lnd.xprv/lnwallet/wallet.go
Oliver Gugger 5a52420ab6
lnwallet+fundingmgr: interrupt funding flow for PSBT
In case the funding manager detects that a funding flow is requested
to be executed with the help of a PsbtIntent, the normal channel
negotiation with the remote peer is interrupted, as soon as the
accept_channel message was received. With the remote peer's funding
multisig key and our local key, we can derive the funding output
script and its address. This is enough to start the PSBT funding
and signing process which the user will do externally to the daemon.
2020-03-31 09:17:24 +02:00

1827 lines
60 KiB
Go

package lnwallet
import (
"bytes"
"crypto/sha256"
"errors"
"fmt"
"net"
"sync"
"sync/atomic"
"github.com/btcsuite/btcd/blockchain"
"github.com/btcsuite/btcd/btcec"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
"github.com/btcsuite/btcutil/psbt"
"github.com/btcsuite/btcutil/txsort"
"github.com/davecgh/go-spew/spew"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/input"
"github.com/lightningnetwork/lnd/keychain"
"github.com/lightningnetwork/lnd/lnwallet/chainfee"
"github.com/lightningnetwork/lnd/lnwallet/chanfunding"
"github.com/lightningnetwork/lnd/lnwallet/chanvalidate"
"github.com/lightningnetwork/lnd/lnwire"
"github.com/lightningnetwork/lnd/shachain"
)
const (
// The size of the buffered queue of requests to the wallet from the
// outside word.
msgBufferSize = 100
)
var (
// ErrPsbtFundingRequired is the error that is returned during the
// contribution handling process if the process should be paused for
// the construction of a PSBT outside of lnd's wallet.
ErrPsbtFundingRequired = errors.New("PSBT funding required")
)
// PsbtFundingRequired is a type that implements the error interface and
// contains the information needed to construct a PSBT.
type PsbtFundingRequired struct {
// Intent is the pending PSBT funding intent that needs to be funded
// if the wrapping error is returned.
Intent *chanfunding.PsbtIntent
}
// Error returns the underlying error.
//
// NOTE: This method is part of the error interface.
func (p *PsbtFundingRequired) Error() string {
return ErrPsbtFundingRequired.Error()
}
// InitFundingReserveMsg is the first message sent to initiate the workflow
// required to open a payment channel with a remote peer. The initial required
// parameters are configurable across channels. These parameters are to be
// chosen depending on the fee climate within the network, and time value of
// funds to be locked up within the channel. Upon success a ChannelReservation
// will be created in order to track the lifetime of this pending channel.
// Outputs selected will be 'locked', making them unavailable, for any other
// pending reservations. Therefore, all channels in reservation limbo will be
// periodically timed out after an idle period in order to avoid "exhaustion"
// attacks.
type InitFundingReserveMsg struct {
// ChainHash denotes that chain to be used to ultimately open the
// target channel.
ChainHash *chainhash.Hash
// PendingChanID is the pending channel ID for this funding flow as
// used in the wire protocol.
PendingChanID [32]byte
// NodeID is the ID of the remote node we would like to open a channel
// with.
NodeID *btcec.PublicKey
// NodeAddr is the address port that we used to either establish or
// accept the connection which led to the negotiation of this funding
// workflow.
NodeAddr net.Addr
// SubtractFees should be set if we intend to spend exactly
// LocalFundingAmt when opening the channel, subtracting the fees from
// the funding output. This can be used for instance to use all our
// remaining funds to open the channel, since it will take fees into
// account.
SubtractFees bool
// LocalFundingAmt is the amount of funds requested from us for this
// channel.
LocalFundingAmt btcutil.Amount
// RemoteFundingAmnt is the amount of funds the remote will contribute
// to this channel.
RemoteFundingAmt btcutil.Amount
// CommitFeePerKw is the starting accepted satoshis/Kw fee for the set
// of initial commitment transactions. In order to ensure timely
// confirmation, it is recommended that this fee should be generous,
// paying some multiple of the accepted base fee rate of the network.
CommitFeePerKw chainfee.SatPerKWeight
// FundingFeePerKw is the fee rate in sat/kw to use for the initial
// funding transaction.
FundingFeePerKw chainfee.SatPerKWeight
// PushMSat is the number of milli-satoshis that should be pushed over
// the responder as part of the initial channel creation.
PushMSat lnwire.MilliSatoshi
// Flags are the channel flags specified by the initiator in the
// open_channel message.
Flags lnwire.FundingFlag
// MinConfs indicates the minimum number of confirmations that each
// output selected to fund the channel should satisfy.
MinConfs int32
// CommitType indicates what type of commitment type the channel should
// be using, like tweakless or anchors.
CommitType CommitmentType
// ChanFunder is an optional channel funder that allows the caller to
// control exactly how the channel funding is carried out. If not
// specified, then the default chanfunding.WalletAssembler will be
// used.
ChanFunder chanfunding.Assembler
// err is a channel in which all errors will be sent across. Will be
// nil if this initial set is successful.
//
// NOTE: In order to avoid deadlocks, this channel MUST be buffered.
err chan error
// resp is channel in which a ChannelReservation with our contributions
// filled in will be sent across this channel in the case of a
// successfully reservation initiation. In the case of an error, this
// will read a nil pointer.
//
// NOTE: In order to avoid deadlocks, this channel MUST be buffered.
resp chan *ChannelReservation
}
// fundingReserveCancelMsg is a message reserved for cancelling an existing
// channel reservation identified by its reservation ID. Cancelling a reservation
// frees its locked outputs up, for inclusion within further reservations.
type fundingReserveCancelMsg struct {
pendingFundingID uint64
// NOTE: In order to avoid deadlocks, this channel MUST be buffered.
err chan error // Buffered
}
// addContributionMsg represents a message executing the second phase of the
// channel reservation workflow. This message carries the counterparty's
// "contribution" to the payment channel. In the case that this message is
// processed without generating any errors, then channel reservation will then
// be able to construct the funding tx, both commitment transactions, and
// finally generate signatures for all our inputs to the funding transaction,
// and for the remote node's version of the commitment transaction.
type addContributionMsg struct {
pendingFundingID uint64
// TODO(roasbeef): Should also carry SPV proofs in we're in SPV mode
contribution *ChannelContribution
// NOTE: In order to avoid deadlocks, this channel MUST be buffered.
err chan error
}
// continueContributionMsg represents a message that signals that the
// interrupted funding process involving a PSBT can now be continued because the
// finalized transaction is now available.
type continueContributionMsg struct {
pendingFundingID uint64
// NOTE: In order to avoid deadlocks, this channel MUST be buffered.
err chan error
}
// addSingleContributionMsg represents a message executing the second phase of
// a single funder channel reservation workflow. This messages carries the
// counterparty's "contribution" to the payment channel. As this message is
// sent when on the responding side to a single funder workflow, no further
// action apart from storing the provided contribution is carried out.
type addSingleContributionMsg struct {
pendingFundingID uint64
contribution *ChannelContribution
// NOTE: In order to avoid deadlocks, this channel MUST be buffered.
err chan error
}
// addCounterPartySigsMsg represents the final message required to complete,
// and 'open' a payment channel. This message carries the counterparty's
// signatures for each of their inputs to the funding transaction, and also a
// signature allowing us to spend our version of the commitment transaction.
