lnd/itest/lnd_mpp_test.go

380 lines
10 KiB
Go

package itest
import (
"time"
"github.com/btcsuite/btcd/btcutil"
"github.com/lightningnetwork/lnd/chainreg"
"github.com/lightningnetwork/lnd/lnrpc"
"github.com/lightningnetwork/lnd/lnrpc/routerrpc"
"github.com/lightningnetwork/lnd/lntest"
"github.com/lightningnetwork/lnd/lntest/node"
"github.com/lightningnetwork/lnd/lntypes"
"github.com/lightningnetwork/lnd/routing/route"
"github.com/stretchr/testify/require"
)
// testSendToRouteMultiPath tests that we are able to successfully route a
// payment using multiple shards across different paths, by using SendToRoute.
func testSendToRouteMultiPath(ht *lntest.HarnessTest) {
mts := newMppTestScenario(ht)
// To ensure the payment goes through separate paths, we'll set a
// channel size that can only carry one shard at a time. We'll divide
// the payment into 3 shards.
const (
paymentAmt = btcutil.Amount(300000)
shardAmt = paymentAmt / 3
chanAmt = shardAmt * 3 / 2
)
// Set up a network with three different paths Alice <-> Bob.
// _ Eve _
// / \
// Alice -- Carol ---- Bob
// \ /
// \__ Dave ____/
//
req := &mppOpenChannelRequest{
// Since the channel Alice-> Carol will have to carry two
// shards, we make it larger.
amtAliceCarol: chanAmt + shardAmt,
amtAliceDave: chanAmt,
amtCarolBob: chanAmt,
amtCarolEve: chanAmt,
amtDaveBob: chanAmt,
amtEveBob: chanAmt,
}
mts.openChannels(req)
// Make Bob create an invoice for Alice to pay.
payReqs, rHashes, invoices := ht.CreatePayReqs(mts.bob, paymentAmt, 1)
rHash := rHashes[0]
payReq := payReqs[0]
decodeResp := mts.bob.RPC.DecodePayReq(payReq)
payAddr := decodeResp.PaymentAddr
// Subscribe the invoice.
stream := mts.bob.RPC.SubscribeSingleInvoice(rHash)
// We'll send shards along three routes from Alice.
sendRoutes := [][]*node.HarnessNode{
{mts.carol, mts.bob},
{mts.dave, mts.bob},
{mts.carol, mts.eve, mts.bob},
}
responses := make(chan *lnrpc.HTLCAttempt, len(sendRoutes))
for _, hops := range sendRoutes {
// Build a route for the specified hops.
r := mts.buildRoute(shardAmt, mts.alice, hops)
// Set the MPP records to indicate this is a payment shard.
hop := r.Hops[len(r.Hops)-1]
hop.TlvPayload = true
hop.MppRecord = &lnrpc.MPPRecord{
PaymentAddr: payAddr,
TotalAmtMsat: int64(paymentAmt * 1000),
}
// Send the shard.
sendReq := &routerrpc.SendToRouteRequest{
PaymentHash: rHash,
Route: r,
}
// We'll send all shards in their own goroutine, since
// SendToRoute will block as long as the payment is in flight.
go func() {
resp := mts.alice.RPC.SendToRouteV2(sendReq)
responses <- resp
}()
}
// Wait for all responses to be back, and check that they all
// succeeded.
timer := time.After(defaultTimeout)
for range sendRoutes {
var resp *lnrpc.HTLCAttempt
select {
case resp = <-responses:
case <-timer:
require.Fail(ht, "response not received")
}
require.Nil(ht, resp.Failure, "received payment failure")
// All shards should come back with the preimage.
require.Equal(ht, resp.Preimage, invoices[0].RPreimage,
"preimage doesn't match")
}
// assertNumHtlcs is a helper that checks the node's latest payment,
// and asserts it was split into num shards.
assertNumHtlcs := func(hn *node.HarnessNode, num int) {
var preimage lntypes.Preimage
copy(preimage[:], invoices[0].RPreimage)
payment := ht.AssertPaymentStatus(
hn, preimage, lnrpc.Payment_SUCCEEDED,
)
htlcs := payment.Htlcs
require.NotEmpty(ht, htlcs, "no htlcs")
succeeded := 0
for _, htlc := range htlcs {
if htlc.Status == lnrpc.HTLCAttempt_SUCCEEDED {
succeeded++
}
}
require.Equal(ht, num, succeeded, "HTLCs not matched")
}
// assertSettledInvoice checks that the invoice for the given payment
// hash is settled, and has been paid using num HTLCs.
