lnd/walletunlocker/service.go
Olaoluwa Osuntokun f0e9a1f753
walletunlock: exend the Init and Unlock methods to also return optional SCB's
In this commit, we we extend the Init and Unlock methods to also parse
out and return optional SCB instances. With this change, when the user
creates their node, if they have an existing seed and also a set of SCBs
(either single or multi), they'll be able to recover both their on-chain
balance, and also any funds that were settled within their existing
channels.
2019-03-28 17:53:23 -07:00

443 lines
15 KiB
Go

package walletunlocker
import (
"crypto/rand"
"errors"
"fmt"
"os"
"time"
"github.com/btcsuite/btcd/chaincfg"
"github.com/btcsuite/btcwallet/wallet"
"github.com/lightningnetwork/lnd/aezeed"
"github.com/lightningnetwork/lnd/chanbackup"
"github.com/lightningnetwork/lnd/keychain"
"github.com/lightningnetwork/lnd/lnrpc"
"github.com/lightningnetwork/lnd/lnwallet"
"github.com/lightningnetwork/lnd/lnwallet/btcwallet"
"golang.org/x/net/context"
)
// ChannelsToRecover wraps any set of packed (serialized+encrypted) channel
// back ups together. These can be passed in when unlocking the wallet, or
// creating a new wallet for the first time with an existing seed.
type ChannelsToRecover struct {
// PackedMultiChanBackup is an encrypted and serialized multi-channel
// backup.
PackedMultiChanBackup chanbackup.PackedMulti
// PackedSingleChanBackups is a series of encrypted and serialized
// single-channel backup for one or more channels.
PackedSingleChanBackups chanbackup.PackedSingles
}
// WalletInitMsg is a message sent by the UnlockerService when a user wishes to
// set up the internal wallet for the first time. The user MUST provide a
// passphrase, but is also able to provide their own source of entropy. If
// provided, then this source of entropy will be used to generate the wallet's
// HD seed. Otherwise, the wallet will generate one itself.
type WalletInitMsg struct {
// Passphrase is the passphrase that will be used to encrypt the wallet
// itself. This MUST be at least 8 characters.
Passphrase []byte
// WalletSeed is the deciphered cipher seed that the wallet should use
// to initialize itself.
WalletSeed *aezeed.CipherSeed
// RecoveryWindow is the address look-ahead used when restoring a seed
// with existing funds. A recovery window zero indicates that no
// recovery should be attempted, such as after the wallet's initial
// creation.
RecoveryWindow uint32
// ChanBackups a set of static channel backups that should be received
// after the wallet has been initialized.
ChanBackups ChannelsToRecover
}
// WalletUnlockMsg is a message sent by the UnlockerService when a user wishes
// to unlock the internal wallet after initial setup. The user can optionally
// specify a recovery window, which will resume an interrupted rescan for used
// addresses.
type WalletUnlockMsg struct {
// Passphrase is the passphrase that will be used to encrypt the wallet
// itself. This MUST be at least 8 characters.
Passphrase []byte
// RecoveryWindow is the address look-ahead used when restoring a seed
// with existing funds. A recovery window zero indicates that no
// recovery should be attempted, such as after the wallet's initial
// creation, but before any addresses have been created.
RecoveryWindow uint32
// Wallet is the loaded and unlocked Wallet. This is returned through
// the channel to avoid it being unlocked twice (once to check if the
// password is correct, here in the WalletUnlocker and again later when
// lnd actually uses it). Because unlocking involves scrypt which is
// resource intensive, we want to avoid doing it twice.
Wallet *wallet.Wallet
// ChanBackups a set of static channel backups that should be received
// after the wallet has been unlocked.
ChanBackups ChannelsToRecover
}
// UnlockerService implements the WalletUnlocker service used to provide lnd
// with a password for wallet encryption at startup. Additionally, during
// initial setup, users can provide their own source of entropy which will be
// used to generate the seed that's ultimately used within the wallet.
type UnlockerService struct {
// InitMsgs is a channel that carries all wallet init messages.
