package main import ( "bytes" "encoding/hex" "encoding/json" "fmt" "io" "io/ioutil" "math" "os" "os/exec" "strconv" "strings" "github.com/awalterschulze/gographviz" "github.com/lightningnetwork/lnd/lnrpc" "github.com/roasbeef/btcd/chaincfg/chainhash" "github.com/roasbeef/btcutil" "github.com/urfave/cli" "golang.org/x/net/context" ) // TODO(roasbeef): cli logic for supporting both positional and unix style // arguments. func printRespJson(resp interface{}) { b, err := json.Marshal(resp) if err != nil { fatal(err) } // TODO(roasbeef): disable 'omitempty' like behavior var out bytes.Buffer json.Indent(&out, b, "", "\t") out.WriteTo(os.Stdout) } var NewAddressCommand = cli.Command{ Name: "newaddress", Usage: "generates a new address. Three address types are supported: p2wkh, np2wkh, p2pkh", Action: newAddress, } func newAddress(ctx *cli.Context) error { client, cleanUp := getClient(ctx) defer cleanUp() stringAddrType := ctx.Args().Get(0) // Map the string encoded address type, to the concrete typed address // type enum. An unrecognized address type will result in an error. var addrType lnrpc.NewAddressRequest_AddressType switch stringAddrType { // TODO(roasbeef): make them ints on the cli? case "p2wkh": addrType = lnrpc.NewAddressRequest_WITNESS_PUBKEY_HASH case "np2wkh": addrType = lnrpc.NewAddressRequest_NESTED_PUBKEY_HASH case "p2pkh": addrType = lnrpc.NewAddressRequest_PUBKEY_HASH default: return fmt.Errorf("invalid address type %v, support address type "+ "are: p2wkh, np2wkh, p2pkh", stringAddrType) } ctxb := context.Background() addr, err := client.NewAddress(ctxb, &lnrpc.NewAddressRequest{ Type: addrType, }) if err != nil { return err } printRespJson(addr) return nil } var SendCoinsCommand = cli.Command{ Name: "sendcoins", Description: "send a specified amount of bitcoin to the passed address", Usage: "sendcoins --addr= --amt=", Flags: []cli.Flag{ cli.StringFlag{ Name: "addr", Usage: "the bitcoin address to send coins to on-chain", }, // TODO(roasbeef): switch to BTC on command line? int may not be sufficient cli.IntFlag{ Name: "amt", Usage: "the number of bitcoin denominated in satoshis to send", }, }, Action: sendCoins, } func sendCoins(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.SendCoinsRequest{ Addr: ctx.String("addr"), Amount: int64(ctx.Int("amt")), } txid, err := client.SendCoins(ctxb, req) if err != nil { return err } printRespJson(txid) return nil } var SendManyCommand = cli.Command{ Name: "sendmany", Description: "create and broadcast a transaction paying the specified " + "amount(s) to the passed address(es)", Usage: `sendmany '{"ExampleAddr": NumCoinsInSatoshis, "SecondAddr": NumCoins}'`, Action: sendMany, } func sendMany(ctx *cli.Context) error { var amountToAddr map[string]int64 jsonMap := ctx.Args().Get(0) if err := json.Unmarshal([]byte(jsonMap), &amountToAddr); err != nil { return err } ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() txid, err := client.SendMany(ctxb, &lnrpc.SendManyRequest{amountToAddr}) if err != nil { return err } printRespJson(txid) return nil } var ConnectCommand = cli.Command{ Name: "connect", Usage: "connect to a remote lnd peer: @host (--perm=true|false])", Flags: []cli.Flag{ cli.BoolFlag{ Name: "perm", Usage: "If true, then the daemon will attempt to persistently " + "connect to the target peer. If false then the call " + "will be synchronous.", }, }, Action: connectPeer, } func connectPeer(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() targetAddress := ctx.Args().Get(0) splitAddr := strings.Split(targetAddress, "@") if len(splitAddr) != 2 { return fmt.Errorf("target address expected in format: " + "pubkey@host:port") } addr := &lnrpc.LightningAddress{ Pubkey: splitAddr[0], Host: splitAddr[1], } req := &lnrpc.ConnectPeerRequest{ Addr: addr, Perm: ctx.Bool("perm"), } lnid, err := client.ConnectPeer(ctxb, req) if err != nil { return err } printRespJson(lnid) return nil } // TODO(roasbeef): default number of confirmations var OpenChannelCommand = cli.Command{ Name: "openchannel", Description: "Attempt to open a new channel to an existing peer, " + "optionally blocking until the channel is 'open'. Once the " + "channel is open, a channelPoint (txid:vout) of the funding " + "output is returned. NOTE: peer_id and node_key are " + "mutually