assertSettledInvoice := func(rhash []byte, num int) {
var payHash lntypes.Hash
copy(payHash[:], rhash)
inv := ht.AssertInvoiceState(stream, lnrpc.Invoice_SETTLED)
// Assert that the amount paid to the invoice is correct.
require.EqualValues(ht, paymentAmt, inv.AmtPaidSat,
"incorrect payment amt")
require.Len(ht, inv.Htlcs, num, "wrong num of HTLCs")
}
// Finally check that the payment shows up with three settled HTLCs in
// Alice's list of payments...
assertNumHtlcs(mts.alice, 3)
// ...and in Bob's list of paid invoices.
assertSettledInvoice(rHash, 3)
// Finally, close all channels.
mts.closeChannels()
}
// mppTestScenario defines a test scenario used for testing MPP-related tests.
// It has two standby nodes, alice and bob, and three new nodes, carol, dave,
// and eve.
type mppTestScenario struct {
ht *lntest.HarnessTest
alice, bob, carol, dave, eve *node.HarnessNode
nodes []*node.HarnessNode
// Keep a list of all our active channels.
channelPoints []*lnrpc.ChannelPoint
}
// newMppTestScenario initializes a new mpp test scenario with five funded
// nodes and connects them to have the following topology,
//
// _ Eve _
// / \
// Alice -- Carol ---- Bob
// \ /
// \__ Dave ____/
func newMppTestScenario(ht *lntest.HarnessTest) *mppTestScenario {
alice, bob := ht.Alice, ht.Bob
ht.RestartNodeWithExtraArgs(bob, []string{
"--maxpendingchannels=2",
"--accept-amp",
})
// Create a five-node context consisting of Alice, Bob and three new
// nodes.
carol := ht.NewNode("carol", []string{
"--maxpendingchannels=2",
"--accept-amp",
})
dave := ht.NewNode("dave", nil)
eve := ht.NewNode("eve", nil)
// Connect nodes to ensure propagation of channels.
ht.EnsureConnected(alice, carol)
ht.EnsureConnected(alice, dave)
ht.EnsureConnected(carol, bob)
ht.EnsureConnected(carol, eve)
ht.EnsureConnected(dave, bob)
ht.EnsureConnected(eve, bob)
// Send coins to the nodes and mine 1 blocks to confirm them.
for i := 0; i < 2; i++ {
ht.FundCoinsUnconfirmed(btcutil.SatoshiPerBitcoin, carol)
ht.FundCoinsUnconfirmed(btcutil.SatoshiPerBitcoin, dave)
ht.FundCoinsUnconfirmed(btcutil.SatoshiPerBitcoin, eve)
ht.MineBlocks(1)
}
mts := &mppTestScenario{
ht: ht,
alice: alice,
bob: bob,
carol: carol,
dave: dave,
eve: eve,
nodes: []*node.HarnessNode{alice, bob, carol, dave, eve},
}
return mts
}
// mppOpenChannelRequest defines the amounts used for each channel opening.
type mppOpenChannelRequest struct {
// Channel Alice=>Carol.
amtAliceCarol btcutil.Amount
// Channel Alice=>Dave.
amtAliceDave btcutil.Amount
// Channel Carol=>Bob.
amtCarolBob btcutil.Amount
// Channel Carol=>Eve.
amtCarolEve btcutil.Amount
// Channel Dave=>Bob.
amtDaveBob btcutil.Amount
// Channel Eve=>Bob.
amtEveBob btcutil.Amount
}
// openChannels is a helper to open channels that sets up a network topology
// with three different paths Alice <-> Bob as following,
//
// _ Eve _
// / \
// Alice -- Carol ---- Bob
// \ /
// \__ Dave ____/
//
// NOTE: all the channels are open together to save blocks mined.
