mirror of
https://github.com/lightningnetwork/lnd.git
synced 2024-11-19 18:10:34 +01:00
612 lines
20 KiB
Go
612 lines
20 KiB
Go
package chanbackup
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import (
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"bytes"
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"fmt"
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"io"
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"net"
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"github.com/btcsuite/btcd/btcec/v2"
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"github.com/btcsuite/btcd/btcutil"
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"github.com/btcsuite/btcd/chaincfg/chainhash"
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"github.com/btcsuite/btcd/wire"
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"github.com/lightningnetwork/lnd/channeldb"
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"github.com/lightningnetwork/lnd/keychain"
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"github.com/lightningnetwork/lnd/lnencrypt"
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"github.com/lightningnetwork/lnd/lnwire"
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)
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// SingleBackupVersion denotes the version of the single static channel backup.
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// Based on this version, we know how to pack/unpack serialized versions of the
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// backup.
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type SingleBackupVersion byte
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const (
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// DefaultSingleVersion is the default version of the single channel
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// backup. The serialized version of this static channel backup is
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// simply: version || SCB. Where SCB is the known format of the
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// version.
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DefaultSingleVersion = 0
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// TweaklessCommitVersion is the second SCB version. This version
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// implicitly denotes that this channel uses the new tweakless commit
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// format.
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TweaklessCommitVersion = 1
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// AnchorsCommitVersion is the third SCB version. This version
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// implicitly denotes that this channel uses the new anchor commitment
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// format.
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AnchorsCommitVersion = 2
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// AnchorsZeroFeeHtlcTxCommitVersion is a version that denotes this
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// channel is using the zero-fee second-level anchor commitment format.
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AnchorsZeroFeeHtlcTxCommitVersion = 3
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// ScriptEnforcedLeaseVersion is a version that denotes this channel is
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// using the zero-fee second-level anchor commitment format along with
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// an additional CLTV requirement of the channel lease maturity on any
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// commitment and HTLC outputs that pay directly to the channel
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// initiator.
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ScriptEnforcedLeaseVersion = 4
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// SimpleTaprootVersion is a version that denotes this channel is using
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// the musig2 based taproot commitment format.
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SimpleTaprootVersion = 5
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)
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// Single is a static description of an existing channel that can be used for
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// the purposes of backing up. The fields in this struct allow a node to
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// recover the settled funds within a channel in the case of partial or
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// complete data loss. We provide the network address that we last used to
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// connect to the peer as well, in case the node stops advertising the IP on
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// the network for whatever reason.
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//
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// TODO(roasbeef): suffix version into struct?
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type Single struct {
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// Version is the version that should be observed when attempting to
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// pack the single backup.
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Version SingleBackupVersion
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// IsInitiator is true if we were the initiator of the channel, and
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// false otherwise. We'll need to know this information in order to
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// properly re-derive the state hint information.
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IsInitiator bool
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// ChainHash is a hash which represents the blockchain that this
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// channel will be opened within. This value is typically the genesis
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// hash. In the case that the original chain went through a contentious
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// hard-fork, then this value will be tweaked using the unique fork
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// point on each branch.
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ChainHash chainhash.Hash
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// FundingOutpoint is the outpoint of the final funding transaction.
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// This value uniquely and globally identities the channel within the
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// target blockchain as specified by the chain hash parameter.
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FundingOutpoint wire.OutPoint
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// ShortChannelID encodes the exact location in the chain in which the
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// channel was initially confirmed. This includes: the block height,
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// transaction index, and the output within the target transaction.
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// Channels that were not confirmed at the time of backup creation will
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// have the funding TX broadcast height set as their block height in
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// the ShortChannelID.
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ShortChannelID lnwire.ShortChannelID
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// RemoteNodePub is the identity public key of the remote node this
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// channel has been established with.
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RemoteNodePub *btcec.PublicKey
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// Addresses is a list of IP address in which either we were able to
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// reach the node over in the past, OR we received an incoming
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// authenticated connection for the stored identity public key.
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Addresses []net.Addr
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// Capacity is the size of the original channel.
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Capacity btcutil.Amount
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// LocalChanCfg is our local channel configuration. It contains all the
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// information we need to re-derive the keys we used within the
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// channel. Most importantly, it allows to derive the base public
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// that's used to deriving the key used within the non-delayed
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// pay-to-self output on the commitment transaction for a node. With
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// this information, we can re-derive the private key needed to sweep
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// the funds on-chain.
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//
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// NOTE: Of the items in the ChannelConstraints, we only write the CSV
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// delay.
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LocalChanCfg channeldb.ChannelConfig
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// RemoteChanCfg is the remote channel confirmation. We store this as
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// well since we'll need some of their keys to re-derive things like
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// the state hint obfuscator which will allow us to recognize the state
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// their broadcast on chain.
