mirror of
https://github.com/lightningnetwork/lnd.git
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430 lines
14 KiB
Go
430 lines
14 KiB
Go
package htlcswitch
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import (
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"encoding/binary"
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"io"
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"github.com/lightningnetwork/lightning-onion"
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"github.com/lightningnetwork/lnd/lnwire"
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"github.com/roasbeef/btcd/btcec"
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)
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// NetworkHop indicates the blockchain network that is intended to be the next
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// hop for a forwarded HTLC. The existence of this field within the
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// ForwardingInfo struct enables the ability for HTLC to cross chain-boundaries
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// at will.
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type NetworkHop uint8
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const (
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// BitcoinHop denotes that an HTLC is to be forwarded along the Bitcoin
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// link with the specified short channel ID.
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BitcoinHop NetworkHop = iota
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// LitecoinHop denotes that an HTLC is to be forwarded along the
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// Litecoin link with the specified short channel ID.
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LitecoinHop
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)
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// String returns the string representation of the target NetworkHop.
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func (c NetworkHop) String() string {
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switch c {
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case BitcoinHop:
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return "Bitcoin"
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case LitecoinHop:
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return "Litecoin"
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default:
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return "Kekcoin"
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}
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}
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var (
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// exitHop is a special "hop" which denotes that an incoming HTLC is
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// meant to pay finally to the receiving node.
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exitHop lnwire.ShortChannelID
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// sourceHop is a sentinel value denoting that an incoming HTLC is
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// initiated by our own switch.
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sourceHop lnwire.ShortChannelID
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)
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// ForwardingInfo contains all the information that is necessary to forward and
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// incoming HTLC to the next hop encoded within a valid HopIterator instance.
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// Forwarding links are to use this information to authenticate the information
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// received within the incoming HTLC, to ensure that the prior hop didn't
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// tamper with the end-to-end routing information at all.
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type ForwardingInfo struct {
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// Network is the target blockchain network that the HTLC will travel
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// over next.
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Network NetworkHop
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// NextHop is the channel ID of the next hop. The received HTLC should
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// be forwarded to this particular channel in order to continue the
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// end-to-end route.
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NextHop lnwire.ShortChannelID
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// AmountToForward is the amount of milli-satoshis that the receiving
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// node should forward to the next hop.
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AmountToForward lnwire.MilliSatoshi
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// OutgoingCTLV is the specified value of the CTLV timelock to be used
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// in the outgoing HTLC.
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OutgoingCTLV uint32
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// TODO(roasbeef): modify sphinx logic to not just discard the
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// remaining bytes, instead should include the rest as excess
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}
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// HopIterator is an interface that abstracts away the routing information
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// included in HTLC's which includes the entirety of the payment path of an
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// HTLC. This interface provides two basic method which carry out: how to
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// interpret the forwarding information encoded within the HTLC packet, and hop
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// to encode the forwarding information for the _next_ hop.
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type HopIterator interface {
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// ForwardingInstructions returns the set of fields that detail exactly
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// _how_ this hop should forward the HTLC to the next hop.
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// Additionally, the information encoded within the returned
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// ForwardingInfo is to be used by each hop to authenticate the
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// information given to it by the prior hop.
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ForwardingInstructions() ForwardingInfo
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// EncodeNextHop encodes the onion packet destined for the next hop
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// into the passed io.Writer.
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EncodeNextHop(w io.Writer) error
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// ExtractErrorEncrypter returns the ErrorEncrypter needed for this hop,
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// along with a failure code to signal if the decoding was successful.
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ExtractErrorEncrypter(ErrorEncrypterExtracter) (ErrorEncrypter,
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lnwire.FailCode)
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}
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// sphinxHopIterator is the Sphinx implementation of hop iterator which uses
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// onion routing to encode the payment route in such a way so that node might
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// see only the next hop in the route..
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type sphinxHopIterator struct {
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// ogPacket is the original packet from which the processed packet is
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// derived.
