use secp256k1::key::PublicKey; use secp256k1::{Secp256k1,Message}; use bitcoin::util::hash::Sha256dHash; use ln::channelmanager; use ln::msgs::{ErrorAction,HandleError,RoutingMessageHandler,MsgEncodable,NetAddress,GlobalFeatures}; use ln::msgs; use std::cmp; use std::sync::RwLock; use std::collections::{HashMap,BinaryHeap}; use std::collections::hash_map::Entry; /// A hop in a route #[derive(Clone)] pub struct RouteHop { pub pubkey: PublicKey, /// The channel that should be used from the previous hop to reach this node. pub short_channel_id: u64, /// The fee taken on this hop. For the last hop, this should be the full value of the payment. pub fee_msat: u64, /// The CLTV delta added for this hop. For the last hop, this should be the full CLTV value /// expected at the destination, in excess of the current block height. pub cltv_expiry_delta: u32, } /// A route from us through the network to a destination #[derive(Clone)] pub struct Route { /// The list of hops, NOT INCLUDING our own, where the last hop is the destination. Thus, this /// must always be at least length one. By protocol rules, this may not currently exceed 20 in /// length. pub hops: Vec, } struct DirectionalChannelInfo { src_node_id: PublicKey, last_update: u32, enabled: bool, cltv_expiry_delta: u16, htlc_minimum_msat: u64, fee_base_msat: u32, fee_proportional_millionths: u32, } struct ChannelInfo { features: GlobalFeatures, one_to_two: DirectionalChannelInfo, two_to_one: DirectionalChannelInfo, } struct NodeInfo { #[cfg(feature = "non_bitcoin_chain_hash_routing")] channels: Vec<(u64, Sha256dHash)>, #[cfg(not(feature = "non_bitcoin_chain_hash_routing"))] channels: Vec, lowest_inbound_channel_fee_base_msat: u32, lowest_inbound_channel_fee_proportional_millionths: u32, features: GlobalFeatures, last_update: u32, rgb: [u8; 3], alias: [u8; 32], addresses: Vec, } struct NetworkMap { #[cfg(feature = "non_bitcoin_chain_hash_routing")] channels: HashMap<(u64, Sha256dHash), ChannelInfo>, #[cfg(not(feature = "non_bitcoin_chain_hash_routing"))] channels: HashMap, our_node_id: PublicKey, nodes: HashMap, } impl NetworkMap { #[cfg(feature = "non_bitcoin_chain_hash_routing")] #[inline] fn get_key(short_channel_id: u64, chain_hash: Sha256dHash) -> (u64, Sha256dHash) { (short_channel_id, chain_hash) } #[cfg(not(feature = "non_bitcoin_chain_hash_routing"))] #[inline] fn get_key(short_channel_id: u64, _: Sha256dHash) -> u64 { short_channel_id } } /// A channel descriptor which provides a last-hop route to get_route pub struct RouteHint { pub src_node_id: PublicKey, pub short_channel_id: u64, pub fee_base_msat: u64, pub fee_proportional_millionths: u32, pub cltv_expiry_delta: u16, pub htlc_minimum_msat: u64, } /// Tracks a view of the network, receiving updates from peers and generating Routes to /// payment destinations. pub struct Router { secp_ctx: Secp256k1, network_map: RwLock, } macro_rules! secp_verify_sig { ( $secp_ctx: expr, $msg: expr, $sig: expr, $pubkey: expr ) => { match $secp_ctx.verify($msg, $sig, $pubkey) { Ok(_) => {}, Err(_) => return Err(HandleError{err: "Invalid signature from remote node", action: None}), } }; } impl RoutingMessageHandler for Router { fn handle_node_announcement(&self, msg: &msgs::NodeAnnouncement) -> Result<(), HandleError> { let msg_hash = Message::from_slice(&Sha256dHash::from_data(&msg.contents.encode()[..])[..]).unwrap(); secp_verify_sig!(self.secp_ctx, &msg_hash, &msg.signature, &msg.contents.node_id); let mut network = self.network_map.write().unwrap(); match network.nodes.get_mut(&msg.contents.node_id) { None => Err(HandleError{err: "No existing channels for node_announcement", action: Some(ErrorAction::IgnoreError)}), Some(node) => { if node.last_update >= msg.contents.timestamp { return Err(HandleError{err: "Update older than last processed update", action: Some(ErrorAction::IgnoreError)}); } node.features = msg.contents.features.clone(); node.last_update = msg.contents.timestamp; node.rgb = msg.contents.rgb; node.alias = msg.contents.alias; node.addresses = msg.contents.addresses.clone(); Ok(()) } } } fn handle_channel_announcement(&self, msg: &msgs::ChannelAnnouncement) -> Result { let msg_hash = Message::from_slice(&Sha256dHash::from_data(&msg.contents.encode()[..])[..]).unwrap(); secp_verify_sig!(self.secp_ctx, &msg_hash, &msg.node_signature_1, &msg.contents.node_id_1); secp_verify_sig!(self.secp_ctx, &msg_hash, &msg.node_signature_2, &msg.contents.node_id_2); secp_verify_sig!(self.secp_ctx, &msg_hash, &msg.bitcoin_signature_1, &msg.contents.bitcoin_key_1); secp_verify_sig!