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//
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// NOTE: Of the items in the ChannelConstraints, we only write the CSV
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// delay.
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RemoteChanCfg channeldb.ChannelConfig
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// ShaChainRootDesc describes how to derive the private key that was
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// used as the shachain root for this channel.
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ShaChainRootDesc keychain.KeyDescriptor
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// LeaseExpiry represents the absolute expiration as a height of the
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// chain of a channel lease that is applied to every output that pays
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// directly to the channel initiator in addition to the usual CSV
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// requirement.
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//
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// NOTE: This field will only be present for the following versions:
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//
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// - ScriptEnforcedLeaseVersion
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LeaseExpiry uint32
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}
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// NewSingle creates a new static channel backup based on an existing open
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// channel. We also pass in the set of addresses that we used in the past to
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// connect to the channel peer.
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func NewSingle(channel *channeldb.OpenChannel,
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nodeAddrs []net.Addr) Single {
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var shaChainRootDesc keychain.KeyDescriptor
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// If the channel has a populated RevocationKeyLocator, then we can
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// just store that instead of the public key.
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if channel.RevocationKeyLocator.Family == keychain.KeyFamilyRevocationRoot {
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shaChainRootDesc = keychain.KeyDescriptor{
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KeyLocator: channel.RevocationKeyLocator,
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}
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} else {
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// If the RevocationKeyLocator is not populated, then we'll need
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// to obtain a public point for the shachain root and store that.
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// This is the legacy scheme.
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var b bytes.Buffer
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_ = channel.RevocationProducer.Encode(&b) // Can't return an error.
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// Once we have the root, we'll make a public key from it, such that
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// the backups plaintext don't carry any private information. When
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// we go to recover, we'll present this in order to derive the
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// private key.
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_, shaChainPoint := btcec.PrivKeyFromBytes(b.Bytes())
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shaChainRootDesc = keychain.KeyDescriptor{
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PubKey: shaChainPoint,
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KeyLocator: keychain.KeyLocator{
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Family: keychain.KeyFamilyRevocationRoot,
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},
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}
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}
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// If a channel is unconfirmed, the block height of the ShortChannelID
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// is zero. This will lead to problems when trying to restore that
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// channel as the spend notifier would get a height hint of zero.
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// To work around that problem, we add the channel broadcast height
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// to the channel ID so we can use that as height hint on restore.
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chanID := channel.ShortChanID()
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if chanID.BlockHeight == 0 {
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chanID.BlockHeight = channel.BroadcastHeight()
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}
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// If this is a zero-conf channel, we'll need to have separate logic
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// depending on whether it's confirmed or not. This is because the
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// ShortChanID is an alias.
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if channel.IsZeroConf() {
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// If the channel is confirmed, we'll use the confirmed SCID.
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if channel.ZeroConfConfirmed() {
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chanID = channel.ZeroConfRealScid()
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} else {
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// Else if the zero-conf channel is unconfirmed, we'll
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// need to use the broadcast height and zero out the
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// TxIndex and TxPosition fields. This is so
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// openChannelShell works properly.
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chanID.BlockHeight = channel.BroadcastHeight()
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chanID.TxIndex = 0
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chanID.TxPosition = 0
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}
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}
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single := Single{
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IsInitiator: channel.IsInitiator,
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ChainHash: channel.ChainHash,
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FundingOutpoint: channel.FundingOutpoint,
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ShortChannelID: chanID,
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RemoteNodePub: channel.IdentityPub,
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Addresses: nodeAddrs,
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Capacity: channel.Capacity,
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LocalChanCfg: channel.LocalChanCfg,
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RemoteChanCfg: channel.RemoteChanCfg,
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ShaChainRootDesc: shaChainRootDesc,
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}
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switch {
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case channel.ChanType.IsTaproot():
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single.Version = SimpleTaprootVersion
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case channel.ChanType.HasLeaseExpiration():
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single.Version = ScriptEnforcedLeaseVersion
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single.LeaseExpiry = channel.ThawHeight
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case channel.ChanType.ZeroHtlcTxFee():
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single.Version = AnchorsZeroFeeHtlcTxCommitVersion
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case channel.ChanType.HasAnchors():
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single.Version = AnchorsCommitVersion
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case channel.ChanType.IsTweakless():
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single.Version = TweaklessCommitVersion
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default:
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single.Version = DefaultSingleVersion
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}
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return single
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}
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// Serialize attempts to write out the serialized version of the target
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// StaticChannelBackup into the passed io.Writer.
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func (s *Single) Serialize(w io.Writer) error {
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// Check to ensure that we'll only attempt to serialize a version that
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// we're aware of.