// If we're able to verify all the signatures are valid, the funding transaction
// will be broadcast to the network. After the funding transaction gains a
// configurable number of confirmations, the channel is officially considered
// 'open'.
type addCounterPartySigsMsg struct {
pendingFundingID uint64
// Should be order of sorted inputs that are theirs. Sorting is done
// in accordance to BIP-69:
// https://github.com/bitcoin/bips/blob/master/bip-0069.mediawiki.
theirFundingInputScripts []*input.Script
// This should be 1/2 of the signatures needed to successfully spend our
// version of the commitment transaction.
theirCommitmentSig []byte
// This channel is used to return the completed channel after the wallet
// has completed all of its stages in the funding process.
completeChan chan *channeldb.OpenChannel
// NOTE: In order to avoid deadlocks, this channel MUST be buffered.
err chan error
}
// addSingleFunderSigsMsg represents the next-to-last message required to
// complete a single-funder channel workflow. Once the initiator is able to
// construct the funding transaction, they send both the outpoint and a
// signature for our version of the commitment transaction. Once this message
// is processed we (the responder) are able to construct both commitment
// transactions, signing the remote party's version.
type addSingleFunderSigsMsg struct {
pendingFundingID uint64
// fundingOutpoint is the outpoint of the completed funding
// transaction as assembled by the workflow initiator.
fundingOutpoint *wire.OutPoint
// theirCommitmentSig are the 1/2 of the signatures needed to
// successfully spend our version of the commitment transaction.
theirCommitmentSig []byte
// This channel is used to return the completed channel after the wallet
// has completed all of its stages in the funding process.
completeChan chan *channeldb.OpenChannel
// NOTE: In order to avoid deadlocks, this channel MUST be buffered.
err chan error
}
// LightningWallet is a domain specific, yet general Bitcoin wallet capable of
// executing workflow required to interact with the Lightning Network. It is
// domain specific in the sense that it understands all the fancy scripts used
// within the Lightning Network, channel lifetimes, etc. However, it embeds a
// general purpose Bitcoin wallet within it. Therefore, it is also able to
// serve as a regular Bitcoin wallet which uses HD keys. The wallet is highly
// concurrent internally. All communication, and requests towards the wallet
// are dispatched as messages over channels, ensuring thread safety across all
// operations. Interaction has been designed independent of any peer-to-peer
// communication protocol, allowing the wallet to be self-contained and
// embeddable within future projects interacting with the Lightning Network.
//
// NOTE: At the moment the wallet requires a btcd full node, as it's dependent
// on btcd's websockets notifications as event triggers during the lifetime of a
// channel. However, once the chainntnfs package is complete, the wallet will
// be compatible with multiple RPC/notification services such as Electrum,
// Bitcoin Core + ZeroMQ, etc. Eventually, the wallet won't require a full-node
// at all, as SPV support is integrated into btcwallet.
type LightningWallet struct {
started int32 // To be used atomically.
shutdown int32 // To be used atomically.
nextFundingID uint64 // To be used atomically.
// Cfg is the configuration struct that will be used by the wallet to
// access the necessary interfaces and default it needs to carry on its
// duties.
Cfg Config
// WalletController is the core wallet, all non Lightning Network
// specific interaction is proxied to the internal wallet.
WalletController
// SecretKeyRing is the interface we'll use to derive any keys related
// to our purpose within the network including: multi-sig keys, node
// keys, revocation keys, etc.
keychain.SecretKeyRing
// This mutex MUST be held when performing coin selection in order to
// avoid inadvertently creating multiple funding transaction which
// double spend inputs across each other.
coinSelectMtx sync.RWMutex
// All messages to the wallet are to be sent across this channel.
msgChan chan interface{}
// Incomplete payment channels are stored in the map below. An intent
// to create a payment channel is tracked as a "reservation" within
// limbo. Once the final signatures have been exchanged, a reservation
// is removed from limbo. Each reservation is tracked by a unique
// monotonically integer. All requests concerning the channel MUST
// carry a valid, active funding ID.
fundingLimbo map[uint64]*ChannelReservation
limboMtx sync.RWMutex
// lockedOutPoints is a set of the currently locked outpoint. This
// information is kept in order to provide an easy way to unlock all
// the currently locked outpoints.
lockedOutPoints map[wire.OutPoint]struct{}
// fundingIntents houses all the "interception" registered by a caller
// using the RegisterFundingIntent method.
intentMtx sync.RWMutex
fundingIntents map[[32]byte]chanfunding.Intent
quit chan struct{}
wg sync.WaitGroup
// TODO(roasbeef): handle wallet lock/unlock
}
// NewLightningWallet creates/opens and initializes a LightningWallet instance.
// If the wallet has never been created (according to the passed dataDir), first-time
// setup is executed.
func NewLightningWallet(Cfg Config) (*LightningWallet, error) {
return &LightningWallet{
Cfg: Cfg,
SecretKeyRing: Cfg.SecretKeyRing,
WalletController: Cfg.WalletController,
msgChan: make(chan interface{}, msgBufferSize),
nextFundingID: 0,
fundingLimbo: make(map[uint64]*ChannelReservation),
lockedOutPoints: make(map[wire.OutPoint]struct{}),
fundingIntents: make(map[[32]byte]chanfunding.Intent),
quit: make(chan struct{}),
}, nil
}
// Startup establishes a connection to the RPC source, and spins up all
// goroutines required to handle incoming messages.
func (l *LightningWallet) Startup() error {
// Already started?
if atomic.AddInt32(&l.started, 1) != 1 {
return nil
}
// Start the underlying wallet controller.
if err := l.Start(); err != nil {
return err
}
l.wg.Add(1)
// TODO(roasbeef): multiple request handlers?
go l.requestHandler()
return nil
}
// Shutdown gracefully stops the wallet, and all active goroutines.
func (l *LightningWallet) Shutdown() error {
if atomic.AddInt32(&l.shutdown, 1) != 1 {
return nil
}
// Signal the underlying wallet controller to shutdown, waiting until
// all active goroutines have been shutdown.
if err := l.Stop(); err != nil {
return err
}
close(l.quit)
l.wg.Wait()
return nil
}
// LockedOutpoints returns a list of all currently locked outpoint.
func (l *LightningWallet) LockedOutpoints() []*wire.OutPoint {
outPoints := make([]*wire.OutPoint, 0, len(l.lockedOutPoints))
for outPoint := range l.lockedOutPoints {
outPoint := outPoint
outPoints = append(outPoints, &outPoint)
}
return outPoints
}
// ResetReservations reset the volatile wallet state which tracks all currently
// active reservations.
func (l *LightningWallet) ResetReservations() {
l.nextFundingID = 0
l.fundingLimbo = make(map[uint64]*ChannelReservation)
for outpoint := range l.lockedOutPoints {
l.UnlockOutpoint(outpoint)
}
l.lockedOutPoints = make(map[wire.OutPoint]struct{})
}
// ActiveReservations returns a slice of all the currently active
// (non-canceled) reservations.
func (l *LightningWallet) ActiveReservations() []*ChannelReservation {
reservations := make([]*ChannelReservation, 0, len(l.fundingLimbo))
for _, reservation := range l.fundingLimbo {
reservations = append(reservations, reservation)
}
return reservations
}
// requestHandler is the primary goroutine(s) responsible for handling, and
// dispatching replies to all messages.
func (l *LightningWallet) requestHandler() {
out:
for {
select {
case m := <-l.msgChan:
switch msg := m.(type) {
case *InitFundingReserveMsg:
l.handleFundingReserveRequest(msg)
case *fundingReserveCancelMsg:
l.handleFundingCancelRequest(msg)
case *addSingleContributionMsg:
l.handleSingleContribution(msg)
case *addContributionMsg:
l.handleContributionMsg(msg)
case *continueContributionMsg:
l.handleChanPointReady(msg)
case *addSingleFunderSigsMsg:
l.handleSingleFunderSigs(msg)
case *addCounterPartySigsMsg:
l.handleFundingCounterPartySigs(msg)
}
case <-l.quit:
// TODO: do some clean up
break out
}
}
l.wg.Done()
}
// InitChannelReservation kicks off the 3-step workflow required to successfully
// open a payment channel with a remote node. As part of the funding
// reservation, the inputs selected for the funding transaction are 'locked'.
