1286 lines
49 KiB
Go
1286 lines
49 KiB
Go
package lnwallet
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import (
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"bytes"
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"crypto/sha256"
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"encoding/binary"
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"fmt"
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"math/big"
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"golang.org/x/crypto/hkdf"
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"golang.org/x/crypto/ripemd160"
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"github.com/roasbeef/btcd/btcec"
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"github.com/roasbeef/btcd/chaincfg/chainhash"
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"github.com/roasbeef/btcd/txscript"
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"github.com/roasbeef/btcd/wire"
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"github.com/roasbeef/btcutil"
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)
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var (
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// TODO(roasbeef): remove these and use the one's defined in txscript
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// within testnet-L.
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// SequenceLockTimeSeconds is the 22nd bit which indicates the lock
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// time is in seconds.
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SequenceLockTimeSeconds = uint32(1 << 22)
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// TimelockShift is used to make sure the commitment transaction is
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// spendable by setting the locktime with it so that it is larger than
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// 500,000,000, thus interpreting it as Unix epoch timestamp and not
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// a block height. It is also smaller than the current timestamp which
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// has bit (1 << 30) set, so there is no risk of having the commitment
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// transaction be rejected. This way we can safely use the lower 24 bits
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// of the locktime field for part of the obscured commitment transaction
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// number.
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TimelockShift = uint32(1 << 29)
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)
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const (
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// StateHintSize is the total number of bytes used between the sequence
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// number and locktime of the commitment transaction use to encode a hint
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// to the state number of a particular commitment transaction.
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StateHintSize = 6
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// maxStateHint is the maximum state number we're able to encode using
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// StateHintSize bytes amongst the sequence number and locktime fields
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// of the commitment transaction.
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maxStateHint uint64 = (1 << 48) - 1
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)
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// witnessScriptHash generates a pay-to-witness-script-hash public key script
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// paying to a version 0 witness program paying to the passed redeem script.
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func witnessScriptHash(witnessScript []byte) ([]byte, error) {
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bldr := txscript.NewScriptBuilder()
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bldr.AddOp(txscript.OP_0)
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scriptHash := sha256.Sum256(witnessScript)
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bldr.AddData(scriptHash[:])
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return bldr.Script()
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}
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// genMultiSigScript generates the non-p2sh'd multisig script for 2 of 2
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// pubkeys.
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func genMultiSigScript(aPub, bPub []byte) ([]byte, error) {
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if len(aPub) != 33 || len(bPub) != 33 {
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return nil, fmt.Errorf("Pubkey size error. Compressed pubkeys only")
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}
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// Swap to sort pubkeys if needed. Keys are sorted in lexicographical
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// order. The signatures within the scriptSig must also adhere to the
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// order, ensuring that the signatures for each public key appears in
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// the proper order on the stack.
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if bytes.Compare(aPub, bPub) == 1 {
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aPub, bPub = bPub, aPub
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}
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bldr := txscript.NewScriptBuilder()
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bldr.AddOp(txscript.OP_2)
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bldr.AddData(aPub) // Add both pubkeys (sorted).
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bldr.AddData(bPub)
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bldr.AddOp(txscript.OP_2)
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bldr.AddOp(txscript.OP_CHECKMULTISIG)
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return bldr.Script()
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}
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// GenFundingPkScript creates a redeem script, and its matching p2wsh
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// output for the funding transaction.
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func GenFundingPkScript(aPub, bPub []byte, amt int64) ([]byte, *wire.TxOut, error) {
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// As a sanity check, ensure that the passed amount is above zero.
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if amt <= 0 {
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return nil, nil, fmt.Errorf("can't create FundTx script with " +
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"zero, or negative coins")
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}
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// First, create the 2-of-2 multi-sig script itself.
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witnessScript, err := genMultiSigScript(aPub, bPub)
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if err != nil {
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return nil, nil, err
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}
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// With the 2-of-2 script in had, generate a p2wsh script which pays
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// to the funding script.
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pkScript, err := witnessScriptHash(witnessScript)
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if err != nil {
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return nil, nil, err
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}
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return witnessScript, wire.NewTxOut(amt, pkScript), nil
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}
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// SpendMultiSig generates the witness stack required to redeem the 2-of-2 p2wsh
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// multi-sig output.
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func SpendMultiSig(witnessScript, pubA, sigA, pubB, sigB []byte) [][]byte {
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witness := make([][]byte, 4)
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// When spending a p2wsh multi-sig script, rather than an OP_0, we add
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// a nil stack element to eat the extra pop.
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witness[0] = nil
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// When initially generating the witnessScript, we sorted the serialized
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// public keys in descending order. So we do a quick comparison in order
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// ensure the signatures appear on the Script Virtual Machine stack in
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// the correct order.
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if bytes.Compare(pubA, pubB) == 1 {
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witness[1] = sigB
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witness[2] = sigA
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} else {
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witness[1] = sigA
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witness[2] = sigB
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}
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// Finally, add the preimage as the last witness element.
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witness[3] = witnessScript
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return witness
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}
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// FindScriptOutputIndex finds the index of the public key script output
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// matching 'script'. Additionally, a boolean is returned indicating if a
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// matching output was found at all.
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//
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// NOTE: The search stops after the first matching script is found.
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func FindScriptOutputIndex(tx *wire.MsgTx, script []byte) (bool, uint32) {
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found := false
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index := uint32(0)
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for i, txOut := range tx.TxOut {
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if bytes.Equal(txOut.PkScript, script) {
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found = true
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index = uint32(i)
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break
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}
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}
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return found, index
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}
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// ripemd160H calculates the ripemd160 of the passed byte slice. This is used to
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// calculate the intermediate hash for payment pre-images. Payment hashes are
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// the result of ripemd160(sha256(paymentPreimage)). As a result, the value
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// passed in should be the sha256 of the payment hash.
