lnd/chanbackup/single.go
Boris Nagaev df84148ed2
chanbackup: add Single.CloseTxInputs field
The field is optional. It stores inputs needed to produce signed commit tx using
chantools scbforceclose, which calls function GetSignedCommitTx. New backups
have this field filled if commit tx is available (for all cases except when DLP
is active). If a backup has this data, the field is filled from it, otherwise it
is kept empty.

Modified test function genRandomOpenChannelShell to cover new types of channels
(simple taproot channel and custom channel) and to cover combinations of bits.
Make sure that TapscriptRoot field is properly packed and unpacked.
2024-10-14 09:44:17 -03:00

812 lines
26 KiB
Go

package chanbackup
import (
"bytes"
"errors"
"fmt"
"io"
"net"
"github.com/btcsuite/btcd/btcec/v2"
"github.com/btcsuite/btcd/btcutil"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/wire"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/fn"
"github.com/lightningnetwork/lnd/keychain"
"github.com/lightningnetwork/lnd/lnencrypt"
"github.com/lightningnetwork/lnd/lnwire"
)
// SingleBackupVersion denotes the version of the single static channel backup.
// Based on this version, we know how to pack/unpack serialized versions of the
// backup.
type SingleBackupVersion byte
const (
// DefaultSingleVersion is the default version of the single channel
// backup. The serialized version of this static channel backup is
// simply: version || SCB. Where SCB is the known format of the
// version.
DefaultSingleVersion = 0
// TweaklessCommitVersion is the second SCB version. This version
// implicitly denotes that this channel uses the new tweakless commit
// format.
TweaklessCommitVersion = 1
// AnchorsCommitVersion is the third SCB version. This version
// implicitly denotes that this channel uses the new anchor commitment
// format.
AnchorsCommitVersion = 2
// AnchorsZeroFeeHtlcTxCommitVersion is a version that denotes this
// channel is using the zero-fee second-level anchor commitment format.
AnchorsZeroFeeHtlcTxCommitVersion = 3
// ScriptEnforcedLeaseVersion is a version that denotes this channel is
// using the zero-fee second-level anchor commitment format along with
// an additional CLTV requirement of the channel lease maturity on any
// commitment and HTLC outputs that pay directly to the channel
// initiator.
ScriptEnforcedLeaseVersion = 4
// SimpleTaprootVersion is a version that denotes this channel is using
// the musig2 based taproot commitment format.
SimpleTaprootVersion = 5
// TapscriptRootVersion is a version that denotes this is a MuSig2
// channel with a top level tapscript commitment.
TapscriptRootVersion = 6
// closeTxVersionMask is the byte mask used that is ORed to version byte
// on wire indicating that the backup has CloseTxInputs.
closeTxVersionMask = 1 << 7
)
// Encode returns encoding of the version to put into channel backup.
// Argument "closeTx" specifies if the backup includes force close transaction.
func (v SingleBackupVersion) Encode(closeTx bool) byte {
encoded := byte(v)
// If the backup includes closing transaction, set this bit in the
// encoded version.
if closeTx {
encoded |= closeTxVersionMask
}
return encoded
}
// DecodeVersion decodes the encoding of the version from a channel backup.
// It returns the version and if the backup includes the force close tx.
func DecodeVersion(encoded byte) (SingleBackupVersion, bool) {
// Find if it has a closing transaction by inspecting the bit.
closeTx := (encoded & closeTxVersionMask) != 0
// The version byte also encodes the closeTxVersion feature, so we
// extract it here and return it separately to the backup version.
version := SingleBackupVersion(encoded &^ closeTxVersionMask)
return version, closeTx
}
// IsTaproot returns if this is a backup of a taproot channel. This will also be
// true for simple taproot overlay channels when a version is added.
func (v SingleBackupVersion) IsTaproot() bool {
return v == SimpleTaprootVersion || v == TapscriptRootVersion
}
// HasTapscriptRoot returns true if the channel is using a top level tapscript
// root commitment.
func (v SingleBackupVersion) HasTapscriptRoot() bool {
return v == TapscriptRootVersion
}
// Single is a static description of an existing channel that can be used for
// the purposes of backing up. The fields in this struct allow a node to
// recover the settled funds within a channel in the case of partial or
// complete data loss. We provide the network address that we last used to
// connect to the peer as well, in case the node stops advertising the IP on
// the network for whatever reason.