exclusive, only one should be used, not both.", Usage: "openchannel --node_key=X --local_amt=N --push_amt=N --num_confs=N", Flags: []cli.Flag{ cli.IntFlag{ Name: "peer_id", Usage: "the relative id of the peer to open a channel with", }, cli.StringFlag{ Name: "node_key", Usage: "the identity public key of the target peer " + "serialized in compressed format", }, cli.IntFlag{ Name: "local_amt", Usage: "the number of satoshis the wallet should commit to the channel", }, cli.IntFlag{ Name: "push_amt", Usage: "the number of satoshis to push to the remote " + "side as part of the initial commitment state", }, cli.IntFlag{ Name: "num_confs", Usage: "the number of confirmations required before the " + "channel is considered 'open'", }, cli.BoolFlag{ Name: "block", Usage: "block and wait until the channel is fully open", }, }, Action: openChannel, } func openChannel(ctx *cli.Context) error { // TODO(roasbeef): add deadline to context ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() if ctx.Int("peer_id") != 0 && ctx.String("node_key") != "" { return fmt.Errorf("both peer_id and lightning_id cannot be set " + "at the same time, only one can be specified") } req := &lnrpc.OpenChannelRequest{ LocalFundingAmount: int64(ctx.Int("local_amt")), PushSat: int64(ctx.Int("push_amt")), NumConfs: uint32(ctx.Int("num_confs")), } if ctx.Int("peer_id") != 0 { req.TargetPeerId = int32(ctx.Int("peer_id")) } else { nodePubHex, err := hex.DecodeString(ctx.String("node_key")) if err != nil { return fmt.Errorf("unable to decode lightning id: %v", err) } req.NodePubkey = nodePubHex } stream, err := client.OpenChannel(ctxb, req) if err != nil { return err } if !ctx.Bool("block") { return nil } for { resp, err := stream.Recv() if err == io.EOF { return nil } else if err != nil { return err } switch update := resp.Update.(type) { case *lnrpc.OpenStatusUpdate_ChanOpen: channelPoint := update.ChanOpen.ChannelPoint txid, err := chainhash.NewHash(channelPoint.FundingTxid) if err != nil { return err } index := channelPoint.OutputIndex printRespJson(struct { ChannelPoint string `json:"channel_point"` }{ ChannelPoint: fmt.Sprintf("%v:%v", txid, index), }, ) } } return nil } // TODO(roasbeef): also allow short relative channel ID. var CloseChannelCommand = cli.Command{ Name: "closechannel", Description: "Close an existing channel. The channel can be closed either " + "cooperatively, or uncooperatively (forced).", Usage: "closechannel funding_txid output_index time_limit allow_force", Flags: []cli.Flag{ cli.StringFlag{ Name: "funding_txid", Usage: "the txid of the channel's funding transaction", }, cli.IntFlag{ Name: "output_index", Usage: "the output index for the funding output of the funding " + "transaction", }, cli.StringFlag{ Name: "time_limit", Usage: "a relative deadline afterwhich the attempt should be " + "abandonded", }, cli.BoolFlag{ Name: "force", Usage: "after the time limit has passed, attempt an " + "uncooperative closure", }, cli.BoolFlag{ Name: "block", Usage: "block until the channel is closed", }, }, Action: closeChannel, } func closeChannel(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() txid, err := chainhash.NewHashFromStr(ctx.String("funding_txid")) if err != nil { return err } // TODO(roasbeef): implement time deadline within server req := &lnrpc.CloseChannelRequest{ ChannelPoint: &lnrpc.ChannelPoint{ FundingTxid: txid[:], OutputIndex: uint32(ctx.Int("output_index")), }, Force: ctx.Bool("force"), } stream, err := client.CloseChannel(ctxb, req) if err != nil { return err } if !ctx.Bool("block") { return nil } for { resp, err := stream.Recv() if err == io.EOF { return nil } else if err != nil { return err } switch update := resp.Update.