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switch s.Version {
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case DefaultSingleVersion:
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case TweaklessCommitVersion:
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case AnchorsCommitVersion:
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case AnchorsZeroFeeHtlcTxCommitVersion:
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case ScriptEnforcedLeaseVersion:
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case SimpleTaprootVersion:
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default:
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return fmt.Errorf("unable to serialize w/ unknown "+
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"version: %v", s.Version)
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}
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// If the sha chain root has specified a public key (which is
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// optional), then we'll encode it now.
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var shaChainPub [33]byte
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if s.ShaChainRootDesc.PubKey != nil {
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copy(
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shaChainPub[:],
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s.ShaChainRootDesc.PubKey.SerializeCompressed(),
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)
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}
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// First we gather the SCB as is into a temporary buffer so we can
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// determine the total length. Before we write out the serialized SCB,
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// we write the length which allows us to skip any Singles that we
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// don't know of when decoding a multi.
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var singleBytes bytes.Buffer
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if err := lnwire.WriteElements(
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&singleBytes,
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s.IsInitiator,
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s.ChainHash[:],
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s.FundingOutpoint,
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s.ShortChannelID,
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s.RemoteNodePub,
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s.Addresses,
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s.Capacity,
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s.LocalChanCfg.CsvDelay,
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// We only need to write out the KeyLocator portion of the
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// local channel config.
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uint32(s.LocalChanCfg.MultiSigKey.Family),
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s.LocalChanCfg.MultiSigKey.Index,
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uint32(s.LocalChanCfg.RevocationBasePoint.Family),
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s.LocalChanCfg.RevocationBasePoint.Index,
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uint32(s.LocalChanCfg.PaymentBasePoint.Family),
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s.LocalChanCfg.PaymentBasePoint.Index,
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uint32(s.LocalChanCfg.DelayBasePoint.Family),
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s.LocalChanCfg.DelayBasePoint.Index,
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uint32(s.LocalChanCfg.HtlcBasePoint.Family),
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s.LocalChanCfg.HtlcBasePoint.Index,
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s.RemoteChanCfg.CsvDelay,
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// We only need to write out the raw pubkey for the remote
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// channel config.
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s.RemoteChanCfg.MultiSigKey.PubKey,
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s.RemoteChanCfg.RevocationBasePoint.PubKey,
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s.RemoteChanCfg.PaymentBasePoint.PubKey,
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s.RemoteChanCfg.DelayBasePoint.PubKey,
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s.RemoteChanCfg.HtlcBasePoint.PubKey,
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shaChainPub[:],
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uint32(s.ShaChainRootDesc.KeyLocator.Family),
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s.ShaChainRootDesc.KeyLocator.Index,
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); err != nil {
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return err
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}
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if s.Version == ScriptEnforcedLeaseVersion {
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err := lnwire.WriteElements(&singleBytes, s.LeaseExpiry)
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if err != nil {
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return err
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}
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}
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// TODO(yy): remove the type assertion when we finished refactoring db
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// into using write buffer.
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buf, ok := w.(*bytes.Buffer)
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if !ok {
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return fmt.Errorf("expect io.Writer to be *bytes.Buffer")
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}
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return lnwire.WriteElements(
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buf,
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byte(s.Version),
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uint16(len(singleBytes.Bytes())),
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singleBytes.Bytes(),
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)
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}
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// PackToWriter is similar to the Serialize method, but takes the operation a
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// step further by encryption the raw bytes of the static channel back up. For
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// encryption we use the chacah20poly1305 AEAD cipher with a 24 byte nonce and
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// 32-byte key size. We use a 24-byte nonce, as we can't ensure that we have a
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// global counter to use as a sequence number for nonces, and want to ensure
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// that we're able to decrypt these blobs without any additional context. We
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// derive the key that we use for encryption via a SHA2 operation of the with
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// the golden keychain.KeyFamilyBaseEncryption base encryption key. We then
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// take the serialized resulting shared secret point, and hash it using sha256
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// to obtain the key that we'll use for encryption. When using the AEAD, we
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// pass the nonce as associated data such that we'll be able to package the two
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// together for storage. Before writing out the encrypted payload, we prepend
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// the nonce to the final blob.
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func (s *Single) PackToWriter(w io.Writer, keyRing keychain.KeyRing) error {
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// First, we'll serialize the SCB (StaticChannelBackup) into a
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// temporary buffer so we can store it in a temporary place before we
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// go to encrypt the entire thing.
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var rawBytes bytes.Buffer
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if err := s.Serialize(&rawBytes); err != nil {
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return err
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}
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// Finally, we'll encrypt the raw serialized SCB (using the nonce as
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// associated data), and write out the ciphertext prepend with the
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// nonce that we used to the passed io.Reader.