InitMsgs chan *WalletInitMsg
// UnlockMsgs is a channel where unlock parameters provided by the rpc
// client to be used to unlock and decrypt an existing wallet will be
// sent.
UnlockMsgs chan *WalletUnlockMsg
chainDir string
netParams *chaincfg.Params
macaroonFiles []string
}
// New creates and returns a new UnlockerService.
func New(chainDir string, params *chaincfg.Params,
macaroonFiles []string) *UnlockerService {
return &UnlockerService{
InitMsgs: make(chan *WalletInitMsg, 1),
UnlockMsgs: make(chan *WalletUnlockMsg, 1),
chainDir: chainDir,
netParams: params,
macaroonFiles: macaroonFiles,
}
}
// GenSeed is the first method that should be used to instantiate a new lnd
// instance. This method allows a caller to generate a new aezeed cipher seed
// given an optional passphrase. If provided, the passphrase will be necessary
// to decrypt the cipherseed to expose the internal wallet seed.
//
// Once the cipherseed is obtained and verified by the user, the InitWallet
// method should be used to commit the newly generated seed, and create the
// wallet.
func (u *UnlockerService) GenSeed(ctx context.Context,
in *lnrpc.GenSeedRequest) (*lnrpc.GenSeedResponse, error) {
// Before we start, we'll ensure that the wallet hasn't already created
// so we don't show a *new* seed to the user if one already exists.
netDir := btcwallet.NetworkDir(u.chainDir, u.netParams)
loader := wallet.NewLoader(u.netParams, netDir, 0)
walletExists, err := loader.WalletExists()
if err != nil {
return nil, err
}
if walletExists {
return nil, fmt.Errorf("wallet already exists")
}
var entropy [aezeed.EntropySize]byte
switch {
// If the user provided any entropy, then we'll make sure it's sized
// properly.
case len(in.SeedEntropy) != 0 && len(in.SeedEntropy) != aezeed.EntropySize:
return nil, fmt.Errorf("incorrect entropy length: expected "+
"16 bytes, instead got %v bytes", len(in.SeedEntropy))
// If the user provided the correct number of bytes, then we'll copy it
// over into our buffer for usage.
case len(in.SeedEntropy) == aezeed.EntropySize:
copy(entropy[:], in.SeedEntropy[:])
// Otherwise, we'll generate a fresh new set of bytes to use as entropy
// to generate the seed.
default:
if _, err := rand.Read(entropy[:]); err != nil {
return nil, err
}
}
// Now that we have our set of entropy, we'll create a new cipher seed
// instance.
//
cipherSeed, err := aezeed.New(
keychain.KeyDerivationVersion, &entropy, time.Now(),
)
if err != nil {
return nil, err
}
// With our raw cipher seed obtained, we'll convert it into an encoded
// mnemonic using the user specified pass phrase.
mnemonic, err := cipherSeed.ToMnemonic(in.AezeedPassphrase)
if err != nil {
return nil, err
}
// Additionally, we'll also obtain the raw enciphered cipher seed as
// well to return to the user.
encipheredSeed, err := cipherSeed.Encipher(in.AezeedPassphrase)
if err != nil {
return nil, err
}
return &lnrpc.GenSeedResponse{
CipherSeedMnemonic: []string(mnemonic[:]),
EncipheredSeed: encipheredSeed[:],
}, nil
}
// extractChanBackups is a helper function that extracts the set of channel
// backups from the proto into a format that we'll pass to higher level
// sub-systems.
func extractChanBackups(chanBackups *lnrpc.ChanBackupSnapshot) *ChannelsToRecover {
// If there aren't any populated channel backups, then we can exit
// early as there's nothing to extract.
if chanBackups == nil || (chanBackups.SingleChanBackups == nil &&
chanBackups.MultiChanBackup == nil) {
return nil
}
// Now that we know there's at least a single back up populated, we'll
// extract the multi-chan backup (if it's there).
