[ldk-sample] / src / main.rs

pub mod bitcoind_client;
mod cli;
mod convert;
mod disk;
mod hex_utils;

use crate::bitcoind_client::BitcoindClient;
use crate::disk::FilesystemLogger;
use bitcoin::blockdata::constants::genesis_block;
use bitcoin::blockdata::transaction::Transaction;
use bitcoin::consensus::encode;
use bitcoin::hashes::sha256::Hash as Sha256;
use bitcoin::hashes::Hash;
use bitcoin::network::constants::Network;
use bitcoin::secp256k1::Secp256k1;
use bitcoin::BlockHash;
use bitcoin_bech32::WitnessProgram;
use lightning::chain;
use lightning::chain::chaininterface::{BroadcasterInterface, ConfirmationTarget, FeeEstimator};
use lightning::chain::chainmonitor;
use lightning::chain::keysinterface::{InMemorySigner, KeysInterface, KeysManager};
use lightning::chain::{BestBlock, Filter, Watch};
use lightning::ln::channelmanager;
use lightning::ln::channelmanager::{
        ChainParameters, ChannelManagerReadArgs, SimpleArcChannelManager,
};
use lightning::ln::peer_handler::{MessageHandler, SimpleArcPeerManager};
use lightning::ln::{PaymentHash, PaymentPreimage, PaymentSecret};
use lightning::routing::network_graph::NetGraphMsgHandler;
use lightning::util::config::UserConfig;
use lightning::util::events::{Event, PaymentPurpose};
use lightning::util::ser::ReadableArgs;
use lightning_background_processor::BackgroundProcessor;
use lightning_block_sync::init;
use lightning_block_sync::poll;
use lightning_block_sync::SpvClient;
use lightning_block_sync::UnboundedCache;
use lightning_net_tokio::SocketDescriptor;
use lightning_persister::FilesystemPersister;
use rand::{thread_rng, Rng};
use std::collections::hash_map::Entry;
use std::collections::HashMap;
use std::fmt;
use std::fs;
use std::fs::File;
use std::io;
use std::io::Write;
use std::ops::Deref;
use std::path::Path;
use std::sync::{Arc, Mutex};
use std::time::{Duration, SystemTime};

pub(crate) enum HTLCStatus {
        Pending,
        Succeeded,
        Failed,
}

pub(crate) struct MillisatAmount(Option<u64>);

impl fmt::Display for MillisatAmount {
        fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
                match self.0 {
                        Some(amt) => write!(f, "{}", amt),
                        None => write!(f, "unknown"),
                }
        }
}

pub(crate) struct PaymentInfo {
        preimage: Option<PaymentPreimage>,
        secret: Option<PaymentSecret>,
        status: HTLCStatus,
        amt_msat: MillisatAmount,
}

pub(crate) type PaymentInfoStorage = Arc<Mutex<HashMap<PaymentHash, PaymentInfo>>>;

type ChainMonitor = chainmonitor::ChainMonitor<
        InMemorySigner,
        Arc<dyn Filter + Send + Sync>,
        Arc<BitcoindClient>,
        Arc<BitcoindClient>,
        Arc<FilesystemLogger>,
        Arc<FilesystemPersister>,
>;

pub(crate) type PeerManager = SimpleArcPeerManager<
        SocketDescriptor,
        ChainMonitor,
        BitcoindClient,
        BitcoindClient,
        dyn chain::Access + Send + Sync,
        FilesystemLogger,
>;

pub(crate) type ChannelManager =
        SimpleArcChannelManager<ChainMonitor, BitcoindClient, BitcoindClient, FilesystemLogger>;

