NodeID, err) } isLastIteration := i == nPolls-1 aliceStateCorrect := aliceNumChans == expected if !aliceStateCorrect && isLastIteration { t.Fatalf("number of pending channels for alice incorrect. "+ "expected %v, got %v", expected, aliceNumChans) } bobStateCorrect := bobNumChans == expected if !bobStateCorrect && isLastIteration { t.Fatalf("number of pending channels for bob incorrect. "+ "expected %v, got %v", expected, bobNumChans) } if aliceStateCorrect && bobStateCorrect { return } <-ticker.C } } // assertNumConnections asserts number current connections between two peers. func assertNumConnections(ctxt context.Context, t *harnessTest, alice, bob *lntest.HarnessNode, expected int) { const nPolls = 10 tick := time.NewTicker(300 * time.Millisecond) defer tick.Stop() for i := nPolls - 1; i >= 0; i-- { select { case <-tick.C: aNumPeers, err := alice.ListPeers(ctxt, &lnrpc.ListPeersRequest{}) if err != nil { t.Fatalf("unable to fetch alice's node (%v) list peers %v", alice.NodeID, err) } bNumPeers, err := bob.ListPeers(ctxt, &lnrpc.ListPeersRequest{}) if err != nil { t.Fatalf("unable to fetch bob's node (%v) list peers %v", bob.NodeID, err) } if len(aNumPeers.Peers) != expected { // Continue polling if this is not the final // loop. if i > 0 { continue } t.Fatalf("number of peers connected to alice is incorrect: "+ "expected %v, got %v", expected, len(aNumPeers.Peers)) } if len(bNumPeers.Peers) != expected { // Continue polling if this is not the final // loop. if i > 0 { continue } t.Fatalf("number of peers connected to bob is incorrect: "+ "expected %v, got %v", expected, len(bNumPeers.Peers)) } // Alice and Bob both have the required number of // peers, stop polling and return to caller. return } } } // calcStaticFee calculates appropriate fees for commitment transactions. This // function provides a simple way to allow test balance assertions to take fee // calculations into account. // // TODO(bvu): Refactor when dynamic fee estimation is added. // TODO(conner) remove code duplication func calcStaticFee(numHTLCs int) btcutil.Amount { const ( commitWeight = btcutil.Amount(724) htlcWeight = 172 feePerKw = btcutil.Amount(50 * 1000 / 4) ) return feePerKw * (commitWeight + btcutil.Amount(htlcWeight*numHTLCs)) / 1000 } // completePaymentRequests sends payments from a lightning node to complete all // payment requests. If the awaitResponse parameter is true, this function // does not return until all payments successfully complete without errors. func completePaymentRequests(ctx context.Context, client lnrpc.LightningClient, paymentRequests []string, awaitResponse bool) error { ctx, cancel := context.WithCancel(ctx) defer cancel() payStream, err := client.SendPayment(ctx) if err != nil { return err } for _, payReq := range paymentRequests { sendReq := &lnrpc.SendRequest{PaymentRequest: payReq} err := payStream.Send(sendReq) if err != nil { return err } } if awaitResponse { for range paymentRequests { resp, err := payStream.Recv() if err != nil { return err } if resp.PaymentError != "" { return fmt.Errorf("received payment error: %v", resp.PaymentError) } } } else { // We are not waiting for feedback in the form of a response, but we // should still wait long enough for the server to receive and handle // the send before cancelling the request. time.Sleep(200 * time.Millisecond) } return nil } // testBasicChannelFunding performs a test exercising expected behavior from a // basic funding workflow. The test creates a new channel between Alice and // Bob, then immediately closes the channel after asserting some expected post // conditions. Finally, the chain itself is checked to ensure the closing // transaction was mined. func testBasicChannelFunding(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 5) ctxb := context.Background() chanAmt := maxFundingAmount pushAmt := btcutil.Amount(100000) // First establish a channel with a capacity of 0.5 BTC between Alice // and Bob with Alice pushing 100k satoshis to Bob's side during // funding. This function will block until the channel itself is fully // open or an error occurs in the funding process. A series of // assertions will be executed to ensure the funding process completed // successfully. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, pushAmt) ctxt, _ = context.WithTimeout(ctxb, time.Second*15) err := net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't report channel: %v", err) } err = net.Bob.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("bob didn't report channel: %v", err) } // With then channel open, ensure that the amount specified above has // properly been pushed to Bob. balReq := &lnrpc.ChannelBalanceRequest{} aliceBal, err := net.Alice.ChannelBalance(ctxb, balReq) if err != nil { t.Fatalf("unable to get alice's balance: %v", err) } bobBal, err := net.Bob.ChannelBalance(ctxb, balReq) if err != nil { t.Fatalf("unable to get bobs's balance: %v", err) } if aliceBal.Balance != int64(chanAmt-pushAmt-calcStaticFee(0)) { t.Fatalf("alice's balance is incorrect: expected %v got %v", chanAmt-pushAmt-calcStaticFee(0), aliceBal) } if bobBal.Balance != int64(pushAmt) { t.Fatalf("bob's balance is incorrect: expected %v got %v", pushAmt, bobBal.Balance) } // Finally, immediately close the channel. This function will also // block until the channel is closed and will additionally assert the // relevant channel closing post conditions. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) } // testUpdateChannelPolicy tests that policy updates made to a channel // gets propagated to other nodes in the network. func testUpdateChannelPolicy(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 5) ctxb := context.Background() // Launch notification clients for all nodes, such that we can // get notified when they discover new channels and updates // in the graph. aliceUpdates, aQuit := subscribeGraphNotifications(t, ctxb, net.Alice) defer close(aQuit) bobUpdates, bQuit := subscribeGraphNotifications(t, ctxb, net.Bob) defer close(bQuit) chanAmt := maxFundingAmount pushAmt := btcutil.Amount(100000) // Create a channel Alice->Bob. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, pushAmt) ctxt, _ = context.WithTimeout(ctxb, time.Second*15) err := net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't report channel: %v", err) } err = net.Bob.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("bob didn't report channel: %v", err) } // Create Carol and a new channel Bob->Carol. carol, err := net.NewNode(nil) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } carolUpdates, cQuit := subscribeGraphNotifications(t, ctxb, carol) defer close(cQuit) if err := net.ConnectNodes(ctxb, carol, net.Bob); err != nil { t.Fatalf("unable to connect dave to alice: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPoint2 := openChannelAndAssert(ctxt, t, net, net.Bob, carol, chanAmt, pushAmt) ctxt, _ = context.WithTimeout(ctxb, time.Second*15) err = net.Bob.WaitForNetworkChannelOpen(ctxt, chanPoint2) if err != nil { t.Fatalf("bob didn't report channel: %v", err) } err = carol.WaitForNetworkChannelOpen(ctxt, chanPoint2) if err != nil { t.Fatalf("carol didn't report channel: %v", err) } // Update the fees for the channel Alice->Bob, and make sure // all nodes learn about it. const feeBase = 1000000 baseFee := int64(1500) feeRate := int64(12) timeLockDelta := uint32(66) req := &lnrpc.PolicyUpdateRequest{ BaseFeeMsat: baseFee, FeeRate: float64(feeRate), TimeLockDelta: timeLockDelta, } req.Scope = &lnrpc.PolicyUpdateRequest_ChanPoint{ ChanPoint: chanPoint, } _, err = net.Alice.UpdateChannelPolicy(ctxb, req) if err != nil { t.Fatalf("unable to get alice's balance: %v", err) } // txStr returns the string representation of the channel's // funding tx. txStr := func(chanPoint *lnrpc.ChannelPoint) string { txidHash, err := getChanPointFundingTxid(chanPoint) if err != nil { return "" } fundingTxID, err := chainhash.NewHash(txidHash) if err != nil { return "" } cp := wire.OutPoint{ Hash: *fundingTxID, Index: chanPoint.OutputIndex, } return cp.String() } // A closure that is used to wait for a channel updates that matches // the channel policy update done by Alice. waitForChannelUpdate := func(graphUpdates chan *lnrpc.GraphTopologyUpdate, chanPoints ...*lnrpc.ChannelPoint) { // Create a map containing all the channel points we are // waiting for updates for. cps := make(map[string]bool) for _, chanPoint := range chanPoints { cps[txStr(chanPoint)] = true } Loop: for { select { case graphUpdate := <-graphUpdates: if len(graphUpdate.ChannelUpdates) == 0 { continue } chanUpdate := graphUpdate.ChannelUpdates[0] fundingTxStr := txStr(chanUpdate.ChanPoint) if _, ok := cps[fundingTxStr]; !ok { continue } if chanUpdate.AdvertisingNode != net.Alice.PubKeyStr { continue } policy := chanUpdate.RoutingPolicy if policy.FeeBaseMsat != baseFee { continue } if policy.FeeRateMilliMsat != feeRate*feeBase { continue } if policy.TimeLockDelta != timeLockDelta { continue } // We got a policy update that matched the // values and channel point of what we // expected, delete it from the map. delete(cps, fundingTxStr) // If we have no more channel points we are // waiting for, break out of the loop. if len(cps) == 0 { break Loop } case <-time.After(20 * time.Second): t.Fatalf("did not receive channel update") } } } // Wait for all nodes to have seen the policy update done by Alice. waitForChannelUpdate(aliceUpdates, chanPoint) waitForChannelUpdate(bobUpdates, chanPoint) waitForChannelUpdate(carolUpdates, chanPoint) // assertChannelPolicy asserts that the passed node's known channel // policy for the passed chanPoint is consistent with Alice's current // expected policy values. assertChannelPolicy := func(node *lntest.HarnessNode, chanPoint *lnrpc.ChannelPoint) { // Get a DescribeGraph from the node. descReq := &lnrpc.ChannelGraphRequest{} chanGraph, err := node.DescribeGraph(ctxb, descReq) if err != nil { t.Fatalf("unable to query for alice's routing table: %v", err) } edgeFound := false for _, e := range chanGraph.Edges { if e.ChanPoint == txStr(chanPoint) { edgeFound = true if e.Node1Pub == net.Alice.PubKeyStr { if e.Node1Policy.FeeBaseMsat != baseFee { t.Fatalf("expected base fee "+ "%v, got %v", baseFee, e.Node1Policy.FeeBaseMsat) } if e.Node1Policy.FeeRateMilliMsat != feeRate*feeBase { t.Fatalf("expected fee rate "+ "%v, got %v", feeRate*feeBase, e.Node1Policy.FeeRateMilliMsat) } if e.Node1Policy.TimeLockDelta != timeLockDelta { t.Fatalf("expected time lock "+ "delta %v, got %v", timeLockDelta, e.Node1Policy.TimeLockDelta) } } else { if e.Node2Policy.FeeBaseMsat != baseFee { t.Fatalf("expected base fee "+ "%v, got %v", baseFee, e.Node2Policy.FeeBaseMsat) } if e.Node2Policy.FeeRateMilliMsat != feeRate*feeBase { t.Fatalf("expected fee rate "+ "%v, got %v", feeRate*feeBase, e.Node2Policy.FeeRateMilliMsat) } if e.Node2Policy.TimeLockDelta != timeLockDelta { t.Fatalf("expected time lock "+ "delta %v, got %v", timeLockDelta, e.Node2Policy.TimeLockDelta) } } } } if !edgeFound { t.Fatalf("did not find edge") } } // Check that all nodes now know about Alice's updated policy. assertChannelPolicy(net.Alice, chanPoint) assertChannelPolicy(net.Bob, chanPoint) assertChannelPolicy(carol, chanPoint) // Open channel to Carol. if err := net.ConnectNodes(ctxb, net.Alice, carol); err != nil { t.Fatalf("unable to connect dave to alice: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPoint3 := openChannelAndAssert(ctxt, t, net, net.Alice, carol, chanAmt, pushAmt) ctxt, _ = context.WithTimeout(ctxb, time.Second*15) err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint3) if err != nil { t.Fatalf("alice didn't report channel: %v", err) } err = carol.WaitForNetworkChannelOpen(ctxt, chanPoint3) if err != nil { t.Fatalf("bob didn't report channel: %v", err) } // Make a global update, and check that both channels' // new policies get propagated. baseFee = int64(800) feeRate = int64(123) timeLockDelta = uint32(22) req = &lnrpc.PolicyUpdateRequest{ BaseFeeMsat: baseFee, FeeRate: float64(feeRate), TimeLockDelta: timeLockDelta, } req.Scope = &lnrpc.PolicyUpdateRequest_Global{} _, err = net.Alice.UpdateChannelPolicy(ctxb, req) if err != nil { t.Fatalf("unable to get alice's balance: %v", err) } // Wait for all nodes to have seen the policy updates // for both of Alice's channels. waitForChannelUpdate(aliceUpdates, chanPoint, chanPoint3) waitForChannelUpdate(bobUpdates, chanPoint, chanPoint3) waitForChannelUpdate(carolUpdates, chanPoint, chanPoint3) // And finally check that all nodes remembers the policy // update they received. assertChannelPolicy(net.Alice, chanPoint) assertChannelPolicy(net.Bob, chanPoint) assertChannelPolicy(carol, chanPoint) assertChannelPolicy(net.Alice, chanPoint3) assertChannelPolicy(net.Bob, chanPoint3) assertChannelPolicy(carol, chanPoint3) // Close the channels. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Bob, chanPoint2, false) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint3, false) ctxt, _ = context.WithTimeout(ctxb, timeout) // Clean up carol's node. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } // testOpenChannelAfterReorg tests that in the case where we have an open // channel where the funding tx gets reorged out, the channel will no // longer be present in the node's routing table. func testOpenChannelAfterReorg(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 5) ctxb := context.Background() // Set up a new miner that we can use to cause a reorg. args := []string{"--rejectnonstd"} miner, err := rpctest.New(harnessNetParams, &rpcclient.NotificationHandlers{}, args) if err != nil { t.Fatalf("unable to create mining node: %v", err) } if err := miner.SetUp(true, 50); err != nil { t.Fatalf("unable to set up mining node: %v", err) } defer miner.TearDown() if err := miner.Node.NotifyNewTransactions(false); err != nil { t.Fatalf("unable to request transaction notifications: %v", err) } // We start by connecting the new miner to our original miner, // such that it will sync to our original chain. if err := rpctest.ConnectNode(net.Miner, miner); err != nil { t.Fatalf("unable to connect harnesses: %v", err) } nodeSlice := []*rpctest.Harness{net.Miner, miner} if err := rpctest.JoinNodes(nodeSlice, rpctest.Blocks); err != nil { t.Fatalf("unable to join node on blocks: %v", err) } // The two should be on the same blockheight. _, newNodeHeight, err := miner.Node.GetBestBlock() if err != nil { t.Fatalf("unable to get current blockheight %v", err) } _, orgNodeHeight, err := net.Miner.Node.GetBestBlock() if err != nil { t.Fatalf("unable to get current blockheight %v", err) } if newNodeHeight != orgNodeHeight { t.Fatalf("expected new miner(%d) and original miner(%d) to "+ "be on the same height", newNodeHeight, orgNodeHeight) } // We disconnect the two nodes, such that we can start mining on them // individually without the other one learning about the new blocks. err = net.Miner.Node.AddNode(miner.P2PAddress(), rpcclient.ANRemove) if err != nil { t.Fatalf("unable to remove node: %v", err) } // Create a new channel that requires 1 confs before it's considered // open, then broadcast the funding transaction chanAmt := maxFundingAmount pushAmt := btcutil.Amount(0) ctxt, _ := context.WithTimeout(ctxb, timeout) pendingUpdate, err := net.OpenPendingChannel(ctxt, net.Alice, net.Bob, chanAmt, pushAmt) if err != nil { t.Fatalf("unable to open channel: %v", err) } // At this point, the channel's funding transaction will have been // broadcast, but not confirmed, and the channel should be pending. ctxt, _ = context.WithTimeout(ctxb, timeout) assertNumOpenChannelsPending(ctxt, t, net.Alice, net.Bob, 1) fundingTxID, err := chainhash.NewHash(pendingUpdate.Txid) if err != nil { t.Fatalf("unable to convert funding txid into chainhash.Hash:"+ " %v", err) } // We now cause a fork, by letting our original miner mine 10 blocks, // and our new miner mine 15. This will also confirm our pending // channel, which should be considered open. block := mineBlocks(t, net, 10)[0] assertTxInBlock(t, block, fundingTxID) miner.Node.Generate(15) // Ensure the chain lengths are what we expect. _, newNodeHeight, err = miner.Node.GetBestBlock() if err != nil { t.Fatalf("unable to get current blockheight %v", err) } _, orgNodeHeight, err = net.Miner.Node.GetBestBlock() if err != nil { t.Fatalf("unable to get current blockheight %v", err) } if newNodeHeight != orgNodeHeight+5 { t.Fatalf("expected new miner(%d) to be 5 blocks ahead of "+ "original miner(%d)", newNodeHeight, orgNodeHeight) } chanPoint := &lnrpc.ChannelPoint{ FundingTxid: &lnrpc.ChannelPoint_FundingTxidBytes{ FundingTxidBytes: pendingUpdate.Txid, }, OutputIndex: pendingUpdate.OutputIndex, } // Ensure channel is no longer pending. assertNumOpenChannelsPending(ctxt, t, net.Alice, net.Bob, 0) // Wait for Alice and Bob to recognize and advertise the new channel // generated above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't advertise channel before "+ "timeout: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) err = net.Bob.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("bob didn't advertise channel before "+ "timeout: %v", err) } // Alice should now have 1 edge in her graph. req := &lnrpc.ChannelGraphRequest{} chanGraph, err := net.Alice.DescribeGraph(ctxb, req) if err != nil { t.Fatalf("unable to query for alice's routing table: %v", err) } numEdges := len(chanGraph.Edges) if numEdges != 1 { t.Fatalf("expected to find one edge in the graph, found %d", numEdges) } // Connecting the two miners should now cause our original one to sync // to the new, and longer chain. if err := rpctest.ConnectNode(net.Miner, miner); err != nil { t.Fatalf("unable to connect harnesses: %v", err) } if err := rpctest.JoinNodes(nodeSlice, rpctest.Blocks); err != nil { t.Fatalf("unable to join node on blocks: %v", err) } // Once again they should be on the same chain. _, newNodeHeight, err = miner.Node.GetBestBlock() if err != nil { t.Fatalf("unable to get current blockheight %v", err) } _, orgNodeHeight, err = net.Miner.Node.GetBestBlock() if err != nil { t.Fatalf("unable to get current blockheight %v", err) } if newNodeHeight != orgNodeHeight { t.Fatalf("expected new miner(%d) and original miner(%d) to "+ "be on the same height", newNodeHeight, orgNodeHeight) } time.Sleep(time.Second * 2) // Since the fundingtx was reorged out, Alice should now have no edges // in her graph. req = &lnrpc.ChannelGraphRequest{} chanGraph, err = net.Alice.DescribeGraph(ctxb, req) if err != nil { t.Fatalf("unable to query for alice's routing table: %v", err) } numEdges = len(chanGraph.Edges) if numEdges != 0 { t.Fatalf("expected to find no edge in the graph, found %d", numEdges) } ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) } // testDisconnectingTargetPeer performs a test which // disconnects Alice-peer from Bob-peer and then re-connects them again func testDisconnectingTargetPeer(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() // Check existing connection. assertNumConnections(ctxb, t, net.Alice, net.Bob, 1) chanAmt := maxFundingAmount pushAmt := btcutil.Amount(0) timeout := time.Duration(time.Second * 10) ctxt, _ := context.WithTimeout(ctxb, timeout) // Create a new channel that requires 1 confs before it's considered // open, then broadcast the funding transaction const numConfs = 1 pendingUpdate, err := net.OpenPendingChannel(ctxt, net.Alice, net.Bob, chanAmt, pushAmt) if err != nil { t.Fatalf("unable to open channel: %v", err) } // At this point, the channel's funding transaction will have // been broadcast, but not confirmed. Alice and Bob's nodes // should reflect this when queried via RPC. ctxt, _ = context.WithTimeout(ctxb, timeout) assertNumOpenChannelsPending(ctxt, t, net.Alice, net.Bob, 1) // Disconnect Alice-peer from Bob-peer and get error // causes by one pending channel with detach node is existing. if err := net.DisconnectNodes(ctxt, net.Alice, net.Bob); err == nil { t.Fatalf("Bob's peer was disconnected from Alice's"+ " while one pending channel is existing: err %v", err) } time.Sleep(time.Millisecond * 300) // Check existing connection. assertNumConnections(ctxb, t, net.Alice, net.Bob, 1) fundingTxID, err := chainhash.NewHash(pendingUpdate.Txid) if err != nil { t.Fatalf("unable to convert funding txid into chainhash.Hash:"+ " %v", err) } // Mine a block, then wait for Alice's node to notify us that the // channel has been opened. The funding transaction should be found // within the newly mined block. block := mineBlocks(t, net, numConfs)[0] assertTxInBlock(t, block, fundingTxID) // At this point, the channel should be fully opened and there should // be no pending channels remaining for either node. time.Sleep(time.Millisecond * 300) ctxt, _ = context.WithTimeout(ctxb, timeout) assertNumOpenChannelsPending(ctxt, t, net.Alice, net.Bob, 0) // The channel should be listed in the peer information returned by // both peers. outPoint := wire.OutPoint{ Hash: *fundingTxID, Index: pendingUpdate.OutputIndex, } // Check both nodes to ensure that the channel is ready for operation. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.AssertChannelExists(ctxt, net.Alice, &outPoint); err != nil { t.Fatalf("unable to assert channel existence: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.AssertChannelExists(ctxt, net.Bob, &outPoint); err != nil { t.Fatalf("unable to assert channel existence: %v", err) } // Finally, immediately close the channel. This function will also // block until the channel is closed and will additionally assert the // relevant channel closing post conditions. chanPoint := &lnrpc.ChannelPoint{ FundingTxid: &lnrpc.ChannelPoint_FundingTxidBytes{ FundingTxidBytes: pendingUpdate.Txid, }, OutputIndex: pendingUpdate.OutputIndex, } // Disconnect Alice-peer from Bob-peer and get error // causes by one active channel with detach node is existing. if err := net.DisconnectNodes(ctxt, net.Alice, net.Bob); err == nil { t.Fatalf("Bob's peer was disconnected from Alice's"+ " while one active channel is existing: err %v", err) } // Check existing connection. assertNumConnections(ctxb, t, net.Alice, net.Bob, 1) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, true) // Disconnect Alice-peer from Bob-peer without getting error // about existing channels. if err := net.DisconnectNodes(ctxt, net.Alice, net.Bob); err != nil { t.Fatalf("unable to disconnect Bob's peer from Alice's: err %v", err) } // Check zero peer connections. assertNumConnections(ctxb, t, net.Alice, net.Bob, 0) // Finally, re-connect both nodes. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.ConnectNodes(ctxt, net.Alice, net.Bob); err != nil { t.Fatalf("unable to connect Alice's peer to Bob's: err %v", err) } // Check existing connection. assertNumConnections(ctxb, t, net.Alice, net.Bob, 1) // Mine enough blocks to clear the force closed outputs from the UTXO // nursery. if _, err := net.Miner.Node.Generate(4); err != nil { t.Fatalf("unable to mine blocks: %v", err) } time.Sleep(300 * time.Millisecond) } // testFundingPersistence is intended to ensure that the Funding Manager // persists the state of new channels prior to broadcasting the channel's // funding transaction. This ensures that the daemon maintains an up-to-date // representation of channels if the system is restarted or disconnected. // testFundingPersistence mirrors testBasicChannelFunding, but adds restarts // and checks for the state of channels with unconfirmed funding transactions. func testChannelFundingPersistence(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() chanAmt := maxFundingAmount pushAmt := btcutil.Amount(0) timeout := time.Duration(time.Second * 10) // As we need to create a channel that requires more than 1 // confirmation before it's open, with the current set of defaults, // we'll need to create a new node instance. const numConfs = 5 carolArgs := []string{fmt.Sprintf("--bitcoin.defaultchanconfs=%v", numConfs)} carol, err := net.NewNode(carolArgs) if err != nil { t.Fatalf("unable to create new node: %v", err) } ctxt, _ := context.WithTimeout(ctxb, timeout) if err := net.ConnectNodes(ctxt, net.Alice, carol); err != nil { t.Fatalf("unable to connect alice to carol: %v", err) } // Create a new channel that requires 5 confs before it's considered // open, then broadcast the funding transaction ctxt, _ = context.WithTimeout(ctxb, timeout) pendingUpdate, err := net.OpenPendingChannel(ctxt, net.Alice, carol, chanAmt, pushAmt) if err != nil { t.Fatalf("unable to open channel: %v", err) } // At this point, the channel's funding transaction will have been // broadcast, but not confirmed. Alice and Bob's nodes should reflect // this when queried via RPC. ctxt, _ = context.WithTimeout(ctxb, timeout) assertNumOpenChannelsPending(ctxt, t, net.Alice, carol, 1) // Restart both nodes to test that the appropriate state has been // persisted and that both nodes recover gracefully. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } if err := net.RestartNode(carol, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } fundingTxID, err := chainhash.NewHash(pendingUpdate.Txid) if err != nil { t.Fatalf("unable to convert funding txid into chainhash.Hash:"+ " %v", err) } // Mine a block, then wait for Alice's node to notify us that the // channel has been opened. The funding transaction should be found // within the newly mined block. block := mineBlocks(t, net, 1)[0] assertTxInBlock(t, block, fundingTxID) // Restart both nodes to test that the appropriate state has been // persisted and that both nodes recover gracefully. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } if err := net.RestartNode(carol, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } // The following block ensures that after both nodes have restarted, // they have reconnected before the execution of the next test. peersTimeout := time.After(15 * time.Second) checkPeersTick := time.NewTicker(100 * time.Millisecond) defer checkPeersTick.Stop() peersPoll: for { select { case <-peersTimeout: t.Fatalf("peers unable to reconnect after restart") case <-checkPeersTick.C: peers, err := carol.ListPeers(ctxb, &lnrpc.ListPeersRequest{}) if err != nil { t.Fatalf("ListPeers error: %v\n", err) } if len(peers.Peers) > 0 { break peersPoll } } } // Next, mine enough blocks s.t the channel will open with a single // additional block mined. if _, err := net.Miner.Node.Generate(3); err != nil { t.Fatalf("unable to mine blocks: %v", err) } // Both nodes should still show a single channel as pending. time.Sleep(time.Second * 1) ctxt, _ = context.WithTimeout(ctxb, timeout) assertNumOpenChannelsPending(ctxt, t, net.Alice, carol, 1) // Finally, mine the last block which should mark the channel as open. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to mine blocks: %v", err) } // At this point, the channel should be fully opened and there should // be no pending channels remaining for either node. time.Sleep(time.Second * 1) ctxt, _ = context.WithTimeout(ctxb, timeout) assertNumOpenChannelsPending(ctxt, t, net.Alice, carol, 0) // The channel should be listed in the peer information returned by // both peers. outPoint := wire.OutPoint{ Hash: *fundingTxID, Index: pendingUpdate.OutputIndex, } // Check both nodes to ensure that the channel is ready for operation. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.AssertChannelExists(ctxt, net.Alice, &outPoint); err != nil { t.Fatalf("unable to assert channel existence: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.AssertChannelExists(ctxt, carol, &outPoint); err != nil { t.Fatalf("unable to assert channel existence: %v", err) } // Finally, immediately close the channel. This function will also // block until the channel is closed and will additionally assert the // relevant channel closing post conditions. chanPoint := &lnrpc.ChannelPoint{ FundingTxid: &lnrpc.ChannelPoint_FundingTxidBytes{ FundingTxidBytes: pendingUpdate.Txid, }, OutputIndex: pendingUpdate.OutputIndex, } ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) // Clean up carol's node. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } // testChannelBalance creates a new channel between Alice and Bob, then // checks channel balance to be equal amount specified while creation of channel. func testChannelBalance(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 5) // Open a channel with 0.16 BTC between Alice and Bob, ensuring the // channel has been opened properly. amount := maxFundingAmount ctx, _ := context.WithTimeout(context.Background(), timeout) // Creates a helper closure to be used below which asserts the proper // response to a channel balance RPC. checkChannelBalance := func(node lnrpc.LightningClient, amount btcutil.Amount) { response, err := node.ChannelBalance(ctx, &lnrpc.ChannelBalanceRequest{}) if err != nil { t.Fatalf("unable to get channel balance: %v", err) } balance := btcutil.Amount(response.Balance) if balance != amount { t.Fatalf("channel balance wrong: %v != %v", balance, amount) } } chanPoint := openChannelAndAssert(ctx, t, net, net.Alice, net.Bob, amount, 0) // Wait for both Alice and Bob to recognize this new channel. ctxt, _ := context.WithTimeout(context.Background(), timeout) err := net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't advertise channel before "+ "timeout: %v", err) } ctxt, _ = context.WithTimeout(context.Background(), timeout) err = net.Bob.