(self.secp_ctx, &msg_hash, &msg.bitcoin_signature_2, &msg.contents.bitcoin_key_2); //TODO: Call blockchain thing to ask if the short_channel_id is valid //TODO: Only allow bitcoin chain_hash if msg.contents.features.requires_unknown_bits() { return Err(HandleError{err: "Channel announcement required unknown feature flags", action: None}); } let mut network = self.network_map.write().unwrap(); match network.channels.entry(NetworkMap::get_key(msg.contents.short_channel_id, msg.contents.chain_hash)) { Entry::Occupied(_) => { //TODO: because asking the blockchain if short_channel_id is valid is only optional //in the blockchain API, we need to handle it smartly here, though its unclear //exactly how... return Err(HandleError{err: "Already have knowledge of channel", action: Some(ErrorAction::IgnoreError)}) }, Entry::Vacant(entry) => { entry.insert(ChannelInfo { features: msg.contents.features.clone(), one_to_two: DirectionalChannelInfo { src_node_id: msg.contents.node_id_1.clone(), last_update: 0, enabled: false, cltv_expiry_delta: u16::max_value(), htlc_minimum_msat: u64::max_value(), fee_base_msat: u32::max_value(), fee_proportional_millionths: u32::max_value(), }, two_to_one: DirectionalChannelInfo { src_node_id: msg.contents.node_id_2.clone(), last_update: 0, enabled: false, cltv_expiry_delta: u16::max_value(), htlc_minimum_msat: u64::max_value(), fee_base_msat: u32::max_value(), fee_proportional_millionths: u32::max_value(), } }); } }; macro_rules! add_channel_to_node { ( $node_id: expr ) => { match network.nodes.entry($node_id) { Entry::Occupied(node_entry) => { node_entry.into_mut().channels.push(NetworkMap::get_key(msg.contents.short_channel_id, msg.contents.chain_hash)); }, Entry::Vacant(node_entry) => { node_entry.insert(NodeInfo { channels: vec!(NetworkMap::get_key(msg.contents.short_channel_id, msg.contents.chain_hash)), lowest_inbound_channel_fee_base_msat: u32::max_value(), lowest_inbound_channel_fee_proportional_millionths: u32::max_value(), features: GlobalFeatures::new(), last_update: 0, rgb: [0; 3], alias: [0; 32], addresses: Vec::new(), }); } } }; } add_channel_to_node!(msg.contents.node_id_1); add_channel_to_node!(msg.contents.node_id_2); Ok(!msg.contents.features.supports_unknown_bits()) } fn handle_htlc_fail_channel_update(&self, update: &msgs::HTLCFailChannelUpdate) { match update { &msgs::HTLCFailChannelUpdate::ChannelUpdateMessage { ref msg } => { let _ = self.handle_channel_update(msg); }, &msgs::HTLCFailChannelUpdate::ChannelClosed { ref short_channel_id } => { let mut network = self.network_map.write().unwrap(); network.channels.remove(short_channel_id); }, } } fn handle_channel_update(&self, msg: &msgs::ChannelUpdate) -> Result<(), HandleError> { let mut network = self.network_map.write().unwrap(); let dest_node_id; let chan_enabled = msg.contents.flags & (1 << 1) != (1 << 1); let chan_was_enabled; match network.channels.get_mut(&NetworkMap::get_key(msg.contents.short_channel_id, msg.contents.chain_hash)) { None => return Err(HandleError{err: "Couldn't find channel for update", action: Some(ErrorAction::IgnoreError)}), Some(channel) => { macro_rules! maybe_update_channel_info { ( $target: expr) => { if $target.last_update >= msg.contents.timestamp { return Err(HandleError{err: "Update older than last processed update", action: Some(ErrorAction::IgnoreError)}); } chan_was_enabled = $target.enabled; $target.last_update = msg.contents.timestamp; $target.enabled = chan_enabled; $target.cltv_expiry_delta = msg.contents.cltv_expiry_delta; $target.htlc_minimum_msat = msg.contents.htlc_minimum_msat; $target.fee_base_msat = msg.contents.fee_base_msat; $target.fee_proportional_millionths = msg.contents.fee_proportional_millionths; } } let msg_hash = Message::from_slice(&Sha256dHash::from_data(&msg.contents.encode()[..])[..]).unwrap(); if msg.contents.flags & 1 == 1 { dest_node_id = channel.one_to_two.src_node_id.clone(); secp_verify_sig!(self.secp_ctx, &msg_hash, &msg.signature, &channel.two_to_one.src_node_id); maybe_update_channel_info!(channel.two_to_one); } else { dest_node_id = channel.two_to_one.src_node_id.clone(); secp_verify_sig!(self.secp_ctx, &msg_hash, &msg.signature, &channel.one_to_two.src_node_id); maybe_update_channel_info!