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