lnd.xprv/lnwallet/script_utils.go

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package lnwallet
import (
"bytes"
"crypto/sha256"
"encoding/binary"
"fmt"
"math/big"
"golang.org/x/crypto/hkdf"
"github.com/roasbeef/btcd/btcec"
"github.com/roasbeef/btcd/chaincfg/chainhash"
"github.com/roasbeef/btcd/txscript"
"github.com/roasbeef/btcd/wire"
"github.com/roasbeef/btcutil"
)
var (
// TODO(roasbeef): remove these and use the one's defined in txscript
// within testnet-L.
2017-02-23 22:56:47 +03:00
// SequenceLockTimeSeconds is the 22nd bit which indicates the lock
// time is in seconds.
SequenceLockTimeSeconds = uint32(1 << 22)
OP_CHECKSEQUENCEVERIFY byte = txscript.OP_NOP3
// TimelockShift is used to make sure the commitment transaction is
// spendable by setting the locktime with it so that it is larger than
// 500,000,000, thus interpreting it as Unix epoch timestamp and not
// a block height. It is also smaller than the current timestamp which
// has bit (1 << 30) set, so there is no risk of having the commitment
// transaction be rejected. This way we can safely use the lower 24 bits
// of the locktime field for part of the obscured commitment transaction
// number.
TimelockShift = uint32(1 << 29)
)
const (
// StateHintSize is the total number of bytes used between the sequence
// number and locktime of the commitment transaction use to encode a hint
// to the state number of a particular commitment transaction.
StateHintSize = 6
// maxStateHint is the maximum state number we're able to encode using
// StateHintSize bytes amongst the sequence number and locktime fields
// of the commitment transaction.
maxStateHint = (1 << 48) - 1
)
// witnessScriptHash generates a pay-to-witness-script-hash public key script
// paying to a version 0 witness program paying to the passed redeem script.
func witnessScriptHash(witnessScript []byte) ([]byte, error) {
bldr := txscript.NewScriptBuilder()
bldr.AddOp(txscript.OP_0)
scriptHash := sha256.Sum256(witnessScript)
bldr.AddData(scriptHash[:])
return bldr.Script()
}
// genMultiSigScript generates the non-p2sh'd multisig script for 2 of 2
// pubkeys.
func genMultiSigScript(aPub, bPub []byte) ([]byte, error) {
if len(aPub) != 33 || len(bPub) != 33 {
return nil, fmt.Errorf("Pubkey size error. Compressed pubkeys only")
}
// Swap to sort pubkeys if needed. Keys are sorted in lexicographical
// order. The signatures within the scriptSig must also adhere to the
// order, ensuring that the signatures for each public key appears
// in the proper order on the stack.
if bytes.Compare(aPub, bPub) == -1 {
aPub, bPub = bPub, aPub
}
bldr := txscript.NewScriptBuilder()
bldr.AddOp(txscript.OP_2)
bldr.AddData(aPub) // Add both pubkeys (sorted).
bldr.AddData(bPub)
bldr.AddOp(txscript.OP_2)
bldr.AddOp(txscript.OP_CHECKMULTISIG)
return bldr.Script()
}
// GenFundingPkScript creates a redeem script, and its matching p2wsh
// output for the funding transaction.
func GenFundingPkScript(aPub, bPub []byte, amt int64) ([]byte, *wire.TxOut, error) {
// As a sanity check, ensure that the passed amount is above zero.
if amt <= 0 {
return nil, nil, fmt.Errorf("can't create FundTx script with " +
"zero, or negative coins")
}
// First, create the 2-of-2 multi-sig script itself.
witnessScript, err := genMultiSigScript(aPub, bPub)
if err != nil {
return nil, nil, err
}
// With the 2-of-2 script in had, generate a p2wsh script which pays
// to the funding script.
pkScript, err := witnessScriptHash(witnessScript)
if err != nil {
return nil, nil, err
}
return witnessScript, wire.NewTxOut(amt, pkScript), nil
}
// SpendMultiSig generates the witness stack required to redeem the 2-of-2 p2wsh
// multi-sig output.
func SpendMultiSig(witnessScript, pubA, sigA, pubB, sigB []byte) [][]byte {
witness := make([][]byte, 4)
// When spending a p2wsh multi-sig script, rather than an OP_0, we add
// a nil stack element to eat the extra pop.
