package lntest
import (
"context"
"encoding/hex"
"fmt"
"testing"
"time"
"github.com/btcsuite/btcd/blockchain"
"github.com/btcsuite/btcd/btcutil"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/go-errors/errors"
"github.com/lightningnetwork/lnd/kvdb/etcd"
"github.com/lightningnetwork/lnd/lnrpc"
"github.com/lightningnetwork/lnd/lnrpc/routerrpc"
"github.com/lightningnetwork/lnd/lnrpc/walletrpc"
"github.com/lightningnetwork/lnd/lntest/node"
"github.com/lightningnetwork/lnd/lntest/rpc"
"github.com/lightningnetwork/lnd/lntest/wait"
"github.com/lightningnetwork/lnd/lnwallet/chainfee"
"github.com/lightningnetwork/lnd/lnwire"
"github.com/stretchr/testify/require"
)
const (
// defaultMinerFeeRate specifies the fee rate in sats when sending
// outputs from the miner.
defaultMinerFeeRate = 7500
// numBlocksSendOutput specifies the number of blocks to mine after
// sending outputs from the miner.
numBlocksSendOutput = 2
// numBlocksOpenChannel specifies the number of blocks mined when
// opening a channel.
numBlocksOpenChannel = 6
// lndErrorChanSize specifies the buffer size used to receive errors
// from lnd process.
lndErrorChanSize = 10
)
// TestCase defines a test case that's been used in the integration test.
type TestCase struct {
// Name specifies the test name.
Name string
// TestFunc is the test case wrapped in a function.
TestFunc func(t *HarnessTest)
}
// standbyNodes are a list of nodes which are created during the initialization
// of the test and used across all test cases.
type standbyNodes struct {
// Alice and Bob are the initial seeder nodes that are automatically
// created to be the initial participants of the test network.
Alice *node.HarnessNode
Bob *node.HarnessNode
}
// HarnessTest builds on top of a testing.T with enhanced error detection. It
// is responsible for managing the interactions among different nodes, and
// providing easy-to-use assertions.
type HarnessTest struct {
*testing.T
// Embed the standbyNodes so we can easily access them via `ht.Alice`.
standbyNodes
// Miner is a reference to a running full node that can be used to
// create new blocks on the network.
Miner *HarnessMiner
// manager handles the start and stop of a given node.
manager *nodeManager
// feeService is a web service that provides external fee estimates to
// lnd.
feeService WebFeeService
// Channel for transmitting stderr output from failed lightning node
// to main process.
lndErrorChan chan error
// runCtx is a context with cancel method. It's used to signal when the
// node needs to quit, and used as the parent context when spawning
// children contexts for RPC requests.
runCtx context.Context //nolint:containedctx
cancel context.CancelFunc
// stopChainBackend points to the cleanup function returned by the
// chainBackend.
stopChainBackend func()
// cleaned specifies whether the cleanup has been applied for the
// current HarnessTest.
cleaned bool
}
// NewHarnessTest creates a new instance of a harnessTest from a regular
// testing.T instance.
func NewHarnessTest(t *testing.T, lndBinary string, feeService WebFeeService,
dbBackend node.DatabaseBackend) *HarnessTest {
t.Helper()
// Create the run context.
ctxt, cancel := context.WithCancel(context.Background())
manager := newNodeManager(lndBinary, dbBackend)
return &HarnessTest{
T: t,
manager: manager,
feeService: feeService,
runCtx: ctxt,
cancel: cancel,
// We need to use buffered channel here as we don't want to
// block sending errors.
lndErrorChan: make(chan error, lndErrorChanSize),
}
}
// Start will assemble the chain backend and the miner for the HarnessTest. It
// also starts the fee service and watches lnd process error.
func (h *HarnessTest) Start(chain node.BackendConfig, miner *HarnessMiner) {
// 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() {
select {
case err, more := <-h.lndErrorChan:
if !more {
return
}
h.Logf("lnd finished with error (stderr):\n%v", err)
case <-h.runCtx.Done():
return
}
}()
// Start the fee service.
err := h.feeService.Start()
require.NoError(h, err, "failed to start fee service")
// Assemble the node manager with chainBackend and feeServiceURL.
h.manager.chainBackend = chain
h.manager.feeServiceURL = h.feeService.URL()
// Assemble the miner.
h.Miner = miner
}
// ChainBackendName returns the chain backend name used in the test.
func (h *HarnessTest) ChainBackendName() string {
return h.manager.chainBackend.Name()
}
// Context returns the run context used in this test. Usaually it should be
// managed by the test itself otherwise undefined behaviors will occur. It can
// be used, however, when a test needs to have its own context being managed
// differently. In that case, instead of using a background context, the run
// context should be used such that the test context scope can be fully
// controlled.
func (h *HarnessTest) Context() context.Context {
return h.runCtx
}
// SetUp starts the initial seeder nodes within the test harness. The initial
// node's wallets will be funded wallets with 10x10 BTC outputs each.
func (h *HarnessTest) SetupStandbyNodes() {
h.Log("Setting up standby nodes Alice and Bob...")
defer h.Log("Finshed the setup, now running tests...")
lndArgs := []string{
"--default-remote-max-htlcs=483",
"--dust-threshold=5000000",
}
// Start the initial seeder nodes within the test network, then connect
// their respective RPC clients.
h.Alice = h.NewNode("Alice", lndArgs)
h.Bob = h.NewNode("Bob", lndArgs)
addrReq := &lnrpc.NewAddressRequest{
Type: lnrpc.AddressType_WITNESS_PUBKEY_HASH,
}
const initialFund = 1 * btcutil.SatoshiPerBitcoin
// Load up the wallets of the seeder nodes with 100 outputs of 1 BTC
// each.
nodes := []*node.HarnessNode{h.Alice, h.Bob}
for _, hn := range nodes {
h.manager.standbyNodes[hn.Cfg.NodeID] = hn
for i := 0; i < 100; i++ {
resp := hn.RPC.NewAddress(addrReq)
addr, err := btcutil.DecodeAddress(
resp.Address, h.Miner.ActiveNet,
)
require.NoError(h, err)
addrScript, err := txscript.PayToAddrScript(addr)
require.NoError(h, err)
output := &wire.TxOut{
PkScript: addrScript,
Value: initialFund,
}
h.Miner.SendOutput(output, defaultMinerFeeRate)
}
}
// We generate several blocks in order to give the outputs created
// above a good number of confirmations.
const totalTxes = 200
h.MineBlocksAndAssertNumTxes(numBlocksSendOutput, totalTxes)
// Now we want to wait for the nodes to catch up.
h.WaitForBlockchainSync(h.Alice)
h.WaitForBlockchainSync(h.Bob)
// Now block until both wallets have fully synced up.
const expectedBalance = 100 * initialFund
err := wait.NoError(func() error {
aliceResp := h.Alice.RPC.WalletBalance()
bobResp := h.Bob.RPC.WalletBalance()
if aliceResp.ConfirmedBalance != expectedBalance {
return fmt.Errorf("expected 10 BTC, instead "+
"alice has %d", aliceResp.ConfirmedBalance)
}
if bobResp.ConfirmedBalance != expectedBalance {
return fmt.Errorf("expected 10 BTC, instead "+
"bob has %d", bobResp.ConfirmedBalance)
}
return nil
}, DefaultTimeout)
require.NoError(h, err, "timeout checking balance for node")
}
// Stop stops the test harness.
func (h *HarnessTest) Stop() {
// Do nothing if it's not started.
if h.runCtx == nil {
h.Log("HarnessTest is not started")
return
}
// Stop all running nodes.
for _, node := range h.manager.activeNodes {
h.Shutdown(node)
}
close(h.lndErrorChan)
// Stop the fee service.
err := h.feeService.Stop()
require.NoError(h, err, "failed to stop fee service")
// Stop the chainBackend.
h.stopChainBackend()
// Stop the miner.
h.Miner.Stop()
}
// RunTestCase executes a harness test case. Any errors or panics will be
// represented as fatal.
func (h *HarnessTest) RunTestCase(testCase *TestCase) {
defer func() {
if err := recover(); err != nil {
description := errors.Wrap(err, 2).ErrorStack()
h.Fatalf("Failed: (%v) panic with: \n%v",
testCase.Name, description)
}
}()
testCase.TestFunc(h)
}
// resetStandbyNodes resets all standby nodes by attaching the new testing.T
// and restarting them with the original config.
func (h *HarnessTest) resetStandbyNodes(t *testing.T) {
t.Helper()
for _, hn := range h.manager.standbyNodes {
// Inherit the testing.T.
h.T = t
// Reset the config so the node will be using the default
// config for the coming test. This will also inherit the
// test's running context.
h.RestartNodeWithExtraArgs(hn, hn.Cfg.OriginalExtraArgs)
}
}
// Subtest creates a child HarnessTest, which inherits the harness net and
// stand by nodes created by the parent test. It will return a cleanup function
// which resets all the standby nodes' configs back to its original state and
// create snapshots of each nodes' internal state.
func (h *HarnessTest) Subtest(t *testing.T) *HarnessTest {
t.Helper()
st := &HarnessTest{
T: t,
manager: h.manager,
Miner: h.Miner,
standbyNodes: h.standbyNodes,
feeService: h.feeService,
lndErrorChan: make(chan error, lndErrorChanSize),
}
// Inherit context from the main test.
st.runCtx, st.cancel = context.WithCancel(h.runCtx)
// Inherit the subtest for the miner.
st.Miner.T = st.T
// Reset the standby nodes.
st.resetStandbyNodes(t)
// Reset fee estimator.
st.SetFeeEstimate(DefaultFeeRateSatPerKw)
// Record block height.
