lnd/watchtower/wtclient/client.go
2021-01-04 08:33:34 -08:00

1275 lines
42 KiB
Go

package wtclient
import (
"bytes"
"errors"
"fmt"
"net"
"sync"
"time"
"github.com/btcsuite/btcd/btcec"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btclog"
"github.com/lightningnetwork/lnd/build"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/input"
"github.com/lightningnetwork/lnd/keychain"
"github.com/lightningnetwork/lnd/lnwallet"
"github.com/lightningnetwork/lnd/lnwire"
"github.com/lightningnetwork/lnd/tor"
"github.com/lightningnetwork/lnd/watchtower/wtdb"
"github.com/lightningnetwork/lnd/watchtower/wtpolicy"
"github.com/lightningnetwork/lnd/watchtower/wtserver"
"github.com/lightningnetwork/lnd/watchtower/wtwire"
)
const (
// DefaultReadTimeout specifies the default duration we will wait during
// a read before breaking out of a blocking read.
DefaultReadTimeout = 15 * time.Second
// DefaultWriteTimeout specifies the default duration we will wait during
// a write before breaking out of a blocking write.
DefaultWriteTimeout = 15 * time.Second
// DefaultStatInterval specifies the default interval between logging
// metrics about the client's operation.
DefaultStatInterval = time.Minute
// DefaultForceQuitDelay specifies the default duration after which the
// client should abandon any pending updates or session negotiations
// before terminating.
DefaultForceQuitDelay = 10 * time.Second
)
// genActiveSessionFilter generates a filter that selects active sessions that
// also match the desired channel type, either legacy or anchor.
func genActiveSessionFilter(anchor bool) func(*wtdb.ClientSession) bool {
return func(s *wtdb.ClientSession) bool {
return s.Status == wtdb.CSessionActive &&
anchor == s.Policy.IsAnchorChannel()
}
}
// RegisteredTower encompasses information about a registered watchtower with
// the client.
type RegisteredTower struct {
*wtdb.Tower
// Sessions is the set of sessions corresponding to the watchtower.
Sessions map[wtdb.SessionID]*wtdb.ClientSession
// ActiveSessionCandidate determines whether the watchtower is currently
// being considered for new sessions.
ActiveSessionCandidate bool
}
// Client is the primary interface used by the daemon to control a client's
// lifecycle and backup revoked states.
type Client interface {
// AddTower adds a new watchtower reachable at the given address and
// considers it for new sessions. If the watchtower already exists, then
// any new addresses included will be considered when dialing it for
// session negotiations and backups.
AddTower(*lnwire.NetAddress) error
// RemoveTower removes a watchtower from being considered for future
// session negotiations and from being used for any subsequent backups
// until it's added again. If an address is provided, then this call
// only serves as a way of removing the address from the watchtower
// instead.
RemoveTower(*btcec.PublicKey, net.Addr) error
// RegisteredTowers retrieves the list of watchtowers registered with
// the client.
RegisteredTowers() ([]*RegisteredTower, error)
// LookupTower retrieves a registered watchtower through its public key.
LookupTower(*btcec.PublicKey) (*RegisteredTower, error)
// Stats returns the in-memory statistics of the client since startup.
Stats() ClientStats
// Policy returns the active client policy configuration.
Policy() wtpolicy.Policy
// RegisterChannel persistently initializes any channel-dependent
// parameters within the client. This should be called during link
// startup to ensure that the client is able to support the link during
// operation.
RegisterChannel(lnwire.ChannelID) error
// BackupState initiates a request to back up a particular revoked
// state. If the method returns nil, the backup is guaranteed to be
// successful unless the client is force quit, or the justice
// transaction would create dust outputs when trying to abide by the
// negotiated policy. If the channel we're trying to back up doesn't
// have a tweak for the remote party's output, then isTweakless should
// be true.
BackupState(*lnwire.ChannelID, *lnwallet.BreachRetribution,
channeldb.ChannelType) error
// Start initializes the watchtower client, allowing it process requests
// to backup revoked channel states.
Start() error
// Stop attempts a graceful shutdown of the watchtower client. In doing
// so, it will attempt to flush the pipeline and deliver any queued
// states to the tower before exiting.
Stop() error
// ForceQuit will forcibly shutdown the watchtower client. Calling this
// may lead to queued states being dropped.
ForceQuit()
}
// Config provides the TowerClient with access to the resources it requires to
// perform its duty. All nillable fields must be non-nil for the tower to be
// initialized properly.
type Config struct {
// Signer provides access to the wallet so that the client can sign
// justice transactions that spend from a remote party's commitment
// transaction.
Signer input.Signer
// NewAddress generates a new on-chain sweep pkscript.
NewAddress func() ([]byte, error)
// SecretKeyRing is used to derive the session keys used to communicate
// with the tower. The client only stores the KeyLocators internally so
// that we never store private keys on disk.
SecretKeyRing ECDHKeyRing
// Dial connects to an addr using the specified net and returns the
// connection object.
Dial tor.DialFunc
// AuthDialer establishes a brontide connection over an onion or clear
// network.