witness[0] = nil
// When initially generating the witnessScript, we sorted the serialized
// public keys in descending order. So we do a quick comparison in order
// ensure the signatures appear on the Script Virtual Machine stack in
// the correct order.
if bytes.Compare(pubA, pubB) == -1 {
witness[1] = sigB
witness[2] = sigA
} else {
witness[1] = sigA
witness[2] = sigB
}
// Finally, add the preimage as the last witness element.
witness[3] = witnessScript
return witness
}
// FindScriptOutputIndex finds the index of the public key script output
// matching 'script'. Additionally, a boolean is returned indicating if a
// matching output was found at all.
//
// NOTE: The search stops after the first matching script is found.
func FindScriptOutputIndex(tx *wire.MsgTx, script []byte) (bool, uint32) {
found := false
index := uint32(0)
for i, txOut := range tx.TxOut {
if bytes.Equal(txOut.PkScript, script) {
found = true
index = uint32(i)
break
}
}
return found, index
}
// senderHTLCScript constructs the public key script for an outgoing HTLC
// output payment for the sender's version of the commitment transaction:
//
// Possible Input Scripts:
// SENDR: <sig> 0
// RECVR: <sig> <preimage> 0 1
// REVOK: <sig <preimage> 1 1
// * receiver revoke
//
// OP_IF
// //Receiver
// OP_IF
// //Revoke
// <revocation hash>
// OP_ELSE
// //Receive
// OP_SIZE 32 OP_EQUALVERIFY
// <payment hash>
// OP_ENDIF
// OP_SWAP
// OP_SHA256 OP_EQUALVERIFY
// <recv key> OP_CHECKSIG
// OP_ELSE
// //Sender
// <absolute blockheight> OP_CHECKLOCKTIMEVERIFY
// <relative blockheight> OP_CHECKSEQUENCEVERIFY
// OP_2DROP
// <sendr key> OP_CHECKSIG
// OP_ENDIF
func senderHTLCScript(absoluteTimeout, relativeTimeout uint32, senderKey,
receiverKey *btcec.PublicKey, revokeHash, paymentHash []byte) ([]byte, error) {
builder := txscript.NewScriptBuilder()
// The receiver of the HTLC places a 1 as the first item in the witness
// stack, forcing Script execution to enter the "if" clause within the
// main body of the script.
builder.AddOp(txscript.OP_IF)
// The receiver will place a 1 as the second item of the witness stack
// in the case the sender broadcasts a revoked commitment transaction.
// Executing this branch allows the receiver to claim the sender's
// funds as a result of their contract violation.
builder.AddOp(txscript.OP_IF)
builder.AddData(revokeHash)
// Alternatively, the receiver can place a 0 as the second item of the
// witness stack if they wish to claim the HTLC with the proper
// preimage as normal. In order to prevent an over-sized preimage
// attack (which can create undesirable redemption asymmetries), we
// strongly require that all HTLC preimages are exactly 32 bytes.
builder.AddOp(txscript.OP_ELSE)
builder.AddOp(txscript.OP_SIZE)
builder.AddInt64(32)
builder.AddOp(txscript.OP_EQUALVERIFY)
builder.AddData(paymentHash)
builder.AddOp(txscript.OP_ENDIF)
builder.AddOp(txscript.OP_SWAP)
builder.AddOp(txscript.OP_SHA256)
builder.AddOp(txscript.OP_EQUALVERIFY)
// In either case, we require a valid signature by the receiver.
builder.AddData(receiverKey.SerializeCompressed())
builder.AddOp(txscript.OP_CHECKSIG)
// Otherwise, the sender of the HTLC will place a 0 as the first item
// of the witness stack in order to sweep the funds back after the HTLC
// times out.
builder.AddOp(txscript.OP_ELSE)
// In this case, the sender will need to wait for an absolute HTLC
// timeout, then afterwards a relative timeout before we claim re-claim
// the unsettled funds. This delay gives the other party a chance to
// present the preimage to the revocation hash in the event that the
// sender (at this time) broadcasts this commitment transaction after
// it has been revoked.
