lnd.xprv/watchtower/wtclient/backup_task.go
Conner Fromknecht a00fc148c8
watchtower/wtclient/backup_task: make sweep pkscript independent of session
This commit changes when the sweep pkscript
is assigned in the construction of the justice
transaction. Currently, the sweep pkscript is
assigned when the task is bound to a session.
However, we will moving to an assignment where
a unique sweep pkscript is used per channel to
prevent address inflation. Hence, this commit
makes the sweep pkscript a state dependent
variable, since it can be known at the time the
channel id is assigned.
2019-02-06 18:24:30 -08:00

305 lines
11 KiB
Go

package wtclient
import (
"github.com/btcsuite/btcd/blockchain"
"github.com/btcsuite/btcd/btcec"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
"github.com/btcsuite/btcutil/txsort"
"github.com/lightningnetwork/lnd/input"
"github.com/lightningnetwork/lnd/lnwallet"
"github.com/lightningnetwork/lnd/lnwire"
"github.com/lightningnetwork/lnd/watchtower/blob"
"github.com/lightningnetwork/lnd/watchtower/wtdb"
)
// backupTask is an internal struct for computing the justice transaction for a
// particular revoked state. A backupTask functions as a scratch pad for storing
// computing values of the transaction itself, such as the final split in
// balance if the justice transaction will give a reward to the tower. The
// backup task has three primary phases:
// 1. Init: Determines which inputs from the breach transaction will be spent,
// and the total amount contained in the inputs.
// 2. Bind: Asserts that the revoked state is eligible under a given session's
// parameters. Certain states may be ineligible due to fee rates, too little
// input amount, etc. Backup of these states can be deferred to a later time
// or session with more favorable parameters. If the session is bound
// successfully, the final session-dependent values to the justice
// transaction are solidified.
// 3. Send: Once the task is bound, it will be queued to send to a specific
// tower corresponding to the session in which it was bound. The justice
// transaction will be assembled by examining the parameters left as a
// result of the binding. After the justice transaction is signed, the
// necessary components are stripped out and encrypted before being sent to
// the tower in a StateUpdate.
type backupTask struct {
chanID lnwire.ChannelID
commitHeight uint64
breachInfo *lnwallet.BreachRetribution
// state-dependent variables
toLocalInput input.Input
toRemoteInput input.Input
totalAmt btcutil.Amount
sweepPkScript []byte
// session-dependent variables
blobType blob.Type
outputs []*wire.TxOut
}
// newBackupTask initializes a new backupTask and populates all state-dependent
// variables.
func newBackupTask(chanID *lnwire.ChannelID,
breachInfo *lnwallet.BreachRetribution,
sweepPkScript []byte) *backupTask {
// Parse the non-dust outputs from the breach transaction,
// simultaneously computing the total amount contained in the inputs
// present. We can't compute the exact output values at this time
// since the task has not been assigned to a session, at which point
// parameters such as fee rate, number of outputs, and reward rate will
// be finalized.
var (
totalAmt int64
toLocalInput input.Input
toRemoteInput input.Input
)
// Add the sign descriptors and outputs corresponding to the to-local
// and to-remote outputs, respectively, if either input amount is
// non-dust. Note that the naming here seems reversed, but both are
// correct. For example, the to-remote output on the remote party's
// commitment is an output that pays to us. Hence the retribution refers
// to that output as local, though relative to their commitment, it is
// paying to-the-remote party (which is us).
if breachInfo.RemoteOutputSignDesc != nil {
toLocalInput = input.NewBaseInput(
&breachInfo.RemoteOutpoint,
input.CommitmentRevoke,
breachInfo.RemoteOutputSignDesc,
0,
)
totalAmt += breachInfo.RemoteOutputSignDesc.Output.Value
}
if breachInfo.LocalOutputSignDesc != nil {
toRemoteInput = input.NewBaseInput(
&breachInfo.LocalOutpoint,
input.CommitmentNoDelay,
breachInfo.LocalOutputSignDesc,
0,
)
totalAmt += breachInfo.LocalOutputSignDesc.Output.Value
}
return &backupTask{
chanID: *chanID,
commitHeight: breachInfo.RevokedStateNum,
breachInfo: breachInfo,
toLocalInput: toLocalInput,
toRemoteInput: toRemoteInput,
totalAmt: btcutil.Amount(totalAmt),
sweepPkScript: sweepPkScript,
}
}
// inputs returns all non-dust inputs that we will attempt to spend from.
//
// NOTE: Ordering of the inputs is not critical as we sort the transaction with
// BIP69.
func (t *backupTask) inputs() map[wire.OutPoint]input.Input {
inputs := make(map[wire.OutPoint]input.Input)
if t.toLocalInput != nil {
inputs[*t.toLocalInput.OutPoint()] = t.toLocalInput
}
if t.toRemoteInput != nil {
inputs[*t.toRemoteInput.OutPoint()] = t.toRemoteInput
}
return inputs
}
// bindSession determines if the backupTask is compatible with the passed
// SessionInfo's policy. If no error is returned, the task has been bound to the
// session and can be queued to upload to the tower. Otherwise, the bind failed
// and should be rescheduled with a different session.
func (t *backupTask) bindSession(session *wtdb.SessionInfo) error {
// First we'll begin by deriving a weight estimate for the justice
// transaction. The final weight can be different depending on whether
// the watchtower is taking a reward.
var weightEstimate input.TxWeightEstimator
// Next, add the contribution from the inputs that are present on this
// breach transaction.