AuthDial AuthDialer
// DB provides access to the client's stable storage medium.
DB DB
// Policy is the session policy the client will propose when creating
// new sessions with the tower. If the policy differs from any active
// sessions recorded in the database, those sessions will be ignored and
// new sessions will be requested immediately.
Policy wtpolicy.Policy
// ChainHash identifies the chain that the client is on and for which
// the tower must be watching to monitor for breaches.
ChainHash chainhash.Hash
// ForceQuitDelay is the duration after attempting to shutdown that the
// client will automatically abort any pending backups if an unclean
// shutdown is detected. If the value is less than or equal to zero, a
// call to Stop may block indefinitely. The client can always be
// ForceQuit externally irrespective of the chosen parameter.
ForceQuitDelay time.Duration
// ReadTimeout is the duration we will wait during a read before
// breaking out of a blocking read. If the value is less than or equal
// to zero, the default will be used instead.
ReadTimeout time.Duration
// WriteTimeout is the duration we will wait during a write before
// breaking out of a blocking write. If the value is less than or equal
// to zero, the default will be used instead.
WriteTimeout time.Duration
// MinBackoff defines the initial backoff applied to connections with
// watchtowers. Subsequent backoff durations will grow exponentially up
// until MaxBackoff.
MinBackoff time.Duration
// MaxBackoff defines the maximum backoff applied to connections with
// watchtowers. If the exponential backoff produces a timeout greater
// than this value, the backoff will be clamped to MaxBackoff.
MaxBackoff time.Duration
}
// newTowerMsg is an internal message we'll use within the TowerClient to signal
// that a new tower can be considered.
type newTowerMsg struct {
// addr is the tower's reachable address that we'll use to establish a
// connection with.
addr *lnwire.NetAddress
// errChan is the channel through which we'll send a response back to
// the caller when handling their request.
//
// NOTE: This channel must be buffered.
errChan chan error
}
// staleTowerMsg is an internal message we'll use within the TowerClient to
// signal that a tower should no longer be considered.
type staleTowerMsg struct {
// pubKey is the identifying public key of the watchtower.
pubKey *btcec.PublicKey
// addr is an optional field that when set signals that the address
// should be removed from the watchtower's set of addresses, indicating
// that it is stale. If it's not set, then the watchtower should be
// no longer be considered for new sessions.
addr net.Addr
// errChan is the channel through which we'll send a response back to
// the caller when handling their request.
//
// NOTE: This channel must be buffered.
errChan chan error
}
// TowerClient is a concrete implementation of the Client interface, offering a
// non-blocking, reliable subsystem for backing up revoked states to a specified
// private tower.
type TowerClient struct {
started sync.Once
stopped sync.Once
forced sync.Once
cfg *Config
log btclog.Logger
pipeline *taskPipeline
negotiator SessionNegotiator
candidateTowers TowerCandidateIterator
candidateSessions map[wtdb.SessionID]*wtdb.ClientSession
activeSessions sessionQueueSet
sessionQueue *sessionQueue
prevTask *backupTask
backupMu sync.Mutex
summaries wtdb.ChannelSummaries
chanCommitHeights map[lnwire.ChannelID]uint64
statTicker *time.Ticker
stats *ClientStats
newTowers chan *newTowerMsg
staleTowers chan *staleTowerMsg
wg sync.WaitGroup
forceQuit chan struct{}
}
// Compile-time constraint to ensure *TowerClient implements the Client
// interface.
var _ Client = (*TowerClient)(nil)
// New initializes a new TowerClient from the provide Config. An error is
// returned if the client could not initialized.
func New(config *Config) (*TowerClient, error) {
// Copy the config to prevent side-effects from modifying both the
// internal and external version of the Config.
cfg := new(Config)
*cfg = *config
// Set the read timeout to the default if none was provided.
if cfg.ReadTimeout <= 0 {
cfg.ReadTimeout = DefaultReadTimeout
}
// Set the write timeout to the default if none was provided.
if cfg.WriteTimeout <= 0 {
cfg.WriteTimeout = DefaultWriteTimeout
}
prefix := "(legacy)"
if cfg.Policy.IsAnchorChannel() {
prefix = "(anchor)"
}
plog := build.NewPrefixLog(prefix, log)
// Next, load all candidate sessions and towers from the database into
// the client. We will use any of these session if their policies match
// the current policy of the client, otherwise they will be ignored and
// new sessions will be requested.
isAnchorClient := cfg.Policy.IsAnchorChannel()
activeSessionFilter := genActiveSessionFilter(isAnchorClient)
candidateSessions, err := getClientSessions(
cfg.DB, cfg.SecretKeyRing, nil, activeSessionFilter,
)
if err != nil {
return nil, err
}
var candidateTowers []*wtdb.Tower
for _, s := range candidateSessions {
plog.Infof("Using private watchtower %s, offering policy %s",
s.Tower, cfg.Policy)
candidateTowers = append(candidateTowers, s.Tower)
}
// Load the sweep pkscripts that have been generated for all previously
// registered channels.
