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e135cf7326
When an undecryptable failure comes back for a payment attempt, we previously only penalized our own outgoing connection. However, any node could have caused this failure. It is therefore better to penalize all node connections along the route. Then at least we know for sure that we will hit the responsible node.
342 lines
11 KiB
Go
342 lines
11 KiB
Go
package routing
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import (
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"github.com/lightningnetwork/lnd/channeldb"
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"github.com/lightningnetwork/lnd/lnwire"
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"github.com/lightningnetwork/lnd/routing/route"
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)
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// Instantiate variables to allow taking a reference from the failure reason.
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var (
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reasonError = channeldb.FailureReasonError
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)
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// interpretedResult contains the result of the interpretation of a payment
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// outcome.
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type interpretedResult struct {
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// nodeFailure points to a node pubkey if all channels of that node are
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// responsible for the result.
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nodeFailure *route.Vertex
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// pairResults contains a map of node pairs that could be responsible
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// for the failure. The map values are the minimum amounts for which a
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// future penalty should be applied.
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pairResults map[DirectedNodePair]lnwire.MilliSatoshi
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// finalFailureReason is set to a non-nil value if it makes no more
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// sense to start another payment attempt. It will contain the reason
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// why.
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finalFailureReason *channeldb.FailureReason
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// policyFailure is set to a node pair if there is a policy failure on
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// that connection. This is used to control the second chance logic for
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// policy failures.
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policyFailure *DirectedNodePair
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}
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// interpretResult interprets a payment outcome and returns an object that
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// contains information required to update mission control.
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func interpretResult(rt *route.Route, failureSrcIdx *int,
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failure lnwire.FailureMessage) *interpretedResult {
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i := &interpretedResult{
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pairResults: make(map[DirectedNodePair]lnwire.MilliSatoshi),
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}
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final, reason := i.processFail(rt, failureSrcIdx, failure)
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if final {
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i.finalFailureReason = &reason
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}
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return i
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}
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// processFail processes a failed payment attempt.
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func (i *interpretedResult) processFail(
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rt *route.Route, errSourceIdx *int,
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failure lnwire.FailureMessage) (bool, channeldb.FailureReason) {
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if errSourceIdx == nil {
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i.processPaymentOutcomeUnknown(rt)
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return false, 0
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}
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var failureVertex route.Vertex
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failureSourceIdxInt := *errSourceIdx
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if failureSourceIdxInt > 0 {
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failureVertex = rt.Hops[failureSourceIdxInt-1].PubKeyBytes
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} else {
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failureVertex = rt.SourcePubKey
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}
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log.Tracef("Node %x (index %v) reported failure when sending htlc",
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failureVertex, errSourceIdx)
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// Always determine chan id ourselves, because a channel update with id
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// may not be available.
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failedPair, failedAmt := getFailedPair(
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rt, failureSourceIdxInt,
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)
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switch failure.(type) {
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// If the end destination didn't know the payment hash or we sent the
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// wrong payment amount to the destination, then we'll terminate
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// immediately.
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case *lnwire.FailIncorrectDetails:
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// TODO(joostjager): Check onionErr.Amount() whether it matches
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// what we expect. (Will it ever not match, because if not
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// final_incorrect_htlc_amount would be returned?)
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return true, channeldb.FailureReasonIncorrectPaymentDetails
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// If we sent the wrong amount to the destination, then we'll exit
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// early.
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case *lnwire.FailIncorrectPaymentAmount:
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return true, channeldb.FailureReasonIncorrectPaymentDetails
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// If the time-lock that was extended to the final node was incorrect,
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// then we can't proceed.
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case *lnwire.FailFinalIncorrectCltvExpiry:
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// TODO(joostjager): Take into account that second last hop may
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// have deliberately handed out an htlc that expires too soon.
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// In that case we should continue routing.
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return true, channeldb.FailureReasonError
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// If we crafted an invalid onion payload for the final node, then we'll
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// exit early.
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case *lnwire.FailFinalIncorrectHtlcAmount:
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// TODO(joostjager): Take into account that second last hop may
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// have deliberately handed out an htlc with a too low value. In
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// that case we should continue routing.