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func ripemd160H(d []byte) []byte {
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h := ripemd160.New()
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h.Write(d)
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return h.Sum(nil)
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}
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// senderHTLCScript constructs the public key script for an outgoing HTLC
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// output payment for the sender's version of the commitment transaction. The
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// possible script paths from this output include:
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//
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// * The sender timing out the HTLC using the second level HTLC timeout
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// transaction.
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// * The receiver of the HTLC claiming the output on-chain with the payment
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// preimage.
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// * The receiver of the HTLC sweeping all the funds in the case that a
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// revoked commitment transaction bearing this HTLC was broadcast.
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//
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// Possible Input Scripts:
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// SENDR: <0> <sendr sig> <recvr sig> <0> (spend using HTLC timeout transaction)
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// RECVR: <recvr sig> <preimage>
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// REVOK: <revoke sig> <revoke key>
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// * receiver revoke
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//
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// OP_DUP OP_HASH160 <revocation key hash160> OP_EQUAL
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// OP_IF
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// OP_CHECKSIG
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// OP_ELSE
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// <recv key>
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// OP_SWAP OP_SIZE 32 OP_EQUAL
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// OP_NOTIF
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// OP_DROP 2 OP_SWAP <sender key> 2 OP_CHECKMULTISIG
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// OP_ELSE
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// OP_HASH160 <ripemd160(payment hash)> OP_EQUALVERIFY
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// OP_ENDIF
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// OP_ENDIF
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func senderHTLCScript(senderKey, receiverKey, revocationKey *btcec.PublicKey,
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paymentHash []byte) ([]byte, error) {
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builder := txscript.NewScriptBuilder()
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// The opening operations are used to determine if this is the receiver
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// of the HTLC attempting to sweep all the funds due to a contract
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// breach. In this case, they'll place the revocation key at the top of
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// the stack.
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builder.AddOp(txscript.OP_DUP)
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builder.AddOp(txscript.OP_HASH160)
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builder.AddData(btcutil.Hash160(revocationKey.SerializeCompressed()))
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builder.AddOp(txscript.OP_EQUAL)
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// If the hash matches, then this is the revocation clause. The output
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// can be spent if the check sig operation passes.
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builder.AddOp(txscript.OP_IF)
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builder.AddOp(txscript.OP_CHECKSIG)
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// Otherwise, this may either be the receiver of the HTLC claiming with
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// the pre-image, or the sender of the HTLC sweeping the output after
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// it has timed out.
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builder.AddOp(txscript.OP_ELSE)
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// We'll do a bit of set up by pushing the receiver's key on the top of
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// the stack. This will be needed later if we decide that this is the
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// sender activating the time out clause with the HTLC timeout
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// transaction.
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builder.AddData(receiverKey.SerializeCompressed())
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// Atm, the top item of the stack is the receiverKey's so we use a swap
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// to expose what is either the payment pre-image or a signature.
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builder.AddOp(txscript.OP_SWAP)
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// With the top item swapped, check if it's 32 bytes. If so, then this
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// *may* be the payment pre-image.
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builder.AddOp(txscript.OP_SIZE)
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builder.AddInt64(32)
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builder.AddOp(txscript.OP_EQUAL)
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// If it isn't then this might be the sender of the HTLC activating the
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// time out clause.
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builder.AddOp(txscript.OP_NOTIF)
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// We'll drop the OP_IF return value off the top of the stack so we can
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// reconstruct the multi-sig script used as an off-chain covenant. If
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// two valid signatures are provided, ten then output will be deemed as
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// spendable.
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builder.AddOp(txscript.OP_DROP)
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builder.AddOp(txscript.OP_2)
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builder.AddOp(txscript.OP_SWAP)
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builder.AddData(senderKey.SerializeCompressed())
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builder.AddOp(txscript.OP_2)
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builder.AddOp(txscript.OP_CHECKMULTISIG)
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// Otherwise, then the only other case is that this is the receiver of
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// the HTLC sweeping it on-chain with the payment pre-image.
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builder.AddOp(txscript.OP_ELSE)
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// Hash the top item of the stack and compare it with the hash160 of
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// the payment hash, which is already the sha256 of the payment
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// pre-image. By using this little trick we're able save space on-chain
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// as the witness includes a 20-byte hash rather than a 32-byte hash.
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builder.AddOp(txscript.OP_HASH160)
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builder.AddData(ripemd160H(paymentHash))
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builder.AddOp(txscript.OP_EQUALVERIFY)
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// This checks the receiver's signature so that a third party with
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// knowledge of the payment preimage still cannot steal the output.
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builder.AddOp(txscript.OP_CHECKSIG)
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// Close out the OP_IF statement above.
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builder.AddOp(txscript.OP_ENDIF)
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// Close out the OP_IF statement at the top of the script.
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builder.AddOp(txscript.OP_ENDIF)
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return builder.Script()
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}
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// senderHtlcSpendRevoke constructs a valid witness allowing the receiver of an
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// HTLC to claim the output with knowledge of the revocation private key in the
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// scenario that the sender of the HTLC broadcasts a previously revoked
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// commitment transaction. A valid spend requires knowledge of the private key
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// that corresponds to their revocation base point and also the private key fro
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// the per commitment point, and a valid signature under the combined public
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// key.
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func senderHtlcSpendRevoke(signer Signer, signDesc *SignDescriptor,
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revokeKey *btcec.PublicKey, sweepTx *wire.MsgTx) (wire.TxWitness, error) {
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sweepSig, err := signer.SignOutputRaw(sweepTx, signDesc)
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if err != nil {
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return nil, err
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}
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// The stack required to sweep a revoke HTLC output consists simply of
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// the exact witness stack as one of a regular p2wkh spend. The only
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// difference is that the keys used were derived in an adversarial
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// manner in order to encode the revocation contract into a sig+key
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// pair.