_, startHeight := h.Miner.GetBestBlock()
st.Cleanup(func() {
_, endHeight := h.Miner.GetBestBlock()
st.Logf("finished test: %s, start height=%d, end height=%d, "+
"mined blocks=%d", st.manager.currentTestCase,
startHeight, endHeight, endHeight-startHeight)
// Don't bother run the cleanups if the test is failed.
if st.Failed() {
st.Log("test failed, skipped cleanup")
st.shutdownAllNodes()
return
}
// Don't run cleanup if it's already done. This can happen if
// we have multiple level inheritance of the parent harness
// test. For instance, a `Subtest(st)`.
if st.cleaned {
st.Log("test already cleaned, skipped cleanup")
return
}
// When we finish the test, reset the nodes' configs and take a
// snapshot of each of the nodes' internal states.
for _, node := range st.manager.standbyNodes {
st.cleanupStandbyNode(node)
}
// If found running nodes, shut them down.
st.shutdownNonStandbyNodes()
// We require the mempool to be cleaned from the test.
require.Empty(st, st.Miner.GetRawMempool(), "mempool not "+
"cleaned, please mine blocks to clean them all.")
// Finally, cancel the run context. We have to do it here
// because we need to keep the context alive for the above
// assertions used in cleanup.
st.cancel()
// We now want to mark the parent harness as cleaned to avoid
// running cleanup again since its internal state has been
// cleaned up by its child harness tests.
h.cleaned = true
})
return st
}
// shutdownNonStandbyNodes will shutdown any non-standby nodes.
func (h *HarnessTest) shutdownNonStandbyNodes() {
h.shutdownNodes(true)
}
// shutdownAllNodes will shutdown all running nodes.
func (h *HarnessTest) shutdownAllNodes() {
h.shutdownNodes(false)
}
// shutdownNodes will shutdown any non-standby nodes. If skipStandby is false,
// all the standby nodes will be shutdown too.
func (h *HarnessTest) shutdownNodes(skipStandby bool) {
for nid, node := range h.manager.activeNodes {
// If it's a standby node, skip.
_, ok := h.manager.standbyNodes[nid]
if ok && skipStandby {
continue
}
// The process may not be in a state to always shutdown
// immediately, so we'll retry up to a hard limit to ensure we
// eventually shutdown.
err := wait.NoError(func() error {
return h.manager.shutdownNode(node)
}, DefaultTimeout)
if err == nil {
continue
}
// Instead of returning the error, we will log it instead. This
// is needed so other nodes can continue their shutdown
// processes.
h.Logf("unable to shutdown %s, got err: %v", node.Name(), err)
}
}
// cleanupStandbyNode is a function should be called with defer whenever a
// subtest is created. It will reset the standby nodes configs, snapshot the
// states, and validate the node has a clean state.
func (h *HarnessTest) cleanupStandbyNode(hn *node.HarnessNode) {
// Remove connections made from this test.
h.removeConnectionns(hn)
// Delete all payments made from this test.
hn.RPC.DeleteAllPayments()
// Check the node's current state with timeout.
//
// NOTE: we need to do this in a `wait` because it takes some time for
// the node to update its internal state. Once the RPCs are synced we
// can then remove this wait.
err := wait.NoError(func() error {
// Update the node's internal state.
hn.UpdateState()
// Check the node is in a clean state for the following tests.
return h.validateNodeState(hn)
}, wait.DefaultTimeout)
require.NoError(h, err, "timeout checking node's state")
}
// removeConnectionns will remove all connections made on the standby nodes
// expect the connections between Alice and Bob.
func (h *HarnessTest) removeConnectionns(hn *node.HarnessNode) {
resp := hn.RPC.ListPeers()
for _, peer := range resp.Peers {
// Skip disconnecting Alice and Bob.
switch peer.PubKey {
case h.Alice.PubKeyStr:
continue
case h.Bob.PubKeyStr:
continue
}
hn.RPC.DisconnectPeer(peer.PubKey)
}
}
// SetTestName set the test case name.
func (h *HarnessTest) SetTestName(name string) {
h.manager.currentTestCase = name
// Overwrite the old log filename so we can create new log files.
for _, node := range h.manager.standbyNodes {
node.Cfg.LogFilenamePrefix = name
}
}
// NewNode creates a new node and asserts its creation. The node is guaranteed
// to have finished its initialization and all its subservers are started.
func (h *HarnessTest) NewNode(name string,
extraArgs []string) *node.HarnessNode {
node, err := h.manager.newNode(h.T, name, extraArgs, nil, false)
require.NoErrorf(h, err, "unable to create new node for %s", name)
// Start the node.
err = node.Start(h.runCtx)
require.NoError(h, err, "failed to start node %s", node.Name())
return node
}
// Shutdown shuts down the given node and asserts that no errors occur.
func (h *HarnessTest) Shutdown(node *node.HarnessNode) {
// The process may not be in a state to always shutdown immediately, so
// we'll retry up to a hard limit to ensure we eventually shutdown.
err := wait.NoError(func() error {
return h.manager.shutdownNode(node)
}, DefaultTimeout)
require.NoErrorf(h, err, "unable to shutdown %v", node.Name())
}
// SuspendNode stops the given node and returns a callback that can be used to
// start it again.
func (h *HarnessTest) SuspendNode(node *node.HarnessNode) func() error {
err := node.Stop()
require.NoErrorf(h, err, "failed to stop %s", node.Name())
// Remove the node from active nodes.
delete(h.manager.activeNodes, node.Cfg.NodeID)
return func() error {
h.manager.registerNode(node)
if err := node.Start(h.runCtx); err != nil {
return err
}
h.WaitForBlockchainSync(node)
return nil
}
}
// RestartNode restarts a given node, unlocks it and asserts it's successfully
// started.
func (h *HarnessTest) RestartNode(hn *node.HarnessNode) {
err := h.manager.restartNode(h.runCtx, hn, nil)
require.NoErrorf(h, err, "failed to restart node %s", hn.Name())
err = h.manager.unlockNode(hn)
require.NoErrorf(h, err, "failed to unlock node %s", hn.Name())
if !hn.Cfg.SkipUnlock {
// Give the node some time to catch up with the chain before we
// continue with the tests.
h.WaitForBlockchainSync(hn)
}
}
// RestartNodeNoUnlock restarts a given node without unlocking its wallet.
func (h *HarnessTest) RestartNodeNoUnlock(hn *node.HarnessNode) {
err := h.manager.restartNode(h.runCtx, hn, nil)
require.NoErrorf(h, err, "failed to restart node %s", hn.Name())
}
// RestartNodeWithChanBackups restarts a given node with the specified channel
// backups.
func (h *HarnessTest) RestartNodeWithChanBackups(hn *node.HarnessNode,
chanBackups ...*lnrpc.ChanBackupSnapshot) {
err := h.manager.restartNode(h.runCtx, hn, nil)
require.NoErrorf(h, err, "failed to restart node %s", hn.Name())
err = h.manager.unlockNode(hn, chanBackups...)
require.NoErrorf(h, err, "failed to unlock node %s", hn.Name())
// Give the node some time to catch up with the chain before we
// continue with the tests.
h.WaitForBlockchainSync(hn)
}
// RestartNodeWithExtraArgs updates the node's config and restarts it.
func (h *HarnessTest) RestartNodeWithExtraArgs(hn *node.HarnessNode,
extraArgs []string) {
hn.SetExtraArgs(extraArgs)
h.RestartNode(hn)
}
// NewNodeWithSeed fully initializes a new HarnessNode after creating a fresh
// aezeed. The provided password is used as both the aezeed password and the
// wallet password. The generated mnemonic is returned along with the
// initialized harness node.
func (h *HarnessTest) NewNodeWithSeed(name string,
extraArgs []string, password []byte,
statelessInit bool) (*node.HarnessNode, []string, []byte) {
// Create a request to generate a new aezeed. The new seed will have
// the same password as the internal wallet.
req := &lnrpc.GenSeedRequest{
AezeedPassphrase: password,
SeedEntropy: nil,
}
return h.newNodeWithSeed(name, extraArgs, req, statelessInit)
}
// newNodeWithSeed creates and initializes a new HarnessNode such that it'll be
// ready to accept RPC calls. A `GenSeedRequest` is needed to generate the
// seed.
func (h *HarnessTest) newNodeWithSeed(name string,
extraArgs []string, req *lnrpc.GenSeedRequest,
statelessInit bool) (*node.HarnessNode, []string, []byte) {
node, err := h.manager.newNode(
h.T, name, extraArgs, req.AezeedPassphrase, true,
)
require.NoErrorf(h, err, "unable to create new node for %s", name)
// Start the node with seed only, which will only create the `State`
// and `WalletUnlocker` clients.
err = node.StartWithNoAuth(h.runCtx)
require.NoErrorf(h, err, "failed to start node %s", node.Name())
// Generate a new seed.
genSeedResp := node.RPC.GenSeed(req)
// With the seed created, construct the init request to the node,
// including the newly generated seed.
initReq := &lnrpc.InitWalletRequest{
WalletPassword: req.AezeedPassphrase,
CipherSeedMnemonic: genSeedResp.CipherSeedMnemonic,
AezeedPassphrase: req.AezeedPassphrase,
StatelessInit: statelessInit,
}
// Pass the init request via rpc to finish unlocking the node. This
// will also initialize the macaroon-authenticated LightningClient.
adminMac, err := h.manager.initWalletAndNode(node, initReq)
require.NoErrorf(h, err, "failed to unlock and init node %s",
node.Name())
// In stateless initialization mode we get a macaroon back that we have
// to return to the test, otherwise gRPC calls won't be possible since
// there are no macaroon files created in that mode.