(channel.one_to_two); } } } if chan_enabled { let node = network.nodes.get_mut(&dest_node_id).unwrap(); node.lowest_inbound_channel_fee_base_msat = cmp::min(node.lowest_inbound_channel_fee_base_msat, msg.contents.fee_base_msat); node.lowest_inbound_channel_fee_proportional_millionths = cmp::min(node.lowest_inbound_channel_fee_proportional_millionths, msg.contents.fee_proportional_millionths); } else if chan_was_enabled { let mut lowest_inbound_channel_fee_base_msat = u32::max_value(); let mut lowest_inbound_channel_fee_proportional_millionths = u32::max_value(); { let node = network.nodes.get(&dest_node_id).unwrap(); for chan_id in node.channels.iter() { let chan = network.channels.get(chan_id).unwrap(); if chan.one_to_two.src_node_id == dest_node_id { lowest_inbound_channel_fee_base_msat = cmp::min(lowest_inbound_channel_fee_base_msat, chan.two_to_one.fee_base_msat); lowest_inbound_channel_fee_proportional_millionths = cmp::min(lowest_inbound_channel_fee_proportional_millionths, chan.two_to_one.fee_proportional_millionths); } else { lowest_inbound_channel_fee_base_msat = cmp::min(lowest_inbound_channel_fee_base_msat, chan.one_to_two.fee_base_msat); lowest_inbound_channel_fee_proportional_millionths = cmp::min(lowest_inbound_channel_fee_proportional_millionths, chan.one_to_two.fee_proportional_millionths); } } } //TODO: satisfy the borrow-checker without a double-map-lookup :( let mut_node = network.nodes.get_mut(&dest_node_id).unwrap(); mut_node.lowest_inbound_channel_fee_base_msat = lowest_inbound_channel_fee_base_msat; mut_node.lowest_inbound_channel_fee_proportional_millionths = lowest_inbound_channel_fee_proportional_millionths; } Ok(()) } } #[derive(Eq, PartialEq)] struct RouteGraphNode { pubkey: PublicKey, lowest_fee_to_peer_through_node: u64, } impl cmp::Ord for RouteGraphNode { fn cmp(&self, other: &RouteGraphNode) -> cmp::Ordering { other.lowest_fee_to_peer_through_node.cmp(&self.lowest_fee_to_peer_through_node) .then_with(|| other.pubkey.serialize().cmp(&self.pubkey.serialize())) } } impl cmp::PartialOrd for RouteGraphNode { fn partial_cmp(&self, other: &RouteGraphNode) -> Option { Some(self.cmp(other)) } } struct DummyDirectionalChannelInfo { src_node_id: PublicKey, cltv_expiry_delta: u32, htlc_minimum_msat: u64, fee_base_msat: u32, fee_proportional_millionths: u32, } impl Router { pub fn new(our_pubkey: PublicKey) -> Router { let mut nodes = HashMap::new(); nodes.insert(our_pubkey.clone(), NodeInfo { channels: Vec::new(), lowest_inbound_channel_fee_base_msat: u32::max_value(), lowest_inbound_channel_fee_proportional_millionths: u32::max_value(), features: GlobalFeatures::new(), last_update: 0, rgb: [0; 3], alias: [0; 32], addresses: Vec::new(), }); Router { secp_ctx: Secp256k1::new(), network_map: RwLock::new(NetworkMap { channels: HashMap::new(), our_node_id: our_pubkey, nodes: nodes, }), } } /// Get network addresses by node id pub fn get_addresses(&self, pubkey: &PublicKey) -> Option> { let network = self.network_map.read().unwrap(); network.nodes.get(pubkey).map(|n| n.addresses.clone()) } /// Marks a node as having failed a route. This will avoid re-using the node in routes for now, /// with an expotnential decay in node "badness". Note that there is deliberately no /// mark_channel_bad as a node may simply lie and suggest that an upstream channel from it is /// what failed the route and not the node itself. Instead, setting the blamed_upstream_node /// boolean will reduce the penalty, returning the node to usability faster. If the node is /// behaving correctly, it will disable the failing channel and we will use it again next time. pub fn mark_node_bad(&self, _node_id: &PublicKey, _blamed_upstream_node: bool) { unimplemented!(); } /// Gets a route from us to the given target node. /// Extra routing hops between known nodes and the target will be used if they are included in /// last_hops. /// If some channels aren't announced, it may be useful to fill in a first_hops with the /// results from a local ChannelManager::list_usable_channels() call. If it is filled in, our /// (this Router's) view of our local channels will be ignored, and only those in first_hops /// will be used. Panics if first_hops contains channels without short_channel_ids /// (ChannelManager::list_usable_channels will never include such channels). /// The fees on channels from us to next-hops are ignored (as they are assumed to all be /// equal), however the enabled/disabled bit on such channels as well as the htlc_minimum_msat /// *is* checked as they may change based on the receiving node. pub fn get_route(&self, target: &PublicKey, first_hops: Option<&[channelmanager::ChannelDetails]>, last_hops: &[RouteHint], final_value_msat: u64, final_cltv: u32) -> Result { // TODO: Obviously *only* using total fee cost sucks. We should consider weighting by // uptime/success in using a node in the past. let network = self.network_map.read().unwrap(); if *target == network.our_node_id { return Err(HandleError{err: "Cannot generate a route to ourselves", action: None}); } // We do a