lnd/invoices/update.go
2021-04-07 12:08:35 -07:00

436 lines
14 KiB
Go

package invoices
import (
"errors"
"github.com/lightningnetwork/lnd/amp"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/lntypes"
"github.com/lightningnetwork/lnd/lnwire"
"github.com/lightningnetwork/lnd/record"
)
// invoiceUpdateCtx is an object that describes the context for the invoice
// update to be carried out.
type invoiceUpdateCtx struct {
hash lntypes.Hash
circuitKey channeldb.CircuitKey
amtPaid lnwire.MilliSatoshi
expiry uint32
currentHeight int32
finalCltvRejectDelta int32
customRecords record.CustomSet
mpp *record.MPP
amp *record.AMP
}
// invoiceRef returns an identifier that can be used to lookup or update the
// invoice this HTLC is targeting.
func (i *invoiceUpdateCtx) invoiceRef() channeldb.InvoiceRef {
switch {
case i.amp != nil && i.mpp != nil:
payAddr := i.mpp.PaymentAddr()
return channeldb.InvoiceRefByAddr(payAddr)
case i.mpp != nil:
payAddr := i.mpp.PaymentAddr()
return channeldb.InvoiceRefByHashAndAddr(i.hash, payAddr)
default:
return channeldb.InvoiceRefByHash(i.hash)
}
}
// setID returns an identifier that identifies other possible HTLCs that this
// particular one is related to. If nil is returned this means the HTLC is an
// MPP or legacy payment, otherwise the HTLC belongs AMP payment.
func (i invoiceUpdateCtx) setID() *[32]byte {
if i.amp != nil {
setID := i.amp.SetID()
return &setID
}
return nil
}
// log logs a message specific to this update context.
func (i *invoiceUpdateCtx) log(s string) {
log.Debugf("Invoice%v: %v, amt=%v, expiry=%v, circuit=%v, mpp=%v, "+
"amp=%v", i.invoiceRef(), s, i.amtPaid, i.expiry, i.circuitKey,
i.mpp, i.amp)
}
// failRes is a helper function which creates a failure resolution with
// the information contained in the invoiceUpdateCtx and the fail resolution
// result provided.
func (i invoiceUpdateCtx) failRes(outcome FailResolutionResult) *HtlcFailResolution {
return NewFailResolution(i.circuitKey, i.currentHeight, outcome)
}
// settleRes is a helper function which creates a settle resolution with
// the information contained in the invoiceUpdateCtx and the preimage and
// the settle resolution result provided.
func (i invoiceUpdateCtx) settleRes(preimage lntypes.Preimage,
outcome SettleResolutionResult) *HtlcSettleResolution {
return NewSettleResolution(
preimage, i.circuitKey, i.currentHeight, outcome,
)
}
// acceptRes is a helper function which creates an accept resolution with
// the information contained in the invoiceUpdateCtx and the accept resolution
// result provided.
func (i invoiceUpdateCtx) acceptRes(outcome acceptResolutionResult) *htlcAcceptResolution {
return newAcceptResolution(i.circuitKey, outcome)
}
// updateInvoice is a callback for DB.UpdateInvoice that contains the invoice
// settlement logic. It returns a hltc resolution that indicates what the
// outcome of the update was.
func updateInvoice(ctx *invoiceUpdateCtx, inv *channeldb.Invoice) (
*channeldb.InvoiceUpdateDesc, HtlcResolution, error) {
// Don't update the invoice when this is a replayed htlc.
htlc, ok := inv.Htlcs[ctx.circuitKey]
if ok {
switch htlc.State {
case channeldb.HtlcStateCanceled:
return nil, ctx.failRes(ResultReplayToCanceled), nil
case channeldb.HtlcStateAccepted:
return nil, ctx.acceptRes(resultReplayToAccepted), nil
case channeldb.HtlcStateSettled:
return nil, ctx.settleRes(
*inv.Terms.PaymentPreimage,
ResultReplayToSettled,
), nil
default:
return nil, nil, errors.New("unknown htlc state")
}
}
// If no MPP payload was provided, then we expect this to be a keysend,
// or a payment to an invoice created before we started to require the
// MPP payload.