// In stateful init the admin macaroon will just be nil.
return node, genSeedResp.CipherSeedMnemonic, adminMac
}
// RestoreNodeWithSeed fully initializes a HarnessNode using a chosen mnemonic,
// password, recovery window, and optionally a set of static channel backups.
// After providing the initialization request to unlock the node, this method
// will finish initializing the LightningClient such that the HarnessNode can
// be used for regular rpc operations.
func (h *HarnessTest) RestoreNodeWithSeed(name string, extraArgs []string,
password []byte, mnemonic []string, rootKey string,
recoveryWindow int32, chanBackups *lnrpc.ChanBackupSnapshot,
opts ...node.Option) *node.HarnessNode {
node, err := h.manager.newNode(h.T, name, extraArgs, password, true)
require.NoErrorf(h, err, "unable to create new node for %s", name)
// Start the node with seed only, which will only create the `State`
// and `WalletUnlocker` clients.
err = node.StartWithNoAuth(h.runCtx)
require.NoErrorf(h, err, "failed to start node %s", node.Name())
// Create the wallet.
initReq := &lnrpc.InitWalletRequest{
WalletPassword: password,
CipherSeedMnemonic: mnemonic,
AezeedPassphrase: password,
ExtendedMasterKey: rootKey,
RecoveryWindow: recoveryWindow,
ChannelBackups: chanBackups,
}
_, err = h.manager.initWalletAndNode(node, initReq)
require.NoErrorf(h, err, "failed to unlock and init node %s",
node.Name())
return node
}
// NewNodeEtcd starts a new node with seed that'll use an external etcd
// database as its storage. The passed cluster flag indicates that we'd like
// the node to join the cluster leader election. We won't wait until RPC is
// available (this is useful when the node is not expected to become the leader
// right away).
func (h *HarnessTest) NewNodeEtcd(name string, etcdCfg *etcd.Config,
password []byte, cluster bool,
leaderSessionTTL int) *node.HarnessNode {
// We don't want to use the embedded etcd instance.
h.manager.dbBackend = node.BackendBbolt
extraArgs := node.ExtraArgsEtcd(
etcdCfg, name, cluster, leaderSessionTTL,
)
node, err := h.manager.newNode(h.T, name, extraArgs, password, true)
require.NoError(h, err, "failed to create new node with etcd")
// Start the node daemon only.
err = node.StartLndCmd(h.runCtx)
require.NoError(h, err, "failed to start node %s", node.Name())
return node
}
// NewNodeWithSeedEtcd starts a new node with seed that'll use an external etcd
// database as its storage. The passed cluster flag indicates that we'd like
// the node to join the cluster leader election.
func (h *HarnessTest) NewNodeWithSeedEtcd(name string, etcdCfg *etcd.Config,
password []byte, entropy []byte, statelessInit, cluster bool,
leaderSessionTTL int) (*node.HarnessNode, []string, []byte) {
// We don't want to use the embedded etcd instance.
h.manager.dbBackend = node.BackendBbolt
// Create a request to generate a new aezeed. The new seed will have
// the same password as the internal wallet.
req := &lnrpc.GenSeedRequest{
AezeedPassphrase: password,
SeedEntropy: nil,
}
extraArgs := node.ExtraArgsEtcd(
etcdCfg, name, cluster, leaderSessionTTL,
)
return h.newNodeWithSeed(name, extraArgs, req, statelessInit)
}
// NewNodeRemoteSigner creates a new remote signer node and asserts its
// creation.
func (h *HarnessTest) NewNodeRemoteSigner(name string, extraArgs []string,
password []byte, watchOnly *lnrpc.WatchOnly) *node.HarnessNode {
hn, err := h.manager.newNode(h.T, name, extraArgs, password, true)
require.NoErrorf(h, err, "unable to create new node for %s", name)
err = hn.StartWithNoAuth(h.runCtx)
require.NoError(h, err, "failed to start node %s", name)
// With the seed created, construct the init request to the node,
// including the newly generated seed.
initReq := &lnrpc.InitWalletRequest{
WalletPassword: password,
WatchOnly: watchOnly,
}
// Pass the init request via rpc to finish unlocking the node. This
// will also initialize the macaroon-authenticated LightningClient.
_, err = h.manager.initWalletAndNode(hn, initReq)
require.NoErrorf(h, err, "failed to init node %s", name)
return hn
}
// KillNode kills the node (but won't wait for the node process to stop).
func (h *HarnessTest) KillNode(hn *node.HarnessNode) {
require.NoErrorf(h, hn.Kill(), "%s: kill got error", hn.Name())
delete(h.manager.activeNodes, hn.Cfg.NodeID)
}
// SetFeeEstimate sets a fee rate to be returned from fee estimator.
//
// NOTE: this method will set the fee rate for a conf target of 1, which is the
// fallback fee rate for a `WebAPIEstimator` if a higher conf target's fee rate
// is not set. This means if the fee rate for conf target 6 is set, the fee
// estimator will use that value instead.
func (h *HarnessTest) SetFeeEstimate(fee chainfee.SatPerKWeight) {
h.feeService.SetFeeRate(fee, 1)
}
// SetFeeEstimateWithConf sets a fee rate of a specified conf target to be
// returned from fee estimator.
func (h *HarnessTest) SetFeeEstimateWithConf(
fee chainfee.SatPerKWeight, conf uint32) {
h.feeService.SetFeeRate(fee, conf)
}
// validateNodeState checks that the node doesn't have any uncleaned states
// which will affect its following tests.
func (h *HarnessTest) validateNodeState(hn *node.HarnessNode) error {
errStr := func(subject string) error {
return fmt.Errorf("%s: found %s channels, please close "+
"them properly", hn.Name(), subject)
}
// If the node still has open channels, it's most likely that the
// current test didn't close it properly.
if hn.State.OpenChannel.Active != 0 {
return errStr("active")
}
if hn.State.OpenChannel.Public != 0 {
return errStr("public")
}
if hn.State.OpenChannel.Private != 0 {
return errStr("private")
}
if hn.State.OpenChannel.Pending != 0 {
return errStr("pending open")
}
// The number of pending force close channels should be zero.
if hn.State.CloseChannel.PendingForceClose != 0 {
return errStr("pending force")
}
// The number of waiting close channels should be zero.
if hn.State.CloseChannel.WaitingClose != 0 {
return errStr("waiting close")
}
// Ths number of payments should be zero.
if hn.State.Payment.Total != 0 {
return fmt.Errorf("%s: found uncleaned payments, please "+
"delete all of them properly", hn.Name())
}
return nil
}
// GetChanPointFundingTxid takes a channel point and converts it into a chain
// hash.
func (h *HarnessTest) GetChanPointFundingTxid(
cp *lnrpc.ChannelPoint) *chainhash.Hash {
txid, err := lnrpc.GetChanPointFundingTxid(cp)
require.NoError(h, err, "unable to get txid")
return txid
}
// OutPointFromChannelPoint creates an outpoint from a given channel point.
func (h *HarnessTest) OutPointFromChannelPoint(
cp *lnrpc.ChannelPoint) wire.OutPoint {
txid := h.GetChanPointFundingTxid(cp)
return wire.OutPoint{
Hash: *txid,
Index: cp.OutputIndex,
}
}
// OpenChannelParams houses the params to specify when opening a new channel.
type OpenChannelParams struct {
// Amt is the local amount being put into the channel.
Amt btcutil.Amount
// PushAmt is the amount that should be pushed to the remote when the
// channel is opened.
PushAmt btcutil.Amount
// Private is a boolan indicating whether the opened channel should be
// private.
Private bool
// SpendUnconfirmed is a boolean indicating whether we can utilize
// unconfirmed outputs to fund the channel.