// This ensures that multiple channel reservations aren't double spending the
// same inputs in the funding transaction. If reservation initialization is
// successful, a ChannelReservation containing our completed contribution is
// returned. Our contribution contains all the items necessary to allow the
// counterparty to build the funding transaction, and both versions of the
// commitment transaction. Otherwise, an error occurred and a nil pointer along
// with an error are returned.
//
// Once a ChannelReservation has been obtained, two additional steps must be
// processed before a payment channel can be considered 'open'. The second step
// validates, and processes the counterparty's channel contribution. The third,
// and final step verifies all signatures for the inputs of the funding
// transaction, and that the signature we record for our version of the
// commitment transaction is valid.
func (l *LightningWallet) InitChannelReservation(
req *InitFundingReserveMsg) (*ChannelReservation, error) {
req.resp = make(chan *ChannelReservation, 1)
req.err = make(chan error, 1)
select {
case l.msgChan <- req:
case <-l.quit:
return nil, errors.New("wallet shutting down")
}
return <-req.resp, <-req.err
}
// RegisterFundingIntent allows a caller to signal to the wallet that if a
// pending channel ID of expectedID is found, then it can skip constructing a
// new chanfunding.Assembler, and instead use the specified chanfunding.Intent.
// As an example, this lets some of the parameters for funding transaction to
// be negotiated outside the regular funding protocol.
func (l *LightningWallet) RegisterFundingIntent(expectedID [32]byte,
shimIntent chanfunding.Intent) error {
l.intentMtx.Lock()
defer l.intentMtx.Unlock()
if _, ok := l.fundingIntents[expectedID]; ok {
return fmt.Errorf("pendingChanID(%x) already has intent "+
"registered", expectedID[:])
}
l.fundingIntents[expectedID] = shimIntent
return nil
}
// PsbtFundingVerify looks up a previously registered funding intent by its
// pending channel ID and tries to advance the state machine by verifying the
// passed PSBT.
func (l *LightningWallet) PsbtFundingVerify(pid [32]byte,
packet *psbt.Packet) error {
l.intentMtx.Lock()
defer l.intentMtx.Unlock()
intent, ok := l.fundingIntents[pid]
if !ok {
return fmt.Errorf("no funding intent found for "+
"pendingChannelID(%x)", pid[:])
}
psbtIntent, ok := intent.(*chanfunding.PsbtIntent)
if !ok {
return fmt.Errorf("incompatible funding intent")
}
err := psbtIntent.Verify(packet)
if err != nil {
return fmt.Errorf("error verifying PSBT: %v", err)
}
return nil
}
// PsbtFundingFinalize looks up a previously registered funding intent by its
// pending channel ID and tries to advance the state machine by finalizing the
// passed PSBT.
func (l *LightningWallet) PsbtFundingFinalize(pid [32]byte,
packet *psbt.Packet) error {
l.intentMtx.Lock()
defer l.intentMtx.Unlock()
intent, ok := l.fundingIntents[pid]
if !ok {
return fmt.Errorf("no funding intent found for "+
"pendingChannelID(%x)", pid[:])
}
psbtIntent, ok := intent.(*chanfunding.PsbtIntent)
if !ok {
return fmt.Errorf("incompatible funding intent")
}
err := psbtIntent.Finalize(packet)
if err != nil {
return fmt.Errorf("error finalizing PSBT: %v", err)
}
return nil
}
// CancelFundingIntent allows a caller to cancel a previously registered
// funding intent. If no intent was found, then an error will be returned.
func (l *LightningWallet) CancelFundingIntent(pid [32]byte) error {
l.intentMtx.Lock()
defer l.intentMtx.Unlock()
intent, ok := l.fundingIntents[pid]
if !ok {
return fmt.Errorf("no funding intent found for "+
"pendingChannelID(%x)", pid[:])
}
// Give the intent a chance to clean up after itself, removing coin
// locks or similar reserved resources.
intent.Cancel()
delete(l.fundingIntents, pid)
return nil
}
// handleFundingReserveRequest processes a message intending to create, and
// validate a funding reservation request.
func (l *LightningWallet) handleFundingReserveRequest(req *InitFundingReserveMsg) {
// It isn't possible to create a channel with zero funds committed.
if req.LocalFundingAmt+req.RemoteFundingAmt == 0 {
err := ErrZeroCapacity()
req.err <- err
req.resp <- nil
return
}
// If the funding request is for a different chain than the one the
// wallet is aware of, then we'll reject the request.
if !bytes.Equal(l.Cfg.NetParams.GenesisHash[:], req.ChainHash[:]) {
err := ErrChainMismatch(
l.Cfg.NetParams.GenesisHash, req.ChainHash,
)
req.err <- err
req.resp <- nil
return
}
// If no chanFunder was provided, then we'll assume the default
// assembler, which is backed by the wallet's internal coin selection.
if req.ChanFunder == nil {
cfg := chanfunding.WalletConfig{
CoinSource: &CoinSource{l},
CoinSelectLocker: l,
CoinLocker: l,
Signer: l.Cfg.Signer,
DustLimit: DefaultDustLimit(),
}
req.ChanFunder = chanfunding.NewWalletAssembler(cfg)
}
localFundingAmt := req.LocalFundingAmt
remoteFundingAmt := req.RemoteFundingAmt
var (
fundingIntent chanfunding.Intent
err error
)
// If we've just received an inbound funding request that we have a
// registered shim intent to, then we'll obtain the backing intent now.
// In this case, we're doing a special funding workflow that allows
// more advanced constructions such as channel factories to be
// instantiated.
l.intentMtx.Lock()
fundingIntent, ok := l.fundingIntents[req.PendingChanID]
l.intentMtx.Unlock()
// Otherwise, this is a normal funding flow, so we'll use the chan
// funder in the attached request to provision the inputs/outputs
// that'll ultimately be used to construct the funding transaction.
if !ok {
// Coin selection is done on the basis of sat/kw, so we'll use
// the fee rate passed in to perform coin selection.
var err error
fundingReq := &chanfunding.Request{
RemoteAmt: req.RemoteFundingAmt,
LocalAmt: req.LocalFundingAmt,
MinConfs: req.MinConfs,
SubtractFees: req.SubtractFees,
FeeRate: req.FundingFeePerKw,
ChangeAddr: func() (btcutil.Address, error) {
return l.NewAddress(WitnessPubKey, true)
},
}
fundingIntent, err = req.ChanFunder.ProvisionChannel(
fundingReq,
)
if err != nil {
req.err <- err
req.resp <- nil
return
}
// Register the funding intent now in case we need to access it
// again later, as it's the case for the PSBT state machine for
// example.
err = l.RegisterFundingIntent(req.PendingChanID, fundingIntent)
if err != nil {
req.err <- err
req.resp <- nil
return
}
localFundingAmt = fundingIntent.LocalFundingAmt()
remoteFundingAmt = fundingIntent.RemoteFundingAmt()
}
// At this point there _has_ to be a funding intent, otherwise something
// went really wrong.
if fundingIntent == nil {
req.err <- fmt.Errorf("no funding intent present")
req.resp <- nil
return
}
// If this is a shim intent, then it may be attempting to use an
// existing set of keys for the funding workflow. In this case, we'll
// make a simple wrapper keychain.KeyRing that will proxy certain
// derivation calls to future callers.