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("bob didn't advertise channel before "+ "timeout: %v", err) } // As this is a single funder channel, Alice's balance should be // exactly 0.5 BTC since now state transitions have taken place yet. checkChannelBalance(net.Alice, amount-calcStaticFee(0)) // Ensure Bob currently has no available balance within the channel. checkChannelBalance(net.Bob, 0) // Finally close the channel between Alice and Bob, asserting that the // channel has been properly closed on-chain. ctx, _ = context.WithTimeout(context.Background(), timeout) closeChannelAndAssert(ctx, t, net, net.Alice, chanPoint, false) } // findForceClosedChannel searches a pending channel response for a particular // channel, returning the force closed channel upon success. func findForceClosedChannel(t *harnessTest, pendingChanResp *lnrpc.PendingChannelsResponse, op *wire.OutPoint) *lnrpc.PendingChannelsResponse_ForceClosedChannel { var found bool var forceClose *lnrpc.PendingChannelsResponse_ForceClosedChannel for _, forceClose = range pendingChanResp.PendingForceClosingChannels { if forceClose.Channel.ChannelPoint == op.String() { found = true break } } if !found { t.Fatalf("channel not marked as force closed") } return forceClose } func assertCommitmentMaturity(t *harnessTest, forceClose *lnrpc.PendingChannelsResponse_ForceClosedChannel, maturityHeight uint32, blocksTilMaturity int32) { if forceClose.MaturityHeight != maturityHeight { t.Fatalf("expected commitment maturity height to be %d, "+ "found %d instead", maturityHeight, forceClose.MaturityHeight) } if forceClose.BlocksTilMaturity != blocksTilMaturity { t.Fatalf("expected commitment blocks til maturity to be %d, "+ "found %d instead", blocksTilMaturity, forceClose.BlocksTilMaturity) } } // assertForceClosedChannelNumHtlcs verifies that a force closed channel has the // proper number of htlcs. func assertPendingChannelNumHtlcs(t *harnessTest, forceClose *lnrpc.PendingChannelsResponse_ForceClosedChannel, expectedNumHtlcs int) { if len(forceClose.PendingHtlcs) != expectedNumHtlcs { t.Fatalf("expected force closed channel to have %d pending "+ "htlcs, found %d instead", expectedNumHtlcs, len(forceClose.PendingHtlcs)) } } // assertNumForceClosedChannels checks that a pending channel response has the // expected number of force closed channels. func assertNumForceClosedChannels(t *harnessTest, pendingChanResp *lnrpc.PendingChannelsResponse, expectedNumChans int) { if len(pendingChanResp.PendingForceClosingChannels) != expectedNumChans { t.Fatalf("expected to find %d force closed channels, got %d", expectedNumChans, len(pendingChanResp.PendingForceClosingChannels)) } } // assertPendingHtlcStageAndMaturity uniformly tests all pending htlc's // belonging to a force closed channel, testing for the expected stage number, // blocks till maturity, and the maturity height. func assertPendingHtlcStageAndMaturity(t *harnessTest, forceClose *lnrpc.PendingChannelsResponse_ForceClosedChannel, stage, maturityHeight uint32, blocksTillMaturity int32) { for _, pendingHtlc := range forceClose.PendingHtlcs { if pendingHtlc.Stage != stage { t.Fatalf("expected pending htlc to be stage %d, "+ "found %d", stage, pendingHtlc.Stage) } if pendingHtlc.MaturityHeight != maturityHeight { t.Fatalf("expected pending htlc maturity height to be "+ "%d, instead has %d", maturityHeight, pendingHtlc.MaturityHeight) } if pendingHtlc.BlocksTilMaturity != blocksTillMaturity { t.Fatalf("expected pending htlc blocks til maturity "+ "to be %d, instead has %d", blocksTillMaturity, pendingHtlc.BlocksTilMaturity) } } } // testChannelForceClosure performs a test to exercise the behavior of "force" // closing a channel or unilaterally broadcasting the latest local commitment // state on-chain. The test creates a new channel between Alice and Carol, then // force closes the channel after some cursory assertions. Within the test, a // total of 3 + n transactions will be broadcast, representing the commitment // transaction, a transaction sweeping the local CSV delayed output, a // transaction sweeping the CSV delayed 2nd-layer htlcs outputs, and n // htlc success transactions, where n is the number of payments Alice attempted // to send to Carol. This test includes several restarts to ensure that the // transaction output states are persisted throughout the forced closure // process. // // TODO(roasbeef): also add an unsettled HTLC before force closing. func testChannelForceClosure(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() const ( timeout = time.Duration(time.Second * 10) chanAmt = btcutil.Amount(10e6) pushAmt = btcutil.Amount(5e6) paymentAmt = 100000 numInvoices = 6 ) // TODO(roasbeef): should check default value in config here // instead, or make delay a param defaultCSV := uint32(4) defaultCLTV := uint32(defaultBitcoinTimeLockDelta) // Since we'd like to test failure scenarios with outstanding htlcs, // we'll introduce another node into our test network: Carol. carol, err := net.NewNode([]string{"--debughtlc", "--hodlhtlc"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } // We must let Alice have an open channel before she can send a node // announcement, so we open a channel with Carol, if err := net.ConnectNodes(ctxb, net.Alice, carol); err != nil { t.Fatalf("unable to connect alice to carol: %v", err) } // Before we start, obtain Carol's current wallet balance, we'll check // to ensure that at the end of the force closure by Alice, Carol // recognizes his new on-chain output. carolBalReq := &lnrpc.WalletBalanceRequest{} carolBalResp, err := carol.WalletBalance(ctxb, carolBalReq) if err != nil { t.Fatalf("unable to get carol's balance: %v", err) } carolStartingBalance := btcutil.Amount(carolBalResp.ConfirmedBalance * 1e8) ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, carol, chanAmt, pushAmt) // Wait for Alice and Carol to receive the channel edge from the // funding manager. ctxt, _ = context.WithTimeout(ctxb, timeout) err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't see the alice->carol channel before "+ "timeout: %v", err) } err = carol.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't see the alice->carol channel before "+ "timeout: %v", err) } // Send payments from Alice to Carol, since Carol is htlchodl mode, the // htlc outputs should be left unsettled, and should be swept by the // utxo nursery. alicePayStream, err := net.Alice.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream for alice: %v", err) } carolPubKey := carol.PubKey[:] payHash := bytes.Repeat([]byte{2}, 32) for i := 0; i < numInvoices; i++ { err = alicePayStream.Send(&lnrpc.SendRequest{ Dest: carolPubKey, Amt: int64(paymentAmt), PaymentHash: payHash, FinalCltvDelta: defaultBitcoinTimeLockDelta, }) if err != nil { t.Fatalf("unable to send alice htlc: %v", err) } } // Once the HTLC has cleared, all the nodes n our mini network should // show that the HTLC has been locked in. nodes := []*lntest.HarnessNode{net.Alice, carol} err = lntest.WaitPredicate(func() bool { return assertNumActiveHtlcs(nodes, numInvoices) }, time.Second*15) if err != nil { t.Fatalf("htlc mismatch: %v", err) } // As we'll be querying the state of Carol's channels frequently we'll // create a closure helper function for the purpose. getAliceChanInfo := func() (*lnrpc.ActiveChannel, error) { req := &lnrpc.ListChannelsRequest{} aliceChannelInfo, err := net.Alice.ListChannels(ctxb, req) if err != nil { return nil, err } if len(aliceChannelInfo.Channels) != 1 { t.Fatalf("alice should only have a single channel, "+ "instead he has %v", len(aliceChannelInfo.Channels)) } return aliceChannelInfo.Channels[0], nil } // Fetch starting height of this test so we can compute the block // heights we expect certain events to take place. _, curHeight, err := net.Miner.Node.GetBestBlock() if err != nil { t.Fatalf("unable to get best block height") } // Using the current height of the chain, derive the relevant heights // for incubating two-stage htlcs. var ( startHeight = uint32(curHeight) commCsvMaturityHeight = startHeight + 1 + defaultCSV htlcExpiryHeight = startHeight + defaultCLTV htlcCsvMaturityHeight = startHeight + defaultCLTV + 1 + defaultCSV ) time.Sleep(200 * time.Millisecond) aliceChan, err := getAliceChanInfo() if err != nil { t.Fatalf("unable to get alice's channel info: %v", err) } if aliceChan.NumUpdates == 0 { t.Fatalf("alice should see at least one update to her channel") } // Now that the channel is open and we have unsettled htlcs, immediately // execute a force closure of the channel. This will also assert that // the commitment transaction was immediately broadcast in order to // fulfill the force closure request. _, closingTxID, err := net.CloseChannel(ctxb, net.Alice, chanPoint, true) if err != nil { t.Fatalf("unable to execute force channel closure: %v", err) } // Now that the channel has been force closed, it should show up in the // PendingChannels RPC under the force close section. pendingChansRequest := &lnrpc.PendingChannelsRequest{} pendingChanResp, err := net.Alice.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } assertNumForceClosedChannels(t, pendingChanResp, 1) // Compute the outpoint of the channel, which we will use repeatedly to // locate the pending channel information in the rpc responses. txidHash, err := getChanPointFundingTxid(chanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } txid, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } op := wire.OutPoint{ Hash: *txid, Index: chanPoint.OutputIndex, } forceClose := findForceClosedChannel(t, pendingChanResp, &op) // Immediately after force closing, all of the funds should be in limbo, // and the pending channels response should not indicate that any funds // have been recovered. if forceClose.LimboBalance == 0 { t.Fatalf("all funds should still be in limbo") } if forceClose.RecoveredBalance != 0 { t.Fatalf("no funds should yet be shown as recovered") } // The commitment transaction has not been confirmed, so we expect to // see a maturity height and blocks til maturity of 0. assertCommitmentMaturity(t, forceClose, 0, 0) // The several restarts in this test are intended to ensure that when a // channel is force-closed, the UTXO nursery has persisted the state of // the channel in the closure process and will recover the correct state // when the system comes back on line. This restart tests state // persistence at the beginning of the process, when the commitment // transaction has been broadcast but not yet confirmed in a block. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } // Mine a block which should confirm the commitment transaction // broadcast as a result of the force closure. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate block: %v", err) } // The following sleep provides time for the UTXO nursery to move the // output from the preschool to the kindergarten database buckets // prior to RestartNode() being triggered. Without this sleep, the // database update may fail, causing the UTXO nursery to retry the move // operation upon restart. This will change the blockheights from what // is expected by the test. // TODO(bvu): refactor out this sleep. duration := time.Millisecond * 300 time.Sleep(duration) pendingChanResp, err = net.Alice.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } assertNumForceClosedChannels(t, pendingChanResp, 1) forceClose = findForceClosedChannel(t, pendingChanResp, &op) // Now that the channel has been force closed, it should now have the // height and number of blocks to confirm populated. assertCommitmentMaturity(t, forceClose, commCsvMaturityHeight, int32(defaultCSV)) // None of our outputs have been swept, so they should all be limbo. if forceClose.LimboBalance == 0 { t.Fatalf("all funds should still be in limbo") } if forceClose.RecoveredBalance != 0 { t.Fatalf("no funds should yet be shown as recovered") } // The following restart is intended to ensure that outputs from the // force close commitment transaction have been persisted once the // transaction has been confirmed, but before the outputs are spendable // (the "kindergarten" bucket.) if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } // Currently within the codebase, the default CSV is 4 relative blocks. // For the persistence test, we generate three blocks, then trigger // a restart and then generate the final block that should trigger // the creation of the sweep transaction. if _, err := net.Miner.Node.Generate(defaultCSV - 1); err != nil { t.Fatalf("unable to mine blocks: %v", err) } // The following restart checks to ensure that outputs in the // kindergarten bucket are persisted while waiting for the required // number of confirmations to be reported. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } pendingChanResp, err = net.Alice.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } assertNumForceClosedChannels(t, pendingChanResp, 1) forceClose = findForceClosedChannel(t, pendingChanResp, &op) // At this point, the nursery should show that the commitment output has // 1 block left before its CSV delay expires. In total, we have mined // exactly defaultCSV blocks, so the htlc outputs should also reflect // that this many blocks have passed. assertCommitmentMaturity(t, forceClose, commCsvMaturityHeight, 1) // All funds should still be shown in limbo. if forceClose.LimboBalance == 0 { t.Fatalf("all funds should still be in limbo") } if forceClose.RecoveredBalance != 0 { t.Fatalf("no funds should yet be shown as recovered") } // Generate an additional block, which should cause the CSV delayed // output from the commitment txn to expire. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to mine blocks: %v", err) } // At this point, the sweeping transaction should now be broadcast. So // we fetch the node's mempool to ensure it has been properly // broadcast. sweepingTXID, err := waitForTxInMempool(net.Miner.Node, 3*time.Second) if err != nil { t.Fatalf("failed to get sweep tx from mempool: %v", err) } // Fetch the sweep transaction, all input it's spending should be from // the commitment transaction which was broadcast on-chain. sweepTx, err := net.Miner.Node.GetRawTransaction(sweepingTXID) if err != nil { t.Fatalf("unable to fetch sweep tx: %v", err) } for _, txIn := range sweepTx.MsgTx().TxIn { if !closingTxID.IsEqual(&txIn.PreviousOutPoint.Hash) { t.Fatalf("sweep transaction not spending from commit "+ "tx %v, instead spending %v", closingTxID, txIn.PreviousOutPoint) } } // Restart Alice to ensure that she resumes watching the finalized // commitment sweep txid. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } // Next, we mine an additional block which should include the sweep // transaction as the input scripts and the sequence locks on the // inputs should be properly met. blockHash, err := net.Miner.Node.Generate(1) if err != nil { t.Fatalf("unable to generate block: %v", err) } block, err := net.Miner.Node.GetBlock(blockHash[0]) if err != nil { t.Fatalf("unable to get block: %v", err) } assertTxInBlock(t, block, sweepTx.Hash()) // We sleep here to ensure that Alice has enough time to receive a // confirmation for the commitment transaction, which we already // asserted was in the last block. time.Sleep(300 * time.Millisecond) // Now that the commit output has been fully swept, check to see that // the channel remains open for the pending htlc outputs. pendingChanResp, err = net.Alice.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } assertNumForceClosedChannels(t, pendingChanResp, 1) // The htlc funds will still be shown as limbo, since they are still in // their first stage. The commitment funds will have been recovered // after the commit txn was included in the last block. if forceClose.LimboBalance == 0 { t.Fatalf("htlc funds should still be in limbo") } // Compute the height preceding that which will cause the htlc CLTV // timeouts will expire. The outputs entered at the same height as the // output spending from the commitment txn, so we must deduct the number // of blocks we have generated since adding it to the nursery, and take // an additional block off so that we end up one block shy of the expiry // height. cltvHeightDelta := defaultCLTV - defaultCSV - 2 - 1 // Advance the blockchain until just before the CLTV expires, nothing // exciting should have happened during this time. blockHash, err = net.Miner.Node.Generate(cltvHeightDelta) if err != nil { t.Fatalf("unable to generate block: %v", err) } time.Sleep(duration) // We now restart Alice, to ensure that she will broadcast the presigned // htlc timeout txns after the delay expires after experiencing an while // waiting for the htlc outputs to incubate. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } time.Sleep(duration) pendingChanResp, err = net.Alice.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } assertNumForceClosedChannels(t, pendingChanResp, 1) forceClose = findForceClosedChannel(t, pendingChanResp, &op) // We should now be at the block just before the utxo nursery will // attempt to broadcast the htlc timeout transactions. assertPendingChannelNumHtlcs(t, forceClose, numInvoices) assertPendingHtlcStageAndMaturity(t, forceClose, 1, htlcExpiryHeight, 1) // Now that our commitment confirmation depth has been surpassed, we // should now see a non-zero recovered balance. All htlc outputs are // still left in limbo, so it should be non-zero as well. if forceClose.LimboBalance == 0 { t.Fatalf("htlc funds should still be in limbo") } // Now, generate the block which will cause Alice to broadcast the // presigned htlc timeout txns. blockHash, err = net.Miner.Node.Generate(1) if err != nil { t.Fatalf("unable to generate block: %v", err) } // Since Alice had numInvoices (6) htlcs extended to Carol before force // closing, we expect Alice to broadcast an htlc timeout txn for each // one. Wait for them all to show up in the mempool. htlcTxIDs, err := waitForNTxsInMempool(net.Miner.Node, numInvoices, 10*time.Second) if err != nil { t.Fatalf("unable to find htlc timeout txns in mempool: %v", err) } // Retrieve each htlc timeout txn from the mempool, and ensure it is // well-formed. This entails verifying that each only spends from // output, and that that output is from the commitment txn. for _, htlcTxID := range htlcTxIDs { // Fetch the sweep transaction, all input it's spending should // be from the commitment transaction which was broadcast // on-chain. htlcTx, err := net.Miner.Node.GetRawTransaction(htlcTxID) if err != nil { t.Fatalf("unable to fetch sweep tx: %v", err) } // Ensure the htlc transaction only has one input. if len(htlcTx.MsgTx().TxIn) != 1 { t.Fatalf("htlc transaction should only have one txin, "+ "has %d", len(htlcTx.MsgTx().TxIn)) } // Ensure the htlc transaction is spending from the commitment // transaction. txIn := htlcTx.MsgTx().TxIn[0] if !closingTxID.IsEqual(&txIn.PreviousOutPoint.Hash) { t.Fatalf("htlc transaction not spending from commit "+ "tx %v, instead spending %v", closingTxID, txIn.PreviousOutPoint) } } // With the htlc timeout txns still in the mempool, we restart Alice to // verify that she can resume watching the htlc txns she broadcasted // before crashing. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } time.Sleep(duration) // Generate a block that mines the htlc timeout txns. Doing so now // activates the 2nd-stage CSV delayed outputs. blockHash, err = net.Miner.Node.Generate(1) if err != nil { t.Fatalf("unable to generate block: %v", err) } // This sleep gives Alice enough to time move the crib outputs into the // kindergarten bucket. time.Sleep(duration) // Alice is restarted here to ensure that she promptly moved the crib // outputs to the kindergarten bucket after the htlc timeout txns were // confirmed. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } // Advance the chain until just before the 2nd-layer CSV delays expire. blockHash, err = net.Miner.Node.Generate(defaultCSV - 1) if err != nil { t.Fatalf("unable to generate block: %v", err) } // Restart Alice to ensure that she can recover from a failure before // having graduated the htlc outputs in the kindergarten bucket. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } // Now that the channel has been fully swept, it should no longer show // incubated, check to see that Alice's node still reports the channel // as pending force closed. pendingChanResp, err = net.Alice.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } assertNumForceClosedChannels(t, pendingChanResp, 1) forceClose = findForceClosedChannel(t, pendingChanResp, &op) if forceClose.LimboBalance == 0 { t.Fatalf("htlc funds should still be in limbo") } assertPendingChannelNumHtlcs(t, forceClose, numInvoices) // Generate a block that causes Alice to sweep the htlc outputs in the // kindergarten bucket. blockHash, err = net.Miner.Node.Generate(1) if err != nil { t.Fatalf("unable to generate block: %v", err) } // Wait for the single sweep txn to appear in the mempool. htlcSweepTxID, err := waitForTxInMempool(net.Miner.Node, 15*time.Second) if err != nil { t.Fatalf("failed to get sweep tx from mempool: %v", err) } // Construct a map of the already confirmed htlc timeout txids, that // will count the number of times each is spent by the sweep txn. We // prepopulate it in this way so that we can later detect if we are // spending from an output that was not a confirmed htlc timeout txn. var htlcTxIDSet = make(map[chainhash.Hash]int) for _, htlcTxID := range htlcTxIDs { htlcTxIDSet[*htlcTxID] = 0 } // Fetch the htlc sweep transaction from the mempool. htlcSweepTx, err := net.Miner.Node.GetRawTransaction(htlcSweepTxID) if err != nil { t.Fatalf("unable to fetch sweep tx: %v", err) } // Ensure the htlc sweep transaction only has one input for each htlc // Alice extended before force closing. if len(htlcSweepTx.MsgTx().TxIn) != numInvoices { t.Fatalf("htlc transaction should have %d txin, "+ "has %d", numInvoices, len(htlcSweepTx.MsgTx().TxIn)) } // Ensure that each output spends from exactly one htlc timeout txn. for _, txIn := range htlcSweepTx.MsgTx().TxIn { outpoint := txIn.PreviousOutPoint.Hash // Check that the input is a confirmed htlc timeout txn. if _, ok := htlcTxIDSet[outpoint]; !ok { t.Fatalf("htlc sweep output not spending from htlc "+ "tx, instead spending output %v", outpoint) } // Increment our count for how many times this output was spent. htlcTxIDSet[outpoint]++ // Check that each is only spent once. if htlcTxIDSet[outpoint] > 1 { t.Fatalf("htlc sweep tx has multiple spends from "+ "outpoint %v", outpoint) } } // The following restart checks to ensure that the nursery store is // storing the txid of the previously broadcast htlc sweep txn, and that // it begins watching that txid after restarting. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } time.Sleep(duration) // Now that the channel has been fully swept, it should no longer show // incubated, check to see that Alice's node still reports the channel // as pending force closed. pendingChanResp, err = net.Alice.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } assertNumForceClosedChannels(t, pendingChanResp, 1) // All htlcs should show zero blocks until maturity, as evidenced by // having checked the sweep transaction in the mempool. forceClose = findForceClosedChannel(t, pendingChanResp, &op) assertPendingChannelNumHtlcs(t, forceClose, numInvoices) assertPendingHtlcStageAndMaturity(t, forceClose, 2, htlcCsvMaturityHeight, 0) // Generate the final block that sweeps all htlc funds into the user's // wallet. blockHash, err = net.Miner.Node.Generate(1) if err != nil { t.Fatalf("unable to generate block: %v", err) } time.Sleep(3 * duration) // Now that the channel has been fully swept, it should no longer show // up within the pending channels RPC. pendingChanResp, err = net.Alice.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } assertNumForceClosedChannels(t, pendingChanResp, 0) // In addition to there being no pending channels, we verify that // pending channels does not report any money still in limbo. if pendingChanResp.TotalLimboBalance != 0 { t.Fatalf("no user funds should be left in limbo after incubation") } // At this point, Carol should now be aware of his new immediately // spendable on-chain balance, as it was Alice who broadcast the // commitment transaction. carolBalResp, err = net.Bob.WalletBalance(ctxb, carolBalReq) if err != nil { t.Fatalf("unable to get carol's balance: %v", err) } carolExpectedBalance := carolStartingBalance + pushAmt if btcutil.Amount(carolBalResp.ConfirmedBalance*1e8) < carolExpectedBalance { t.Fatalf("carol's balance is incorrect: expected %v got %v", carolExpectedBalance, btcutil.Amount(carolBalResp.ConfirmedBalance*1e8)) } } // testSphinxReplayPersistence verifies that replayed onion packets are rejected // by a remote peer after a restart. We use a combination of unsafe // configuration arguments to force Carol to replay the same sphinx packet after // reconnecting to Dave, and compare the returned failure message with what we // expect for replayed onion packets. func testSphinxReplayPersistence(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() timeout := time.Duration(time.Second * 5) // Open a channel with 100k satoshis between Carol and Dave with Carol being // the sole funder of the channel. chanAmt := btcutil.Amount(100000) // First, we'll create Dave, the receiver, and start him in hodl mode. dave, err := net.NewNode([]string{"--debughtlc", "--hodlhtlc"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } // Next, we'll create Carol and establish a channel to from her to // Dave. Carol is started in both unsafe-replay and unsafe-disconnect, // which will cause her to replay any pending Adds held in memory upon // reconnection. carol, err := net.NewNode([]string{"--unsafe-replay"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, carol, dave); err != nil { t.Fatalf("unable to connect carol to dave: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, carol) if err != nil { t.Fatalf("unable to send coins to carol: %v", err) } ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, carol, dave, chanAmt, 0) assertAmountSent := func(amt btcutil.Amount) { // Both channels should also have properly accounted from the // amount that has been sent/received over the channel. listReq := &lnrpc.ListChannelsRequest{} carolListChannels, err := carol.ListChannels(ctxb, listReq) if err != nil { t.Fatalf("unable to query for alice's channel list: %v", err) } carolSatoshisSent := carolListChannels.Channels[0].TotalSatoshisSent if carolSatoshisSent != int64(amt) { t.Fatalf("Carol's satoshis sent is incorrect got %v, expected %v", carolSatoshisSent, amt) } daveListChannels, err := dave.ListChannels(ctxb, listReq) if err != nil { t.Fatalf("unable to query for Dave's channel list: %v", err) } daveSatoshisReceived := daveListChannels.Channels[0].TotalSatoshisReceived if daveSatoshisReceived != int64(amt) { t.Fatalf("Dave's satoshis received is incorrect got %v, expected %v", daveSatoshisReceived, amt) } } // Now that the channel is open, create an invoice for Dave which // expects a payment of 1000 satoshis from Carol paid via a particular // preimage. const paymentAmt = 1000 preimage := bytes.Repeat([]byte("A"), 32) invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } invoiceResp, err := dave.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } // Wait for Carol to recognize and advertise the new channel generated // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = carol.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't advertise channel before "+ "timeout: %v", err) } err = dave.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("bob didn't advertise channel before "+ "timeout: %v", err) } // With the invoice for Dave added, send a payment from Carol paying // to the above generated invoice. ctx, cancel := context.WithCancel(ctxb) defer cancel() payStream, err := carol.SendPayment(ctx) if err != nil { t.Fatalf("unable to open payment stream: %v", err) } sendReq := &lnrpc.SendRequest{PaymentRequest: invoiceResp.PaymentRequest} err = payStream.Send(sendReq) if err != nil { t.Fatalf("unable to send payment: %v", err) } time.Sleep(200 * time.Millisecond) // Dave's invoice should not be marked as settled. payHash := &lnrpc.PaymentHash{ RHash: invoiceResp.RHash, } dbInvoice, err := dave.LookupInvoice(ctxb, payHash) if err != nil { t.Fatalf("unable to lookup invoice: %v", err) } if dbInvoice.Settled { t.Fatalf("dave's invoice should not be marked as settled: %v", spew.Sdump(dbInvoice)) } // With the payment sent but hedl, all balance related stats should not // have changed. time.Sleep(time.Millisecond * 200) assertAmountSent(0) // With the first payment sent, restart dave to make sure he is // persisting the information required to detect replayed sphinx // packets. if err := net.RestartNode(dave, nil); err != nil { t.Fatalf("unable to restart dave: %v", err) } // Carol should retransmit the Add hedl in her mailbox on startup. Dave // should not accept the replayed Add, and actually fail back the // pending payment. Even though he still holds the original settle, if // he does fail, it is almost certainly caused by the sphinx replay // protection, as it is the only validation we do in hodl mode. resp, err := payStream.Recv() if err != nil { t.Fatalf("unable to receive payment response: %v", err) } // Construct the response we expect after sending a duplicate packet // that fails due to sphinx replay detection. replayErr := fmt.Sprintf("unable to route payment to destination: "+ "TemporaryChannelFailure: unable to de-obfuscate onion failure, "+ "htlc with hash(%x): unable to retrieve onion failure", invoiceResp.RHash) if resp.PaymentError != replayErr { t.Fatalf("received payment error: %v", resp.PaymentError) } // Since the payment failed, the balance should still be left unaltered. assertAmountSent(0) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, carol, chanPoint, false) // Finally, shutdown the nodes we created for the duration of the tests, // only leaving the two seed nodes (Alice and Bob) within our test // network. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } if err := net.ShutdownNode(dave); err != nil { t.Fatalf("unable to shutdown dave: %v", err) } } func testSingleHopInvoice(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() timeout := time.Duration(time.Second * 5) // Open a channel with 100k satoshis between Alice and Bob with Alice being // the sole funder of the channel. ctxt, _ := context.WithTimeout(ctxb, timeout) chanAmt := btcutil.Amount(100000) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, 0) assertAmountSent := func(amt btcutil.Amount) { // Both channels should also have properly accounted from the // amount that has been sent/received over the channel. listReq := &lnrpc.ListChannelsRequest{} aliceListChannels, err := net.Alice.ListChannels(ctxb, listReq) if err != nil { t.Fatalf("unable to query for alice's channel list: %v", err) } aliceSatoshisSent := aliceListChannels.Channels[0].TotalSatoshisSent if aliceSatoshisSent != int64(amt) { t.Fatalf("Alice's satoshis sent is incorrect got %v, expected %v", aliceSatoshisSent, amt) } bobListChannels, err := net.Bob.ListChannels(ctxb, listReq) if err != nil { t.Fatalf("unable to query for bob's channel list: %v", err) } bobSatoshisReceived := bobListChannels.Channels[0].TotalSatoshisReceived if bobSatoshisReceived != int64(amt) { t.Fatalf("Bob's satoshis received is incorrect got %v, expected %v", bobSatoshisReceived, amt) } } // Now that the channel is open, create an invoice for Bob which // expects a payment of 1000 satoshis from Alice paid via a particular // preimage. const paymentAmt = 1000 preimage := bytes.Repeat([]byte("A"), 32) invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } invoiceResp, err := net.Bob.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } // Wait for Alice to recognize and advertise the new channel generated // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't advertise channel before "+ "timeout: %v", err) } err = net.Bob.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("bob didn't advertise channel before "+ "timeout: %v", err) } // With the invoice for Bob added, send a payment towards Alice paying // to the above generated invoice. sendReq := &lnrpc.SendRequest{ PaymentRequest: invoiceResp.PaymentRequest, } ctxt, _ = context.WithTimeout(ctxb, timeout) resp, err := net.Alice.SendPaymentSync(ctxt, sendReq) if err != nil { t.Fatalf("unable to send payment: %v", err) } // Ensure we obtain the proper preimage in the response. if resp.PaymentError != "" { t.Fatalf("error when attempting recv: %v", resp.PaymentError) } else if !bytes.Equal(preimage, resp.PaymentPreimage) { t.Fatalf("preimage mismatch: expected %v, got %v", preimage, resp.GetPaymentPreimage()) } // Bob's invoice should now be found and marked as settled. payHash := &lnrpc.PaymentHash{ RHash: invoiceResp.RHash, } dbInvoice, err := net.Bob.LookupInvoice(ctxb, payHash) if err != nil { t.Fatalf("unable to lookup invoice: %v", err) } if !dbInvoice.Settled { t.Fatalf("bob's invoice should be marked as settled: %v", spew.Sdump(dbInvoice)) } // With the payment completed all balance related stats should be // properly updated. time.Sleep(time.Millisecond * 200) assertAmountSent(paymentAmt) // Create another invoice for Bob, this time leaving off the preimage // to one will be randomly generated. We'll test the proper // encoding/decoding of the zpay32 payment requests. invoice = &lnrpc.Invoice{ Memo: "test3", Value: paymentAmt, } invoiceResp, err = net.Bob.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } // Next send another payment, but this time using a zpay32 encoded // invoice rather than manually specifying the payment details. sendReq = &lnrpc.SendRequest{ PaymentRequest: invoiceResp.PaymentRequest, } ctxt, _ = context.WithTimeout(ctxb, timeout) resp, err = net.Alice.SendPaymentSync(ctxt, sendReq) if err != nil { t.Fatalf("unable to send payment: %v", err) } if resp.PaymentError != "" { t.Fatalf("error when attempting recv: %v", resp.PaymentError) } // The second payment should also have succeeded, with the balances // being update accordingly. time.Sleep(time.Millisecond * 200) assertAmountSent(paymentAmt * 2) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) } func testListPayments(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() timeout := time.Duration(time.Second * 5) // First start by deleting all payments that Alice knows of. This will // allow us to execute the test with a clean state for Alice. delPaymentsReq := &lnrpc.DeleteAllPaymentsRequest{} if _, err := net.Alice.DeleteAllPayments(ctxb, delPaymentsReq); err != nil { t.Fatalf("unable to delete payments: %v", err) } // Check that there are no payments before test. reqInit := &lnrpc.ListPaymentsRequest{} paymentsRespInit, err := net.Alice.ListPayments(ctxb, reqInit) if err != nil { t.Fatalf("error when obtaining Alice payments: %v", err) } if len(paymentsRespInit.Payments) != 0 { t.Fatalf("incorrect number of payments, got %v, want %v", len(paymentsRespInit.Payments), 0) } // Open a channel with 100k satoshis between Alice and Bob with Alice // being the sole funder of the channel. chanAmt := btcutil.Amount(100000) ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, 0) // Now that the channel is open, create an invoice for Bob which // expects a payment of 1000 satoshis from Alice paid via a particular // preimage. const paymentAmt = 1000 preimage := bytes.Repeat([]byte("B"), 32) invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } addInvoiceCtxt, _ := context.WithTimeout(ctxb, timeout) invoiceResp, err := net.Bob.AddInvoice(addInvoiceCtxt, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } // Wait for Alice to recognize and advertise the new channel generated // above. ctxt, _ = context.WithTimeout(ctxb, timeout) if err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint); err != nil { t.Fatalf("alice didn't advertise channel before "+ "timeout: %v", err) } if err = net.Bob.WaitForNetworkChannelOpen(ctxt, chanPoint); err != nil { t.Fatalf("bob didn't advertise channel before "+ "timeout: %v", err) } // With the invoice for Bob added, send a payment towards Alice paying // to the above generated invoice. sendReq := &lnrpc.SendRequest{ PaymentRequest: invoiceResp.PaymentRequest, } ctxt, _ = context.WithTimeout(ctxb, timeout) resp, err := net.Alice.SendPaymentSync(ctxt, sendReq) if err != nil { t.Fatalf("unable to send payment: %v", err) } if resp.PaymentError != "" { t.Fatalf("error when attempting recv: %v", resp.PaymentError) } // Grab Alice's list of payments, she should show the existence of // exactly one payment. req := &lnrpc.ListPaymentsRequest{} paymentsResp, err := net.Alice.ListPayments(ctxb, req) if err != nil { t.Fatalf("error when obtaining Alice payments: %v", err) } if len(paymentsResp.Payments) != 1 { t.Fatalf("incorrect number of payments, got %v, want %v", len(paymentsResp.Payments), 1) } p := paymentsResp.Payments[0] // Ensure that the stored path shows a direct payment to Bob with no // other nodes in-between. expectedPath := []string{ net.Bob.PubKeyStr, } if !reflect.DeepEqual(p.Path, expectedPath) { t.Fatalf("incorrect path, got %v, want %v", p.Path, expectedPath) } // The payment amount should also match our previous payment directly. if p.Value != paymentAmt { t.Fatalf("incorrect amount, got %v, want %v", p.Value, paymentAmt) } // The payment hash (or r-hash) should have been stored correctly. correctRHash := hex.EncodeToString(invoiceResp.RHash) if !reflect.DeepEqual(p.PaymentHash, correctRHash) { t.Fatalf("incorrect RHash, got %v, want %v", p.PaymentHash, correctRHash) } // Finally, as we made a single-hop direct payment, there should have // been no fee applied. if p.Fee != 0 { t.Fatalf("incorrect Fee, got %v, want %v", p.Fee, 0) } // Delete all payments from Alice. DB should have no payments. delReq := &lnrpc.DeleteAllPaymentsRequest{} _, err = net.Alice.DeleteAllPayments(ctxb, delReq) if err != nil { t.Fatalf("Can't delete payments at the end: %v", err) } // Check that there are no payments before test. listReq := &lnrpc.ListPaymentsRequest{} paymentsResp, err = net.Alice.ListPayments(ctxb, listReq) if err != nil { t.Fatalf("error when obtaining Alice payments: %v", err) } if len(paymentsResp.Payments) != 0 { t.Fatalf("incorrect number of payments, got %v, want %v", len(paymentsRespInit.Payments), 0) } ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) } // assertAmountPaid checks that the ListChannels command of the provided // node list the total amount sent and received as expected for the // provided channel. func assertAmountPaid(t *harnessTest, ctxb context.Context, channelName string, node *lntest.HarnessNode, chanPoint wire.OutPoint, amountSent, amountReceived int64) { checkAmountPaid := func() error { listReq := &lnrpc.ListChannelsRequest{} resp, err := node.ListChannels(ctxb, listReq) if err != nil { return fmt.Errorf("unable to for node's "+ "channels: %v", err) } for _, channel := range resp.Channels { if channel.ChannelPoint != chanPoint.String() { continue } if channel.TotalSatoshisSent != amountSent { return fmt.Errorf("%v: incorrect amount"+ " sent: %v != %v", channelName, channel.TotalSatoshisSent, amountSent) } if channel.TotalSatoshisReceived != amountReceived { return fmt.Errorf("%v: incorrect amount"+ " received: %v != %v", channelName, channel.TotalSatoshisReceived, amountReceived) } return nil } return fmt.Errorf("channel not found") } // As far as HTLC inclusion in commitment transaction might be // postponed we will try to check the balance couple of times, // and then if after some period of time we receive wrong // balance return the error. // TODO(roasbeef): remove sleep after invoice notification hooks // are in place var timeover uint32 go func() { <-time.After(time.Second * 20) atomic.StoreUint32(&timeover, 1) }() for { isTimeover := atomic.LoadUint32(&timeover) == 1 if err := checkAmountPaid(); err != nil { if isTimeover { t.Fatalf("Check amount Paid failed: %v", err) } } else { break } } } func testMultiHopPayments(net *lntest.NetworkHarness, t *harnessTest) { const chanAmt = btcutil.Amount(100000) ctxb := context.Background() timeout := time.Duration(time.Second * 15) var networkChans []*lnrpc.ChannelPoint // Open a channel with 100k satoshis between Alice and Bob with Alice // being the sole funder of the channel. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPointAlice := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, 0) networkChans = append(networkChans, chanPointAlice) txidHash, err := getChanPointFundingTxid(chanPointAlice) if err != nil { t.Fatalf("unable to get txid: %v", err) } aliceChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } aliceFundPoint := wire.OutPoint{ Hash: *aliceChanTXID, Index: chanPointAlice.OutputIndex, } // As preliminary setup, we'll create two new nodes: Carol and Dave, // such that we now have a 4 ndoe, 3 channel topology. Dave will make // a channel with Alice, and Carol with Dave. After this setup, the // network topology should now look like: // Carol -> Dave -> Alice -> Bob // // First, we'll create Dave and establish a channel to Alice. dave, err := net.NewNode(nil) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, dave, net.Alice); err != nil { t.Fatalf("unable to connect dave to alice: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, dave) if err != nil { t.Fatalf("unable to send coins to dave: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointDave := openChannelAndAssert(ctxt, t, net, dave, net.Alice, chanAmt, 0) networkChans = append(networkChans, chanPointDave) txidHash, err = getChanPointFundingTxid(chanPointDave) if err != nil { t.Fatalf("unable to get txid: %v", err) } daveChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } daveFundPoint := wire.OutPoint{ Hash: *daveChanTXID, Index: chanPointDave.OutputIndex, } // Next, we'll create Carol and establish a channel to from her to // Dave. carol, err := net.NewNode(nil) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, carol, dave); err != nil { t.Fatalf("unable to connect carol to dave: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, carol) if err != nil { t.Fatalf("unable to send coins to carol: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointCarol := openChannelAndAssert(ctxt, t, net, carol, dave, chanAmt, 0) networkChans = append(networkChans, chanPointCarol) txidHash, err = getChanPointFundingTxid(chanPointCarol) if err != nil { t.Fatalf("unable to get txid: %v", err) } carolChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } carolFundPoint := wire.OutPoint{ Hash: *carolChanTXID, Index: chanPointCarol.OutputIndex, } // Wait for all nodes to have seen all channels. nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol, dave} nodeNames := []string{"Alice", "Bob", "Carol", "Dave"} for _, chanPoint := range networkChans { for i, node := range nodes { txidHash, err := getChanPointFundingTxid(chanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } txid, e := chainhash.NewHash(txidHash) if e != nil { t.Fatalf("unable to create sha hash: %v", e) } point := wire.OutPoint{ Hash: *txid, Index: chanPoint.OutputIndex, } ctxt, _ = context.WithTimeout(ctxb, timeout) err = node.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("%s(%d): timeout waiting for "+ "channel(%s) open: %v", nodeNames[i], node.NodeID, point, err) } } } // Create 5 invoices for Bob, which expect a payment from Carol for 1k // satoshis with a different preimage each time. const numPayments = 5 const paymentAmt = 1000 payReqs := make([]string, numPayments) for i := 0; i < numPayments; i++ { invoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt, } resp, err := net.Bob.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs[i] = resp.PaymentRequest } // We'll wait for all parties to recognize the new channels within the // network. ctxt, _ = context.WithTimeout(ctxb, timeout) err = dave.WaitForNetworkChannelOpen(ctxt, chanPointDave) if err != nil { t.Fatalf("dave didn't advertise his channel: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) err = carol.WaitForNetworkChannelOpen(ctxt, chanPointCarol) if err != nil { t.Fatalf("carol didn't advertise her channel in time: %v", err) } time.Sleep(time.Millisecond * 50) // Using Carol as the source, pay to the 5 invoices from Bob created // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, carol, payReqs, true) if err != nil { t.Fatalf("unable to send payments: %v", err) } // When asserting the amount of satoshis moved, we'll factor in the // default base fee, as we didn't modify the fee structure when // creating the seed nodes in the network. const baseFee = 1 // At this point all the channels within our proto network should be // shifted by 5k satoshis in the direction of Bob, the sink within the // payment flow generated above. The order of asserts corresponds to // increasing of time is needed to embed the HTLC in commitment // transaction, in channel Carol->David->Alice->Bob, order is Bob, // Alice, David, Carol. const amountPaid = int64(5000) assertAmountPaid(t, ctxb, "Alice(local) => Bob(remote)", net.Bob, aliceFundPoint, int64(0), amountPaid) assertAmountPaid(t, ctxb, "Alice(local) => Bob(remote)", net.Alice, aliceFundPoint, amountPaid, int64(0)) assertAmountPaid(t, ctxb, "Dave(local) => Alice(remote)", net.Alice, daveFundPoint, int64(0), amountPaid+(baseFee*numPayments)) assertAmountPaid(t, ctxb, "Dave(local) => Alice(remote)", dave, daveFundPoint, amountPaid+(baseFee*numPayments), int64(0)) assertAmountPaid(t, ctxb, "Carol(local) => Dave(remote)", dave, carolFundPoint, int64(0), amountPaid+((baseFee*numPayments)*2)) assertAmountPaid(t, ctxb, "Carol(local) => Dave(remote)", carol, carolFundPoint, amountPaid+(baseFee*numPayments)*2, int64(0)) // Now that we know all the balances have been settled out properly, // we'll ensure that our internal record keeping for completed circuits // was properly updated. // First, check that the FeeReport response shows the proper fees // accrued over each time range. Dave should've earned 1 satoshi for // each of the forwarded payments. feeReport, err := dave.FeeReport(ctxb, &lnrpc.FeeReportRequest{}) if err != nil { t.Fatalf("unable to query for fee report: %v", err) } const exectedFees = 5 if feeReport.DayFeeSum != exectedFees { t.Fatalf("fee mismatch: expected %v, got %v", 5, feeReport.DayFeeSum) } if feeReport.WeekFeeSum != exectedFees { t.Fatalf("fee mismatch: expected %v, got %v", 5, feeReport.WeekFeeSum) } if feeReport.MonthFeeSum != exectedFees { t.Fatalf("fee mismatch: expected %v, got %v", 5, feeReport.MonthFeeSum) } // Next, ensure that if we issue the vanilla query for the forwarding // history, it returns 5 values, and each entry is formatted properly. fwdingHistory, err := dave.ForwardingHistory( ctxb, &lnrpc.ForwardingHistoryRequest{}, ) if err != nil { t.Fatalf("unable to query for fee report: %v", err) } if len(fwdingHistory.ForwardingEvents) != 5 { t.Fatalf("wrong number of forwarding event: expected %v, "+ "got %v", 5, len(fwdingHistory.ForwardingEvents)) } for _, event := range fwdingHistory.ForwardingEvents { // Each event should show a fee of 1 satoshi. if event.Fee != 1 { t.Fatalf("fee mismatch: expected %v, got %v", 1, event.Fee) } } ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPointAlice, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, dave, chanPointDave, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, carol, chanPointCarol, false) // Finally, shutdown the nodes we created for the duration of the // tests, only leaving the two seed nodes (Alice and Bob) within our // test network. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } if err := net.ShutdownNode(dave); err != nil { t.Fatalf("unable to shutdown dave: %v", err) } } // testPrivateChannels tests that a private channel can be used for // routing by the two endpoints of the channel, but is not known by // the rest of the nodes in the graph. func testPrivateChannels(net *lntest.NetworkHarness, t *harnessTest) { const chanAmt = btcutil.Amount(100000) ctxb := context.Background() timeout := time.Duration(time.Second * 5) var networkChans []*lnrpc.ChannelPoint // We create the the following topology: // // Dave --100k--> Alice --200k--> Bob // ^ ^ // | | // 100k 100k // | | // +---- Carol ----+ // // where the 100k channel between Carol and Alice is private. // Open a channel with 200k satoshis between Alice and Bob. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPointAlice := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt*2, 0) networkChans = append(networkChans, chanPointAlice) txidHash, err := getChanPointFundingTxid(chanPointAlice) if err != nil { t.Fatalf("unable to get txid: %v", err) } aliceChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } aliceFundPoint := wire.OutPoint{ Hash: *aliceChanTXID, Index: chanPointAlice.OutputIndex, } // Create Dave, and a channel to Alice of 100k. dave, err := net.NewNode(nil) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, dave, net.Alice); err != nil { t.Fatalf("unable to connect dave to alice: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, dave) if err != nil { t.Fatalf("unable to send coins to dave: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointDave := openChannelAndAssert(ctxt, t, net, dave, net.Alice, chanAmt, 0) networkChans = append(networkChans, chanPointDave) txidHash, err = getChanPointFundingTxid(chanPointDave) if err != nil { t.Fatalf("unable to get txid: %v", err) } daveChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } daveFundPoint := wire.OutPoint{ Hash: *daveChanTXID, Index: chanPointDave.OutputIndex, } // Next, we'll create Carol and establish a channel from her to // Dave of 100k. carol, err := net.NewNode(nil) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, carol, dave); err != nil { t.Fatalf("unable to connect carol to dave: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, carol) if err != nil { t.Fatalf("unable to send coins to carol: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointCarol := openChannelAndAssert(ctxt, t, net, carol, dave, chanAmt, 0) networkChans = append(networkChans, chanPointCarol) txidHash, err = getChanPointFundingTxid(chanPointCarol) if err != nil { t.Fatalf("unable to get txid: %v", err) } carolChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } carolFundPoint := wire.OutPoint{ Hash: *carolChanTXID, Index: chanPointCarol.OutputIndex, } // Wait for all nodes to have seen all these channels, as they // are all public. nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol, dave} nodeNames := []string{"Alice", "Bob", "Carol", "Dave"} for _, chanPoint := range networkChans { for i, node := range nodes { txidHash, err := getChanPointFundingTxid(chanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } txid, e := chainhash.NewHash(txidHash) if e != nil { t.Fatalf("unable to create sha hash: %v", e) } point := wire.OutPoint{ Hash: *txid, Index: chanPoint.OutputIndex, } ctxt, _ = context.WithTimeout(ctxb, timeout) err = node.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("%s(%d): timeout waiting for "+ "channel(%s) open: %v", nodeNames[i], node.NodeID, point, err) } } } // Now create a _private_ channel directly between Carol and // Alice of 100k. if err := net.ConnectNodes(ctxb, carol, net.Alice); err != nil { t.Fatalf("unable to connect dave to alice: %v", err) } chanOpenUpdate, err := net.OpenChannel(ctxb, carol, net.Alice, chanAmt, 0, true) if err != nil { t.Fatalf("unable to open channel: %v", err) } // One block is enough to make the channel ready for use, since the // nodes have defaultNumConfs=1 set. block := mineBlocks(t, net, 1)[0] chanPointPrivate, err := net.WaitForChannelOpen(ctxb, chanOpenUpdate) if err != nil { t.Fatalf("error while waiting for channel open: %v", err) } txidHash, err = getChanPointFundingTxid(chanPointPrivate) if err != nil { t.Fatalf("unable to get txid: %v", err) } fundingTxID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } assertTxInBlock(t, block, fundingTxID) // The channel should be listed in the peer information returned by // both peers. privateFundPoint := wire.OutPoint{ Hash: *fundingTxID, Index: chanPointPrivate.OutputIndex, } err = net.AssertChannelExists(ctxb, carol, &privateFundPoint) if err != nil { t.Fatalf("unable to assert channel existence: %v", err) } err = net.AssertChannelExists(ctxb, net.Alice, &privateFundPoint) if err != nil { t.Fatalf("unable to assert channel existence: %v", err) } // The channel should be available for payments between Carol and Alice. // We check this by sending payments from Carol to Bob, that // collectively would deplete at least one of Carol's channels. // Create 2 invoices for Bob, each of 70k satoshis. Since each of // Carol's channels is of size 100k, these payments cannot succeed // by only using one of the channels. const numPayments = 2 const paymentAmt = 70000 payReqs := make([]string, numPayments) for i := 0; i < numPayments; i++ { invoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt, } resp, err := net.Bob.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs[i] = resp.PaymentRequest } time.Sleep(time.Millisecond * 50) // Let Carol pay the invoices. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, carol, payReqs, true) if err != nil { t.Fatalf("unable to send payments: %v", err) } // When asserting the amount of satoshis moved, we'll factor in the // default base fee, as we didn't modify the fee structure when // creating the seed nodes in the network. const baseFee = 1 // Bob should have received 140k satoshis from Alice. assertAmountPaid(t, ctxb, "Alice(local) => Bob(remote)", net.Bob, aliceFundPoint, int64(0), 2*paymentAmt) // Alice sent 140k to Bob. assertAmountPaid(t, ctxb, "Alice(local) => Bob(remote)", net.Alice, aliceFundPoint, 2*paymentAmt, int64(0)) // Alice received 70k + fee from Dave. assertAmountPaid(t, ctxb, "Dave(local) => Alice(remote)", net.Alice, daveFundPoint, int64(0), paymentAmt+baseFee) // Dave sent 70k+fee to Alice. assertAmountPaid(t, ctxb, "Dave(local) => Alice(remote)", dave, daveFundPoint, paymentAmt+baseFee, int64(0)) // Dave received 70k+fee of two hops from Carol. assertAmountPaid(t, ctxb, "Carol(local) => Dave(remote)", dave, carolFundPoint, int64(0), paymentAmt+baseFee*2) // Carol sent 70k+fee of two hops to Dave. assertAmountPaid(t, ctxb, "Carol(local) => Dave(remote)", carol, carolFundPoint, paymentAmt+baseFee*2, int64(0)) // Alice received 70k+fee from Carol. assertAmountPaid(t, ctxb, "Carol(local) [private=>] Alice(remote)", net.Alice, privateFundPoint, int64(0), paymentAmt+baseFee) // Carol sent 70k+fee to Alice. assertAmountPaid(t, ctxb, "Carol(local) [private=>] Alice(remote)", carol, privateFundPoint, paymentAmt+baseFee, int64(0)) // Alice should also be able to route payments using this channel, // so send two payments of 60k back to Carol. const paymentAmt60k = 60000 payReqs = make([]string, numPayments) for i := 0; i < numPayments; i++ { invoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt60k, } resp, err := carol.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs[i] = resp.PaymentRequest } time.Sleep(time.Millisecond * 50) // Let Bob pay the invoices. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Alice, payReqs, true) if err != nil { t.Fatalf("unable to send payments: %v", err) } // Finally, we make sure Dave and Bob does not know about the // private channel between Carol and Alice. We first mine // plenty of blocks, such that the channel would have been // announced in case it was public. mineBlocks(t, net, 10) // We create a helper method to check how many edges each of the // nodes know about. Carol and Alice should know about 4, while // Bob and Dave should only know about 3, since one channel is // private. numChannels := func(node *lntest.HarnessNode) int { req := &lnrpc.ChannelGraphRequest{} ctxt, _ := context.WithTimeout(ctxb, timeout) chanGraph, err := node.DescribeGraph(ctxt, req) if err != nil { t.Fatalf("unable go describegraph: %v", err) } return len(chanGraph.Edges) } aliceChans := numChannels(net.Alice) if aliceChans != 4 { t.Fatalf("expected Alice to know 4 edges, had %v", aliceChans) } bobChans := numChannels(net.Bob) if bobChans != 3 { t.Fatalf("expected Bob to know 3 edges, had %v", bobChans) } carolChans := numChannels(carol) if carolChans != 4 { t.Fatalf("expected Carol to know 4 edges, had %v", carolChans) } daveChans := numChannels(dave) if daveChans != 3 { t.Fatalf("expected Dave to know 3 edges, had %v", daveChans) } // Close all channels. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPointAlice, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, dave, chanPointDave, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, carol, chanPointCarol, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, carol, chanPointPrivate, false) // Finally, shutdown the nodes we created for the duration of the tests, // only leaving the two seed nodes (Alice and Bob) within our test // network. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } if err := net.ShutdownNode(dave); err != nil { t.Fatalf("unable to shutdown dave: %v", err) } } func testInvoiceSubscriptions(net *lntest.NetworkHarness, t *harnessTest) { const chanAmt = btcutil.Amount(500000) ctxb := context.Background() timeout := time.Duration(time.Second * 5) // Open a channel with 500k satoshis between Alice and Bob with Alice // being the sole funder of the channel. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, 0) // Next create a new invoice for Bob requesting 1k satoshis. // TODO(roasbeef): make global list of invoices for each node to re-use // and avoid collisions const paymentAmt = 1000 preimage := bytes.Repeat([]byte{byte(90)}, 32) invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } invoiceResp, err := net.Bob.