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return true, channeldb.FailureReasonError
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// Similarly, if the HTLC expiry that we extended to the final hop
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// expires too soon, then will fail the payment.
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//
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// TODO(roasbeef): can happen to to race condition, try again with
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// recent block height
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case *lnwire.FailFinalExpiryTooSoon:
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// TODO(joostjager): Take into account that any hop may have
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// delayed. Ideally we should continue routing. Knowing the
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// delaying node at this point would help.
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return true, channeldb.FailureReasonIncorrectPaymentDetails
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// If we erroneously attempted to cross a chain border, then we'll
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// cancel the payment.
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case *lnwire.FailInvalidRealm:
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return true, channeldb.FailureReasonError
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// If we get a notice that the expiry was too soon for an intermediate
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// node, then we'll prune out the node that sent us this error, as it
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// doesn't now what the correct block height is.
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case *lnwire.FailExpiryTooSoon:
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i.nodeFailure = &failureVertex
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return false, 0
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// If we hit an instance of onion payload corruption or an invalid
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// version, then we'll exit early as this shouldn't happen in the
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// typical case.
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//
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// TODO(joostjager): Take into account that the previous hop may have
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// tampered with the onion. Routing should continue using other paths.
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case *lnwire.FailInvalidOnionVersion:
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return true, channeldb.FailureReasonError
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case *lnwire.FailInvalidOnionHmac:
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return true, channeldb.FailureReasonError
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case *lnwire.FailInvalidOnionKey:
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return true, channeldb.FailureReasonError
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// If we get a failure due to violating the minimum amount, we'll apply
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// the new minimum amount and retry routing.
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case *lnwire.FailAmountBelowMinimum:
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i.policyFailure = &failedPair
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i.pairResults[failedPair] = 0
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return false, 0
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// If we get a failure due to a fee, we'll apply the new fee update, and
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// retry our attempt using the newly updated fees.
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case *lnwire.FailFeeInsufficient:
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i.policyFailure = &failedPair
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i.pairResults[failedPair] = 0
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return false, 0
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// If we get the failure for an intermediate node that disagrees with
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// our time lock values, then we'll apply the new delta value and try it
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// once more.
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case *lnwire.FailIncorrectCltvExpiry:
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i.policyFailure = &failedPair
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i.pairResults[failedPair] = 0
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return false, 0
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// The outgoing channel that this node was meant to forward one is
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// currently disabled, so we'll apply the update and continue.
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case *lnwire.FailChannelDisabled:
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i.pairResults[failedPair] = 0
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return false, 0
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// It's likely that the outgoing channel didn't have sufficient
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// capacity, so we'll prune this edge for now, and continue onwards with
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// our path finding.
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case *lnwire.FailTemporaryChannelFailure:
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i.pairResults[failedPair] = failedAmt
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return false, 0
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// If the send fail due to a node not having the required features, then
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// we'll note this error and continue.
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case *lnwire.FailRequiredNodeFeatureMissing:
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i.nodeFailure = &failureVertex
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return false, 0
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// If the send fail due to a node not having the required features, then
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// we'll note this error and continue.
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case *lnwire.FailRequiredChannelFeatureMissing:
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i.nodeFailure = &failureVertex
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return false, 0
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// If the next hop in the route wasn't known or offline, we'll only the
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// channel which we attempted to route over. This is conservative, and
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// it can handle faulty channels between nodes properly. Additionally,
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// this guards against routing nodes returning errors in order to
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// attempt to black list another node.
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case *lnwire.FailUnknownNextPeer:
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i.pairResults[failedPair] = 0
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return false, 0
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// If the node wasn't able to forward for which ever reason, then we'll
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// note this and continue with the routes.
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case *lnwire.FailTemporaryNodeFailure:
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i.nodeFailure = &failureVertex
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return false, 0
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case *lnwire.FailPermanentNodeFailure:
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i.nodeFailure = &failureVertex
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return false, 0
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// If we crafted a route that contains a too long time lock for an
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// intermediate node, we'll prune the node. As there currently is no way
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// of knowing that node's maximum acceptable cltv, we cannot take this
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// constraint into account during routing.