var (
keyRing keychain.KeyRing = l.SecretKeyRing
thawHeight uint32
)
if shimIntent, ok := fundingIntent.(*chanfunding.ShimIntent); ok {
keyRing = &shimKeyRing{
KeyRing: keyRing,
ShimIntent: shimIntent,
}
// As this was a registered shim intent, we'll obtain the thaw
// height of the intent, if present at all. If this is
// non-zero, then we'll mark this as the proper channel type.
thawHeight = shimIntent.ThawHeight()
}
// The total channel capacity will be the size of the funding output we
// created plus the remote contribution.
capacity := localFundingAmt + remoteFundingAmt
id := atomic.AddUint64(&l.nextFundingID, 1)
reservation, err := NewChannelReservation(
capacity, localFundingAmt, req.CommitFeePerKw, l, id,
req.PushMSat, l.Cfg.NetParams.GenesisHash, req.Flags,
req.CommitType, req.ChanFunder, req.PendingChanID,
thawHeight,
)
if err != nil {
fundingIntent.Cancel()
req.err <- err
req.resp <- nil
return
}
err = l.initOurContribution(
reservation, fundingIntent, req.NodeAddr, req.NodeID, keyRing,
)
if err != nil {
fundingIntent.Cancel()
req.err <- err
req.resp <- nil
return
}
// Create a limbo and record entry for this newly pending funding
// request.
l.limboMtx.Lock()
l.fundingLimbo[id] = reservation
l.limboMtx.Unlock()
// Funding reservation request successfully handled. The funding inputs
// will be marked as unavailable until the reservation is either
// completed, or canceled.
req.resp <- reservation
req.err <- nil
}
// initOurContribution initializes the given ChannelReservation with our coins
// and change reserved for the channel, and derives the keys to use for this
// channel.
func (l *LightningWallet) initOurContribution(reservation *ChannelReservation,
fundingIntent chanfunding.Intent, nodeAddr net.Addr,
nodeID *btcec.PublicKey, keyRing keychain.KeyRing) error {
// Grab the mutex on the ChannelReservation to ensure thread-safety
reservation.Lock()
defer reservation.Unlock()
// At this point, if we have a funding intent, we'll use it to populate
// the existing reservation state entries for our coin selection.
if fundingIntent != nil {
if intent, ok := fundingIntent.(*chanfunding.FullIntent); ok {
for _, coin := range intent.InputCoins {
reservation.ourContribution.Inputs = append(
reservation.ourContribution.Inputs,
&wire.TxIn{
PreviousOutPoint: coin.OutPoint,
},
)
}
reservation.ourContribution.ChangeOutputs = intent.ChangeOutputs
}
reservation.fundingIntent = fundingIntent
}
reservation.nodeAddr = nodeAddr
reservation.partialState.IdentityPub = nodeID
var err error
reservation.ourContribution.MultiSigKey, err = keyRing.DeriveNextKey(
keychain.KeyFamilyMultiSig,
)
if err != nil {
return err
}
reservation.ourContribution.RevocationBasePoint, err = keyRing.DeriveNextKey(
keychain.KeyFamilyRevocationBase,
)
if err != nil {
return err
}
reservation.ourContribution.HtlcBasePoint, err = keyRing.DeriveNextKey(
keychain.KeyFamilyHtlcBase,
)
if err != nil {
return err
}
reservation.ourContribution.PaymentBasePoint, err = keyRing.DeriveNextKey(
keychain.KeyFamilyPaymentBase,
)
if err != nil {
return err
}
reservation.ourContribution.DelayBasePoint, err = keyRing.DeriveNextKey(
keychain.KeyFamilyDelayBase,
)
if err != nil {
return err
}
// With the above keys created, we'll also need to initialization our
// initial revocation tree state.
nextRevocationKeyDesc, err := keyRing.DeriveNextKey(
keychain.KeyFamilyRevocationRoot,
)
if err != nil {
return err
}
revocationRoot, err := l.DerivePrivKey(nextRevocationKeyDesc)
if err != nil {
return err
}
// Once we have the root, we can then generate our shachain producer
// and from that generate the per-commitment point.
revRoot, err := chainhash.NewHash(revocationRoot.Serialize())
if err != nil {
return err
}
producer := shachain.NewRevocationProducer(*revRoot)
firstPreimage, err := producer.AtIndex(0)
if err != nil {
return err
}
reservation.ourContribution.FirstCommitmentPoint = input.ComputeCommitmentPoint(
firstPreimage[:],
)
reservation.partialState.RevocationProducer = producer
reservation.ourContribution.ChannelConstraints = l.Cfg.DefaultConstraints
return nil
}
// handleFundingReserveCancel cancels an existing channel reservation. As part
// of the cancellation, outputs previously selected as inputs for the funding
// transaction via coin selection are freed allowing future reservations to
// include them.
func (l *LightningWallet) handleFundingCancelRequest(req *fundingReserveCancelMsg) {
// TODO(roasbeef): holding lock too long
l.limboMtx.Lock()
defer l.limboMtx.Unlock()
pendingReservation, ok := l.fundingLimbo[req.pendingFundingID]
if !ok {
// TODO(roasbeef): make new error, "unknown funding state" or something
req.err <- fmt.Errorf("attempted to cancel non-existent funding state")
return
}
// Grab the mutex on the ChannelReservation to ensure thread-safety
pendingReservation.Lock()
defer pendingReservation.Unlock()
// Mark all previously locked outpoints as useable for future funding
// requests.
for _, unusedInput := range pendingReservation.ourContribution.Inputs {
delete(l.lockedOutPoints, unusedInput.PreviousOutPoint)
l.UnlockOutpoint(unusedInput.PreviousOutPoint)
}
// TODO(roasbeef): is it even worth it to keep track of unused keys?
// TODO(roasbeef): Is it possible to mark the unused change also as
// available?
delete(l.fundingLimbo, req.pendingFundingID)
pid := pendingReservation.pendingChanID
l.intentMtx.Lock()
if intent, ok := l.fundingIntents[pid]; ok {
intent.Cancel()
delete(l.fundingIntents, pendingReservation.pendingChanID)
}
l.intentMtx.Unlock()
req.err <- nil
}
// CreateCommitmentTxns is a helper function that creates the initial
// commitment transaction for both parties. This function is used during the
// initial funding workflow as both sides must generate a signature for the
// remote party's commitment transaction, and verify the signature for their
// version of the commitment transaction.
func CreateCommitmentTxns(localBalance, remoteBalance btcutil.Amount,
ourChanCfg, theirChanCfg *channeldb.ChannelConfig,
localCommitPoint, remoteCommitPoint *btcec.PublicKey,
fundingTxIn wire.TxIn, chanType channeldb.ChannelType) (
*wire.MsgTx, *wire.MsgTx, error) {
localCommitmentKeys := DeriveCommitmentKeys(
localCommitPoint, true, chanType, ourChanCfg, theirChanCfg,
)
remoteCommitmentKeys := DeriveCommitmentKeys(
remoteCommitPoint, false, chanType, ourChanCfg, theirChanCfg,
)
ourCommitTx, err := CreateCommitTx(
chanType, fundingTxIn, localCommitmentKeys, ourChanCfg,
theirChanCfg, localBalance, remoteBalance, 0,
)
if err != nil {
return nil, nil, err
}
otxn := btcutil.NewTx(ourCommitTx)
if err := blockchain.CheckTransactionSanity(otxn); err != nil {
return nil, nil, err
}
theirCommitTx, err := CreateCommitTx(
chanType, fundingTxIn, remoteCommitmentKeys, theirChanCfg,
ourChanCfg, remoteBalance, localBalance, 0,
)
if err != nil {
return nil, nil, err
}
ttxn := btcutil.NewTx(theirCommitTx)
if err := blockchain.CheckTransactionSanity(ttxn); err != nil {
return nil, nil, err
}
return ourCommitTx, theirCommitTx, nil
}
// handleContributionMsg processes the second workflow step for the lifetime of
// a channel reservation. Upon completion, the reservation will carry a
// completed funding transaction (minus the counterparty's input signatures),
// both versions of the commitment transaction, and our signature for their
// version of the commitment transaction.