//
// TODO(roasbeef): suffix version into struct?
type Single struct {
// Version is the version that should be observed when attempting to
// pack the single backup.
Version SingleBackupVersion
// IsInitiator is true if we were the initiator of the channel, and
// false otherwise. We'll need to know this information in order to
// properly re-derive the state hint information.
IsInitiator bool
// ChainHash is a hash which represents the blockchain that this
// channel will be opened within. This value is typically the genesis
// hash. In the case that the original chain went through a contentious
// hard-fork, then this value will be tweaked using the unique fork
// point on each branch.
ChainHash chainhash.Hash
// FundingOutpoint is the outpoint of the final funding transaction.
// This value uniquely and globally identities the channel within the
// target blockchain as specified by the chain hash parameter.
FundingOutpoint wire.OutPoint
// ShortChannelID encodes the exact location in the chain in which the
// channel was initially confirmed. This includes: the block height,
// transaction index, and the output within the target transaction.
// Channels that were not confirmed at the time of backup creation will
// have the funding TX broadcast height set as their block height in
// the ShortChannelID.
ShortChannelID lnwire.ShortChannelID
// RemoteNodePub is the identity public key of the remote node this
// channel has been established with.
RemoteNodePub *btcec.PublicKey
// Addresses is a list of IP address in which either we were able to
// reach the node over in the past, OR we received an incoming
// authenticated connection for the stored identity public key.
Addresses []net.Addr
// Capacity is the size of the original channel.
Capacity btcutil.Amount
// LocalChanCfg is our local channel configuration. It contains all the
// information we need to re-derive the keys we used within the
// channel. Most importantly, it allows to derive the base public
// that's used to deriving the key used within the non-delayed
// pay-to-self output on the commitment transaction for a node. With
// this information, we can re-derive the private key needed to sweep
// the funds on-chain.
//
// NOTE: Of the items in the ChannelConstraints, we only write the CSV
// delay.
LocalChanCfg channeldb.ChannelConfig
// RemoteChanCfg is the remote channel confirmation. We store this as
// well since we'll need some of their keys to re-derive things like
// the state hint obfuscator which will allow us to recognize the state
// their broadcast on chain.
//
// NOTE: Of the items in the ChannelConstraints, we only write the CSV
// delay.
RemoteChanCfg channeldb.ChannelConfig
// ShaChainRootDesc describes how to derive the private key that was
// used as the shachain root for this channel.
ShaChainRootDesc keychain.KeyDescriptor
// LeaseExpiry represents the absolute expiration as a height of the
// chain of a channel lease that is applied to every output that pays
// directly to the channel initiator in addition to the usual CSV
// requirement.
//
// NOTE: This field will only be present for the following versions:
//
// - ScriptEnforcedLeaseVersion
LeaseExpiry uint32
// CloseTxInputs contains data needed to produce a force close tx
// using for example the "chantools scbforceclose" command.
//
// The field is optional.
CloseTxInputs fn.Option[CloseTxInputs]
}
// CloseTxInputs contains data needed to produce a force close transaction
// using for example the "chantools scbforceclose" command.
type CloseTxInputs struct {
// CommitTx is the latest version of the commitment state, broadcast
// able by us, but not signed. It can be signed by for example the
// "chantools scbforceclose" command.
CommitTx *wire.MsgTx
// CommitSig is one half of the signature required to fully complete
// the script for the commitment transaction above. This is the
// signature signed by the remote party for our version of the
// commitment transactions.
