lnd/routing/payment_session.go
yyforyongyu f31001e103
routing: make shardHandler aware of payment session
This commit adds payment session to shardHandler to enable private edge
policies being updated in shardHandler. The relevant interface and mock
are updated. From now on, upon seeing a ChannelUpdate message,
shardHandler will first try to find the target policy in additionalEdges
and update it. If nothing found, it will then check the database for
edge policy to update.
2021-06-23 18:13:04 +08:00

450 lines
14 KiB
Go

package routing
import (
"fmt"
"github.com/btcsuite/btcd/btcec"
"github.com/btcsuite/btclog"
"github.com/davecgh/go-spew/spew"
"github.com/lightningnetwork/lnd/build"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/lnwire"
"github.com/lightningnetwork/lnd/routing/route"
)
// BlockPadding is used to increment the finalCltvDelta value for the last hop
// to prevent an HTLC being failed if some blocks are mined while it's in-flight.
const BlockPadding uint16 = 3
// ValidateCLTVLimit is a helper function that validates that the cltv limit is
// greater than the final cltv delta parameter, optionally including the
// BlockPadding in this calculation.
func ValidateCLTVLimit(limit uint32, delta uint16, includePad bool) error {
if includePad {
delta += BlockPadding
}
if limit <= uint32(delta) {
return fmt.Errorf("cltv limit %v should be greater than %v",
limit, delta)
}
return nil
}
// noRouteError encodes a non-critical error encountered during path finding.
type noRouteError uint8
const (
// errNoTlvPayload is returned when the destination hop does not support
// a tlv payload.
errNoTlvPayload noRouteError = iota
// errNoPaymentAddr is returned when the destination hop does not
// support payment addresses.
errNoPaymentAddr
// errNoPathFound is returned when a path to the target destination does
// not exist in the graph.
errNoPathFound
// errInsufficientLocalBalance is returned when none of the local
// channels have enough balance for the payment.
errInsufficientBalance
// errEmptyPaySession is returned when the empty payment session is
// queried for a route.
errEmptyPaySession
// errUnknownRequiredFeature is returned when the destination node
// requires an unknown feature.
errUnknownRequiredFeature
// errMissingDependentFeature is returned when the destination node
// misses a feature that a feature that we require depends on.
errMissingDependentFeature
)
var (
// DefaultShardMinAmt is the default amount beyond which we won't try to
// further split the payment if no route is found. It is the minimum
// amount that we use as the shard size when splitting.
DefaultShardMinAmt = lnwire.NewMSatFromSatoshis(10000)
)
// Error returns the string representation of the noRouteError
func (e noRouteError) Error() string {
switch e {
case errNoTlvPayload:
return "destination hop doesn't understand new TLV payloads"
case errNoPaymentAddr:
return "destination hop doesn't understand payment addresses"
case errNoPathFound:
return "unable to find a path to destination"
case errEmptyPaySession:
return "empty payment session"
case errInsufficientBalance:
return "insufficient local balance"
case errUnknownRequiredFeature:
return "unknown required feature"
case errMissingDependentFeature:
return "missing dependent feature"
default:
return "unknown no-route error"
}
}
// FailureReason converts a path finding error into a payment-level failure.
func (e noRouteError) FailureReason() channeldb.FailureReason {
switch e {
case
errNoTlvPayload,
errNoPaymentAddr,
errNoPathFound,
errEmptyPaySession,
errUnknownRequiredFeature,
errMissingDependentFeature:
return channeldb.FailureReasonNoRoute
case errInsufficientBalance:
return channeldb.FailureReasonInsufficientBalance
default:
return channeldb.FailureReasonError
}
}
// PaymentSession is used during SendPayment attempts to provide routes to
// attempt. It also defines methods to give the PaymentSession additional
// information learned during the previous attempts.
type PaymentSession interface {
// RequestRoute returns the next route to attempt for routing the
// specified HTLC payment to the target node. The returned route should
// carry at most maxAmt to the target node, and pay at most feeLimit in
// fees. It can carry less if the payment is MPP. The activeShards
// argument should be set to instruct the payment session about the
// number of in flight HTLCS for the payment, such that it can choose
// splitting strategy accordingly.
//
// A noRouteError is returned if a non-critical error is encountered
// during path finding.
RequestRoute(maxAmt, feeLimit lnwire.MilliSatoshi,
activeShards, height uint32) (*route.Route, error)
// UpdateAdditionalEdge takes an additional channel edge policy
// (private channels) and applies the update from the message. Returns
// a boolean to indicate whether the update has been applied without
// error.
UpdateAdditionalEdge(msg *lnwire.ChannelUpdate, pubKey *btcec.PublicKey,
policy *channeldb.ChannelEdgePolicy) bool
// GetAdditionalEdgePolicy uses the public key and channel ID to query
// the ephemeral channel edge policy for additional edges. Returns a nil
// if nothing found.