async fn handle_ldk_events(
        channel_manager: Arc<ChannelManager>, bitcoind_client: Arc<BitcoindClient>,
        keys_manager: Arc<KeysManager>, inbound_payments: PaymentInfoStorage,
        outbound_payments: PaymentInfoStorage, network: Network, event: Event,
) {
        match event {
                Event::FundingGenerationReady {
                        temporary_channel_id,
                        channel_value_satoshis,
                        output_script,
                        ..
                } => {
                        // Construct the raw transaction with one output, that is paid the amount of the
                        // channel.
                        let addr = WitnessProgram::from_scriptpubkey(
                                &output_script[..],
                                match network {
                                        Network::Bitcoin => bitcoin_bech32::constants::Network::Bitcoin,
                                        Network::Testnet => bitcoin_bech32::constants::Network::Testnet,
                                        Network::Regtest => bitcoin_bech32::constants::Network::Regtest,
                                        Network::Signet => panic!("Signet unsupported"),
                                },
                        )
                        .expect("Lightning funding tx should always be to a SegWit output")
                        .to_address();
                        let mut outputs = vec![HashMap::with_capacity(1)];
                        outputs[0].insert(addr, channel_value_satoshis as f64 / 100_000_000.0);
                        let raw_tx = bitcoind_client.create_raw_transaction(outputs).await;

                        // Have your wallet put the inputs into the transaction such that the output is
                        // satisfied.
                        let funded_tx = bitcoind_client.fund_raw_transaction(raw_tx).await;

                        // Sign the final funding transaction and broadcast it.
                        let signed_tx = bitcoind_client.sign_raw_transaction_with_wallet(funded_tx.hex).await;
                        assert_eq!(signed_tx.complete, true);
                        let final_tx: Transaction =
                                encode::deserialize(&hex_utils::to_vec(&signed_tx.hex).unwrap()).unwrap();
                        // Give the funding transaction back to LDK for opening the channel.
                        if channel_manager
                                .funding_transaction_generated(&temporary_channel_id, final_tx)
                                .is_err()
                        {
                                println!(
                                        "\nERROR: Channel went away before we could fund it. The peer disconnected or refused the channel.");
                                print!("> ");
                                io::stdout().flush().unwrap();
                        }
                }
                Event::PaymentReceived { payment_hash, purpose, amt, .. } => {
                        let mut payments = inbound_payments.lock().unwrap();
                        let (payment_preimage, payment_secret) = match purpose {
                                PaymentPurpose::InvoicePayment { payment_preimage, payment_secret, .. } => {
                                        (payment_preimage, Some(payment_secret))
                                }
                                PaymentPurpose::SpontaneousPayment(preimage) => (Some(preimage), None),
                        };
                        let status = match channel_manager.claim_funds(payment_preimage.unwrap()) {
                                true => {
                                        println!(
                                                "\nEVENT: received payment from payment hash {} of {} millisatoshis",
                                                hex_utils::hex_str(&payment_hash.0),
                                                amt
                                        );
                                        print!("> ");
                                        io::stdout().flush().unwrap();
                                        HTLCStatus::Succeeded
                                }
                                _ => HTLCStatus::Failed,
                        };
                        match payments.entry(payment_hash) {
                                Entry::Occupied(mut e) => {
                                        let payment = e.get_mut();
                                        payment.status = status;
                                        payment.preimage = payment_preimage;
                                        payment.secret = payment_secret;
                                }
                                Entry::Vacant(e) => {
                                        e.insert(PaymentInfo {
                                                preimage: payment_preimage,
                                                secret: payment_secret,
                                                status,
                                                amt_msat: MillisatAmount(Some(amt)),
                                        });
                                }
                        }
                }
                Event::PaymentSent { payment_preimage } => {
                        let hashed = PaymentHash(Sha256::hash(&payment_preimage.0).into_inner());
                        let mut payments = outbound_payments.lock().unwrap();
                        for (payment_hash, payment) in payments.iter_mut() {
                                if *payment_hash == hashed {
                                        payment.preimage = Some(payment_preimage);
                                        payment.status = HTLCStatus::Succeeded;
                                        println!(
                                                "\nEVENT: successfully sent payment of {} millisatoshis from \
                                                                 payment hash {:?} with preimage {:?}",
                                                payment.amt_msat,
                                                hex_utils::hex_str(&payment_hash.0),
                                                hex_utils::hex_str(&payment_preimage.0)
                                        );
                                        print!("> ");
                                        io::stdout().flush().unwrap();
                                }
                        }
                }
                Event::PaymentFailed { payment_hash, rejected_by_dest } => {
                        print!(
                                "\nEVENT: Failed to send payment to payment hash {:?}: ",
                                hex_utils::hex_str(&payment_hash.0)
                        );
                        if rejected_by_dest {
                                println!("re-attempting the payment will not succeed");
                        } else {
                                println!("payment may be retried");
                        }
                        print!("> ");
                        io::stdout().flush().unwrap();