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ogPacket *sphinx.OnionPacket
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// processedPacket is the outcome of processing an onion packet. It
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// includes the information required to properly forward the packet to
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// the next hop.
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processedPacket *sphinx.ProcessedPacket
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}
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// makeSphinxHopIterator converts a processed packet returned from a sphinx
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// router and converts it into an hop iterator for usage in the link.
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func makeSphinxHopIterator(ogPacket *sphinx.OnionPacket,
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packet *sphinx.ProcessedPacket) *sphinxHopIterator {
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return &sphinxHopIterator{
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ogPacket: ogPacket,
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processedPacket: packet,
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}
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}
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// A compile time check to ensure sphinxHopIterator implements the HopIterator
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// interface.
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var _ HopIterator = (*sphinxHopIterator)(nil)
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// Encode encodes iterator and writes it to the writer.
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//
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// NOTE: Part of the HopIterator interface.
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func (r *sphinxHopIterator) EncodeNextHop(w io.Writer) error {
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return r.processedPacket.NextPacket.Encode(w)
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}
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// ForwardingInstructions returns the set of fields that detail exactly _how_
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// this hop should forward the HTLC to the next hop. Additionally, the
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// information encoded within the returned ForwardingInfo is to be used by each
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// hop to authenticate the information given to it by the prior hop.
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//
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// NOTE: Part of the HopIterator interface.
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func (r *sphinxHopIterator) ForwardingInstructions() ForwardingInfo {
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fwdInst := r.processedPacket.ForwardingInstructions
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var nextHop lnwire.ShortChannelID
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switch r.processedPacket.Action {
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case sphinx.ExitNode:
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nextHop = exitHop
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case sphinx.MoreHops:
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s := binary.BigEndian.Uint64(fwdInst.NextAddress[:])
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nextHop = lnwire.NewShortChanIDFromInt(s)
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}
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return ForwardingInfo{
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Network: BitcoinHop,
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NextHop: nextHop,
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AmountToForward: lnwire.MilliSatoshi(fwdInst.ForwardAmount),
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OutgoingCTLV: fwdInst.OutgoingCltv,
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}
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}
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// ExtractErrorEncrypter decodes and returns the ErrorEncrypter for this hop,
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// along with a failure code to signal if the decoding was successful. The
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// ErrorEncrypter is used to encrypt errors back to the sender in the event that
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// a payment fails.
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//
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// NOTE: Part of the HopIterator interface.
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func (r *sphinxHopIterator) ExtractErrorEncrypter(
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extracter ErrorEncrypterExtracter) (ErrorEncrypter, lnwire.FailCode) {
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return extracter(r.ogPacket.EphemeralKey)
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}
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// OnionProcessor is responsible for keeping all sphinx dependent parts inside
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// and expose only decoding function. With such approach we give freedom for
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// subsystems which wants to decode sphinx path to not be dependable from
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// sphinx at all.
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//
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// NOTE: The reason for keeping decoder separated from hop iterator is too
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// maintain the hop iterator abstraction. Without it the structures which using
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// the hop iterator should contain sphinx router which makes their creations in
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// tests dependent from the sphinx internal parts.
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type OnionProcessor struct {
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router *sphinx.Router
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}
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// NewOnionProcessor creates new instance of decoder.
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func NewOnionProcessor(router *sphinx.Router) *OnionProcessor {
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return &OnionProcessor{router}
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}
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// Start spins up the onion processor's sphinx router.
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func (p *OnionProcessor) Start() error {
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return p.router.Start()
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}
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// Stop shutsdown the onion processor's sphinx router.
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func (p *OnionProcessor) Stop() error {
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p.router.Stop()
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return nil
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}
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// DecodeHopIterator attempts to decode a valid sphinx packet from the passed io.Reader
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// instance using the rHash as the associated data when checking the relevant
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// MACs during the decoding process.