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witnessStack := wire.TxWitness(make([][]byte, 3))
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witnessStack[0] = append(sweepSig, byte(txscript.SigHashAll))
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witnessStack[1] = revokeKey.SerializeCompressed()
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witnessStack[2] = signDesc.WitnessScript
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return witnessStack, nil
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}
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// SenderHtlcSpendRevoke constructs a valid witness allowing the receiver of an
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// HTLC to claim the output with knowledge of the revocation private key in the
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// scenario that the sender of the HTLC broadcasts a previously revoked
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// commitment transaction. This method first derives the appropriate revocation
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// key, and requires that the provided SignDescriptor has a local revocation
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// basepoint and commitment secret in the PubKey and DoubleTweak fields,
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// respectively.
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func SenderHtlcSpendRevoke(signer Signer, signDesc *SignDescriptor,
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sweepTx *wire.MsgTx) (wire.TxWitness, error) {
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// Derive the revocation key using the local revocation base point and
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// commitment point.
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revokeKey := DeriveRevocationPubkey(signDesc.PubKey,
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signDesc.DoubleTweak.PubKey())
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return senderHtlcSpendRevoke(signer, signDesc, revokeKey, sweepTx)
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}
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// senderHtlcSpendRedeem constructs a valid witness allowing the receiver of an
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// HTLC to redeem the pending output in the scenario that the sender broadcasts
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// their version of the commitment transaction. A valid spend requires
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// knowledge of the payment preimage, and a valid signature under the receivers
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// public key.
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func senderHtlcSpendRedeem(signer Signer, signDesc *SignDescriptor,
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sweepTx *wire.MsgTx, paymentPreimage []byte) (wire.TxWitness, error) {
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sweepSig, err := signer.SignOutputRaw(sweepTx, signDesc)
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if err != nil {
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return nil, err
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}
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// The stack require to spend this output is simply the signature
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// generated above under the receiver's public key, and the payment
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// pre-image.
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witnessStack := wire.TxWitness(make([][]byte, 3))
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witnessStack[0] = append(sweepSig, byte(txscript.SigHashAll))
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witnessStack[1] = paymentPreimage
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witnessStack[2] = signDesc.WitnessScript
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return witnessStack, nil
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}
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// senderHtlcSpendTimeout constructs a valid witness allowing the sender of an
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// HTLC to activate the time locked covenant clause of a soon to be expired
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// HTLC. This script simply spends the multi-sig output using the
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// pre-generated HTLC timeout transaction.
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func senderHtlcSpendTimeout(receiverSig []byte, signer Signer,
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signDesc *SignDescriptor, htlcTimeoutTx *wire.MsgTx) (wire.TxWitness, error) {
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sweepSig, err := signer.SignOutputRaw(htlcTimeoutTx, signDesc)
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if err != nil {
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return nil, err
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}
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// We place a zero as the first item of the evaluated witness stack in
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// order to force Script execution to the HTLC timeout clause. The
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// second zero is require to consume the extra pop due to a bug in the
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// original OP_CHECKMULTISIG.
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witnessStack := wire.TxWitness(make([][]byte, 5))
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witnessStack[0] = nil
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witnessStack[1] = append(receiverSig, byte(txscript.SigHashAll))
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witnessStack[2] = append(sweepSig, byte(txscript.SigHashAll))
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witnessStack[3] = nil
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witnessStack[4] = signDesc.WitnessScript
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return witnessStack, nil
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}
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// receiverHTLCScript constructs the public key script for an incoming HTLC
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// output payment for the receiver's version of the commitment transaction. The
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// possible execution paths from this script include:
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// * The receiver of the HTLC uses it's second level HTLC transaction to
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// advance the state of the HTLC into the delay+claim state.
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// * The sender of the HTLC sweeps all the funds of the HTLC as a breached
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// commitment was broadcast.
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// * The sender of the HTLC sweeps the HTLC on-chain after the timeout period
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// of the HTLC has passed.
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//
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// Possible Input Scripts:
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// RECVR: <0> <sender sig> <recvr sig> <preimage>
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// REVOK: <sig> <key>
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// SENDR: <sig> 0
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//
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//
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// OP_DUP OP_HASH160 <revocation key hash160> OP_EQUAL
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// OP_IF
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// OP_CHECKSIG
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// OP_ELSE
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// <sendr key>
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// OP_SWAP OP_SIZE 32 OP_EQUAL
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// OP_IF
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// OP_HASH160 <ripemd160(payment hash)> OP_EQUALVERIFY
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// 2 OP_SWAP <recvr key> 2 OP_CHECKMULTISIG
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// OP_ELSE
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// OP_DROP <cltv expiry> OP_CHECKLOCKTIMEVERIFY OP_DROP
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// OP_CHECKSIG
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// OP_ENDIF
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// OP_ENDIF
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func receiverHTLCScript(cltvExipiry uint32, senderKey,
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receiverKey, revocationKey *btcec.PublicKey, paymentHash []byte) ([]byte, error) {
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builder := txscript.NewScriptBuilder()
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|
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// The opening operations are used to determine if this is the sender
|
|
// of the HTLC attempting to sweep all the funds due to a contract
|
|
// breach. In this case, they'll place the revocation key at the top of
|
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// the stack.
|
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builder.AddOp(txscript.OP_DUP)
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builder.AddOp(txscript.OP_HASH160)
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builder.AddData(btcutil.Hash160(revocationKey.SerializeCompressed()))
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builder.AddOp(txscript.OP_EQUAL)
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// If the hash matches, then this is the revocation clause. The output
|
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// can be spent if the check sig operation passes.
|
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builder.AddOp(txscript.OP_IF)
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builder.AddOp(txscript.OP_CHECKSIG)
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|
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// Otherwise, this may either be the receiver of the HTLC starting the
|
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// claiming process via the second level HTLC success transaction and
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// the pre-image, or the sender of the HTLC sweeping the output after
|
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// it has timed out.