if t.toLocalInput != nil {
weightEstimate.AddWitnessInput(input.ToLocalPenaltyWitnessSize)
}
if t.toRemoteInput != nil {
weightEstimate.AddWitnessInput(input.P2WKHWitnessSize)
}
// All justice transactions have a p2wkh output paying to the victim.
weightEstimate.AddP2WKHOutput()
// If the justice transaction has a reward output, add the output's
// contribution to the weight estimate.
if session.Policy.BlobType.Has(blob.FlagReward) {
weightEstimate.AddP2WKHOutput()
}
// Now, compute the output values depending on whether FlagReward is set
// in the current session's policy.
outputs, err := session.Policy.ComputeJusticeTxOuts(
t.totalAmt, int64(weightEstimate.Weight()),
t.sweepPkScript, session.RewardAddress,
)
if err != nil {
return err
}
t.blobType = session.Policy.BlobType
t.outputs = outputs
return nil
}
// craftSessionPayload is the final stage for a backupTask, and generates the
// encrypted payload and breach hint that should be sent to the tower. This
// method computes the final justice transaction using the bound
// session-dependent variables, and signs the resulting transaction. The
// required pieces from signatures, witness scripts, etc are then packaged into
// a JusticeKit and encrypted using the breach transaction's key.
func (t *backupTask) craftSessionPayload(
signer input.Signer) (wtdb.BreachHint, []byte, error) {
var hint wtdb.BreachHint
// First, copy over the sweep pkscript, the pubkeys used to derive the
// to-local script, and the remote CSV delay.
keyRing := t.breachInfo.KeyRing
justiceKit := &blob.JusticeKit{
SweepAddress: t.sweepPkScript,
RevocationPubKey: toBlobPubKey(keyRing.RevocationKey),
LocalDelayPubKey: toBlobPubKey(keyRing.DelayKey),
CSVDelay: t.breachInfo.RemoteDelay,
}
// If this commitment has an output that pays to us, copy the to-remote
// pubkey into the justice kit. This serves as the indicator to the
// tower that we expect the breaching transaction to have a non-dust
// output to spend from.
if t.toRemoteInput != nil {
justiceKit.CommitToRemotePubKey = toBlobPubKey(
keyRing.NoDelayKey,
)
}
// Now, begin construction of the justice transaction. We'll start with
// a version 2 transaction.
justiceTxn := wire.NewMsgTx(2)
// Next, add the non-dust inputs that were derived from the breach
// information. This will either be contain both the to-local and
// to-remote outputs, or only be the to-local output.
inputs := t.inputs()
for prevOutPoint := range inputs {
justiceTxn.AddTxIn(&wire.TxIn{
PreviousOutPoint: prevOutPoint,
})
}
// Add the sweep output paying directly to the user and possibly a
// reward output, using the outputs computed when the task was bound.
justiceTxn.TxOut = t.outputs
// Sort the justice transaction according to BIP69.
txsort.InPlaceSort(justiceTxn)
// Check that the justice transaction meets basic validity requirements
// before attempting to attach the witnesses.
btx := btcutil.NewTx(justiceTxn)
if err := blockchain.CheckTransactionSanity(btx); err != nil {
return hint, nil, err
}
// Construct a sighash cache to improve signing performance.
hashCache := txscript.NewTxSigHashes(justiceTxn)
// Since the transaction inputs could have been reordered as a result of
// the BIP69 sort, create an index mapping each prevout to it's new
// index.
inputIndex := make(map[wire.OutPoint]int)
for i, txIn := range justiceTxn.TxIn {
inputIndex[txIn.PreviousOutPoint] = i
}
// Now, iterate through the list of inputs that were initially added to
// the transaction and store the computed witness within the justice
// kit.
for _, inp := range inputs {
// Lookup the input's new post-sort position.
i := inputIndex[*inp.OutPoint()]
// Construct the full witness required to spend this input.
inputScript, err := inp.CraftInputScript(
signer, justiceTxn, hashCache, i,
)
if err != nil {
return hint, nil, err
}
// Parse the DER-encoded signature from the first position of
// the resulting witness. We trim an extra byte to remove the
// sighash flag.
witness := inputScript.Witness
rawSignature := witness[0][:len(witness[0])-1]
// Reencode the DER signature into a fixed-size 64 byte
// signature.
signature, err := lnwire.NewSigFromRawSignature(rawSignature)
if err != nil {
return hint, nil, err
}
// Finally, copy the serialized signature into the justice kit,
// using the input's witness type to select the appropriate
// field.
switch inp.WitnessType() {
case input.CommitmentRevoke:
copy(justiceKit.CommitToLocalSig[:], signature[:])
case input.CommitmentNoDelay:
copy(justiceKit.CommitToRemoteSig[:], signature[:])
}
}
// Compute the breach hint from the breach transaction id's prefix.
breachKey := t.breachInfo.BreachTransaction.TxHash()
// Then, we'll encrypt the computed justice kit using the full breach
// transaction id, which will allow the tower to recover the contents
// after the transaction is seen in the chain or mempool.
encBlob, err := justiceKit.Encrypt(breachKey[:], t.blobType)
if err != nil {
return hint, nil, err
}
// Finally, compute the breach hint, taken as the first half of the
// breach transactions txid. Once the tower sees the breach transaction
// on the network, it can use the full txid to decyrpt the blob.
hint = wtdb.NewBreachHintFromHash(&breachKey)
return hint, encBlob, nil
}
// toBlobPubKey serializes the given pubkey into a blob.PubKey that can be set
// as a field on a blob.JusticeKit.
func toBlobPubKey(pubKey *btcec.PublicKey) blob.PubKey {
var blobPubKey blob.PubKey
copy(blobPubKey[:], pubKey.SerializeCompressed())
return blobPubKey
}