CommitSig []byte
// CommitHeight is the update number that this ChannelDelta represents
// the total number of commitment updates to this point. This can be
// viewed as sort of a "commitment height" as this number is
// monotonically increasing.
//
// This field is filled only for taproot channels.
CommitHeight uint64
// TapscriptRoot is the root of the tapscript tree that will be used to
// create the funding output. This is an optional field that should
// only be set for overlay taproot channels (HasTapscriptRoot).
TapscriptRoot fn.Option[chainhash.Hash]
}
// NewSingle creates a new static channel backup based on an existing open
// channel. We also pass in the set of addresses that we used in the past to
// connect to the channel peer. If possible, we include the data needed to
// produce a force close transaction from the most recent state using externally
// provided private key.
func NewSingle(channel *channeldb.OpenChannel,
nodeAddrs []net.Addr) Single {
var shaChainRootDesc keychain.KeyDescriptor
// If the channel has a populated RevocationKeyLocator, then we can
// just store that instead of the public key.
if channel.RevocationKeyLocator.Family == keychain.KeyFamilyRevocationRoot {
shaChainRootDesc = keychain.KeyDescriptor{
KeyLocator: channel.RevocationKeyLocator,
}
} else {
// If the RevocationKeyLocator is not populated, then we'll need
// to obtain a public point for the shachain root and store that.
// This is the legacy scheme.
var b bytes.Buffer
_ = channel.RevocationProducer.Encode(&b) // Can't return an error.
// Once we have the root, we'll make a public key from it, such that
// the backups plaintext don't carry any private information. When
// we go to recover, we'll present this in order to derive the
// private key.
_, shaChainPoint := btcec.PrivKeyFromBytes(b.Bytes())
shaChainRootDesc = keychain.KeyDescriptor{
PubKey: shaChainPoint,
KeyLocator: keychain.KeyLocator{
Family: keychain.KeyFamilyRevocationRoot,
},
}
}
// If a channel is unconfirmed, the block height of the ShortChannelID
// is zero. This will lead to problems when trying to restore that
// channel as the spend notifier would get a height hint of zero.
// To work around that problem, we add the channel broadcast height
// to the channel ID so we can use that as height hint on restore.
chanID := channel.ShortChanID()
if chanID.BlockHeight == 0 {
chanID.BlockHeight = channel.BroadcastHeight()
}
// If this is a zero-conf channel, we'll need to have separate logic
// depending on whether it's confirmed or not. This is because the
// ShortChanID is an alias.
if channel.IsZeroConf() {
// If the channel is confirmed, we'll use the confirmed SCID.
if channel.ZeroConfConfirmed() {
chanID = channel.ZeroConfRealScid()
} else {
// Else if the zero-conf channel is unconfirmed, we'll
// need to use the broadcast height and zero out the
// TxIndex and TxPosition fields. This is so
// openChannelShell works properly.
chanID.BlockHeight = channel.BroadcastHeight()
chanID.TxIndex = 0
chanID.TxPosition = 0
}
}
single := Single{
IsInitiator: channel.IsInitiator,
ChainHash: channel.ChainHash,
FundingOutpoint: channel.FundingOutpoint,
ShortChannelID: chanID,
RemoteNodePub: channel.IdentityPub,
Addresses: nodeAddrs,
Capacity: channel.Capacity,
LocalChanCfg: channel.LocalChanCfg,
RemoteChanCfg: channel.RemoteChanCfg,
ShaChainRootDesc: shaChainRootDesc,
}
switch {
case channel.ChanType.IsTaproot():
if channel.ChanType.HasTapscriptRoot() {
single.Version = TapscriptRootVersion
} else {
single.Version = SimpleTaprootVersion
}
case channel.ChanType.HasLeaseExpiration():
single.Version = ScriptEnforcedLeaseVersion
single.LeaseExpiry = channel.ThawHeight
case channel.ChanType.ZeroHtlcTxFee():
single.Version = AnchorsZeroFeeHtlcTxCommitVersion
case channel.ChanType.HasAnchors():
single.Version = AnchorsCommitVersion
case channel.ChanType.IsTweakless():
single.Version = TweaklessCommitVersion
default:
single.Version = DefaultSingleVersion
}
// Include unsigned force-close transaction for the most recent channel
// state as well as the data needed to produce the signature, given the
// private key is provided separately.