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builder.AddOp(txscript.OP_ELSE)
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|
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// We'll do a bit of set up by pushing the sender's key on the top of
|
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// the stack. This will be needed later if we decide that this is the
|
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// receiver transitioning the output to the claim state using their
|
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// second-level HTLC success transaction.
|
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builder.AddData(senderKey.SerializeCompressed())
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// Atm, the top item of the stack is the sender's key so we use a swap
|
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// to expose what is either the payment pre-image or something else.
|
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builder.AddOp(txscript.OP_SWAP)
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|
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// With the top item swapped, check if it's 32 bytes. If so, then this
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// *may* be the payment pre-image.
|
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builder.AddOp(txscript.OP_SIZE)
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builder.AddInt64(32)
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builder.AddOp(txscript.OP_EQUAL)
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// If the item on the top of the stack is 32-bytes, then it is the
|
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// proper size, so this indicates that the receiver of the HTLC is
|
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// attempting to claim the output on-chain by transitioning the state
|
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// of the HTLC to delay+claim.
|
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builder.AddOp(txscript.OP_IF)
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|
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// Next we'll hash the item on the top of the stack, if it matches the
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// payment pre-image, then we'll continue. Otherwise, we'll end the
|
|
// script here as this is the invalid payment pre-image.
|
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builder.AddOp(txscript.OP_HASH160)
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builder.AddData(ripemd160H(paymentHash))
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builder.AddOp(txscript.OP_EQUALVERIFY)
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|
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// If the payment hash matches, then we'll also need to satisfy the
|
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// multi-sig covenant by providing both signatures of the sender and
|
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// receiver. If the convenient is met, then we'll allow the spending of
|
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// this output, but only by the HTLC success transaction.
|
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builder.AddOp(txscript.OP_2)
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builder.AddOp(txscript.OP_SWAP)
|
|
builder.AddData(receiverKey.SerializeCompressed())
|
|
builder.AddOp(txscript.OP_2)
|
|
builder.AddOp(txscript.OP_CHECKMULTISIG)
|
|
|
|
// Otherwise, this might be the sender of the HTLC attempting to sweep
|
|
// it on-chain after the timeout.
|
|
builder.AddOp(txscript.OP_ELSE)
|
|
|
|
// We'll drop the extra item (which is the output from evaluating the
|
|
// OP_EQUAL) above from the stack.
|
|
builder.AddOp(txscript.OP_DROP)
|
|
|
|
// With that item dropped off, we can now enforce the absolute
|
|
// lock-time required to timeout the HTLC. If the time has passed, then
|
|
// we'll proceed with a checksig to ensure that this is actually the
|
|
// sender of he original HLTC.
|
|
builder.AddInt64(int64(cltvExipiry))
|
|
builder.AddOp(txscript.OP_CHECKLOCKTIMEVERIFY)
|
|
builder.AddOp(txscript.OP_DROP)
|
|
builder.AddOp(txscript.OP_CHECKSIG)
|
|
|
|
// Close out the inner if statement.
|
|
builder.AddOp(txscript.OP_ENDIF)
|
|
|
|
// Close out the outer if statement.
|
|
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. This clause transitions the state of the HLTC
|
|
// output into the delay+claim state by activating the off-chain covenant bound
|
|
// by the 2-of-2 multi-sig output. The HTLC success timeout transaction being
|
|
// signed has a relative timelock delay enforced by its sequence number. This
|
|
// delay give the sender of the HTLC enough time to revoke the output if this
|
|
// is a breach commitment transaction.
|
|
func receiverHtlcSpendRedeem(senderSig, paymentPreimage []byte,
|
|
signer Signer, signDesc *SignDescriptor,
|
|
htlcSuccessTx *wire.MsgTx) (wire.TxWitness, error) {
|
|
|
|
// First, we'll generate a signature for the HTLC success transaction.
|
|
// The signDesc should be signing with the public key used as the
|
|
// receiver's public key and also the correct single tweak.
|
|
sweepSig, err := signer.SignOutputRaw(htlcSuccessTx, signDesc)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// The final witness stack is used the provide the script with the
|
|
// payment pre-image, and also execute the multi-sig clause after the
|
|
// pre-images matches. We add a nil item at the bottom of the stack in
|
|
// order to consume the extra pop within OP_CHECKMULTISIG.
|
|
witnessStack := wire.TxWitness(make([][]byte, 5))
|
|
witnessStack[0] = nil
|
|
witnessStack[1] = append(senderSig, byte(txscript.SigHashAll))
|
|
witnessStack[2] = append(sweepSig, byte(txscript.SigHashAll))
|
|
witnessStack[3] = paymentPreimage
|
|
witnessStack[4] = signDesc.WitnessScript
|
|
|
|
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(signer Signer, signDesc *SignDescriptor,
|
|
revokeKey *btcec.PublicKey, sweepTx *wire.MsgTx) (wire.TxWitness, error) {
|
|
|
|
// First, we'll generate a signature for the sweep transaction. The
|
|
// signDesc should be signing with the public key used as the fully
|
|
// derived revocation public key and also the correct double tweak
|
|
// value.
|
|
sweepSig, err := signer.SignOutputRaw(sweepTx, signDesc)
|
|
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, 3))
|
|
witnessStack[0] = append(sweepSig, byte(txscript.SigHashAll))
|
|
witnessStack[1] = revokeKey.SerializeCompressed()
|
|
witnessStack[2] = signDesc.WitnessScript
|
|
|
|
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. This method first derives the appropriate revocation
|
|
// key, and requires that the provided SignDescriptor has a local revocation
|
|
// basepoint and commitment secret in the PubKey and DoubleTweak fields,
|
|
// respectively.
|
|
func ReceiverHtlcSpendRevoke(signer Signer, signDesc *SignDescriptor,
|
|
sweepTx *wire.MsgTx) (wire.TxWitness, error) {
|
|
|
|
// Derive the revocation key using the local revocation base point and
|
|
// commitment point.
|
|
revokeKey := DeriveRevocationPubkey(signDesc.PubKey,
|
|
signDesc.DoubleTweak.PubKey())
|
|
|
|
return receiverHtlcSpendRevoke(signer, signDesc, revokeKey, sweepTx)
|
|
}
|
|
|
|
// 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.