var backups ChannelsToRecover
if chanBackups.MultiChanBackup != nil {
multiBackup := chanBackups.MultiChanBackup
backups.PackedMultiChanBackup = chanbackup.PackedMulti(
multiBackup.MultiChanBackup,
)
}
if chanBackups.SingleChanBackups == nil {
return &backups
}
// Finally, we can extract all the single chan backups as well.
for _, backup := range chanBackups.SingleChanBackups.ChanBackups {
singleChanBackup := backup.ChanBackup
backups.PackedSingleChanBackups = append(
backups.PackedSingleChanBackups, singleChanBackup,
)
}
return &backups
}
// InitWallet is used when lnd is starting up for the first time to fully
// initialize the daemon and its internal wallet. At the very least a wallet
// password must be provided. This will be used to encrypt sensitive material
// on disk.
//
// In the case of a recovery scenario, the user can also specify their aezeed
// mnemonic and passphrase. If set, then the daemon will use this prior state
// to initialize its internal wallet.
//
// Alternatively, this can be used along with the GenSeed RPC to obtain a
// seed, then present it to the user. Once it has been verified by the user,
// the seed can be fed into this RPC in order to commit the new wallet.
func (u *UnlockerService) InitWallet(ctx context.Context,
in *lnrpc.InitWalletRequest) (*lnrpc.InitWalletResponse, error) {
// Make sure the password meets our constraints.
password := in.WalletPassword
if err := ValidatePassword(password); err != nil {
return nil, err
}
// Require that the recovery window be non-negative.
recoveryWindow := in.RecoveryWindow
if recoveryWindow < 0 {
return nil, fmt.Errorf("recovery window %d must be "+
"non-negative", recoveryWindow)
}
// We'll then open up the directory that will be used to store the
// wallet's files so we can check if the wallet already exists.
netDir := btcwallet.NetworkDir(u.chainDir, u.netParams)
loader := wallet.NewLoader(u.netParams, netDir, uint32(recoveryWindow))
walletExists, err := loader.WalletExists()
if err != nil {
return nil, err
}
// If the wallet already exists, then we'll exit early as we can't
// create the wallet if it already exists!
if walletExists {
return nil, fmt.Errorf("wallet already exists")
}
// At this point, we know that the wallet doesn't already exist. So
// we'll map the user provided aezeed and passphrase into a decoded
// cipher seed instance.
var mnemonic aezeed.Mnemonic
copy(mnemonic[:], in.CipherSeedMnemonic[:])
// If we're unable to map it back into the ciphertext, then either the
// mnemonic is wrong, or the passphrase is wrong.
cipherSeed, err := mnemonic.ToCipherSeed(in.AezeedPassphrase)
if err != nil {
return nil, err
}
// With the cipher seed deciphered, and the auth service created, we'll
// now send over the wallet password and the seed. This will allow the
// daemon to initialize itself and startup.
initMsg := &WalletInitMsg{
Passphrase: password,
WalletSeed: cipherSeed,
RecoveryWindow: uint32(recoveryWindow),
}
// Before we return the unlock payload, we'll check if we can extract
// any channel backups to pass up to the higher level sub-system.
chansToRestore := extractChanBackups(in.ChannelBackups)
if chansToRestore != nil {
initMsg.ChanBackups = *chansToRestore
}
u.InitMsgs <- initMsg
return &lnrpc.InitWalletResponse{}, nil
}
// UnlockWallet sends the password provided by the incoming UnlockWalletRequest
// over the UnlockMsgs channel in case it successfully decrypts an existing
// wallet found in the chain's wallet database directory.
func (u *UnlockerService) UnlockWallet(ctx context.Context,
in *lnrpc.UnlockWalletRequest) (*lnrpc.UnlockWalletResponse, error) {
password := in.WalletPassword
recoveryWindow := uint32(in.RecoveryWindow)
netDir := btcwallet.NetworkDir(u.chainDir, u.netParams)
loader := wallet.NewLoader(u.netParams, netDir, recoveryWindow)
// Check if wallet already exists.