dest-to-source Dijkstra's sorting by each node's distance from the destination // plus the minimum per-HTLC fee to get from it to another node (aka "shitty A*"). // TODO: There are a few tweaks we could do, including possibly pre-calculating more stuff // to use as the A* heuristic beyond just the cost to get one node further than the current // one. let dummy_directional_info = DummyDirectionalChannelInfo { // used for first_hops routes src_node_id: network.our_node_id.clone(), cltv_expiry_delta: 0, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }; let mut targets = BinaryHeap::new(); //TODO: Do we care about switching to eg Fibbonaci heap? let mut dist = HashMap::with_capacity(network.nodes.len()); let mut first_hop_targets = HashMap::with_capacity(if first_hops.is_some() { first_hops.as_ref().unwrap().len() } else { 0 }); if let Some(hops) = first_hops { for chan in hops { let short_channel_id = chan.short_channel_id.expect("first_hops should be filled in with usable channels, not pending ones"); if chan.remote_network_id == *target { return Ok(Route { hops: vec![RouteHop { pubkey: chan.remote_network_id, short_channel_id, fee_msat: final_value_msat, cltv_expiry_delta: final_cltv, }], }); } first_hop_targets.insert(chan.remote_network_id, short_channel_id); } if first_hop_targets.is_empty() { return Err(HandleError{err: "Cannot route when there are no outbound routes away from us", action: None}); } } macro_rules! add_entry { // Adds entry which goes from the node pointed to by $directional_info to // $dest_node_id over the channel with id $chan_id with fees described in // $directional_info. ( $chan_id: expr, $dest_node_id: expr, $directional_info: expr, $starting_fee_msat: expr ) => { //TODO: Explore simply adding fee to hit htlc_minimum_msat if $starting_fee_msat as u64 + final_value_msat > $directional_info.htlc_minimum_msat { let proportional_fee_millions = ($starting_fee_msat + final_value_msat).checked_mul($directional_info.fee_proportional_millionths as u64); if let Some(proportional_fee) = proportional_fee_millions { let new_fee = $directional_info.fee_base_msat as u64 + proportional_fee / 1000000; let mut total_fee = $starting_fee_msat as u64; let mut hm_entry = dist.entry(&$directional_info.src_node_id); let old_entry = hm_entry.or_insert_with(|| { let node = network.nodes.get(&$directional_info.src_node_id).unwrap(); (u64::max_value(), node.lowest_inbound_channel_fee_base_msat as u64, node.lowest_inbound_channel_fee_proportional_millionths as u64, RouteHop { pubkey: PublicKey::new(), short_channel_id: 0, fee_msat: 0, cltv_expiry_delta: 0, }) }); if $directional_info.src_node_id != network.our_node_id { // Ignore new_fee for channel-from-us as we assume all channels-from-us // will have the same effective-fee total_fee += new_fee; total_fee += old_entry.2 * (final_value_msat + total_fee) / 1000000 + old_entry.1; } let new_graph_node = RouteGraphNode { pubkey: $directional_info.src_node_id, lowest_fee_to_peer_through_node: total_fee, }; if old_entry.0 > total_fee { targets.push(new_graph_node); old_entry.0 = total_fee; old_entry.3 = RouteHop { pubkey: $dest_node_id.clone(), short_channel_id: $chan_id.clone(), fee_msat: new_fee, // This field is ignored on the last-hop anyway cltv_expiry_delta: $directional_info.cltv_expiry_delta as u32, } } } } }; } macro_rules! add_entries_to_cheapest_to_target_node { ( $node: expr, $node_id: expr, $fee_to_target_msat: expr ) => { if first_hops.is_some() { if let Some(first_hop) = first_hop_targets.get(&$node_id) { add_entry!(first_hop, $node_id, dummy_directional_info, $fee_to_target_msat); } } for chan_id in $node.channels.iter() { let chan = network.channels.get(chan_id).unwrap(); if chan.one_to_two.src_node_id == *$node_id { // ie $node is one, ie next hop in A* is two, via the two_to_one channel if first_hops.is_none() || chan.two_to_one.src_node_id != network.our_node_id { if chan.two_to_one.enabled { add_entry!(chan_id, chan.one_to_two.src_node_id, chan.two_to_one, $fee_to_target_msat); } } } else { if first_hops.is_none() || chan.one_to_two.src_node_id != network.our_node_id { if chan.one_to_two.enabled { add_entry!(chan_id, chan.two_to_one.src_node_id, chan.one_to_two, $fee_to_target_msat); } } } } }; } match network.nodes.get(target) { None => {}, Some(node) => { add_entries_to_cheapest_to_target_node!(node, target, 0); }, } for hop in last_hops.iter() { if first_hops.is_none() || hop.src_node_id != network.our_node_id { // first_hop overrules last_hops if network.nodes.get(&hop.src_node_id).is_some() { if first_hops.is_some() { if let Some(first_hop) = first_hop_targets.get(&hop.src_node_id) { add_entry!