builder.AddInt64(int64(absoluteTimeout))
builder.AddOp(txscript.OP_CHECKLOCKTIMEVERIFY)
builder.AddInt64(int64(relativeTimeout))
builder.AddOp(OP_CHECKSEQUENCEVERIFY)
builder.AddOp(txscript.OP_2DROP)
builder.AddData(senderKey.SerializeCompressed())
builder.AddOp(txscript.OP_CHECKSIG)
builder.AddOp(txscript.OP_ENDIF)
return builder.Script()
}
// senderHtlcSpendRevoke constructs a valid witness allowing the receiver of an
// HTLC to claim the output with knowledge of the revocation preimage in the
// scenario that the sender of the HTLC broadcasts a previously revoked
// commitment transaction. A valid spend requires knowledge of the preimage to
// the commitment transaction's revocation hash, and a valid signature under
// the receiver's public key.
func senderHtlcSpendRevoke(commitScript []byte, outputAmt btcutil.Amount,
reciverKey *btcec.PrivateKey, sweepTx *wire.MsgTx,
revokePreimage []byte) (wire.TxWitness, error) {
hashCache := txscript.NewTxSigHashes(sweepTx)
sweepSig, err := txscript.RawTxInWitnessSignature(
sweepTx, hashCache, 0, int64(outputAmt), commitScript,
txscript.SigHashAll, reciverKey)
if err != nil {
return nil, err
}
// In order to force script execution to enter the revocation clause,
// we place two one's as the first items in the final evaluated witness
// stack.
witnessStack := wire.TxWitness(make([][]byte, 5))
witnessStack[0] = sweepSig
witnessStack[1] = revokePreimage
witnessStack[2] = []byte{1}
witnessStack[3] = []byte{1}
witnessStack[4] = commitScript
return witnessStack, nil
}
// senderHtlcSpendRedeem constructs a valid witness allowing the receiver of an
// HTLC to redeem the pending output in the scenario that the sender broadcasts
// their version of the commitment transaction. A valid spend requires
// knowledge of the payment preimage, and a valid signature under the
// receivers public key.
func senderHtlcSpendRedeem(commitScript []byte, outputAmt btcutil.Amount,
reciverKey *btcec.PrivateKey, sweepTx *wire.MsgTx,
paymentPreimage []byte) (wire.TxWitness, error) {
hashCache := txscript.NewTxSigHashes(sweepTx)
sweepSig, err := txscript.RawTxInWitnessSignature(
sweepTx, hashCache, 0, int64(outputAmt), commitScript,
txscript.SigHashAll, reciverKey)
if err != nil {
return nil, err
}
// We force script execution into the HTLC redemption clause by placing
// a one, then a zero as the first items in the final evaluated
// witness stack.
witnessStack := wire.TxWitness(make([][]byte, 5))
witnessStack[0] = sweepSig
witnessStack[1] = paymentPreimage
witnessStack[2] = []byte{0}
witnessStack[3] = []byte{1}
witnessStack[4] = commitScript
return witnessStack, nil
}
// htlcSpendTimeout constructs a valid witness allowing the sender of an HTLC
// to recover the pending funds after an absolute, then relative locktime
// period.
func senderHtlcSpendTimeout(commitScript []byte, outputAmt btcutil.Amount,
senderKey *btcec.PrivateKey, sweepTx *wire.MsgTx,
absoluteTimeout, relativeTimeout uint32) (wire.TxWitness, error) {
// Since the HTLC output has an absolute timeout before we're permitted
// to sweep the output, we need to set the locktime of this sweeping
// transaction to that absolute value in order to pass Script
// verification.
sweepTx.LockTime = absoluteTimeout
// Additionally, we're required to wait a relative period of time
// before we can sweep the output in order to allow the other party to
// contest our claim of validity to this version of the commitment
// transaction.
sweepTx.TxIn[0].Sequence = lockTimeToSequence(false, relativeTimeout)
// Finally, OP_CSV requires that the version of the transaction
// spending a pkscript with OP_CSV within it *must* be >= 2.