chanSummaries, err := cfg.DB.FetchChanSummaries()
if err != nil {
return nil, err
}
c := &TowerClient{
cfg: cfg,
log: plog,
pipeline: newTaskPipeline(plog),
candidateTowers: newTowerListIterator(candidateTowers...),
candidateSessions: candidateSessions,
activeSessions: make(sessionQueueSet),
summaries: chanSummaries,
statTicker: time.NewTicker(DefaultStatInterval),
stats: new(ClientStats),
newTowers: make(chan *newTowerMsg),
staleTowers: make(chan *staleTowerMsg),
forceQuit: make(chan struct{}),
}
c.negotiator = newSessionNegotiator(&NegotiatorConfig{
DB: cfg.DB,
SecretKeyRing: cfg.SecretKeyRing,
Policy: cfg.Policy,
ChainHash: cfg.ChainHash,
SendMessage: c.sendMessage,
ReadMessage: c.readMessage,
Dial: c.dial,
Candidates: c.candidateTowers,
MinBackoff: cfg.MinBackoff,
MaxBackoff: cfg.MaxBackoff,
Log: plog,
})
// Reconstruct the highest commit height processed for each channel
// under the client's current policy.
c.buildHighestCommitHeights()
return c, nil
}
// getClientSessions retrieves the client sessions for a particular tower if
// specified, otherwise all client sessions for all towers are retrieved. An
// optional filter can be provided to filter out any undesired client sessions.
//
// NOTE: This method should only be used when deserialization of a
// ClientSession's Tower and SessionPrivKey fields is desired, otherwise, the
// existing ListClientSessions method should be used.
func getClientSessions(db DB, keyRing ECDHKeyRing, forTower *wtdb.TowerID,
passesFilter func(*wtdb.ClientSession) bool) (
map[wtdb.SessionID]*wtdb.ClientSession, error) {
sessions, err := db.ListClientSessions(forTower)
if err != nil {
return nil, err
}
// Reload the tower from disk using the tower ID contained in each
// candidate session. We will also rederive any session keys needed to
// be able to communicate with the towers and authenticate session
// requests. This prevents us from having to store the private keys on
// disk.
for _, s := range sessions {
tower, err := db.LoadTowerByID(s.TowerID)
if err != nil {
return nil, err
}
s.Tower = tower
towerKeyDesc, err := keyRing.DeriveKey(keychain.KeyLocator{
Family: keychain.KeyFamilyTowerSession,
Index: s.KeyIndex,
})
if err != nil {
return nil, err
}
s.SessionKeyECDH = keychain.NewPubKeyECDH(towerKeyDesc, keyRing)
// If an optional filter was provided, use it to filter out any
// undesired sessions.
if passesFilter != nil && !passesFilter(s) {
delete(sessions, s.ID)
}
}
return sessions, nil
}
// buildHighestCommitHeights inspects the full set of candidate client sessions
// loaded from disk, and determines the highest known commit height for each
// channel. This allows the client to reject backups that it has already
// processed for it's active policy.
func (c *TowerClient) buildHighestCommitHeights() {
chanCommitHeights := make(map[lnwire.ChannelID]uint64)
for _, s := range c.candidateSessions {
// We only want to consider accepted updates that have been
// accepted under an identical policy to the client's current
// policy.
if s.Policy != c.cfg.Policy {
continue
}
// Take the highest commit height found in the session's
// committed updates.
for _, committedUpdate := range s.CommittedUpdates {
bid := committedUpdate.BackupID
height, ok := chanCommitHeights[bid.ChanID]
if !ok || bid.CommitHeight > height {
chanCommitHeights[bid.ChanID] = bid.CommitHeight
}
}
// Take the heights commit height found in the session's acked
// updates.
for _, bid := range s.AckedUpdates {
height, ok := chanCommitHeights[bid.ChanID]
if !ok || bid.CommitHeight > height {
chanCommitHeights[bid.ChanID] = bid.CommitHeight
}
}
}
c.chanCommitHeights = chanCommitHeights
}
// Start initializes the watchtower client by loading or negotiating an active
// session and then begins processing backup tasks from the request pipeline.
func (c *TowerClient) Start() error {
var err error
c.started.Do(func() {
c.log.Infof("Starting watchtower client")
// First, restart a session queue for any sessions that have
// committed but unacked state updates. This ensures that these
// sessions will be able to flush the committed updates after a
// restart.
for _, session := range c.candidateSessions {
if len(session.CommittedUpdates) > 0 {
c.log.Infof("Starting session=%s to process "+
"%d committed backups", session.ID,
len(session.CommittedUpdates))
c.initActiveQueue(session)
}
}
// Now start the session negotiator, which will allow us to
// request new session as soon as the backupDispatcher starts
// up.
err = c.negotiator.Start()
if err != nil {
return
}
// Start the task pipeline to which new backup tasks will be
// submitted from active links.
c.pipeline.Start()
c.wg.Add(1)
go c.backupDispatcher()
c.log.Infof("Watchtower client started successfully")
})
return err
}
// Stop idempotently initiates a graceful shutdown of the watchtower client.
func (c *TowerClient) Stop() error {
c.stopped.Do(func() {
c.log.Debugf("Stopping watchtower client")
// 1. To ensure we don't hang forever on shutdown due to
// unintended failures, we'll delay a call to force quit the
// pipeline if a ForceQuitDelay is specified. This will have no
// effect if the pipeline shuts down cleanly before the delay
// fires.