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } // Create a new invoice subscription client for Bob, the notification // should be dispatched shortly below. req := &lnrpc.InvoiceSubscription{} bobInvoiceSubscription, err := net.Bob.SubscribeInvoices(ctxb, req) if err != nil { t.Fatalf("unable to subscribe to bob's invoice updates: %v", err) } quit := make(chan struct{}) updateSent := make(chan struct{}) go func() { invoiceUpdate, err := bobInvoiceSubscription.Recv() select { case <-quit: // Received cancellation return default: } if err != nil { t.Fatalf("unable to recv invoice update: %v", err) } // The invoice update should exactly match the invoice created // above, but should now be settled and have SettleDate if !invoiceUpdate.Settled { t.Fatalf("invoice not settled but should be") } if invoiceUpdate.SettleDate == 0 { t.Fatalf("invoice should have non zero settle date, but doesn't") } if !bytes.Equal(invoiceUpdate.RPreimage, invoice.RPreimage) { t.Fatalf("payment preimages don't match: expected %v, got %v", invoice.RPreimage, invoiceUpdate.RPreimage) } close(updateSent) }() // Wait for the channel to be recognized by both Alice and Bob before // continuing the rest of the test. ctxt, _ = context.WithTimeout(ctxb, timeout) err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { // TODO(roasbeef): will need to make num blocks to advertise a // node param close(quit) t.Fatalf("channel not seen by alice before timeout: %v", err) } // With the assertion above set up, send a payment from Alice to Bob // which should finalize and settle the invoice. sendReq := &lnrpc.SendRequest{ PaymentRequest: invoiceResp.PaymentRequest, } ctxt, _ = context.WithTimeout(ctxb, timeout) resp, err := net.Alice.SendPaymentSync(ctxt, sendReq) if err != nil { close(quit) t.Fatalf("unable to send payment: %v", err) } if resp.PaymentError != "" { close(quit) t.Fatalf("error when attempting recv: %v", resp.PaymentError) } select { case <-time.After(time.Second * 10): close(quit) t.Fatalf("update not sent after 10 seconds") case <-updateSent: // Fall through on success } ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) } // testBasicChannelCreation test multiple channel opening and closing. func testBasicChannelCreation(net *lntest.NetworkHarness, t *harnessTest) { const ( numChannels = 2 timeout = time.Duration(time.Second * 5) amount = maxFundingAmount ) // Open the channel between Alice and Bob, asserting that the // channel has been properly open on-chain. chanPoints := make([]*lnrpc.ChannelPoint, numChannels) for i := 0; i < numChannels; i++ { ctx, _ := context.WithTimeout(context.Background(), timeout) chanPoints[i] = openChannelAndAssert(ctx, t, net, net.Alice, net.Bob, amount, 0) } // Close the channel between Alice and Bob, asserting that the // channel has been properly closed on-chain. for _, chanPoint := range chanPoints { ctx, _ := context.WithTimeout(context.Background(), timeout) closeChannelAndAssert(ctx, t, net, net.Alice, chanPoint, false) } } // testMaxPendingChannels checks that error is returned from remote peer if // max pending channel number was exceeded and that '--maxpendingchannels' flag // exists and works properly. func testMaxPendingChannels(net *lntest.NetworkHarness, t *harnessTest) { maxPendingChannels := defaultMaxPendingChannels + 1 amount := maxFundingAmount timeout := time.Duration(time.Second * 10) ctx, _ := context.WithTimeout(context.Background(), timeout) // Create a new node (Carol) with greater number of max pending // channels. args := []string{ fmt.Sprintf("--maxpendingchannels=%v", maxPendingChannels), } carol, err := net.NewNode(args) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } ctx, _ = context.WithTimeout(context.Background(), timeout) if err := net.ConnectNodes(ctx, net.Alice, carol); err != nil { t.Fatalf("unable to connect carol to alice: %v", err) } ctx, _ = context.WithTimeout(context.Background(), timeout) carolBalance := btcutil.Amount(maxPendingChannels) * amount if err := net.SendCoins(ctx, carolBalance, carol); err != nil { t.Fatalf("unable to send coins to carol: %v", err) } // Send open channel requests without generating new blocks thereby // increasing pool of pending channels. Then check that we can't open // the channel if the number of pending channels exceed max value. openStreams := make([]lnrpc.Lightning_OpenChannelClient, maxPendingChannels) for i := 0; i < maxPendingChannels; i++ { ctx, _ = context.WithTimeout(context.Background(), timeout) stream, err := net.OpenChannel(ctx, net.Alice, carol, amount, 0, false) if err != nil { t.Fatalf("unable to open channel: %v", err) } openStreams[i] = stream } // Carol exhausted available amount of pending channels, next open // channel request should cause ErrorGeneric to be sent back to Alice. ctx, _ = context.WithTimeout(context.Background(), timeout) _, err = net.OpenChannel(ctx, net.Alice, carol, amount, 0, false) if err == nil { t.Fatalf("error wasn't received") } else if grpc.Code(err) != lnwire.ErrMaxPendingChannels.ToGrpcCode() { t.Fatalf("not expected error was received: %v", err) } // For now our channels are in pending state, in order to not interfere // with other tests we should clean up - complete opening of the // channel and then close it. // Mine 6 blocks, then wait for node's to notify us that the channel has // been opened. The funding transactions should be found within the // first newly mined block. 6 blocks make sure the funding transaction // has enough confirmations to be announced publicly. block := mineBlocks(t, net, 6)[0] chanPoints := make([]*lnrpc.ChannelPoint, maxPendingChannels) for i, stream := range openStreams { ctxt, _ := context.WithTimeout(context.Background(), timeout) fundingChanPoint, err := net.WaitForChannelOpen(ctxt, stream) if err != nil { t.Fatalf("error while waiting for channel open: %v", err) } txidHash, err := getChanPointFundingTxid(fundingChanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } fundingTxID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } // Ensure that the funding transaction enters a block, and is // properly advertised by Alice. assertTxInBlock(t, block, fundingTxID) ctxt, _ = context.WithTimeout(context.Background(), timeout) err = net.Alice.WaitForNetworkChannelOpen(ctxt, fundingChanPoint) if err != nil { t.Fatalf("channel not seen on network before "+ "timeout: %v", err) } // The channel should be listed in the peer information // returned by both peers. chanPoint := wire.OutPoint{ Hash: *fundingTxID, Index: fundingChanPoint.OutputIndex, } if err := net.AssertChannelExists(ctx, net.Alice, &chanPoint); err != nil { t.Fatalf("unable to assert channel existence: %v", err) } chanPoints[i] = fundingChanPoint } // Next, close the channel between Alice and Carol, asserting that the // channel has been properly closed on-chain. for _, chanPoint := range chanPoints { ctxt, _ := context.WithTimeout(context.Background(), timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) } // Finally, shutdown the node we created for the duration of the tests, // only leaving the two seed nodes (Alice and Bob) within our test // network. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } func copyFile(dest, src string) error { s, err := os.Open(src) if err != nil { return err } defer s.Close() d, err := os.Create(dest) if err != nil { return err } if _, err := io.Copy(d, s); err != nil { d.Close() return err } return d.Close() } func waitForTxInMempool(miner *rpcclient.Client, timeout time.Duration) (*chainhash.Hash, error) { var txid *chainhash.Hash breakTimeout := time.After(timeout) ticker := time.NewTicker(50 * time.Millisecond) defer ticker.Stop() poll: for { select { case <-breakTimeout: return nil, errors.New("no tx found in mempool") case <-ticker.C: mempool, err := miner.GetRawMempool() if err != nil { return nil, err } if len(mempool) == 0 { continue } txid = mempool[0] break poll } } return txid, nil } // waitForNTxsInMempool polls until finding the desired number of transactions // in the provided miner's mempool. An error is returned if the this number is // not met after the given timeout. func waitForNTxsInMempool(miner *rpcclient.Client, n int, timeout time.Duration) ([]*chainhash.Hash, error) { breakTimeout := time.After(timeout) ticker := time.NewTicker(50 * time.Millisecond) defer ticker.Stop() var err error var mempool []*chainhash.Hash for { select { case <-breakTimeout: return nil, fmt.Errorf("wanted %v, only found %v txs "+ "in mempool", n, len(mempool)) case <-ticker.C: mempool, err = miner.GetRawMempool() if err != nil { return nil, err } if len(mempool) == n { return mempool, nil } } } } // testRevokedCloseRetribution tests that Alice is able carry out // retribution in the event that she fails immediately after detecting Bob's // breach txn in the mempool. func testRevokedCloseRetribution(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() const ( timeout = time.Duration(time.Second * 10) chanAmt = maxFundingAmount paymentAmt = 10000 numInvoices = 6 ) // In order to test Alice's response to an uncooperative channel // closure by Bob, we'll first open up a channel between them with a // 0.5 BTC value. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, 0) // With the channel open, we'll create a few invoices for Bob that // Alice will pay to in order to advance the state of the channel. bobPayReqs := make([]string, numInvoices) for i := 0; i < numInvoices; i++ { preimage := bytes.Repeat([]byte{byte(255 - i)}, 32) invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } resp, err := net.Bob.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } bobPayReqs[i] = resp.PaymentRequest } // As we'll be querying the state of bob's channels frequently we'll // create a closure helper function for the purpose. getBobChanInfo := func() (*lnrpc.ActiveChannel, error) { req := &lnrpc.ListChannelsRequest{} bobChannelInfo, err := net.Bob.ListChannels(ctxb, req) if err != nil { return nil, err } if len(bobChannelInfo.Channels) != 1 { t.Fatalf("bob should only have a single channel, instead he has %v", len(bobChannelInfo.Channels)) } return bobChannelInfo.Channels[0], nil } // Wait for Alice to receive the channel edge from the funding manager. ctxt, _ = context.WithTimeout(ctxb, timeout) err := net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't see the alice->bob channel before "+ "timeout: %v", err) } // Send payments from Alice to Bob using 3 of Bob's payment hashes // generated above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Alice, bobPayReqs[:numInvoices/2], true) if err != nil { t.Fatalf("unable to send payments: %v", err) } // Next query for Bob's channel state, as we sent 3 payments of 10k // satoshis each, Bob should now see his balance as being 30k satoshis. var bobChan *lnrpc.ActiveChannel var predErr error err = lntest.WaitPredicate(func() bool { bChan, err := getBobChanInfo() if err != nil { t.Fatalf("unable to get bob's channel info: %v", err) } if bChan.LocalBalance != 30000 { predErr = fmt.Errorf("bob's balance is incorrect, "+ "got %v, expected %v", bChan.LocalBalance, 30000) return false } bobChan = bChan return true }, time.Second*15) if err != nil { t.Fatalf("%v", predErr) } // Grab Bob's current commitment height (update number), we'll later // revert him to this state after additional updates to force him to // broadcast this soon to be revoked state. bobStateNumPreCopy := bobChan.NumUpdates // Create a temporary file to house Bob's database state at this // particular point in history. bobTempDbPath, err := ioutil.TempDir("", "bob-past-state") if err != nil { t.Fatalf("unable to create temp db folder: %v", err) } bobTempDbFile := filepath.Join(bobTempDbPath, "channel.db") defer os.Remove(bobTempDbPath) // With the temporary file created, copy Bob's current state into the // temporary file we created above. Later after more updates, we'll // restore this state. if err := copyFile(bobTempDbFile, net.Bob.DBPath()); err != nil { t.Fatalf("unable to copy database files: %v", err) } // Finally, send payments from Alice to Bob, consuming Bob's remaining // payment hashes. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Alice, bobPayReqs[numInvoices/2:], true) if err != nil { t.Fatalf("unable to send payments: %v", err) } bobChan, err = getBobChanInfo() if err != nil { t.Fatalf("unable to get bob chan info: %v", err) } // Now we shutdown Bob, copying over the his temporary database state // which has the *prior* channel state over his current most up to date // state. With this, we essentially force Bob to travel back in time // within the channel's history. if err = net.RestartNode(net.Bob, func() error { return os.Rename(bobTempDbFile, net.Bob.DBPath()) }); err != nil { t.Fatalf("unable to restart node: %v", err) } // Now query for Bob's channel state, it should show that he's at a // state number in the past, not the *latest* state. bobChan, err = getBobChanInfo() if err != nil { t.Fatalf("unable to get bob chan info: %v", err) } if bobChan.NumUpdates != bobStateNumPreCopy { t.Fatalf("db copy failed: %v", bobChan.NumUpdates) } // Now force Bob to execute a *force* channel closure by unilaterally // broadcasting his current channel state. This is actually the // commitment transaction of a prior *revoked* state, so he'll soon // feel the wrath of Alice's retribution. force := true closeUpdates, _, err := net.CloseChannel(ctxb, net.Bob, chanPoint, force) if err != nil { t.Fatalf("unable to close channel: %v", err) } // Wait for Bob's breach transaction to show up in the mempool to ensure // that Alice's node has started waiting for confirmations. _, err = waitForTxInMempool(net.Miner.Node, 5*time.Second) if err != nil { t.Fatalf("unable to find Bob's breach tx in mempool: %v", err) } // Here, Alice sees Bob's breach transaction in the mempool, but is waiting // for it to confirm before continuing her retribution. We restart Alice to // ensure that she is persisting her retribution state and continues // watching for the breach transaction to confirm even after her node // restarts. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("unable to restart Alice's node: %v", err) } // Finally, generate a single block, wait for the final close status // update, then ensure that the closing transaction was included in the // block. block := mineBlocks(t, net, 1)[0] breachTXID, err := net.WaitForChannelClose(ctxb, closeUpdates) if err != nil { t.Fatalf("error while waiting for channel close: %v", err) } assertTxInBlock(t, block, breachTXID) // Query the mempool for Alice's justice transaction, this should be // broadcast as Bob's contract breaching transaction gets confirmed // above. justiceTXID, err := waitForTxInMempool(net.Miner.Node, 5*time.Second) if err != nil { t.Fatalf("unable to find Alice's justice tx in mempool: %v", err) } time.Sleep(100 * time.Millisecond) // Query for the mempool transaction found above. Then assert that all // the inputs of this transaction are spending outputs generated by // Bob's breach transaction above. justiceTx, err := net.Miner.Node.GetRawTransaction(justiceTXID) if err != nil { t.Fatalf("unable to query for justice tx: %v", err) } for _, txIn := range justiceTx.MsgTx().TxIn { if !bytes.Equal(txIn.PreviousOutPoint.Hash[:], breachTXID[:]) { t.Fatalf("justice tx not spending commitment utxo "+ "instead is: %v", txIn.PreviousOutPoint) } } // We restart Alice here to ensure that she persists her retribution state // and successfully continues exacting retribution after restarting. At // this point, Alice has broadcast the justice transaction, but it hasn't // been confirmed yet; when Alice restarts, she should start waiting for // the justice transaction to confirm again. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("unable to restart Alice's node: %v", err) } // Now mine a block, this transaction should include Alice's justice // transaction which was just accepted into the mempool. block = mineBlocks(t, net, 1)[0] // The block should have exactly *two* transactions, one of which is // the justice transaction. if len(block.Transactions) != 2 { t.Fatalf("transaction wasn't mined") } justiceSha := block.Transactions[1].TxHash() if !bytes.Equal(justiceTx.Hash()[:], justiceSha[:]) { t.Fatalf("justice tx wasn't mined") } assertNodeNumChannels(t, ctxb, net.Alice, 0) } // testRevokedCloseRetributionZeroValueRemoteOutput tests that Alice is able // carry out retribution in the event that she fails in state where the remote // commitment output has zero-value. func testRevokedCloseRetributionZeroValueRemoteOutput(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() const ( timeout = time.Duration(time.Second * 10) chanAmt = maxFundingAmount paymentAmt = 10000 numInvoices = 6 ) // Since we'd like to test some multi-hop failure scenarios, we'll // introduce another node into our test network: Carol. carol, err := net.NewNode([]string{"--debughtlc", "--hodlhtlc"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } // We must let Alice have an open channel before she can send a node // announcement, so we open a channel with Carol, if err := net.ConnectNodes(ctxb, net.Alice, carol); err != nil { t.Fatalf("unable to connect alice to carol: %v", err) } // In order to test Alice's response to an uncooperative channel // closure by Carol, we'll first open up a channel between them with a // 0.5 BTC value. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, carol, chanAmt, 0) // With the channel open, we'll create a few invoices for Carol that // Alice will pay to in order to advance the state of the channel. carolPayReqs := make([]string, numInvoices) for i := 0; i < numInvoices; i++ { preimage := bytes.Repeat([]byte{byte(192 - i)}, 32) invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } resp, err := carol.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } carolPayReqs[i] = resp.PaymentRequest } // As we'll be querying the state of Carols's channels frequently we'll // create a closure helper function for the purpose. getCarolChanInfo := func() (*lnrpc.ActiveChannel, error) { req := &lnrpc.ListChannelsRequest{} carolChannelInfo, err := carol.ListChannels(ctxb, req) if err != nil { return nil, err } if len(carolChannelInfo.Channels) != 1 { t.Fatalf("carol should only have a single channel, "+ "instead he has %v", len(carolChannelInfo.Channels)) } return carolChannelInfo.Channels[0], nil } // Wait for Alice to receive the channel edge from the funding manager. ctxt, _ = context.WithTimeout(ctxb, timeout) err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't see the alice->carol channel before "+ "timeout: %v", err) } // Next query for Carol's channel state, as we sent 0 payments, Carol // should now see her balance as being 0 satoshis. carolChan, err := getCarolChanInfo() if err != nil { t.Fatalf("unable to get carol's channel info: %v", err) } if carolChan.LocalBalance != 0 { t.Fatalf("carol's balance is incorrect, got %v, expected %v", carolChan.LocalBalance, 0) } // Grab Carol's current commitment height (update number), we'll later // revert her to this state after additional updates to force him to // broadcast this soon to be revoked state. carolStateNumPreCopy := carolChan.NumUpdates // Create a temporary file to house Carol's database state at this // particular point in history. carolTempDbPath, err := ioutil.TempDir("", "carol-past-state") if err != nil { t.Fatalf("unable to create temp db folder: %v", err) } carolTempDbFile := filepath.Join(carolTempDbPath, "channel.db") defer os.Remove(carolTempDbPath) // With the temporary file created, copy Carol's current state into the // temporary file we created above. Later after more updates, we'll // restore this state. if err := copyFile(carolTempDbFile, carol.DBPath()); err != nil { t.Fatalf("unable to copy database files: %v", err) } // Finally, send payments from Alice to Carol, consuming Carol's remaining // payment hashes. err = completePaymentRequests(ctxb, net.Alice, carolPayReqs, false) if err != nil { t.Fatalf("unable to send payments: %v", err) } carolChan, err = getCarolChanInfo() if err != nil { t.Fatalf("unable to get carol chan info: %v", err) } // Now we shutdown Carol, copying over the his temporary database state // which has the *prior* channel state over his current most up to date // state. With this, we essentially force Carol to travel back in time // within the channel's history. if err = net.RestartNode(carol, func() error { return os.Rename(carolTempDbFile, carol.DBPath()) }); err != nil { t.Fatalf("unable to restart node: %v", err) } // Now query for Carol's channel state, it should show that he's at a // state number in the past, not the *latest* state. carolChan, err = getCarolChanInfo() if err != nil { t.Fatalf("unable to get carol chan info: %v", err) } if carolChan.NumUpdates != carolStateNumPreCopy { t.Fatalf("db copy failed: %v", carolChan.NumUpdates) } // Now force Carol to execute a *force* channel closure by unilaterally // broadcasting his current channel state. This is actually the // commitment transaction of a prior *revoked* state, so he'll soon // feel the wrath of Alice's retribution. force := true closeUpdates, _, err := net.CloseChannel(ctxb, carol, chanPoint, force) if err != nil { t.Fatalf("unable to close channel: %v", err) } // Finally, generate a single block, wait for the final close status // update, then ensure that the closing transaction was included in the // block. block := mineBlocks(t, net, 1)[0] // Here, Alice receives a confirmation of Carol's breach transaction. // We restart Alice to ensure that she is persisting her retribution // state and continues exacting justice after her node restarts. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("unable to stop Alice's node: %v", err) } breachTXID, err := net.WaitForChannelClose(ctxb, closeUpdates) if err != nil { t.Fatalf("error while waiting for channel close: %v", err) } assertTxInBlock(t, block, breachTXID) // Query the mempool for Alice's justice transaction, this should be // broadcast as Carol's contract breaching transaction gets confirmed // above. justiceTXID, err := waitForTxInMempool(net.Miner.Node, 15*time.Second) if err != nil { t.Fatalf("unable to find Alice's justice tx in mempool: %v", err) } time.Sleep(100 * time.Millisecond) // Query for the mempool transaction found above. Then assert that all // the inputs of this transaction are spending outputs generated by // Carol's breach transaction above. justiceTx, err := net.Miner.Node.GetRawTransaction(justiceTXID) if err != nil { t.Fatalf("unable to query for justice tx: %v", err) } for _, txIn := range justiceTx.MsgTx().TxIn { if !bytes.Equal(txIn.PreviousOutPoint.Hash[:], breachTXID[:]) { t.Fatalf("justice tx not spending commitment utxo "+ "instead is: %v", txIn.PreviousOutPoint) } } // We restart Alice here to ensure that she persists her retribution state // and successfully continues exacting retribution after restarting. At // this point, Alice has broadcast the justice transaction, but it hasn't // been confirmed yet; when Alice restarts, she should start waiting for // the justice transaction to confirm again. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("unable to restart Alice's node: %v", err) } // Now mine a block, this transaction should include Alice's justice // transaction which was just accepted into the mempool. block = mineBlocks(t, net, 1)[0] // The block should have exactly *two* transactions, one of which is // the justice transaction. if len(block.Transactions) != 2 { t.Fatalf("transaction wasn't mined") } justiceSha := block.Transactions[1].TxHash() if !bytes.Equal(justiceTx.Hash()[:], justiceSha[:]) { t.Fatalf("justice tx wasn't mined") } assertNodeNumChannels(t, ctxb, net.Alice, 0) } // testRevokedCloseRetributionRemoteHodl tests that Alice properly responds to a // channel breach made by the remote party, specifically in the case that the // remote party breaches before settling extended HTLCs. func testRevokedCloseRetributionRemoteHodl(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() const ( timeout = time.Duration(time.Second * 10) chanAmt = maxFundingAmount pushAmt = 20000 paymentAmt = 10000 numInvoices = 6 ) // Since this test will result in the counterparty being left in a weird // state, we will introduce another node into our test network: Carol. carol, err := net.NewNode([]string{"--debughtlc", "--hodlhtlc"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } // We must let Alice communicate with Carol before they are able to // open channel, so we connect Alice and Carol, if err := net.ConnectNodes(ctxb, net.Alice, carol); err != nil { t.Fatalf("unable to connect alice to carol: %v", err) } // In order to test Alice's response to an uncooperative channel // closure by Carol, we'll first open up a channel between them with a // maxFundingAmount (2^24) satoshis value. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, carol, chanAmt, pushAmt) // With the channel open, we'll create a few invoices for Carol that // Alice will pay to in order to advance the state of the channel. carolPayReqs := make([]string, numInvoices) for i := 0; i < numInvoices; i++ { preimage := bytes.Repeat([]byte{byte(192 - i)}, 32) invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } resp, err := carol.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } carolPayReqs[i] = resp.PaymentRequest } // As we'll be querying the state of Carol's channels frequently we'll // create a closure helper function for the purpose. getCarolChanInfo := func() (*lnrpc.ActiveChannel, error) { req := &lnrpc.ListChannelsRequest{} carolChannelInfo, err := carol.ListChannels(ctxb, req) if err != nil { return nil, err } if len(carolChannelInfo.Channels) != 1 { t.Fatalf("carol should only have a single channel, instead he has %v", len(carolChannelInfo.Channels)) } return carolChannelInfo.Channels[0], nil } // We'll introduce a closure to validate that Carol's current balance // matches the given expected amount. checkCarolBalance := func(expectedAmt int64) { carolChan, err := getCarolChanInfo() if err != nil { t.Fatalf("unable to get carol's channel info: %v", err) } if carolChan.LocalBalance != expectedAmt { t.Fatalf("carol's balance is incorrect, "+ "got %v, expected %v", carolChan.LocalBalance, expectedAmt) } } // We'll introduce another closure to validate that Carol's current // number of updates is at least as large as the provided minimum // number. checkCarolNumUpdatesAtLeast := func(minimum uint64) { carolChan, err := getCarolChanInfo() if err != nil { t.Fatalf("unable to get carol's channel info: %v", err) } if carolChan.NumUpdates < minimum { t.Fatalf("carol's numupdates is incorrect, want %v "+ "to be at least %v", carolChan.NumUpdates, minimum) } } // Wait for Alice to receive the channel edge from the funding manager. ctxt, _ = context.WithTimeout(ctxb, timeout) err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't see the alice->carol channel before "+ "timeout: %v", err) } // Ensure that carol's balance starts with the amount we pushed to her. checkCarolBalance(pushAmt) // Send payments from Alice to Carol using 3 of Carol's payment hashes // generated above. err = completePaymentRequests(ctxb, net.Alice, carolPayReqs[:numInvoices/2], false) if err != nil { t.Fatalf("unable to send payments: %v", err) } // Next query for Carol's channel state, as we sent 3 payments of 10k // satoshis each, however Carol should now see her balance as being // equal to the push amount in satoshis since she has not settled. carolChan, err := getCarolChanInfo() if err != nil { t.Fatalf("unable to get carol's channel info: %v", err) } // Grab Carol's current commitment height (update number), we'll later // revert her to this state after additional updates to force her to // broadcast this soon to be revoked state. carolStateNumPreCopy := carolChan.NumUpdates // Ensure that carol's balance still reflects the original amount we // pushed to her. checkCarolBalance(pushAmt) // Since Carol has not settled, she should only see at least one update // to her channel. checkCarolNumUpdatesAtLeast(1) // Create a temporary file to house Carol's database state at this // particular point in history. carolTempDbPath, err := ioutil.TempDir("", "carol-past-state") if err != nil { t.Fatalf("unable to create temp db folder: %v", err) } carolTempDbFile := filepath.Join(carolTempDbPath, "channel.db") defer os.Remove(carolTempDbPath) // With the temporary file created, copy Carol's current state into the // temporary file we created above. Later after more updates, we'll // restore this state. if err := copyFile(carolTempDbFile, carol.DBPath()); err != nil { t.Fatalf("unable to copy database files: %v", err) } // Finally, send payments from Alice to Carol, consuming Carol's remaining // payment hashes. err = completePaymentRequests(ctxb, net.Alice, carolPayReqs[numInvoices/2:], false) if err != nil { t.Fatalf("unable to send payments: %v", err) } // Ensure that carol's balance still shows the amount we originally // pushed to her, and that at least one more update has occurred. time.Sleep(500 * time.Millisecond) checkCarolBalance(pushAmt) checkCarolNumUpdatesAtLeast(carolStateNumPreCopy + 1) // Now we shutdown Carol, copying over the her temporary database state // which has the *prior* channel state over her current most up to date // state. With this, we essentially force Carol to travel back in time // within the channel's history. if err = net.RestartNode(carol, func() error { return os.Rename(carolTempDbFile, carol.DBPath()) }); err != nil { t.Fatalf("unable to restart node: %v", err) } time.Sleep(200 * time.Millisecond) // Ensure that Carol's view of the channel is consistent with the // state of the channel just before it was snapshotted. checkCarolBalance(pushAmt) checkCarolNumUpdatesAtLeast(1) // Now query for Carol's channel state, it should show that she's at a // state number in the past, *not* the latest state. carolChan, err = getCarolChanInfo() if err != nil { t.Fatalf("unable to get carol chan info: %v", err) } if carolChan.NumUpdates != carolStateNumPreCopy { t.Fatalf("db copy failed: %v", carolChan.NumUpdates) } // Now force Carol to execute a *force* channel closure by unilaterally // broadcasting her current channel state. This is actually the // commitment transaction of a prior *revoked* state, so she'll soon // feel the wrath of Alice's retribution. force := true closeUpdates, _, err := net.CloseChannel(ctxb, carol, chanPoint, force) if err != nil { t.Fatalf("unable to close channel: %v", err) } // Query the mempool for Alice's justice transaction, this should be // broadcast as Carol's contract breaching transaction gets confirmed // above. _, err = waitForTxInMempool(net.Miner.Node, 5*time.Second) if err != nil { t.Fatalf("unable to find Alice's justice tx in mempool: %v", err) } time.Sleep(200 * time.Millisecond) // Generate a single block to mine the breach transaction. block := mineBlocks(t, net, 1)[0] // Wait so Alice receives a confirmation of Carol's breach transaction. time.Sleep(200 * time.Millisecond) // We restart Alice to ensure that she is persisting her retribution // state and continues exacting justice after her node restarts. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("unable to stop Alice's node: %v", err) } // Finally, Wait for the final close status update, then ensure that the // closing transaction was included in the block. breachTXID, err := net.WaitForChannelClose(ctxb, closeUpdates) if err != nil { t.Fatalf("error while waiting for channel close: %v", err) } assertTxInBlock(t, block, breachTXID) // Query the mempool for Alice's justice transaction, this should be // broadcast as Carol's contract breaching transaction gets confirmed // above. justiceTXID, err := waitForTxInMempool(net.Miner.Node, 5*time.Second) if err != nil { t.Fatalf("unable to find Alice's justice tx in mempool: %v", err) } time.Sleep(100 * time.Millisecond) // We restart Alice here to ensure that she persists her retribution state // and successfully continues exacting retribution after restarting. At // this point, Alice has broadcast the justice transaction, but it hasn't // been confirmed yet; when Alice restarts, she should start waiting for // the justice transaction to confirm again. if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("unable to restart Alice's node: %v", err) } // Query for the mempool transaction found above. Then assert that (1) // the justice tx has the appropriate number of inputs, and (2) all // the inputs of this transaction are spending outputs generated by // Carol's breach transaction above. justiceTx, err := net.Miner.Node.GetRawTransaction(justiceTXID) if err != nil { t.Fatalf("unable to query for justice tx: %v", err) } exNumInputs := 2 + numInvoices/2 if len(justiceTx.MsgTx().TxIn) != exNumInputs { t.Fatalf("justice tx should have exactly 2 commitment inputs"+ "and %v htlc inputs, expected %v in total, got %v", numInvoices/2, exNumInputs, len(justiceTx.MsgTx().TxIn)) } // Now mine a block, this transaction should include Alice's justice // transaction which was just accepted into the mempool. block = mineBlocks(t, net, 1)[0] // The block should have exactly *two* transactions, one of which is // the justice transaction. if len(block.Transactions) != 2 { t.Fatalf("transaction wasn't mined") } justiceSha := block.Transactions[1].TxHash() if !bytes.Equal(justiceTx.Hash()[:], justiceSha[:]) { t.Fatalf("justice tx wasn't mined") } assertNodeNumChannels(t, ctxb, net.Alice, 0) } // assertNodeNumChannels polls the provided node's list channels rpc until it // reaches the desired number of total channels. func assertNodeNumChannels(t *harnessTest, ctxb context.Context, node *lntest.HarnessNode, numChannels int) { // Poll alice for her list of channels. req := &lnrpc.ListChannelsRequest{} var predErr error pred := func() bool { chanInfo, err := node.ListChannels(ctxb, req) if err != nil { predErr = fmt.Errorf("unable to query for alice's "+ "channels: %v", err) return false } // Return true if the query returned the expected number of // channels. return len(chanInfo.Channels) == numChannels } if err := lntest.WaitPredicate(pred, time.Second*15); err != nil { t.Fatalf("node has incorrect number of channels: %v", predErr) } } func testHtlcErrorPropagation(net *lntest.NetworkHarness, t *harnessTest) { // In this test we wish to exercise the daemon's correct parsing, // handling, and propagation of errors that occur while processing a // multi-hop payment. timeout := time.Duration(time.Second * 15) ctxb := context.Background() const chanAmt = maxFundingAmount // First establish a channel with a capacity of 0.5 BTC between Alice // and Bob. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPointAlice := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, 0) ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.Alice.WaitForNetworkChannelOpen(ctxt, chanPointAlice); err != nil { t.Fatalf("channel not seen by alice before timeout: %v", err) } commitFee := calcStaticFee(0) assertBaseBalance := func() { balReq := &lnrpc.ChannelBalanceRequest{} aliceBal, err := net.Alice.ChannelBalance(ctxb, balReq) if err != nil { t.Fatalf("unable to get channel balance: %v", err) } bobBal, err := net.Bob.ChannelBalance(ctxb, balReq) if err != nil { t.Fatalf("unable to get channel balance: %v", err) } if aliceBal.Balance != int64(chanAmt-commitFee) { t.Fatalf("alice has an incorrect balance: expected %v got %v", int64(chanAmt-commitFee), aliceBal) } if bobBal.Balance != int64(chanAmt-commitFee) { t.Fatalf("bob has an incorrect balance: expected %v got %v", int64(chanAmt-commitFee), bobBal) } } // Since we'd like to test some multi-hop failure scenarios, we'll // introduce another node into our test network: Carol. carol, err := net.NewNode(nil) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } // Next, we'll create a connection from Bob to Carol, and open a // channel between them so we have the topology: Alice -> Bob -> Carol. // The channel created will be of lower capacity that the one created // above. if err := net.ConnectNodes(ctxb, net.Bob, carol); err != nil { t.Fatalf("unable to connect bob to carol: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) const bobChanAmt = maxFundingAmount chanPointBob := openChannelAndAssert(ctxt, t, net, net.Bob, carol, chanAmt, 0) // Ensure that Alice has Carol in her routing table before proceeding. nodeInfoReq := &lnrpc.NodeInfoRequest{ PubKey: carol.PubKeyStr, } checkTableTimeout := time.After(time.Second * 10) checkTableTicker := time.NewTicker(100 * time.Millisecond) defer checkTableTicker.Stop() out: // TODO(roasbeef): make into async hook for node announcements for { select { case <-checkTableTicker.C: _, err := net.Alice.GetNodeInfo(ctxb, nodeInfoReq) if err != nil && strings.Contains(err.Error(), "unable to find") { continue } break out case <-checkTableTimeout: t.Fatalf("carol's node announcement didn't propagate within " + "the timeout period") } } // With the channels, open we can now start to test our multi-hop error // scenarios. First, we'll generate an invoice from carol that we'll // use to test some error cases. const payAmt = 10000 invoiceReq := &lnrpc.Invoice{ Memo: "kek99", Value: payAmt, } carolInvoice, err := carol.AddInvoice(ctxb, invoiceReq) if err != nil { t.Fatalf("unable to generate carol invoice: %v", err) } // Before we send the payment, ensure that the announcement of the new // channel has been processed by Alice. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.Alice.WaitForNetworkChannelOpen(ctxt, chanPointBob); err != nil { t.Fatalf("channel not seen by alice before timeout: %v", err) } // For the first scenario, we'll test the cancellation of an HTLC with // an unknown payment hash. // TODO(roasbeef): return failure response rather than failing entire // stream on payment error. ctxt, _ = context.WithTimeout(ctxb, timeout) sendReq := &lnrpc.SendRequest{ PaymentHashString: hex.EncodeToString(bytes.Repeat([]byte("Z"), 32)), DestString: hex.EncodeToString(carol.PubKey[:]), Amt: payAmt, } resp, err := net.Alice.SendPaymentSync(ctxt, sendReq) if err != nil { t.Fatalf("unable to send payment: %v", err) } // The payment should have resulted in an error since we sent it with the // wrong payment hash. if resp.PaymentError == "" { t.Fatalf("payment should have been rejected due to invalid " + "payment hash") } expectedErrorCode := lnwire.CodeUnknownPaymentHash.String() if !strings.Contains(resp.PaymentError, expectedErrorCode) { // TODO(roasbeef): make into proper gRPC error code t.Fatalf("payment should have failed due to unknown payment hash, "+ "instead failed due to: %v", resp.PaymentError) } // The balances of all parties should be the same as initially since // the HTLC was cancelled. assertBaseBalance() // Next, we'll test the case of a recognized payHash but, an incorrect // value on the extended HTLC. sendReq = &lnrpc.SendRequest{ PaymentHashString: hex.EncodeToString(carolInvoice.RHash), DestString: hex.EncodeToString(carol.PubKey[:]), Amt: 1000, // 10k satoshis are expected. } ctxt, _ = context.WithTimeout(ctxb, timeout) resp, err = net.Alice.SendPaymentSync(ctxt, sendReq) if err != nil { t.Fatalf("unable to send payment: %v", err) } // The payment should fail with an error since we sent 1k satoshis isn't of // 10k as was requested. if resp.PaymentError == "" { t.Fatalf("payment should have been rejected due to wrong " + "HTLC amount") } expectedErrorCode = lnwire.CodeIncorrectPaymentAmount.String() if !strings.Contains(resp.PaymentError, expectedErrorCode) { t.Fatalf("payment should have failed due to wrong amount, "+ "instead failed due to: %v", resp.PaymentError) } // The balances of all parties should be the same as initially since // the HTLC was cancelled. assertBaseBalance() // Next we'll test an error that occurs mid-route due to an outgoing // link having insufficient capacity. In order to do so, we'll first // need to unbalance the link connecting Bob<->Carol. bobPayStream, err := net.Bob.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream: %v", err) } // To do so, we'll push most of the funds in the channel over to // Alice's side, leaving on 10k satoshis of available balance for bob. // There's a max payment amount, so we'll have to do this // incrementally. chanReserve := int64(chanAmt / 100) amtToSend := int64(chanAmt) - chanReserve - 20000 amtSent := int64(0) for amtSent != amtToSend { // We'll send in chunks of the max payment amount. If we're // about to send too much, then we'll only send the amount // remaining. toSend := int64(maxPaymentMSat.ToSatoshis()) if toSend+amtSent > amtToSend { toSend = amtToSend - amtSent } invoiceReq = &lnrpc.Invoice{ Value: toSend, } carolInvoice2, err := carol.AddInvoice(ctxb, invoiceReq) if err != nil { t.Fatalf("unable to generate carol invoice: %v", err) } if err := bobPayStream.Send(&lnrpc.SendRequest{ PaymentRequest: carolInvoice2.PaymentRequest, }); err != nil { t.Fatalf("unable to send payment: %v", err) } if resp, err := bobPayStream.Recv(); err != nil { t.Fatalf("payment stream has been closed: %v", err) } else if resp.PaymentError != "" { t.Fatalf("bob's payment failed: %v", resp.PaymentError) } amtSent += toSend } // At this point, Alice has 50mil satoshis on her side of the channel, // but Bob only has 10k available on his side of the channel. So a // payment from Alice to Carol worth 100k satoshis should fail. invoiceReq = &lnrpc.Invoice{ Value: 100000, } carolInvoice3, err := carol.AddInvoice(ctxb, invoiceReq) if err != nil { t.Fatalf("unable to generate carol invoice: %v", err) } sendReq = &lnrpc.SendRequest{ PaymentRequest: carolInvoice3.PaymentRequest, } ctxt, _ = context.WithTimeout(ctxb, timeout) resp, err = net.Alice.SendPaymentSync(ctxt, sendReq) if err != nil { t.Fatalf("unable to send payment: %v", err) } if resp.PaymentError == "" { t.Fatalf("payment should fail due to insufficient "+ "capacity: %v", err) } else if !strings.Contains(resp.PaymentError, lnwire.CodeTemporaryChannelFailure.String()) { t.Fatalf("payment should fail due to insufficient capacity, "+ "instead: %v", resp.PaymentError) } // For our final test, we'll ensure that if a target link isn't // available for what ever reason then the payment fails accordingly. // // We'll attempt to complete the original invoice we created with Carol // above, but before we do so, Carol will go offline, resulting in a // failed payment. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } // TODO(roasbeef): mission control time.Sleep(time.Second * 5) sendReq = &lnrpc.SendRequest{ PaymentRequest: carolInvoice.PaymentRequest, } ctxt, _ = context.WithTimeout(ctxb, timeout) resp, err = net.Alice.SendPaymentSync(ctxt, sendReq) if err != nil { t.Fatalf("unable to send payment: %v", err) } if resp.PaymentError == "" { t.Fatalf("payment should have failed") } expectedErrorCode = lnwire.CodeUnknownNextPeer.String() if !strings.Contains(resp.PaymentError, expectedErrorCode) { t.Fatalf("payment should fail due to unknown hop, instead: %v", resp.PaymentError) } // Finally, immediately close the channel. This function will also // block until the channel is closed and will additionally assert the // relevant channel closing post conditions. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPointAlice, false) // Force close Bob's final channel, also mining enough blocks to // trigger a sweep of the funds by the utxoNursery. // TODO(roasbeef): use config value for default CSV here. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Bob, chanPointBob, true) if _, err := net.Miner.Node.Generate(5); err != nil { t.Fatalf("unable to generate blocks: %v", err) } } // subscribeGraphNotifications subscribes to channel graph updates and launches // a goroutine that forwards these to the returned channel. func subscribeGraphNotifications(t *harnessTest, ctxb context.Context, node *lntest.HarnessNode) (chan *lnrpc.GraphTopologyUpdate, chan struct{}) { // We'll first start by establishing a notification client which will // send us notifications upon detected changes in the channel graph. req := &lnrpc.GraphTopologySubscription{} topologyClient, err := node.SubscribeChannelGraph(ctxb, req) if err != nil { t.Fatalf("unable to create topology client: %v", err) } // We'll launch a goroutine that will be responsible for proxying all // notifications recv'd from the client into the channel below. quit := make(chan struct{}) graphUpdates := make(chan *lnrpc.GraphTopologyUpdate, 20) go func() { for { select { case <-quit: return default: graphUpdate, err := topologyClient.Recv() select { case <-quit: return default: } if err == io.EOF { return } else if err != nil { t.Fatalf("unable to recv graph update: %v", err) } select { case graphUpdates <- graphUpdate: case <-quit: return } } } }() return graphUpdates, quit } func testGraphTopologyNotifications(net *lntest.NetworkHarness, t *harnessTest) { const chanAmt = maxFundingAmount timeout := time.Duration(time.Second * 5) ctxb := context.Background() // Let Alice subscribe to graph notifications. graphUpdates, quit := subscribeGraphNotifications(t, ctxb, net.Alice) // Open a new channel between Alice and Bob. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, 0) // The channel opening above should have triggered a few notifications // sent to the notification client. We'll expect two channel updates, // and two node announcements. const numExpectedUpdates = 4 for i := 0; i < numExpectedUpdates; i++ { select { // Ensure that a new update for both created edges is properly // dispatched to our registered client. case graphUpdate := <-graphUpdates: if len(graphUpdate.ChannelUpdates) > 0 { chanUpdate := graphUpdate.ChannelUpdates[0] if chanUpdate.Capacity != int64(chanAmt) { t.Fatalf("channel capacities mismatch:"+ " expected %v, got %v", chanAmt, btcutil.Amount(chanUpdate.Capacity)) } switch chanUpdate.AdvertisingNode { case net.Alice.PubKeyStr: case net.Bob.PubKeyStr: default: t.Fatalf("unknown advertising node: %v", chanUpdate.AdvertisingNode) } switch chanUpdate.ConnectingNode { case net.Alice.PubKeyStr: case net.Bob.PubKeyStr: default: t.Fatalf("unknown connecting node: %v", chanUpdate.ConnectingNode) } } if len(graphUpdate.NodeUpdates) > 0 { nodeUpdate := graphUpdate.NodeUpdates[0] switch nodeUpdate.IdentityKey { case net.Alice.PubKeyStr: case net.Bob.PubKeyStr: default: t.Fatalf("unknown node: %v", nodeUpdate.IdentityKey) } } case <-time.After(time.Second * 10): t.Fatalf("timeout waiting for graph notification %v", i) } } _, blockHeight, err := net.Miner.Node.GetBestBlock() if err != nil { t.Fatalf("unable to get current blockheight %v", err) } // Now we'll test that updates are properly sent after channels are closed // within the network. ctxt, _ = context.WithTimeout(context.Background(), timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) // Similar to the case above, we should receive another notification // detailing the channel closure. select { case graphUpdate := <-graphUpdates: if len(graphUpdate.ClosedChans) != 1 { t.Fatalf("expected a single update, instead "+ "have %v", len(graphUpdate.ClosedChans)) } closedChan := graphUpdate.ClosedChans[0] if closedChan.ClosedHeight != uint32(blockHeight+1) { t.Fatalf("close heights of channel mismatch: expected "+ "%v, got %v", blockHeight+1, closedChan.ClosedHeight) } chanPointTxid, err := getChanPointFundingTxid(chanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } closedChanTxid, err := getChanPointFundingTxid(closedChan.ChanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } if !bytes.Equal(closedChanTxid, chanPointTxid) { t.Fatalf("channel point hash mismatch: expected %v, "+ "got %v", chanPointTxid, closedChanTxid) } if closedChan.ChanPoint.OutputIndex != chanPoint.OutputIndex { t.Fatalf("output index mismatch: expected %v, got %v", chanPoint.OutputIndex, closedChan.ChanPoint) } case <-time.After(time.Second * 10): t.Fatalf("notification for channel closure not " + "sent") } // For the final portion of the test, we'll ensure that once a new node // appears in the network, the proper notification is dispatched. Note // that a node that does not have any channels open is ignored, so first // we disconnect Alice and Bob, open a channel between Bob and Carol, // and finally connect Alice to Bob again. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.DisconnectNodes(ctxt, net.Alice, net.Bob); err != nil { t.Fatalf("unable to disconnect alice and bob: %v", err) } carol, err := net.NewNode(nil) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, net.Bob, carol); err != nil { t.Fatalf("unable to connect bob to carol: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPoint = openChannelAndAssert(ctxt, t, net, net.Bob, carol, chanAmt, 0) // Reconnect Alice and Bob. This should result in the nodes syncing up // their respective graph state, with the new addition being the // existence of Carol in the graph, and also the channel between Bob // and Carol. Note that we will also receive a node announcement from // Bob, since a node will update its node announcement after a new // channel is opened. if err := net.ConnectNodes(ctxb, net.Alice, net.Bob); err != nil { t.Fatalf("unable to connect alice to bob: %v", err) } // We should receive an update advertising the newly connected node, // Bob's new node announcement, and the channel between Bob and Carol. for i := 0; i < 3; i++ { select { case graphUpdate := <-graphUpdates: if len(graphUpdate.NodeUpdates) > 0 { nodeUpdate := graphUpdate.NodeUpdates[0] switch nodeUpdate.IdentityKey { case carol.PubKeyStr: case net.Bob.PubKeyStr: default: t.Fatalf("unknown node update pubey: %v", nodeUpdate.IdentityKey) } } if len(graphUpdate.ChannelUpdates) > 0 { chanUpdate := graphUpdate.ChannelUpdates[0] if chanUpdate.Capacity != int64(chanAmt) { t.Fatalf("channel capacities mismatch:"+ " expected %v, got %v", chanAmt, btcutil.Amount(chanUpdate.Capacity)) } switch chanUpdate.AdvertisingNode { case carol.PubKeyStr: case net.Bob.PubKeyStr: default: t.Fatalf("unknown advertising node: %v", chanUpdate.AdvertisingNode) } switch chanUpdate.ConnectingNode { case carol.PubKeyStr: case net.Bob.PubKeyStr: default: t.Fatalf("unknown connecting node: %v", chanUpdate.ConnectingNode) } } case <-time.After(time.Second * 10): t.Fatalf("timeout waiting for graph notification %v", i) } } // Close the channel between Bob and Carol. ctxt, _ = context.WithTimeout(context.Background(), timeout) closeChannelAndAssert(ctxt, t, net, net.Bob, chanPoint, false) close(quit) // Finally, shutdown carol as our test has concluded successfully. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } // testNodeAnnouncement ensures that when a node is started with one or more // external IP addresses specified on the command line, that those addresses // announced to the network and reported in the network graph. func testNodeAnnouncement(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() ipAddresses := map[string]bool{ "192.168.1.1:8333": true, "[2001:db8:85a3:8d3:1319:8a2e:370:7348]:8337": true, } var lndArgs []string for address := range ipAddresses { lndArgs = append(lndArgs, "--externalip="+address) } dave, err := net.NewNode(lndArgs) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } // We must let Dave have an open channel before he can send a node // announcement, so we open a channel with Bob, if err := net.ConnectNodes(ctxb, net.Bob, dave); err != nil { t.Fatalf("unable to connect bob to carol: %v", err) } timeout := time.Duration(time.Second * 5) ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Bob, dave, 1000000, 0) // When Alice now connects with Dave, Alice will get his node announcement. if err := net.ConnectNodes(ctxb, net.Alice, dave); err != nil { t.Fatalf("unable to connect bob to carol: %v", err) } time.Sleep(time.Second * 1) req := &lnrpc.ChannelGraphRequest{} chanGraph, err := net.Alice.DescribeGraph(ctxb, req) if err != nil { t.Fatalf("unable to query for alice's routing table: %v", err) } for _, node := range chanGraph.Nodes { if node.PubKey == dave.PubKeyStr { for _, address := range node.Addresses { addrStr := address.String() // parse the IP address from the string // representation of the TCPAddr parts := strings.Split(addrStr, "\"") if ipAddresses[parts[3]] { delete(ipAddresses, parts[3]) } else { if !strings.HasPrefix(parts[3], "127.0.0.1:") { t.Fatalf("unexpected IP: %v", parts[3]) } } } } } if len(ipAddresses) != 0 { t.Fatalf("expected IP addresses not in channel "+ "graph: %v", ipAddresses) } // Close the channel between Bob and Dave. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Bob, chanPoint, false) if err := net.ShutdownNode(dave); err != nil { t.Fatalf("unable to shutdown dave: %v", err) } } func testNodeSignVerify(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 15) ctxb := context.Background() chanAmt := maxFundingAmount pushAmt := btcutil.Amount(100000) // Create a channel between alice and bob. ctxt, _ := context.WithTimeout(ctxb, timeout) aliceBobCh := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, pushAmt) aliceMsg := []byte("alice msg") // alice signs "alice msg" and sends her signature to bob. sigReq := &lnrpc.SignMessageRequest{Msg: aliceMsg} sigResp, err := net.Alice.SignMessage(ctxb, sigReq) if err != nil { t.Fatalf("SignMessage rpc call failed: %v", err) } aliceSig := sigResp.Signature // bob verifying alice's signature should succeed since alice and bob are // connected. verifyReq := &lnrpc.VerifyMessageRequest{Msg: aliceMsg, Signature: aliceSig} verifyResp, err := net.Bob.VerifyMessage(ctxb, verifyReq) if err != nil { t.Fatalf("VerifyMessage failed: %v", err) } if !verifyResp.Valid { t.Fatalf("alice's signature didn't validate") } if verifyResp.Pubkey != net.Alice.PubKeyStr { t.Fatalf("alice's signature doesn't contain alice's pubkey.") } // carol is a new node that is unconnected to alice or bob. carol, err := net.NewNode(nil) if err != nil { t.Fatalf("unable to create new node: %v", err) } carolMsg := []byte("carol msg") // carol signs "carol msg" and sends her signature to bob. sigReq = &lnrpc.SignMessageRequest{Msg: carolMsg} sigResp, err = carol.SignMessage(ctxb, sigReq) if err != nil { t.Fatalf("SignMessage rpc call failed: %v", err) } carolSig := sigResp.Signature // bob verifying carol's signature should fail since they are not connected. verifyReq = &lnrpc.VerifyMessageRequest{Msg: carolMsg, Signature: carolSig} verifyResp, err = net.Bob.VerifyMessage(ctxb, verifyReq) if err != nil { t.Fatalf("VerifyMessage failed: %v", err) } if verifyResp.Valid { t.Fatalf("carol's signature should not be valid") } if verifyResp.Pubkey != carol.PubKeyStr { t.Fatalf("carol's signature doesn't contain her pubkey") } // Clean up carol's node. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } // Close the channel between alice and bob. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, aliceBobCh, false) } // testAsyncPayments tests the performance of the async payments, and also // checks that balances of both sides can't be become negative under stress // payment strikes. func testAsyncPayments(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() // As we'll be querying the channels state frequently we'll // create a closure helper function for the purpose. getChanInfo := func(node *lntest.HarnessNode) (*lnrpc.ActiveChannel, error) { req := &lnrpc.ListChannelsRequest{} channelInfo, err := node.ListChannels(ctxb, req) if err != nil { return nil, err } if len(channelInfo.Channels) != 1 { t.Fatalf("node should only have a single channel, "+ "instead he has %v", len(channelInfo.Channels)) } return channelInfo.Channels[0], nil } const ( timeout = time.Duration(time.Second * 5) paymentAmt = 100 ) // First establish a channel with a capacity equals to the overall // amount of payments, between Alice and Bob, at the end of the test // Alice should send all money from her side to Bob. ctxt, _ := context.WithTimeout(ctxb, timeout) channelCapacity := btcutil.Amount(paymentAmt * 2000) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, channelCapacity, 0) info, err := getChanInfo(net.Alice) if err != nil { t.Fatalf("unable to get alice channel info: %v", err) } // Calculate the number of invoices. We will deplete the channel // all the way down to the channel reserve. chanReserve := channelCapacity / 100 availableBalance := btcutil.Amount(info.LocalBalance) - chanReserve numInvoices := int(availableBalance / paymentAmt) bobAmt := int64(numInvoices * paymentAmt) aliceAmt := info.LocalBalance - bobAmt // Send one more payment in order to cause insufficient capacity error. numInvoices++ // Initialize seed random in order to generate invoices. prand.Seed(time.Now().UnixNano()) // With the channel open, we'll create a invoices for Bob that Alice // will pay to in order to advance the state of the channel. bobPayReqs := make([]string, numInvoices) for i := 0; i < numInvoices; i++ { preimage := make([]byte, 32) _, err := rand.Read(preimage) if err != nil { t.Fatalf("unable to generate preimage: %v", err) } invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } resp, err := net.Bob.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } bobPayReqs[i] = resp.PaymentRequest } // Wait for Alice to receive the channel edge from the funding manager. ctxt, _ = context.WithTimeout(ctxb, timeout) err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("alice didn't see the alice->bob channel before "+ "timeout: %v", err) } // Open up a payment stream to Alice that we'll use to send payment to // Bob. We also create a small helper function to send payments to Bob, // consuming the payment hashes we generated above. ctxt, _ = context.WithTimeout(ctxb, time.Minute) alicePayStream, err := net.Alice.SendPayment(ctxt) if err != nil { t.Fatalf("unable to create payment stream for alice: %v", err) } // Send payments from Alice to Bob using of Bob's payment hashes // generated above. now := time.Now() for i := 0; i < numInvoices; i++ { sendReq := &lnrpc.SendRequest{ PaymentRequest: bobPayReqs[i], } if err := alicePayStream.Send(sendReq); err != nil { t.Fatalf("unable to send payment: "+ "stream has been closed: %v", err) } } // We should receive one insufficient capacity error, because we sent // one more payment than we can actually handle with the current // channel capacity. errorReceived := false for i := 0; i < numInvoices; i++ { if resp, err := alicePayStream.Recv(); err != nil { t.Fatalf("payment stream have been closed: %v", err) } else if resp.PaymentError != "" { if errorReceived { t.Fatalf("redundant payment error: %v", resp.PaymentError) } errorReceived = true continue } } if !errorReceived { t.Fatalf("insufficient capacity error haven't been received") } // All payments have been sent, mark the finish time. timeTaken := time.Since(now) // Next query for Bob's and Alice's channel states, in order to confirm // that all payment have been successful transmitted. aliceChan, err := getChanInfo(net.Alice) if len(aliceChan.PendingHtlcs) != 0 { t.Fatalf("alice's pending htlcs is incorrect, got %v, "+ "expected %v", len(aliceChan.PendingHtlcs), 0) } if err != nil { t.Fatalf("unable to get bob's channel info: %v", err) } if aliceChan.RemoteBalance != bobAmt { t.Fatalf("alice's remote balance is incorrect, got %v, "+ "expected %v", aliceChan.RemoteBalance, bobAmt) } if aliceChan.LocalBalance != aliceAmt { t.Fatalf("alice's local balance is incorrect, got %v, "+ "expected %v", aliceChan.LocalBalance, aliceAmt) } // Wait for Bob to receive revocation from Alice. time.Sleep(2 * time.Second) bobChan, err := getChanInfo(net.Bob) if err != nil { t.Fatalf("unable to get bob's channel info: %v", err) } if len(bobChan.PendingHtlcs) != 0 { t.Fatalf("bob's pending htlcs is incorrect, got %v, "+ "expected %v", len(bobChan.PendingHtlcs), 0) } if bobChan.LocalBalance != bobAmt { t.Fatalf("bob's local balance is incorrect, got %v, expected"+ " %v", bobChan.LocalBalance, bobAmt) } if bobChan.RemoteBalance != aliceAmt { t.Fatalf("bob's remote balance is incorrect, got %v, "+ "expected %v", bobChan.RemoteBalance, aliceAmt) } t.Log("\tBenchmark info: Elapsed time: ", timeTaken) t.Log("\tBenchmark info: TPS: ", float64(numInvoices)/float64(timeTaken.Seconds())) // Finally, immediately close the channel. This function will also // block until the channel is closed and will additionally assert the // relevant channel closing post conditions. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) } // testBidirectionalAsyncPayments tests that nodes are able to send the // payments to each other in async manner without blocking. func testBidirectionalAsyncPayments(net *lntest.NetworkHarness, t *harnessTest) { ctxb := context.Background() // As we'll be querying the channels state frequently we'll // create a closure helper function for the purpose. getChanInfo := func(node *lntest.HarnessNode) (*lnrpc.ActiveChannel, error) { req := &lnrpc.ListChannelsRequest{} channelInfo, err := node.ListChannels(ctxb, req) if err != nil { return nil, err } if len(channelInfo.Channels) != 1 { t.Fatalf("node should only have a single channel, "+ "instead he has %v", len(channelInfo.Channels)) } return channelInfo.Channels[0], nil } const ( timeout = time.Duration(time.Second * 5) paymentAmt = 1000 ) // First establish a channel with a capacity equals to the overall // amount of payments, between Alice and Bob, at the end of the test // Alice should send all money from her side to Bob. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPoint := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, paymentAmt*2000, paymentAmt*1000) info, err := getChanInfo(net.Alice) if err != nil { t.Fatalf("unable to get alice channel info: %v", err) } // Calculate the number of invoices. numInvoices := int(info.LocalBalance / paymentAmt) // Nodes should exchange the same amount of money and because of this // at the end balances should remain the same. aliceAmt := info.LocalBalance bobAmt := info.RemoteBalance // Initialize seed random in order to generate invoices. prand.Seed(time.Now().UnixNano()) // With the channel open, we'll create a invoices for Bob that Alice // will pay to in order to advance the state of the channel. bobPayReqs := make([]string, numInvoices) for i := 0; i < numInvoices; i++ { preimage := make([]byte, 32) _, err := rand.Read(preimage) if err != nil { t.Fatalf("unable to generate preimage: %v", err) } invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } resp, err := net.Bob.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } bobPayReqs[i] = resp.PaymentRequest } // With the channel open, we'll create a invoices for Alice that Bob // will pay to in order to advance the state of the channel. alicePayReqs := make([]string, numInvoices) for i := 0; i < numInvoices; i++ { preimage := make([]byte, 32) _, err := rand.Read(preimage) if err != nil { t.Fatalf("unable to generate preimage: %v", err) } invoice := &lnrpc.Invoice{ Memo: "testing", RPreimage: preimage, Value: paymentAmt, } resp, err := net.Alice.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } alicePayReqs[i] = resp.PaymentRequest } // Wait for Alice to receive the channel edge from the funding manager. ctxt, _ = context.WithTimeout(ctxb, timeout) if err = net.Alice.WaitForNetworkChannelOpen(ctxt, chanPoint); err != nil { t.Fatalf("alice didn't see the alice->bob channel before "+ "timeout: %v", err) } if err = net.Bob.WaitForNetworkChannelOpen(ctxt, chanPoint); err != nil { t.Fatalf("bob didn't see the bob->alice channel before "+ "timeout: %v", err) } // Open up a payment streams to Alice and to Bob, that we'll use to // send payment between nodes. alicePayStream, err := net.Alice.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream for alice: %v", err) } bobPayStream, err := net.Bob.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream for bob: %v", err) } // Send payments from Alice to Bob and from Bob to Alice in async // manner. for i := 0; i < numInvoices; i++ { aliceSendReq := &lnrpc.SendRequest{ PaymentRequest: bobPayReqs[i], } bobSendReq := &lnrpc.SendRequest{ PaymentRequest: alicePayReqs[i], } if err := alicePayStream.Send(aliceSendReq); err != nil { t.Fatalf("unable to send payment: "+ "%v", err) } if err := bobPayStream.Send(bobSendReq); err != nil { t.Fatalf("unable to send payment: "+ "%v", err) } } errChan := make(chan error) go func() { for i := 0; i < numInvoices; i++ { if resp, err := alicePayStream.Recv(); err != nil { errChan <- errors.Errorf("payment stream has"+ " been closed: %v", err) return } else if resp.PaymentError != "" { errChan <- errors.Errorf("unable to send "+ "payment from alice to bob: %v", resp.PaymentError) return } } errChan <- nil }() go func() { for i := 0; i < numInvoices; i++ { if resp, err := bobPayStream.Recv(); err != nil { errChan <- errors.Errorf("payment stream has"+ " been closed: %v", err) return } else if resp.PaymentError != "" { errChan <- errors.Errorf("unable to send "+ "payment from bob to alice: %v", resp.PaymentError) return } } errChan <- nil }() // Wait for Alice and Bob receive their payments, and throw and error // if something goes wrong. maxTime := 60 * time.Second for i := 0; i < 2; i++ { select { case err := <-errChan: if err != nil { t.Fatalf(err.Error()) } case <-time.After(maxTime): t.Fatalf("waiting for payments to finish too long "+ "(%v)", maxTime) } } // Wait for Alice and Bob to receive revocations messages, and update // states, i.e. balance info. time.Sleep(1 * time.Second) aliceInfo, err := getChanInfo(net.Alice) if err != nil { t.Fatalf("unable to get bob's channel info: %v", err) } if aliceInfo.RemoteBalance != bobAmt { t.Fatalf("alice's remote balance is incorrect, got %v, "+ "expected %v", aliceInfo.RemoteBalance, bobAmt) } if aliceInfo.LocalBalance != aliceAmt { t.Fatalf("alice's local balance is incorrect, got %v, "+ "expected %v", aliceInfo.LocalBalance, aliceAmt) } if len(aliceInfo.PendingHtlcs) != 0 { t.Fatalf("alice's pending htlcs is incorrect, got %v, "+ "expected %v", len(aliceInfo.PendingHtlcs), 0) } // Next query for Bob's and Alice's channel states, in order to confirm // that all payment have been successful transmitted. bobInfo, err := getChanInfo(net.Bob) if err != nil { t.Fatalf("unable to get bob's channel info: %v", err) } if bobInfo.LocalBalance != bobAmt { t.Fatalf("bob's local balance is incorrect, got %v, expected"+ " %v", bobInfo.LocalBalance, bobAmt) } if bobInfo.RemoteBalance != aliceAmt { t.Fatalf("bob's remote balance is incorrect, got %v, "+ "expected %v", bobInfo.RemoteBalance, aliceAmt) } if len(bobInfo.PendingHtlcs) != 0 { t.Fatalf("bob's pending htlcs is incorrect, got %v, "+ "expected %v", len(bobInfo.PendingHtlcs), 0) } // Finally, immediately close the channel. This function will also // block until the channel is closed and will additionally assert the // relevant channel closing post conditions. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPoint, false) } func assertActiveHtlcs(nodes []*lntest.HarnessNode, payHashes ...[]byte) error { req := &lnrpc.ListChannelsRequest{} ctxb := context.Background() for _, node := range nodes { nodeChans, err := node.ListChannels(ctxb, req) if err != nil { return fmt.Errorf("unable to get node chans: %v", err) } for _, channel := range nodeChans.Channels { if len(channel.PendingHtlcs) == 0 { return fmt.Errorf("node %x has no htlcs: %v", node.PubKey[:], spew.Sdump(channel)) } for _, htlc := range channel.PendingHtlcs { var htlcIsMatch bool for _, payHash := range payHashes { if bytes.Equal(htlc.HashLock, payHash) { htlcIsMatch = true } } if htlcIsMatch { continue } return fmt.Errorf("node %x doesn't have expected "+ "payment hashes: %v", node.PubKey[:], spew.Sdump(channel.PendingHtlcs)) } } } return nil } func assertNumActiveHtlcs(nodes []*lntest.HarnessNode, numHtlcs int) bool { req := &lnrpc.ListChannelsRequest{} ctxb := context.Background() for _, node := range nodes { nodeChans, err := node.ListChannels(ctxb, req) if err != nil { return false } for _, channel := range nodeChans.Channels { if len(channel.PendingHtlcs) != numHtlcs { return false } } } return true } func assertSpendingTxInMempool(t *harnessTest, miner *rpcclient.Client, timeout time.Duration, chanPoint wire.OutPoint) { breakTimeout := time.After(timeout) ticker := time.NewTicker(50 * time.Millisecond) defer ticker.Stop() for { select { case <-breakTimeout: t.Fatalf("didn't find tx in mempool") case <-ticker.C: mempool, err := miner.GetRawMempool() if err != nil { t.Fatalf("unable to get mempool: %v", err) } if len(mempool) == 0 { continue } for _, txid := range mempool { tx, err := miner.GetRawTransaction(txid) if err != nil { t.Fatalf("unable to fetch tx: %v", err) } for _, txIn := range tx.MsgTx().TxIn { if txIn.PreviousOutPoint == chanPoint { return } } } } } } func createThreeHopHodlNetwork(t *harnessTest, net *lntest.NetworkHarness) (*lnrpc.ChannelPoint, *lnrpc.ChannelPoint, *lntest.HarnessNode) { // We'll start the test by creating a channel between Alice and Bob, // which will act as the first leg for out multi-hop HTLC. const chanAmt = 1000000 ctxb := context.Background() timeout := time.Duration(time.Second * 15) ctxt, _ := context.WithTimeout(ctxb, timeout) aliceChanPoint := openChannelAndAssert( ctxt, t, net, net.Alice, net.Bob, chanAmt, 0, ) ctxt, _ = context.WithTimeout(ctxb, time.Second*15) err := net.Alice.WaitForNetworkChannelOpen(ctxt, aliceChanPoint) if err != nil { t.Fatalf("alice didn't report channel: %v", err) } ctxt, _ = context.WithTimeout(ctxb, time.Second*15) err = net.Bob.WaitForNetworkChannelOpen(ctxt, aliceChanPoint) if err != nil { t.Fatalf("bob didn't report channel: %v", err) } // Next, we'll create a new node "carol" and have Bob connect to her. // In this test, we'll make carol always hold onto the HTLC, this way // it'll force Bob to go to chain to resolve the HTLC. carol, err := net.NewNode([]string{"--debughtlc", "--hodlhtlc"}) if err != nil { t.Fatalf("unable to create new node: %v", err) } if err := net.ConnectNodes(ctxb, net.Bob, carol); err != nil { t.Fatalf("unable to connect bob to carol: %v", err) } // We'll then create a channel from Bob to Carol. After this channel is // open, our topology looks like: A -> B -> C. ctxt, _ = context.WithTimeout(ctxb, timeout) bobChanPoint := openChannelAndAssert( ctxt, t, net, net.Bob, carol, chanAmt, 0, ) ctxt, _ = context.WithTimeout(ctxb, time.Second*15) err = net.Bob.WaitForNetworkChannelOpen(ctxt, bobChanPoint) if err != nil { t.Fatalf("alice didn't report channel: %v", err) } ctxt, _ = context.WithTimeout(ctxb, time.Second*15) err = carol.WaitForNetworkChannelOpen(ctxt, bobChanPoint) if err != nil { t.Fatalf("bob didn't report channel: %v", err) } ctxt, _ = context.WithTimeout(ctxb, time.Second*15) err = net.Alice.WaitForNetworkChannelOpen(ctxt, bobChanPoint) if err != nil { t.Fatalf("bob didn't report channel: %v", err) } return aliceChanPoint, bobChanPoint, carol } // testMultiHopHtlcLocalTimeout tests that in a multi-hop HTLC scenario, if the // outgoing HTLC is about to time out, then we'll go to chain in order to claim // it. Any dust HTLC's should be immediately cancelled backwards. Once the // timeout has been reached, then we should sweep it on-chain, and cancel the // HTLC backwards. func testMultiHopHtlcLocalTimeout(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 15) ctxb := context.Background() // First, we'll create a three hop network: Alice -> Bob -> Carol, with // Carol refusing to actually settle or directly cancel any HTLC's // self. aliceChanPoint, bobChanPoint, carol := createThreeHopHodlNetwork(t, net) time.Sleep(time.Second * 1) // Now that our channels are set up, we'll send two HTLC's from Alice // to Carol. The first HTLC will be universally considered "dust", // while the second will be a proper fully valued HTLC. const ( dustHtlcAmt = btcutil.Amount(100) htlcAmt = btcutil.Amount(30000) finalCltvDelta = 40 ) alicePayStream, err := net.Alice.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream for alice: %v", err) } // We'll create two random payment hashes unknown to carol, then send // each of them by manually specifying the HTLC details. carolPubKey := carol.PubKey[:] dustPayHash := bytes.Repeat([]byte{1}, 32) payHash := bytes.Repeat([]byte{2}, 32) err = alicePayStream.Send(&lnrpc.SendRequest{ Dest: carolPubKey, Amt: int64(dustHtlcAmt), PaymentHash: dustPayHash, FinalCltvDelta: finalCltvDelta, }) if err != nil { t.Fatalf("unable to send alice htlc: %v", err) } err = alicePayStream.Send(&lnrpc.SendRequest{ Dest: carolPubKey, Amt: int64(htlcAmt), PaymentHash: payHash, FinalCltvDelta: finalCltvDelta, }) if err != nil { t.Fatalf("unable to send alice htlc: %v", err) } // Verify that all nodes in the path now have two HTLC's with the // proper parameters. var predErr error nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol} err = lntest.WaitPredicate(func() bool { predErr = assertActiveHtlcs(nodes, dustPayHash, payHash) if predErr != nil { return false } return true }, time.Second*15) if err != nil { t.Fatalf("htlc mismatch: %v", predErr) } // We'll now mine enough blocks to trigger Bob's broadcast of his // commitment transaction due to the fact that the HTLC is about to // timeout. numBlocks := uint32(finalCltvDelta - defaultBroadcastDelta) if _, err := net.Miner.Node.Generate(numBlocks); err != nil { t.Fatalf("unable to generate blocks: %v", err) } // Bob's force close transaction should now be found in the mempool. txidHash, err := getChanPointFundingTxid(bobChanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } bobFundingTxid, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } assertSpendingTxInMempool( t, net.Miner.Node, time.Second*10, wire.OutPoint{ Hash: *bobFundingTxid, Index: bobChanPoint.OutputIndex, }, ) // At this point, Bob should have cancelled backwards the dust HTLC // that we sent earlier. This means Alice should now only have a single // HTLC on her channel. nodes = []*lntest.HarnessNode{net.Alice} err = lntest.WaitPredicate(func() bool { predErr = assertActiveHtlcs(nodes, payHash) if predErr != nil { return false } return true }, time.Second*15) if err != nil { t.Fatalf("htlc mismatch: %v", err) } // TODO(roasbeef): need to fix utxn so it can accept incubation for // timeout that has already past // // * remove after solved time.Sleep(time.Second * 5) // We'll now mine the remaining blocks to cause the HTLC itself to // timeout. if _, err := net.Miner.Node.Generate(defaultBroadcastDelta); err != nil { t.Fatalf("unable to generate blocks: %v", err) } // The second layer HTLC timeout transaction should now have been // broadcast on-chain. _, err = waitForTxInMempool(net.Miner.Node, time.Second*10) if err != nil { t.Fatalf("unable to find bob's second layer transaction") } // Bob's pending channel report should show that he has a commitment // output awaiting sweeping, and also that there's an outgoing HTLC // output pending. pendingChansRequest := &lnrpc.PendingChannelsRequest{} pendingChanResp, err := net.Bob.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } if len(pendingChanResp.PendingForceClosingChannels) == 0 { t.Fatalf("bob should have pending for close chan but doesn't") } forceCloseChan := pendingChanResp.PendingForceClosingChannels[0] if forceCloseChan.LimboBalance == 0 { t.Fatalf("bob should have nonzero limbo balance instead "+ "has: %v", forceCloseChan.LimboBalance) } if len(forceCloseChan.PendingHtlcs) == 0 { t.Fatalf("bob should have pending htlc but doesn't") } // Now we'll mine an additional block. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate blocks: %v", err) } // The block should have confirmed Bob's second layer sweeping // transaction. Therefore, at this point, there should be no active // HTLC's on the commitment transaction from Alice -> Bob. nodes = []*lntest.HarnessNode{net.Alice} err = lntest.WaitPredicate(func() bool { return assertNumActiveHtlcs(nodes, 0) }, time.Second*15) if err != nil { t.Fatalf("alice's channel still has active htlc's") } // At this point, Bob should show that the pending HTLC has advanced to // the second stage and is to be swept. pendingChanResp, err = net.Bob.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } forceCloseChan = pendingChanResp.PendingForceClosingChannels[0] if forceCloseChan.PendingHtlcs[0].Stage != 2 { t.Fatalf("bob's htlc should have advanced to the second stage: %v", err) } // We'll now mine four more blocks. After the 4th block, a transaction // sweeping the HTLC output should be broadcast. if _, err := net.Miner.Node.Generate(4); err != nil { t.Fatalf("unable to generate blocks: %v", err) } _, err = waitForTxInMempool(net.Miner.Node, time.Second*10) if err != nil { t.Fatalf("unable to find bob's sweeping transaction") } // Next, we'll mine a final block that should confirm the second-layer // sweeping transaction. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate blocks: %v", err) } // Once this transaction has been confirmed, Bob should detect that he // no longer has any pending channels. err = lntest.WaitPredicate(func() bool { pendingChanResp, err = net.Bob.PendingChannels(ctxb, pendingChansRequest) if err != nil { predErr = fmt.Errorf("unable to query for pending "+ "channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) != 0 { predErr = fmt.Errorf("bob still has pending "+ "channels but shouldn't: %v", spew.Sdump(pendingChanResp)) return false } return true }, time.Second*15) if err != nil { t.Fatalf(predErr.Error()) } ctxt, _ := context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, aliceChanPoint, false) // Clean up carol's node. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } // testMultiHopReceiverChainClaim tests that in the multi-hop setting, if the // receiver of an HTLC knows the preimage, but wasn't able to settle the HTLC // off-chain, then it goes on chain to claim the HTLC. In this scenario, the // node that sent the outgoing HTLC should extract the preimage from the sweep // transaction, and finish settling the HTLC backwards into the route. func testMultiHopReceiverChainClaim(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 15) ctxb := context.Background() defaultCSV := uint32(4) // First, we'll create a three hop network: Alice -> Bob -> Carol, with // Carol refusing to actually settle or directly cancel any HTLC's // self. aliceChanPoint, bobChanPoint, carol := createThreeHopHodlNetwork(t, net) // With the network active, we'll now add a new invoice at Carol's end. invoiceReq := &lnrpc.Invoice{ Value: 100000, } carolInvoice, err := carol.AddInvoice(ctxb, invoiceReq) if err != nil { t.Fatalf("unable to generate carol invoice: %v", err) } // Now that we've created the invoice, we'll send a single payment from // Alice to Carol. We won't wait for the response however, as Carol // will not immediately settle the payment. alicePayStream, err := net.Alice.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream for alice: %v", err) } err = alicePayStream.Send(&lnrpc.SendRequest{ PaymentRequest: carolInvoice.PaymentRequest, }) if err != nil { t.Fatalf("unable to send payment: %v", err) } // At this point, all 3 nodes should now have an active channel with // the created HTLC pending on all of them. var predErr error nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol} err = lntest.WaitPredicate(func() bool { predErr = assertActiveHtlcs(nodes, carolInvoice.RHash) if predErr != nil { return false } return true }, time.Second*15) if err != nil { t.Fatalf("htlc mismatch: %v", err) } // Now we'll mine enough blocks to prompt carol to actually go to the // chain in order to sweep her HTLC since the value is high enough. // TODO(roasbeef): modify once go to chain policy changes numBlocks := uint32(defaultBitcoinTimeLockDelta - (2 * defaultBroadcastDelta)) if _, err := net.Miner.Node.Generate(numBlocks); err != nil { t.Fatalf("unable to generate blocks") } // At this point, Carol should broadcast her active commitment // transaction in order to go to the chain and sweep her HTLC. // Additionally, Carol's should have broadcast her second layer sweep // transaction for the HTLC as well. txids, err := waitForNTxsInMempool(net.Miner.Node, 2, time.Second*15) if err != nil { t.Fatalf("transactions not found in mempool: %v", err) } txidHash, err := getChanPointFundingTxid(bobChanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } bobFundingTxid, err := chainhash.NewHash(txidHash) carolFundingPoint := wire.OutPoint{ Hash: *bobFundingTxid, Index: bobChanPoint.OutputIndex, } tx1, err := net.Miner.Node.GetRawTransaction(txids[0]) if err != nil { t.Fatalf("unable to get txn: %v", err) } tx1Hash := tx1.MsgTx().TxHash() tx2, err := net.Miner.Node.GetRawTransaction(txids[1]) if err != nil { t.Fatalf("unable to get txn: %v", err) } tx2Hash := tx2.MsgTx().TxHash() // Of the two transactions, one should be spending from the funding // transaction, and the second transaction should then be spending from // the commitment transaction. var commitHash *chainhash.Hash if tx1.MsgTx().TxIn[0].PreviousOutPoint == carolFundingPoint { commitHash = &tx1Hash if tx2.MsgTx().TxIn[0].PreviousOutPoint.Hash != *commitHash { t.Fatalf("second transaction not spending commit tx: %v", spew.Sdump(tx2)) } } if tx2.MsgTx().TxIn[0].PreviousOutPoint == carolFundingPoint { commitHash = &tx2Hash if tx1.MsgTx().TxIn[0].PreviousOutPoint.Hash != *commitHash { t.Fatalf("second transaction not spending commit tx: %v", spew.Sdump(tx1)) } } if commitHash == nil { t.Fatalf("commit tx not found in mempool") } // We'll now mine an additional block which should confirm both the // second layer transaction as well as the commitment transaction // itself. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate block: %v", err) } time.Sleep(time.Second * 4) // TODO(roasbeef): assert bob pending state as well // Carol's pending channel report should now show two outputs under // limbo: her commitment output, as well as the second-layer claim // output. pendingChansRequest := &lnrpc.PendingChannelsRequest{} pendingChanResp, err := carol.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } if len(pendingChanResp.PendingForceClosingChannels) == 0 { t.Fatalf("carol should have pending for close chan but doesn't") } forceCloseChan := pendingChanResp.PendingForceClosingChannels[0] if forceCloseChan.LimboBalance == 0 { t.Fatalf("carol should have nonzero limbo balance instead "+ "has: %v", forceCloseChan.LimboBalance) } // The pending HTLC carol has should also now be in stage 2. if len(forceCloseChan.PendingHtlcs) != 1 { t.Fatalf("carol should have pending htlc but doesn't") } if forceCloseChan.PendingHtlcs[0].Stage != 2 { t.Fatalf("carol's htlc should have advanced to the second "+ "stage: %v", err) } // Once the second-level transaction confirmed, Bob should have // extracted the preimage from the chain, and sent it back to Alice, // clearing the HTLC off-chain. nodes = []*lntest.HarnessNode{net.Alice} err = lntest.WaitPredicate(func() bool { return assertNumActiveHtlcs(nodes, 0) }, time.Second*15) if err != nil { t.Fatalf("htlc mismatch: %v", err) } // If we mine 4 additional blocks, then both outputs should now be // mature. if _, err := net.Miner.Node.Generate(defaultCSV); err != nil { t.Fatalf("unable to generate blocks: %v", err) } // We should have a new transaction in the mempool. _, err = waitForTxInMempool(net.Miner.Node, time.Second*10) if err != nil { t.Fatalf("unable to find bob's sweeping transaction") } // Finally, if we mine an additional block to confirm these two sweep // transactions, Carol should not show a pending channel in her report // afterwards. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to mine block: %v", err) } err = lntest.WaitPredicate(func() bool { pendingChanResp, err = carol.PendingChannels(ctxb, pendingChansRequest) if err != nil { predErr = fmt.Errorf("unable to query for pending channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) != 0 { predErr = fmt.Errorf("carol still has pending channels: %v", spew.Sdump(pendingChanResp)) return false } return true }, time.Second*15) if err != nil { t.Fatalf(predErr.Error()) } // We'll close out the channel between Alice and Bob, then shutdown // carol to conclude the test. ctxt, _ := context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, aliceChanPoint, false) // Clean up carol's node. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } // testMultiHopLocalForceCloseOnChainHtlcTimeout tests that in a multi-hop HTLC // scenario, if the node that extended the HTLC to the final node closes their // commitment on-chain early, then it eventually recognizes this HTLC as one // that's timed out. At this point, the node should timeout the HTLC, then // cancel it backwards as normal. func testMultiHopLocalForceCloseOnChainHtlcTimeout(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 15) ctxb := context.Background() // First, we'll create a three hop network: Alice -> Bob -> Carol, with // Carol refusing to actually settle or directly cancel any HTLC's // self. aliceChanPoint, bobChanPoint, carol := createThreeHopHodlNetwork(t, net) // With our channels set up, we'll then send a single HTLC from Alice // to Carol. As Carol is in hodl mode, she won't settle this HTLC which // opens up the base for out tests. const ( finalCltvDelta = 40 htlcAmt = btcutil.Amount(30000) ) alicePayStream, err := net.Alice.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream for alice: %v", err) } // We'll now send a single HTLC across our multi-hop network. carolPubKey := carol.PubKey[:] payHash := bytes.Repeat([]byte{2}, 32) err = alicePayStream.Send(&lnrpc.SendRequest{ Dest: carolPubKey, Amt: int64(htlcAmt), PaymentHash: payHash, FinalCltvDelta: finalCltvDelta, }) if err != nil { t.Fatalf("unable to send alice htlc: %v", err) } // Once the HTLC has cleared, all channels in our mini network should // have the it locked in. var predErr error nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol} err = lntest.WaitPredicate(func() bool { predErr = assertActiveHtlcs(nodes, payHash) if predErr != nil { return false } return true }, time.Second*15) if err != nil { t.Fatalf("htlc mismatch: %v", err) } // Now that all parties have the HTLC locked in, we'll immediately // force close the Bob -> Carol channel. This should trigger contract // resolution mode for both of them. ctxt, _ := context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Bob, bobChanPoint, true) // At this point, Bob should have a pending force close channel as he // just went to chain. pendingChansRequest := &lnrpc.PendingChannelsRequest{} pendingChanResp, err := net.Bob.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } if len(pendingChanResp.PendingForceClosingChannels) == 0 { t.Fatalf("bob should have pending for close chan but doesn't") } forceCloseChan := pendingChanResp.PendingForceClosingChannels[0] if forceCloseChan.LimboBalance == 0 { t.Fatalf("bob should have nonzero limbo balance instead "+ "has: %v", forceCloseChan.LimboBalance) } // We'll now mine enough blocks for the HTLC to expire. After this, Bob // should hand off the now expired HTLC output to the utxo nursery. if _, err := net.Miner.Node.Generate(finalCltvDelta); err != nil { t.Fatalf("unable to generate blocks: %v", err) } // Bob's pending channel report should show that he has a single HTLC // that's now in stage one. err = lntest.WaitPredicate(func() bool { pendingChanResp, err := net.Bob.PendingChannels( ctxb, pendingChansRequest, ) if err != nil { predErr = fmt.Errorf("unable to query for pending "+ "channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) == 0 { predErr = fmt.Errorf("bob should have pending for " + "close chan but doesn't") return false } forceCloseChan = pendingChanResp.PendingForceClosingChannels[0] if len(forceCloseChan.PendingHtlcs) != 1 { predErr = fmt.Errorf("bob should have pending htlc " + "but doesn't") return false } if forceCloseChan.PendingHtlcs[0].Stage != 1 { predErr = fmt.Errorf("bob's htlc should have "+ "advanced to the first stage: %v", err) return false } return true }, time.Second*15) if err != nil { t.Fatalf("bob didn't hand off time-locked HTLC: %v", predErr) } // We should also now find a transaction in the mempool, as Bob should // have broadcast his second layer timeout transaction. _, err = waitForTxInMempool(net.Miner.Node, time.Second*10) if err != nil { t.Fatalf("unable to find bob's sweeping transaction") } // Next, we'll mine an additional block. This should serve to confirm // the second layer timeout transaction. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate block: %v", err) } // With the second layer timeout transaction confirmed, Bob should have // cancelled backwards the HTLC that carol sent. nodes = []*lntest.HarnessNode{net.Alice} err = lntest.WaitPredicate(func() bool { return assertNumActiveHtlcs(nodes, 0) }, time.Second*15) if err != nil { t.Fatalf("alice's channel still has active htlc's") } // Additionally, Bob should now show that HTLC as being advanced to the // second stage. err = lntest.WaitPredicate(func() bool { pendingChanResp, err := net.Bob.PendingChannels( ctxb, pendingChansRequest, ) if err != nil { predErr = fmt.Errorf("unable to query for pending "+ "channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) == 0 { predErr = fmt.Errorf("bob should have pending for " + "close chan but doesn't") return false } forceCloseChan = pendingChanResp.PendingForceClosingChannels[0] if len(forceCloseChan.PendingHtlcs) != 1 { predErr = fmt.Errorf("bob should have pending htlc " + "but doesn't") return false } if forceCloseChan.PendingHtlcs[0].Stage != 2 { predErr = fmt.Errorf("bob's htlc should have "+ "advanced to the second stage: %v", err) return false } return true }, time.Second*15) if err != nil { t.Fatalf("bob didn't hand off time-locked HTLC: %v", predErr) } // We'll now mine 4 additional blocks. This should be enough for Bob's // CSV timelock to expire, and the sweeping transaction to be // confirmed. if _, err := net.Miner.Node.Generate(4); err != nil { t.Fatalf("unable to mine blocks: %v", err) } time.Sleep(time.Second * 3) // We'll then mine a final block which should confirm this second layer // sweep transaction. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to mine blocks: %v", err) } // At this point, Bob should no longer show any channels as pending // close. err = lntest.WaitPredicate(func() bool { pendingChanResp, err = net.Bob.PendingChannels( ctxb, pendingChansRequest, ) if err != nil { predErr = fmt.Errorf("unable to query for pending "+ "channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) != 0 { predErr = fmt.Errorf("bob still has pending channels "+ "but shouldn't: %v", spew.Sdump(pendingChanResp)) return false } return true }, time.Second*15) if err != nil { t.Fatalf(predErr.Error()) } ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, aliceChanPoint, false) // Clean up carol's node. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } // testMultiHopRemoteForceCloseOnChainHtlcTimeout tests that if we extend a // multi-hop HTLC, and the final destination of the HTLC force closes the // channel, then we properly timeout the HTLC on *their* commitment transaction // once the timeout has expired. Once we sweep the transaction, we should also // cancel back the initial HTLC. func testMultHopRemoteForceCloseOnChainHtlcTimeout(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 15) ctxb := context.Background() // First, we'll create a three hop network: Alice -> Bob -> Carol, with // Carol refusing to actually settle or directly cancel any HTLC's // self. aliceChanPoint, bobChanPoint, carol := createThreeHopHodlNetwork(t, net) // With our channels set up, we'll then send a single HTLC from Alice // to Carol. As Carol is in hodl mode, she won't settle this HTLC which // opens up the base for out tests. const ( finalCltvDelta = 40 htlcAmt = btcutil.Amount(30000) ) alicePayStream, err := net.Alice.