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e, err := lnencrypt.KeyRingEncrypter(keyRing)
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if err != nil {
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return fmt.Errorf("unable to generate encrypt key %v", err)
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}
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return e.EncryptPayloadToWriter(rawBytes.Bytes(), w)
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}
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// readLocalKeyDesc reads a KeyDescriptor encoded within an unpacked Single.
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// For local KeyDescs, we only write out the KeyLocator information as we can
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// re-derive the pubkey from it.
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func readLocalKeyDesc(r io.Reader) (keychain.KeyDescriptor, error) {
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var keyDesc keychain.KeyDescriptor
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var keyFam uint32
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if err := lnwire.ReadElements(r, &keyFam); err != nil {
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return keyDesc, err
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}
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keyDesc.Family = keychain.KeyFamily(keyFam)
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if err := lnwire.ReadElements(r, &keyDesc.Index); err != nil {
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return keyDesc, err
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}
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return keyDesc, nil
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}
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// readRemoteKeyDesc reads a remote KeyDescriptor encoded within an unpacked
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// Single. For remote KeyDescs, we write out only the PubKey since we don't
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// actually have the KeyLocator data.
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func readRemoteKeyDesc(r io.Reader) (keychain.KeyDescriptor, error) {
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var (
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keyDesc keychain.KeyDescriptor
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pub [33]byte
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)
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_, err := io.ReadFull(r, pub[:])
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if err != nil {
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return keychain.KeyDescriptor{}, err
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}
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keyDesc.PubKey, err = btcec.ParsePubKey(pub[:])
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if err != nil {
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return keychain.KeyDescriptor{}, err
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}
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return keyDesc, nil
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}
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// Deserialize attempts to read the raw plaintext serialized SCB from the
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// passed io.Reader. If the method is successful, then the target
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// StaticChannelBackup will be fully populated.
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func (s *Single) Deserialize(r io.Reader) error {
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// First, we'll need to read the version of this single-back up so we
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// can know how to unpack each of the SCB.
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var version byte
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err := lnwire.ReadElements(r, &version)
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if err != nil {
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return err
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}
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s.Version = SingleBackupVersion(version)
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switch s.Version {
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case DefaultSingleVersion:
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case TweaklessCommitVersion:
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case AnchorsCommitVersion:
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case AnchorsZeroFeeHtlcTxCommitVersion:
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case ScriptEnforcedLeaseVersion:
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case SimpleTaprootVersion:
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default:
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return fmt.Errorf("unable to de-serialize w/ unknown "+
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"version: %v", s.Version)
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}
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var length uint16
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if err := lnwire.ReadElements(r, &length); err != nil {
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return err
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}
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err = lnwire.ReadElements(
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r, &s.IsInitiator, s.ChainHash[:], &s.FundingOutpoint,
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&s.ShortChannelID, &s.RemoteNodePub, &s.Addresses, &s.Capacity,
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)
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if err != nil {
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return err
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}
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err = lnwire.ReadElements(r, &s.LocalChanCfg.CsvDelay)
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if err != nil {
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return err
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}
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s.LocalChanCfg.MultiSigKey, err = readLocalKeyDesc(r)
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if err != nil {
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return err
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}
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s.LocalChanCfg.RevocationBasePoint, err = readLocalKeyDesc(r)
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if err != nil {
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return err
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}
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s.LocalChanCfg.PaymentBasePoint, err = readLocalKeyDesc(r)
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if err != nil {
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return err
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}
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s.LocalChanCfg.DelayBasePoint, err = readLocalKeyDesc(r)
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if err != nil {
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return err
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}
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s.LocalChanCfg.HtlcBasePoint, err = readLocalKeyDesc(r)
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if err != nil {
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return err
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}
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err = lnwire.ReadElements(r, &s.RemoteChanCfg.CsvDelay)
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if err != nil {
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return err
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}
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s.RemoteChanCfg.MultiSigKey, err = readRemoteKeyDesc(r)
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if err != nil {
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return err
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}
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s.RemoteChanCfg.RevocationBasePoint, err = readRemoteKeyDesc(r)
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if err != nil {
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return err
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}
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s.RemoteChanCfg.PaymentBasePoint, err = readRemoteKeyDesc(r)
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if err != nil {
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return err
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}
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s.RemoteChanCfg.DelayBasePoint, err = readRemoteKeyDesc(r)
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if err != nil {
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return err
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}
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s.RemoteChanCfg.HtlcBasePoint, err = readRemoteKeyDesc(r)
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if err != nil {
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return err
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}
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// Finally, we'll parse out the ShaChainRootDesc.
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var (
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shaChainPub [33]byte
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zeroPub [33]byte
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)
|
|
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
|
|
}
|
|
}
|
|
|
|
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 %v", 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?
|