//
// For full safety, this can be set to 0 and wait out
// indefinitely. However for mobile clients which may have a
// limited amount of time to exit before the background process
// is killed, this offers a way to ensure the process
// terminates.
if c.cfg.ForceQuitDelay > 0 {
time.AfterFunc(c.cfg.ForceQuitDelay, c.ForceQuit)
}
// 2. Shutdown the backup queue, which will prevent any further
// updates from being accepted. In practice, the links should be
// shutdown before the client has been stopped, so all updates
// would have been added prior.
c.pipeline.Stop()
// 3. Once the backup queue has shutdown, wait for the main
// dispatcher to exit. The backup queue will signal it's
// completion to the dispatcher, which releases the wait group
// after all tasks have been assigned to session queues.
c.wg.Wait()
// 4. Since all valid tasks have been assigned to session
// queues, we no longer need to negotiate sessions.
c.negotiator.Stop()
c.log.Debugf("Waiting for active session queues to finish "+
"draining, stats: %s", c.stats)
// 5. Shutdown all active session queues in parallel. These will
// exit once all updates have been acked by the watchtower.
c.activeSessions.ApplyAndWait(func(s *sessionQueue) func() {
return s.Stop
})
// Skip log if force quitting.
select {
case <-c.forceQuit:
return
default:
}
c.log.Debugf("Client successfully stopped, stats: %s", c.stats)
})
return nil
}
// ForceQuit idempotently initiates an unclean shutdown of the watchtower
// client. This should only be executed if Stop is unable to exit cleanly.
func (c *TowerClient) ForceQuit() {
c.forced.Do(func() {
c.log.Infof("Force quitting watchtower client")
// 1. Shutdown the backup queue, which will prevent any further
// updates from being accepted. In practice, the links should be
// shutdown before the client has been stopped, so all updates
// would have been added prior.
c.pipeline.ForceQuit()
// 2. Once the backup queue has shutdown, wait for the main
// dispatcher to exit. The backup queue will signal it's
// completion to the dispatcher, which releases the wait group
// after all tasks have been assigned to session queues.
close(c.forceQuit)
c.wg.Wait()
// 3. Since all valid tasks have been assigned to session
// queues, we no longer need to negotiate sessions.
c.negotiator.Stop()
// 4. Force quit all active session queues in parallel. These
// will exit once all updates have been acked by the watchtower.
c.activeSessions.ApplyAndWait(func(s *sessionQueue) func() {
return s.ForceQuit
})
c.log.Infof("Watchtower client unclean shutdown complete, "+
"stats: %s", c.stats)
})
}
// RegisterChannel persistently initializes any channel-dependent parameters
// within the client. This should be called during link startup to ensure that
// the client is able to support the link during operation.
func (c *TowerClient) RegisterChannel(chanID lnwire.ChannelID) error {
c.backupMu.Lock()
defer c.backupMu.Unlock()
// If a pkscript for this channel already exists, the channel has been
// previously registered.
if _, ok := c.summaries[chanID]; ok {
return nil
}
// Otherwise, generate a new sweep pkscript used to sweep funds for this
// channel.
pkScript, err := c.cfg.NewAddress()
if err != nil {
return err
}
// Persist the sweep pkscript so that restarts will not introduce
// address inflation when the channel is reregistered after a restart.
err = c.cfg.DB.RegisterChannel(chanID, pkScript)
if err != nil {
return err
}
// Finally, cache the pkscript in our in-memory cache to avoid db
// lookups for the remainder of the daemon's execution.
c.summaries[chanID] = wtdb.ClientChanSummary{
SweepPkScript: pkScript,
}
return nil
}
// BackupState initiates a request to back up a particular revoked state. If the
// method returns nil, the backup is guaranteed to be successful unless the:
// - client is force quit,
// - justice transaction would create dust outputs when trying to abide by the
// negotiated policy, or
// - breached outputs contain too little value to sweep at the target sweep fee
// rate.
func (c *TowerClient) BackupState(chanID *lnwire.ChannelID,
breachInfo *lnwallet.BreachRetribution,
chanType channeldb.ChannelType) error {
// Retrieve the cached sweep pkscript used for this channel.
c.backupMu.Lock()
summary, ok := c.summaries[*chanID]
if !ok {
c.backupMu.Unlock()
return ErrUnregisteredChannel
}
// Ignore backups that have already been presented to the client.
height, ok := c.chanCommitHeights[*chanID]
if ok && breachInfo.RevokedStateNum <= height {
c.backupMu.Unlock()
c.log.Debugf("Ignoring duplicate backup for chanid=%v at height=%d",
chanID, breachInfo.RevokedStateNum)
return nil
}
// This backup has a higher commit height than any known backup for this
// channel. We'll update our tip so that we won't accept it again if the
// link flaps.