                        let mut payments = outbound_payments.lock().unwrap();
                        if payments.contains_key(&payment_hash) {
                                let payment = payments.get_mut(&payment_hash).unwrap();
                                payment.status = HTLCStatus::Failed;
                        }
                }
                Event::PaymentForwarded { fee_earned_msat, claim_from_onchain_tx } => {
                        let from_onchain_str = if claim_from_onchain_tx {
                                "from onchain downstream claim"
                        } else {
                                "from HTLC fulfill message"
                        };
                        if let Some(fee_earned) = fee_earned_msat {
                                println!(
                                        "\nEVENT: Forwarded payment, earning {} msat {}",
                                        fee_earned, from_onchain_str
                                );
                        } else {
                                println!("\nEVENT: Forwarded payment, claiming onchain {}", from_onchain_str);
                        }
                        print!("> ");
                        io::stdout().flush().unwrap();
                }
                Event::PendingHTLCsForwardable { time_forwardable } => {
                        let forwarding_channel_manager = channel_manager.clone();
                        tokio::spawn(async move {
                                let min = time_forwardable.as_millis() as u64;
                                let millis_to_sleep = thread_rng().gen_range(min, min * 5) as u64;
                                tokio::time::sleep(Duration::from_millis(millis_to_sleep)).await;
                                forwarding_channel_manager.process_pending_htlc_forwards();
                        });
                }
                Event::SpendableOutputs { outputs } => {
                        let destination_address = bitcoind_client.get_new_address().await;
                        let output_descriptors = &outputs.iter().map(|a| a).collect::<Vec<_>>();
                        let tx_feerate =
                                bitcoind_client.get_est_sat_per_1000_weight(ConfirmationTarget::Normal);
                        let spending_tx = keys_manager
                                .spend_spendable_outputs(
                                        output_descriptors,
                                        Vec::new(),
                                        destination_address.script_pubkey(),
                                        tx_feerate,
                                        &Secp256k1::new(),
                                )
                                .unwrap();
                        bitcoind_client.broadcast_transaction(&spending_tx);
                }
        }
}

async fn start_ldk() {
        let args = match cli::parse_startup_args() {
                Ok(user_args) => user_args,
                Err(()) => return,
        };

        // Initialize the LDK data directory if necessary.
        let ldk_data_dir = format!("{}/.ldk", args.ldk_storage_dir_path);
        fs::create_dir_all(ldk_data_dir.clone()).unwrap();

        // Initialize our bitcoind client.
        let bitcoind_client = match BitcoindClient::new(
                args.bitcoind_rpc_host.clone(),
                args.bitcoind_rpc_port,
                args.bitcoind_rpc_username.clone(),
                args.bitcoind_rpc_password.clone(),
        )
        .await
        {
                Ok(client) => Arc::new(client),
                Err(e) => {
                        println!("Failed to connect to bitcoind client: {}", e);
                        return;
                }
        };

        // Check that the bitcoind we've connected to is running the network we expect
        let bitcoind_chain = bitcoind_client.get_blockchain_info().await.chain;
        if bitcoind_chain
                != match args.network {
                        bitcoin::Network::Bitcoin => "main",
                        bitcoin::Network::Testnet => "test",
                        bitcoin::Network::Regtest => "regtest",
                        bitcoin::Network::Signet => "signet",
                } {
                println!(
                        "Chain argument ({}) didn't match bitcoind chain ({})",
                        args.network, bitcoind_chain
                );
                return;
        }

        // ## Setup
        // Step 1: Initialize the FeeEstimator

        // BitcoindClient implements the FeeEstimator trait, so it'll act as our fee estimator.
        let fee_estimator = bitcoind_client.clone();