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func (p *OnionProcessor) DecodeHopIterator(r io.Reader, rHash []byte,
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incomingCltv uint32) (HopIterator, lnwire.FailCode) {
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onionPkt := &sphinx.OnionPacket{}
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if err := onionPkt.Decode(r); err != nil {
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switch err {
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case sphinx.ErrInvalidOnionVersion:
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return nil, lnwire.CodeInvalidOnionVersion
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case sphinx.ErrInvalidOnionKey:
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return nil, lnwire.CodeInvalidOnionKey
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default:
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log.Errorf("unable to decode onion packet: %v", err)
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return nil, lnwire.CodeInvalidOnionKey
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}
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}
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// Attempt to process the Sphinx packet. We include the payment hash of
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// the HTLC as it's authenticated within the Sphinx packet itself as
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// associated data in order to thwart attempts a replay attacks. In the
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// case of a replay, an attacker is *forced* to use the same payment
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// hash twice, thereby losing their money entirely.
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sphinxPacket, err := p.router.ProcessOnionPacket(
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onionPkt, rHash, incomingCltv,
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)
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if err != nil {
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switch err {
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case sphinx.ErrInvalidOnionVersion:
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return nil, lnwire.CodeInvalidOnionVersion
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case sphinx.ErrInvalidOnionHMAC:
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return nil, lnwire.CodeInvalidOnionHmac
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case sphinx.ErrInvalidOnionKey:
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return nil, lnwire.CodeInvalidOnionKey
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default:
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log.Errorf("unable to process onion packet: %v", err)
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return nil, lnwire.CodeInvalidOnionKey
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}
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}
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return makeSphinxHopIterator(onionPkt, sphinxPacket), lnwire.CodeNone
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}
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// DecodeHopIteratorRequest encapsulates all date necessary to process an onion
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// packet, perform sphinx replay detection, and schedule the entry for garbage
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// collection.
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type DecodeHopIteratorRequest struct {
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OnionReader io.Reader
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RHash []byte
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IncomingCltv uint32
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}
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// DecodeHopIteratorResponse encapsulates the outcome of a batched sphinx onion
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// processing.
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type DecodeHopIteratorResponse struct {
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HopIterator HopIterator
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FailCode lnwire.FailCode
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}
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// Result returns the (HopIterator, lnwire.FailCode) tuple, which should
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// correspond to the index of a particular DecodeHopIteratorRequest.
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//
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// NOTE: The HopIterator should be considered invalid if the fail code is
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// anything but lnwire.CodeNone.
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func (r *DecodeHopIteratorResponse) Result() (HopIterator, lnwire.FailCode) {
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return r.HopIterator, r.FailCode
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}
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// DecodeHopIterators performs batched decoding and validation of incoming
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// sphinx packets. For the same `id`, this method will return the same iterators
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// and failcodes upon subsequent invocations.
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//
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// NOTE: In order for the responses to be valid, the caller must guarantee that
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// the presented readers and rhashes *NEVER* deviate across invocations for the
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// same id.
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func (p *OnionProcessor) DecodeHopIterators(id []byte,
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reqs []DecodeHopIteratorRequest) ([]DecodeHopIteratorResponse, error) {
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var (
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batchSize = len(reqs)
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onionPkts = make([]sphinx.OnionPacket, batchSize)
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resps = make([]DecodeHopIteratorResponse, batchSize)
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)
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tx := p.router.BeginTxn(id, batchSize)
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for i, req := range reqs {
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onionPkt := &onionPkts[i]
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resp := &resps[i]
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err := onionPkt.Decode(req.OnionReader)
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switch err {
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case nil:
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// success
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case sphinx.ErrInvalidOnionVersion:
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resp.FailCode = lnwire.CodeInvalidOnionVersion
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continue
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case sphinx.ErrInvalidOnionKey:
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resp.FailCode = lnwire.CodeInvalidOnionKey
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continue
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default:
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log.Errorf("unable to decode onion packet: %v", err)
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resp.FailCode = lnwire.CodeInvalidOnionKey
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continue
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}
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err = tx.ProcessOnionPacket(
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uint16(i), onionPkt, req.RHash, req.IncomingCltv,
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)
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switch err {
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case nil:
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// success
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case sphinx.ErrInvalidOnionVersion:
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resp.FailCode = lnwire.CodeInvalidOnionVersion
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continue
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case sphinx.ErrInvalidOnionHMAC:
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resp.FailCode = lnwire.CodeInvalidOnionHmac
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continue
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case sphinx.ErrInvalidOnionKey:
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resp.FailCode = lnwire.CodeInvalidOnionKey
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continue
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default:
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log.Errorf("unable to process onion packet: %v", err)
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resp.FailCode = lnwire.CodeInvalidOnionKey
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continue
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}
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}
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// With that batch created, we will now attempt to write the shared
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// secrets to disk. This operation will returns the set of indices that
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// were detected as replays, and the computed sphinx packets for all
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// indices that did not fail the above loop. Only indices that are not
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// in the replay set should be considered valid, as they are
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// opportunistically computed.