single.CloseTxInputs = buildCloseTxInputs(channel)
return single
}
// errEmptyTapscriptRoot is returned by Serialize if field TapscriptRoot is
// empty, when it should be filled according to the channel version.
var errEmptyTapscriptRoot = errors.New("field TapscriptRoot is not filled")
// Serialize attempts to write out the serialized version of the target
// StaticChannelBackup into the passed io.Writer.
func (s *Single) Serialize(w io.Writer) error {
// Check to ensure that we'll only attempt to serialize a version that
// we're aware of.
switch s.Version {
case DefaultSingleVersion:
case TweaklessCommitVersion:
case AnchorsCommitVersion:
case AnchorsZeroFeeHtlcTxCommitVersion:
case ScriptEnforcedLeaseVersion:
case SimpleTaprootVersion:
case TapscriptRootVersion:
default:
return fmt.Errorf("unable to serialize w/ unknown "+
"version: %v", s.Version)
}
// If the sha chain root has specified a public key (which is
// optional), then we'll encode it now.
var shaChainPub [33]byte
if s.ShaChainRootDesc.PubKey != nil {
copy(
shaChainPub[:],
s.ShaChainRootDesc.PubKey.SerializeCompressed(),
)
}
// First we gather the SCB as is into a temporary buffer so we can
// determine the total length. Before we write out the serialized SCB,
// we write the length which allows us to skip any Singles that we
// don't know of when decoding a multi.
var singleBytes bytes.Buffer
if err := lnwire.WriteElements(
&singleBytes,
s.IsInitiator,
s.ChainHash[:],
s.FundingOutpoint,
s.ShortChannelID,
s.RemoteNodePub,
s.Addresses,
s.Capacity,
s.LocalChanCfg.CsvDelay,
// We only need to write out the KeyLocator portion of the
// local channel config.
uint32(s.LocalChanCfg.MultiSigKey.Family),
s.LocalChanCfg.MultiSigKey.Index,
uint32(s.LocalChanCfg.RevocationBasePoint.Family),
s.LocalChanCfg.RevocationBasePoint.Index,
uint32(s.LocalChanCfg.PaymentBasePoint.Family),
s.LocalChanCfg.PaymentBasePoint.Index,
uint32(s.LocalChanCfg.DelayBasePoint.Family),
s.LocalChanCfg.DelayBasePoint.Index,
uint32(s.LocalChanCfg.HtlcBasePoint.Family),
s.LocalChanCfg.HtlcBasePoint.Index,
s.RemoteChanCfg.CsvDelay,
// We only need to write out the raw pubkey for the remote
// channel config.
s.RemoteChanCfg.MultiSigKey.PubKey,
s.RemoteChanCfg.RevocationBasePoint.PubKey,
s.RemoteChanCfg.PaymentBasePoint.PubKey,
s.RemoteChanCfg.DelayBasePoint.PubKey,
s.RemoteChanCfg.HtlcBasePoint.PubKey,
shaChainPub[:],
uint32(s.ShaChainRootDesc.KeyLocator.Family),
s.ShaChainRootDesc.KeyLocator.Index,
); err != nil {
return err
}
if s.Version == ScriptEnforcedLeaseVersion {
err := lnwire.WriteElements(&singleBytes, s.LeaseExpiry)
if err != nil {
return err
}
}
// Encode version enum and hasCloseTx flag to version byte.
version := s.Version.Encode(s.CloseTxInputs.IsSome())
// Serialize CloseTxInputs if it is provided. Fill err if it fails.