        // Step 2: Initialize the Logger
        let logger = Arc::new(FilesystemLogger::new(ldk_data_dir.clone()));

        // Step 3: Initialize the BroadcasterInterface

        // BitcoindClient implements the BroadcasterInterface trait, so it'll act as our transaction
        // broadcaster.
        let broadcaster = bitcoind_client.clone();

        // Step 4: Initialize Persist
        let persister = Arc::new(FilesystemPersister::new(ldk_data_dir.clone()));

        // Step 5: Initialize the ChainMonitor
        let chain_monitor: Arc<ChainMonitor> = Arc::new(chainmonitor::ChainMonitor::new(
                None,
                broadcaster.clone(),
                logger.clone(),
                fee_estimator.clone(),
                persister.clone(),
        ));

        // Step 6: Initialize the KeysManager

        // The key seed that we use to derive the node privkey (that corresponds to the node pubkey) and
        // other secret key material.
        let keys_seed_path = format!("{}/keys_seed", ldk_data_dir.clone());
        let keys_seed = if let Ok(seed) = fs::read(keys_seed_path.clone()) {
                assert_eq!(seed.len(), 32);
                let mut key = [0; 32];
                key.copy_from_slice(&seed);
                key
        } else {
                let mut key = [0; 32];
                thread_rng().fill_bytes(&mut key);
                match File::create(keys_seed_path.clone()) {
                        Ok(mut f) => {
                                f.write_all(&key).expect("Failed to write node keys seed to disk");
                                f.sync_all().expect("Failed to sync node keys seed to disk");
                        }
                        Err(e) => {
                                println!("ERROR: Unable to create keys seed file {}: {}", keys_seed_path, e);
                                return;
                        }
                }
                key
        };
        let cur = SystemTime::now().duration_since(SystemTime::UNIX_EPOCH).unwrap();
        let keys_manager = Arc::new(KeysManager::new(&keys_seed, cur.as_secs(), cur.subsec_nanos()));

        // Step 7: Read ChannelMonitor state from disk
        let mut channelmonitors = persister.read_channelmonitors(keys_manager.clone()).unwrap();

        // Step 8: Initialize the ChannelManager
        let mut user_config = UserConfig::default();
        user_config.peer_channel_config_limits.force_announced_channel_preference = false;
        let mut restarting_node = true;
        let (channel_manager_blockhash, mut channel_manager) = {
                if let Ok(mut f) = fs::File::open(format!("{}/manager", ldk_data_dir.clone())) {
                        let mut channel_monitor_mut_references = Vec::new();
                        for (_, channel_monitor) in channelmonitors.iter_mut() {
                                channel_monitor_mut_references.push(channel_monitor);
                        }
                        let read_args = ChannelManagerReadArgs::new(
                                keys_manager.clone(),
                                fee_estimator.clone(),
                                chain_monitor.clone(),
                                broadcaster.clone(),
                                logger.clone(),
                                user_config,
                                channel_monitor_mut_references,
                        );
                        <(BlockHash, ChannelManager)>::read(&mut f, read_args).unwrap()
                } else {
                        // We're starting a fresh node.
                        restarting_node = false;
                        let getinfo_resp = bitcoind_client.get_blockchain_info().await;

                        let chain_params = ChainParameters {
                                network: args.network,
                                best_block: BestBlock::new(
                                        getinfo_resp.latest_blockhash,
                                        getinfo_resp.latest_height as u32,
                                ),
                        };
                        let fresh_channel_manager = channelmanager::ChannelManager::new(
                                fee_estimator.clone(),
                                chain_monitor.clone(),
                                broadcaster.clone(),
                                logger.clone(),
                                keys_manager.clone(),
                                user_config,
                                chain_params,
                        );
                        (getinfo_resp.latest_blockhash, fresh_channel_manager)
                }
        };