(type) { case *lnrpc.CloseStatusUpdate_ChanClose: closingHash := update.ChanClose.ClosingTxid txid, err := chainhash.NewHash(closingHash) if err != nil { return err } printRespJson(struct { ClosingTXID string `json:"closing_txid"` }{ ClosingTXID: txid.String(), }) } } return nil } var ListPeersCommand = cli.Command{ Name: "listpeers", Description: "List all active, currently connected peers.", Action: listPeers, } func listPeers(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.ListPeersRequest{} resp, err := client.ListPeers(ctxb, req) if err != nil { return err } printRespJson(resp) return nil } var WalletBalanceCommand = cli.Command{ Name: "walletbalance", Description: "compute and display the wallet's current balance", Usage: "walletbalance --witness_only=[true|false]", Flags: []cli.Flag{ cli.BoolFlag{ Name: "witness_only", Usage: "if only witness outputs should be considered when " + "calculating the wallet's balance", }, }, Action: walletBalance, } func walletBalance(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.WalletBalanceRequest{ WitnessOnly: ctx.Bool("witness_only"), } resp, err := client.WalletBalance(ctxb, req) if err != nil { return err } printRespJson(resp) return nil } var ChannelBalanceCommand = cli.Command{ Name: "channelbalance", Description: "returns the sum of the total available channel balance across all open channels", Action: channelBalance, } func channelBalance(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.ChannelBalanceRequest{} resp, err := client.ChannelBalance(ctxb, req) if err != nil { return err } printRespJson(resp) return nil } var GetInfoCommand = cli.Command{ Name: "getinfo", Description: "returns basic information related to the active daemon", Action: getInfo, } func getInfo(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.GetInfoRequest{} resp, err := client.GetInfo(ctxb, req) if err != nil { return err } printRespJson(resp) return nil } var PendingChannelsCommand = cli.Command{ Name: "pendingchannels", Description: "display information pertaining to pending channels", Usage: "pendingchannels --status=[all|opening|closing]", Flags: []cli.Flag{ cli.BoolFlag{ Name: "open, o", Usage: "display the status of new pending channels", }, cli.BoolFlag{ Name: "close, c", Usage: "display the status of channels being closed", }, cli.BoolFlag{ Name: "all, a", Usage: "display the status of channels in the " + "process of being opened or closed", }, }, Action: pendingChannels, } func pendingChannels(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() var channelStatus lnrpc.ChannelStatus switch { case ctx.Bool("all"): channelStatus = lnrpc.ChannelStatus_ALL case ctx.Bool("open"): channelStatus = lnrpc.ChannelStatus_OPENING case ctx.Bool("close"): channelStatus = lnrpc.ChannelStatus_CLOSING default: channelStatus = lnrpc.ChannelStatus_ALL } req := &lnrpc.PendingChannelRequest{channelStatus} resp, err := client.PendingChannels(ctxb, req) if err != nil { return err } printRespJson(resp) return nil } var ListChannelsCommand = cli.Command{ Name: "listchannels", Description: "list all open channels", Usage: "listchannels --active_only", Flags: []cli.Flag{ cli.BoolFlag{ Name: "active_only, a", Usage: "only list channels which are currently active", }, }, Action: listChannels, } func listChannels(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.ListChannelsRequest{} resp, err := client.ListChannels(ctxb, req) if err != nil { return err } // TODO(roasbeef): defer close the client for the all printRespJson(resp) return nil } var SendPaymentCommand = cli.Command{ Name: "sendpayment", Description: "send a payment over lightning", Usage: "sendpayment --dest=[node_key] --amt=[in_satoshis] --payment_hash=[hash] --debug_send=[true|false]", Flags: []cli.Flag{ cli.StringFlag{ Name: "dest, d", Usage: "the compressed identity pubkey of the " + "payment recipient", }, cli.IntFlag{ // TODO(roasbeef): float64? Name: "amt, a", Usage: "number of satoshis to send", }, cli.StringFlag{ Name: "payment_hash, r", Usage: "the hash to use within the payment's HTLC", }, cli.BoolFlag{ Name: "debug_send", Usage: "use the debug rHash when sending the HTLC", }, cli.StringFlag{ Name: "pay_req", Usage: "a zbase32-check encoded payment request to fulfill", }, }, Action: sendPaymentCommand, } func sendPaymentCommand(ctx *cli.Context) error { client, cleanUp := getClient(ctx) defer cleanUp() var req *lnrpc.SendRequest if ctx.String("pay_req") != "" { req = &lnrpc.SendRequest{ PaymentRequest: ctx.String("pay_req"), } } else { destNode, err := hex.DecodeString(ctx.String("dest")) if err != nil { return err } if len(destNode) != 33 { return fmt.Errorf("dest node pubkey must be exactly 33 bytes, is "+ "instead: %v", len(destNode)) } req = &lnrpc.SendRequest{ Dest: destNode, Amt: int64(ctx.Int("amt")), } if !ctx.Bool("debug_send") { rHash, err := hex.DecodeString(ctx.String("payment_hash")) if err != nil { return err } if len(rHash) != 32 { return fmt.Errorf("payment hash must be exactly 32 "+ "bytes, is instead %v", len(rHash)) } req.PaymentHash = rHash } } paymentStream, err := client.SendPayment(context.Background()) if err != nil { return err } if err := paymentStream.Send(req); err != nil { return err } resp, err := paymentStream.Recv() if err != nil { return err } paymentStream.CloseSend() printRespJson(resp) return nil } var AddInvoiceCommand = cli.Command{ Name: "addinvoice", Description: "add a new invoice, expressing intent for a future payment", Usage: "addinvoice --memo=[note] --receipt=[sig+contract hash] --value=[in_satoshis] --preimage=[32_byte_hash]", Flags: []cli.Flag{ cli.StringFlag{ Name: "memo", Usage: "an optional memo to attach along with the invoice", }, cli.StringFlag{ Name: "receipt", Usage: "an optional cryptographic receipt of payment", }, cli.StringFlag{ Name: "preimage", Usage: "the hex-encoded preimage which will allow settling an incoming HTLC payable to this preimage", }, cli.IntFlag{ Name: "value", Usage: "the value of this invoice in satoshis", }, }, Action: addInvoice, } func addInvoice(ctx *cli.Context) error { client, cleanUp := getClient(ctx) defer cleanUp() preimage, err := hex.DecodeString(ctx.String("preimage")) if err != nil { return fmt.Errorf("unable to parse preimage: %v", err) } receipt, err := hex.DecodeString(ctx.String("receipt")) if err != nil { return fmt.Errorf("unable to parse receipt: %v", err) } invoice := &lnrpc.Invoice{ Memo: ctx.String("memo"), Receipt: receipt, RPreimage: preimage, Value: int64(ctx.Int("value")), } resp, err := client.AddInvoice(context.Background(), invoice) if err != nil { return err } printRespJson(struct { RHash string `json:"r_hash"` PayReq string `json:"pay_req"` }{ RHash: hex.EncodeToString(resp.RHash), PayReq: resp.PaymentRequest, }) return nil } var LookupInvoiceCommand = cli.Command{ Name: "lookupinvoice", Description: "lookup an existing invoice by its payment hash", Usage: "lookupinvoice --rhash=[32_byte_hash]", Flags: []cli.Flag{ cli.StringFlag{ Name: "rhash", Usage: "the payment hash of the invoice to query for, the hash " + "should be a hex-encoded string", }, }, Action: lookupInvoice, } func lookupInvoice(ctx *cli.Context) error { client, cleanUp := getClient(ctx) defer cleanUp() rHash, err := hex.DecodeString(ctx.String("rhash")) if err != nil { return err } req := &lnrpc.PaymentHash{ RHash: rHash, } invoice, err := client.LookupInvoice(context.Background(), req) if err != nil { return err } printRespJson(invoice) return nil } var ListInvoicesCommand = cli.Command{ Name: "listinvoices", Usage: "listinvoice --pending_only=[true|false]", Description: "list all invoices currently stored", Flags: []cli.Flag{ cli.BoolFlag{ Name: "pending_only", Usage: "toggles if all invoices should be returned, or only " + "those that are currently unsettled", }, }, Action: listInvoices, } func listInvoices(ctx *cli.Context) error { client, cleanUp := getClient(ctx) defer cleanUp() pendingOnly := true if !ctx.Bool("pending_only") { pendingOnly = false } req := &lnrpc.ListInvoiceRequest{ PendingOnly: pendingOnly, } invoices, err := client.ListInvoices(context.Background(), req) if err != nil { return err } printRespJson(invoices) return nil } var DescribeGraphCommand = cli.Command{ Name: "describegraph", Description: "prints a human readable version of the known channel " + "graph from the PoV of the node", Usage: "describegraph", Flags: []cli.Flag{ cli.BoolFlag{ Name: "draw", Usage: "If true, then an image of graph will be generated and displayed. The generated image is stored within the current directory with a file name of 'graph.svg'", }, }, Action: describeGraph, } func describeGraph(ctx *cli.Context) error { client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.ChannelGraphRequest{} graph, err := client.DescribeGraph(context.Background(), req) if err != nil { return err } // If the draw flag is on, then we'll use the 'dot' command to create a // visualization of the graph itself. if ctx.Bool("draw") { return drawChannelGraph(graph) } printRespJson(graph) return nil } // normalizeFunc is a factory function which returns a function that normalizes // the capacity of of edges within