|
|
//
|
|
// NOTE: The target input of the passed transaction MUST NOT have a final
|
|
// sequence number. Otherwise, the OP_CHECKLOCKTIMEVERIFY check will fail.
|
|
func receiverHtlcSpendTimeout(signer Signer, signDesc *SignDescriptor,
|
|
sweepTx *wire.MsgTx, cltvExpiry 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 = cltvExpiry
|
|
|
|
// With the lock time on the transaction set, we'll not generate a
|
|
// signature for the sweep transaction. The passed sign descriptor
|
|
// should be created using the raw public key of the sender (w/o the
|
|
// single tweak applied), and the single tweak set to the proper value
|
|
// taking into account the current state's point.
|
|
sweepSig, err := signer.SignOutputRaw(sweepTx, signDesc)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
witnessStack := wire.TxWitness(make([][]byte, 3))
|
|
witnessStack[0] = append(sweepSig, byte(txscript.SigHashAll))
|
|
witnessStack[1] = nil
|
|
witnessStack[2] = signDesc.WitnessScript
|
|
|
|
return witnessStack, nil
|
|
}
|
|
|
|
// createHtlcTimeoutTx creates a transaction that spends the HTLC output on the
|
|
// commitment transaction of the peer that created an HTLC (the sender). This
|
|
// transaction essentially acts as an off-chain covenant as it spends a 2-of-2
|
|
// multi-sig output. This output requires a signature from both the sender and
|
|
// receiver of the HTLC. By using a distinct transaction, we're able to
|
|
// uncouple the timeout and delay clauses of the HTLC contract. This
|
|
// transaction is locked with an absolute lock-time so the sender can only
|
|
// attempt to claim the output using it after the lock time has passed.
|
|
//
|
|
// In order to spend the HTLC output, the witness for the passed transaction
|
|
// should be:
|
|
// * <0> <sender sig> <receiver sig> <0>
|
|
//
|
|
// NOTE: The passed amount for the HTLC should take into account the required
|
|
// fee rate at the time the HTLC was created. The fee should be able to
|
|
// entirely pay for this (tiny: 1-in 1-out) transaction.
|
|
func createHtlcTimeoutTx(htlcOutput wire.OutPoint, htlcAmt btcutil.Amount,
|
|
cltvExpiry, csvDelay uint32,
|
|
revocationKey, delayKey *btcec.PublicKey) (*wire.MsgTx, error) {
|
|
|
|
// Create a version two transaction (as the success version of this
|
|
// spends an output with a CSV timeout), and set the lock-time to the
|
|
// specified absolute lock-time in blocks.
|
|
timeoutTx := wire.NewMsgTx(2)
|
|
timeoutTx.LockTime = cltvExpiry
|
|
|
|
// The input to the transaction is the outpoint that creates the
|
|
// original HTLC on the sender's commitment transaction.
|
|
timeoutTx.AddTxIn(&wire.TxIn{
|
|
PreviousOutPoint: htlcOutput,
|
|
})
|
|
|
|
// Next, we'll generate the script used as the output for all second
|
|
// level HTLC which forces a covenant w.r.t what can be done with all
|
|
// HTLC outputs.
|
|
witnessScript, err := secondLevelHtlcScript(revocationKey, delayKey,
|
|
csvDelay)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
pkScript, err := witnessScriptHash(witnessScript)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// Finally, the output is simply the amount of the HTLC (minus the
|
|
// required fees), paying to the regular second level HTLC script.
|
|
timeoutTx.AddTxOut(&wire.TxOut{
|
|
Value: int64(htlcAmt),
|
|
PkScript: pkScript,
|
|
})
|
|
|
|
return timeoutTx, nil
|
|
}
|
|
|
|
// createHtlcSuccessTx creats a transaction that spends the output on the
|
|
// commitment transaction of the peer that receives an HTLC. This transaction
|
|
// essentially acts as an off-chain covenant as it's only permitted to spend
|
|
// the designated HTLC output, and also that spend can _only_ be used as a
|
|
// state transition to create another output which actually allows redemption
|
|
// or revocation of an HTLC.
|
|
//
|
|
// In order to spend the HTLC output, the witness for the passed transaction
|
|
// should be:
|
|
// * <0> <sender sig> <recvr sig> <preimage>
|
|
func createHtlcSuccessTx(htlcOutput wire.OutPoint, htlcAmt btcutil.Amount,
|
|
csvDelay uint32,
|
|
revocationKey, delayKey *btcec.PublicKey) (*wire.MsgTx, error) {
|
|
|
|
// Create a version two transaction (as the success version of this
|
|
// spends an output with a CSV timeout).
|
|
successTx := wire.NewMsgTx(2)
|
|
|
|
// The input to the transaction is the outpoint that creates the
|
|
// original HTLC on the sender's commitment transaction.
|
|
successTx.AddTxIn(&wire.TxIn{
|
|
PreviousOutPoint: htlcOutput,
|
|
})
|
|
|
|
// Next, we'll generate the script used as the output for all second
|
|
// level HTLC which forces a covenant w.r.t what can be done with all
|
|
// HTLC outputs.
|
|
witnessScript, err := secondLevelHtlcScript(revocationKey, delayKey,
|
|
csvDelay)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
pkScript, err := witnessScriptHash(witnessScript)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// Finally, the output is simply the amount of the HTLC (minus the
|
|
// required fees), paying to the timeout script.
|
|
successTx.AddTxOut(&wire.TxOut{
|
|
Value: int64(htlcAmt),
|
|
PkScript: pkScript,
|
|
})
|
|
|
|
return successTx, nil
|
|
}
|
|
|
|
// secondLevelHtlcScript is the uniform script that's used as the output for
|
|
// the second-level HTLC transactions. The second level transaction act as a
|
|
// sort of covenant, ensuring that an 2-of-2 multi-sig output can only be
|
|
// spent in a particular way, and to a particular output.