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream for alice: %v", err) } // We'll now send a single HTLC across our multi-hop network. carolPubKey := carol.PubKey[:] payHash := bytes.Repeat([]byte{2}, 32) err = alicePayStream.Send(&lnrpc.SendRequest{ Dest: carolPubKey, Amt: int64(htlcAmt), PaymentHash: payHash, FinalCltvDelta: finalCltvDelta, }) if err != nil { t.Fatalf("unable to send alice htlc: %v", err) } // Once the HTLC has cleared, all the nodes n our mini network should // show that the HTLC has been locked in. var predErr error nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol} err = lntest.WaitPredicate(func() bool { predErr = assertActiveHtlcs(nodes, payHash) if predErr != nil { return false } return true }, time.Second*15) if err != nil { t.Fatalf("htlc mismatch: %v", err) } // At this point, we'll now instruct Carol to force close the // transaction. This will let us exercise that Bob is able to sweep the // expired HTLC on Carol's version of the commitment transaction. ctxt, _ := context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, carol, bobChanPoint, true) // At this point, Bob should have a pending force close channel as // Carol has gone directly to chain. pendingChansRequest := &lnrpc.PendingChannelsRequest{} pendingChanResp, err := net.Bob.PendingChannels(ctxb, pendingChansRequest) if err != nil { t.Fatalf("unable to query for pending channels: %v", err) } if len(pendingChanResp.PendingForceClosingChannels) == 0 { t.Fatalf("bob should have pending for close chan but doesn't") } // Next, we'll mine enough blocks for the HTLC to expire. At this // point, Bob should hand off the output to his internal utxo nursery. if _, err := net.Miner.Node.Generate(finalCltvDelta - 1); err != nil { t.Fatalf("unable to generate blocks: %v", err) } // If we check Bob's pending channel report, it should show that he has // a single HTLC that's now in the second stage, as skip the initial // first stage since this is a direct HTLC. err = lntest.WaitPredicate(func() bool { pendingChanResp, err := net.Bob.PendingChannels( ctxb, pendingChansRequest, ) if err != nil { predErr = fmt.Errorf("unable to query for pending "+ "channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) == 0 { predErr = fmt.Errorf("bob should have pending for " + "close chan but doesn't") return false } forceCloseChan := pendingChanResp.PendingForceClosingChannels[0] if len(forceCloseChan.PendingHtlcs) != 1 { predErr = fmt.Errorf("bob should have pending htlc " + "but doesn't") return false } if forceCloseChan.PendingHtlcs[0].Stage != 2 { predErr = fmt.Errorf("bob's htlc should have "+ "advanced to the second stage: %v", err) return false } return true }, time.Second*15) if err != nil { t.Fatalf("bob didn't hand off time-locked HTLC: %v", predErr) } // We'll now mine an additional block to push the HTLC to full // expiration. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate block: %v", err) } // Bob's sweeping transaction should now be found in the mempool at // this point. _, err = waitForTxInMempool(net.Miner.Node, time.Second*10) if err != nil { t.Fatalf("unable to find bob's sweeping transaction") } // If we mine an additional block, then this should confirm Bob's // transaction which sweeps the direct HTLC output. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate block: %v", err) } // Now that the sweeping transaction has been confirmed, Bob should // cancel back that HTLC. As a result, Alice should not know of any // active HTLC's. nodes = []*lntest.HarnessNode{net.Alice} err = lntest.WaitPredicate(func() bool { return assertNumActiveHtlcs(nodes, 0) }, time.Second*15) if err != nil { t.Fatalf("alice's channel still has active htlc's") } // Now we'll check Bob's pending channel report. Since this was Carol's // commitment, he doesn't have to wait for any CSV delays. As a result, // he should show no additional pending transactions. err = lntest.WaitPredicate(func() bool { pendingChanResp, err = net.Bob.PendingChannels( ctxb, pendingChansRequest, ) if err != nil { predErr = fmt.Errorf("unable to query for pending "+ "channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) != 0 { predErr = fmt.Errorf("bob still has pending channels "+ "but shouldn't: %v", spew.Sdump(pendingChanResp)) return false } return true }, time.Second*15) if err != nil { t.Fatalf(predErr.Error()) } // We'll close out the test by closing the channel from Alice to Bob, // and then shutting down the new node we created as its no longer // needed. ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, aliceChanPoint, false) if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } // testMultiHopHtlcLocalChainClaim tests that in a multi-hop HTLC scenario, if // we're forced to go to chain with an incoming HTLC, then when we find out the // preimage via the witness beacon, we properly settle the HTLC on-chain in // order to ensure we don't lose any funds. func testMultiHopHtlcLocalChainClaim(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 15) ctxb := context.Background() defaultCSV := uint32(4) // First, we'll create a three hop network: Alice -> Bob -> Carol, with // Carol refusing to actually settle or directly cancel any HTLC's // self. aliceChanPoint, bobChanPoint, carol := createThreeHopHodlNetwork(t, net) // With the network active, we'll now add a new invoice at Carol's end. invoiceReq := &lnrpc.Invoice{ Value: 100000, } carolInvoice, err := carol.AddInvoice(ctxb, invoiceReq) if err != nil { t.Fatalf("unable to generate carol invoice: %v", err) } // Now that we've created the invoice, we'll send a single payment from // Alice to Carol. We won't wait for the response however, as Carol // will not immediately settle the payment. alicePayStream, err := net.Alice.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream for alice: %v", err) } err = alicePayStream.Send(&lnrpc.SendRequest{ PaymentRequest: carolInvoice.PaymentRequest, }) if err != nil { t.Fatalf("unable to send payment: %v", err) } // We'll now wait until all 3 nodes have the HTLC as just sent fully // locked in. var predErr error nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol} err = lntest.WaitPredicate(func() bool { predErr = assertActiveHtlcs(nodes, carolInvoice.RHash) if predErr != nil { return false } return true }, time.Second*15) if err != nil { t.Fatalf("htlc mismatch: %v", err) } // At this point, Bob decides that he wants to exit the channel // immediately, so he force closes his commitment transaction. ctxt, _ := context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Bob, aliceChanPoint, true) // We'll now mine enough blocks so Carol decides that she needs to go // on-chain to claim the HTLC as Bob has been inactive. numBlocks := uint32(defaultBitcoinTimeLockDelta - (2 * defaultBroadcastDelta)) if _, err := net.Miner.Node.Generate(numBlocks); err != nil { t.Fatalf("unable to generate blocks") } // Carol's commitment transaction should now be in the mempool. She // should also have broadcast her second level HTLC transaction. txids, err := waitForNTxsInMempool(net.Miner.Node, 2, time.Second*15) if err != nil { t.Fatalf("transactions not found in mempool: %v", err) } txidHash, err := getChanPointFundingTxid(bobChanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } bobFundingTxid, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } carolFundingPoint := wire.OutPoint{ Hash: *bobFundingTxid, Index: bobChanPoint.OutputIndex, } // Of the two transactions, one should be spending from the funding // transaction, and the second transaction should then be spending from // the commitment transaction. var commitHash *chainhash.Hash tx1, err := net.Miner.Node.GetRawTransaction(txids[0]) if err != nil { t.Fatalf("unable to get txn: %v", err) } tx1Hash := tx1.MsgTx().TxHash() tx2, err := net.Miner.Node.GetRawTransaction(txids[1]) if err != nil { t.Fatalf("unable to get txn: %v", err) } tx2Hash := tx2.MsgTx().TxHash() if tx1.MsgTx().TxIn[0].PreviousOutPoint == carolFundingPoint { commitHash = &tx1Hash if tx2.MsgTx().TxIn[0].PreviousOutPoint.Hash != *commitHash { t.Fatalf("second transaction not spending commit tx: %v", spew.Sdump(tx2)) } } if tx2.MsgTx().TxIn[0].PreviousOutPoint == carolFundingPoint { commitHash = &tx2Hash if tx1.MsgTx().TxIn[0].PreviousOutPoint.Hash != *commitHash { t.Fatalf("second transaction not spending commit tx: %v", spew.Sdump(tx1)) } } if commitHash == nil { t.Fatalf("commit tx not found in mempool") } // We'll now mine a block which should confirm both the second layer // transaction as well as the commitment transaction. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate block: %v", err) } // At this point, Bob should detect that Carol has revealed the // preimage on-chain. As a result, he should now attempt to broadcast // his second-layer claim transaction to claim the output. _, err = waitForTxInMempool(net.Miner.Node, time.Second*10) if err != nil { t.Fatalf("unable to find bob's sweeping transaction") } // At this point, Bob should have broadcast his second layer success // transaction, and should have sent it to the nursery for incubation. pendingChansRequest := &lnrpc.PendingChannelsRequest{} err = lntest.WaitPredicate(func() bool { pendingChanResp, err := net.Bob.PendingChannels( ctxb, pendingChansRequest, ) if err != nil { predErr = fmt.Errorf("unable to query for pending "+ "channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) == 0 { predErr = fmt.Errorf("bob should have pending for " + "close chan but doesn't") return false } for _, forceCloseChan := range pendingChanResp.PendingForceClosingChannels { if forceCloseChan.Channel.LocalBalance != 0 { continue } if len(forceCloseChan.PendingHtlcs) != 1 { predErr = fmt.Errorf("bob should have pending htlc " + "but doesn't") return false } if forceCloseChan.PendingHtlcs[0].Stage != 1 { predErr = fmt.Errorf("bob's htlc should have "+ "advanced to the first stage: %v", err) return false } } return true }, time.Second*15) if err != nil { t.Fatalf("bob didn't hand off time-locked HTLC: %v", predErr) } // If we then mine 4 additional blocks, Bob should pull the output // destined for him. if _, err := net.Miner.Node.Generate(defaultCSV); err != nil { t.Fatalf("unable to generate block: %v", err) } _, err = waitForTxInMempool(net.Miner.Node, time.Second*10) if err != nil { t.Fatalf("unable to find bob's sweeping transaction") } // At this point, Bob should detect that he has no pending channels // anymore, as this just resolved it by the confirmation of the sweep // transaction we detected above. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate block: %v", err) } err = lntest.WaitPredicate(func() bool { pendingChanResp, err := net.Bob.PendingChannels( ctxb, pendingChansRequest, ) if err != nil { predErr = fmt.Errorf("unable to query for pending "+ "channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) != 0 { predErr = fmt.Errorf("bob still has pending channels "+ "but shouldn't: %v", spew.Sdump(pendingChanResp)) return false } return true }, time.Second*15) if err != nil { t.Fatalf(predErr.Error()) } // Clean up carol's node. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } // testMultiHopHtlcRemoteChainClaim tests that in the multi-hop HTLC scenario, // if the remote party goes to chain while we have an incoming HTLC, then when // we found out the preimage via the witness beacon, we properly settle the // HTLC on-chain in order to ensure that we don't lose any funds. func testMultiHopHtlcRemoteChainClaim(net *lntest.NetworkHarness, t *harnessTest) { timeout := time.Duration(time.Second * 15) ctxb := context.Background() // First, we'll create a three hop network: Alice -> Bob -> Carol, with // Carol refusing to actually settle or directly cancel any HTLC's // self. aliceChanPoint, bobChanPoint, carol := createThreeHopHodlNetwork(t, net) // With the network active, we'll now add a new invoice at Carol's end. invoiceReq := &lnrpc.Invoice{ Value: 100000, } carolInvoice, err := carol.AddInvoice(ctxb, invoiceReq) if err != nil { t.Fatalf("unable to generate carol invoice: %v", err) } // Now that we've created the invoice, we'll send a single payment from // Alice to Carol. We won't wait for the response however, as Carol // will not immediately settle the payment. alicePayStream, err := net.Alice.SendPayment(ctxb) if err != nil { t.Fatalf("unable to create payment stream for alice: %v", err) } err = alicePayStream.Send(&lnrpc.SendRequest{ PaymentRequest: carolInvoice.PaymentRequest, }) if err != nil { t.Fatalf("unable to send payment: %v", err) } // We'll now wait until all 3 nodes have the HTLC as just sent fully // locked in. var predErr error nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol} err = lntest.WaitPredicate(func() bool { predErr = assertActiveHtlcs(nodes, carolInvoice.RHash) if predErr != nil { return false } return true }, time.Second*15) if err != nil { t.Fatalf("htlc mismatch: %v", err) } // Next, Alice decides that she wants to exit the channel, so she'll // immediately force close the channel by broadcast her commitment // transaction. ctxt, _ := context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, aliceChanPoint, true) // We'll now mine enough blocks so Carol decides that she needs to go // on-chain to claim the HTLC as Bob has been inactive. claimDelta := uint32(2 * defaultBroadcastDelta) numBlocks := uint32(defaultBitcoinTimeLockDelta - claimDelta) if _, err := net.Miner.Node.Generate(numBlocks); err != nil { t.Fatalf("unable to generate blocks") } // Carol's commitment transaction should now be in the mempool. She // should also have broadcast her second level HTLC transaction. txids, err := waitForNTxsInMempool(net.Miner.Node, 2, time.Second*15) if err != nil { t.Fatalf("transactions not found in mempool: %v", err) } txidHash, err := getChanPointFundingTxid(bobChanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } bobFundingTxid, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } carolFundingPoint := wire.OutPoint{ Hash: *bobFundingTxid, Index: bobChanPoint.OutputIndex, } // Of the two transactions, one should be spending from the funding // transaction, and the second transaction should then be spending from // the commitment transaction. var commitHash *chainhash.Hash tx1, err := net.Miner.Node.GetRawTransaction(txids[0]) if err != nil { t.Fatalf("unable to get txn: %v", err) } tx1Hash := tx1.MsgTx().TxHash() tx2, err := net.Miner.Node.GetRawTransaction(txids[1]) if err != nil { t.Fatalf("unable to get txn: %v", err) } tx2Hash := tx2.MsgTx().TxHash() if tx1.MsgTx().TxIn[0].PreviousOutPoint == carolFundingPoint { commitHash = &tx1Hash if tx2.MsgTx().TxIn[0].PreviousOutPoint.Hash != *commitHash { t.Fatalf("second transaction not spending commit tx: %v", spew.Sdump(tx2)) } } if tx2.MsgTx().TxIn[0].PreviousOutPoint == carolFundingPoint { commitHash = &tx2Hash if tx1.MsgTx().TxIn[0].PreviousOutPoint.Hash != *commitHash { t.Fatalf("second transaction not spending commit tx: %v", spew.Sdump(tx1)) } } if commitHash == nil { t.Fatalf("commit tx not found in mempool") } // We'll now mine a block which should confirm both the second layer // transaction as well as the commitment transaction. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate block: %v", err) } // With the block mined above, Bob should detect that Carol is // attempting to sweep the HTLC on-chain, and should obtain the // preimage. _, err = waitForNTxsInMempool(net.Miner.Node, 2, time.Second*15) if err != nil { t.Fatalf("unable to find bob's sweeping transaction") } // We'll now mine another block, this should confirm the sweep // transaction that Bob broadcast in the prior stage. if _, err := net.Miner.Node.Generate(1); err != nil { t.Fatalf("unable to generate block: %v", err) } // Now that the sweeping transaction has been confirmed, Bob should now // recognize that all contracts have been fully resolved, and show no // pending close channels. pendingChansRequest := &lnrpc.PendingChannelsRequest{} err = lntest.WaitPredicate(func() bool { pendingChanResp, err := net.Bob.PendingChannels( ctxb, pendingChansRequest, ) if err != nil { predErr = fmt.Errorf("unable to query for pending "+ "channels: %v", err) return false } if len(pendingChanResp.PendingForceClosingChannels) != 0 { predErr = fmt.Errorf("bob still has pending channels "+ "but shouldn't: %v", spew.Sdump(pendingChanResp)) return false } return true }, time.Second*15) if err != nil { t.Fatalf(predErr.Error()) } if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } } // testSwitchCircuitPersistence creates a multihop network to ensure the sender // and intermediaries are persisting their open payment circuits. After // forwarding a packet via an outgoing link, all are restarted, and expected to // forward a response back from the receiver once back online. // // The general flow of this test: // 1. Carol --> Dave --> Alice --> Bob forward payment // 2. X X X Bob restart sender and intermediaries // 3. Carol <-- Dave <-- Alice <-- Bob expect settle to propagate func testSwitchCircuitPersistence(net *lntest.NetworkHarness, t *harnessTest) { const chanAmt = btcutil.Amount(1000000) const pushAmt = btcutil.Amount(900000) ctxb := context.Background() timeout := time.Duration(time.Second * 15) var networkChans []*lnrpc.ChannelPoint // Open a channel with 100k satoshis between Alice and Bob with Alice // being the sole funder of the channel. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPointAlice := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, pushAmt) networkChans = append(networkChans, chanPointAlice) txidHash, err := getChanPointFundingTxid(chanPointAlice) if err != nil { t.Fatalf("unable to get txid: %v", err) } aliceChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } aliceFundPoint := wire.OutPoint{ Hash: *aliceChanTXID, Index: chanPointAlice.OutputIndex, } // As preliminary setup, we'll create two new nodes: Carol and Dave, // such that we now have a 4 ndoe, 3 channel topology. Dave will make // a channel with Alice, and Carol with Dave. After this setup, the // network topology should now look like: // Carol -> Dave -> Alice -> Bob // // First, we'll create Dave and establish a channel to Alice. dave, err := net.NewNode(nil) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, dave, net.Alice); err != nil { t.Fatalf("unable to connect dave to alice: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, dave) if err != nil { t.Fatalf("unable to send coins to dave: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointDave := openChannelAndAssert(ctxt, t, net, dave, net.Alice, chanAmt, pushAmt) networkChans = append(networkChans, chanPointDave) txidHash, err = getChanPointFundingTxid(chanPointDave) if err != nil { t.Fatalf("unable to get txid: %v", err) } daveChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } daveFundPoint := wire.OutPoint{ Hash: *daveChanTXID, Index: chanPointDave.OutputIndex, } // Next, we'll create Carol and establish a channel to from her to // Dave. Carol is started in htlchodl mode so that we can disconnect the // intermediary hops before starting the settle. carol, err := net.NewNode([]string{"--debughtlc", "--hodlhtlc"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, carol, dave); err != nil { t.Fatalf("unable to connect carol to dave: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, carol) if err != nil { t.Fatalf("unable to send coins to carol: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointCarol := openChannelAndAssert(ctxt, t, net, carol, dave, chanAmt, pushAmt) networkChans = append(networkChans, chanPointCarol) txidHash, err = getChanPointFundingTxid(chanPointCarol) if err != nil { t.Fatalf("unable to get txid: %v", err) } carolChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } carolFundPoint := wire.OutPoint{ Hash: *carolChanTXID, Index: chanPointCarol.OutputIndex, } // Wait for all nodes to have seen all channels. nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol, dave} nodeNames := []string{"Alice", "Bob", "Carol", "Dave"} for _, chanPoint := range networkChans { for i, node := range nodes { txidHash, err := getChanPointFundingTxid(chanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } txid, e := chainhash.NewHash(txidHash) if e != nil { t.Fatalf("unable to create sha hash: %v", e) } point := wire.OutPoint{ Hash: *txid, Index: chanPoint.OutputIndex, } ctxt, _ = context.WithTimeout(ctxb, timeout) err = node.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("%s(%d): timeout waiting for "+ "channel(%s) open: %v", nodeNames[i], node.NodeID, point, err) } } } // Create 5 invoices for Carol, which expect a payment from Bob for 1k // satoshis with a different preimage each time. const numPayments = 5 const paymentAmt = 1000 payReqs := make([]string, numPayments) for i := 0; i < numPayments; i++ { invoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt, } resp, err := carol.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs[i] = resp.PaymentRequest } // We'll wait for all parties to recognize the new channels within the // network. ctxt, _ = context.WithTimeout(ctxb, timeout) err = dave.WaitForNetworkChannelOpen(ctxt, chanPointDave) if err != nil { t.Fatalf("dave didn't advertise his channel: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) err = carol.WaitForNetworkChannelOpen(ctxt, chanPointCarol) if err != nil { t.Fatalf("carol didn't advertise her channel in time: %v", err) } time.Sleep(time.Millisecond * 50) // Using Carol as the source, pay to the 5 invoices from Bob created // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Bob, payReqs, false) if err != nil { t.Fatalf("unable to send payments: %v", err) } time.Sleep(time.Millisecond * 200) // Restart the intermediaries and the sender. if err := net.RestartNode(dave, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } if err := net.RestartNode(net.Alice, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } if err := net.RestartNode(net.Bob, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } // Now restart carol without hodl mode, to settle back the outstanding // payments. carol.SetExtraArgs(nil) if err := net.RestartNode(carol, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } time.Sleep(time.Second * 5) // When asserting the amount of satoshis moved, we'll factor in the // default base fee, as we didn't modify the fee structure when // creating the seed nodes in the network. const baseFee = 1 // At this point all the channels within our proto network should be // shifted by 5k satoshis in the direction of Carol, the sink within the // payment flow generated above. The order of asserts corresponds to // increasing of time is needed to embed the HTLC in commitment // transaction, in channel Bob->Alice->David->Carol, order is Carol, // David, Alice, Bob. var amountPaid = int64(5000) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", carol, carolFundPoint, int64(0), amountPaid) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", dave, carolFundPoint, amountPaid, int64(0)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", dave, daveFundPoint, int64(0), amountPaid+(baseFee*numPayments)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", net.Alice, daveFundPoint, amountPaid+(baseFee*numPayments), int64(0)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Alice, aliceFundPoint, int64(0), amountPaid+((baseFee*numPayments)*2)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Bob, aliceFundPoint, amountPaid+(baseFee*numPayments)*2, int64(0)) // Lastly, we will send one more payment to ensure all channels are // still functioning properly. finalInvoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt, } resp, err := carol.AddInvoice(ctxb, finalInvoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs = []string{resp.PaymentRequest} // Using Carol as the source, pay to the 5 invoices from Bob created // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Bob, payReqs, true) if err != nil { t.Fatalf("unable to send payments: %v", err) } amountPaid = int64(6000) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", carol, carolFundPoint, int64(0), amountPaid) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", dave, carolFundPoint, amountPaid, int64(0)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", dave, daveFundPoint, int64(0), amountPaid+(baseFee*(numPayments+1))) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", net.Alice, daveFundPoint, amountPaid+(baseFee*(numPayments+1)), int64(0)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Alice, aliceFundPoint, int64(0), amountPaid+((baseFee*(numPayments+1))*2)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Bob, aliceFundPoint, amountPaid+(baseFee*(numPayments+1))*2, int64(0)) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPointAlice, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, dave, chanPointDave, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, carol, chanPointCarol, false) // Finally, shutdown the nodes we created for the duration of the tests, // only leaving the two seed nodes (Alice and Bob) within our test // network. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } if err := net.ShutdownNode(dave); err != nil { t.Fatalf("unable to shutdown dave: %v", err) } } // testSwitchOfflineDelivery constructs a set of multihop payments, and tests // that the returning payments are not lost if a peer on the backwards path is // offline when the settle/fails are received. We expect the payments to be // buffered in memory, and transmitted as soon as the disconnect link comes back // online. // // The general flow of this test: // 1. Carol --> Dave --> Alice --> Bob forward payment // 2. Carol --- Dave X Alice --- Bob disconnect intermediaries // 3. Carol --- Dave X Alice <-- Bob settle last hop // 4. Carol <-- Dave <-- Alice --- Bob reconnect, expect settle to propagate func testSwitchOfflineDelivery(net *lntest.NetworkHarness, t *harnessTest) { const chanAmt = btcutil.Amount(1000000) const pushAmt = btcutil.Amount(900000) ctxb := context.Background() timeout := time.Duration(time.Second * 15) var networkChans []*lnrpc.ChannelPoint // Open a channel with 100k satoshis between Alice and Bob with Alice // being the sole funder of the channel. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPointAlice := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, pushAmt) networkChans = append(networkChans, chanPointAlice) txidHash, err := getChanPointFundingTxid(chanPointAlice) if err != nil { t.Fatalf("unable to get txid: %v", err) } aliceChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } aliceFundPoint := wire.OutPoint{ Hash: *aliceChanTXID, Index: chanPointAlice.OutputIndex, } // As preliminary setup, we'll create two new nodes: Carol and Dave, // such that we now have a 4 ndoe, 3 channel topology. Dave will make // a channel with Alice, and Carol with Dave. After this setup, the // network topology should now look like: // Carol -> Dave -> Alice -> Bob // // First, we'll create Dave and establish a channel to Alice. dave, err := net.NewNode([]string{"--unsafe-disconnect"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, dave, net.Alice); err != nil { t.Fatalf("unable to connect dave to alice: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, dave) if err != nil { t.Fatalf("unable to send coins to dave: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointDave := openChannelAndAssert(ctxt, t, net, dave, net.Alice, chanAmt, pushAmt) networkChans = append(networkChans, chanPointDave) txidHash, err = getChanPointFundingTxid(chanPointDave) if err != nil { t.Fatalf("unable to get txid: %v", err) } daveChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } daveFundPoint := wire.OutPoint{ Hash: *daveChanTXID, Index: chanPointDave.OutputIndex, } // Next, we'll create Carol and establish a channel to from her to // Dave. Carol is started in htlchodl mode so that we can disconnect the // intermediary hops before starting the settle. carol, err := net.NewNode([]string{"--debughtlc", "--hodlhtlc"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, carol, dave); err != nil { t.Fatalf("unable to connect carol to dave: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, carol) if err != nil { t.Fatalf("unable to send coins to carol: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointCarol := openChannelAndAssert(ctxt, t, net, carol, dave, chanAmt, pushAmt) networkChans = append(networkChans, chanPointCarol) txidHash, err = getChanPointFundingTxid(chanPointCarol) if err != nil { t.Fatalf("unable to get txid: %v", err) } carolChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } carolFundPoint := wire.OutPoint{ Hash: *carolChanTXID, Index: chanPointCarol.OutputIndex, } // Wait for all nodes to have seen all channels. nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol, dave} nodeNames := []string{"Alice", "Bob", "Carol", "Dave"} for _, chanPoint := range networkChans { for i, node := range nodes { txidHash, err := getChanPointFundingTxid(chanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } txid, e := chainhash.NewHash(txidHash) if e != nil { t.Fatalf("unable to create sha hash: %v", e) } point := wire.OutPoint{ Hash: *txid, Index: chanPoint.OutputIndex, } ctxt, _ = context.WithTimeout(ctxb, timeout) err = node.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("%s(%d): timeout waiting for "+ "channel(%s) open: %v", nodeNames[i], node.NodeID, point, err) } } } // Create 5 invoices for Carol, which expect a payment from Bob for 1k // satoshis with a different preimage each time. const numPayments = 5 const paymentAmt = 1000 payReqs := make([]string, numPayments) for i := 0; i < numPayments; i++ { invoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt, } resp, err := carol.