        // Step 9: Sync ChannelMonitors and ChannelManager to chain tip
        let mut chain_listener_channel_monitors = Vec::new();
        let mut cache = UnboundedCache::new();
        let mut chain_tip: Option<poll::ValidatedBlockHeader> = None;
        if restarting_node {
                let mut chain_listeners =
                        vec![(channel_manager_blockhash, &mut channel_manager as &mut dyn chain::Listen)];

                for (blockhash, channel_monitor) in channelmonitors.drain(..) {
                        let outpoint = channel_monitor.get_funding_txo().0;
                        chain_listener_channel_monitors.push((
                                blockhash,
                                (channel_monitor, broadcaster.clone(), fee_estimator.clone(), logger.clone()),
                                outpoint,
                        ));
                }

                for monitor_listener_info in chain_listener_channel_monitors.iter_mut() {
                        chain_listeners.push((
                                monitor_listener_info.0,
                                &mut monitor_listener_info.1 as &mut dyn chain::Listen,
                        ));
                }
                chain_tip = Some(
                        init::synchronize_listeners(
                                &mut bitcoind_client.deref(),
                                args.network,
                                &mut cache,
                                chain_listeners,
                        )
                        .await
                        .unwrap(),
                );
        }

        // Step 10: Give ChannelMonitors to ChainMonitor
        for item in chain_listener_channel_monitors.drain(..) {
                let channel_monitor = item.1 .0;
                let funding_outpoint = item.2;
                chain_monitor.watch_channel(funding_outpoint, channel_monitor).unwrap();
        }

        // Step 11: Optional: Initialize the NetGraphMsgHandler
        let genesis = genesis_block(args.network).header.block_hash();
        let network_graph_path = format!("{}/network_graph", ldk_data_dir.clone());
        let network_graph = disk::read_network(Path::new(&network_graph_path), genesis);
        let router = Arc::new(NetGraphMsgHandler::from_net_graph(
                None::<Arc<dyn chain::Access + Send + Sync>>,
                logger.clone(),
                network_graph,
        ));
        let router_persist = Arc::clone(&router);
        tokio::spawn(async move {
                let mut interval = tokio::time::interval(Duration::from_secs(600));
                loop {
                        interval.tick().await;
                        if disk::persist_network(
                                Path::new(&network_graph_path),
                                &*router_persist.network_graph.read().unwrap(),
                        )
                        .is_err()
                        {
                                // Persistence errors here are non-fatal as we can just fetch the routing graph
                                // again later, but they may indicate a disk error which could be fatal elsewhere.
                                eprintln!(
                                        "Warning: Failed to persist network graph, check your disk and permissions"
                                );
                        }
                }
        });

        // Step 12: Initialize the PeerManager
        let channel_manager: Arc<ChannelManager> = Arc::new(channel_manager);
        let mut ephemeral_bytes = [0; 32];
        rand::thread_rng().fill_bytes(&mut ephemeral_bytes);
        let lightning_msg_handler =
                MessageHandler { chan_handler: channel_manager.clone(), route_handler: router.clone() };
        let peer_manager: Arc<PeerManager> = Arc::new(PeerManager::new(
                lightning_msg_handler,
                keys_manager.get_node_secret(),
                &ephemeral_bytes,
                logger.clone(),
        ));

        // ## Running LDK
        // Step 13: Initialize networking

        let peer_manager_connection_handler = peer_manager.clone();
        let listening_port = args.ldk_peer_listening_port;
        tokio::spawn(async move {
                let listener = tokio::net::TcpListener::bind(format!("0.0.0.0:{}", listening_port))
                        .await
                        .expect("Failed to bind to listen port - is something else already listening on it?");
                loop {
                        let peer_mgr = peer_manager_connection_handler.clone();
                        let tcp_stream = listener.accept().await.unwrap().0;
                        tokio::spawn(async move {
                                lightning_net_tokio::setup_inbound(
                                        peer_mgr.clone(),
                                        tcp_stream.into_std().unwrap(),
                                )
                                .await;
                        });
                }
        });