|
|
//
|
|
// Possible Input Scripts:
|
|
// * To revoke an HTLC output that has been transitioned to the claim+delay
|
|
// state:
|
|
// * <revoke sig> 1
|
|
//
|
|
// * To claim and HTLC output, either with a pre-image or due to a timeout:
|
|
// * <delay sig> 0
|
|
//
|
|
// OP_IF
|
|
// <revoke key>
|
|
// OP_ELSE
|
|
// <delay in blocks>
|
|
// OP_CHECKSEQUENCEVERIFY
|
|
// OP_DROP
|
|
// <delay key>
|
|
// OP_ENDIF
|
|
// OP_CHECKSIG
|
|
//
|
|
// TODO(roasbeef): possible renames for second-level
|
|
// * transition?
|
|
// * covenant output
|
|
func secondLevelHtlcScript(revocationKey, delayKey *btcec.PublicKey,
|
|
csvDelay uint32) ([]byte, error) {
|
|
|
|
builder := txscript.NewScriptBuilder()
|
|
|
|
// If this is the revocation clause for this script is to be executed,
|
|
// the spender will push a 1, forcing us to hit the true clause of this
|
|
// if statement.
|
|
builder.AddOp(txscript.OP_IF)
|
|
|
|
// If this this is the revocation case, then we'll push the revocation
|
|
// public key on the stack.
|
|
builder.AddData(revocationKey.SerializeCompressed())
|
|
|
|
// Otherwise, this is either the sender or receiver of the HTLC
|
|
// attempting to claim the HTLC output.
|
|
builder.AddOp(txscript.OP_ELSE)
|
|
|
|
// In order to give the other party time to execute the revocation
|
|
// clause above, we require a relative timeout to pass before the
|
|
// output can be spent.
|
|
builder.AddInt64(int64(csvDelay))
|
|
builder.AddOp(txscript.OP_CHECKSEQUENCEVERIFY)
|
|
builder.AddOp(txscript.OP_DROP)
|
|
|
|
// If the relative timelock passes, then we'll add the delay key to the
|
|
// stack to ensure that we properly authenticate the spending party.
|
|
builder.AddData(delayKey.SerializeCompressed())
|
|
|
|
// Close out the if statement.
|
|
builder.AddOp(txscript.OP_ENDIF)
|
|
|
|
// In either case, we'll ensure that only either the party possessing
|
|
// the revocation private key, or the delay private key is able to
|
|
// spend this output.
|
|
builder.AddOp(txscript.OP_CHECKSIG)
|
|
|
|
return builder.Script()
|
|
}
|
|
|
|
// htlcSpendSuccess spends a second-level HTLC output. This function is to be
|
|
// used by the sender of an HTLC to claim the output after a relative timeout
|
|
// or the receiver of the HTLC to claim on-chain with the pre-image.
|
|
func htlcSpendSuccess(signer Signer, signDesc *SignDescriptor,
|
|
sweepTx *wire.MsgTx, csvDelay uint32) (wire.TxWitness, error) {
|
|
|
|
// 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, csvDelay)
|
|
|
|
// Finally, OP_CSV requires that the version of the transaction
|
|
// spending a pkscript with OP_CSV within it *must* be >= 2.
|
|
sweepTx.Version = 2
|
|
|
|
// As we mutated the transaction, we'll re-calculate the sighashes for
|
|
// this instance.
|
|
signDesc.SigHashes = txscript.NewTxSigHashes(sweepTx)
|
|
|
|
// With the proper sequence an version set, we'll now sign the timeout
|
|
// transaction using the passed signed descriptor. In order to generate
|
|
// a valid signature, then signDesc should be using the base delay
|
|
// public key, and the proper single tweak bytes.
|
|
sweepSig, err := signer.SignOutputRaw(sweepTx, signDesc)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// We set a zero as the first element the witness stack (ignoring the
|
|
// witness script), in order to force execution to the second portion
|
|
// of the if clause.
|
|
witnessStack := wire.TxWitness(make([][]byte, 3))
|
|
witnessStack[0] = append(sweepSig, byte(txscript.SigHashAll))
|
|
witnessStack[1] = nil
|
|
witnessStack[2] = signDesc.WitnessScript
|
|
|
|
return witnessStack, nil
|
|
}
|
|
|
|
// htlcTimeoutRevoke spends a second-level HTLC output. This function is to be
|
|
// used by the sender or receiver of an HTLC to claim the HTLC after a revoked
|
|
// commitment transaction was broadcast.
|
|
func htlcSpendRevoke(signer Signer, signDesc *SignDescriptor,
|
|
revokeTx *wire.MsgTx) (wire.TxWitness, error) {
|
|
|
|
// We don't need any spacial modifications to the transaction as this
|
|
// is just sweeping a revoked HTLC output. So we'll generate a regular
|
|
// witness signature.
|
|
sweepSig, err := signer.SignOutputRaw(revokeTx, signDesc)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// We set a one as the first element the witness stack (ignoring the
|
|
// witness script), in order to force execution to the revocation
|
|
// clause in the second level HTLC script.
|
|
witnessStack := wire.TxWitness(make([][]byte, 3))
|
|
witnessStack[0] = append(sweepSig, byte(txscript.SigHashAll))
|
|
witnessStack[1] = []byte{1}
|
|
witnessStack[2] = signDesc.WitnessScript
|
|
|
|
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_ELSE
|
|
// <numRelativeBlocks> OP_CHECKSEQUENCEVERIFY OP_DROP
|
|
// <timeKey>
|
|
// OP_ENDIF
|
|
// OP_CHECKSIG
|
|
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_ELSE)
|
|
|
|
// Otherwise, we can re-claim our funds after a CSV delay of
|
|
// 'csvTimeout' timeout blocks, and a valid signature.
|
|
builder.AddInt64(int64(csvTimeout))
|
|
builder.AddOp(txscript.OP_CHECKSEQUENCEVERIFY)
|
|
builder.AddOp(txscript.OP_DROP)
|
|
builder.AddData(selfKey.SerializeCompressed())
|
|
|
|
builder.AddOp(txscript.OP_ENDIF)
|
|
|
|
// Finally, we'll validate the signature against the public key that's
|
|
// left on the top of the stack.