sweepTx.Version = 2
hashCache := txscript.NewTxSigHashes(sweepTx)
sweepSig, err := txscript.RawTxInWitnessSignature(
sweepTx, hashCache, 0, int64(outputAmt), commitScript,
txscript.SigHashAll, senderKey)
if err != nil {
return nil, err
}
// We place a zero as the first item of the evaluated witness stack in
// order to force Script execution to the HTLC timeout clause.
witnessStack := wire.TxWitness(make([][]byte, 3))
witnessStack[0] = sweepSig
witnessStack[1] = []byte{0}
witnessStack[2] = commitScript
return witnessStack, nil
}
// receiverHTLCScript constructs the public key script for an incoming HTLC
// output payment for the receiver's version of the commitment transaction:
//
// Possible Input Scripts:
// RECVR: <sig> <preimage> 1
// REVOK: <sig> <preimage> 0 1
// SENDR: <sig> 0 0
//
// OP_IF
// //Receiver
// OP_SIZE 32 OP_EQUALVERIFY
// OP_SHA256
// <payment hash> OP_EQUALVERIFY
// <relative blockheight> OP_CHECKSEQUENCEVERIFY OP_DROP
// <receiver key> OP_CHECKSIG
// OP_ELSE
// //Sender
// OP_IF
// //Revocation
// OP_SHA256
// <revoke hash> OP_EQUALVERIFY
// OP_ELSE
// //Refund
// <absolute blockheight> OP_CHECKLOCKTIMEVERIFY OP_DROP
// OP_ENDIF
// <sender key> OP_CHECKSIG
// OP_ENDIF
// TODO(roasbeef): go back to revocation keys in the HTLC outputs?
// * also could combine preimage with their key?
func receiverHTLCScript(absoluteTimeout, relativeTimeout uint32, senderKey,
receiverKey *btcec.PublicKey, revokeHash, paymentHash []byte) ([]byte, error) {
builder := txscript.NewScriptBuilder()
// The receiver of the script will place a 1 as the first item of the
// witness stack forcing Script execution to enter the "if" clause of
// the main body of the script.
builder.AddOp(txscript.OP_IF)
// In this clause, the receiver can redeem the HTLC after a relative
// timeout. This added delay gives the sender (at this time) an
// opportunity to re-claim the pending HTLC in the event that the
// receiver (at this time) broadcasts this old commitment transaction
// after it has been revoked. Additionally, we require that the
// preimage is exactly 32-bytes in order to avoid undesirable
// redemption asymmetries in the multi-hop scenario.
builder.AddOp(txscript.OP_SIZE)
builder.AddInt64(32)
builder.AddOp(txscript.OP_EQUALVERIFY)
builder.AddOp(txscript.OP_SHA256)
builder.AddData(paymentHash)
builder.AddOp(txscript.OP_EQUALVERIFY)
builder.AddInt64(int64(relativeTimeout))
builder.AddOp(OP_CHECKSEQUENCEVERIFY)
builder.AddOp(txscript.OP_DROP)
builder.AddData(receiverKey.SerializeCompressed())
builder.AddOp(txscript.OP_CHECKSIG)
// Otherwise, the sender will place a 0 as the first item of the
// witness stack forcing execution to enter the "else" clause of the
// main body of the script.
builder.AddOp(txscript.OP_ELSE)
// The sender will place a 1 as the second item of the witness stack in
// the scenario that the receiver broadcasts an invalidated commitment
// transaction, allowing the sender to sweep all the receiver's funds.
builder.AddOp(txscript.OP_IF)
builder.AddOp(txscript.OP_SHA256)
builder.AddData(revokeHash)
builder.AddOp(txscript.OP_EQUALVERIFY)
// If not, then the sender needs to wait for the HTLC timeout. This
// clause may be executed if the receiver fails to present the r-value
// in time. This prevents the pending funds from being locked up
// indefinitely.