SpendUnconfirmed bool
// MinHtlc is the htlc_minimum_msat value set when opening the channel.
MinHtlc lnwire.MilliSatoshi
// RemoteMaxHtlcs is the remote_max_htlcs value set when opening the
// channel, restricting the number of concurrent HTLCs the remote party
// can add to a commitment.
RemoteMaxHtlcs uint16
// FundingShim is an optional funding shim that the caller can specify
// in order to modify the channel funding workflow.
FundingShim *lnrpc.FundingShim
// SatPerVByte is the amount of satoshis to spend in chain fees per
// virtual byte of the transaction.
SatPerVByte btcutil.Amount
// CommitmentType is the commitment type that should be used for the
// channel to be opened.
CommitmentType lnrpc.CommitmentType
// ZeroConf is used to determine if the channel will be a zero-conf
// channel. This only works if the explicit negotiation is used with
// anchors or script enforced leases.
ZeroConf bool
// ScidAlias denotes whether the channel will be an option-scid-alias
// channel type negotiation.
ScidAlias bool
// BaseFee is the channel base fee applied during the channel
// announcement phase.
BaseFee uint64
// FeeRate is the channel fee rate in ppm applied during the channel
// announcement phase.
FeeRate uint64
// UseBaseFee, if set, instructs the downstream logic to apply the
// user-specified channel base fee to the channel update announcement.
// If set to false it avoids applying a base fee of 0 and instead
// activates the default configured base fee.
UseBaseFee bool
// UseFeeRate, if set, instructs the downstream logic to apply the
// user-specified channel fee rate to the channel update announcement.
// If set to false it avoids applying a fee rate of 0 and instead
// activates the default configured fee rate.
UseFeeRate bool
// FundMax is a boolean indicating whether the channel should be funded
// with the maximum possible amount from the wallet.
FundMax bool
}
// prepareOpenChannel waits for both nodes to be synced to chain and returns an
// OpenChannelRequest.
func (h *HarnessTest) prepareOpenChannel(srcNode, destNode *node.HarnessNode,
p OpenChannelParams) *lnrpc.OpenChannelRequest {
// Wait until srcNode and destNode have the latest chain synced.
// Otherwise, we may run into a check within the funding manager that
// prevents any funding workflows from being kicked off if the chain
// isn't yet synced.
h.WaitForBlockchainSync(srcNode)
h.WaitForBlockchainSync(destNode)
// Specify the minimal confirmations of the UTXOs used for channel
// funding.
minConfs := int32(1)
if p.SpendUnconfirmed {
minConfs = 0
}
// Prepare the request.
return &lnrpc.OpenChannelRequest{
NodePubkey: destNode.PubKey[:],
LocalFundingAmount: int64(p.Amt),
PushSat: int64(p.PushAmt),
Private: p.Private,
MinConfs: minConfs,
SpendUnconfirmed: p.SpendUnconfirmed,
MinHtlcMsat: int64(p.MinHtlc),
RemoteMaxHtlcs: uint32(p.RemoteMaxHtlcs),
FundingShim: p.FundingShim,
SatPerByte: int64(p.SatPerVByte),
CommitmentType: p.CommitmentType,
ZeroConf: p.ZeroConf,
ScidAlias: p.ScidAlias,
BaseFee: p.BaseFee,
FeeRate: p.FeeRate,
UseBaseFee: p.UseBaseFee,
UseFeeRate: p.UseFeeRate,
FundMax: p.FundMax,
}
}
// OpenChannelAssertPending attempts to open a channel between srcNode and
// destNode with the passed channel funding parameters. Once the `OpenChannel`
// is called, it will consume the first event it receives from the open channel
// client and asserts it's a channel pending event.
func (h *HarnessTest) openChannelAssertPending(srcNode,
destNode *node.HarnessNode,
p OpenChannelParams) (*lnrpc.PendingUpdate, rpc.OpenChanClient) {
// Prepare the request and open the channel.
openReq := h.prepareOpenChannel(srcNode, destNode, p)
respStream := srcNode.RPC.OpenChannel(openReq)
// Consume the "channel pending" update. This waits until the node
// notifies us that the final message in the channel funding workflow
// has been sent to the remote node.
resp := h.ReceiveOpenChannelUpdate(respStream)
// Check that the update is channel pending.
update, ok := resp.Update.(*lnrpc.OpenStatusUpdate_ChanPending)
require.Truef(h, ok, "expected channel pending: update, instead got %v",
resp)
return update.ChanPending, respStream
}
// OpenChannelAssertPending attempts to open a channel between srcNode and
// destNode with the passed channel funding parameters. Once the `OpenChannel`
// is called, it will consume the first event it receives from the open channel
// client and asserts it's a channel pending event. It returns the
// `PendingUpdate`.
func (h *HarnessTest) OpenChannelAssertPending(srcNode,
destNode *node.HarnessNode, p OpenChannelParams) *lnrpc.PendingUpdate {
resp, _ := h.openChannelAssertPending(srcNode, destNode, p)
return resp
}
// OpenChannelAssertStream attempts to open a channel between srcNode and
// destNode with the passed channel funding parameters. Once the `OpenChannel`
// is called, it will consume the first event it receives from the open channel
// client and asserts it's a channel pending event. It returns the open channel
// stream.
func (h *HarnessTest) OpenChannelAssertStream(srcNode,
destNode *node.HarnessNode, p OpenChannelParams) rpc.OpenChanClient {
_, stream := h.openChannelAssertPending(srcNode, destNode, p)
return stream
}
// OpenChannel attempts to open a channel with the specified parameters
// extended from Alice to Bob. Additionally, for public channels, it will mine
// extra blocks so they are announced to the network. In specific, the
// following items are asserted,
// - for non-zero conf channel, 1 blocks will be mined to confirm the funding
// tx.
// - both nodes should see the channel edge update in their network graph.
// - both nodes can report the status of the new channel from ListChannels.
// - extra blocks are mined if it's a public channel.
func (h *HarnessTest) OpenChannel(alice, bob *node.HarnessNode,
p OpenChannelParams) *lnrpc.ChannelPoint {
// First, open the channel without announcing it.
cp := h.OpenChannelNoAnnounce(alice, bob, p)
// If this is a private channel, there's no need to mine extra blocks
// since it will never be announced to the network.
if p.Private {
return cp
}
// Mine extra blocks to announce the channel.
if p.ZeroConf {
// For a zero-conf channel, no blocks have been mined so we
// need to mine 6 blocks.
//
// Mine 1 block to confirm the funding transaction.
h.MineBlocksAndAssertNumTxes(numBlocksOpenChannel, 1)
} else {
// For a regular channel, 1 block has already been mined to
// confirm the funding transaction, so we mine 5 blocks.
h.MineBlocks(numBlocksOpenChannel - 1)
}
return cp
}
// OpenChannelNoAnnounce attempts to open a channel with the specified
// parameters extended from Alice to Bob without mining the necessary blocks to
// announce the channel. Additionally, the following items are asserted,
// - for non-zero conf channel, 1 blocks will be mined to confirm the funding
// tx.
// - both nodes should see the channel edge update in their network graph.
// - both nodes can report the status of the new channel from ListChannels.
func (h *HarnessTest) OpenChannelNoAnnounce(alice, bob *node.HarnessNode,
p OpenChannelParams) *lnrpc.ChannelPoint {
chanOpenUpdate := h.OpenChannelAssertStream(alice, bob, p)
// Open a zero conf channel.
if p.ZeroConf {
return h.openChannelZeroConf(alice, bob, chanOpenUpdate)
}
// Open a non-zero conf channel.
return h.openChannel(alice, bob, chanOpenUpdate)
}
// openChannel attempts to open a channel with the specified parameters
// extended from Alice to Bob. Additionally, the following items are asserted,
// - 1 block is mined and the funding transaction should be found in it.
// - both nodes should see the channel edge update in their network graph.
// - both nodes can report the status of the new channel from ListChannels.
func (h *HarnessTest) openChannel(alice, bob *node.HarnessNode,
stream rpc.OpenChanClient) *lnrpc.ChannelPoint {
// Mine 1 block to confirm the funding transaction.
block := h.MineBlocksAndAssertNumTxes(1, 1)[0]
// Wait for the channel open event.
fundingChanPoint := h.WaitForChannelOpenEvent(stream)
// Check that the funding tx is found in the first block.
fundingTxID := h.GetChanPointFundingTxid(fundingChanPoint)
h.Miner.AssertTxInBlock(block, fundingTxID)
// Check that both alice and bob have seen the channel from their
// network topology.
h.AssertTopologyChannelOpen(alice, fundingChanPoint)
h.AssertTopologyChannelOpen(bob, fundingChanPoint)
// Check that the channel can be seen in their ListChannels.
h.AssertChannelExists(alice, fundingChanPoint)
h.AssertChannelExists(bob, fundingChanPoint)
return fundingChanPoint
}
// openChannelZeroConf attempts to open a channel with the specified parameters
// extended from Alice to Bob. Additionally, the following items are asserted,
// - both nodes should see the channel edge update in their network graph.