|
|
builder.AddOp(txscript.OP_CHECKSIG)
|
|
|
|
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.
|
|
//
|
|
// NOTE: The passed SignDescriptor should include the raw (untweaked)
|
|
// revocation base public key of the receiver and also the proper double tweak
|
|
// value based on the commitment secret of the revoked commitment.
|
|
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.
|
|
//
|
|
// NOTE: The passed SignDescriptor should include the raw (untweaked) public
|
|
// key of the receiver and also the proper single tweak value based on the
|
|
// current commitment point.
|
|
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>
|
|
sweepSig, err := signer.SignOutputRaw(sweepTx, signDesc)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// Finally, we'll manually craft the witness. The witness here is the
|
|
// exact same as a regular p2wkh witness, but we'll need to ensure that
|
|
// we use the tweaked public key as the last item in the witness stack
|
|
// which was originally used to created the pkScript we're spending.
|
|
witness := make([][]byte, 2)
|
|
witness[0] = append(sweepSig, byte(txscript.SigHashAll))
|
|
witness[1] = TweakPubKeyWithTweak(
|
|
signDesc.PubKey, signDesc.SingleTweak,
|
|
).SerializeCompressed()
|
|
|
|
return witness, nil
|
|
}
|
|
|
|
// SingleTweakBytes computes set of bytes we call the single tweak. The purpose
|
|
// of the single tweak is to randomize all regular delay and payment base
|
|
// points. To do this, we generate a hash that binds the commitment point to
|
|
// the pay/delay base point. The end end results is that the basePoint is
|
|
// tweaked as follows:
|
|
//
|
|
// * key = basePoint + sha256(commitPoint || basePoint)*G
|
|
func SingleTweakBytes(commitPoint, basePoint *btcec.PublicKey) []byte {
|
|
h := sha256.New()
|
|
h.Write(commitPoint.SerializeCompressed())
|
|
h.Write(basePoint.SerializeCompressed())
|
|
return h.Sum(nil)
|
|
}
|
|
|
|
// TweakPubKey tweaks a public base point given a per commitment point. The per
|
|
// commitment point is a unique point on our target curve for each commitment
|
|
// transaction. When tweaking a local base point for use in a remote commitment
|
|
// transaction, the remote party's current per commitment point is to be used.
|
|
// The opposite applies for when tweaking remote keys. Precisely, the following
|
|
// operation is used to "tweak" public keys:
|
|
//
|
|
// tweakPub := basePoint + sha256(commitPoint || basePoint) * G
|
|
// := G*k + sha256(commitPoint || basePoint)*G
|
|
// := G*(k + sha256(commitPoint || basePoint))
|
|
//
|
|
// Therefore, if a party possess the value k, the private key of the base
|
|
// point, then they are able to derive the private key by computing: compute
|
|
// the proper private key for the revokeKey by computing:
|
|
//
|
|
// revokePriv := k + sha256(commitPoint || basePoint) mod N
|
|
//
|
|
// Where N is the order of the sub-group.
|
|
//
|
|
// The rationale for tweaking all public keys used within the commitment
|
|
// contracts is to ensure that all keys are properly delinearized to avoid any
|
|
// funny business when jointly collaborating to compute public and private
|
|
// keys. Additionally, the use of the per commitment point ensures that each
|
|
// commitment state houses a unique set of keys which is useful when creating
|
|
// blinded channel outsourcing protocols.
|
|
//
|
|
// TODO(roasbeef): should be using double-scalar mult here
|
|
func TweakPubKey(basePoint, commitPoint *btcec.PublicKey) *btcec.PublicKey {
|
|
tweakBytes := SingleTweakBytes(commitPoint, basePoint)
|
|
return TweakPubKeyWithTweak(basePoint, tweakBytes)
|
|
}
|
|
|
|
// TweakPubKeyWithTweak is the exact same as the TweakPubKey function, however
|
|
// it accepts the raw tweak bytes directly rather than the commitment point.
|
|
func TweakPubKeyWithTweak(pubKey *btcec.PublicKey, tweakBytes []byte) *btcec.PublicKey {
|
|
curve := btcec.S256()
|
|
tweakX, tweakY := curve.ScalarBaseMult(tweakBytes)
|
|
|
|
// TODO(roasbeef): check that both passed on curve?
|
|
x, y := curve.Add(pubKey.X, pubKey.Y, tweakX, tweakY)
|
|
return &btcec.PublicKey{
|
|
X: x,
|
|
Y: y,
|
|
Curve: curve,
|
|
}
|
|
}
|
|
|
|
// TweakPrivKey tweaks the private key of a public base point given a per
|
|
// commitment point. The per commitment secret is the revealed revocation
|
|
// secret for the commitment state in question. This private key will only need
|
|
// to be generated in the case that a channel counter party broadcasts a
|
|
// revoked state. Precisely, the following operation is used to derive a
|
|
// tweaked private key:
|
|
//
|
|
// * tweakPriv := basePriv + sha256(commitment || basePub) mod N
|
|
//
|
|
// Where N is the order of the sub-group.
|
|
func TweakPrivKey(basePriv *btcec.PrivateKey, commitTweak []byte) *btcec.PrivateKey {
|
|
// tweakInt := sha256(commitPoint || basePub)
|
|
tweakInt := new(big.Int).SetBytes(commitTweak)
|
|
|
|
tweakInt = tweakInt.Add(tweakInt, basePriv.D)
|
|
tweakInt = tweakInt.Mod(tweakInt, btcec.S256().N)
|
|
|
|
tweakPriv, _ := btcec.PrivKeyFromBytes(btcec.S256(), tweakInt.Bytes())
|
|
return tweakPriv
|
|
}
|
|
|
|
// 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 := revokeBase * sha256(revocationBase || commitPoint) +
|
|
// commitPoint * sha256(commitPoint || revocationBase)
|
|
//
|
|
// := G*(revokeBasePriv * sha256(revocationBase || commitPoint)) +
|
|
// G*(commitSecret * sha256(commitPoint || revocationBase))
|
|
//
|
|
// := G*(revokeBasePriv * sha256(revocationBase || commitPoint) +
|
|
// commitSecret * sha256(commitPoint || revocationBase))
|
|
//
|
|
// Therefore, once we divulge the revocation secret, the remote peer is able to
|
|
// compute the proper private key for the revokeKey by computing:
|
|
//
|
|
// revokePriv := (revokeBasePriv * sha256(revocationBase || commitPoint)) +
|
|
// (commitSecret * sha256(commitPoint || revocationBase)) mod N
|
|
//
|
|
// Where N is the order of the sub-group.