(first_hop, hop.src_node_id, dummy_directional_info, 0); } } add_entry!(hop.short_channel_id, target, hop, 0); } } } while let Some(RouteGraphNode { pubkey, lowest_fee_to_peer_through_node }) = targets.pop() { if pubkey == network.our_node_id { let mut res = vec!(dist.remove(&network.our_node_id).unwrap().3); while res.last().unwrap().pubkey != *target { let new_entry = dist.remove(&res.last().unwrap().pubkey).unwrap().3; res.last_mut().unwrap().fee_msat = new_entry.fee_msat; res.last_mut().unwrap().cltv_expiry_delta = new_entry.cltv_expiry_delta; res.push(new_entry); } res.last_mut().unwrap().fee_msat = final_value_msat; res.last_mut().unwrap().cltv_expiry_delta = final_cltv; return Ok(Route { hops: res }); } match network.nodes.get(&pubkey) { None => {}, Some(node) => { let mut fee = lowest_fee_to_peer_through_node - node.lowest_inbound_channel_fee_base_msat as u64; fee -= node.lowest_inbound_channel_fee_proportional_millionths as u64 * (fee + final_value_msat) / 1000000; add_entries_to_cheapest_to_target_node!(node, &pubkey, fee); }, } } Err(HandleError{err: "Failed to find a path to the given destination", action: None}) } } #[cfg(test)] mod tests { use ln::channelmanager; use ln::router::{Router,NodeInfo,NetworkMap,ChannelInfo,DirectionalChannelInfo,RouteHint}; use ln::msgs::GlobalFeatures; use bitcoin::util::misc::hex_bytes; use bitcoin::util::hash::Sha256dHash; use secp256k1::key::{PublicKey,SecretKey}; use secp256k1::Secp256k1; #[test] fn route_test() { let secp_ctx = Secp256k1::new(); let our_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&secp_ctx, &hex_bytes("0101010101010101010101010101010101010101010101010101010101010101").unwrap()[..]).unwrap()).unwrap(); let router = Router::new(our_id); // Build network from our_id to node8: // // -1(1)2- node1 -1(3)2- // / \ // our_id -1(12)2- node8 -1(13)2--- node3 // \ / // -1(2)2- node2 -1(4)2- // // // chan1 1-to-2: disabled // chan1 2-to-1: enabled, 0 fee // // chan2 1-to-2: enabled, ignored fee // chan2 2-to-1: enabled, 0 fee // // chan3 1-to-2: enabled, 0 fee // chan3 2-to-1: enabled, 100 msat fee // // chan4 1-to-2: enabled, 100% fee // chan4 2-to-1: enabled, 0 fee // // chan12 1-to-2: enabled, ignored fee // chan12 2-to-1: enabled, 0 fee // // chan13 1-to-2: enabled, 200% fee // chan13 2-to-1: enabled, 0 fee // // // -1(5)2- node4 -1(8)2-- // | 2 | // | (11) | // / 1 \ // node3--1(6)2- node5 -1(9)2--- node7 (not in global route map) // \ / // -1(7)2- node6 -1(10)2- // // chan5 1-to-2: enabled, 100 msat fee // chan5 2-to-1: enabled, 0 fee // // chan6 1-to-2: enabled, 0 fee // chan6 2-to-1: enabled, 0 fee // // chan7 1-to-2: enabled, 100% fee // chan7 2-to-1: enabled, 0 fee // // chan8 1-to-2: enabled, variable fee (0 then 1000 msat) // chan8 2-to-1: enabled, 0 fee // // chan9 1-to-2: enabled, 1001 msat fee // chan9 2-to-1: enabled, 0 fee // // chan10 1-to-2: enabled, 0 fee // chan10 2-to-1: enabled, 0 fee // // chan11 1-to-2: enabled, 0 fee // chan11 2-to-1: enabled, 0 fee let node1 = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&secp_ctx, &hex_bytes("0202020202020202020202020202020202020202020202020202020202020202").unwrap()[..]).unwrap()).unwrap(); let node2 = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&secp_ctx, &hex_bytes("0303030303030303030303030303030303030303030303030303030303030303").unwrap()[..]).unwrap()).unwrap(); let node3 = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&secp_ctx, &hex_bytes("0404040404040404040404040404040404040404040404040404040404040404").unwrap()[..]).unwrap()).unwrap(); let node4 = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&secp_ctx, &hex_bytes("0505050505050505050505050505050505050505050505050505050505050505").unwrap()[..]).unwrap()).unwrap(); let node5 = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&secp_ctx, &hex_bytes("0606060606060606060606060606060606060606060606060606060606060606").unwrap()[..]).unwrap()).unwrap(); let node6 = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&secp_ctx, &hex_bytes("0707070707070707070707070707070707070707070707070707070707070707").unwrap()[..]).unwrap()).unwrap(); let node7 = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&secp_ctx, &hex_bytes("0808080808080808080808080808080808080808080808080808080808080808").unwrap()[..]).unwrap()).unwrap(); let node8 = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&secp_ctx, &hex_bytes("0909090909090909090909090909090909090909090909090909090909090909").unwrap()[..]).unwrap()).unwrap(); let zero_hash = Sha256dHash::from_data(&[0; 32]); { let mut network = router.network_map.write().unwrap(); network.nodes.insert(node1.clone(), NodeInfo { channels: vec!