the graph. The value of the returned // function can be used to either plot the capacities, or to use a weight in a // rendering of the graph. func normalizeFunc(edges []*lnrpc.ChannelEdge, scaleFactor float64) func(int64) float64 { var ( min float64 = math.MaxInt64 max float64 ) for _, edge := range edges { // In order to obtain saner values, we reduce the capacity of a // channel to it's base 2 logarithm. z := math.Log2(float64(edge.Capacity)) if z < min { min = z } if z > max { max = z } } return func(x int64) float64 { y := math.Log2(float64(x)) // TODO(roasbeef): results in min being zero return float64(y-min) / float64(max-min) * scaleFactor } } func drawChannelGraph(graph *lnrpc.ChannelGraph) error { // First we'll create a temporary file that we'll write the compiled // string that describes our graph in the dot format to. tempDotFile, err := ioutil.TempFile("", "") if err != nil { return err } defer os.Remove(tempDotFile.Name()) // Next, we'll create (or re-create) the file that the final graph // image will be written to. imageFile, err := os.Create("graph.svg") if err != nil { return err } // With our temporary files set up, we'll initialize the graphviz // object that we'll use to draw our graph. graphName := "LightningNetwork" graphCanvas := gographviz.NewGraph() graphCanvas.SetName(graphName) graphCanvas.SetDir(false) const numKeyChars = 10 truncateStr := func(k string, n uint) string { return k[:n] } // For each node within the graph, we'll add a new vertex to the graph. for _, node := range graph.Nodes { // Rather than using the entire hex-encoded string, we'll only // use the first 10 characters. We also add a prefix of "Z" as // graphviz is unable to parse the compressed pubkey as a // non-integer. // // TODO(roasbeef): should be able to get around this? nodeID := fmt.Sprintf(`"%v"`, truncateStr(node.PubKey, numKeyChars)) graphCanvas.AddNode(graphName, nodeID, gographviz.Attrs{}) } normalize := normalizeFunc(graph.Edges, 3) // Similarly, for each edge we'll add an edge between the corresponding // nodes added to the graph above. for _, edge := range graph.Edges { // Once again, we add a 'Z' prefix so we're compliant with the // dot grammar. src := fmt.Sprintf(`"%v"`, truncateStr(edge.Node1Pub, numKeyChars)) dest := fmt.Sprintf(`"%v"`, truncateStr(edge.Node2Pub, numKeyChars)) // The weight for our edge will be the total capacity of the // channel, in BTC. // TODO(roasbeef): can also factor in the edges time-lock delta // and fee information amt := btcutil.Amount(edge.Capacity).ToBTC() edgeWeight := strconv.FormatFloat(amt, 'f', -1, 64) // The label for each edge will simply be a truncated version // of it's channel ID. chanIDStr := strconv.FormatUint(edge.ChannelId, 10) edgeLabel := fmt.Sprintf(`"cid:%v"`, truncateStr(chanIDStr, 7)) // We'll also use a normalized version of the channels' // capacity in satoshis in order to modulate the "thickness" of // the line that creates the edge within the graph. normalizedCapacity := normalize(edge.Capacity) edgeThickness := strconv.FormatFloat(normalizedCapacity, 'f', -1, 64) // TODO(roasbeef): color code based on percentile capacity graphCanvas.AddEdge(src, dest, false, gographviz.Attrs{ "penwidth": edgeThickness, "weight": edgeWeight, "label": edgeLabel, }) } // With the declarative generation of the graph complete, we now write // the dot-string description of the graph graphDotString := graphCanvas.String() if _, err := tempDotFile.WriteString(graphDotString); err != nil { return err } if err := tempDotFile.Sync(); err != nil { return err } var errBuffer bytes.Buffer // Once our dot file has been written to disk, we can use the dot // command itself to generate the drawn rendering of the graph // described. drawCmd := exec.Command("dot", "-T"+"svg", "-o"+imageFile.Name(), tempDotFile.Name()) drawCmd.Stderr = &errBuffer if err := drawCmd.Run(); err != nil { fmt.Println("error rendering graph: ", errBuffer.String()) fmt.Println("dot: ", graphDotString) return err } errBuffer.Reset() // Finally, we'll open the drawn graph to display to the user. openCmd := exec.Command("open", imageFile.Name()) openCmd.Stderr = &errBuffer if err := openCmd.Run(); err != nil { fmt.Println("error opening rendered graph image: ", errBuffer.String()) return err } return nil } var ListPaymentsCommand = cli.Command{ Name: "listpayments", Usage: "listpayments", Description: "list all outgoing payments", Action: listPayments, } func listPayments(ctx *cli.Context) error { client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.ListPaymentsRequest{} payments, err := client.ListPayments(context.Background(), req) if err != nil { return err } printRespJson(payments) return nil } var GetChanInfoCommand = cli.Command{ Name: "getchaninfo", Usage: "getchaninfo --chand_id=[8_byte_channel_id]", Description: "prints out the latest authenticated state for a " + "particular channel", Flags: []cli.Flag{ cli.IntFlag{ Name: "chan_id", Usage: "the 8-byte compact channel ID to query for", }, }, Action: getChanInfo, } func getChanInfo(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.ChanInfoRequest{ ChanId: uint64(ctx.Int("chan_id")), } chanInfo, err := client.GetChanInfo(ctxb, req) if err != nil { return err } printRespJson(chanInfo) return nil } var GetNodeInfoCommand = cli.Command{ Name: "getnodeinfo", Usage: "getnodeinfo --pub_key=[33_byte_serialized_pub_lky]", Description: "prints out the latest authenticated node state for an " + "advertised node", Flags: []cli.Flag{ cli.StringFlag{ Name: "pub_key", Usage: "the 33-byte hex-encoded compressed public of the target " + "node", }, }, Action: getNodeInfo, } func getNodeInfo(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.NodeInfoRequest{ PubKey: ctx.String("pub_key"), } nodeInfo, err := client.GetNodeInfo(ctxb, req) if err != nil { return err } printRespJson(nodeInfo) return nil } var QueryRouteCommand = cli.Command{ Name: "queryroute", Usage: "queryroute --dest=[dest_pub_key] --amt=[amt_to_send_in_satoshis]", Description: "queries the channel router for a potential path to the destination that has sufficient flow for the amount including fees", Flags: []cli.Flag{ cli.StringFlag{ Name: "dest", Usage: "the 33-byte hex-encoded public key for the payment " + "destination", }, cli.IntFlag{ Name: "amt", Usage: "the amount to send expressed in satoshis", }, }, Action: queryRoute, } func queryRoute(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.RouteRequest{ PubKey: ctx.String("dest"), Amt: int64(ctx.Int("amt")), } route, err := client.QueryRoute(ctxb, req) if err != nil { return err } printRespJson(route) return nil } var GetNetworkInfoCommand = cli.Command{ Name: "getnetworkinfo", Usage: "getnetworkinfo", Description: "returns a set of statistics pertaining to the known channel " + "graph", Action: getNetworkInfo, } func getNetworkInfo(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.NetworkInfoRequest{} netInfo, err := client.GetNetworkInfo(ctxb, req) if err != nil { return err } printRespJson(netInfo) return nil } var DebugLevel = cli.Command{ Name: "debuglevel", Usage: "debuglevel [--show|--level=]", Description: "Logging level for all subsystems {trace, debug, info, warn, error, critical} -- You may also specify =,=,... to set the log level for individual subsystems -- Use show to list available subsystems", Flags: []cli.Flag{ cli.BoolFlag{ Name: "show", Usage: "if true, then the list of available sub-systems will be printed out", }, cli.StringFlag{ Name: "level", Usage: "the level specification to target either a coarse logging level, or granular set of specific sub-systems with loggin levels for each", }, }, Action: debugLevel, } func debugLevel(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.DebugLevelRequest{ Show: ctx.Bool("show"), LevelSpec: ctx.String("level"), } resp, err := client.DebugLevel(ctxb, req) if err != nil { return err } printRespJson(resp) return nil } var DecodePayReq = cli.Command{ Name: "decodepayreq", Usage: "decodepayreq --pay_req=[encoded_pay_req]", Description: "Decode the passed payment request revealing the destination, payment hash and value of the payment request", Flags: []cli.Flag{ cli.StringFlag{ Name: "pay_req", Usage: "the zpay32 encoded payment request", }, }, Action: decodePayReq, } func decodePayReq(ctx *cli.Context) error { ctxb := context.Background() client, cleanUp := getClient(ctx) defer cleanUp() req := &lnrpc.PayReqString{ PayReq: ctx.String("pay_req"), } resp, err := client.DecodePayReq(ctxb, req) if err != nil { return err } printRespJson(resp) return nil }