err := fn.MapOptionZ(s.CloseTxInputs, func(inputs CloseTxInputs) error {
err := inputs.CommitTx.Serialize(&singleBytes)
if err != nil {
return err
}
err = lnwire.WriteElements(
&singleBytes,
uint16(len(inputs.CommitSig)), inputs.CommitSig,
)
if err != nil {
return err
}
if !s.Version.IsTaproot() {
return nil
}
// Write fields needed for taproot channels.
err = lnwire.WriteElements(
&singleBytes, inputs.CommitHeight,
)
if err != nil {
return err
}
if s.Version.HasTapscriptRoot() {
opt := inputs.TapscriptRoot
var tapscriptRoot chainhash.Hash
tapscriptRoot, err = opt.UnwrapOrErr(
errEmptyTapscriptRoot,
)
if err != nil {
return err
}
err = lnwire.WriteElements(
&singleBytes, tapscriptRoot[:],
)
if err != nil {
return err
}
}
return nil
})
if err != nil {
return fmt.Errorf("failed to encode CloseTxInputs: %w", err)
}
// TODO(yy): remove the type assertion when we finished refactoring db
// into using write buffer.
buf, ok := w.(*bytes.Buffer)
if !ok {
return fmt.Errorf("expect io.Writer to be *bytes.Buffer")
}
return lnwire.WriteElements(
buf,
version,
uint16(len(singleBytes.Bytes())),
singleBytes.Bytes(),
)
}
// PackToWriter is similar to the Serialize method, but takes the operation a
// step further by encryption the raw bytes of the static channel back up. For
// encryption we use the chacah20poly1305 AEAD cipher with a 24 byte nonce and
// 32-byte key size. We use a 24-byte nonce, as we can't ensure that we have a
// global counter to use as a sequence number for nonces, and want to ensure
// that we're able to decrypt these blobs without any additional context. We
// derive the key that we use for encryption via a SHA2 operation of the with
// the golden keychain.KeyFamilyBaseEncryption base encryption key. We then
// take the serialized resulting shared secret point, and hash it using sha256
// to obtain the key that we'll use for encryption. When using the AEAD, we
// pass the nonce as associated data such that we'll be able to package the two
// together for storage. Before writing out the encrypted payload, we prepend
// the nonce to the final blob.
func (s *Single) PackToWriter(w io.Writer, keyRing keychain.KeyRing) error {
// First, we'll serialize the SCB (StaticChannelBackup) into a
// temporary buffer so we can store it in a temporary place before we
// go to encrypt the entire thing.
var rawBytes bytes.Buffer
if err := s.Serialize(&rawBytes); err != nil {
return err
}
// Finally, we'll encrypt the raw serialized SCB (using the nonce as
// associated data), and write out the ciphertext prepend with the
// nonce that we used to the passed io.Reader.
e, err := lnencrypt.KeyRingEncrypter(keyRing)
if err != nil {
return fmt.Errorf("unable to generate encrypt key %w", err)
}
return e.EncryptPayloadToWriter(rawBytes.Bytes(), w)
}
// readLocalKeyDesc reads a KeyDescriptor encoded within an unpacked Single.
// For local KeyDescs, we only write out the KeyLocator information as we can
// re-derive the pubkey from it.
func readLocalKeyDesc(r io.Reader) (keychain.KeyDescriptor, error) {
var keyDesc keychain.KeyDescriptor
var keyFam uint32
if err := lnwire.ReadElements(r, &keyFam); err != nil {
return keyDesc, err
}
keyDesc.Family = keychain.KeyFamily(keyFam)
if err := lnwire.ReadElements(r, &keyDesc.Index); err != nil {
return keyDesc, err
}
return keyDesc, nil
}
// readRemoteKeyDesc reads a remote KeyDescriptor encoded within an unpacked
// Single. For remote KeyDescs, we write out only the PubKey since we don't
// actually have the KeyLocator data.
