lnd/routing/route/route.go

507 lines
14 KiB
Go

package route
import (
"bytes"
"encoding/binary"
"encoding/hex"
"errors"
"fmt"
"io"
"strconv"
"strings"
"github.com/btcsuite/btcd/btcec/v2"
sphinx "github.com/lightningnetwork/lightning-onion"
"github.com/lightningnetwork/lnd/lnwire"
"github.com/lightningnetwork/lnd/record"
"github.com/lightningnetwork/lnd/tlv"
)
// VertexSize is the size of the array to store a vertex.
const VertexSize = 33
var (
// ErrNoRouteHopsProvided is returned when a caller attempts to
// construct a new sphinx packet, but provides an empty set of hops for
// each route.
ErrNoRouteHopsProvided = fmt.Errorf("empty route hops provided")
// ErrMaxRouteHopsExceeded is returned when a caller attempts to
// construct a new sphinx packet, but provides too many hops.
ErrMaxRouteHopsExceeded = fmt.Errorf("route has too many hops")
// ErrIntermediateMPPHop is returned when a hop tries to deliver an MPP
// record to an intermediate hop, only final hops can receive MPP
// records.
ErrIntermediateMPPHop = errors.New("cannot send MPP to intermediate")
// ErrAMPMissingMPP is returned when the caller tries to attach an AMP
// record but no MPP record is presented for the final hop.
ErrAMPMissingMPP = errors.New("cannot send AMP without MPP record")
)
// Vertex is a simple alias for the serialization of a compressed Bitcoin
// public key.
type Vertex [VertexSize]byte
// NewVertex returns a new Vertex given a public key.
func NewVertex(pub *btcec.PublicKey) Vertex {
var v Vertex
copy(v[:], pub.SerializeCompressed())
return v
}
// NewVertexFromBytes returns a new Vertex based on a serialized pubkey in a
// byte slice.
func NewVertexFromBytes(b []byte) (Vertex, error) {
vertexLen := len(b)
if vertexLen != VertexSize {
return Vertex{}, fmt.Errorf("invalid vertex length of %v, "+
"want %v", vertexLen, VertexSize)
}
var v Vertex
copy(v[:], b)
return v, nil
}
// NewVertexFromStr returns a new Vertex given its hex-encoded string format.
func NewVertexFromStr(v string) (Vertex, error) {
// Return error if hex string is of incorrect length.
if len(v) != VertexSize*2 {
return Vertex{}, fmt.Errorf("invalid vertex string length of "+
"%v, want %v", len(v), VertexSize*2)
}
vertex, err := hex.DecodeString(v)
if err != nil {
return Vertex{}, err
}
return NewVertexFromBytes(vertex)
}
// String returns a human readable version of the Vertex which is the
// hex-encoding of the serialized compressed public key.
func (v Vertex) String() string {
return fmt.Sprintf("%x", v[:])
}
// Hop represents an intermediate or final node of the route. This naming
// is in line with the definition given in BOLT #4: Onion Routing Protocol.
// The struct houses the channel along which this hop can be reached and
// the values necessary to create the HTLC that needs to be sent to the
// next hop. It is also used to encode the per-hop payload included within
// the Sphinx packet.
type Hop struct {
// PubKeyBytes is the raw bytes of the public key of the target node.
PubKeyBytes Vertex
// ChannelID is the unique channel ID for the channel. The first 3
// bytes are the block height, the next 3 the index within the block,
// and the last 2 bytes are the output index for the channel.
ChannelID uint64
// OutgoingTimeLock is the timelock value that should be used when
// crafting the _outgoing_ HTLC from this hop.
OutgoingTimeLock uint32
// AmtToForward is the amount that this hop will forward to the next
// hop. This value is less than the value that the incoming HTLC
// carries as a fee will be subtracted by the hop.
AmtToForward lnwire.MilliSatoshi
// MPP encapsulates the data required for option_mpp. This field should
// only be set for the final hop.
MPP *record.MPP
// AMP encapsulates the data required for option_amp. This field should
// only be set for the final hop.
AMP *record.AMP
// CustomRecords if non-nil are a set of additional TLV records that
// should be included in the forwarding instructions for this node.
CustomRecords record.CustomSet
// LegacyPayload if true, then this signals that this node doesn't
// understand the new TLV payload, so we must instead use the legacy
// payload.
LegacyPayload bool
// Metadata is additional data that is sent along with the payment to
// the payee.