// The sender will place a 0 as the second item of the witness stack if
// they wish to sweep the HTLC after an absolute refund timeout. This
// time out clause prevents the pending funds from being locked up
// indefinitely.
builder.AddOp(txscript.OP_ELSE)
builder.AddInt64(int64(absoluteTimeout))
builder.AddOp(txscript.OP_CHECKLOCKTIMEVERIFY)
builder.AddOp(txscript.OP_DROP)
builder.AddOp(txscript.OP_ENDIF)
// In either case, we also require a valid signature with the sender's
// commitment private key.
builder.AddData(senderKey.SerializeCompressed())
builder.AddOp(txscript.OP_CHECKSIG)
builder.AddOp(txscript.OP_ENDIF)
return builder.Script()
}
// receiverHtlcSpendRedeem constructs a valid witness allowing the receiver of
// an HTLC to redeem the conditional payment in the event that their commitment
// transaction is broadcast. Since this is a pay out to the receiving party as
// an output on their commitment transaction, a relative time delay is required
// before the output can be spent.
func receiverHtlcSpendRedeem(commitScript []byte, outputAmt btcutil.Amount,
reciverKey *btcec.PrivateKey, sweepTx *wire.MsgTx,
paymentPreimage []byte, relativeTimeout uint32) (wire.TxWitness, error) {
// In order to properly spend the transaction, we need to set the
// sequence number. We do this by converting the relative block delay
// into a sequence number value able to be interpreted by
// OP_CHECKSEQUENCEVERIFY.
sweepTx.TxIn[0].Sequence = lockTimeToSequence(false, relativeTimeout)
// Additionally, OP_CSV requires that the version of the transaction
// spending a pkscript with OP_CSV within it *must* be >= 2.
sweepTx.Version = 2
hashCache := txscript.NewTxSigHashes(sweepTx)
sweepSig, err := txscript.RawTxInWitnessSignature(
sweepTx, hashCache, 0, int64(outputAmt), commitScript,
txscript.SigHashAll, reciverKey)
if err != nil {
return nil, err
}
// Place a one as the first item in the evaluated witness stack to
// force script execution to the HTLC redemption clause.
witnessStack := wire.TxWitness(make([][]byte, 4))
witnessStack[0] = sweepSig
witnessStack[1] = paymentPreimage
witnessStack[2] = []byte{1}
witnessStack[3] = commitScript
return witnessStack, nil
}
// receiverHtlcSpendRevoke constructs a valid witness allowing the sender of an
// HTLC within a previously revoked commitment transaction to re-claim the
// pending funds in the case that the receiver broadcasts this revoked
// commitment transaction.
func receiverHtlcSpendRevoke(commitScript []byte, outputAmt btcutil.Amount,
senderKey *btcec.PrivateKey, sweepTx *wire.MsgTx,
revokePreimage []byte) (wire.TxWitness, error) {
// TODO(roasbeef): move sig generate outside func, or just factor out?
hashCache := txscript.NewTxSigHashes(sweepTx)
sweepSig, err := txscript.RawTxInWitnessSignature(
sweepTx, hashCache, 0, int64(outputAmt), commitScript,
txscript.SigHashAll, senderKey)
if err != nil {
return nil, err
}
// We place a zero, then one as the first items in the evaluated
// witness stack in order to force script execution to the HTLC
// revocation clause.
witnessStack := wire.TxWitness(make([][]byte, 5))
witnessStack[0] = sweepSig
witnessStack[1] = revokePreimage
witnessStack[2] = []byte{1}
witnessStack[3] = []byte{0}
witnessStack[4] = commitScript
return witnessStack, nil
}
// receiverHtlcSpendTimeout constructs a valid witness allowing the sender of
// an HTLC to recover the pending funds after an absolute timeout in the
// scenario that the receiver of the HTLC broadcasts their version of the
// commitment transaction.
func receiverHtlcSpendTimeout(commitScript []byte, outputAmt btcutil.Amount,
senderKey *btcec.PrivateKey, sweepTx *wire.MsgTx,
absoluteTimeout uint32) (wire.TxWitness, error) {
// The HTLC output has an absolute time period before we are permitted
// to recover the pending funds. Therefore we need to set the locktime
// on this sweeping transaction in order to pass Script verification.
sweepTx.LockTime = absoluteTimeout
hashCache := txscript.NewTxSigHashes(sweepTx)
sweepSig, err := txscript.RawTxInWitnessSignature(
sweepTx, hashCache, 0, int64(outputAmt), commitScript,
txscript.SigHashAll, senderKey)
if err != nil {
return nil, err
}
witnessStack := wire.TxWitness(make([][]byte, 4))
witnessStack[0] = sweepSig
witnessStack[1] = []byte{0}
witnessStack[2] = []byte{0}
witnessStack[3] = commitScript
return witnessStack, nil
}
// lockTimeToSequence converts the passed relative locktime to a sequence
// number in accordance to BIP-68.
