package keychain import ( "crypto/sha256" "fmt" "github.com/btcsuite/btcd/btcec" "github.com/btcsuite/btcwallet/waddrmgr" "github.com/btcsuite/btcwallet/wallet" "github.com/btcsuite/btcwallet/walletdb" ) const ( // CoinTypeBitcoin specifies the BIP44 coin type for Bitcoin key // derivation. CoinTypeBitcoin uint32 = 0 // CoinTypeTestnet specifies the BIP44 coin type for all testnet key // derivation. CoinTypeTestnet = 1 // CoinTypeLitecoin specifies the BIP44 coin type for Litecoin key // derivation. CoinTypeLitecoin = 2 ) var ( // lightningAddrSchema is the scope addr schema for all keys that we // derive. We'll treat them all as p2wkh addresses, as atm we must // specify a particular type. lightningAddrSchema = waddrmgr.ScopeAddrSchema{ ExternalAddrType: waddrmgr.WitnessPubKey, InternalAddrType: waddrmgr.WitnessPubKey, } // waddrmgrNamespaceKey is the namespace key that the waddrmgr state is // stored within the top-level waleltdb buckets of btcwallet. waddrmgrNamespaceKey = []byte("waddrmgr") ) // BtcWalletKeyRing is an implementation of both the KeyRing and SecretKeyRing // interfaces backed by btcwallet's internal root waddrmgr. Internally, we'll // be using a ScopedKeyManager to do all of our derivations, using the key // scope and scope addr scehma defined above. Re-using the existing key scope // construction means that all key derivation will be protected under the root // seed of the wallet, making each derived key fully deterministic. type BtcWalletKeyRing struct { // wallet is a pointer to the active instance of the btcwallet core. // This is required as we'll need to manually open database // transactions in order to derive addresses and lookup relevant keys wallet *wallet.Wallet // chainKeyScope defines the purpose and coin type to be used when generating // keys for this keyring. chainKeyScope waddrmgr.KeyScope // lightningScope is a pointer to the scope that we'll be using as a // sub key manager to derive all the keys that we require. lightningScope *waddrmgr.ScopedKeyManager } // NewBtcWalletKeyRing creates a new implementation of the // keychain.SecretKeyRing interface backed by btcwallet. // // NOTE: The passed waddrmgr.Manager MUST be unlocked in order for the keychain // to function. func NewBtcWalletKeyRing(w *wallet.Wallet, coinType uint32) SecretKeyRing { // Construct the key scope that will be used within the waddrmgr to // create an HD chain for deriving all of our required keys. A different // scope is used for each specific coin type. chainKeyScope := waddrmgr.KeyScope{ Purpose: BIP0043Purpose, Coin: coinType, } return &BtcWalletKeyRing{ wallet: w, chainKeyScope: chainKeyScope, } } // keyScope attempts to return the key scope that we'll use to derive all of // our keys. If the scope has already been fetched from the database, then a // cached version will be returned. Otherwise, we'll fetch it from the database // and cache it for subsequent accesses. func (b *BtcWalletKeyRing) keyScope() (*waddrmgr.ScopedKeyManager, error) { // If the scope has already been populated, then we'll return it // directly. if b.lightningScope != nil { return b.lightningScope, nil } // Otherwise, we'll first do a check to ensure that the root manager // isn't locked, as otherwise we won't be able to *use* the scope. if b.wallet.Manager.IsLocked() { return nil, fmt.Errorf("cannot create BtcWalletKeyRing with " + "locked waddrmgr.Manager") } // If the manager is indeed unlocked, then we'll fetch the scope, cache // it, and return to the caller. lnScope, err := b.wallet.Manager.FetchScopedKeyManager(b.chainKeyScope) if err != nil { return nil, err } b.lightningScope = lnScope return lnScope, nil } // createAccountIfNotExists will create the corresponding account for a key // family if it doesn't already exist in the database. func (b *BtcWalletKeyRing) createAccountIfNotExists( addrmgrNs walletdb.ReadWriteBucket, keyFam KeyFamily, scope *waddrmgr.ScopedKeyManager) error { // If this is the multi-sig key family, then