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packets, replays, err := tx.Commit()
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if err != nil {
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log.Errorf("unable to process onion packet batch %x: %v",
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id, err)
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// If we failed to commit the batch to the secret share log, we
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// will mark all not-yet-failed channels with a temporary
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// channel failure and exit since we cannot proceed.
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for i := range resps {
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resp := &resps[i]
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// Skip any indexes that already failed onion decoding.
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if resp.FailCode != lnwire.CodeNone {
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continue
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}
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log.Errorf("unable to process onion packet %x-%v",
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id, i)
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resp.FailCode = lnwire.CodeTemporaryChannelFailure
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}
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// TODO(conner): return real errors to caller so link can fail?
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return resps, err
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}
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// Otherwise, the commit was successful. Now we will post process any
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// remaining packets, additionally failing any that were included in the
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// replay set.
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for i := range resps {
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resp := &resps[i]
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// Skip any indexes that already failed onion decoding.
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if resp.FailCode != lnwire.CodeNone {
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continue
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}
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// If this index is contained in the replay set, mark it with a
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// temporary channel failure error code. We infer that the
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// offending error was due to a replayed packet because this
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// index was found in the replay set.
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if replays.Contains(uint16(i)) {
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log.Errorf("unable to process onion packet: %v",
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sphinx.ErrReplayedPacket)
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resp.FailCode = lnwire.CodeTemporaryChannelFailure
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continue
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}
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// Finally, construct a hop iterator from our processed sphinx
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// packet, simultaneously caching the original onion packet.
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resp.HopIterator = makeSphinxHopIterator(&onionPkts[i], &packets[i])
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}
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return resps, nil
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}
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// ExtractErrorEncrypter takes an io.Reader which should contain the onion
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// packet as original received by a forwarding node and creates an
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// ErrorEncrypter instance using the derived shared secret. In the case that en
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// error occurs, a lnwire failure code detailing the parsing failure will be
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// returned.
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func (p *OnionProcessor) ExtractErrorEncrypter(ephemeralKey *btcec.PublicKey) (
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ErrorEncrypter, lnwire.FailCode) {
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onionObfuscator, err := sphinx.NewOnionErrorEncrypter(
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p.router, ephemeralKey,
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)
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if err != nil {
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switch err {
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case sphinx.ErrInvalidOnionVersion:
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return nil, lnwire.CodeInvalidOnionVersion
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case sphinx.ErrInvalidOnionHMAC:
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return nil, lnwire.CodeInvalidOnionHmac
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case sphinx.ErrInvalidOnionKey:
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return nil, lnwire.CodeInvalidOnionKey
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default:
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log.Errorf("unable to process onion packet: %v", err)
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return nil, lnwire.CodeInvalidOnionKey
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}
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}
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return &SphinxErrorEncrypter{
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OnionErrorEncrypter: onionObfuscator,
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EphemeralKey: ephemeralKey,
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}, lnwire.CodeNone
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}
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