func (m *mppTestScenario) openChannels(r *mppOpenChannelRequest) {
reqs := []*lntest.OpenChannelRequest{
{
Local: m.alice,
Remote: m.carol,
Param: lntest.OpenChannelParams{Amt: r.amtAliceCarol},
},
{
Local: m.alice,
Remote: m.dave,
Param: lntest.OpenChannelParams{Amt: r.amtAliceDave},
},
{
Local: m.carol,
Remote: m.bob,
Param: lntest.OpenChannelParams{Amt: r.amtCarolBob},
},
{
Local: m.carol,
Remote: m.eve,
Param: lntest.OpenChannelParams{Amt: r.amtCarolEve},
},
{
Local: m.dave,
Remote: m.bob,
Param: lntest.OpenChannelParams{Amt: r.amtDaveBob},
},
{
Local: m.eve,
Remote: m.bob,
Param: lntest.OpenChannelParams{Amt: r.amtEveBob},
},
}
m.channelPoints = m.ht.OpenMultiChannelsAsync(reqs)
// Make sure every node has heard every channel.
for _, hn := range m.nodes {
for _, cp := range m.channelPoints {
m.ht.AssertTopologyChannelOpen(hn, cp)
}
// Each node should have exactly 6 edges.
m.ht.AssertNumEdges(hn, len(m.channelPoints), false)
}
}
// closeChannels closes all the open channels from `openChannels`.
func (m *mppTestScenario) closeChannels() {
if m.ht.Failed() {
m.ht.Log("Skipped closing channels for failed test")
return
}
// Close all channels without mining the closing transactions.
m.ht.CloseChannelAssertPending(m.alice, m.channelPoints[0], false)
m.ht.CloseChannelAssertPending(m.alice, m.channelPoints[1], false)
m.ht.CloseChannelAssertPending(m.carol, m.channelPoints[2], false)
m.ht.CloseChannelAssertPending(m.carol, m.channelPoints[3], false)
m.ht.CloseChannelAssertPending(m.dave, m.channelPoints[4], false)
m.ht.CloseChannelAssertPending(m.eve, m.channelPoints[5], false)
// Now mine a block to include all the closing transactions.
m.ht.MineBlocks(1)
// Assert that the channels are closed.
for _, hn := range m.nodes {
m.ht.AssertNumWaitingClose(hn, 0)
}
}
// Helper function for Alice to build a route from pubkeys.
func (m *mppTestScenario) buildRoute(amt btcutil.Amount,
sender *node.HarnessNode, hops []*node.HarnessNode) *lnrpc.Route {
rpcHops := make([][]byte, 0, len(hops))
for _, hop := range hops {
k := hop.PubKeyStr
pubkey, err := route.NewVertexFromStr(k)
require.NoErrorf(m.ht, err, "error parsing %v: %v", k, err)
rpcHops = append(rpcHops, pubkey[:])
}
req := &routerrpc.BuildRouteRequest{
AmtMsat: int64(amt * 1000),
FinalCltvDelta: chainreg.DefaultBitcoinTimeLockDelta,
HopPubkeys: rpcHops,
}
routeResp := sender.RPC.BuildRoute(req)
return routeResp.Route
}
// updatePolicy updates a Dave's global channel policy and returns the expected
// policy for further check. It changes Dave's `FeeBaseMsat` from 1000 msat to
// 500,000 msat, and `FeeProportionalMillonths` from 1 msat to 1000 msat.
func (m *mppTestScenario) updateDaveGlobalPolicy() *lnrpc.RoutingPolicy {
const (
baseFeeMsat = 500_000
feeRate = 0.001
maxHtlcMsat = 133_650_000
)
expectedPolicy := &lnrpc.RoutingPolicy{
FeeBaseMsat: baseFeeMsat,
FeeRateMilliMsat: feeRate * testFeeBase,
TimeLockDelta: 40,
MinHtlc: 1000, // default value
MaxHtlcMsat: maxHtlcMsat,
}
updateFeeReq := &lnrpc.PolicyUpdateRequest{
BaseFeeMsat: baseFeeMsat,
FeeRate: feeRate,
TimeLockDelta: 40,
Scope: &lnrpc.PolicyUpdateRequest_Global{Global: true},
MaxHtlcMsat: maxHtlcMsat,
}
m.dave.RPC.UpdateChannelPolicy(updateFeeReq)
return expectedPolicy
}