c.chanCommitHeights[*chanID] = breachInfo.RevokedStateNum
c.backupMu.Unlock()
task := newBackupTask(
chanID, breachInfo, summary.SweepPkScript, chanType,
)
return c.pipeline.QueueBackupTask(task)
}
// nextSessionQueue attempts to fetch an active session from our set of
// candidate sessions. Candidate sessions with a differing policy from the
// active client's advertised policy will be ignored, but may be resumed if the
// client is restarted with a matching policy. If no candidates were found, nil
// is returned to signal that we need to request a new policy.
func (c *TowerClient) nextSessionQueue() *sessionQueue {
// Select any candidate session at random, and remove it from the set of
// candidate sessions.
var candidateSession *wtdb.ClientSession
for id, sessionInfo := range c.candidateSessions {
delete(c.candidateSessions, id)
// Skip any sessions with policies that don't match the current
// TxPolicy, as they would result in different justice
// transactions from what is requested. These can be used again
// if the client changes their configuration and restarting.
if sessionInfo.Policy.TxPolicy != c.cfg.Policy.TxPolicy {
continue
}
candidateSession = sessionInfo
break
}
// If none of the sessions could be used or none were found, we'll
// return nil to signal that we need another session to be negotiated.
if candidateSession == nil {
return nil
}
// Initialize the session queue and spin it up so it can begin handling
// updates. If the queue was already made active on startup, this will
// simply return the existing session queue from the set.
return c.getOrInitActiveQueue(candidateSession)
}
// backupDispatcher processes events coming from the taskPipeline and is
// responsible for detecting when the client needs to renegotiate a session to
// fulfill continuing demand. The event loop exits after all tasks have been
// received from the upstream taskPipeline, or the taskPipeline is force quit.
//
// NOTE: This method MUST be run as a goroutine.
func (c *TowerClient) backupDispatcher() {
defer c.wg.Done()
c.log.Tracef("Starting backup dispatcher")
defer c.log.Tracef("Stopping backup dispatcher")
for {
switch {
// No active session queue and no additional sessions.
case c.sessionQueue == nil && len(c.candidateSessions) == 0:
c.log.Infof("Requesting new session.")
// Immediately request a new session.
c.negotiator.RequestSession()
// Wait until we receive the newly negotiated session.
// All backups sent in the meantime are queued in the
// revoke queue, as we cannot process them.
awaitSession:
select {
case session := <-c.negotiator.NewSessions():
c.log.Infof("Acquired new session with id=%s",
session.ID)
c.candidateSessions[session.ID] = session
c.stats.sessionAcquired()
// We'll continue to choose the newly negotiated
// session as our active session queue.
continue
case <-c.statTicker.C:
c.log.Infof("Client stats: %s", c.stats)
// A new tower has been requested to be added. We'll
// update our persisted and in-memory state and consider
// its corresponding sessions, if any, as new
// candidates.
case msg := <-c.newTowers:
msg.errChan <- c.handleNewTower(msg)
// A tower has been requested to be removed. We'll
// immediately return an error as we want to avoid the
// possibility of a new session being negotiated with
// this request's tower.
case msg := <-c.staleTowers:
msg.errChan <- errors.New("removing towers " +
"is disallowed while a new session " +
"negotiation is in progress")
case <-c.forceQuit:
return
}
// Instead of looping, we'll jump back into the select
// case and await the delivery of the session to prevent
// us from re-requesting additional sessions.
goto awaitSession
// No active session queue but have additional sessions.
case c.sessionQueue == nil && len(c.candidateSessions) > 0:
// We've exhausted the prior session, we'll pop another
// from the remaining sessions and continue processing
// backup tasks.
c.sessionQueue = c.nextSessionQueue()
if c.sessionQueue != nil {
c.log.Debugf("Loaded next candidate session "+
"queue id=%s", c.sessionQueue.ID())
}
// Have active session queue, process backups.
case c.sessionQueue != nil:
if c.prevTask != nil {
c.processTask(c.prevTask)
// Continue to ensure the sessionQueue is
// properly initialized before attempting to
// process more tasks from the pipeline.
continue
}
// Normal operation where new tasks are read from the
// pipeline.
select {
// If any sessions are negotiated while we have an
// active session queue, queue them for future use.
// This shouldn't happen with the current design, so
// it doesn't hurt to select here just in case. In the
// future, we will likely allow more asynchrony so that
// we can request new sessions before the session is
// fully empty, which this case would handle.
case session := <-c.negotiator.NewSessions():
c.log.Warnf("Acquired new session with id=%s "+
"while processing tasks", session.ID)
c.candidateSessions[session.ID] = session
c.stats.sessionAcquired()
case <-c.statTicker.C:
c.log.Infof("Client stats: %s", c.stats)
// Process each backup task serially from the queue of
// revoked states.
case task, ok := <-c.pipeline.NewBackupTasks():
// All backups in the pipeline have been
// processed, it is now safe to exit.
if !ok {
return
}
c.log.Debugf("Processing %v", task.id)
c.stats.taskReceived()
c.processTask(task)
// A new tower has been requested to be added. We'll
// update our persisted and in-memory state and consider
// its corresponding sessions, if any, as new
// candidates.