func (l *LightningWallet) handleContributionMsg(req *addContributionMsg) {
l.limboMtx.Lock()
pendingReservation, ok := l.fundingLimbo[req.pendingFundingID]
l.limboMtx.Unlock()
if !ok {
req.err <- fmt.Errorf("attempted to update non-existent funding state")
return
}
// Grab the mutex on the ChannelReservation to ensure thread-safety
pendingReservation.Lock()
defer pendingReservation.Unlock()
// Some temporary variables to cut down on the resolution verbosity.
pendingReservation.theirContribution = req.contribution
theirContribution := req.contribution
ourContribution := pendingReservation.ourContribution
var (
chanPoint *wire.OutPoint
err error
)
// At this point, we can now construct our channel point. Depending on
// which type of intent we obtained from our chanfunding.Assembler,
// we'll carry out a distinct set of steps.
switch fundingIntent := pendingReservation.fundingIntent.(type) {
// The transaction was created outside of the wallet and might already
// be published. Nothing left to do other than using the correct
// outpoint.
case *chanfunding.ShimIntent:
chanPoint, err = fundingIntent.ChanPoint()
if err != nil {
req.err <- fmt.Errorf("unable to obtain chan point: %v", err)
return
}
pendingReservation.partialState.FundingOutpoint = *chanPoint
// The user has signaled that they want to use a PSBT to construct the
// funding transaction. Because we now have the multisig keys from both
// parties, we can create the multisig script that needs to be funded
// and then pause the process until the user supplies the PSBT
// containing the eventual funding transaction.
case *chanfunding.PsbtIntent:
if fundingIntent.PendingPsbt != nil {
req.err <- fmt.Errorf("PSBT funding already in" +
"progress")
return
}
// Now that we know our contribution, we can bind both the local
// and remote key which will be needed to calculate the multisig
// funding output in a next step.
pendingChanID := pendingReservation.pendingChanID
walletLog.Debugf("Advancing PSBT funding flow for "+
"pending_id(%x), binding keys local_key=%v, "+
"remote_key=%x", pendingChanID,
&ourContribution.MultiSigKey,
theirContribution.MultiSigKey.PubKey.SerializeCompressed())
fundingIntent.BindKeys(
&ourContribution.MultiSigKey,
theirContribution.MultiSigKey.PubKey,
)
// Exit early because we can't continue the funding flow yet.
req.err <- &PsbtFundingRequired{
Intent: fundingIntent,
}
return
case *chanfunding.FullIntent:
// Now that we know their public key, we can bind theirs as
// well as ours to the funding intent.
fundingIntent.BindKeys(
&pendingReservation.ourContribution.MultiSigKey,
theirContribution.MultiSigKey.PubKey,
)
// With our keys bound, we can now construct+sign the final
// funding transaction and also obtain the chanPoint that
// creates the channel.
fundingTx, err := fundingIntent.CompileFundingTx(
theirContribution.Inputs,
theirContribution.ChangeOutputs,
)
if err != nil {
req.err <- fmt.Errorf("unable to construct funding "+
"tx: %v", err)
return
}
chanPoint, err = fundingIntent.ChanPoint()
if err != nil {
req.err <- fmt.Errorf("unable to obtain chan "+
"point: %v", err)
return
}
// Finally, we'll populate the relevant information in our
// pendingReservation so the rest of the funding flow can
// continue as normal.
pendingReservation.fundingTx = fundingTx
pendingReservation.partialState.FundingOutpoint = *chanPoint
pendingReservation.ourFundingInputScripts = make(
[]*input.Script, 0, len(ourContribution.Inputs),
)
for _, txIn := range fundingTx.TxIn {
_, err := l.FetchInputInfo(&txIn.PreviousOutPoint)
if err != nil {
continue
}
pendingReservation.ourFundingInputScripts = append(
pendingReservation.ourFundingInputScripts,
&input.Script{
Witness: txIn.Witness,
SigScript: txIn.SignatureScript,
},
)
}
walletLog.Debugf("Funding tx for ChannelPoint(%v) "+
"generated: %v", chanPoint, spew.Sdump(fundingTx))
}
// If we landed here and didn't exit early, it means we already have
// the channel point ready. We can jump directly to the next step.
l.handleChanPointReady(&continueContributionMsg{
pendingFundingID: req.pendingFundingID,
err: req.err,
})
}
// handleChanPointReady continues the funding process once the channel point
// is known and the funding transaction can be completed.
func (l *LightningWallet) handleChanPointReady(req *continueContributionMsg) {
l.limboMtx.Lock()
pendingReservation, ok := l.fundingLimbo[req.pendingFundingID]
l.limboMtx.Unlock()
if !ok {
req.err <- fmt.Errorf("attempted to update non-existent " +
"funding state")
return
}
ourContribution := pendingReservation.ourContribution
theirContribution := pendingReservation.theirContribution
chanPoint := pendingReservation.partialState.FundingOutpoint
// If we're in the PSBT funding flow, we now should have everything that
// is needed to construct and publish the full funding transaction.
intent := pendingReservation.fundingIntent
if psbtIntent, ok := intent.(*chanfunding.PsbtIntent); ok {
// With our keys bound, we can now construct+sign the final
// funding transaction and also obtain the chanPoint that
// creates the channel.
fundingTx, err := psbtIntent.CompileFundingTx()
if err != nil {
req.err <- fmt.Errorf("unable to construct funding "+
"tx: %v", err)
return
}
chanPointPtr, err := psbtIntent.ChanPoint()
if err != nil {
req.err <- fmt.Errorf("unable to obtain chan "+
"point: %v", err)
return
}
// Finally, we'll populate the relevant information in our
// pendingReservation so the rest of the funding flow can
// continue as normal.
pendingReservation.fundingTx = fundingTx
pendingReservation.partialState.FundingOutpoint = *chanPointPtr
chanPoint = *chanPointPtr
pendingReservation.ourFundingInputScripts = make(
[]*input.Script, 0, len(ourContribution.Inputs),
)
for _, txIn := range fundingTx.TxIn {
pendingReservation.ourFundingInputScripts = append(
pendingReservation.ourFundingInputScripts,
&input.Script{
Witness: txIn.Witness,
SigScript: txIn.SignatureScript,
},
)
}
}
// Initialize an empty sha-chain for them, tracking the current pending
// revocation hash (we don't yet know the preimage so we can't add it
// to the chain).
s := shachain.NewRevocationStore()
pendingReservation.partialState.RevocationStore = s
// Store their current commitment point. We'll need this after the
// first state transition in order to verify the authenticity of the
// revocation.
chanState := pendingReservation.partialState
chanState.RemoteCurrentRevocation = theirContribution.FirstCommitmentPoint
// Create the txin to our commitment transaction; required to construct
// the commitment transactions.
fundingTxIn := wire.TxIn{
PreviousOutPoint: chanPoint,
}
// With the funding tx complete, create both commitment transactions.
localBalance := pendingReservation.partialState.LocalCommitment.LocalBalance.ToSatoshis()
remoteBalance := pendingReservation.partialState.LocalCommitment.RemoteBalance.ToSatoshis()
ourCommitTx, theirCommitTx, err := CreateCommitmentTxns(
localBalance, remoteBalance, ourContribution.ChannelConfig,
theirContribution.ChannelConfig,
ourContribution.FirstCommitmentPoint,
theirContribution.FirstCommitmentPoint, fundingTxIn,
pendingReservation.partialState.ChanType,
)
if err != nil {
req.err <- err
return
}
// With both commitment transactions constructed, generate the state
// obfuscator then use it to encode the current state number within
// both commitment transactions.