we can return early as // this is the default account that's created. if keyFam == KeyFamilyMultiSig { return nil } // Otherwise, we'll check if the account already exists, if so, we can // once again bail early. _, err := scope.AccountName(addrmgrNs, uint32(keyFam)) if err == nil { return nil } // If we reach this point, then the account hasn't yet been created, so // we'll need to create it before we can proceed. return scope.NewRawAccount(addrmgrNs, uint32(keyFam)) } // DeriveNextKey attempts to derive the *next* key within the key family // (account in BIP43) specified. This method should return the next external // child within this branch. // // NOTE: This is part of the keychain.KeyRing interface. func (b *BtcWalletKeyRing) DeriveNextKey(keyFam KeyFamily) (KeyDescriptor, error) { var ( pubKey *btcec.PublicKey keyLoc KeyLocator ) db := b.wallet.Database() err := walletdb.Update(db, func(tx walletdb.ReadWriteTx) error { addrmgrNs := tx.ReadWriteBucket(waddrmgrNamespaceKey) scope, err := b.keyScope() if err != nil { return err } // If the account doesn't exist, then we may need to create it // for the first time in order to derive the keys that we // require. err = b.createAccountIfNotExists(addrmgrNs, keyFam, scope) if err != nil { return err } addrs, err := scope.NextExternalAddresses( addrmgrNs, uint32(keyFam), 1, ) if err != nil { return err } // Extract the first address, ensuring that it is of the proper // interface type, otherwise we can't manipulate it below. addr, ok := addrs[0].(waddrmgr.ManagedPubKeyAddress) if !ok { return fmt.Errorf("address is not a managed pubkey " + "addr") } pubKey = addr.PubKey() _, pathInfo, _ := addr.DerivationInfo() keyLoc = KeyLocator{ Family: keyFam, Index: pathInfo.Index, } return nil }) if err != nil { return KeyDescriptor{}, err } return KeyDescriptor{ PubKey: pubKey, KeyLocator: keyLoc, }, nil } // DeriveKey attempts to derive an arbitrary key specified by the passed // KeyLocator. This may be used in several recovery scenarios, or when manually // rotating something like our current default node key. // // NOTE: This is part of the keychain.KeyRing interface. func (b *BtcWalletKeyRing) DeriveKey(keyLoc KeyLocator) (KeyDescriptor, error) { var keyDesc KeyDescriptor db := b.wallet.Database() err := walletdb.Update(db, func(tx walletdb.ReadWriteTx) error { addrmgrNs := tx.ReadWriteBucket(waddrmgrNamespaceKey) scope, err := b.keyScope() if err != nil { return err } // If the account doesn't exist, then we may need to create it // for the first time in order to derive the keys that we // require. err = b.createAccountIfNotExists(addrmgrNs, keyLoc.Family, scope) if err != nil { return err } path := waddrmgr.DerivationPath{ Account: uint32(keyLoc.Family), Branch: 0, Index: uint32(keyLoc.Index), } addr, err := scope.DeriveFromKeyPath(addrmgrNs, path) if err != nil { return err } keyDesc.KeyLocator = keyLoc keyDesc.PubKey = addr.(waddrmgr.ManagedPubKeyAddress).PubKey() return nil }) if err != nil { return keyDesc, err } return keyDesc, nil } // DerivePrivKey attempts to derive the private key that corresponds to the // passed key descriptor. // // NOTE: This is part of the keychain.SecretKeyRing interface. func (b *BtcWalletKeyRing) DerivePrivKey(keyDesc KeyDescriptor) ( *btcec.PrivateKey, error) { var key *btcec.PrivateKey db := b.wallet.Database() err := walletdb.Update(db, func(tx walletdb.ReadWriteTx) error { addrmgrNs := tx.ReadWriteBucket(waddrmgrNamespaceKey) scope, err := b.keyScope() if err != nil { return err } // If the account doesn't exist, then we may need to create it // for the first time in order to derive the keys that we // require. err = b.createAccountIfNotExists( addrmgrNs, keyDesc.Family, scope, ) if err != nil { return err } // If the public key isn't set or they have a non-zero index, // then we know that the caller instead knows the derivation // path for a key. if keyDesc.PubKey == nil || keyDesc.Index > 0 { // Now that we know the account exists, we can safely // derive the full private key from the given path. path := waddrmgr.DerivationPath{ Account: uint32(keyDesc.Family), Branch: 0, Index: uint32(keyDesc.Index), } addr, err := scope.DeriveFromKeyPath(addrmgrNs, path) if err != nil { return err } key, err = addr.