// Copyright (c) 2013-2017 The btcsuite developers // Copyright (c) 2015-2016 The Decred developers // Copyright (C) 2015-2017 The Lightning Network Developers package main import ( "bytes" "crypto/ecdsa" "crypto/elliptic" "crypto/rand" "crypto/tls" "crypto/x509" "crypto/x509/pkix" "encoding/pem" "fmt" "io/ioutil" "math/big" "net" "net/http" _ "net/http/pprof" "os" "path/filepath" "runtime/pprof" "strings" "sync" "time" "gopkg.in/macaroon-bakery.v2/bakery" "golang.org/x/net/context" "google.golang.org/grpc" "google.golang.org/grpc/credentials" proxy "github.com/grpc-ecosystem/grpc-gateway/runtime" flags "github.com/jessevdk/go-flags" "github.com/lightningnetwork/lnd/autopilot" "github.com/lightningnetwork/lnd/channeldb" "github.com/lightningnetwork/lnd/keychain" "github.com/lightningnetwork/lnd/lnrpc" "github.com/lightningnetwork/lnd/lnwallet" "github.com/lightningnetwork/lnd/lnwallet/btcwallet" "github.com/lightningnetwork/lnd/lnwire" "github.com/lightningnetwork/lnd/macaroons" "github.com/lightningnetwork/lnd/walletunlocker" "github.com/roasbeef/btcd/btcec" "github.com/roasbeef/btcd/wire" "github.com/roasbeef/btcutil" "github.com/roasbeef/btcwallet/wallet" ) const ( // Make certificate valid for 14 months. autogenCertValidity = 14 /*months*/ * 30 /*days*/ * 24 * time.Hour ) var ( //Commit stores the current commit hash of this build. This should be //set using -ldflags during compilation. Commit string cfg *config shutdownChannel = make(chan struct{}) registeredChains = newChainRegistry() macaroonDatabaseDir string // End of ASN.1 time. endOfTime = time.Date(2049, 12, 31, 23, 59, 59, 0, time.UTC) // Max serial number. serialNumberLimit = new(big.Int).Lsh(big.NewInt(1), 128) /* * These cipher suites fit the following criteria: * - Don't use outdated algorithms like SHA-1 and 3DES * - Don't use ECB mode or other insecure symmetric methods * - Included in the TLS v1.2 suite * - Are available in the Go 1.7.6 standard library (more are * available in 1.8.3 and will be added after lnd no longer * supports 1.7, including suites that support CBC mode) **/ tlsCipherSuites = []uint16{ tls.TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256, tls.TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256, tls.TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384, tls.TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305, } ) // lndMain is the true entry point for lnd. This function is required since // defers created in the top-level scope of a main method aren't executed if // os.Exit() is called. func lndMain() error { // Load the configuration, and parse any command line options. This // function will also set up logging properly. loadedConfig, err := loadConfig() if err != nil { return err } cfg = loadedConfig defer func() { if logRotator != nil { logRotator.Close() } }() // Show version at startup. ltndLog.Infof("Version %s", version()) var network string switch { case cfg.Bitcoin.TestNet3 || cfg.Litecoin.TestNet3: network = "testnet" case cfg.Bitcoin.MainNet || cfg.Litecoin.MainNet: network = "mainnet" case cfg.Bitcoin.SimNet: network = "simmnet" case cfg.Bitcoin.RegTest: network = "regtest" } ltndLog.Infof("Active chain: %v (network=%v)", strings.Title(registeredChains.PrimaryChain().String()), network, ) // Enable http profiling server if requested. if cfg.Profile != "" { go func() { listenAddr := net.JoinHostPort("", cfg.Profile) profileRedirect := http.RedirectHandler("/debug/pprof", http.StatusSeeOther) http.Handle("/", profileRedirect) fmt.Println(http.ListenAndServe(listenAddr, nil)) }() } // Write cpu profile if requested. if cfg.CPUProfile != "" { f, err := os.Create(cfg.CPUProfile) if err != nil { ltndLog.Errorf("Unable to create cpu profile: %v", err) return err } pprof.StartCPUProfile(f) defer f.Close() defer pprof.StopCPUProfile() } // Create the network-segmented directory for the channel database. graphDir := filepath.Join(cfg.DataDir, defaultGraphSubDirname, normalizeNetwork(activeNetParams.Name)) // Open