var stateObfuscator [StateHintSize]byte
if chanState.ChanType.IsSingleFunder() {
stateObfuscator = DeriveStateHintObfuscator(
ourContribution.PaymentBasePoint.PubKey,
theirContribution.PaymentBasePoint.PubKey,
)
} else {
ourSer := ourContribution.PaymentBasePoint.PubKey.SerializeCompressed()
theirSer := theirContribution.PaymentBasePoint.PubKey.SerializeCompressed()
switch bytes.Compare(ourSer, theirSer) {
case -1:
stateObfuscator = DeriveStateHintObfuscator(
ourContribution.PaymentBasePoint.PubKey,
theirContribution.PaymentBasePoint.PubKey,
)
default:
stateObfuscator = DeriveStateHintObfuscator(
theirContribution.PaymentBasePoint.PubKey,
ourContribution.PaymentBasePoint.PubKey,
)
}
}
err = initStateHints(ourCommitTx, theirCommitTx, stateObfuscator)
if err != nil {
req.err <- err
return
}
// Sort both transactions according to the agreed upon canonical
// ordering. This lets us skip sending the entire transaction over,
// instead we'll just send signatures.
txsort.InPlaceSort(ourCommitTx)
txsort.InPlaceSort(theirCommitTx)
walletLog.Debugf("Local commit tx for ChannelPoint(%v): %v",
chanPoint, spew.Sdump(ourCommitTx))
walletLog.Debugf("Remote commit tx for ChannelPoint(%v): %v",
chanPoint, spew.Sdump(theirCommitTx))
// Record newly available information within the open channel state.
chanState.FundingOutpoint = chanPoint
chanState.LocalCommitment.CommitTx = ourCommitTx
chanState.RemoteCommitment.CommitTx = theirCommitTx
// Next, we'll obtain the funding witness script, and the funding
// output itself so we can generate a valid signature for the remote
// party.
fundingIntent := pendingReservation.fundingIntent
fundingWitnessScript, fundingOutput, err := fundingIntent.FundingOutput()
if err != nil {
req.err <- fmt.Errorf("unable to obtain funding output")
return
}
// Generate a signature for their version of the initial commitment
// transaction.
ourKey := ourContribution.MultiSigKey
signDesc := input.SignDescriptor{
WitnessScript: fundingWitnessScript,
KeyDesc: ourKey,
Output: fundingOutput,
HashType: txscript.SigHashAll,
SigHashes: txscript.NewTxSigHashes(theirCommitTx),
InputIndex: 0,
}
sigTheirCommit, err := l.Cfg.Signer.SignOutputRaw(theirCommitTx, &signDesc)
if err != nil {
req.err <- err
return
}
pendingReservation.ourCommitmentSig = sigTheirCommit
req.err <- nil
}
// handleSingleContribution is called as the second step to a single funder
// workflow to which we are the responder. It simply saves the remote peer's
// contribution to the channel, as solely the remote peer will contribute any
// funds to the channel.
func (l *LightningWallet) handleSingleContribution(req *addSingleContributionMsg) {
l.limboMtx.Lock()
pendingReservation, ok := l.fundingLimbo[req.pendingFundingID]
l.limboMtx.Unlock()
if !ok {
req.err <- fmt.Errorf("attempted to update non-existent funding state")
return
}
// Grab the mutex on the channelReservation to ensure thread-safety.
pendingReservation.Lock()
defer pendingReservation.Unlock()
// TODO(roasbeef): verify sanity of remote party's parameters, fail if
// disagree
// Simply record the counterparty's contribution into the pending
// reservation data as they'll be solely funding the channel entirely.
pendingReservation.theirContribution = req.contribution
theirContribution := pendingReservation.theirContribution
chanState := pendingReservation.partialState
// Initialize an empty sha-chain for them, tracking the current pending
// revocation hash (we don't yet know the preimage so we can't add it
// to the chain).
remotePreimageStore := shachain.NewRevocationStore()
chanState.RevocationStore = remotePreimageStore
// Now that we've received their first commitment point, we'll store it
// within the channel state so we can sync it to disk once the funding
// process is complete.
chanState.RemoteCurrentRevocation = theirContribution.FirstCommitmentPoint
req.err <- nil
return
}
// verifyFundingInputs attempts to verify all remote inputs to the funding
// transaction.
func (l *LightningWallet) verifyFundingInputs(fundingTx *wire.MsgTx,
remoteInputScripts []*input.Script) error {
sigIndex := 0
fundingHashCache := txscript.NewTxSigHashes(fundingTx)
inputScripts := remoteInputScripts
for i, txin := range fundingTx.TxIn {
if len(inputScripts) != 0 && len(txin.Witness) == 0 {
// Attach the input scripts so we can verify it below.
txin.Witness = inputScripts[sigIndex].Witness
txin.SignatureScript = inputScripts[sigIndex].SigScript
// Fetch the alleged previous output along with the
// pkscript referenced by this input.
//
// TODO(roasbeef): when dual funder pass actual
// height-hint
//
// TODO(roasbeef): this fails for neutrino always as it
// treats the height hint as an exact birthday of the
// utxo rather than a lower bound
pkScript, err := txscript.ComputePkScript(
txin.SignatureScript, txin.Witness,
)
if err != nil {
return fmt.Errorf("cannot create script: %v", err)
}
output, err := l.Cfg.ChainIO.GetUtxo(
&txin.PreviousOutPoint,
pkScript.Script(), 0, l.quit,
)
if output == nil {
return fmt.Errorf("input to funding tx does "+
"not exist: %v", err)
}
// Ensure that the witness+sigScript combo is valid.
vm, err := txscript.NewEngine(
output.PkScript, fundingTx, i,
txscript.StandardVerifyFlags, nil,
fundingHashCache, output.Value,
)
if err != nil {
return fmt.Errorf("cannot create script "+
"engine: %s", err)
}
if err = vm.Execute(); err != nil {
return fmt.Errorf("cannot validate "+
"transaction: %s", err)
}
sigIndex++
}
}
return nil
}
// handleFundingCounterPartySigs is the final step in the channel reservation
// workflow. During this step, we validate *all* the received signatures for
// inputs to the funding transaction. If any of these are invalid, we bail,
// and forcibly cancel this funding request. Additionally, we ensure that the
// signature we received from the counterparty for our version of the commitment
// transaction allows us to spend from the funding output with the addition of
// our signature.
func (l *LightningWallet) handleFundingCounterPartySigs(msg *addCounterPartySigsMsg) {
l.limboMtx.RLock()
res, ok := l.fundingLimbo[msg.pendingFundingID]
l.limboMtx.RUnlock()
if !ok {
msg.err <- fmt.Errorf("attempted to update non-existent funding state")
return
}
// Grab the mutex on the ChannelReservation to ensure thread-safety
res.Lock()
defer res.Unlock()
// Now we can complete the funding transaction by adding their
// signatures to their inputs.
res.theirFundingInputScripts = msg.theirFundingInputScripts
inputScripts := msg.theirFundingInputScripts
// Only if we have the final funding transaction do we need to verify
// the final set of inputs. Otherwise, it may be the case that the
// channel was funded via an external wallet.
fundingTx := res.fundingTx
if res.partialState.ChanType.HasFundingTx() {
err := l.verifyFundingInputs(fundingTx, inputScripts)
if err != nil {
msg.err <- err
msg.completeChan <- nil
return
}
}
// At this point, we can also record and verify their signature for our
// commitment transaction.