case msg := <-c.newTowers:
msg.errChan <- c.handleNewTower(msg)
// A tower has been removed, so we'll remove certain
// information that's persisted and also in our
// in-memory state depending on the request, and set any
// of its corresponding candidate sessions as inactive.
case msg := <-c.staleTowers:
msg.errChan <- c.handleStaleTower(msg)
}
}
}
}
// processTask attempts to schedule the given backupTask on the active
// sessionQueue. The task will either be accepted or rejected, afterwhich the
// appropriate modifications to the client's state machine will be made. After
// every invocation of processTask, the caller should ensure that the
// sessionQueue hasn't been exhausted before proceeding to the next task. Tasks
// that are rejected because the active sessionQueue is full will be cached as
// the prevTask, and should be reprocessed after obtaining a new sessionQueue.
func (c *TowerClient) processTask(task *backupTask) {
status, accepted := c.sessionQueue.AcceptTask(task)
if accepted {
c.taskAccepted(task, status)
} else {
c.taskRejected(task, status)
}
}
// taskAccepted processes the acceptance of a task by a sessionQueue depending
// on the state the sessionQueue is in *after* the task is added. The client's
// prevTask is always removed as a result of this call. The client's
// sessionQueue will be removed if accepting the task left the sessionQueue in
// an exhausted state.
func (c *TowerClient) taskAccepted(task *backupTask, newStatus reserveStatus) {
c.log.Infof("Queued %v successfully for session %v",
task.id, c.sessionQueue.ID())
c.stats.taskAccepted()
// If this task was accepted, we discard anything held in the prevTask.
// Either it was nil before, or is the task which was just accepted.
c.prevTask = nil
switch newStatus {
// The sessionQueue still has capacity after accepting this task.
case reserveAvailable:
// The sessionQueue is full after accepting this task, so we will need
// to request a new one before proceeding.
case reserveExhausted:
c.stats.sessionExhausted()
c.log.Debugf("Session %s exhausted", c.sessionQueue.ID())
// This task left the session exhausted, set it to nil and
// proceed to the next loop so we can consume another
// pre-negotiated session or request another.
c.sessionQueue = nil
}
}
// taskRejected process the rejection of a task by a sessionQueue depending on
// the state the was in *before* the task was rejected. The client's prevTask
// will cache the task if the sessionQueue was exhausted before hand, and nil
// the sessionQueue to find a new session. If the sessionQueue was not
// exhausted, the client marks the task as ineligible, as this implies we
// couldn't construct a valid justice transaction given the session's policy.
func (c *TowerClient) taskRejected(task *backupTask, curStatus reserveStatus) {
switch curStatus {
// The sessionQueue has available capacity but the task was rejected,
// this indicates that the task was ineligible for backup.
case reserveAvailable:
c.stats.taskIneligible()
c.log.Infof("Ignoring ineligible %v", task.id)
err := c.cfg.DB.MarkBackupIneligible(
task.id.ChanID, task.id.CommitHeight,
)
if err != nil {
c.log.Errorf("Unable to mark %v ineligible: %v",
task.id, err)
// It is safe to not handle this error, even if we could
// not persist the result. At worst, this task may be
// reprocessed on a subsequent start up, and will either
// succeed do a change in session parameters or fail in
// the same manner.
}
// If this task was rejected *and* the session had available
// capacity, we discard anything held in the prevTask. Either it
// was nil before, or is the task which was just rejected.
c.prevTask = nil
// The sessionQueue rejected the task because it is full, we will stash
// this task and try to add it to the next available sessionQueue.
case reserveExhausted:
c.stats.sessionExhausted()
c.log.Debugf("Session %v exhausted, %v queued for next session",
c.sessionQueue.ID(), task.id)
// Cache the task that we pulled off, so that we can process it
// once a new session queue is available.
c.sessionQueue = nil
c.prevTask = task
}
}
// dial connects the peer at addr using privKey as our secret key for the
// connection. The connection will use the configured Net's resolver to resolve
// the address for either Tor or clear net connections.
func (c *TowerClient) dial(localKey keychain.SingleKeyECDH,
addr *lnwire.NetAddress) (wtserver.Peer, error) {
return c.cfg.AuthDial(localKey, addr, c.cfg.Dial)
}
// readMessage receives and parses the next message from the given Peer. An
// error is returned if a message is not received before the server's read
// timeout, the read off the wire failed, or the message could not be
// deserialized.
func (c *TowerClient) readMessage(peer wtserver.Peer) (wtwire.Message, error) {
// Set a read timeout to ensure we drop the connection if nothing is
// received in a timely manner.
err := peer.SetReadDeadline(time.Now().Add(c.cfg.ReadTimeout))
if err != nil {
err = fmt.Errorf("unable to set read deadline: %v", err)
c.log.Errorf("Unable to read msg: %v", err)
return nil, err
}
// Pull the next message off the wire,
rawMsg, err := peer.ReadNextMessage()
if err != nil {
err = fmt.Errorf("unable to read message: %v", err)
c.log.Errorf("Unable to read msg: %v", err)
return nil, err
}
// Parse the received message according to the watchtower wire
// specification.
msgReader := bytes.NewReader(rawMsg)
msg, err := wtwire.ReadMessage(msgReader, 0)
if err != nil {
err = fmt.Errorf("unable to parse message: %v", err)
c.log.Errorf("Unable to read msg: %v", err)
return nil, err
}
c.logMessage(peer, msg, true)
return msg, nil
}
// sendMessage sends a watchtower wire message to the target peer.
func (c *TowerClient) sendMessage(peer wtserver.Peer, msg wtwire.Message) error {
// Encode the next wire message into the buffer.