(NetworkMap::get_key(1, zero_hash.clone()), NetworkMap::get_key(3, zero_hash.clone())), lowest_inbound_channel_fee_base_msat: 100, lowest_inbound_channel_fee_proportional_millionths: 0, features: GlobalFeatures::new(), last_update: 1, rgb: [0; 3], alias: [0; 32], addresses: Vec::new(), }); network.channels.insert(NetworkMap::get_key(1, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: our_id.clone(), last_update: 0, enabled: false, cltv_expiry_delta: u16::max_value(), // This value should be ignored htlc_minimum_msat: 0, fee_base_msat: u32::max_value(), // This value should be ignored fee_proportional_millionths: u32::max_value(), // This value should be ignored }, two_to_one: DirectionalChannelInfo { src_node_id: node1.clone(), last_update: 0, enabled: true, cltv_expiry_delta: 0, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, }); network.nodes.insert(node2.clone(), NodeInfo { channels: vec!(NetworkMap::get_key(2, zero_hash.clone()), NetworkMap::get_key(4, zero_hash.clone())), lowest_inbound_channel_fee_base_msat: 0, lowest_inbound_channel_fee_proportional_millionths: 0, features: GlobalFeatures::new(), last_update: 1, rgb: [0; 3], alias: [0; 32], addresses: Vec::new(), }); network.channels.insert(NetworkMap::get_key(2, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: our_id.clone(), last_update: 0, enabled: true, cltv_expiry_delta: u16::max_value(), // This value should be ignored htlc_minimum_msat: 0, fee_base_msat: u32::max_value(), // This value should be ignored fee_proportional_millionths: u32::max_value(), // This value should be ignored }, two_to_one: DirectionalChannelInfo { src_node_id: node2.clone(), last_update: 0, enabled: true, cltv_expiry_delta: 0, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, }); network.nodes.insert(node8.clone(), NodeInfo { channels: vec!(NetworkMap::get_key(12, zero_hash.clone()), NetworkMap::get_key(13, zero_hash.clone())), lowest_inbound_channel_fee_base_msat: 0, lowest_inbound_channel_fee_proportional_millionths: 0, features: GlobalFeatures::new(), last_update: 1, rgb: [0; 3], alias: [0; 32], addresses: Vec::new(), }); network.channels.insert(NetworkMap::get_key(12, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: our_id.clone(), last_update: 0, enabled: true, cltv_expiry_delta: u16::max_value(), // This value should be ignored htlc_minimum_msat: 0, fee_base_msat: u32::max_value(), // This value should be ignored fee_proportional_millionths: u32::max_value(), // This value should be ignored }, two_to_one: DirectionalChannelInfo { src_node_id: node8.clone(), last_update: 0, enabled: true, cltv_expiry_delta: 0, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, }); network.nodes.insert(node3.clone(), NodeInfo { channels: vec!( NetworkMap::get_key(3, zero_hash.clone()), NetworkMap::get_key(4, zero_hash.clone()), NetworkMap::get_key(13, zero_hash.clone()), NetworkMap::get_key(5, zero_hash.clone()), NetworkMap::get_key(6, zero_hash.clone()), NetworkMap::get_key(7, zero_hash.clone())), lowest_inbound_channel_fee_base_msat: 0, lowest_inbound_channel_fee_proportional_millionths: 0, features: GlobalFeatures::new(), last_update: 1, rgb: [0; 3], alias: [0; 32], addresses: Vec::new(), }); network.channels.insert(NetworkMap::get_key(3, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: node1.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (3 << 8) | 1, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, two_to_one: DirectionalChannelInfo { src_node_id: node3.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (3 << 8) | 2, htlc_minimum_msat: 0, fee_base_msat: 100, fee_proportional_millionths: 0, }, }); network.channels.insert(NetworkMap::get_key(4, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: node2.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (4 << 8) | 1, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 1000000, }, two_to_one: DirectionalChannelInfo { src_node_id: node3.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (4 << 8) | 2, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, }); network.channels.insert(NetworkMap::get_key(13, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: node8.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (13 << 8) | 1, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 2000000, }, two_to_one: DirectionalChannelInfo { src_node_id: node3.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (13 << 8) | 2, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, }); network.nodes.insert(node4.clone(), NodeInfo { channels: vec!