if ctx.mpp == nil {
return updateLegacy(ctx, inv)
}
return updateMpp(ctx, inv)
}
// updateMpp is a callback for DB.UpdateInvoice that contains the invoice
// settlement logic for mpp payments.
func updateMpp(ctx *invoiceUpdateCtx,
inv *channeldb.Invoice) (*channeldb.InvoiceUpdateDesc,
HtlcResolution, error) {
setID := ctx.setID()
// Start building the accept descriptor.
acceptDesc := &channeldb.HtlcAcceptDesc{
Amt: ctx.amtPaid,
Expiry: ctx.expiry,
AcceptHeight: ctx.currentHeight,
MppTotalAmt: ctx.mpp.TotalMsat(),
CustomRecords: ctx.customRecords,
}
if ctx.amp != nil {
acceptDesc.AMP = &channeldb.InvoiceHtlcAMPData{
Record: *ctx.amp,
Hash: ctx.hash,
Preimage: nil,
}
}
// Only accept payments to open invoices. This behaviour differs from
// non-mpp payments that are accepted even after the invoice is settled.
// Because non-mpp payments don't have a payment address, this is needed
// to thwart probing.
if inv.State != channeldb.ContractOpen {
return nil, ctx.failRes(ResultInvoiceNotOpen), nil
}
// Check the payment address that authorizes the payment.
if ctx.mpp.PaymentAddr() != inv.Terms.PaymentAddr {
return nil, ctx.failRes(ResultAddressMismatch), nil
}
// Don't accept zero-valued sets.
if ctx.mpp.TotalMsat() == 0 {
return nil, ctx.failRes(ResultHtlcSetTotalTooLow), nil
}
// Check that the total amt of the htlc set is high enough. In case this
// is a zero-valued invoice, it will always be enough.
if ctx.mpp.TotalMsat() < inv.Terms.Value {
return nil, ctx.failRes(ResultHtlcSetTotalTooLow), nil
}
htlcSet := inv.HTLCSet(setID)
// Check whether total amt matches other htlcs in the set.
var newSetTotal lnwire.MilliSatoshi
for _, htlc := range htlcSet {
// Only consider accepted mpp htlcs. It is possible that there
// are htlcs registered in the invoice database that previously
// timed out and are in the canceled state now.
if htlc.State != channeldb.HtlcStateAccepted {
continue
}
if ctx.mpp.TotalMsat() != htlc.MppTotalAmt {
return nil, ctx.failRes(ResultHtlcSetTotalMismatch), nil
}
newSetTotal += htlc.Amt
}
// Add amount of new htlc.
newSetTotal += ctx.amtPaid
// Make sure the communicated set total isn't overpaid.
if newSetTotal > ctx.mpp.TotalMsat() {
return nil, ctx.failRes(ResultHtlcSetOverpayment), nil
}
// The invoice is still open. Check the expiry.
if ctx.expiry < uint32(ctx.currentHeight+ctx.finalCltvRejectDelta) {
return nil, ctx.failRes(ResultExpiryTooSoon), nil
}
if ctx.expiry < uint32(ctx.currentHeight+inv.Terms.FinalCltvDelta) {
return nil, ctx.failRes(ResultExpiryTooSoon), nil
}
// Record HTLC in the invoice database.
newHtlcs := map[channeldb.CircuitKey]*channeldb.HtlcAcceptDesc{
ctx.circuitKey: acceptDesc,
}
update := channeldb.InvoiceUpdateDesc{
AddHtlcs: newHtlcs,
}
// If the invoice cannot be settled yet, only record the htlc.
setComplete := newSetTotal == ctx.mpp.TotalMsat()
if !setComplete {
return &update, ctx.acceptRes(resultPartialAccepted), nil
}
// Check to see if we can settle or this is an hold invoice and
// we need to wait for the preimage.