res.theirCommitmentSig = msg.theirCommitmentSig
commitTx := res.partialState.LocalCommitment.CommitTx
ourKey := res.ourContribution.MultiSigKey
theirKey := res.theirContribution.MultiSigKey
// Re-generate both the witnessScript and p2sh output. We sign the
// witnessScript script, but include the p2sh output as the subscript
// for verification.
witnessScript, _, err := input.GenFundingPkScript(
ourKey.PubKey.SerializeCompressed(),
theirKey.PubKey.SerializeCompressed(),
int64(res.partialState.Capacity),
)
if err != nil {
msg.err <- err
msg.completeChan <- nil
return
}
// Next, create the spending scriptSig, and then verify that the script
// is complete, allowing us to spend from the funding transaction.
channelValue := int64(res.partialState.Capacity)
hashCache := txscript.NewTxSigHashes(commitTx)
sigHash, err := txscript.CalcWitnessSigHash(
witnessScript, hashCache, txscript.SigHashAll, commitTx,
0, channelValue,
)
if err != nil {
msg.err <- err
msg.completeChan <- nil
return
}
// Verify that we've received a valid signature from the remote party
// for our version of the commitment transaction.
theirCommitSig := msg.theirCommitmentSig
sig, err := btcec.ParseSignature(theirCommitSig, btcec.S256())
if err != nil {
msg.err <- err
msg.completeChan <- nil
return
} else if !sig.Verify(sigHash, theirKey.PubKey) {
msg.err <- fmt.Errorf("counterparty's commitment signature is invalid")
msg.completeChan <- nil
return
}
res.partialState.LocalCommitment.CommitSig = theirCommitSig
// Funding complete, this entry can be removed from limbo.
l.limboMtx.Lock()
delete(l.fundingLimbo, res.reservationID)
l.limboMtx.Unlock()
l.intentMtx.Lock()
delete(l.fundingIntents, res.pendingChanID)
l.intentMtx.Unlock()
// As we're about to broadcast the funding transaction, we'll take note
// of the current height for record keeping purposes.
//
// TODO(roasbeef): this info can also be piped into light client's
// basic fee estimation?
_, bestHeight, err := l.Cfg.ChainIO.GetBestBlock()
if err != nil {
msg.err <- err
msg.completeChan <- nil
return
}
// As we've completed the funding process, we'll no convert the
// contribution structs into their underlying channel config objects to
// he stored within the database.
res.partialState.LocalChanCfg = res.ourContribution.toChanConfig()
res.partialState.RemoteChanCfg = res.theirContribution.toChanConfig()
// We'll also record the finalized funding txn, which will allow us to
// rebroadcast on startup in case we fail.
res.partialState.FundingTxn = fundingTx
// Set optional upfront shutdown scripts on the channel state so that they
// are persisted. These values may be nil.
res.partialState.LocalShutdownScript =
res.ourContribution.UpfrontShutdown
res.partialState.RemoteShutdownScript =
res.theirContribution.UpfrontShutdown
// Add the complete funding transaction to the DB, in its open bucket
// which will be used for the lifetime of this channel.
nodeAddr := res.nodeAddr
err = res.partialState.SyncPending(nodeAddr, uint32(bestHeight))
if err != nil {
msg.err <- err
msg.completeChan <- nil
return
}
msg.completeChan <- res.partialState
msg.err <- nil
}
// handleSingleFunderSigs is called once the remote peer who initiated the
// single funder workflow has assembled the funding transaction, and generated
// a signature for our version of the commitment transaction. This method
// progresses the workflow by generating a signature for the remote peer's
// version of the commitment transaction.
func (l *LightningWallet) handleSingleFunderSigs(req *addSingleFunderSigsMsg) {
l.limboMtx.RLock()
pendingReservation, ok := l.fundingLimbo[req.pendingFundingID]
l.limboMtx.RUnlock()
if !ok {
req.err <- fmt.Errorf("attempted to update non-existent funding state")
req.completeChan <- nil
return
}
// Grab the mutex on the ChannelReservation to ensure thread-safety
pendingReservation.Lock()
defer pendingReservation.Unlock()
chanState := pendingReservation.partialState
chanState.FundingOutpoint = *req.fundingOutpoint
fundingTxIn := wire.NewTxIn(req.fundingOutpoint, nil, nil)
// Now that we have the funding outpoint, we can generate both versions
// of the commitment transaction, and generate a signature for the
// remote node's commitment transactions.
localBalance := pendingReservation.partialState.LocalCommitment.LocalBalance.ToSatoshis()
remoteBalance := pendingReservation.partialState.LocalCommitment.RemoteBalance.ToSatoshis()
ourCommitTx, theirCommitTx, err := CreateCommitmentTxns(
localBalance, remoteBalance,
pendingReservation.ourContribution.ChannelConfig,
pendingReservation.theirContribution.ChannelConfig,
pendingReservation.ourContribution.FirstCommitmentPoint,
pendingReservation.theirContribution.FirstCommitmentPoint,
*fundingTxIn, pendingReservation.partialState.ChanType,
)
if err != nil {
req.err <- err
req.completeChan <- nil
return
}
// With both commitment transactions constructed, we can now use the
// generator state obfuscator to encode the current state number within
// both commitment transactions.
stateObfuscator := DeriveStateHintObfuscator(
pendingReservation.theirContribution.PaymentBasePoint.PubKey,
pendingReservation.ourContribution.PaymentBasePoint.PubKey,
)
err = initStateHints(ourCommitTx, theirCommitTx, stateObfuscator)
if err != nil {
req.err <- err
req.completeChan <- nil
return
}
// Sort both transactions according to the agreed upon canonical
// ordering. This ensures that both parties sign the same sighash
// without further synchronization.
txsort.InPlaceSort(ourCommitTx)
txsort.InPlaceSort(theirCommitTx)
chanState.LocalCommitment.CommitTx = ourCommitTx
chanState.RemoteCommitment.CommitTx = theirCommitTx
walletLog.Debugf("Local commit tx for ChannelPoint(%v): %v",
req.fundingOutpoint, spew.Sdump(ourCommitTx))
walletLog.Debugf("Remote commit tx for ChannelPoint(%v): %v",
req.fundingOutpoint, spew.Sdump(theirCommitTx))
channelValue := int64(pendingReservation.partialState.Capacity)
hashCache := txscript.NewTxSigHashes(ourCommitTx)
theirKey := pendingReservation.theirContribution.MultiSigKey
ourKey := pendingReservation.ourContribution.MultiSigKey
witnessScript, _, err := input.GenFundingPkScript(
ourKey.PubKey.SerializeCompressed(),
theirKey.PubKey.SerializeCompressed(), channelValue,
)
if err != nil {
req.err <- err
req.completeChan <- nil
return
}
sigHash, err := txscript.CalcWitnessSigHash(
witnessScript, hashCache, txscript.SigHashAll, ourCommitTx, 0,
channelValue,
)
if err != nil {
req.err <- err
req.completeChan <- nil
return
}
// Verify that we've received a valid signature from the remote party
// for our version of the commitment transaction.
sig, err := btcec.ParseSignature(req.theirCommitmentSig, btcec.S256())
if err != nil {
req.err <- err
req.completeChan <- nil
return
}
if !sig.Verify(sigHash, theirKey.PubKey) {
req.err <- fmt.Errorf("counterparty's commitment signature " +
"is invalid")
req.completeChan <- nil
return
}
chanState.LocalCommitment.CommitSig = req.theirCommitmentSig
// With their signature for our version of the commitment transactions
// verified, we can now generate a signature for their version,
// allowing the funding transaction to be safely broadcast.