// TODO(conner): use buffer pool
var b bytes.Buffer
_, err := wtwire.WriteMessage(&b, msg, 0)
if err != nil {
err = fmt.Errorf("Unable to encode msg: %v", err)
c.log.Errorf("Unable to send msg: %v", err)
return err
}
// Set the write deadline for the connection, ensuring we drop the
// connection if nothing is sent in a timely manner.
err = peer.SetWriteDeadline(time.Now().Add(c.cfg.WriteTimeout))
if err != nil {
err = fmt.Errorf("unable to set write deadline: %v", err)
c.log.Errorf("Unable to send msg: %v", err)
return err
}
c.logMessage(peer, msg, false)
// Write out the full message to the remote peer.
_, err = peer.Write(b.Bytes())
if err != nil {
c.log.Errorf("Unable to send msg: %v", err)
}
return err
}
// newSessionQueue creates a sessionQueue from a ClientSession loaded from the
// database and supplying it with the resources needed by the client.
func (c *TowerClient) newSessionQueue(s *wtdb.ClientSession) *sessionQueue {
return newSessionQueue(&sessionQueueConfig{
ClientSession: s,
ChainHash: c.cfg.ChainHash,
Dial: c.dial,
ReadMessage: c.readMessage,
SendMessage: c.sendMessage,
Signer: c.cfg.Signer,
DB: c.cfg.DB,
MinBackoff: c.cfg.MinBackoff,
MaxBackoff: c.cfg.MaxBackoff,
Log: c.log,
})
}
// getOrInitActiveQueue checks the activeSessions set for a sessionQueue for the
// passed ClientSession. If it exists, the active sessionQueue is returned.
// Otherwise a new sessionQueue is initialized and added to the set.
func (c *TowerClient) getOrInitActiveQueue(s *wtdb.ClientSession) *sessionQueue {
if sq, ok := c.activeSessions[s.ID]; ok {
return sq
}
return c.initActiveQueue(s)
}
// initActiveQueue creates a new sessionQueue from the passed ClientSession,
// adds the sessionQueue to the activeSessions set, and starts the sessionQueue
// so that it can deliver any committed updates or begin accepting newly
// assigned tasks.
func (c *TowerClient) initActiveQueue(s *wtdb.ClientSession) *sessionQueue {
// Initialize the session queue, providing it with all of the resources
// it requires from the client instance.
sq := c.newSessionQueue(s)
// Add the session queue as an active session so that we remember to
// stop it on shutdown.
c.activeSessions.Add(sq)
// Start the queue so that it can be active in processing newly assigned
// tasks or to upload previously committed updates.
sq.Start()
return sq
}
// AddTower adds a new watchtower reachable at the given address and considers
// it for new sessions. If the watchtower already exists, then any new addresses
// included will be considered when dialing it for session negotiations and
// backups.
func (c *TowerClient) AddTower(addr *lnwire.NetAddress) error {
errChan := make(chan error, 1)
select {
case c.newTowers <- &newTowerMsg{
addr: addr,
errChan: errChan,
}:
case <-c.pipeline.quit:
return ErrClientExiting
case <-c.pipeline.forceQuit:
return ErrClientExiting
}
select {
case err := <-errChan:
return err
case <-c.pipeline.quit:
return ErrClientExiting
case <-c.pipeline.forceQuit:
return ErrClientExiting
}
}
// handleNewTower handles a request for a new tower to be added. If the tower
// already exists, then its corresponding sessions, if any, will be set
// considered as candidates.
func (c *TowerClient) handleNewTower(msg *newTowerMsg) error {
// We'll start by updating our persisted state, followed by our
// in-memory state, with the new tower. This might not actually be a new
// tower, but it might include a new address at which it can be reached.
tower, err := c.cfg.DB.CreateTower(msg.addr)
if err != nil {
return err
}
c.candidateTowers.AddCandidate(tower)
// Include all of its corresponding sessions to our set of candidates.
isAnchorClient := c.cfg.Policy.IsAnchorChannel()
activeSessionFilter := genActiveSessionFilter(isAnchorClient)
sessions, err := getClientSessions(
c.cfg.DB, c.cfg.SecretKeyRing, &tower.ID, activeSessionFilter,
)
if err != nil {
return fmt.Errorf("unable to determine sessions for tower %x: "+
"%v", tower.IdentityKey.SerializeCompressed(), err)
}
for id, session := range sessions {
c.candidateSessions[id] = session
}
return nil
}
// RemoveTower removes a watchtower from being considered for future session
// negotiations and from being used for any subsequent backups until it's added
// again. If an address is provided, then this call only serves as a way of
// removing the address from the watchtower instead.