// See: https://github.com/bitcoin/bips/blob/master/bip-0068.mediawiki
// * (Compatibility)
func lockTimeToSequence(isSeconds bool, locktime uint32) uint32 {
if !isSeconds {
// The locktime is to be expressed in confirmations.
return locktime
}
// Set the 22nd bit which indicates the lock time is in seconds, then
// shift the locktime over by 9 since the time granularity is in
// 512-second intervals (2^9). This results in a max lock-time of
// 33,554,431 seconds, or 1.06 years.
return SequenceLockTimeSeconds | (locktime >> 9)
}
// commitScriptToSelf constructs the public key script for the output on the
// commitment transaction paying to the "owner" of said commitment transaction.
// If the other party learns of the preimage to the revocation hash, then they
// can claim all the settled funds in the channel, plus the unsettled funds.
//
// Possible Input Scripts:
// REVOKE: <sig> 1
// SENDRSWEEP: <sig> <emptyvector>
//
// Output Script:
// OP_IF
// <revokeKey> OP_CHECKSIG
// OP_ELSE
// <timeKey> OP_CHECKSIGVERIFY
// <numRelativeBlocks> OP_CHECKSEQUENCEVERIFY
// OP_ENDIF
func commitScriptToSelf(csvTimeout uint32, selfKey, revokeKey *btcec.PublicKey) ([]byte, error) {
// This script is spendable under two conditions: either the
// 'csvTimeout' has passed and we can redeem our funds, or they can
// produce a valid signature with the revocation public key. The
// revocation public key will *only* be known to the other party if we
// have divulged the revocation hash, allowing them to homomorphically
// derive the proper private key which corresponds to the revoke public
// key.
builder := txscript.NewScriptBuilder()
builder.AddOp(txscript.OP_IF)
// If a valid signature using the revocation key is presented, then
// allow an immediate spend provided the proper signature.
builder.AddData(revokeKey.SerializeCompressed())
builder.AddOp(txscript.OP_CHECKSIG)
builder.AddOp(txscript.OP_ELSE)
// Otherwise, we can re-claim our funds after a CSV delay of
// 'csvTimeout' timeout blocks, and a valid signature.
builder.AddData(selfKey.SerializeCompressed())
builder.AddOp(txscript.OP_CHECKSIGVERIFY)
builder.AddInt64(int64(csvTimeout))
builder.AddOp(OP_CHECKSEQUENCEVERIFY)
builder.AddOp(txscript.OP_ENDIF)
return builder.Script()
}
// commitScriptUnencumbered constructs the public key script on the commitment
// transaction paying to the "other" party. The constructed output is a normal
// p2wkh output spendable immediately, requiring no contestation period.
func commitScriptUnencumbered(key *btcec.PublicKey) ([]byte, error) {
// This script goes to the "other" party, and it spendable immediately.
builder := txscript.NewScriptBuilder()
builder.AddOp(txscript.OP_0)
builder.AddData(btcutil.Hash160(key.SerializeCompressed()))
return builder.Script()
}
// CommitSpendTimeout constructs a valid witness allowing the owner of a
// particular commitment transaction to spend the output returning settled
// funds back to themselves after a relative block timeout. In order to
// properly spend the transaction, the target input's sequence number should be
// set accordingly based off of the target relative block timeout within the
// redeem script. Additionally, OP_CSV requires that the version of the
// transaction spending a pkscript with OP_CSV within it *must* be >= 2.
func CommitSpendTimeout(signer Signer, signDesc *SignDescriptor,
sweepTx *wire.MsgTx) (wire.TxWitness, error) {
// Ensure the transaction version supports the validation of sequence
// locks and CSV semantics.
if sweepTx.Version < 2 {
return nil, fmt.Errorf("version of passed transaction MUST "+
"be >= 2, not %v", sweepTx.Version)
}
// With the sequence number in place, we're now able to properly sign
// off on the sweep transaction.
