#![deny(non_upper_case_globals)]
#![deny(non_camel_case_types)]
#![deny(non_snake_case)]
-#![deny(unused_mut)]
#![deny(unused_variables)]
#![deny(unused_imports)]
use std::collections::{HashMap, HashSet};
use std::fs::File;
use std::io::BufReader;
+use std::ops::Deref;
use std::sync::Arc;
-use std::sync::atomic::{AtomicBool, Ordering};
+use bitcoin::blockdata::constants::ChainHash;
+use lightning::log_info;
-use bitcoin::blockdata::constants::genesis_block;
-use bitcoin::Network;
-use bitcoin::secp256k1::PublicKey;
-use lightning::routing::gossip::NetworkGraph;
+use lightning::routing::gossip::{NetworkGraph, NodeId};
+use lightning::util::logger::Logger;
use lightning::util::ser::{ReadableArgs, Writeable};
use tokio::sync::mpsc;
+use tokio_postgres::{Client, NoTls};
+use crate::config::SYMLINK_GRANULARITY_INTERVAL;
use crate::lookup::DeltaSet;
use crate::persistence::GossipPersister;
-use crate::serialization::UpdateSerializationMechanism;
+use crate::serialization::UpdateSerialization;
use crate::snapshot::Snapshotter;
-use crate::types::TestLogger;
+use crate::types::RGSSLogger;
mod downloader;
-mod types;
mod tracking;
mod lookup;
mod persistence;
mod hex_utils;
mod verifier;
-pub struct RapidSyncProcessor {
- network_graph: Arc<NetworkGraph<TestLogger>>,
- pub initial_sync_complete: Arc<AtomicBool>,
+pub mod types;
+
+#[cfg(test)]
+mod tests;
+
+/// The purpose of this prefix is to identify the serialization format, should other rapid gossip
+/// sync formats arise in the future.
+///
+/// The fourth byte is the protocol version in case our format gets updated.
+const GOSSIP_PREFIX: [u8; 4] = [76, 68, 75, 1];
+
+pub struct RapidSyncProcessor<L: Deref> where L::Target: Logger {
+ network_graph: Arc<NetworkGraph<L>>,
+ logger: L
}
pub struct SerializedResponse {
pub update_count_incremental: u32,
}
-impl RapidSyncProcessor {
- pub fn new() -> Self {
- let logger = TestLogger::new();
- let mut initial_sync_complete = false;
+impl<L: Deref + Clone + Send + Sync + 'static> RapidSyncProcessor<L> where L::Target: Logger {
+ pub fn new(logger: L) -> Self {
+ let network = config::network();
let network_graph = if let Ok(file) = File::open(&config::network_graph_cache_path()) {
- println!("Initializing from cached network graph…");
+ log_info!(logger, "Initializing from cached network graph…");
let mut buffered_reader = BufReader::new(file);
- let network_graph_result = NetworkGraph::read(&mut buffered_reader, logger);
+ let network_graph_result = NetworkGraph::read(&mut buffered_reader, logger.clone());
if let Ok(network_graph) = network_graph_result {
- initial_sync_complete = true;
- network_graph.remove_stale_channels();
- println!("Initialized from cached network graph!");
+ log_info!(logger, "Initialized from cached network graph!");
network_graph
} else {
- println!("Initialization from cached network graph failed: {}", network_graph_result.err().unwrap());
- NetworkGraph::new(genesis_block(Network::Bitcoin).header.block_hash(), logger)
+ log_info!(logger, "Initialization from cached network graph failed: {}", network_graph_result.err().unwrap());
+ NetworkGraph::new(network, logger.clone())
}
} else {
- NetworkGraph::new(genesis_block(Network::Bitcoin).header.block_hash(), logger)
+ NetworkGraph::new(network, logger.clone())
};
let arc_network_graph = Arc::new(network_graph);
Self {
network_graph: arc_network_graph,
- initial_sync_complete: Arc::new(AtomicBool::new(initial_sync_complete)),
+ logger
}
}
pub async fn start_sync(&self) {
+ log_info!(self.logger, "Starting Rapid Gossip Sync Server");
+ log_info!(self.logger, "Snapshot interval: {} seconds", config::snapshot_generation_interval());
+
// means to indicate sync completion status within this module
let (sync_completion_sender, mut sync_completion_receiver) = mpsc::channel::<()>(1);
- let initial_sync_complete = self.initial_sync_complete.clone();