Metadata []byte
}
// Copy returns a deep copy of the Hop.
func (h *Hop) Copy() *Hop {
c := *h
if h.MPP != nil {
m := *h.MPP
c.MPP = &m
}
if h.AMP != nil {
a := *h.AMP
c.AMP = &a
}
return &c
}
// PackHopPayload writes to the passed io.Writer, the series of byes that can
// be placed directly into the per-hop payload (EOB) for this hop. This will
// include the required routing fields, as well as serializing any of the
// passed optional TLVRecords. nextChanID is the unique channel ID that
// references the _outgoing_ channel ID that follows this hop. This field
// follows the same semantics as the NextAddress field in the onion: it should
// be set to zero to indicate the terminal hop.
func (h *Hop) PackHopPayload(w io.Writer, nextChanID uint64) error {
// If this is a legacy payload, then we'll exit here as this method
// shouldn't be called.
if h.LegacyPayload == true {
return fmt.Errorf("cannot pack hop payloads for legacy " +
"payloads")
}
// Otherwise, we'll need to make a new stream that includes our
// required routing fields, as well as these optional values.
var records []tlv.Record
// Every hop must have an amount to forward and CLTV expiry.
amt := uint64(h.AmtToForward)
records = append(records,
record.NewAmtToFwdRecord(&amt),
record.NewLockTimeRecord(&h.OutgoingTimeLock),
)
// BOLT 04 says the next_hop_id should be omitted for the final hop,
// but present for all others.
//
// TODO(conner): test using hop.Exit once available
if nextChanID != 0 {
records = append(records,
record.NewNextHopIDRecord(&nextChanID),
)
}
// If an MPP record is destined for this hop, ensure that we only ever
// attach it to the final hop. Otherwise the route was constructed
// incorrectly.
if h.MPP != nil {
if nextChanID == 0 {
records = append(records, h.MPP.Record())
} else {
return ErrIntermediateMPPHop
}
}
// If an AMP record is destined for this hop, ensure that we only ever
// attach it if we also have an MPP record. We can infer that this is
// already a final hop if MPP is non-nil otherwise we would have exited
// above.
if h.AMP != nil {
if h.MPP != nil {
records = append(records, h.AMP.Record())
} else {
return ErrAMPMissingMPP
}
}
// If metadata is specified, generate a tlv record for it.
if h.Metadata != nil {
records = append(records,
record.NewMetadataRecord(&h.Metadata),
)
}
// Append any custom types destined for this hop.
tlvRecords := tlv.MapToRecords(h.CustomRecords)
records = append(records, tlvRecords...)
// To ensure we produce a canonical stream, we'll sort the records
// before encoding them as a stream in the hop payload.
tlv.SortRecords(records)
tlvStream, err := tlv.NewStream(records...)
if err != nil {
return err
}
return tlvStream.Encode(w)
}
// Size returns the total size this hop's payload would take up in the onion
// packet.
func (h *Hop) PayloadSize(nextChanID uint64) uint64 {
if h.LegacyPayload {
return sphinx.LegacyHopDataSize
}
var payloadSize uint64
addRecord := func(tlvType tlv.Type, length uint64) {
payloadSize += tlv.VarIntSize(uint64(tlvType)) +
tlv.VarIntSize(length) + length
}
// Add amount size.
addRecord(record.AmtOnionType, tlv.SizeTUint64(uint64(h.AmtToForward)))
// Add lock time size.
addRecord(
record.LockTimeOnionType,
tlv.SizeTUint64(uint64(h.OutgoingTimeLock)),
)
// Add next hop if present.
if nextChanID != 0 {
addRecord(record.NextHopOnionType, 8)
}
// Add mpp if present.
if h.MPP != nil {
addRecord(record.MPPOnionType, h.MPP.PayloadSize())
}
// Add amp if present.
if h.AMP != nil {
addRecord(record.AMPOnionType, h.AMP.PayloadSize())
}
// Add metadata if present.
if h.Metadata != nil {
addRecord(record.MetadataOnionType, uint64(len(h.Metadata)))
}
// Add custom records.
for k, v := range h.CustomRecords {
addRecord(tlv.Type(k), uint64(len(v)))
}
// Add the size required to encode the payload length.
payloadSize += tlv.VarIntSize(payloadSize)
// Add HMAC.
payloadSize += sphinx.HMACSize
return payloadSize
}
// Route represents a path through the channel graph which runs over one or
// more channels in succession. This struct carries all the information
// required to craft the Sphinx onion packet, and send the payment along the
// first hop in the path. A route is only selected as valid if all the channels
// have sufficient capacity to carry the initial payment amount after fees are
// accounted for.
type Route struct {
// TotalTimeLock is the cumulative (final) time lock across the entire
// route. This is the CLTV value that should be extended to the first
// hop in the route. All other hops will decrement the time-lock as
// advertised, leaving enough time for all hops to wait for or present
// the payment preimage to complete the payment.
TotalTimeLock uint32
// TotalAmount is the total amount of funds required to complete a
// payment over this route. This value includes the cumulative fees at
// each hop. As a result, the HTLC extended to the first-hop in the
// route will need to have at least this many satoshis, otherwise the
// route will fail at an intermediate node due to an insufficient
// amount of fees.
TotalAmount lnwire.MilliSatoshi
// SourcePubKey is the pubkey of the node where this route originates
// from.
SourcePubKey Vertex
// Hops contains details concerning the specific forwarding details at
// each hop.