if inv.HodlInvoice {
update.State = &channeldb.InvoiceStateUpdateDesc{
NewState: channeldb.ContractAccepted,
SetID: setID,
}
return &update, ctx.acceptRes(resultAccepted), nil
}
var (
htlcPreimages map[channeldb.CircuitKey]lntypes.Preimage
htlcPreimage lntypes.Preimage
)
if ctx.amp != nil {
var failRes *HtlcFailResolution
htlcPreimages, failRes = reconstructAMPPreimages(ctx, htlcSet)
if failRes != nil {
update.State = &channeldb.InvoiceStateUpdateDesc{
NewState: channeldb.ContractCanceled,
SetID: setID,
}
return &update, failRes, nil
}
// The preimage for _this_ HTLC will be the one with context's
// circuit key.
htlcPreimage = htlcPreimages[ctx.circuitKey]
} else {
htlcPreimage = *inv.Terms.PaymentPreimage
}
update.State = &channeldb.InvoiceStateUpdateDesc{
NewState: channeldb.ContractSettled,
Preimage: inv.Terms.PaymentPreimage,
HTLCPreimages: htlcPreimages,
SetID: setID,
}
return &update, ctx.settleRes(htlcPreimage, ResultSettled), nil
}
// HTLCSet is a map of CircuitKey to InvoiceHTLC.
type HTLCSet = map[channeldb.CircuitKey]*channeldb.InvoiceHTLC
// HTLCPreimages is a map of CircuitKey to preimage.
type HTLCPreimages = map[channeldb.CircuitKey]lntypes.Preimage
// reconstructAMPPreimages reconstructs the root seed for an AMP HTLC set and
// verifies that all derived child hashes match the payment hashes of the HTLCs
// in the set. This method is meant to be called after receiving the full amount
// committed to via mpp_total_msat. This method will return a fail resolution if
// any of the child hashes fail to matche theire corresponding HTLCs.
func reconstructAMPPreimages(ctx *invoiceUpdateCtx,
htlcSet HTLCSet) (HTLCPreimages, *HtlcFailResolution) {
// Create a slice containing all the child descriptors to be used for
// reconstruction. This should include all HTLCs currently in the HTLC
// set, plus the incoming HTLC.
childDescs := make([]amp.ChildDesc, 0, 1+len(htlcSet))
// Add the new HTLC's child descriptor at index 0.
childDescs = append(childDescs, amp.ChildDesc{
Share: ctx.amp.RootShare(),
Index: ctx.amp.ChildIndex(),
})
// Next, construct an index mapping the position in childDescs to a
// circuit key for all preexisting HTLCs.
indexToCircuitKey := make(map[int]channeldb.CircuitKey)
// Add the child descriptor for each HTLC in the HTLC set, recording
// it's position within the slice.
var htlcSetIndex int
for circuitKey, htlc := range htlcSet {
childDescs = append(childDescs, amp.ChildDesc{
Share: htlc.AMP.Record.RootShare(),
Index: htlc.AMP.Record.ChildIndex(),
})
indexToCircuitKey[htlcSetIndex] = circuitKey
htlcSetIndex++
}
// Using the child descriptors, reconstruct the root seed and derive the
// child hash/preimage pairs for each of the HTLCs.
children := amp.ReconstructChildren(childDescs...)
// Validate that the derived child preimages match the hash of each
// HTLC's respective hash.
if ctx.hash != children[0].Hash {
return nil, ctx.failRes(ResultAmpReconstruction)
}
for idx, child := range children[1:] {
circuitKey := indexToCircuitKey[idx]
htlc := htlcSet[circuitKey]
if htlc.AMP.Hash != child.Hash {
return nil, ctx.failRes(ResultAmpReconstruction)
}
}
// Finally, construct the map of learned preimages indexed by circuit
// key, so that they can be persisted along with each HTLC when updating
// the invoice.
htlcPreimages := make(map[channeldb.CircuitKey]lntypes.Preimage)
htlcPreimages[ctx.circuitKey] = children[0].Preimage
for idx, child := range children[1:] {
circuitKey := indexToCircuitKey[idx]
htlcPreimages[circuitKey] = child.Preimage
}
return htlcPreimages, nil
}
// updateLegacy is a callback for DB.UpdateInvoice that contains the invoice
// settlement logic for legacy payments.