the channeldb, which is dedicated to storing channel, and // network related metadata. chanDB, err := channeldb.Open(graphDir) if err != nil { ltndLog.Errorf("unable to open channeldb: %v", err) return err } defer chanDB.Close() // Only process macaroons if --no-macaroons isn't set. ctx := context.Background() ctx, cancel := context.WithCancel(ctx) defer cancel() // Ensure we create TLS key and certificate if they don't exist if !fileExists(cfg.TLSCertPath) && !fileExists(cfg.TLSKeyPath) { if err := genCertPair(cfg.TLSCertPath, cfg.TLSKeyPath); err != nil { return err } } cert, err := tls.LoadX509KeyPair(cfg.TLSCertPath, cfg.TLSKeyPath) if err != nil { return err } tlsConf := &tls.Config{ Certificates: []tls.Certificate{cert}, CipherSuites: tlsCipherSuites, MinVersion: tls.VersionTLS12, } sCreds := credentials.NewTLS(tlsConf) serverOpts := []grpc.ServerOption{grpc.Creds(sCreds)} cCreds, err := credentials.NewClientTLSFromFile(cfg.TLSCertPath, "") if err != nil { return err } proxyOpts := []grpc.DialOption{grpc.WithTransportCredentials(cCreds)} var macaroonService *macaroons.Service if !cfg.NoMacaroons { // Create the macaroon authentication/authorization service. macaroonService, err = macaroons.NewService(macaroonDatabaseDir, macaroons.IPLockChecker) if err != nil { srvrLog.Errorf("unable to create macaroon service: %v", err) return err } defer macaroonService.Close() } var ( privateWalletPw = []byte("hello") publicWalletPw = []byte("public") birthday time.Time recoveryWindow uint32 ) // We wait until the user provides a password over RPC. In case lnd is // started with the --noencryptwallet flag, we use the default password // "hello" for wallet encryption. if !cfg.NoEncryptWallet { walletInitParams, err := waitForWalletPassword( cfg.RPCListeners, cfg.RESTListeners, serverOpts, proxyOpts, tlsConf, macaroonService, ) if err != nil { return err } privateWalletPw = walletInitParams.Password publicWalletPw = walletInitParams.Password birthday = walletInitParams.Birthday recoveryWindow = walletInitParams.RecoveryWindow if recoveryWindow > 0 { ltndLog.Infof("Wallet recovery mode enabled with "+ "address lookahead of %d addresses", recoveryWindow) } } if !cfg.NoMacaroons { // Try to unlock the macaroon store with the private password. // Ignore ErrAlreadyUnlocked since it could be unlocked by the // wallet unlocker. err = macaroonService.CreateUnlock(&privateWalletPw) if err != nil && err != macaroons.ErrAlreadyUnlocked { srvrLog.Error(err) return err } // Create macaroon files for lncli to use if they don't exist. if !fileExists(cfg.AdminMacPath) && !fileExists(cfg.ReadMacPath) && !fileExists(cfg.InvoiceMacPath) { err = genMacaroons( ctx, macaroonService, cfg.AdminMacPath, cfg.ReadMacPath, cfg.InvoiceMacPath, ) if err != nil { ltndLog.Errorf("unable to create macaroon "+ "files: %v", err) return err } } } // With the information parsed from the configuration, create valid // instances of the pertinent interfaces required to operate the // Lightning Network Daemon. activeChainControl, chainCleanUp, err := newChainControlFromConfig( cfg, chanDB, privateWalletPw, publicWalletPw, birthday, recoveryWindow, ) if err != nil { fmt.Printf("unable to create chain control: %v\n", err) return err } if chainCleanUp != nil { defer chainCleanUp() } // Finally before we start the server, we'll register the "holy // trinity" of interface for our current "home chain" with the active // chainRegistry interface. primaryChain := registeredChains.PrimaryChain() registeredChains.RegisterChain(primaryChain, activeChainControl) // Select the configuration and furnding parameters for Bitcoin or // Litecoin, depending on the primary registered chain. chainCfg := cfg.Bitcoin minRemoteDelay := minBtcRemoteDelay maxRemoteDelay := maxBtcRemoteDelay if primaryChain == litecoinChain { chainCfg = cfg.Litecoin minRemoteDelay = minLtcRemoteDelay maxRemoteDelay = maxLtcRemoteDelay } // TODO(roasbeef): add rotation idPrivKey, err := activeChainControl.wallet.DerivePrivKey(keychain.KeyDescriptor{ KeyLocator: keychain.KeyLocator{ Family: keychain.KeyFamilyNodeKey, Index: 0, }, }) if err != nil { return err } idPrivKey.Curve = btcec.S256() if cfg.Tor.Socks != "" && cfg.Tor.DNS != "" { srvrLog.Infof("Proxying all network traffic via Tor "+ "(stream_isolation=%v)! NOTE: If running with a full-node "+ "backend, ensure that is proxying over Tor as well", cfg.Tor.StreamIsolation) } // Set up the core server which will listen for incoming peer // connections. server, err := newServer( cfg.Listeners, chanDB, activeChainControl, idPrivKey, ) if err != nil { srvrLog.Errorf("unable to create server: %v\n", err) return err } // Next, we'll initialize the funding manager itself so it can answer // queries while the wallet+chain are still syncing. nodeSigner := newNodeSigner(idPrivKey) var chanIDSeed [32]byte if _, err := rand.Read(chanIDSeed[:]); err != nil { return err } fundingMgr, err := newFundingManager(fundingConfig{ IDKey: idPrivKey.PubKey(), Wallet: activeChainControl.wallet, PublishTransaction: activeChainControl.wallet.PublishTransaction, Notifier: activeChainControl.chainNotifier, FeeEstimator: activeChainControl.feeEstimator, SignMessage: func(pubKey *btcec.PublicKey, msg []byte) (*btcec.Signature, error) { if pubKey.IsEqual(idPrivKey.PubKey()) { return nodeSigner.SignMessage(pubKey, msg) } return activeChainControl.msgSigner.SignMessage( pubKey, msg, ) }, CurrentNodeAnnouncement: func() (lnwire.NodeAnnouncement, error) { return server.genNodeAnnouncement(true) }, SendAnnouncement: func(msg lnwire.Message) error { errChan := server.authGossiper.ProcessLocalAnnouncement(msg, idPrivKey.PubKey()) return <-errChan }, SendToPeer: server.SendToPeer, NotifyWhenOnline: server.NotifyWhenOnline, FindPeer: server.FindPeer, TempChanIDSeed: chanIDSeed, FindChannel: func(chanID lnwire.ChannelID) (*lnwallet.LightningChannel, error) { dbChannels, err := chanDB.FetchAllChannels() if err != nil { return nil, err } for _, channel := range dbChannels { if chanID.IsChanPoint(&channel.FundingOutpoint) { // TODO(roasbeef): populate beacon return lnwallet.NewLightningChannel( activeChainControl.signer, server.witnessBeacon, channel) } } return nil, fmt.Errorf("unable to find channel") }, DefaultRoutingPolicy: activeChainControl.routingPolicy, NumRequiredConfs: func(chanAmt btcutil.Amount, pushAmt lnwire.MilliSatoshi) uint16 { // For large channels we increase the number // of confirmations we require for the // channel to be considered open. As it is // always the responder that gets to choose // value, the pushAmt is value being pushed // to us. This means we have more to lose // in the case this gets re-orged out, and // we will require more confirmations before // we consider it open. // TODO(halseth): Use Litecoin params in case // of LTC channels. // In case the user has explicitly specified // a default value for the number of // confirmations, we use it. defaultConf := uint16(chainCfg.DefaultNumChanConfs) if defaultConf != 0 { return defaultConf } // If not we return a value scaled linearly // between 3 and 6, depending on channel size. // TODO(halseth): Use 1 as minimum? minConf := uint64(3) maxConf := uint64(6) maxChannelSize := uint64( lnwire.NewMSatFromSatoshis(maxFundingAmount)) stake := lnwire.NewMSatFromSatoshis(chanAmt) + pushAmt conf := maxConf * uint64(stake) / maxChannelSize if conf < minConf { conf = minConf } if conf > maxConf { conf = maxConf } return uint16(conf) }, RequiredRemoteDelay: func(chanAmt btcutil.Amount) uint16 { // We scale the remote CSV delay (the time the // remote have to claim funds in case of a unilateral // close) linearly from minRemoteDelay blocks // for small channels, to maxRemoteDelay blocks // for channels of size maxFundingAmount. // TODO(halseth): Litecoin parameter for LTC. // In case the user has explicitly specified // a