package keys import ( "bufio" "fmt" "os" "strings" "github.com/pkg/errors" crypto "github.com/tendermint/go-crypto" "github.com/tendermint/go-crypto/keys/words" dbm "github.com/tendermint/tmlibs/db" ) // dbKeybase combines encyption and storage implementation to provide // a full-featured key manager type dbKeybase struct { db dbm.DB codec words.Codec } func New(db dbm.DB, codec words.Codec) dbKeybase { return dbKeybase{ db: db, codec: codec, } } var _ Keybase = dbKeybase{} // CreateMnemonic generates a new key and persists it to storage, encrypted // using the passphrase. It returns the generated seedphrase // (mnemonic) and the key Info. It returns an error if it fails to // generate a key for the given algo type, or if another key is // already stored under the same name. func (kb dbKeybase) CreateMnemonic(name, passphrase string, algo SignAlgo) (Info, string, error) { // NOTE: secret is SHA256 hashed by secp256k1 and ed25519. // 16 byte secret corresponds to 12 BIP39 words. // XXX: Ledgers use 24 words now - should we ? secret := crypto.CRandBytes(16) priv, err := generate(algo, secret) if err != nil { return nil, "", err } // encrypt and persist the key info := kb.writeLocalKey(priv, name, passphrase) // we append the type byte to the serialized secret to help with // recovery // ie [secret] = [type] + [secret] typ := cryptoAlgoToByte(algo) secret = append([]byte{typ}, secret...) // return the mnemonic phrase words, err := kb.codec.BytesToWords(secret) seed := strings.Join(words, " ") return info, seed, err } // CreateLedger creates a new locally-stored reference to a Ledger keypair // It returns the created key info and an error if the Ledger could not be queried func (kb dbKeybase) CreateLedger(name string, path crypto.DerivationPath, algo SignAlgo) (Info, error) { if algo != AlgoSecp256k1 { return nil, fmt.Errorf("Only secp256k1 is supported for Ledger devices") } priv, err := crypto.NewPrivKeyLedgerSecp256k1(path) if err != nil { return nil, err } pub, err := priv.PubKey() if err != nil { return nil, err } return kb.writeLedgerKey(pub, path, name), nil } // CreateOffline creates a new reference to an offline keypair // It returns the created key info func (kb dbKeybase) CreateOffline(name string, pub crypto.PubKey) (Info, error) { return kb.writeOfflineKey(pub, name), nil } // Recover converts a seedphrase to a private key and persists it, // encrypted with the given passphrase. Functions like Create, but // seedphrase is input not output. func (kb dbKeybase) Recover(name, passphrase, seedphrase string) (Info, error) { words := strings.Split(strings.TrimSpace(seedphrase), " ") secret, err := kb.codec.WordsToBytes(words) if err != nil { return nil, err } // secret is comprised of the actual secret with the type // appended. // ie [secret] = [type] + [secret] typ, secret := secret[0], secret[1:] algo := byteToSignAlgo(typ) priv, err := generate(algo, secret) if err != nil { return nil, err } // encrypt and persist key. public := kb.writeLocalKey(priv, name, passphrase) return public, nil } // List returns the keys from storage in alphabetical order. func (kb dbKeybase) List() ([]Info, error) { var res []Info iter := kb.db.Iterator(nil, nil) defer iter.Close() for ; iter.Valid(); iter.Next() { info, err := readInfo(iter.Value()) if err != nil { return nil, err } res = append(res, info) } return res, nil } // Get returns the public information about one key. func (kb dbKeybase) Get(name string) (Info, error) { bs := kb.db.Get(infoKey(name)) return readInfo(bs) } // Sign signs the msg with the named key. // It returns an error if the key doesn't exist or the decryption fails. func (kb dbKeybase) Sign(name, passphrase string, msg []byte) (sig crypto.Signature, pub crypto.PubKey, err error) { info, err := kb.Get(name) if err != nil { return } var priv crypto.PrivKey switch info.(type) { case localInfo: linfo := info.(localInfo) if linfo.PrivKeyArmor == "" { err = fmt.Errorf("private key not available") return } priv, err = unarmorDecryptPrivKey(linfo.PrivKeyArmor, passphrase) if err != nil { return nil, nil, err } case ledgerInfo: linfo := info.(ledgerInfo) priv, err = crypto.NewPrivKeyLedgerSecp256k1(linfo.Path) if err != nil { return } case offlineInfo: linfo := info.