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs[i] = resp.PaymentRequest } // We'll wait for all parties to recognize the new channels within the // network. ctxt, _ = context.WithTimeout(ctxb, timeout) err = dave.WaitForNetworkChannelOpen(ctxt, chanPointDave) if err != nil { t.Fatalf("dave didn't advertise his channel: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) err = carol.WaitForNetworkChannelOpen(ctxt, chanPointCarol) if err != nil { t.Fatalf("carol didn't advertise her channel in time: %v", err) } time.Sleep(time.Millisecond * 50) // Using Carol as the source, pay to the 5 invoices from Bob created // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Bob, payReqs, false) if err != nil { t.Fatalf("unable to send payments: %v", err) } time.Sleep(2 * time.Second) // First, disconnect Dave and Alice so that their link is broken. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.DisconnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to disconnect alice from dave: %v", err) } // Then, reconnect them to ensure Dave doesn't just fail back the htlc. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.ConnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to reconnect alice to dave: %v", err) } // Now, disconnect Dave from Alice again before settling back the // payment. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.DisconnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to disconnect alice from dave: %v", err) } // Now restart carol without hodl mode, to settle back the outstanding // payments. carol.SetExtraArgs(nil) if err := net.RestartNode(carol, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } time.Sleep(200 * time.Millisecond) ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.ConnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to reconnect alice to dave: %v", err) } time.Sleep(200 * time.Millisecond) // When asserting the amount of satoshis moved, we'll factor in the // default base fee, as we didn't modify the fee structure when // creating the seed nodes in the network. const baseFee = 1 // At this point all the channels within our proto network should be // shifted by 5k satoshis in the direction of Carol, the sink within the // payment flow generated above. The order of asserts corresponds to // increasing of time is needed to embed the HTLC in commitment // transaction, in channel Bob->Alice->David->Carol, order is Carol, // David, Alice, Bob. var amountPaid = int64(5000) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", carol, carolFundPoint, int64(0), amountPaid) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", dave, carolFundPoint, amountPaid, int64(0)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", dave, daveFundPoint, int64(0), amountPaid+(baseFee*numPayments)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", net.Alice, daveFundPoint, amountPaid+(baseFee*numPayments), int64(0)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Alice, aliceFundPoint, int64(0), amountPaid+((baseFee*numPayments)*2)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Bob, aliceFundPoint, amountPaid+(baseFee*numPayments)*2, int64(0)) ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.DisconnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to disconnect alice from dave: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.ConnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to reconnect alice to dave: %v", err) } // Lastly, we will send one more payment to ensure all channels are // still functioning properly. finalInvoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt, } resp, err := carol.AddInvoice(ctxb, finalInvoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs = []string{resp.PaymentRequest} // Using Carol as the source, pay to the 5 invoices from Bob created // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Bob, payReqs, true) if err != nil { t.Fatalf("unable to send payments: %v", err) } amountPaid = int64(6000) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", carol, carolFundPoint, int64(0), amountPaid) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", dave, carolFundPoint, amountPaid, int64(0)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", dave, daveFundPoint, int64(0), amountPaid+(baseFee*(numPayments+1))) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", net.Alice, daveFundPoint, amountPaid+(baseFee*(numPayments+1)), int64(0)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Alice, aliceFundPoint, int64(0), amountPaid+((baseFee*(numPayments+1))*2)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Bob, aliceFundPoint, amountPaid+(baseFee*(numPayments+1))*2, int64(0)) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPointAlice, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, dave, chanPointDave, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, carol, chanPointCarol, false) // Finally, shutdown the nodes we created for the duration of the tests, // only leaving the two seed nodes (Alice and Bob) within our test // network. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } if err := net.ShutdownNode(dave); err != nil { t.Fatalf("unable to shutdown dave: %v", err) } } // testSwitchOfflineDeliveryPersistence constructs a set of multihop payments, // and tests that the returning payments are not lost if a peer on the backwards // path is offline when the settle/fails are received AND the peer buffering the // responses is completely restarts. We expect the payments to be reloaded from // disk, and transmitted as soon as the intermediaries are reconnected. // // The general flow of this test: // 1. Carol --> Dave --> Alice --> Bob forward payment // 2. Carol --- Dave X Alice --- Bob disconnect intermediaries // 3. Carol --- Dave X Alice <-- Bob settle last hop // 4. Carol --- Dave X X Bob restart Alice // 5. Carol <-- Dave <-- Alice --- Bob expect settle to propagate func testSwitchOfflineDeliveryPersistence(net *lntest.NetworkHarness, t *harnessTest) { const chanAmt = btcutil.Amount(1000000) const pushAmt = btcutil.Amount(900000) ctxb := context.Background() timeout := time.Duration(time.Second * 15) var networkChans []*lnrpc.ChannelPoint // Open a channel with 100k satoshis between Alice and Bob with Alice // being the sole funder of the channel. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPointAlice := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, pushAmt) networkChans = append(networkChans, chanPointAlice) txidHash, err := getChanPointFundingTxid(chanPointAlice) if err != nil { t.Fatalf("unable to get txid: %v", err) } aliceChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } aliceFundPoint := wire.OutPoint{ Hash: *aliceChanTXID, Index: chanPointAlice.OutputIndex, } // As preliminary setup, we'll create two new nodes: Carol and Dave, // such that we now have a 4 ndoe, 3 channel topology. Dave will make // a channel with Alice, and Carol with Dave. After this setup, the // network topology should now look like: // Carol -> Dave -> Alice -> Bob // // First, we'll create Dave and establish a channel to Alice. dave, err := net.NewNode([]string{"--unsafe-disconnect"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, dave, net.Alice); err != nil { t.Fatalf("unable to connect dave to alice: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, dave) if err != nil { t.Fatalf("unable to send coins to dave: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointDave := openChannelAndAssert(ctxt, t, net, dave, net.Alice, chanAmt, pushAmt) networkChans = append(networkChans, chanPointDave) txidHash, err = getChanPointFundingTxid(chanPointDave) if err != nil { t.Fatalf("unable to get txid: %v", err) } daveChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } daveFundPoint := wire.OutPoint{ Hash: *daveChanTXID, Index: chanPointDave.OutputIndex, } // Next, we'll create Carol and establish a channel to from her to // Dave. Carol is started in htlchodl mode so that we can disconnect the // intermediary hops before starting the settle. carol, err := net.NewNode([]string{"--debughtlc", "--hodlhtlc"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, carol, dave); err != nil { t.Fatalf("unable to connect carol to dave: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, carol) if err != nil { t.Fatalf("unable to send coins to carol: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointCarol := openChannelAndAssert(ctxt, t, net, carol, dave, chanAmt, pushAmt) networkChans = append(networkChans, chanPointCarol) txidHash, err = getChanPointFundingTxid(chanPointCarol) if err != nil { t.Fatalf("unable to get txid: %v", err) } carolChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } carolFundPoint := wire.OutPoint{ Hash: *carolChanTXID, Index: chanPointCarol.OutputIndex, } // Wait for all nodes to have seen all channels. nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol, dave} nodeNames := []string{"Alice", "Bob", "Carol", "Dave"} for _, chanPoint := range networkChans { for i, node := range nodes { txidHash, err := getChanPointFundingTxid(chanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } txid, e := chainhash.NewHash(txidHash) if e != nil { t.Fatalf("unable to create sha hash: %v", e) } point := wire.OutPoint{ Hash: *txid, Index: chanPoint.OutputIndex, } ctxt, _ = context.WithTimeout(ctxb, timeout) err = node.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("%s(%d): timeout waiting for "+ "channel(%s) open: %v", nodeNames[i], node.NodeID, point, err) } } } // Create 5 invoices for Carol, which expect a payment from Bob for 1k // satoshis with a different preimage each time. const numPayments = 5 const paymentAmt = 1000 payReqs := make([]string, numPayments) for i := 0; i < numPayments; i++ { invoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt, } resp, err := carol.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs[i] = resp.PaymentRequest } // We'll wait for all parties to recognize the new channels within the // network. ctxt, _ = context.WithTimeout(ctxb, timeout) err = dave.WaitForNetworkChannelOpen(ctxt, chanPointDave) if err != nil { t.Fatalf("dave didn't advertise his channel: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) err = carol.WaitForNetworkChannelOpen(ctxt, chanPointCarol) if err != nil { t.Fatalf("carol didn't advertise her channel in time: %v", err) } time.Sleep(time.Millisecond * 50) // Using Carol as the source, pay to the 5 invoices from Bob created // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Bob, payReqs, false) if err != nil { t.Fatalf("unable to send payments: %v", err) } time.Sleep(2 * time.Second) // Restart the intermediaries and the sender. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.DisconnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to disconnect alice from dave: %v", err) } // Now restart carol without hodl mode, to settle back the outstanding // payments. carol.SetExtraArgs(nil) if err := net.RestartNode(carol, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } time.Sleep(200 * time.Millisecond) if err := net.RestartNode(dave, nil); err != nil { t.Fatalf("unable to reconnect alice to dave: %v", err) } time.Sleep(200 * time.Millisecond) // When asserting the amount of satoshis moved, we'll factor in the // default base fee, as we didn't modify the fee structure when // creating the seed nodes in the network. const baseFee = 1 // At this point all the channels within our proto network should be // shifted by 5k satoshis in the direction of Carol, the sink within the // payment flow generated above. The order of asserts corresponds to // increasing of time is needed to embed the HTLC in commitment // transaction, in channel Bob->Alice->David->Carol, order is Carol, // David, Alice, Bob. var amountPaid = int64(5000) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", carol, carolFundPoint, int64(0), amountPaid) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", dave, carolFundPoint, amountPaid, int64(0)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", dave, daveFundPoint, int64(0), amountPaid+(baseFee*numPayments)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", net.Alice, daveFundPoint, amountPaid+(baseFee*numPayments), int64(0)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Alice, aliceFundPoint, int64(0), amountPaid+((baseFee*numPayments)*2)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Bob, aliceFundPoint, amountPaid+(baseFee*numPayments)*2, int64(0)) ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.DisconnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to disconnect alice from dave: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.ConnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to reconnect alice to dave: %v", err) } // Lastly, we will send one more payment to ensure all channels are // still functioning properly. finalInvoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt, } resp, err := carol.AddInvoice(ctxb, finalInvoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs = []string{resp.PaymentRequest} // Using Carol as the source, pay to the 5 invoices from Bob created // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Bob, payReqs, true) if err != nil { t.Fatalf("unable to send payments: %v", err) } amountPaid = int64(6000) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", carol, carolFundPoint, int64(0), amountPaid) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", dave, carolFundPoint, amountPaid, int64(0)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", dave, daveFundPoint, int64(0), amountPaid+(baseFee*(numPayments+1))) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", net.Alice, daveFundPoint, amountPaid+(baseFee*(numPayments+1)), int64(0)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Alice, aliceFundPoint, int64(0), amountPaid+((baseFee*(numPayments+1))*2)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Bob, aliceFundPoint, amountPaid+(baseFee*(numPayments+1))*2, int64(0)) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPointAlice, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, dave, chanPointDave, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, carol, chanPointCarol, false) // Finally, shutdown the nodes we created for the duration of the tests, // only leaving the two seed nodes (Alice and Bob) within our test // network. if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } if err := net.ShutdownNode(dave); err != nil { t.Fatalf("unable to shutdown dave: %v", err) } } // testSwitchOfflineDeliveryOutgoingOffline constructs a set of multihop payments, // and tests that the returning payments are not lost if a peer on the backwards // path is offline when the settle/fails are received AND the peer buffering the // responses is completely restarts. We expect the payments to be reloaded from // disk, and transmitted as soon as the intermediaries are reconnected. // // The general flow of this test: // 1. Carol --> Dave --> Alice --> Bob forward payment // 2. Carol --- Dave X Alice --- Bob disconnect intermediaries // 3. Carol --- Dave X Alice <-- Bob settle last hop // 4. Carol --- Dave X X shutdown Bob, restart Alice // 5. Carol <-- Dave <-- Alice X expect settle to propagate func testSwitchOfflineDeliveryOutgoingOffline( net *lntest.NetworkHarness, t *harnessTest) { const chanAmt = btcutil.Amount(1000000) const pushAmt = btcutil.Amount(900000) ctxb := context.Background() timeout := time.Duration(time.Second * 15) var networkChans []*lnrpc.ChannelPoint // Open a channel with 100k satoshis between Alice and Bob with Alice // being the sole funder of the channel. ctxt, _ := context.WithTimeout(ctxb, timeout) chanPointAlice := openChannelAndAssert(ctxt, t, net, net.Alice, net.Bob, chanAmt, pushAmt) networkChans = append(networkChans, chanPointAlice) txidHash, err := getChanPointFundingTxid(chanPointAlice) if err != nil { t.Fatalf("unable to get txid: %v", err) } aliceChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } aliceFundPoint := wire.OutPoint{ Hash: *aliceChanTXID, Index: chanPointAlice.OutputIndex, } // As preliminary setup, we'll create two new nodes: Carol and Dave, // such that we now have a 4 ndoe, 3 channel topology. Dave will make // a channel with Alice, and Carol with Dave. After this setup, the // network topology should now look like: // Carol -> Dave -> Alice -> Bob // // First, we'll create Dave and establish a channel to Alice. dave, err := net.NewNode([]string{"--unsafe-disconnect"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, dave, net.Alice); err != nil { t.Fatalf("unable to connect dave to alice: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, dave) if err != nil { t.Fatalf("unable to send coins to dave: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointDave := openChannelAndAssert(ctxt, t, net, dave, net.Alice, chanAmt, pushAmt) networkChans = append(networkChans, chanPointDave) txidHash, err = getChanPointFundingTxid(chanPointDave) if err != nil { t.Fatalf("unable to get txid: %v", err) } daveChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } daveFundPoint := wire.OutPoint{ Hash: *daveChanTXID, Index: chanPointDave.OutputIndex, } // Next, we'll create Carol and establish a channel to from her to // Dave. Carol is started in htlchodl mode so that we can disconnect the // intermediary hops before starting the settle. carol, err := net.NewNode([]string{"--debughtlc", "--hodlhtlc"}) if err != nil { t.Fatalf("unable to create new nodes: %v", err) } if err := net.ConnectNodes(ctxb, carol, dave); err != nil { t.Fatalf("unable to connect carol to dave: %v", err) } err = net.SendCoins(ctxb, btcutil.SatoshiPerBitcoin, carol) if err != nil { t.Fatalf("unable to send coins to carol: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) chanPointCarol := openChannelAndAssert(ctxt, t, net, carol, dave, chanAmt, pushAmt) networkChans = append(networkChans, chanPointCarol) txidHash, err = getChanPointFundingTxid(chanPointCarol) if err != nil { t.Fatalf("unable to get txid: %v", err) } carolChanTXID, err := chainhash.NewHash(txidHash) if err != nil { t.Fatalf("unable to create sha hash: %v", err) } carolFundPoint := wire.OutPoint{ Hash: *carolChanTXID, Index: chanPointCarol.OutputIndex, } // Wait for all nodes to have seen all channels. nodes := []*lntest.HarnessNode{net.Alice, net.Bob, carol, dave} nodeNames := []string{"Alice", "Bob", "Carol", "Dave"} for _, chanPoint := range networkChans { for i, node := range nodes { txidHash, err := getChanPointFundingTxid(chanPoint) if err != nil { t.Fatalf("unable to get txid: %v", err) } txid, e := chainhash.NewHash(txidHash) if e != nil { t.Fatalf("unable to create sha hash: %v", e) } point := wire.OutPoint{ Hash: *txid, Index: chanPoint.OutputIndex, } ctxt, _ = context.WithTimeout(ctxb, timeout) err = node.WaitForNetworkChannelOpen(ctxt, chanPoint) if err != nil { t.Fatalf("%s(%d): timeout waiting for "+ "channel(%s) open: %v", nodeNames[i], node.NodeID, point, err) } } } // Create 5 invoices for Carol, which expect a payment from Bob for 1k // satoshis with a different preimage each time. const numPayments = 5 const paymentAmt = 1000 payReqs := make([]string, numPayments) for i := 0; i < numPayments; i++ { invoice := &lnrpc.Invoice{ Memo: "testing", Value: paymentAmt, } resp, err := carol.AddInvoice(ctxb, invoice) if err != nil { t.Fatalf("unable to add invoice: %v", err) } payReqs[i] = resp.PaymentRequest } // We'll wait for all parties to recognize the new channels within the // network. ctxt, _ = context.WithTimeout(ctxb, timeout) err = dave.WaitForNetworkChannelOpen(ctxt, chanPointDave) if err != nil { t.Fatalf("dave didn't advertise his channel: %v", err) } ctxt, _ = context.WithTimeout(ctxb, timeout) err = carol.WaitForNetworkChannelOpen(ctxt, chanPointCarol) if err != nil { t.Fatalf("carol didn't advertise her channel in time: %v", err) } time.Sleep(time.Millisecond * 50) // Using Carol as the source, pay to the 5 invoices from Bob created // above. ctxt, _ = context.WithTimeout(ctxb, timeout) err = completePaymentRequests(ctxt, net.Bob, payReqs, false) if err != nil { t.Fatalf("unable to send payments: %v", err) } time.Sleep(2 * time.Second) // Restart the intermediaries and the sender. ctxt, _ = context.WithTimeout(ctxb, timeout) if err := net.DisconnectNodes(ctxt, dave, net.Alice); err != nil { t.Fatalf("unable to disconnect alice from dave: %v", err) } // Now restart carol without hodl mode, to settle back the outstanding // payments. carol.SetExtraArgs(nil) if err := net.RestartNode(carol, nil); err != nil { t.Fatalf("Node restart failed: %v", err) } time.Sleep(200 * time.Millisecond) const amountPaid = int64(5000) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", carol, carolFundPoint, int64(0), amountPaid) assertAmountPaid(t, ctxb, "Dave(local) => Carol(remote)", dave, carolFundPoint, amountPaid, int64(0)) if err := net.ShutdownNode(carol); err != nil { t.Fatalf("unable to shutdown carol: %v", err) } if err := net.RestartNode(dave, nil); err != nil { t.Fatalf("unable to reconnect alice to dave: %v", err) } time.Sleep(200 * time.Millisecond) // When asserting the amount of satoshis moved, we'll factor in the // default base fee, as we didn't modify the fee structure when // creating the seed nodes in the network. const baseFee = 1 // At this point all the channels within our proto network should be // shifted by 5k satoshis in the direction of Carol, the sink within the // payment flow generated above. The order of asserts corresponds to // increasing of time is needed to embed the HTLC in commitment // transaction, in channel Bob->Alice->David->Carol, order is Carol, // David, Alice, Bob. assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", dave, daveFundPoint, int64(0), amountPaid+(baseFee*numPayments)) assertAmountPaid(t, ctxb, "Alice(local) => Dave(remote)", net.Alice, daveFundPoint, amountPaid+(baseFee*numPayments), int64(0)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Alice, aliceFundPoint, int64(0), amountPaid+((baseFee*numPayments)*2)) assertAmountPaid(t, ctxb, "Bob(local) => Alice(remote)", net.Bob, aliceFundPoint, amountPaid+(baseFee*numPayments)*2, int64(0)) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, net.Alice, chanPointAlice, false) ctxt, _ = context.WithTimeout(ctxb, timeout) closeChannelAndAssert(ctxt, t, net, dave, chanPointDave, false) // Finally, shutdown the nodes we created for the duration of the tests, // only leaving the two seed nodes (Alice and Bob) within our test // network. if err := net.ShutdownNode(dave); err != nil { t.Fatalf("unable to shutdown dave: %v", err) } } type testCase struct { name string test func(net *lntest.NetworkHarness, t *harnessTest) } var testsCases = []*testCase{ { name: "basic funding flow", test: testBasicChannelFunding, }, { name: "update channel policy", test: testUpdateChannelPolicy, }, { name: "open channel reorg test", test: testOpenChannelAfterReorg, }, { name: "disconnecting target peer", test: testDisconnectingTargetPeer, }, { name: "graph topology notifications", test: testGraphTopologyNotifications, }, { name: "funding flow persistence", test: testChannelFundingPersistence, }, { name: "channel force closure", test: testChannelForceClosure, }, { name: "channel balance", test: testChannelBalance, }, { name: "single hop invoice", test: testSingleHopInvoice, }, { name: "sphinx replay persistence", test: testSphinxReplayPersistence, }, { name: "list outgoing payments", test: testListPayments, }, { name: "max pending channel", test: testMaxPendingChannels, }, { name: "multi-hop payments", test: testMultiHopPayments, }, { name: "private channels", test: testPrivateChannels, }, { name: "multiple channel creation", test: testBasicChannelCreation, }, { name: "invoice update subscription", test: testInvoiceSubscriptions, }, { name: "multi-hop htlc error propagation", test: testHtlcErrorPropagation, }, // TODO(roasbeef): multi-path integration test { name: "node announcement", test: testNodeAnnouncement, }, { name: "node sign verify", test: testNodeSignVerify, }, { name: "async payments benchmark", test: testAsyncPayments, }, { name: "async bidirectional payments", test: testBidirectionalAsyncPayments, }, { // bob: outgoing our commit timeout // carol: incoming their commit watch and see timeout name: "test multi-hop htlc local force close immediate expiry", test: testMultiHopHtlcLocalTimeout, }, { // bob: outgoing watch and see, they sweep on chain // carol: incoming our commit, know preimage name: "test multi-hop htlc receiver chain claim", test: testMultiHopReceiverChainClaim, }, { // bob: outgoing our commit watch and see timeout // carol: incoming their commit watch and see timeout name: "test multi-hop local force close on-chain htlc timeout", test: testMultiHopLocalForceCloseOnChainHtlcTimeout, }, { // bob: outgoing their commit watch and see timeout // carol: incoming our commit watch and see timeout name: "test multi-hop remote force close on-chain htlc timeout", test: testMultHopRemoteForceCloseOnChainHtlcTimeout, }, { // bob: outgoing our commit watch and see, they sweep on chain // bob: incoming our commit watch and learn preimage // carol: incoming their commit know preimage name: "test multi-hop htlc local chain claim", test: testMultiHopHtlcLocalChainClaim, }, { // bob: outgoing their commit watch and see, they sweep on chain // bob: incoming their commit watch and learn preimage // carol: incoming our commit know preimage name: "test multi-hop htlc remote chain claim", test: testMultiHopHtlcRemoteChainClaim, }, { // TODO(roasbeef): test always needs to be last as Bob's state // is borked since we trick him into attempting to cheat Alice? name: "revoked uncooperative close retribution", test: testRevokedCloseRetribution, }, { name: "revoked uncooperative close retribution zero value remote output", test: testRevokedCloseRetributionZeroValueRemoteOutput, }, { name: "revoked uncooperative close retribution remote hodl", test: testRevokedCloseRetributionRemoteHodl, }, { name: "switch circuit persistence", test: testSwitchCircuitPersistence, }, { name: "switch offline delivery", test: testSwitchOfflineDelivery, }, { name: "switch offline delivery persistence", test: testSwitchOfflineDeliveryPersistence, }, { name: "switch offline delivery outgoing offline", test: testSwitchOfflineDeliveryOutgoingOffline, }, } // TestLightningNetworkDaemon performs a series of integration tests amongst a // programmatically driven network of lnd nodes. func TestLightningNetworkDaemon(t *testing.T) { ht := newHarnessTest(t) var lndHarness *lntest.NetworkHarness // First create an instance of the btcd's rpctest.Harness. This will be // used to fund the wallets of the nodes within the test network and to // drive blockchain related events within the network. Revert the default // setting of accepting non-standard transactions on simnet to reject them. // Transactions on the lightning network should always be standard to get // better guarantees of getting included in to blocks. args := []string{"--rejectnonstd"} handlers := &rpcclient.NotificationHandlers{ OnTxAccepted: func(hash *chainhash.Hash, amt btcutil.Amount) { lndHarness.OnTxAccepted(hash) }, } btcdHarness, err := rpctest.New(harnessNetParams, handlers, args) if err != nil { ht.Fatalf("unable to create mining node: %v", err) } defer btcdHarness.TearDown() // First create the network harness to gain access to its // 'OnTxAccepted' call back. lndHarness, err = lntest.NewNetworkHarness(btcdHarness) if err != nil { ht.Fatalf("unable to create lightning network harness: %v", err) } defer lndHarness.TearDownAll() // Spawn a new goroutine to watch for any fatal errors that any of the // running lnd processes encounter. If an error occurs, then the test // case should naturally as a result and we log the server error here to // help debug. go func() { for { select { case err, more := <-lndHarness.ProcessErrors(): if !more { return } ht.Logf("lnd finished with error (stderr):\n%v", err) } } }() // Turn off the btcd rpc logging, otherwise it will lead to panic. // TODO(andrew.shvv|roasbeef) Remove the hack after re-work the way the log // rotator os work. rpcclient.UseLogger(btclog.Disabled) if err := btcdHarness.SetUp(true, 50); err != nil { ht.Fatalf("unable to set up mining node: %v", err) } if err := btcdHarness.Node.NotifyNewTransactions(false); err != nil { ht.Fatalf("unable to request transaction notifications: %v", err) } // Next mine enough blocks in order for segwit and the CSV package // soft-fork to activate on SimNet. numBlocks := chaincfg.SimNetParams.MinerConfirmationWindow * 2 if _, err := btcdHarness.Node.Generate(numBlocks); err != nil { ht.Fatalf("unable to generate blocks: %v", err) } // With the btcd harness created, we can now complete the // initialization of the network. args - list of lnd arguments, // example: "--debuglevel=debug" // TODO(roasbeef): create master balanced channel with all the monies? if err = lndHarness.SetUp(nil); err != nil { ht.Fatalf("unable to set up test lightning network: %v", err) } t.Logf("Running %v integration tests", len(testsCases)) for _, testCase := range testsCases { logLine := fmt.Sprintf("STARTING ============ %v ============\n", testCase.name) if err := lndHarness.Alice.AddToLog(logLine); err != nil { t.Fatalf("unable to add to log: %v", err) } if err := lndHarness.Bob.AddToLog(logLine); err != nil { t.Fatalf("unable to add to log: %v", err) } success := t.Run(testCase.name, func(t1 *testing.T) { ht := newHarnessTest(t1) ht.RunTestCase(testCase, lndHarness) }) // Stop at the first failure. Mimic behavior of original test // framework. if !success { break } } }