Hops []*Hop
}
// Copy returns a deep copy of the Route.
func (r *Route) Copy() *Route {
c := *r
c.Hops = make([]*Hop, len(r.Hops))
for i := range r.Hops {
c.Hops[i] = r.Hops[i].Copy()
}
return &c
}
// HopFee returns the fee charged by the route hop indicated by hopIndex.
func (r *Route) HopFee(hopIndex int) lnwire.MilliSatoshi {
var incomingAmt lnwire.MilliSatoshi
if hopIndex == 0 {
incomingAmt = r.TotalAmount
} else {
incomingAmt = r.Hops[hopIndex-1].AmtToForward
}
// Fee is calculated as difference between incoming and outgoing amount.
return incomingAmt - r.Hops[hopIndex].AmtToForward
}
// TotalFees is the sum of the fees paid at each hop within the final route. In
// the case of a one-hop payment, this value will be zero as we don't need to
// pay a fee to ourself.
func (r *Route) TotalFees() lnwire.MilliSatoshi {
if len(r.Hops) == 0 {
return 0
}
return r.TotalAmount - r.ReceiverAmt()
}
// ReceiverAmt is the amount received by the final hop of this route.
func (r *Route) ReceiverAmt() lnwire.MilliSatoshi {
if len(r.Hops) == 0 {
return 0
}
return r.Hops[len(r.Hops)-1].AmtToForward
}
// FinalHop returns the last hop of the route, or nil if the route is empty.
func (r *Route) FinalHop() *Hop {
if len(r.Hops) == 0 {
return nil
}
return r.Hops[len(r.Hops)-1]
}
// NewRouteFromHops creates a new Route structure from the minimally required
// information to perform the payment. It infers fee amounts and populates the
// node, chan and prev/next hop maps.
func NewRouteFromHops(amtToSend lnwire.MilliSatoshi, timeLock uint32,
sourceVertex Vertex, hops []*Hop) (*Route, error) {
if len(hops) == 0 {
return nil, ErrNoRouteHopsProvided
}
// First, we'll create a route struct and populate it with the fields
// for which the values are provided as arguments of this function.
// TotalFees is determined based on the difference between the amount
// that is send from the source and the final amount that is received
// by the destination.
route := &Route{
SourcePubKey: sourceVertex,
Hops: hops,
TotalTimeLock: timeLock,
TotalAmount: amtToSend,
}
return route, nil
}
// ToSphinxPath converts a complete route into a sphinx PaymentPath that
// contains the per-hop paylods used to encoding the HTLC routing data for each
// hop in the route. This method also accepts an optional EOB payload for the
// final hop.
func (r *Route) ToSphinxPath() (*sphinx.PaymentPath, error) {
var path sphinx.PaymentPath
// We can only construct a route if there are hops provided.
if len(r.Hops) == 0 {
return nil, ErrNoRouteHopsProvided
}
// Check maximum route length.
if len(r.Hops) > sphinx.NumMaxHops {
return nil, ErrMaxRouteHopsExceeded
}
// For each hop encoded within the route, we'll convert the hop struct
// to an OnionHop with matching per-hop payload within the path as used
// by the sphinx package.
for i, hop := range r.Hops {
pub, err := btcec.ParsePubKey(hop.PubKeyBytes[:])
if err != nil {
return nil, err
}
// As a base case, the next hop is set to all zeroes in order
// to indicate that the "last hop" as no further hops after it.
nextHop := uint64(0)
// If we aren't on the last hop, then we set the "next address"
// field to be the channel that directly follows it.
if i != len(r.Hops)-1 {
nextHop = r.Hops[i+1].ChannelID
}
var payload sphinx.HopPayload
// If this is the legacy payload, then we can just include the
// hop data as normal.
if hop.LegacyPayload {
// Before we encode this value, we'll pack the next hop
// into the NextAddress field of the hop info to ensure
// we point to the right now.
hopData := sphinx.HopData{
ForwardAmount: uint64(hop.AmtToForward),
OutgoingCltv: hop.OutgoingTimeLock,
}
binary.BigEndian.PutUint64(
hopData.NextAddress[:], nextHop,
)
payload, err = sphinx.NewHopPayload(&hopData, nil)
if err != nil {
return nil, err
}
} else {
// For non-legacy payloads, we'll need to pack the
// routing information, along with any extra TLV
// information into the new per-hop payload format.
// We'll also pass in the chan ID of the hop this
// channel should be forwarded to so we can construct a
// valid payload.
var b bytes.Buffer
err := hop.PackHopPayload(&b, nextHop)
if err != nil {
return nil, err
}
// TODO(roasbeef): make better API for NewHopPayload?
payload, err = sphinx.NewHopPayload(nil, b.Bytes())
if err != nil {
return nil, err
}
}
path[i] = sphinx.OnionHop{
NodePub: *pub,
HopPayload: payload,
}
}
return &path, nil
}
// String returns a human readable representation of the route.
func (r *Route) String() string {
var b strings.Builder
amt := r.TotalAmount
for i, hop := range r.Hops {
if i > 0 {
b.WriteString(" -> ")
}
b.WriteString(fmt.Sprintf("%v (%v)",
strconv.FormatUint(hop.ChannelID, 10),
amt,
))
amt = hop.AmtToForward
}
return fmt.Sprintf("%v, cltv %v",
b.String(), r.TotalTimeLock,
)
}