walletExists, err := loader.WalletExists()
if err != nil {
return nil, err
}
if !walletExists {
// Cannot unlock a wallet that does not exist!
return nil, fmt.Errorf("wallet not found")
}
// Try opening the existing wallet with the provided password.
unlockedWallet, err := loader.OpenExistingWallet(password, false)
if err != nil {
// Could not open wallet, most likely this means that provided
// password was incorrect.
return nil, err
}
// We successfully opened the wallet and pass the instance back to
// avoid it needing to be unlocked again.
walletUnlockMsg := &WalletUnlockMsg{
Passphrase: password,
RecoveryWindow: recoveryWindow,
Wallet: unlockedWallet,
}
// Before we return the unlock payload, we'll check if we can extract
// any channel backups to pass up to the higher level sub-system.
chansToRestore := extractChanBackups(in.ChannelBackups)
if chansToRestore != nil {
walletUnlockMsg.ChanBackups = *chansToRestore
}
// At this point we was able to open the existing wallet with the
// provided password. We send the password over the UnlockMsgs
// channel, such that it can be used by lnd to open the wallet.
u.UnlockMsgs <- walletUnlockMsg
return &lnrpc.UnlockWalletResponse{}, nil
}
// ChangePassword changes the password of the wallet and sends the new password
// across the UnlockPasswords channel to automatically unlock the wallet if
// successful.
func (u *UnlockerService) ChangePassword(ctx context.Context,
in *lnrpc.ChangePasswordRequest) (*lnrpc.ChangePasswordResponse, error) {
netDir := btcwallet.NetworkDir(u.chainDir, u.netParams)
loader := wallet.NewLoader(u.netParams, netDir, 0)
// First, we'll make sure the wallet exists for the specific chain and
// network.
walletExists, err := loader.WalletExists()
if err != nil {
return nil, err
}
if !walletExists {
return nil, errors.New("wallet not found")
}
publicPw := in.CurrentPassword
privatePw := in.CurrentPassword
// If the current password is blank, we'll assume the user is coming
// from a --noseedbackup state, so we'll use the default passwords.
if len(in.CurrentPassword) == 0 {
publicPw = lnwallet.DefaultPublicPassphrase
privatePw = lnwallet.DefaultPrivatePassphrase
}
// Make sure the new password meets our constraints.
if err := ValidatePassword(in.NewPassword); err != nil {
return nil, err
}
// Load the existing wallet in order to proceed with the password change.
w, err := loader.OpenExistingWallet(publicPw, false)
if err != nil {
return nil, err
}
// Unload the wallet to allow lnd to open it later on.
defer loader.UnloadWallet()
// Since the macaroon database is also encrypted with the wallet's
// password, we'll remove all of the macaroon files so that they're
// re-generated at startup using the new password. We'll make sure to do
// this after unlocking the wallet to ensure macaroon files don't get
// deleted with incorrect password attempts.
for _, file := range u.macaroonFiles {
err := os.Remove(file)
if err != nil && !os.IsNotExist(err) {
return nil, err
}
}
// Attempt to change both the public and private passphrases for the
// wallet. This will be done atomically in order to prevent one
// passphrase change from being successful and not the other.
err = w.ChangePassphrases(
publicPw, in.NewPassword, privatePw, in.NewPassword,
)
if err != nil {
return nil, fmt.Errorf("unable to change wallet passphrase: "+
"%v", err)
}
// Finally, send the new password across the UnlockPasswords channel to
// automatically unlock the wallet.
u.UnlockMsgs <- &WalletUnlockMsg{Passphrase: in.NewPassword}
return &lnrpc.ChangePasswordResponse{}, nil
}
// ValidatePassword assures the password meets all of our constraints.
func ValidatePassword(password []byte) error {
// Passwords should have a length of at least 8 characters.
if len(password) < 8 {
return errors.New("password must have at least 8 characters")
}
return nil
}