(NetworkMap::get_key(5, zero_hash.clone()), NetworkMap::get_key(11, zero_hash.clone())), lowest_inbound_channel_fee_base_msat: 0, lowest_inbound_channel_fee_proportional_millionths: 0, features: GlobalFeatures::new(), last_update: 1, rgb: [0; 3], alias: [0; 32], addresses: Vec::new(), }); network.channels.insert(NetworkMap::get_key(5, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: node3.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (5 << 8) | 1, htlc_minimum_msat: 0, fee_base_msat: 100, fee_proportional_millionths: 0, }, two_to_one: DirectionalChannelInfo { src_node_id: node4.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (5 << 8) | 2, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, }); network.nodes.insert(node5.clone(), NodeInfo { channels: vec!(NetworkMap::get_key(6, zero_hash.clone()), NetworkMap::get_key(11, zero_hash.clone())), lowest_inbound_channel_fee_base_msat: 0, lowest_inbound_channel_fee_proportional_millionths: 0, features: GlobalFeatures::new(), last_update: 1, rgb: [0; 3], alias: [0; 32], addresses: Vec::new(), }); network.channels.insert(NetworkMap::get_key(6, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: node3.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (6 << 8) | 1, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, two_to_one: DirectionalChannelInfo { src_node_id: node5.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (6 << 8) | 2, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, }); network.channels.insert(NetworkMap::get_key(11, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: node5.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (11 << 8) | 1, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, two_to_one: DirectionalChannelInfo { src_node_id: node4.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (11 << 8) | 2, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, }); network.nodes.insert(node6.clone(), NodeInfo { channels: vec!(NetworkMap::get_key(7, zero_hash.clone())), lowest_inbound_channel_fee_base_msat: 0, lowest_inbound_channel_fee_proportional_millionths: 0, features: GlobalFeatures::new(), last_update: 1, rgb: [0; 3], alias: [0; 32], addresses: Vec::new(), }); network.channels.insert(NetworkMap::get_key(7, zero_hash.clone()), ChannelInfo { features: GlobalFeatures::new(), one_to_two: DirectionalChannelInfo { src_node_id: node3.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (7 << 8) | 1, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 1000000, }, two_to_one: DirectionalChannelInfo { src_node_id: node6.clone(), last_update: 0, enabled: true, cltv_expiry_delta: (7 << 8) | 2, htlc_minimum_msat: 0, fee_base_msat: 0, fee_proportional_millionths: 0, }, }); } { // Simple route to 3 via 2 let route = router.get_route(&node3, None, &Vec::new(), 100, 42).unwrap(); assert_eq!(route.hops.len(), 2); assert_eq!(route.hops[0].pubkey, node2); assert_eq!(route.hops[0].short_channel_id, 2); assert_eq!(route.hops[0].fee_msat, 100); assert_eq!(route.hops[0].cltv_expiry_delta, (4 << 8) | 1); assert_eq!(route.hops[1].pubkey, node3); assert_eq!(route.hops[1].short_channel_id, 4); assert_eq!(route.hops[1].fee_msat, 100); assert_eq!(route.hops[1].cltv_expiry_delta, 42); } { // Route to 1 via 2 and 3 because our channel to 1 is disabled let route = router.get_route(&node1, None, &Vec::new(), 100, 42).unwrap(); assert_eq!(route.hops.len(), 3); assert_eq!(route.hops[0].pubkey, node2); assert_eq!(route.hops[0].short_channel_id, 2); assert_eq!(route.hops[0].fee_msat, 200); assert_eq!(route.hops[0].cltv_expiry_delta, (4 << 8) | 1); assert_eq!(route.hops[1].pubkey, node3); assert_eq!(route.hops[1].short_channel_id, 4); assert_eq!(route.hops[1].fee_msat, 100); assert_eq!(route.hops[1].cltv_expiry_delta, (3 << 8) | 2); assert_eq!(route.hops[2].pubkey, node1); assert_eq!(route.hops[2].short_channel_id, 3); assert_eq!(route.hops[2].fee_msat, 100); assert_eq!(route.hops[2].cltv_expiry_delta, 42); } { // If we specify a channel to node8, that overrides our local channel view and that gets used let our_chans = vec![channelmanager::ChannelDetails { channel_id: [0; 32], short_channel_id: Some(42), remote_network_id: node8.clone(), channel_value_satoshis: 0, user_id: 0, }]; let route = router.get_route(&node3, Some(&our_chans), &Vec::new(), 100, 42).unwrap(); assert_eq!(route.hops.len(), 2); assert_eq!(route.hops[0].pubkey, node8); assert_eq!(route.hops[0].short_channel_id, 42); assert_eq!(route.hops[0].fee_msat, 200); assert_eq!(route.hops[0].cltv_expiry_delta, (13 << 8) | 1); assert_eq!(route.hops[1].pubkey, node3); assert_eq!