// - both nodes can report the status of the new channel from ListChannels.
func (h *HarnessTest) openChannelZeroConf(alice, bob *node.HarnessNode,
stream rpc.OpenChanClient) *lnrpc.ChannelPoint {
// Wait for the channel open event.
fundingChanPoint := h.WaitForChannelOpenEvent(stream)
// Check that both alice and bob have seen the channel from their
// network topology.
h.AssertTopologyChannelOpen(alice, fundingChanPoint)
h.AssertTopologyChannelOpen(bob, fundingChanPoint)
// Finally, check that the channel can be seen in their ListChannels.
h.AssertChannelExists(alice, fundingChanPoint)
h.AssertChannelExists(bob, fundingChanPoint)
return fundingChanPoint
}
// OpenChannelAssertErr opens a channel between node srcNode and destNode,
// asserts that the expected error is returned from the channel opening.
func (h *HarnessTest) OpenChannelAssertErr(srcNode, destNode *node.HarnessNode,
p OpenChannelParams, expectedErr error) {
// Prepare the request and open the channel.
openReq := h.prepareOpenChannel(srcNode, destNode, p)
respStream := srcNode.RPC.OpenChannel(openReq)
// Receive an error to be sent from the stream.
_, err := h.receiveOpenChannelUpdate(respStream)
// Use string comparison here as we haven't codified all the RPC errors
// yet.
require.Containsf(h, err.Error(), expectedErr.Error(), "unexpected "+
"error returned, want %v, got %v", expectedErr, err)
}
// CloseChannelAssertPending attempts to close the channel indicated by the
// passed channel point, initiated by the passed node. Once the CloseChannel
// rpc is called, it will consume one event and assert it's a close pending
// event. In addition, it will check that the closing tx can be found in the
// mempool.
func (h *HarnessTest) CloseChannelAssertPending(hn *node.HarnessNode,
cp *lnrpc.ChannelPoint,
force bool) (rpc.CloseChanClient, *chainhash.Hash) {
// Calls the rpc to close the channel.
closeReq := &lnrpc.CloseChannelRequest{
ChannelPoint: cp,
Force: force,
}
stream := hn.RPC.CloseChannel(closeReq)
// Consume the "channel close" update in order to wait for the closing
// transaction to be broadcast, then wait for the closing tx to be seen
// within the network.
event, err := h.ReceiveCloseChannelUpdate(stream)
if err != nil {
// TODO(yy): remove the sleep once the following bug is fixed.
// We may receive the error `cannot co-op close channel with
// active htlcs` or `link failed to shutdown` if we close the
// channel. We need to investigate the order of settling the
// payments and updating commitments to properly fix it.
time.Sleep(5 * time.Second)
// Give it another chance.
stream = hn.RPC.CloseChannel(closeReq)
event, err = h.ReceiveCloseChannelUpdate(stream)
require.NoError(h, err)
}
pendingClose, ok := event.Update.(*lnrpc.CloseStatusUpdate_ClosePending)
require.Truef(h, ok, "expected channel close update, instead got %v",
pendingClose)
closeTxid, err := chainhash.NewHash(pendingClose.ClosePending.Txid)
require.NoErrorf(h, err, "unable to decode closeTxid: %v",
pendingClose.ClosePending.Txid)
// Assert the closing tx is in the mempool.
h.Miner.AssertTxInMempool(closeTxid)
return stream, closeTxid
}
// CloseChannel attempts to coop close a non-anchored channel identified by the
// passed channel point owned by the passed harness node. The following items
// are asserted,
// 1. a close pending event is sent from the close channel client.
// 2. the closing tx is found in the mempool.
// 3. the node reports the channel being waiting to close.
// 4. a block is mined and the closing tx should be found in it.
// 5. the node reports zero waiting close channels.
// 6. the node receives a topology update regarding the channel close.
func (h *HarnessTest) CloseChannel(hn *node.HarnessNode,
cp *lnrpc.ChannelPoint) *chainhash.Hash {
stream, _ := h.CloseChannelAssertPending(hn, cp, false)
return h.AssertStreamChannelCoopClosed(hn, cp, false, stream)
}
// ForceCloseChannel attempts to force close a non-anchored channel identified
// by the passed channel point owned by the passed harness node. The following
// items are asserted,
// 1. a close pending event is sent from the close channel client.
// 2. the closing tx is found in the mempool.
// 3. the node reports the channel being waiting to close.
// 4. a block is mined and the closing tx should be found in it.
// 5. the node reports zero waiting close channels.
// 6. the node receives a topology update regarding the channel close.
// 7. mine DefaultCSV-1 blocks.
// 8. the node reports zero pending force close channels.
func (h *HarnessTest) ForceCloseChannel(hn *node.HarnessNode,
cp *lnrpc.ChannelPoint) *chainhash.Hash {
stream, _ := h.CloseChannelAssertPending(hn, cp, true)
closingTxid := h.AssertStreamChannelForceClosed(hn, cp, false, stream)
// Cleanup the force close.
h.CleanupForceClose(hn, cp)
return closingTxid
}
// CloseChannelAssertErr closes the given channel and asserts an error
// returned.
func (h *HarnessTest) CloseChannelAssertErr(hn *node.HarnessNode,
cp *lnrpc.ChannelPoint, force bool) error {
// Calls the rpc to close the channel.
closeReq := &lnrpc.CloseChannelRequest{
ChannelPoint: cp,
Force: force,
}
stream := hn.RPC.CloseChannel(closeReq)
// Consume the "channel close" update in order to wait for the closing
// transaction to be broadcast, then wait for the closing tx to be seen
// within the network.
_, err := h.ReceiveCloseChannelUpdate(stream)
require.Errorf(h, err, "%s: expect close channel to return an error",
hn.Name())
return err
}
// IsNeutrinoBackend returns a bool indicating whether the node is using a
// neutrino as its backend. This is useful when we want to skip certain tests
// which cannot be done with a neutrino backend.
func (h *HarnessTest) IsNeutrinoBackend() bool {
return h.manager.chainBackend.Name() == NeutrinoBackendName
}
// fundCoins attempts to send amt satoshis from the internal mining node to the
// targeted lightning node. The confirmed boolean indicates whether the
// transaction that pays to the target should confirm. For neutrino backend,
// the `confirmed` param is ignored.
func (h *HarnessTest) fundCoins(amt btcutil.Amount, target *node.HarnessNode,
addrType lnrpc.AddressType, confirmed bool) {
initialBalance := target.RPC.WalletBalance()
// First, obtain an address from the target lightning node, preferring
// to receive a p2wkh address s.t the output can immediately be used as
// an input to a funding transaction.
req := &lnrpc.NewAddressRequest{Type: addrType}
resp := target.RPC.NewAddress(req)
addr := h.DecodeAddress(resp.Address)
addrScript := h.PayToAddrScript(addr)
// Generate a transaction which creates an output to the target
// pkScript of the desired amount.
output := &wire.TxOut{
PkScript: addrScript,
Value: int64(amt),
}
h.Miner.SendOutput(output, defaultMinerFeeRate)
// Encode the pkScript in hex as this the format that it will be
// returned via rpc.
expPkScriptStr := hex.EncodeToString(addrScript)
// Now, wait for ListUnspent to show the unconfirmed transaction
// containing the correct pkscript.
//
// Since neutrino doesn't support unconfirmed outputs, skip this check.
if !h.IsNeutrinoBackend() {
utxos := h.AssertNumUTXOsUnconfirmed(target, 1)
// Assert that the lone unconfirmed utxo contains the same
// pkscript as the output generated above.
pkScriptStr := utxos[0].PkScript
require.Equal(h, pkScriptStr, expPkScriptStr,
"pkscript mismatch")
}
// If the transaction should remain unconfirmed, then we'll wait until
// the target node's unconfirmed balance reflects the expected balance
// and exit.
if !confirmed && !h.IsNeutrinoBackend() {
expectedBalance := btcutil.Amount(
initialBalance.UnconfirmedBalance,
) + amt
h.WaitForBalanceUnconfirmed(target, expectedBalance)
return
}
// Otherwise, we'll generate 1 new blocks to ensure the output gains a
// sufficient number of confirmations and wait for the balance to
// reflect what's expected.
h.MineBlocks(1)
expectedBalance := btcutil.Amount(initialBalance.ConfirmedBalance) + amt
h.WaitForBalanceConfirmed(target, expectedBalance)
}
// FundCoins attempts to send amt satoshis from the internal mining node to the
// targeted lightning node using a P2WKH address. 2 blocks are mined after in
// order to confirm the transaction.
func (h *HarnessTest) FundCoins(amt btcutil.Amount, hn *node.HarnessNode) {
h.fundCoins(amt, hn, lnrpc.AddressType_WITNESS_PUBKEY_HASH, true)
}
// FundCoinsUnconfirmed attempts to send amt satoshis from the internal mining
// node to the targeted lightning node using a P2WKH address. No blocks are
// mined after and the UTXOs are unconfirmed.