default value for the remote delay, we // use it. defaultDelay := uint16(chainCfg.DefaultRemoteDelay) if defaultDelay > 0 { return defaultDelay } // If not we scale according to channel size. delay := uint16(btcutil.Amount(maxRemoteDelay) * chanAmt / maxFundingAmount) if delay < minRemoteDelay { delay = minRemoteDelay } if delay > maxRemoteDelay { delay = maxRemoteDelay } return delay }, WatchNewChannel: func(channel *channeldb.OpenChannel, addr *lnwire.NetAddress) error { // First, we'll mark this new peer as a persistent peer // for re-connection purposes. server.mu.Lock() pubStr := string(addr.IdentityKey.SerializeCompressed()) server.persistentPeers[pubStr] = struct{}{} server.mu.Unlock() // With that taken care of, we'll send this channel to // the chain arb so it can react to on-chain events. return server.chainArb.WatchNewChannel(channel) }, ReportShortChanID: func(chanPoint wire.OutPoint) error { cid := lnwire.NewChanIDFromOutPoint(&chanPoint) return server.htlcSwitch.UpdateShortChanID(cid) }, RequiredRemoteChanReserve: func(chanAmt, dustLimit btcutil.Amount) btcutil.Amount { // By default, we'll require the remote peer to maintain // at least 1% of the total channel capacity at all // times. If this value ends up dipping below the dust // limit, then we'll use the dust limit itself as the // reserve as required by BOLT #2. reserve := chanAmt / 100 if reserve < dustLimit { reserve = dustLimit } return reserve }, RequiredRemoteMaxValue: func(chanAmt btcutil.Amount) lnwire.MilliSatoshi { // By default, we'll allow the remote peer to fully // utilize the full bandwidth of the channel, minus our // required reserve. reserve := lnwire.NewMSatFromSatoshis(chanAmt / 100) return lnwire.NewMSatFromSatoshis(chanAmt) - reserve }, RequiredRemoteMaxHTLCs: func(chanAmt btcutil.Amount) uint16 { // By default, we'll permit them to utilize the full // channel bandwidth. return uint16(lnwallet.MaxHTLCNumber / 2) }, ZombieSweeperInterval: 1 * time.Minute, ReservationTimeout: 10 * time.Minute, MinChanSize: btcutil.Amount(cfg.MinChanSize), }) if err != nil { return err } if err := fundingMgr.Start(); err != nil { return err } server.fundingMgr = fundingMgr // Check macaroon authentication if macaroons aren't disabled. if macaroonService != nil { serverOpts = append(serverOpts, grpc.UnaryInterceptor(macaroonService. UnaryServerInterceptor(permissions)), grpc.StreamInterceptor(macaroonService. StreamServerInterceptor(permissions)), ) } // Initialize, and register our implementation of the gRPC interface // exported by the rpcServer. rpcServer := newRPCServer(server) if err := rpcServer.Start(); err != nil { return err } grpcServer := grpc.NewServer(serverOpts...) lnrpc.RegisterLightningServer(grpcServer, rpcServer) // Next, Start the gRPC server listening for HTTP/2 connections. for _, listener := range cfg.RPCListeners { lis, err := net.Listen("tcp", listener) if err != nil { ltndLog.Errorf("RPC server unable to listen on %s", listener) return err } defer lis.Close() go func() { rpcsLog.Infof("RPC server listening on %s", lis.Addr()) grpcServer.Serve(lis) }() } // Finally, start the REST proxy for our gRPC server above. mux := proxy.NewServeMux() err = lnrpc.RegisterLightningHandlerFromEndpoint(ctx, mux, cfg.RPCListeners[0], proxyOpts) if err != nil { return err } for _, restEndpoint := range cfg.RESTListeners { listener, err := tls.Listen("tcp", restEndpoint, tlsConf) if err != nil { ltndLog.Errorf("gRPC proxy unable to listen on %s", restEndpoint) return err } defer listener.Close() go func() { rpcsLog.Infof("gRPC proxy started at %s", listener.Addr()) http.Serve(listener, mux) }() } // If we're not in simnet mode, We'll wait until we're fully synced to // continue the start up of the remainder of the daemon. This ensures // that we don't accept any possibly invalid state transitions, or // accept channels with spent funds. if !