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//
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// TODO(joostjager): Record the rejected cltv and use that as a hint
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// during future path finding through that node.
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case *lnwire.FailExpiryTooFar:
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i.nodeFailure = &failureVertex
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return false, 0
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// If we get a permanent channel or node failure, then we'll prune the
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// channel in both directions and continue with the rest of the routes.
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case *lnwire.FailPermanentChannelFailure:
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i.pairResults[failedPair] = 0
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i.pairResults[failedPair.Reverse()] = 0
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return false, 0
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// Any other failure or an empty failure will get the node pruned.
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default:
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i.nodeFailure = &failureVertex
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return false, 0
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}
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}
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// processPaymentOutcomeUnknown processes a payment outcome for which no failure
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// message or source is available.
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func (i *interpretedResult) processPaymentOutcomeUnknown(route *route.Route) {
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n := len(route.Hops)
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// If this is a direct payment, the destination must be at fault.
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if n == 1 {
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i.failNode(route, n)
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i.finalFailureReason = &reasonError
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return
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}
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// Otherwise penalize all channels in the route to make sure the
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// responsible node is at least hit too. We even penalize the connection
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// to our own peer, because that peer could also be responsible.
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i.failPairRange(route, 0, n-1)
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}
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// failNode marks the node indicated by idx in the route as failed. This
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// function intentionally panics when the self node is failed.
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func (i *interpretedResult) failNode(rt *route.Route, idx int) {
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i.nodeFailure = &rt.Hops[idx-1].PubKeyBytes
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}
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// failPairRange marks the node pairs from node fromIdx to node toIdx as failed.
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func (i *interpretedResult) failPairRange(
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rt *route.Route, fromIdx, toIdx int) {
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for idx := fromIdx; idx <= toIdx; idx++ {
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i.failPair(rt, idx)
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}
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}
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// failPair marks a pair as failed in both directions.
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func (i *interpretedResult) failPair(
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rt *route.Route, idx int) {
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pair, _ := getPair(rt, idx)
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// Report pair in both directions without a minimum penalization amount.
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i.pairResults[pair] = 0
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i.pairResults[pair.Reverse()] = 0
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}
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// getPair returns a node pair from the route and the amount passed between that
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// pair.
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func getPair(rt *route.Route, channelIdx int) (DirectedNodePair,
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lnwire.MilliSatoshi) {
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nodeTo := rt.Hops[channelIdx].PubKeyBytes
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var (
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nodeFrom route.Vertex
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amt lnwire.MilliSatoshi
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)
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if channelIdx == 0 {
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nodeFrom = rt.SourcePubKey
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amt = rt.TotalAmount
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} else {
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nodeFrom = rt.Hops[channelIdx-1].PubKeyBytes
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amt = rt.Hops[channelIdx-1].AmtToForward
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}
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pair := NewDirectedNodePair(nodeFrom, nodeTo)
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return pair, amt
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}
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// getFailedPair tries to locate the failing pair given a route and the pubkey
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// of the node that sent the failure. It will assume that the failure is
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// associated with the outgoing channel set of the failing node. As a second
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// result, it returns the amount sent between the pair.
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func getFailedPair(route *route.Route, failureSource int) (DirectedNodePair,
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lnwire.MilliSatoshi) {
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// Determine if we have a failure from the final hop. If it is, we
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// assume that the failing channel is the incoming channel.
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//
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// TODO(joostjager): In this case, certain types of failures are not
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// expected. For example FailUnknownNextPeer. This could be a reason to
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// prune the node?
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if failureSource == len(route.Hops) {
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failureSource--
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}
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// As this failure indicates that the target channel was unable to carry
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// this HTLC (for w/e reason), we'll return the _outgoing_ channel that
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// the source of the failure was meant to pass the HTLC along to.
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if failureSource == 0 {
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return NewDirectedNodePair(
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route.SourcePubKey,
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route.Hops[0].PubKeyBytes,
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), route.TotalAmount
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}
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return NewDirectedNodePair(
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route.Hops[failureSource-1].PubKeyBytes,
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route.Hops[failureSource].PubKeyBytes,
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), route.Hops[failureSource-1].AmtToForward
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}
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