func (h *HarnessTest) FundCoinsUnconfirmed(amt btcutil.Amount,
hn *node.HarnessNode) {
h.fundCoins(amt, hn, lnrpc.AddressType_WITNESS_PUBKEY_HASH, false)
}
// FundCoinsNP2WKH attempts to send amt satoshis from the internal mining node
// to the targeted lightning node using a NP2WKH address.
func (h *HarnessTest) FundCoinsNP2WKH(amt btcutil.Amount,
target *node.HarnessNode) {
h.fundCoins(amt, target, lnrpc.AddressType_NESTED_PUBKEY_HASH, true)
}
// FundCoinsP2TR attempts to send amt satoshis from the internal mining node to
// the targeted lightning node using a P2TR address.
func (h *HarnessTest) FundCoinsP2TR(amt btcutil.Amount,
target *node.HarnessNode) {
h.fundCoins(amt, target, lnrpc.AddressType_TAPROOT_PUBKEY, true)
}
// completePaymentRequestsAssertStatus sends payments from a node to complete
// all payment requests. This function does not return until all payments
// have reached the specified status.
func (h *HarnessTest) completePaymentRequestsAssertStatus(hn *node.HarnessNode,
paymentRequests []string, status lnrpc.Payment_PaymentStatus) {
// Create a buffered chan to signal the results.
results := make(chan rpc.PaymentClient, len(paymentRequests))
// send sends a payment and asserts if it doesn't succeeded.
send := func(payReq string) {
req := &routerrpc.SendPaymentRequest{
PaymentRequest: payReq,
TimeoutSeconds: int32(wait.PaymentTimeout.Seconds()),
FeeLimitMsat: noFeeLimitMsat,
}
stream := hn.RPC.SendPayment(req)
// Signal sent succeeded.
results <- stream
}
// Launch all payments simultaneously.
for _, payReq := range paymentRequests {
payReqCopy := payReq
go send(payReqCopy)
}
// Wait for all payments to report the expected status.
timer := time.After(wait.PaymentTimeout)
select {
case stream := <-results:
h.AssertPaymentStatusFromStream(stream, status)
case <-timer:
require.Fail(h, "timeout", "waiting payment results timeout")
}
}
// CompletePaymentRequests sends payments from a node to complete all payment
// requests. This function does not return until all payments successfully
// complete without errors.
func (h *HarnessTest) CompletePaymentRequests(hn *node.HarnessNode,
paymentRequests []string) {
h.completePaymentRequestsAssertStatus(
hn, paymentRequests, lnrpc.Payment_SUCCEEDED,
)
}
// CompletePaymentRequestsNoWait sends payments from a node to complete all
// payment requests without waiting for the results. Instead, it checks the
// number of updates in the specified channel has increased.
func (h *HarnessTest) CompletePaymentRequestsNoWait(hn *node.HarnessNode,
paymentRequests []string, chanPoint *lnrpc.ChannelPoint) {
// We start by getting the current state of the client's channels. This
// is needed to ensure the payments actually have been committed before
// we return.
oldResp := h.GetChannelByChanPoint(hn, chanPoint)
// Send payments and assert they are in-flight.
h.completePaymentRequestsAssertStatus(
hn, paymentRequests, lnrpc.Payment_IN_FLIGHT,
)
// 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. We wait for the number of
// updates to one of our channels has increased before we return.
err := wait.NoError(func() error {
newResp := h.GetChannelByChanPoint(hn, chanPoint)
// If this channel has an increased number of updates, we
// assume the payments are committed, and we can return.
if newResp.NumUpdates > oldResp.NumUpdates {
return nil
}
// Otherwise return an error as the NumUpdates are not
// increased.
return fmt.Errorf("%s: channel:%v not updated after sending "+
"payments, old updates: %v, new updates: %v", hn.Name(),
chanPoint, oldResp.NumUpdates, newResp.NumUpdates)
}, DefaultTimeout)
require.NoError(h, err, "timeout while checking for channel updates")
}
// OpenChannelPsbt attempts to open a channel between srcNode and destNode with
// the passed channel funding parameters. It will assert if the expected step
// of funding the PSBT is not received from the source node.
func (h *HarnessTest) OpenChannelPsbt(srcNode, destNode *node.HarnessNode,
p OpenChannelParams) (rpc.OpenChanClient, []byte) {
// Wait until srcNode and destNode have the latest chain synced.
// Otherwise, we may run into a check within the funding manager that
// prevents any funding workflows from being kicked off if the chain
// isn't yet synced.
h.WaitForBlockchainSync(srcNode)
h.WaitForBlockchainSync(destNode)
// Send the request to open a channel to the source node now. This will
// open a long-lived stream where we'll receive status updates about
// the progress of the channel.
// respStream := h.OpenChannelStreamAndAssert(srcNode, destNode, p)
req := &lnrpc.OpenChannelRequest{
NodePubkey: destNode.PubKey[:],
LocalFundingAmount: int64(p.Amt),
PushSat: int64(p.PushAmt),
Private: p.Private,
SpendUnconfirmed: p.SpendUnconfirmed,
MinHtlcMsat: int64(p.MinHtlc),
FundingShim: p.FundingShim,
}
respStream := srcNode.RPC.OpenChannel(req)
// Consume the "PSBT funding ready" update. This waits until the node
// notifies us that the PSBT can now be funded.
resp := h.ReceiveOpenChannelUpdate(respStream)
upd, ok := resp.Update.(*lnrpc.OpenStatusUpdate_PsbtFund)
require.Truef(h, ok, "expected PSBT funding update, got %v", resp)
return respStream, upd.PsbtFund.Psbt
}
// CleanupForceClose mines a force close commitment found in the mempool and
// the following sweep transaction from the force closing node.
func (h *HarnessTest) CleanupForceClose(hn *node.HarnessNode,
chanPoint *lnrpc.ChannelPoint) {
// Wait for the channel to be marked pending force close.
h.AssertNumPendingForceClose(hn, 1)
// Mine enough blocks for the node to sweep its funds from the force
// closed channel.
//
// The commit sweep resolver is able to broadcast the sweep tx up to
// one block before the CSV elapses, so wait until defaulCSV-1.
h.MineBlocks(node.DefaultCSV - 1)
// The node should now sweep the funds, clean up by mining the sweeping
// tx.
h.MineBlocksAndAssertNumTxes(1, 1)
// Mine blocks to get any second level HTLC resolved. If there are no
// HTLCs, this will behave like h.AssertNumPendingCloseChannels.
h.mineTillForceCloseResolved(hn)
}
// mineTillForceCloseResolved asserts that the number of pending close channels
// are zero. Each time it checks, a new block is mined using MineBlocksSlow to
// give the node some time to catch up the chain.
//
// NOTE: this method is a workaround to make sure we have a clean mempool at
// the end of a channel force closure. We cannot directly mine blocks and
// assert channels being fully closed because the subsystems in lnd don't share
// the same block height. This is especially the case when blocks are produced
// too fast.
// TODO(yy): remove this workaround when syncing blocks are unified in all the
// subsystems.
func (h *HarnessTest) mineTillForceCloseResolved(hn *node.HarnessNode) {
_, startHeight := h.Miner.GetBestBlock()
err := wait.NoError(func() error {
resp := hn.RPC.PendingChannels()
total := len(resp.PendingForceClosingChannels)
if total != 0 {
h.MineBlocks(1)
return fmt.Errorf("expected num of pending force " +
"close channel to be zero")
}
_, height := h.Miner.GetBestBlock()
h.Logf("Mined %d blocks while waiting for force closed "+
"channel to be resolved", height-startHeight)
return nil
}, DefaultTimeout)
require.NoErrorf(h, err, "assert force close resolved timeout")
}
// CreatePayReqs is a helper method that will create a slice of payment
// requests for the given node.
func (h *HarnessTest) CreatePayReqs(hn *node.HarnessNode,
paymentAmt btcutil.Amount, numInvoices int) ([]string,
[][]byte, []*lnrpc.Invoice) {
payReqs := make([]string, numInvoices)
rHashes := make([][]byte, numInvoices)
invoices := make([]*lnrpc.Invoice, numInvoices)
for i := 0; i < numInvoices; i++ {
preimage := h.Random32Bytes()
invoice := &lnrpc.Invoice{
Memo: "testing",
RPreimage: preimage,
Value: int64(paymentAmt),
}
resp := hn.RPC.AddInvoice(invoice)
// Set the payment address in the invoice so the caller can
// properly use it.
invoice.PaymentAddr = resp.PaymentAddr
payReqs[i] = resp.PaymentRequest
rHashes[i] = resp.RHash
invoices[i] = invoice
}
return payReqs, rHashes, invoices
}
// BackupDB creates a backup of the current database. It will stop the node
// first, copy the database files, and restart the node.
func (h *HarnessTest) BackupDB(hn *node.HarnessNode) {
restart := h.SuspendNode(hn)
err := hn.BackupDB()
require.NoErrorf(h, err, "%s: failed to backup db", hn.Name())
err = restart()
require.NoErrorf(h, err, "%s: failed to restart", hn.Name())
}
// RestartNodeAndRestoreDB restarts a given node with a callback to restore the
// db.
func (h *HarnessTest) RestartNodeAndRestoreDB(hn *node.HarnessNode) {
cb := func() error { return hn.RestoreDB() }
err := h.manager.restartNode(h.runCtx, hn, cb)
require.NoErrorf(h, err, "failed to restart node %s", hn.Name())
err = h.manager.unlockNode(hn)
require.NoErrorf(h, err, "failed to unlock node %s", hn.Name())
// Give the node some time to catch up with the chain before we
// continue with the tests.
h.WaitForBlockchainSync(hn)
}
// MineBlocks mines blocks and asserts all active nodes have synced to the
// chain.