GetAdditionalEdgePolicy(pubKey *btcec.PublicKey,
channelID uint64) *channeldb.ChannelEdgePolicy
}
// paymentSession is used during an HTLC routings session to prune the local
// chain view in response to failures, and also report those failures back to
// MissionControl. The snapshot copied for this session will only ever grow,
// and will now be pruned after a decay like the main view within mission
// control. We do this as we want to avoid the case where we continually try a
// bad edge or route multiple times in a session. This can lead to an infinite
// loop if payment attempts take long enough. An additional set of edges can
// also be provided to assist in reaching the payment's destination.
type paymentSession struct {
additionalEdges map[route.Vertex][]*channeldb.ChannelEdgePolicy
getBandwidthHints func() (map[uint64]lnwire.MilliSatoshi, error)
payment *LightningPayment
empty bool
pathFinder pathFinder
getRoutingGraph func() (routingGraph, func(), error)
// pathFindingConfig defines global parameters that control the
// trade-off in path finding between fees and probabiity.
pathFindingConfig PathFindingConfig
missionControl MissionController
// minShardAmt is the amount beyond which we won't try to further split
// the payment if no route is found. If the maximum number of htlcs
// specified in the payment is one, under no circumstances splitting
// will happen and this value remains unused.
minShardAmt lnwire.MilliSatoshi
// log is a payment session-specific logger.
log btclog.Logger
}
// newPaymentSession instantiates a new payment session.
func newPaymentSession(p *LightningPayment,
getBandwidthHints func() (map[uint64]lnwire.MilliSatoshi, error),
getRoutingGraph func() (routingGraph, func(), error),
missionControl MissionController, pathFindingConfig PathFindingConfig) (
*paymentSession, error) {
edges, err := RouteHintsToEdges(p.RouteHints, p.Target)
if err != nil {
return nil, err
}
logPrefix := fmt.Sprintf("PaymentSession(%x):", p.Identifier())
return &paymentSession{
additionalEdges: edges,
getBandwidthHints: getBandwidthHints,
payment: p,
pathFinder: findPath,
getRoutingGraph: getRoutingGraph,
pathFindingConfig: pathFindingConfig,
missionControl: missionControl,
minShardAmt: DefaultShardMinAmt,
log: build.NewPrefixLog(logPrefix, log),
}, nil
}
// RequestRoute returns a route which is likely to be capable for successfully
// routing the specified HTLC payment to the target node. Initially the first
// set of paths returned from this method may encounter routing failure along
// the way, however as more payments are sent, mission control will start to
// build an up to date view of the network itself. With each payment a new area
// will be explored, which feeds into the recommendations made for routing.
//
// NOTE: This function is safe for concurrent access.
// NOTE: Part of the PaymentSession interface.
func (p *paymentSession) RequestRoute(maxAmt, feeLimit lnwire.MilliSatoshi,
activeShards, height uint32) (*route.Route, error) {
if p.empty {
return nil, errEmptyPaySession
}
// Add BlockPadding to the finalCltvDelta so that the receiving node
// does not reject the HTLC if some blocks are mined while it's in-flight.
finalCltvDelta := p.payment.FinalCLTVDelta
finalCltvDelta += BlockPadding
// We need to subtract the final delta before passing it into path
// finding. The optimal path is independent of the final cltv delta and
// the path finding algorithm is unaware of this value.
cltvLimit := p.payment.CltvLimit - uint32(finalCltvDelta)
// TODO(roasbeef): sync logic amongst dist sys
// Taking into account this prune view, we'll attempt to locate a path
// to our destination, respecting the recommendations from
// MissionControl.
restrictions := &RestrictParams{
ProbabilitySource: p.missionControl.GetProbability,
FeeLimit: feeLimit,
OutgoingChannelIDs: p.payment.OutgoingChannelIDs,
LastHop: p.payment.LastHop,
CltvLimit: cltvLimit,
DestCustomRecords: p.payment.DestCustomRecords,
DestFeatures: p.payment.DestFeatures,
PaymentAddr: p.payment.PaymentAddr,
}
finalHtlcExpiry := int32(height) + int32(finalCltvDelta)
// Before we enter the loop below, we'll make sure to respect the max
// payment shard size (if it's set), which is effectively our
// client-side MTU that we'll attempt to respect at all times.