sweepSig, err := signer.SignOutputRaw(sweepTx, signDesc)
if err != nil {
return nil, err
}
// Place an empty byte as the first item in the evaluated witness stack
// to force script execution to the timeout spend clause. We need to
// place an empty byte in order to ensure our script is still valid
// from the PoV of nodes that are enforcing minimal OP_IF/OP_NOTIF.
witnessStack := wire.TxWitness(make([][]byte, 3))
witnessStack[0] = append(sweepSig, byte(txscript.SigHashAll))
witnessStack[1] = nil
witnessStack[2] = signDesc.WitnessScript
return witnessStack, nil
}
// CommitSpendRevoke constructs a valid witness allowing a node to sweep the
// settled output of a malicious counterparty who broadcasts a revoked
// commitment transaction.
func CommitSpendRevoke(signer Signer, signDesc *SignDescriptor,
sweepTx *wire.MsgTx) (wire.TxWitness, error) {
sweepSig, err := signer.SignOutputRaw(sweepTx, signDesc)
if err != nil {
return nil, err
}
// Place a 1 as the first item in the evaluated witness stack to
// force script execution to the revocation clause.
witnessStack := wire.TxWitness(make([][]byte, 3))
witnessStack[0] = append(sweepSig, byte(txscript.SigHashAll))
witnessStack[1] = []byte{1}
witnessStack[2] = signDesc.WitnessScript
return witnessStack, nil
}
// CommitSpendNoDelay constructs a valid witness allowing a node to spend their
// settled no-delay output on the counterparty's commitment transaction.
func CommitSpendNoDelay(signer Signer, signDesc *SignDescriptor,
sweepTx *wire.MsgTx) (wire.TxWitness, error) {
// This is just a regular p2wkh spend which looks something like:
// * witness: <sig> <pubkey>
inputScript, err := signer.ComputeInputScript(sweepTx, signDesc)
if err != nil {
return nil, err
}
return wire.TxWitness(inputScript.Witness), nil
}
// DeriveRevocationPubkey derives the revocation public key given the
// counterparty's commitment key, and revocation preimage derived via a
// pseudo-random-function. In the event that we (for some reason) broadcast a
// revoked commitment transaction, then if the other party knows the revocation
// preimage, then they'll be able to derive the corresponding private key to
// this private key by exploiting the homomorphism in the elliptic curve group:
// * https://en.wikipedia.org/wiki/Group_homomorphism#Homomorphisms_of_abelian_groups
//
// The derivation is performed as follows:
//
// revokeKey := commitKey + revokePoint
// := G*k + G*h
// := G * (k+h)
//
// Therefore, once we divulge the revocation preimage, the remote peer is able to
// compute the proper private key for the revokeKey by computing:
// revokePriv := commitPriv + revokePreimge mod N
//
// Where N is the order of the sub-group.
func DeriveRevocationPubkey(commitPubKey *btcec.PublicKey,
revokePreimage []byte) *btcec.PublicKey {
// First we need to convert the revocation hash into a point on the
// elliptic curve.
revokePointX, revokePointY := btcec.S256().ScalarBaseMult(revokePreimage)
// Now that we have the revocation point, we add this to their commitment
// public key in order to obtain the revocation public key.
revokeX, revokeY := btcec.S256().Add(commitPubKey.X, commitPubKey.Y,
revokePointX, revokePointY)
return &btcec.PublicKey{X: revokeX, Y: revokeY}
}
// DeriveRevocationPrivKey derives the revocation private key given a node's
// commitment private key, and the preimage to a previously seen revocation
// hash. Using this derived private key, a node is able to claim the output
// within the commitment transaction of a node in the case that they broadcast
// a previously revoked commitment transaction.
//
// The private key is derived as follwos:
// revokePriv := commitPriv + revokePreimage mod N
//
// Where N is the order of the sub-group.
func DeriveRevocationPrivKey(commitPrivKey *btcec.PrivateKey,
revokePreimage []byte) *btcec.PrivateKey {
// Convert the revocation preimage into a scalar value so we can
// manipulate it within the curve's defined finite field.
revokeScalar := new(big.Int).SetBytes(revokePreimage)
// To derive the revocation private key, we simply add the revocation
// preimage to the commitment private key.