//
// NOTE: this differs from miner's `MineBlocks` as it requires the nodes to be
// synced.
func (h *HarnessTest) MineBlocks(num uint32) []*wire.MsgBlock {
// Mining the blocks slow to give `lnd` more time to sync.
blocks := h.Miner.MineBlocksSlow(num)
// Make sure all the active nodes are synced.
bestBlock := blocks[len(blocks)-1]
h.AssertActiveNodesSyncedTo(bestBlock)
return blocks
}
// MineBlocksAndAssertNumTxes mines blocks and asserts the number of
// transactions are found in the first block. It also asserts all active nodes
// have synced to the chain.
//
// NOTE: this differs from miner's `MineBlocks` as it requires the nodes to be
// synced.
func (h *HarnessTest) MineBlocksAndAssertNumTxes(num uint32,
numTxs int) []*wire.MsgBlock {
// If we expect transactions to be included in the blocks we'll mine,
// we wait here until they are seen in the miner's mempool.
txids := h.Miner.AssertNumTxsInMempool(numTxs)
// Mine blocks.
blocks := h.Miner.MineBlocksSlow(num)
// Assert that all the transactions were included in the first block.
for _, txid := range txids {
h.Miner.AssertTxInBlock(blocks[0], txid)
}
// Finally, make sure all the active nodes are synced.
bestBlock := blocks[len(blocks)-1]
h.AssertActiveNodesSyncedTo(bestBlock)
return blocks
}
// cleanMempool mines blocks till the mempool is empty and asserts all active
// nodes have synced to the chain.
func (h *HarnessTest) cleanMempool() {
_, startHeight := h.Miner.GetBestBlock()
// Mining the blocks slow to give `lnd` more time to sync.
var bestBlock *wire.MsgBlock
err := wait.NoError(func() error {
// If mempool is empty, exit.
mem := h.Miner.GetRawMempool()
if len(mem) == 0 {
_, height := h.Miner.GetBestBlock()
h.Logf("Mined %d blocks when cleanup the mempool",
height-startHeight)
return nil
}
// Otherwise mine a block.
blocks := h.Miner.MineBlocksSlow(1)
bestBlock = blocks[len(blocks)-1]
// Make sure all the active nodes are synced.
h.AssertActiveNodesSyncedTo(bestBlock)
return fmt.Errorf("still have %d txes in mempool", len(mem))
}, wait.MinerMempoolTimeout)
require.NoError(h, err, "timeout cleaning up mempool")
}
// CleanShutDown is used to quickly end a test by shutting down all non-standby
// nodes and mining blocks to empty the mempool.
//
// NOTE: this method provides a faster exit for a test that involves force
// closures as the caller doesn't need to mine all the blocks to make sure the
// mempool is empty.
func (h *HarnessTest) CleanShutDown() {
// First, shutdown all non-standby nodes to prevent new transactions
// being created and fed into the mempool.
h.shutdownNonStandbyNodes()
// Now mine blocks till the mempool is empty.
h.cleanMempool()
}
// MineEmptyBlocks mines a given number of empty blocks.
//
// NOTE: this differs from miner's `MineEmptyBlocks` as it requires the nodes
// to be synced.
func (h *HarnessTest) MineEmptyBlocks(num int) []*wire.MsgBlock {
blocks := h.Miner.MineEmptyBlocks(num)
// Finally, make sure all the active nodes are synced.
h.AssertActiveNodesSynced()
return blocks
}
// QueryChannelByChanPoint tries to find a channel matching the channel point
// and asserts. It returns the channel found.
func (h *HarnessTest) QueryChannelByChanPoint(hn *node.HarnessNode,
chanPoint *lnrpc.ChannelPoint,
opts ...ListChannelOption) *lnrpc.Channel {
channel, err := h.findChannel(hn, chanPoint, opts...)
require.NoError(h, err, "failed to query channel")
return channel
}
// SendPaymentAndAssertStatus sends a payment from the passed node and asserts
// the desired status is reached.
func (h *HarnessTest) SendPaymentAndAssertStatus(hn *node.HarnessNode,
req *routerrpc.SendPaymentRequest,
status lnrpc.Payment_PaymentStatus) *lnrpc.Payment {
stream := hn.RPC.SendPayment(req)
return h.AssertPaymentStatusFromStream(stream, status)
}
// SendPaymentAssertFail sends a payment from the passed node and asserts the
// payment is failed with the specified failure reason .
func (h *HarnessTest) SendPaymentAssertFail(hn *node.HarnessNode,
req *routerrpc.SendPaymentRequest,
reason lnrpc.PaymentFailureReason) *lnrpc.Payment {
payment := h.SendPaymentAndAssertStatus(hn, req, lnrpc.Payment_FAILED)
require.Equal(h, reason, payment.FailureReason,
"payment failureReason not matched")
return payment
}
// SendPaymentAssertSettled sends a payment from the passed node and asserts the
// payment is settled.
func (h *HarnessTest) SendPaymentAssertSettled(hn *node.HarnessNode,
req *routerrpc.SendPaymentRequest) *lnrpc.Payment {
return h.SendPaymentAndAssertStatus(hn, req, lnrpc.Payment_SUCCEEDED)
}
// OpenChannelRequest is used to open a channel using the method
// OpenMultiChannelsAsync.
type OpenChannelRequest struct {
// Local is the funding node.
Local *node.HarnessNode
// Remote is the receiving node.
Remote *node.HarnessNode
// Param is the open channel params.
Param OpenChannelParams
// stream is the client created after calling OpenChannel RPC.
stream rpc.OpenChanClient
// result is a channel used to send the channel point once the funding
// has succeeded.
result chan *lnrpc.ChannelPoint
}
// OpenMultiChannelsAsync takes a list of OpenChannelRequest and opens them in
// batch. The channel points are returned in same the order of the requests
// once all of the channel open succeeded.
//
// NOTE: compared to open multiple channel sequentially, this method will be
// faster as it doesn't need to mine 6 blocks for each channel open. However,
// it does make debugging the logs more difficult as messages are intertwined.
func (h *HarnessTest) OpenMultiChannelsAsync(
reqs []*OpenChannelRequest) []*lnrpc.ChannelPoint {
// openChannel opens a channel based on the request.
openChannel := func(req *OpenChannelRequest) {
stream := h.OpenChannelAssertStream(
req.Local, req.Remote, req.Param,
)
req.stream = stream
}
// assertChannelOpen is a helper closure that asserts a channel is
// open.
assertChannelOpen := func(req *OpenChannelRequest) {
// Wait for the channel open event from the stream.
cp := h.WaitForChannelOpenEvent(req.stream)
// Check that both alice and bob have seen the channel
// from their channel watch request.
h.AssertTopologyChannelOpen(req.Local, cp)
h.AssertTopologyChannelOpen(req.Remote, cp)
// Finally, check that the channel can be seen in their
// ListChannels.
h.AssertChannelExists(req.Local, cp)
h.AssertChannelExists(req.Remote, cp)
req.result <- cp
}
// Go through the requests and make the OpenChannel RPC call.
for _, r := range reqs {
openChannel(r)
}
// Mine one block to confirm all the funding transactions.
h.MineBlocksAndAssertNumTxes(1, len(reqs))
// Mine 5 more blocks so all the public channels are announced to the
// network.
h.MineBlocks(numBlocksOpenChannel - 1)
// Once the blocks are mined, we fire goroutines for each of the
// request to watch for the channel openning.
for _, r := range reqs {
r.result = make(chan *lnrpc.ChannelPoint, 1)
go assertChannelOpen(r)
}
// Finally, collect the results.
channelPoints := make([]*lnrpc.ChannelPoint, 0)
for _, r := range reqs {
select {
case cp := <-r.result:
channelPoints = append(channelPoints, cp)
case <-time.After(wait.ChannelOpenTimeout):
require.Failf(h, "timeout", "wait channel point "+
"timeout for channel %s=>%s", r.Local.Name(),
r.Remote.Name())
}
}
// Assert that we have the expected num of channel points.
require.Len(h, channelPoints, len(reqs),
"returned channel points not match")
return channelPoints
}
// ReceiveInvoiceUpdate waits until a message is received on the subscribe
// invoice stream or the timeout is reached.
func (h *HarnessTest) ReceiveInvoiceUpdate(
stream rpc.InvoiceUpdateClient) *lnrpc.Invoice {
chanMsg := make(chan *lnrpc.Invoice)
errChan := make(chan error)
go func() {
// Consume one message. This will block until the message is
// received.
resp, err := stream.Recv()
if err != nil {
errChan <- err
return
}
chanMsg <- resp
}()
select {
case <-time.After(DefaultTimeout):
require.Fail(h, "timeout", "timeout receiving invoice update")
case err := <-errChan:
require.Failf(h, "err from stream",
"received err from stream: %v", err)
case updateMsg := <-chanMsg:
return updateMsg
}
return nil
}
// CalculateTxFee retrieves parent transactions and reconstructs the fee paid.
func (h *HarnessTest) CalculateTxFee(tx *wire.MsgTx) btcutil.Amount {
var balance btcutil.Amount
for _, in := range tx.TxIn {
parentHash := in.PreviousOutPoint.Hash
rawTx := h.Miner.GetRawTransaction(&parentHash)
parent := rawTx.MsgTx()
balance += btcutil.Amount(
parent.TxOut[in.PreviousOutPoint.Index].Value,
)
}
for _, out := range tx.TxOut {
balance -= btcutil.Amount(out.Value)
}
return balance
}
// CalculateTxesFeeRate takes a list of transactions and estimates the fee rate
// used to sweep them.