func (c *TowerClient) RemoveTower(pubKey *btcec.PublicKey, addr net.Addr) error {
errChan := make(chan error, 1)
select {
case c.staleTowers <- &staleTowerMsg{
pubKey: pubKey,
addr: addr,
errChan: errChan,
}:
case <-c.pipeline.quit:
return ErrClientExiting
case <-c.pipeline.forceQuit:
return ErrClientExiting
}
select {
case err := <-errChan:
return err
case <-c.pipeline.quit:
return ErrClientExiting
case <-c.pipeline.forceQuit:
return ErrClientExiting
}
}
// handleNewTower handles a request for an existing tower to be removed. If none
// of the tower's sessions have pending updates, then they will become inactive
// and removed as candidates. If the active session queue corresponds to any of
// these sessions, a new one will be negotiated.
func (c *TowerClient) handleStaleTower(msg *staleTowerMsg) error {
// We'll load the tower before potentially removing it in order to
// retrieve its ID within the database.
tower, err := c.cfg.DB.LoadTower(msg.pubKey)
if err != nil {
return err
}
// We'll update our persisted state, followed by our in-memory state,
// with the stale tower.
if err := c.cfg.DB.RemoveTower(msg.pubKey, msg.addr); err != nil {
return err
}
err = c.candidateTowers.RemoveCandidate(tower.ID, msg.addr)
if err != nil {
return err
}
// If an address was provided, then we're only meant to remove the
// address from the tower, so there's nothing left for us to do.
if msg.addr != nil {
return nil
}
// Otherwise, the tower should no longer be used for future session
// negotiations and backups.
pubKey := msg.pubKey.SerializeCompressed()
sessions, err := c.cfg.DB.ListClientSessions(&tower.ID)
if err != nil {
return fmt.Errorf("unable to retrieve sessions for tower %x: "+
"%v", pubKey, err)
}
for sessionID := range sessions {
delete(c.candidateSessions, sessionID)
}
// If our active session queue corresponds to the stale tower, we'll
// proceed to negotiate a new one.
if c.sessionQueue != nil {
activeTower := c.sessionQueue.towerAddr.IdentityKey.SerializeCompressed()
if bytes.Equal(pubKey, activeTower) {
c.sessionQueue = nil
}
}
return nil
}
// RegisteredTowers retrieves the list of watchtowers registered with the
// client.
func (c *TowerClient) RegisteredTowers() ([]*RegisteredTower, error) {
// Retrieve all of our towers along with all of our sessions.
towers, err := c.cfg.DB.ListTowers()
if err != nil {
return nil, err
}
clientSessions, err := c.cfg.DB.ListClientSessions(nil)
if err != nil {
return nil, err
}
// Construct a lookup map that coalesces all of the sessions for a
// specific watchtower.
towerSessions := make(
map[wtdb.TowerID]map[wtdb.SessionID]*wtdb.ClientSession,
)
for id, s := range clientSessions {
sessions, ok := towerSessions[s.TowerID]
if !ok {
sessions = make(map[wtdb.SessionID]*wtdb.ClientSession)
towerSessions[s.TowerID] = sessions
}
sessions[id] = s
}
registeredTowers := make([]*RegisteredTower, 0, len(towerSessions))
for _, tower := range towers {
isActive := c.candidateTowers.IsActive(tower.ID)
registeredTowers = append(registeredTowers, &RegisteredTower{
Tower: tower,
Sessions: towerSessions[tower.ID],
ActiveSessionCandidate: isActive,
})
}
return registeredTowers, nil
}
// LookupTower retrieves a registered watchtower through its public key.
func (c *TowerClient) LookupTower(pubKey *btcec.PublicKey) (*RegisteredTower, error) {
tower, err := c.cfg.DB.LoadTower(pubKey)
if err != nil {
return nil, err
}
towerSessions, err := c.cfg.DB.ListClientSessions(&tower.ID)
if err != nil {
return nil, err
}
return &RegisteredTower{
Tower: tower,
Sessions: towerSessions,
ActiveSessionCandidate: c.candidateTowers.IsActive(tower.ID),
}, nil
}
// Stats returns the in-memory statistics of the client since startup.
func (c *TowerClient) Stats() ClientStats {
return c.stats.Copy()
}
// Policy returns the active client policy configuration.
func (c *TowerClient) Policy() wtpolicy.Policy {
return c.cfg.Policy
}
// logMessage writes information about a message received from a remote peer,
// using directional prepositions to signal whether the message was sent or
// received.
func (c *TowerClient) logMessage(
peer wtserver.Peer, msg wtwire.Message, read bool) {
var action = "Received"
var preposition = "from"
if !read {
action = "Sending"
preposition = "to"
}
summary := wtwire.MessageSummary(msg)
if len(summary) > 0 {
summary = "(" + summary + ")"
}
c.log.Debugf("%s %s%v %s %x@%s", action, msg.MsgType(), summary,
preposition, peer.RemotePub().SerializeCompressed(),
peer.RemoteAddr())
}