maxShardActive := p.payment.MaxShardAmt != nil
if maxShardActive && maxAmt > *p.payment.MaxShardAmt {
p.log.Debug("Clamping payment attempt from %v to %v due to "+
"max shard size of %v", maxAmt,
*p.payment.MaxShardAmt, maxAmt)
maxAmt = *p.payment.MaxShardAmt
}
for {
// We'll also obtain a set of bandwidthHints from the lower
// layer for each of our outbound channels. This will allow the
// path finding to skip any links that aren't active or just
// don't have enough bandwidth to carry the payment. New
// bandwidth hints are queried for every new path finding
// attempt, because concurrent payments may change balances.
bandwidthHints, err := p.getBandwidthHints()
if err != nil {
return nil, err
}
p.log.Debugf("pathfinding for amt=%v", maxAmt)
// Get a routing graph.
routingGraph, cleanup, err := p.getRoutingGraph()
if err != nil {
return nil, err
}
sourceVertex := routingGraph.sourceNode()
// Find a route for the current amount.
path, err := p.pathFinder(
&graphParams{
additionalEdges: p.additionalEdges,
bandwidthHints: bandwidthHints,
graph: routingGraph,
},
restrictions, &p.pathFindingConfig,
sourceVertex, p.payment.Target,
maxAmt, finalHtlcExpiry,
)
// Close routing graph.
cleanup()
switch {
case err == errNoPathFound:
// Don't split if this is a legacy payment without mpp
// record.
if p.payment.PaymentAddr == nil {
p.log.Debugf("not splitting because payment " +
"address is unspecified")
return nil, errNoPathFound
}
if p.payment.DestFeatures == nil {
p.log.Debug("Not splitting because " +
"destination DestFeatures is nil")
return nil, errNoPathFound
}
destFeatures := p.payment.DestFeatures
if !destFeatures.HasFeature(lnwire.MPPOptional) &&
!destFeatures.HasFeature(lnwire.AMPOptional) {
p.log.Debug("not splitting because " +
"destination doesn't declare MPP or AMP")
return nil, errNoPathFound
}
// No splitting if this is the last shard.
isLastShard := activeShards+1 >= p.payment.MaxParts
if isLastShard {
p.log.Debugf("not splitting because shard "+
"limit %v has been reached",
p.payment.MaxParts)
return nil, errNoPathFound
}
// This is where the magic happens. If we can't find a
// route, try it for half the amount.
maxAmt /= 2
// Put a lower bound on the minimum shard size.
if maxAmt < p.minShardAmt {
p.log.Debugf("not splitting because minimum "+
"shard amount %v has been reached",
p.minShardAmt)
return nil, errNoPathFound
}
// Go pathfinding.
continue
// If there isn't enough local bandwidth, there is no point in
// splitting. It won't be possible to create a complete set in
// any case, but the sent out partial payments would be held by
// the receiver until the mpp timeout.
case err == errInsufficientBalance:
p.log.Debug("not splitting because local balance " +
"is insufficient")
return nil, err
case err != nil:
return nil, err
}
// With the next candidate path found, we'll attempt to turn
// this into a route by applying the time-lock and fee
// requirements.
route, err := newRoute(
sourceVertex, path, height,
finalHopParams{
amt: maxAmt,
totalAmt: p.payment.Amount,
cltvDelta: finalCltvDelta,
records: p.payment.DestCustomRecords,
paymentAddr: p.payment.PaymentAddr,
},
)
if err != nil {
return nil, err
}
return route, err
}
}
// UpdateAdditionalEdge updates the channel edge policy for a private edge. It
// validates the message signature and checks it's up to date, then applies the
// updates to the supplied policy. It returns a boolean to indicate whether
// there's an error when applying the updates.
func (p *paymentSession) UpdateAdditionalEdge(msg *lnwire.ChannelUpdate,
pubKey *btcec.PublicKey, policy *channeldb.ChannelEdgePolicy) bool {
// Validate the message signature.
if err := VerifyChannelUpdateSignature(msg, pubKey); err != nil {
log.Errorf(
"Unable to validate channel update signature: %v", err,
)
return false
}
// Update channel policy for the additional edge.
policy.TimeLockDelta = msg.TimeLockDelta
policy.FeeBaseMSat = lnwire.MilliSatoshi(msg.BaseFee)
policy.FeeProportionalMillionths = lnwire.MilliSatoshi(msg.FeeRate)
log.Debugf("New private channel update applied: %v",
newLogClosure(func() string { return spew.Sdump(msg) }))
return true
}
// GetAdditionalEdgePolicy uses the public key and channel ID to query the
// ephemeral channel edge policy for additional edges. Returns a nil if nothing
// found.
func (p *paymentSession) GetAdditionalEdgePolicy(pubKey *btcec.PublicKey,
channelID uint64) *channeldb.ChannelEdgePolicy {
target := route.NewVertex(pubKey)
edges, ok := p.additionalEdges[target]
if !ok {
return nil
}
for _, edge := range edges {
if edge.ChannelID != channelID {
continue
}
return edge
}
return nil
}