//
// NOTE: only used in current test file.
func (h *HarnessTest) CalculateTxesFeeRate(txns []*wire.MsgTx) int64 {
const scale = 1000
var totalWeight, totalFee int64
for _, tx := range txns {
utx := btcutil.NewTx(tx)
totalWeight += blockchain.GetTransactionWeight(utx)
fee := h.CalculateTxFee(tx)
totalFee += int64(fee)
}
feeRate := totalFee * scale / totalWeight
return feeRate
}
type SweptOutput struct {
OutPoint wire.OutPoint
SweepTx *wire.MsgTx
}
// FindCommitAndAnchor looks for a commitment sweep and anchor sweep in the
// mempool. Our anchor output is identified by having multiple inputs in its
// sweep transition, because we have to bring another input to add fees to the
// anchor. Note that the anchor swept output may be nil if the channel did not
// have anchors.
func (h *HarnessTest) FindCommitAndAnchor(sweepTxns []*wire.MsgTx,
closeTx string) (*SweptOutput, *SweptOutput) {
var commitSweep, anchorSweep *SweptOutput
for _, tx := range sweepTxns {
txHash := tx.TxHash()
sweepTx := h.Miner.GetRawTransaction(&txHash)
// We expect our commitment sweep to have a single input, and,
// our anchor sweep to have more inputs (because the wallet
// needs to add balance to the anchor amount). We find their
// sweep txids here to setup appropriate resolutions. We also
// need to find the outpoint for our resolution, which we do by
// matching the inputs to the sweep to the close transaction.
inputs := sweepTx.MsgTx().TxIn
if len(inputs) == 1 {
commitSweep = &SweptOutput{
OutPoint: inputs[0].PreviousOutPoint,
SweepTx: tx,
}
} else {
// Since we have more than one input, we run through
// them to find the one whose previous outpoint matches
// the closing txid, which means this input is spending
// the close tx. This will be our anchor output.
for _, txin := range inputs {
op := txin.PreviousOutPoint.Hash.String()
if op == closeTx {
anchorSweep = &SweptOutput{
OutPoint: txin.PreviousOutPoint,
SweepTx: tx,
}
}
}
}
}
return commitSweep, anchorSweep
}
// AssertSweepFound looks up a sweep in a nodes list of broadcast sweeps and
// asserts it's found.
//
// NOTE: Does not account for node's internal state.
func (h *HarnessTest) AssertSweepFound(hn *node.HarnessNode,
sweep string, verbose bool) {
// List all sweeps that alice's node had broadcast.
sweepResp := hn.RPC.ListSweeps(verbose)
var found bool
if verbose {
found = findSweepInDetails(h, sweep, sweepResp)
} else {
found = findSweepInTxids(h, sweep, sweepResp)
}
require.Truef(h, found, "%s: sweep: %v not found", sweep, hn.Name())
}
func findSweepInTxids(ht *HarnessTest, sweepTxid string,
sweepResp *walletrpc.ListSweepsResponse) bool {
sweepTxIDs := sweepResp.GetTransactionIds()
require.NotNil(ht, sweepTxIDs, "expected transaction ids")
require.Nil(ht, sweepResp.GetTransactionDetails())
// Check that the sweep tx we have just produced is present.
for _, tx := range sweepTxIDs.TransactionIds {
if tx == sweepTxid {
return true
}
}
return false
}
func findSweepInDetails(ht *HarnessTest, sweepTxid string,
sweepResp *walletrpc.ListSweepsResponse) bool {
sweepDetails := sweepResp.GetTransactionDetails()
require.NotNil(ht, sweepDetails, "expected transaction details")
require.Nil(ht, sweepResp.GetTransactionIds())
for _, tx := range sweepDetails.Transactions {
if tx.TxHash == sweepTxid {
return true
}
}
return false
}
// ConnectMiner connects the miner with the chain backend in the network.
func (h *HarnessTest) ConnectMiner() {
err := h.manager.chainBackend.ConnectMiner()
require.NoError(h, err, "failed to connect miner")
}
// DisconnectMiner removes the connection between the miner and the chain
// backend in the network.
func (h *HarnessTest) DisconnectMiner() {
err := h.manager.chainBackend.DisconnectMiner()
require.NoError(h, err, "failed to disconnect miner")
}
// QueryRoutesAndRetry attempts to keep querying a route until timeout is
// reached.
//
// NOTE: when a channel is opened, we may need to query multiple times to get
// it in our QueryRoutes RPC. This happens even after we check the channel is
// heard by the node using ht.AssertChannelOpen. Deep down, this is because our
// GraphTopologySubscription and QueryRoutes give different results regarding a
// specific channel, with the formal reporting it being open while the latter
// not, resulting GraphTopologySubscription acting "faster" than QueryRoutes.
// TODO(yy): make sure related subsystems share the same view on a given
// channel.
func (h *HarnessTest) QueryRoutesAndRetry(hn *node.HarnessNode,
req *lnrpc.QueryRoutesRequest) *lnrpc.QueryRoutesResponse {
var routes *lnrpc.QueryRoutesResponse
err := wait.NoError(func() error {
ctxt, cancel := context.WithCancel(h.runCtx)
defer cancel()
resp, err := hn.RPC.LN.QueryRoutes(ctxt, req)
if err != nil {
return fmt.Errorf("%s: failed to query route: %w",
hn.Name(), err)
}
routes = resp
return nil
}, DefaultTimeout)
require.NoError(h, err, "timeout querying routes")
return routes
}
// ReceiveHtlcInterceptor waits until a message is received on the htlc
// interceptor stream or the timeout is reached.
func (h *HarnessTest) ReceiveHtlcInterceptor(
stream rpc.InterceptorClient) *routerrpc.ForwardHtlcInterceptRequest {
chanMsg := make(chan *routerrpc.ForwardHtlcInterceptRequest)
errChan := make(chan error)
go func() {
// Consume one message. This will block until the message is
// received.
resp, err := stream.Recv()
if err != nil {
errChan <- err
return
}
chanMsg <- resp
}()
select {
case <-time.After(DefaultTimeout):
require.Fail(h, "timeout", "timeout intercepting htlc")
case err := <-errChan:
require.Failf(h, "err from stream",
"received err from stream: %v", err)
case updateMsg := <-chanMsg:
return updateMsg
}
return nil
}
// ReceiveChannelEvent waits until a message is received from the
// ChannelEventsClient stream or the timeout is reached.
func (h *HarnessTest) ReceiveChannelEvent(
stream rpc.ChannelEventsClient) *lnrpc.ChannelEventUpdate {
chanMsg := make(chan *lnrpc.ChannelEventUpdate)
errChan := make(chan error)
go func() {
// Consume one message. This will block until the message is
// received.
resp, err := stream.Recv()
if err != nil {
errChan <- err
return
}
chanMsg <- resp
}()
select {
case <-time.After(DefaultTimeout):
require.Fail(h, "timeout", "timeout intercepting htlc")
case err := <-errChan:
require.Failf(h, "err from stream",
"received err from stream: %v", err)
case updateMsg := <-chanMsg:
return updateMsg
}
return nil
}
// GetOutputIndex returns the output index of the given address in the given
// transaction.
func (h *HarnessTest) GetOutputIndex(txid *chainhash.Hash, addr string) int {
// We'll then extract the raw transaction from the mempool in order to
// determine the index of the p2tr output.
tx := h.Miner.GetRawTransaction(txid)
p2trOutputIndex := -1
for i, txOut := range tx.MsgTx().TxOut {
_, addrs, _, err := txscript.ExtractPkScriptAddrs(
txOut.PkScript, h.Miner.ActiveNet,
)
require.NoError(h, err)
if addrs[0].String() == addr {
p2trOutputIndex = i
}
}
require.Greater(h, p2trOutputIndex, -1)
return p2trOutputIndex
}