//
// This works since:
// P = G*a + G*b
// = G*(a+b)
// = G*p
revokePriv := revokeScalar.Add(revokeScalar, commitPrivKey.D)
revokePriv = revokePriv.Mod(revokePriv, btcec.S256().N)
privRevoke, _ := btcec.PrivKeyFromBytes(btcec.S256(), revokePriv.Bytes())
return privRevoke
}
// deriveRevocationRoot derives an root unique to a channel given the
// private key for our public key in the 2-of-2 multi-sig, and the remote
// node's multi-sig public key. The seed is derived using the HKDF[1][2]
// instantiated with sha-256. The secret data used is our multi-sig private
// key, with the salt being the remote node's public key.
//
// [1]: https://eprint.iacr.org/2010/264.pdf
// [2]: https://tools.ietf.org/html/rfc5869
func deriveRevocationRoot(derivationRoot *btcec.PrivateKey,
localMultiSigKey *btcec.PublicKey,
remoteMultiSigKey *btcec.PublicKey) *chainhash.Hash {
secret := derivationRoot.Serialize()
salt := localMultiSigKey.SerializeCompressed()
info := remoteMultiSigKey.SerializeCompressed()
seedReader := hkdf.New(sha256.New, secret, salt, info)
// It's safe to ignore the error her as we know for sure that we won't
// be draining the HKDF past its available entropy horizon.
// TODO(roasbeef): revisit...
var root chainhash.Hash
seedReader.Read(root[:])
return &root
}
// SetStateNumHint encodes the current state number within the passed
// commitment transaction by re-purposing the locktime and sequence fields
// in the commitment transaction to encode the obfuscated state number.
// The state number is encoded using 48 bits. The lower 24 bits of the
// locktime are the lower 24 bits of the obfuscated state number and the
// lower 24 bits of the sequence field are the higher 24 bits. Finally
// before encoding, the obfuscater is XOR'd against the state number in
// order to hide the exact state number from the PoV of outside parties.
// TODO(roasbeef): unexport function after bobNode is gone
func SetStateNumHint(commitTx *wire.MsgTx, stateNum uint64,
obsfucator [StateHintSize]byte) error {
// With the current schema we are only able able to encode state num
// hints up to 2^48. Therefore if the passed height is greater than our
// state hint ceiling, then exit early.
if stateNum > maxStateHint {
return fmt.Errorf("unable to encode state, %v is greater "+
"state num that max of %v", stateNum, maxStateHint)
}
if len(commitTx.TxIn) != 1 {
return fmt.Errorf("commitment tx must have exactly 1 input, "+
"instead has %v", len(commitTx.TxIn))
}
// Convert the obfuscator into a uint64, then XOR that against the
// targeted height in order to obfuscate the state number of the
// commitment transaction in the case that either commitment
// transaction is broadcast directly on chain.
var obfs [8]byte
copy(obfs[2:], obsfucator[:])
xorInt := binary.BigEndian.Uint64(obfs[:])
stateNum = stateNum ^ xorInt
// Set the height bit of the sequence number in order to disable any
// sequence locks semantics.
commitTx.TxIn[0].Sequence = uint32(stateNum>>24) | wire.SequenceLockTimeDisabled
commitTx.LockTime = uint32(stateNum&0xFFFFFF) | TimelockShift
return nil
}
// GetStateNumHint recovers the current state number given a commitment
// transaction which has previously had the state number encoded within it via
// setStateNumHint and a shared obsfucator.
//
// See setStateNumHint for further details w.r.t exactly how the state-hints
// are encoded.
func GetStateNumHint(commitTx *wire.MsgTx, obsfucator [StateHintSize]byte) uint64 {
// Convert the obfuscater into a uint64, this will be used to
// de-obfuscate the final recovered state number.
var obfs [8]byte
copy(obfs[2:], obsfucator[:])
xorInt := binary.BigEndian.Uint64(obfs[:])
// Retrieve the state hint from the sequence number and locktime
// of the transaction.
stateNumXor := uint64(commitTx.TxIn[0].Sequence&0xFFFFFF) << 24
stateNumXor |= uint64(commitTx.LockTime & 0xFFFFFF)
// Finally, to obtain the final state number, we XOR by the obfuscater
// value to de-obfuscate the state number.
return stateNumXor ^ xorInt
}