(route.hops[1].short_channel_id, 13); assert_eq!(route.hops[1].fee_msat, 100); assert_eq!(route.hops[1].cltv_expiry_delta, 42); } let mut last_hops = vec!(RouteHint { src_node_id: node4.clone(), short_channel_id: 8, fee_base_msat: 0, fee_proportional_millionths: 0, cltv_expiry_delta: (8 << 8) | 1, htlc_minimum_msat: 0, }, RouteHint { src_node_id: node5.clone(), short_channel_id: 9, fee_base_msat: 1001, fee_proportional_millionths: 0, cltv_expiry_delta: (9 << 8) | 1, htlc_minimum_msat: 0, }, RouteHint { src_node_id: node6.clone(), short_channel_id: 10, fee_base_msat: 0, fee_proportional_millionths: 0, cltv_expiry_delta: (10 << 8) | 1, htlc_minimum_msat: 0, }); { // Simple test across 2, 3, 5, and 4 via a last_hop channel let route = router.get_route(&node7, None, &last_hops, 100, 42).unwrap(); assert_eq!(route.hops.len(), 5); assert_eq!(route.hops[0].pubkey, node2); assert_eq!(route.hops[0].short_channel_id, 2); assert_eq!(route.hops[0].fee_msat, 100); assert_eq!(route.hops[0].cltv_expiry_delta, (4 << 8) | 1); assert_eq!(route.hops[1].pubkey, node3); assert_eq!(route.hops[1].short_channel_id, 4); assert_eq!(route.hops[1].fee_msat, 0); assert_eq!(route.hops[1].cltv_expiry_delta, (6 << 8) | 1); assert_eq!(route.hops[2].pubkey, node5); assert_eq!(route.hops[2].short_channel_id, 6); assert_eq!(route.hops[2].fee_msat, 0); assert_eq!(route.hops[2].cltv_expiry_delta, (11 << 8) | 1); assert_eq!(route.hops[3].pubkey, node4); assert_eq!(route.hops[3].short_channel_id, 11); assert_eq!(route.hops[3].fee_msat, 0); assert_eq!(route.hops[3].cltv_expiry_delta, (8 << 8) | 1); assert_eq!(route.hops[4].pubkey, node7); assert_eq!(route.hops[4].short_channel_id, 8); assert_eq!(route.hops[4].fee_msat, 100); assert_eq!(route.hops[4].cltv_expiry_delta, 42); } { // Simple test with outbound channel to 4 to test that last_hops and first_hops connect let our_chans = vec![channelmanager::ChannelDetails { channel_id: [0; 32], short_channel_id: Some(42), remote_network_id: node4.clone(), channel_value_satoshis: 0, user_id: 0, }]; let route = router.get_route(&node7, Some(&our_chans), &last_hops, 100, 42).unwrap(); assert_eq!(route.hops.len(), 2); assert_eq!(route.hops[0].pubkey, node4); assert_eq!(route.hops[0].short_channel_id, 42); assert_eq!(route.hops[0].fee_msat, 0); assert_eq!(route.hops[0].cltv_expiry_delta, (8 << 8) | 1); assert_eq!(route.hops[1].pubkey, node7); assert_eq!(route.hops[1].short_channel_id, 8); assert_eq!(route.hops[1].fee_msat, 100); assert_eq!(route.hops[1].cltv_expiry_delta, 42); } last_hops[0].fee_base_msat = 1000; { // Revert to via 6 as the fee on 8 goes up let route = router.get_route(&node7, None, &last_hops, 100, 42).unwrap(); assert_eq!(route.hops.len(), 4); assert_eq!(route.hops[0].pubkey, node2); assert_eq!(route.hops[0].short_channel_id, 2); assert_eq!(route.hops[0].fee_msat, 200); // fee increased as its % of value transferred across node assert_eq!(route.hops[0].cltv_expiry_delta, (4 << 8) | 1); assert_eq!(route.hops[1].pubkey, node3); assert_eq!(route.hops[1].short_channel_id, 4); assert_eq!(route.hops[1].fee_msat, 100); assert_eq!(route.hops[1].cltv_expiry_delta, (7 << 8) | 1); assert_eq!(route.hops[2].pubkey, node6); assert_eq!(route.hops[2].short_channel_id, 7); assert_eq!(route.hops[2].fee_msat, 0); assert_eq!(route.hops[2].cltv_expiry_delta, (10 << 8) | 1); assert_eq!(route.hops[3].pubkey, node7); assert_eq!(route.hops[3].short_channel_id, 10); assert_eq!(route.hops[3].fee_msat, 100); assert_eq!(route.hops[3].cltv_expiry_delta, 42); } { // ...but still use 8 for larger payments as 6 has a variable feerate let route = router.get_route(&node7, None, &last_hops, 2000, 42).unwrap(); assert_eq!(route.hops.len(), 5); assert_eq!(route.hops[0].pubkey, node2); assert_eq!(route.hops[0].short_channel_id, 2); assert_eq!(route.hops[0].fee_msat, 3000); assert_eq!(route.hops[0].cltv_expiry_delta, (4 << 8) | 1); assert_eq!(route.hops[1].pubkey, node3); assert_eq!(route.hops[1].short_channel_id, 4); assert_eq!(route.hops[1].fee_msat, 0); assert_eq!(route.hops[1].cltv_expiry_delta, (6 << 8) | 1); assert_eq!(route.hops[2].pubkey, node5); assert_eq!(route.hops[2].short_channel_id, 6); assert_eq!(route.hops[2].fee_msat, 0); assert_eq!(route.hops[2].cltv_expiry_delta, (11 << 8) | 1); assert_eq!(route.hops[3].pubkey, node4); assert_eq!(route.hops[3].short_channel_id, 11); assert_eq!(route.hops[3].fee_msat, 1000); assert_eq!(route.hops[3].cltv_expiry_delta, (8 << 8) | 1); assert_eq!(route.hops[4].pubkey, node7); assert_eq!(route.hops[4].short_channel_id, 8); assert_eq!(route.hops[4].fee_msat, 2000); assert_eq!(route.hops[4].cltv_expiry_delta, 42); } } }