(waddrmgr.ManagedPubKeyAddress).PrivKey() if err != nil { return err } return nil } // If the public key isn't nil, then this indicates that we // need to scan for the private key, assuming that we know the // valid key family. nextPath := waddrmgr.DerivationPath{ Account: uint32(keyDesc.Family), Branch: 0, Index: 0, } // We'll now iterate through our key range in an attempt to // find the target public key. // // TODO(roasbeef): possibly move scanning into wallet to allow // to be parallelized for i := 0; i < MaxKeyRangeScan; i++ { // Derive the next key in the range and fetch its // managed address. addr, err := scope.DeriveFromKeyPath( addrmgrNs, nextPath, ) if err != nil { return err } managedAddr := addr.(waddrmgr.ManagedPubKeyAddress) // If this is the target public key, then we'll return // it directly back to the caller. if managedAddr.PubKey().IsEqual(keyDesc.PubKey) { key, err = managedAddr.PrivKey() if err != nil { return err } return nil } // This wasn't the target key, so roll forward and try // the next one. nextPath.Index++ } // If we reach this point, then we we're unable to derive the // private key, so return an error back to the user. return ErrCannotDerivePrivKey }) if err != nil { return nil, err } return key, nil } // ScalarMult performs a scalar multiplication (ECDH-like operation) between // the target key descriptor and remote public key. The output returned will be // the sha256 of the resulting shared point serialized in compressed format. If // k is our private key, and P is the public key, we perform the following // operation: // // sx := k*P s := sha256(sx.SerializeCompressed()) // // NOTE: This is part of the keychain.SecretKeyRing interface. func (b *BtcWalletKeyRing) ScalarMult(keyDesc KeyDescriptor, pub *btcec.PublicKey) ([]byte, error) { privKey, err := b.DerivePrivKey(keyDesc) if err != nil { return nil, err } s := &btcec.PublicKey{} x, y := btcec.S256().ScalarMult(pub.X, pub.Y, privKey.D.Bytes()) s.X = x s.Y = y h := sha256.Sum256(s.SerializeCompressed()) return h[:], nil } // ECDH performs a scalar multiplication (ECDH-like operation) between the // target key descriptor and remote public key. The output returned will be // the sha256 of the resulting shared point serialized in compressed format. If // k is our private key, and P is the public key, we perform the following // operation: // // sx := k*P s := sha256(sx.SerializeCompressed()) // // NOTE: This is part of the keychain.ECDHRing interface. func (b *BtcWalletKeyRing) ECDH(keyDesc KeyDescriptor, pub *btcec.PublicKey) ([32]byte, error) { privKey, err := b.DerivePrivKey(keyDesc) if err != nil { return [32]byte{}, err } s := &btcec.PublicKey{} x, y := btcec.S256().ScalarMult(pub.X, pub.Y, privKey.D.Bytes()) s.X = x s.Y = y h := sha256.Sum256(s.SerializeCompressed()) return h, nil } // SignDigest signs the given SHA256 message digest with the private key // described in the key descriptor. // // NOTE: This is part of the keychain.DigestSignerRing interface. func (b *BtcWalletKeyRing) SignDigest(keyDesc KeyDescriptor, digest [32]byte) (*btcec.Signature, error) { privKey, err := b.DerivePrivKey(keyDesc) if err != nil { return nil, err } return privKey.Sign(digest[:]) } // SignDigestCompact signs the given SHA256 message digest with the private key // described in the key descriptor and returns the signature in the compact, // public key recoverable format. // // NOTE: This is part of the keychain.DigestSignerRing interface. func (b *BtcWalletKeyRing) SignDigestCompact(keyDesc KeyDescriptor, digest [32]byte) ([]byte, error) { privKey, err := b.DerivePrivKey(keyDesc) if err != nil { return nil, err } return btcec.SignCompact(btcec.S256(), privKey, digest[:], true) }