p2wsh, err := input.WitnessScriptHash(witnessScript)
if err != nil {
req.err <- err
req.completeChan <- nil
return
}
signDesc := input.SignDescriptor{
WitnessScript: witnessScript,
KeyDesc: ourKey,
Output: &wire.TxOut{
PkScript: p2wsh,
Value: channelValue,
},
HashType: txscript.SigHashAll,
SigHashes: txscript.NewTxSigHashes(theirCommitTx),
InputIndex: 0,
}
sigTheirCommit, err := l.Cfg.Signer.SignOutputRaw(theirCommitTx, &signDesc)
if err != nil {
req.err <- err
req.completeChan <- nil
return
}
pendingReservation.ourCommitmentSig = sigTheirCommit
_, bestHeight, err := l.Cfg.ChainIO.GetBestBlock()
if err != nil {
req.err <- err
req.completeChan <- nil
return
}
// Set optional upfront shutdown scripts on the channel state so that they
// are persisted. These values may be nil.
chanState.LocalShutdownScript =
pendingReservation.ourContribution.UpfrontShutdown
chanState.RemoteShutdownScript =
pendingReservation.theirContribution.UpfrontShutdown
// Add the complete funding transaction to the DB, in it's open bucket
// which will be used for the lifetime of this channel.
chanState.LocalChanCfg = pendingReservation.ourContribution.toChanConfig()
chanState.RemoteChanCfg = pendingReservation.theirContribution.toChanConfig()
err = chanState.SyncPending(pendingReservation.nodeAddr, uint32(bestHeight))
if err != nil {
req.err <- err
req.completeChan <- nil
return
}
req.completeChan <- chanState
req.err <- nil
l.limboMtx.Lock()
delete(l.fundingLimbo, req.pendingFundingID)
l.limboMtx.Unlock()
l.intentMtx.Lock()
delete(l.fundingIntents, pendingReservation.pendingChanID)
l.intentMtx.Unlock()
}
// WithCoinSelectLock will execute the passed function closure in a
// synchronized manner preventing any coin selection operations from proceeding
// while the closure is executing. This can be seen as the ability to execute a
// function closure under an exclusive coin selection lock.
func (l *LightningWallet) WithCoinSelectLock(f func() error) error {
l.coinSelectMtx.Lock()
defer l.coinSelectMtx.Unlock()
return f()
}
// DeriveStateHintObfuscator derives the bytes to be used for obfuscating the
// state hints from the root to be used for a new channel. The obfuscator is
// generated via the following computation:
//
// * sha256(initiatorKey || responderKey)[26:]
// * where both keys are the multi-sig keys of the respective parties
//
// The first 6 bytes of the resulting hash are used as the state hint.
func DeriveStateHintObfuscator(key1, key2 *btcec.PublicKey) [StateHintSize]byte {
h := sha256.New()
h.Write(key1.SerializeCompressed())
h.Write(key2.SerializeCompressed())
sha := h.Sum(nil)
var obfuscator [StateHintSize]byte
copy(obfuscator[:], sha[26:])
return obfuscator
}
// initStateHints properly sets the obfuscated state hints on both commitment
// transactions using the passed obfuscator.
func initStateHints(commit1, commit2 *wire.MsgTx,
obfuscator [StateHintSize]byte) error {
if err := SetStateNumHint(commit1, 0, obfuscator); err != nil {
return err
}
if err := SetStateNumHint(commit2, 0, obfuscator); err != nil {
return err
}
return nil
}
// ValidateChannel will attempt to fully validate a newly mined channel, given
// its funding transaction and existing channel state. If this method returns
// an error, then the mined channel is invalid, and shouldn't be used.
func (l *LightningWallet) ValidateChannel(channelState *channeldb.OpenChannel,
fundingTx *wire.MsgTx) error {
// First, we'll obtain a fully signed commitment transaction so we can
// pass into it on the chanvalidate package for verification.
channel, err := NewLightningChannel(l.Cfg.Signer, channelState, nil)
if err != nil {
return err
}
signedCommitTx, err := channel.getSignedCommitTx()
if err != nil {
return err
}
// We'll also need the multi-sig witness script itself so the
// chanvalidate package can check it for correctness against the
// funding transaction, and also commitment validity.
localKey := channelState.LocalChanCfg.MultiSigKey.PubKey
remoteKey := channelState.RemoteChanCfg.MultiSigKey.PubKey
witnessScript, err := input.GenMultiSigScript(
localKey.SerializeCompressed(),
remoteKey.SerializeCompressed(),
)
if err != nil {
return err
}
pkScript, err := input.WitnessScriptHash(witnessScript)
if err != nil {
return err
}
// Finally, we'll pass in all the necessary context needed to fully
// validate that this channel is indeed what we expect, and can be
// used.
_, err = chanvalidate.Validate(&chanvalidate.Context{
Locator: &chanvalidate.OutPointChanLocator{
ChanPoint: channelState.FundingOutpoint,
},
MultiSigPkScript: pkScript,
FundingTx: fundingTx,
CommitCtx: &chanvalidate.CommitmentContext{
Value: channel.Capacity,
FullySignedCommitTx: signedCommitTx,
},
})
if err != nil {
return err
}
return nil
}
// CoinSource is a wrapper around the wallet that implements the
// chanfunding.CoinSource interface.
type CoinSource struct {
wallet *LightningWallet
}
// NewCoinSource creates a new instance of the CoinSource wrapper struct.
func NewCoinSource(w *LightningWallet) *CoinSource {
return &CoinSource{wallet: w}
}
// ListCoins returns all UTXOs from the source that have between
// minConfs and maxConfs number of confirmations.
func (c *CoinSource) ListCoins(minConfs int32,
maxConfs int32) ([]chanfunding.Coin, error) {
utxos, err := c.wallet.ListUnspentWitness(minConfs, maxConfs)
if err != nil {
return nil, err
}
var coins []chanfunding.Coin
for _, utxo := range utxos {
coins = append(coins, chanfunding.Coin{
TxOut: wire.TxOut{
Value: int64(utxo.Value),
PkScript: utxo.PkScript,
},
OutPoint: utxo.OutPoint,
})
}
return coins, nil
}
// CoinFromOutPoint attempts to locate details pertaining to a coin based on
// its outpoint. If the coin isn't under the control of the backing CoinSource,
// then an error should be returned.
func (c *CoinSource) CoinFromOutPoint(op wire.OutPoint) (*chanfunding.Coin, error) {
inputInfo, err := c.wallet.FetchInputInfo(&op)
if err != nil {
return nil, err
}
return &chanfunding.Coin{
TxOut: wire.TxOut{
Value: int64(inputInfo.Value),
PkScript: inputInfo.PkScript,
},
OutPoint: inputInfo.OutPoint,
}, nil
}
// shimKeyRing is a wrapper struct that's used to provide the proper multi-sig
// key for an initiated external funding flow.
type shimKeyRing struct {
keychain.KeyRing
*chanfunding.ShimIntent
}
// DeriveNextKey intercepts the normal DeriveNextKey call to a keychain.KeyRing
// instance, and supplies the multi-sig key specified by the ShimIntent. This
// allows us to transparently insert new keys into the existing funding flow,
// as these keys may not come from the wallet itself.
func (s *shimKeyRing) DeriveNextKey(keyFam keychain.KeyFamily) (keychain.KeyDescriptor, error) {
if keyFam != keychain.KeyFamilyMultiSig {
return s.KeyRing.DeriveNextKey(keyFam)
}
fundingKeys, err := s.ShimIntent.MultiSigKeys()
if err != nil {
return keychain.KeyDescriptor{}, err
}
return *fundingKeys.LocalKey, nil
}