(cfg.Bitcoin.SimNet || cfg.Litecoin.SimNet) { _, bestHeight, err := activeChainControl.chainIO.GetBestBlock() if err != nil { return err } ltndLog.Infof("Waiting for chain backend to finish sync, "+ "start_height=%v", bestHeight) for { synced, _, err := activeChainControl.wallet.IsSynced() if err != nil { return err } if synced { break } time.Sleep(time.Second * 1) } _, bestHeight, err = activeChainControl.chainIO.GetBestBlock() if err != nil { return err } ltndLog.Infof("Chain backend is fully synced (end_height=%v)!", bestHeight) } // With all the relevant chains initialized, we can finally start the // server itself. if err := server.Start(); err != nil { srvrLog.Errorf("unable to start server: %v\n", err) return err } // Now that the server has started, if the autopilot mode is currently // active, then we'll initialize a fresh instance of it and start it. var pilot *autopilot.Agent if cfg.Autopilot.Active { pilot, err := initAutoPilot(server, cfg.Autopilot) if err != nil { ltndLog.Errorf("unable to create autopilot agent: %v", err) return err } if err := pilot.Start(); err != nil { ltndLog.Errorf("unable to start autopilot agent: %v", err) return err } } addInterruptHandler(func() { ltndLog.Infof("Gracefully shutting down the server...") rpcServer.Stop() fundingMgr.Stop() server.Stop() if pilot != nil { pilot.Stop() } server.WaitForShutdown() }) // Wait for shutdown signal from either a graceful server stop or from // the interrupt handler. <-shutdownChannel ltndLog.Info("Shutdown complete") return nil } func main() { // Call the "real" main in a nested manner so the defers will properly // be executed in the case of a graceful shutdown. if err := lndMain(); err != nil { if e, ok := err.(*flags.Error); ok && e.Type == flags.ErrHelp { } else { fmt.Fprintln(os.Stderr, err) } os.Exit(1) } } // fileExists reports whether the named file or directory exists. // This function is taken from https://github.com/btcsuite/btcd func fileExists(name string) bool { if _, err := os.Stat(name); err != nil { if os.IsNotExist(err) { return false } } return true } // genCertPair generates a key/cert pair to the paths provided. The // auto-generated certificates should *not* be used in production for public // access as they're self-signed and don't necessarily contain all of the // desired hostnames for the service. For production/public use, consider a // real PKI. // // This function is adapted from https://github.com/btcsuite/btcd and // https://github.com/btcsuite/btcutil func genCertPair(certFile, keyFile string) error { rpcsLog.Infof("Generating TLS certificates...") org := "lnd autogenerated cert" now := time.Now() validUntil := now.Add(autogenCertValidity) // Check that the certificate validity isn't past the ASN.1 end of time. if validUntil.After(endOfTime) { validUntil = endOfTime } // Generate a serial number that's below the serialNumberLimit. serialNumber, err := rand.Int(rand.Reader, serialNumberLimit) if err != nil { return fmt.Errorf("failed to generate serial number: %s", err) } // Collect the host's IP addresses, including loopback, in a slice. ipAddresses := []net.IP{net.ParseIP("127.0.0.1"), net.ParseIP("::1")} // addIP appends an IP address only if it isn't already in the slice. addIP := func(ipAddr net.IP) { for _, ip := range ipAddresses { if bytes.Equal(ip, ipAddr) { return } } ipAddresses = append(ipAddresses, ipAddr) } // Add all the interface IPs that aren't already in the slice. addrs, err := net.InterfaceAddrs() if err != nil { return err } for _, a := range addrs { ipAddr, _, err := net.ParseCIDR(a.String()) if err == nil { addIP(ipAddr) } } // Add extra IP to the slice. ipAddr := net.ParseIP(cfg.TLSExtraIP) if ipAddr != nil { addIP(ipAddr) } // Collect the host's names into a slice. host, err := os.Hostname() if err != nil { return err } dnsNames := []string{host} if host != "localhost" { dnsNames = append(dnsNames, "localhost") } if cfg.TLSExtraDomain != "" { dnsNames = append(dnsNames, cfg.TLSExtraDomain) } // Generate a private