func readRemoteKeyDesc(r io.Reader) (keychain.KeyDescriptor, error) {
var (
keyDesc keychain.KeyDescriptor
pub [33]byte
)
_, err := io.ReadFull(r, pub[:])
if err != nil {
return keychain.KeyDescriptor{}, err
}
keyDesc.PubKey, err = btcec.ParsePubKey(pub[:])
if err != nil {
return keychain.KeyDescriptor{}, err
}
return keyDesc, nil
}
// Deserialize attempts to read the raw plaintext serialized SCB from the
// passed io.Reader. If the method is successful, then the target
// StaticChannelBackup will be fully populated.
func (s *Single) Deserialize(r io.Reader) error {
// First, we'll need to read the version of this single-back up so we
// can know how to unpack each of the SCB.
var version byte
err := lnwire.ReadElements(r, &version)
if err != nil {
return err
}
// Decode version byte to version enum and hasCloseTx flag.
var hasCloseTx bool
s.Version, hasCloseTx = DecodeVersion(version)
switch s.Version {
case DefaultSingleVersion:
case TweaklessCommitVersion:
case AnchorsCommitVersion:
case AnchorsZeroFeeHtlcTxCommitVersion:
case ScriptEnforcedLeaseVersion:
case SimpleTaprootVersion:
case TapscriptRootVersion:
default:
return fmt.Errorf("unable to de-serialize w/ unknown "+
"version: %v", s.Version)
}
var length uint16
if err := lnwire.ReadElements(r, &length); err != nil {
return err
}
err = lnwire.ReadElements(
r, &s.IsInitiator, s.ChainHash[:], &s.FundingOutpoint,
&s.ShortChannelID, &s.RemoteNodePub, &s.Addresses, &s.Capacity,
)
if err != nil {
return err
}
err = lnwire.ReadElements(r, &s.LocalChanCfg.CsvDelay)
if err != nil {
return err
}
s.LocalChanCfg.MultiSigKey, err = readLocalKeyDesc(r)
if err != nil {
return err
}
s.LocalChanCfg.RevocationBasePoint, err = readLocalKeyDesc(r)
if err != nil {
return err
}
s.LocalChanCfg.PaymentBasePoint, err = readLocalKeyDesc(r)
if err != nil {
return err
}
s.LocalChanCfg.DelayBasePoint, err = readLocalKeyDesc(r)
if err != nil {
return err
}
s.LocalChanCfg.HtlcBasePoint, err = readLocalKeyDesc(r)
if err != nil {
return err
}
err = lnwire.ReadElements(r, &s.RemoteChanCfg.CsvDelay)
if err != nil {
return err
}
s.RemoteChanCfg.MultiSigKey, err = readRemoteKeyDesc(r)
if err != nil {
return err
}
s.RemoteChanCfg.RevocationBasePoint, err = readRemoteKeyDesc(r)
if err != nil {
return err
}
s.RemoteChanCfg.PaymentBasePoint, err = readRemoteKeyDesc(r)
if err != nil {
return err
}
s.RemoteChanCfg.DelayBasePoint, err = readRemoteKeyDesc(r)
if err != nil {
return err
}
s.RemoteChanCfg.HtlcBasePoint, err = readRemoteKeyDesc(r)
if err != nil {
return err
}
// Finally, we'll parse out the ShaChainRootDesc.
var (
shaChainPub [33]byte
zeroPub [33]byte
)
if err := lnwire.ReadElements(r, shaChainPub[:]); err != nil {
return err
}
// Since this field is optional, we'll check to see if the pubkey has
// been specified or not.
if !bytes.Equal(shaChainPub[:], zeroPub[:]) {
s.ShaChainRootDesc.PubKey, err = btcec.ParsePubKey(
shaChainPub[:],
)
if err != nil {
return err
}
}
var shaKeyFam uint32
if err := lnwire.ReadElements(r, &shaKeyFam); err != nil {
return err
}
s.ShaChainRootDesc.KeyLocator.Family = keychain.KeyFamily(shaKeyFam)
err = lnwire.ReadElements(r, &s.ShaChainRootDesc.KeyLocator.Index)
if err != nil {
return err
}
if s.Version == ScriptEnforcedLeaseVersion {
if err := lnwire.ReadElement(r, &s.LeaseExpiry); err != nil {
return err
}
}
if !hasCloseTx {
return nil
}
// Deserialize CloseTxInputs if it is present in serialized data.