        // Step 14: Connect and Disconnect Blocks
        if chain_tip.is_none() {
                chain_tip =
                        Some(init::validate_best_block_header(&mut bitcoind_client.deref()).await.unwrap());
        }
        let channel_manager_listener = channel_manager.clone();
        let chain_monitor_listener = chain_monitor.clone();
        let bitcoind_block_source = bitcoind_client.clone();
        let network = args.network;
        tokio::spawn(async move {
                let mut derefed = bitcoind_block_source.deref();
                let chain_poller = poll::ChainPoller::new(&mut derefed, network);
                let chain_listener = (chain_monitor_listener, channel_manager_listener);
                let mut spv_client =
                        SpvClient::new(chain_tip.unwrap(), chain_poller, &mut cache, &chain_listener);
                loop {
                        spv_client.poll_best_tip().await.unwrap();
                        tokio::time::sleep(Duration::from_secs(1)).await;
                }
        });

        // Step 15: Handle LDK Events
        let channel_manager_event_listener = channel_manager.clone();
        let keys_manager_listener = keys_manager.clone();
        // TODO: persist payment info to disk
        let inbound_payments: PaymentInfoStorage = Arc::new(Mutex::new(HashMap::new()));
        let outbound_payments: PaymentInfoStorage = Arc::new(Mutex::new(HashMap::new()));
        let inbound_pmts_for_events = inbound_payments.clone();
        let outbound_pmts_for_events = outbound_payments.clone();
        let network = args.network;
        let bitcoind_rpc = bitcoind_client.clone();
        let handle = tokio::runtime::Handle::current();
        let event_handler = move |event| {
                handle.block_on(handle_ldk_events(
                        channel_manager_event_listener.clone(),
                        bitcoind_rpc.clone(),
                        keys_manager_listener.clone(),
                        inbound_pmts_for_events.clone(),
                        outbound_pmts_for_events.clone(),
                        network,
                        event,
                ))
        };
        // Step 16: Persist ChannelManager
        let data_dir = ldk_data_dir.clone();
        let persist_channel_manager_callback =
                move |node: &ChannelManager| FilesystemPersister::persist_manager(data_dir.clone(), &*node);
        // Step 17: Background Processing
        let background_processor = BackgroundProcessor::start(
                persist_channel_manager_callback,
                event_handler,
                chain_monitor.clone(),
                channel_manager.clone(),
                peer_manager.clone(),
                logger.clone(),
        );

        // Reconnect to channel peers if possible.
        let peer_data_path = format!("{}/channel_peer_data", ldk_data_dir.clone());
        match disk::read_channel_peer_data(Path::new(&peer_data_path)) {
                Ok(mut info) => {
                        for (pubkey, peer_addr) in info.drain() {
                                for chan_info in channel_manager.list_channels() {
                                        if pubkey == chan_info.counterparty.node_id {
                                                let _ =
                                                        cli::connect_peer_if_necessary(pubkey, peer_addr, peer_manager.clone())
                                                                .await;
                                        }
                                }
                        }
                }
                Err(e) => println!("ERROR: errored reading channel peer info from disk: {:?}", e),
        }

        // Regularly broadcast our node_announcement. This is only required (or possible) if we have
        // some public channels, and is only useful if we have public listen address(es) to announce.
        // In a production environment, this should occur only after the announcement of new channels
        // to avoid churn in the global network graph.
        let chan_manager = Arc::clone(&channel_manager);
        let network = args.network;
        if !args.ldk_announced_listen_addr.is_empty() {
                tokio::spawn(async move {
                        let mut interval = tokio::time::interval(Duration::from_secs(60));
                        loop {
                                interval.tick().await;
                                chan_manager.broadcast_node_announcement(
                                        [0; 3],
                                        args.ldk_announced_node_name,
                                        args.ldk_announced_listen_addr.clone(),
                                );
                        }
                });
        }

        // Start the CLI.
        cli::poll_for_user_input(
                peer_manager.clone(),
                channel_manager.clone(),
                keys_manager.clone(),
                router.clone(),
                inbound_payments,
                outbound_payments,
                ldk_data_dir.clone(),
                logger.clone(),
                network,
        )
        .await;

        // Stop the background processor.
        background_processor.stop().unwrap();
}

#[tokio::main]
pub async fn main() {
        start_ldk().await;
}