(offlineInfo) fmt.Printf("Bytes to sign:\n%s", msg) buf := bufio.NewReader(os.Stdin) fmt.Printf("\nEnter Amino-encoded signature:\n") // Will block until user inputs the signature signed, err := buf.ReadString('\n') if err != nil { return nil, nil, err } cdc.MustUnmarshalBinary([]byte(signed), sig) return sig, linfo.GetPubKey(), nil } sig, err = priv.Sign(msg) if err != nil { return nil, nil, err } pub, err = priv.PubKey() if err != nil { return nil, nil, err } return sig, pub, nil } func (kb dbKeybase) Export(name string) (armor string, err error) { bz := kb.db.Get(infoKey(name)) if bz == nil { return "", errors.New("No key to export with name " + name) } return armorInfoBytes(bz), nil } // ExportPubKey returns public keys in ASCII armored format. // Retrieve a Info object by its name and return the public key in // a portable format. func (kb dbKeybase) ExportPubKey(name string) (armor string, err error) { bz := kb.db.Get(infoKey(name)) if bz == nil { return "", errors.New("No key to export with name " + name) } info, err := readInfo(bz) if err != nil { return } return armorPubKeyBytes(info.GetPubKey().Bytes()), nil } func (kb dbKeybase) Import(name string, armor string) (err error) { bz := kb.db.Get(infoKey(name)) if len(bz) > 0 { return errors.New("Cannot overwrite data for name " + name) } infoBytes, err := unarmorInfoBytes(armor) if err != nil { return } kb.db.Set(infoKey(name), infoBytes) return nil } // ImportPubKey imports ASCII-armored public keys. // Store a new Info object holding a public key only, i.e. it will // not be possible to sign with it as it lacks the secret key. func (kb dbKeybase) ImportPubKey(name string, armor string) (err error) { bz := kb.db.Get(infoKey(name)) if len(bz) > 0 { return errors.New("Cannot overwrite data for name " + name) } pubBytes, err := unarmorPubKeyBytes(armor) if err != nil { return } pubKey, err := crypto.PubKeyFromBytes(pubBytes) if err != nil { return } kb.writeOfflineKey(pubKey, name) return } // Delete removes key forever, but we must present the // proper passphrase before deleting it (for security). // A passphrase of 'yes' is used to delete stored // references to offline and Ledger / HW wallet keys func (kb dbKeybase) Delete(name, passphrase string) error { // verify we have the proper password before deleting info, err := kb.Get(name) if err != nil { return err } switch info.(type) { case localInfo: linfo := info.(localInfo) _, err = unarmorDecryptPrivKey(linfo.PrivKeyArmor, passphrase) if err != nil { return err } kb.db.DeleteSync(infoKey(name)) return nil case ledgerInfo: case offlineInfo: if passphrase != "yes" { return fmt.Errorf("enter exactly 'yes' to delete the key") } kb.db.DeleteSync(infoKey(name)) return nil } return nil } // Update changes the passphrase with which an already stored key is // encrypted. // // oldpass must be the current passphrase used for encryption, // newpass will be the only valid passphrase from this time forward. func (kb dbKeybase) Update(name, oldpass, newpass string) error { info, err := kb.Get(name) if err != nil { return err } switch info.(type) { case localInfo: linfo := info.(localInfo) key, err := unarmorDecryptPrivKey(linfo.PrivKeyArmor, oldpass) if err != nil { return err } kb.writeLocalKey(key, name, newpass) return nil default: return fmt.Errorf("Locally stored key required") } } func (kb dbKeybase) writeLocalKey(priv crypto.PrivKey, name, passphrase string) Info { // encrypt private key using passphrase privArmor := encryptArmorPrivKey(priv, passphrase) // make Info pub, err := priv.PubKey() if err != nil { panic(err) } info := newLocalInfo(name, pub, privArmor) kb.writeInfo(info, name) return info } func (kb dbKeybase) writeLedgerKey(pub crypto.PubKey, path crypto.DerivationPath, name string) Info { info := newLedgerInfo(name, pub, path) kb.writeInfo(info, name) return info } func (kb dbKeybase) writeOfflineKey(pub crypto.PubKey, name string) Info { info := newOfflineInfo(name, pub) kb.writeInfo(info, name) return info } func (kb dbKeybase) writeInfo(info Info, name string) { // write the info by key kb.db.SetSync(infoKey(name), writeInfo(info)) } func generate(algo SignAlgo, secret []byte) (crypto.PrivKey, error) { switch algo { case AlgoEd25519: return crypto.GenPrivKeyEd25519FromSecret(secret), nil case AlgoSecp256k1: return crypto.GenPrivKeySecp256k1FromSecret(secret), nil default: err := errors.Errorf("Cannot generate keys for algorithm: %s", algo) return nil, err } } func infoKey(name string) []byte { return []byte(fmt.Sprintf("%s.info", name)) }