|
|
func DeriveRevocationPubkey(revokeBase, commitPoint *btcec.PublicKey) *btcec.PublicKey {
|
|
|
|
// R = revokeBase * sha256(revocationBase || commitPoint)
|
|
revokeTweakBytes := SingleTweakBytes(revokeBase, commitPoint)
|
|
rX, rY := btcec.S256().ScalarMult(revokeBase.X, revokeBase.Y,
|
|
revokeTweakBytes)
|
|
|
|
// C = commitPoint * sha256(commitPoint || revocationBase)
|
|
commitTweakBytes := SingleTweakBytes(commitPoint, revokeBase)
|
|
cX, cY := btcec.S256().ScalarMult(commitPoint.X, commitPoint.Y,
|
|
commitTweakBytes)
|
|
|
|
// Now that we have the revocation point, we add this to their commitment
|
|
// public key in order to obtain the revocation public key.
|
|
//
|
|
// P = R + C
|
|
revX, revY := btcec.S256().Add(rX, rY, cX, cY)
|
|
return &btcec.PublicKey{
|
|
X: revX,
|
|
Y: revY,
|
|
Curve: btcec.S256(),
|
|
}
|
|
}
|
|
|
|
// 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 := (revokeBasePriv * sha256(revocationBase || commitPoint)) +
|
|
// (commitSecret * sha256(commitPoint || revocationBase)) mod N
|
|
//
|
|
// Where N is the order of the sub-group.
|
|
func DeriveRevocationPrivKey(revokeBasePriv *btcec.PrivateKey,
|
|
commitSecret *btcec.PrivateKey) *btcec.PrivateKey {
|
|
|
|
// r = sha256(revokeBasePub || commitPoint)
|
|
revokeTweakBytes := SingleTweakBytes(revokeBasePriv.PubKey(),
|
|
commitSecret.PubKey())
|
|
revokeTweakInt := new(big.Int).SetBytes(revokeTweakBytes)
|
|
|
|
// c = sha256(commitPoint || revokeBasePub)
|
|
commitTweakBytes := SingleTweakBytes(commitSecret.PubKey(),
|
|
revokeBasePriv.PubKey())
|
|
commitTweakInt := new(big.Int).SetBytes(commitTweakBytes)
|
|
|
|
// Finally to derive the revocation secret key we'll perform the
|
|
// following operation:
|
|
//
|
|
// k = (revocationPriv * r) + (commitSecret * c) mod N
|
|
//
|
|
// This works since:
|
|
// P = (G*a)*b + (G*c)*d
|
|
// P = G*(a*b) + G*(c*d)
|
|
// P = G*(a*b + c*d)
|
|
revokeHalfPriv := revokeTweakInt.Mul(revokeTweakInt, revokeBasePriv.D)
|
|
commitHalfPriv := commitTweakInt.Mul(commitTweakInt, commitSecret.D)
|
|
|
|
revocationPriv := revokeHalfPriv.Add(revokeHalfPriv, commitHalfPriv)
|
|
revocationPriv = revocationPriv.Mod(revocationPriv, btcec.S256().N)
|
|
|
|
priv, _ := btcec.PrivKeyFromBytes(btcec.S256(), revocationPriv.Bytes())
|
|
return priv
|
|
}
|
|
|
|
// DeriveRevocationRoot derives an root unique to a channel given the
|
|
// derivation root, and the blockhash that the funding process began at and the
|
|
// remote node's identity public key. The seed is derived using the HKDF[1][2]
|
|
// instantiated with sha-256. With this schema, once we know the block hash of
|
|
// the funding transaction, and who we funded the channel with, we can
|
|
// reconstruct all of our revocation state.
|
|
//
|
|
// [1]: https://eprint.iacr.org/2010/264.pdf
|
|
// [2]: https://tools.ietf.org/html/rfc5869
|
|
func DeriveRevocationRoot(derivationRoot *btcec.PrivateKey,
|
|
blockSalt chainhash.Hash, nodePubKey *btcec.PublicKey) chainhash.Hash {
|
|
|
|
secret := derivationRoot.Serialize()
|
|
salt := blockSalt[:]
|
|
info := nodePubKey.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 lock time 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.
|
|
func SetStateNumHint(commitTx *wire.MsgTx, stateNum uint64,
|
|
obfuscator [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:], obfuscator[:])
|
|
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 obfuscator.
|
|
//
|
|
// See setStateNumHint for further details w.r.t exactly how the state-hints
|
|
// are encoded.
|
|
func GetStateNumHint(commitTx *wire.MsgTx, obfuscator [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:], obfuscator[:])
|
|
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
|
|
}
|
|
|
|
// ComputeCommitmentPoint generates a commitment point given a commitment
|
|
// secret. The commitment point for each state is used to randomize each key in
|
|
// the key-ring and also to used as a tweak to derive new public+private keys
|
|
// for the state.
|
|
func ComputeCommitmentPoint(commitSecret []byte) *btcec.PublicKey {
|
|
x, y := btcec.S256().ScalarBaseMult(commitSecret)
|
|
|
|
return &btcec.PublicKey{
|
|
X: x,
|
|
Y: y,
|
|
Curve: btcec.S256(),
|
|
}
|
|
}
|