key for the certificate. priv, err := ecdsa.GenerateKey(elliptic.P256(), rand.Reader) if err != nil { return err } // Construct the certificate template. template := x509.Certificate{ SerialNumber: serialNumber, Subject: pkix.Name{ Organization: []string{org}, CommonName: host, }, NotBefore: now.Add(-time.Hour * 24), NotAfter: validUntil, KeyUsage: x509.KeyUsageKeyEncipherment | x509.KeyUsageDigitalSignature | x509.KeyUsageCertSign, IsCA: true, // so can sign self. BasicConstraintsValid: true, DNSNames: dnsNames, IPAddresses: ipAddresses, } derBytes, err := x509.CreateCertificate(rand.Reader, &template, &template, &priv.PublicKey, priv) if err != nil { return fmt.Errorf("failed to create certificate: %v", err) } certBuf := &bytes.Buffer{} err = pem.Encode(certBuf, &pem.Block{Type: "CERTIFICATE", Bytes: derBytes}) if err != nil { return fmt.Errorf("failed to encode certificate: %v", err) } keybytes, err := x509.MarshalECPrivateKey(priv) if err != nil { return fmt.Errorf("unable to encode privkey: %v", err) } keyBuf := &bytes.Buffer{} err = pem.Encode(keyBuf, &pem.Block{Type: "EC PRIVATE KEY", Bytes: keybytes}) if err != nil { return fmt.Errorf("failed to encode private key: %v", err) } // Write cert and key files. if err = ioutil.WriteFile(certFile, certBuf.Bytes(), 0644); err != nil { return err } if err = ioutil.WriteFile(keyFile, keyBuf.Bytes(), 0600); err != nil { os.Remove(certFile) return err } rpcsLog.Infof("Done generating TLS certificates") return nil } // genMacaroons generates three macaroon files; one admin-level, one // for invoice access and one read-only. These can also be used // to generate more granular macaroons. func genMacaroons(ctx context.Context, svc *macaroons.Service, admFile, roFile, invoiceFile string) error { // First, we'll generate a macaroon that only allows the caller to // access invoice related calls. This is useful for merchants and other // services to allow an isolated instance that can only query and // modify invoices. invoiceMac, err := svc.Oven.NewMacaroon( ctx, bakery.LatestVersion, nil, invoicePermissions..., ) if err != nil { return err } invoiceMacBytes, err := invoiceMac.M().MarshalBinary() if err != nil { return err } err = ioutil.WriteFile(invoiceFile, invoiceMacBytes, 0644) if err != nil { os.Remove(invoiceFile) return err } // Generate the read-only macaroon and write it to a file. roMacaroon, err := svc.Oven.NewMacaroon( ctx, bakery.LatestVersion, nil, readPermissions..., ) if err != nil { return err } roBytes, err := roMacaroon.M().MarshalBinary() if err != nil { return err } if err = ioutil.WriteFile(roFile, roBytes, 0644); err != nil { os.Remove(admFile) return err } // Generate the admin macaroon and write it to a file. adminPermissions := append(readPermissions, writePermissions...) admMacaroon, err := svc.Oven.NewMacaroon( ctx, bakery.LatestVersion, nil, adminPermissions..., ) if err != nil { return err } admBytes, err := admMacaroon.M().MarshalBinary() if err != nil { return err } if err = ioutil.WriteFile(admFile, admBytes, 0600); err != nil { return err } return nil } // WalletUnlockParams holds the variables used to parameterize the unlocking of // lnd's wallet after it has already been created. type WalletUnlockParams struct { // Password is the public and private wallet passphrase. Password []byte // Birthday specifies the approximate time that this wallet was created. // This is used to bound any rescans on startup. Birthday time.Time // RecoveryWindow specifies the address lookahead when entering recovery // mode. A recovery will be attempted if this value is non-zero. RecoveryWindow uint32 } // waitForWalletPassword will spin up gRPC and REST endpoints for the // WalletUnlocker server, and block until a password is provided by // the user to this RPC server. func waitForWalletPassword( grpcEndpoints, restEndpoints []string, serverOpts []grpc.ServerOption, proxyOpts []grpc.DialOption, tlsConf *tls.Config, macaroonService *macaroons.Service) (*WalletUnlockParams, error) { // Set up a new PasswordService, which will listen // for passwords provided over RPC. grpcServer := grpc.NewServer(serverOpts...) chainConfig := cfg.Bitcoin if registeredChains.PrimaryChain() == litecoinChain { chainConfig = cfg.Litecoin } pwService := walletunlocker.New(macaroonService, chainConfig.ChainDir, activeNetParams.Params) lnrpc.RegisterWalletUnlockerServer(grpcServer, pwService) // Use a WaitGroup so we can be sure the instructions on how to input the // password is the last thing to be printed to the console. var wg sync.WaitGroup for _, grpcEndpoint := range grpcEndpoints { // Start a gRPC server listening for HTTP/2 connections, solely // used for getting the encryption password from the client. lis, err := net.Listen("tcp", grpcEndpoint) if err != nil { ltndLog.Errorf("password RPC server unable to listen on %s", grpcEndpoint) return nil, err } defer lis.Close() wg.Add(1) go func() { rpcsLog.Infof("password RPC server listening on %s", lis.Addr()) wg.Done() grpcServer.Serve(lis) }() } // Start a REST proxy for our gRPC server above. ctx := context.Background() ctx, cancel := context.WithCancel(ctx) defer cancel() mux := proxy.NewServeMux() err := lnrpc.RegisterWalletUnlockerHandlerFromEndpoint(ctx, mux, grpcEndpoints[0], proxyOpts) if err != nil { return nil, err } srv := &http.Server{Handler: mux} for _, restEndpoint := range restEndpoints { lis, err := tls.Listen("tcp", restEndpoint, tlsConf) if err != nil { ltndLog.Errorf("password gRPC proxy unable to listen on %s", restEndpoint) return nil, err } defer lis.Close() wg.Add(1) go func() { rpcsLog.Infof("password gRPC proxy started at %s", lis.Addr()) wg.Done() srv.Serve(lis) }() } // Wait for gRPC and REST servers to be up running. wg.Wait() // Wait for user to provide the password. ltndLog.Infof("Waiting for wallet encryption password. " + "Use `lncli create` to create wallet, or " + "`lncli unlock` to unlock already created wallet.") // We currently don't distinguish between getting a password to be used // for creation or unlocking, as a new wallet db will be created if // none exists when creating the chain control. select { // The wallet is being created for the first time, we'll check to see // if the user provided any entropy for seed creation. If so, then // we'll create the wallet early to load the seed. case initMsg := <-pwService.InitMsgs: password := initMsg.Passphrase cipherSeed := initMsg.WalletSeed recoveryWindow := initMsg.RecoveryWindow // Before we proceed, we'll check the internal version of the // seed. If it's greater than the current key derivation // version, then we'll return an error as we don't understand // this. if cipherSeed.InternalVersion != keychain.KeyDerivationVersion { return nil, fmt.Errorf("invalid internal seed version "+ "%v, current version is %v", cipherSeed.InternalVersion, keychain.KeyDerivationVersion) } netDir := btcwallet.NetworkDir( chainConfig.ChainDir, activeNetParams.Params, ) loader := wallet.NewLoader( activeNetParams.Params, netDir, uint32(recoveryWindow), ) // With the seed, we can now use the wallet loader to create // the wallet, then unload it so it can be opened shortly birthday := cipherSeed.BirthdayTime() _, err = loader.CreateNewWallet( password, password, cipherSeed.Entropy[:], birthday, ) if err != nil { return nil, err } if err := loader.UnloadWallet(); err != nil { return nil, err } walletInitParams := &WalletUnlockParams{ Password: password, Birthday: birthday, RecoveryWindow: recoveryWindow, } return walletInitParams, nil // The wallet has already been created in the past, and is simply being // unlocked. So we'll just return these passphrases. case unlockMsg := <-pwService.UnlockMsgs: walletInitParams := &WalletUnlockParams{ Password: unlockMsg.Passphrase, RecoveryWindow: unlockMsg.RecoveryWindow, } return walletInitParams, nil case <-shutdownChannel: return nil, fmt.Errorf("shutting down") } }