//
// NOTE: This function is only kept in place in order to be able to handle key
// send payments and any invoices we created in the past that are valid and
// still had the optional mpp bit set.
func updateLegacy(ctx *invoiceUpdateCtx,
inv *channeldb.Invoice) (*channeldb.InvoiceUpdateDesc, HtlcResolution, error) {
// If the invoice is already canceled, there is no further
// checking to do.
if inv.State == channeldb.ContractCanceled {
return nil, ctx.failRes(ResultInvoiceAlreadyCanceled), nil
}
// If an invoice amount is specified, check that enough is paid. Also
// check this for duplicate payments if the invoice is already settled
// or accepted. In case this is a zero-valued invoice, it will always be
// enough.
if ctx.amtPaid < inv.Terms.Value {
return nil, ctx.failRes(ResultAmountTooLow), nil
}
// If the invoice had the required feature bit set at this point, then
// if we're in this method it means that the remote party didn't supply
// the expected payload. However if this is a keysend payment, then
// we'll permit it to pass.
_, isKeySend := ctx.customRecords[record.KeySendType]
invoiceFeatures := inv.Terms.Features
paymentAddrRequired := invoiceFeatures.RequiresFeature(
lnwire.PaymentAddrRequired,
)
if !isKeySend && paymentAddrRequired {
log.Warnf("Payment to pay_hash=%v doesn't include MPP "+
"payload, rejecting", ctx.hash)
return nil, ctx.failRes(ResultAddressMismatch), nil
}
// Don't allow settling the invoice with an old style
// htlc if we are already in the process of gathering an
// mpp set.
for _, htlc := range inv.HTLCSet(nil) {
if htlc.MppTotalAmt > 0 {
return nil, ctx.failRes(ResultMppInProgress), nil
}
}
// The invoice is still open. Check the expiry.
if ctx.expiry < uint32(ctx.currentHeight+ctx.finalCltvRejectDelta) {
return nil, ctx.failRes(ResultExpiryTooSoon), nil
}
if ctx.expiry < uint32(ctx.currentHeight+inv.Terms.FinalCltvDelta) {
return nil, ctx.failRes(ResultExpiryTooSoon), nil
}
// Record HTLC in the invoice database.
newHtlcs := map[channeldb.CircuitKey]*channeldb.HtlcAcceptDesc{
ctx.circuitKey: {
Amt: ctx.amtPaid,
Expiry: ctx.expiry,
AcceptHeight: ctx.currentHeight,
CustomRecords: ctx.customRecords,
},
}
update := channeldb.InvoiceUpdateDesc{
AddHtlcs: newHtlcs,
}
// Don't update invoice state if we are accepting a duplicate payment.
// We do accept or settle the HTLC.
switch inv.State {
case channeldb.ContractAccepted:
return &update, ctx.acceptRes(resultDuplicateToAccepted), nil
case channeldb.ContractSettled:
return &update, ctx.settleRes(
*inv.Terms.PaymentPreimage, ResultDuplicateToSettled,
), nil
}
// Check to see if we can settle or this is an hold invoice and we need
// to wait for the preimage.
if inv.HodlInvoice {
update.State = &channeldb.InvoiceStateUpdateDesc{
NewState: channeldb.ContractAccepted,
}
return &update, ctx.acceptRes(resultAccepted), nil
}
update.State = &channeldb.InvoiceStateUpdateDesc{
NewState: channeldb.ContractSettled,
Preimage: inv.Terms.PaymentPreimage,
}
return &update, ctx.settleRes(
*inv.Terms.PaymentPreimage, ResultSettled,
), nil
}