commitTx := &wire.MsgTx{}
if err := commitTx.Deserialize(r); err != nil {
return err
}
var commitSigLen uint16
if err := lnwire.ReadElement(r, &commitSigLen); err != nil {
return err
}
commitSig := make([]byte, commitSigLen)
if err := lnwire.ReadElement(r, commitSig); err != nil {
return err
}
var commitHeight uint64
if s.Version.IsTaproot() {
err := lnwire.ReadElement(r, &commitHeight)
if err != nil {
return err
}
}
tapscriptRootOpt := fn.None[chainhash.Hash]()
if s.Version.HasTapscriptRoot() {
var tapscriptRoot chainhash.Hash
err := lnwire.ReadElement(r, tapscriptRoot[:])
if err != nil {
return err
}
tapscriptRootOpt = fn.Some(tapscriptRoot)
}
s.CloseTxInputs = fn.Some(CloseTxInputs{
CommitTx: commitTx,
CommitSig: commitSig,
CommitHeight: commitHeight,
TapscriptRoot: tapscriptRootOpt,
})
return nil
}
// UnpackFromReader is similar to Deserialize method, but it expects the passed
// io.Reader to contain an encrypt SCB. Refer to the SerializeAndEncrypt method
// for details w.r.t the encryption scheme used. If we're unable to decrypt the
// payload for whatever reason (wrong key, wrong nonce, etc), then this method
// will return an error.
func (s *Single) UnpackFromReader(r io.Reader, keyRing keychain.KeyRing) error {
e, err := lnencrypt.KeyRingEncrypter(keyRing)
if err != nil {
return fmt.Errorf("unable to generate key decrypter %w", err)
}
plaintext, err := e.DecryptPayloadFromReader(r)
if err != nil {
return err
}
// Finally, we'll pack the bytes into a reader to we can deserialize
// the plaintext bytes of the SCB.
backupReader := bytes.NewReader(plaintext)
return s.Deserialize(backupReader)
}
// PackStaticChanBackups accepts a set of existing open channels, and a
// keychain.KeyRing, and returns a map of outpoints to the serialized+encrypted
// static channel backups. The passed keyRing should be backed by the users
// root HD seed in order to ensure full determinism.
func PackStaticChanBackups(backups []Single,
keyRing keychain.KeyRing) (map[wire.OutPoint][]byte, error) {
packedBackups := make(map[wire.OutPoint][]byte)
for _, chanBackup := range backups {
chanPoint := chanBackup.FundingOutpoint
var b bytes.Buffer
err := chanBackup.PackToWriter(&b, keyRing)
if err != nil {
return nil, fmt.Errorf("unable to pack chan backup "+
"for %v: %v", chanPoint, err)
}
packedBackups[chanPoint] = b.Bytes()
}
return packedBackups, nil
}
// PackedSingles represents a series of fully packed SCBs. This may be the
// combination of a series of individual SCBs in order to batch their
// unpacking.
type PackedSingles [][]byte
// Unpack attempts to decrypt the passed set of encrypted SCBs and deserialize
// each one into a new SCB struct. The passed keyRing should be backed by the
// same HD seed as was used to encrypt the set of backups in the first place.
// If we're unable to decrypt any of the back ups, then we'll return an error.
func (p PackedSingles) Unpack(keyRing keychain.KeyRing) ([]Single, error) {
backups := make([]Single, len(p))
for i, encryptedBackup := range p {
var backup Single
backupReader := bytes.NewReader(encryptedBackup)
err := backup.UnpackFromReader(backupReader, keyRing)
if err != nil {
return nil, err
}
backups[i] = backup
}
return backups, nil
}
// TODO(roasbeef): make codec package?