if config::DOWNLOAD_NEW_GOSSIP {
- let (mut persister, persistence_sender) =
- GossipPersister::new(sync_completion_sender, Arc::clone(&self.network_graph));
+ let (mut persister, persistence_sender) = GossipPersister::new(self.network_graph.clone(), self.logger.clone());
- println!("Starting gossip download");
- tokio::spawn(tracking::download_gossip(persistence_sender, Arc::clone(&self.network_graph)));
- println!("Starting gossip db persistence listener");
+ log_info!(self.logger, "Starting gossip download");
+ tokio::spawn(tracking::download_gossip(persistence_sender, sync_completion_sender,
+ Arc::clone(&self.network_graph), self.logger.clone()));
+ log_info!(self.logger, "Starting gossip db persistence listener");
tokio::spawn(async move { persister.persist_gossip().await; });
} else {
sync_completion_sender.send(()).await.unwrap();
}
- {
- let sync_completion = sync_completion_receiver.recv().await;
- if sync_completion.is_none() {
- panic!("Sync failed!");
- }
- initial_sync_complete.store(true, Ordering::Release);
- println!("Initial sync complete!");
-
- // start the gossip snapshotting service
- Snapshotter::new(Arc::clone(&self.network_graph)).snapshot_gossip().await;
+ let sync_completion = sync_completion_receiver.recv().await;
+ if sync_completion.is_none() {
+ panic!("Sync failed!");
}
- }
+ log_info!(self.logger, "Initial sync complete!");
- pub async fn serialize_delta(&self, last_sync_timestamp: u32, consider_intermediate_updates: bool) -> SerializedResponse {
- crate::serialize_delta(self.network_graph.clone(), last_sync_timestamp, consider_intermediate_updates).await
+ // start the gossip snapshotting service
+ Snapshotter::new(Arc::clone(&self.network_graph), self.logger.clone()).snapshot_gossip().await;
}
}
-async fn serialize_delta(network_graph: Arc<NetworkGraph<TestLogger>>, last_sync_timestamp: u32, consider_intermediate_updates: bool) -> SerializedResponse {
- let (client, connection) = lookup::connect_to_db().await;
+pub(crate) async fn connect_to_db() -> Client {
+ let connection_config = config::db_connection_config();
+ let (client, connection) = connection_config.connect(NoTls).await.unwrap();
tokio::spawn(async move {
if let Err(e) = connection.await {
}
});
+ #[cfg(test)]
+ {
+ let schema_name = tests::db_test_schema();
+ let schema_creation_command = format!("CREATE SCHEMA IF NOT EXISTS {}", schema_name);
+ client.execute(&schema_creation_command, &[]).await.unwrap();
+ client.execute(&format!("SET search_path TO {}", schema_name), &[]).await.unwrap();
+ }
+
+ client.execute("set time zone UTC", &[]).await.unwrap();
+ client
+}
+
+/// This method generates a no-op blob that can be used as a delta where none exists.
+///
+/// The primary purpose of this method is the scenario of a client retrieving and processing a
+/// given snapshot, and then immediately retrieving the would-be next snapshot at the timestamp
+/// indicated by the one that was just processed.
+/// Previously, there would not be a new snapshot to be processed for that particular timestamp yet,
+/// and the server would return a 404 error.
+///
+/// In principle, this method could also be used to address another unfortunately all too common
+/// pitfall: requesting snapshots from intermediate timestamps, i. e. those that are not multiples
+/// of our granularity constant. Note that for that purpose, this method could be very dangerous,
+/// because if consumed, the `timestamp` value calculated here will overwrite the timestamp that
+/// the client previously had, which could result in duplicated or omitted gossip down the line.
+fn serialize_empty_blob(current_timestamp: u64) -> Vec<u8> {
+ let mut blob = GOSSIP_PREFIX.to_vec();
+
+ let network = config::network();
+ let chain_hash = ChainHash::using_genesis_block(network);
+ chain_hash.write(&mut blob).unwrap();
+
+ let blob_timestamp = Snapshotter::<Arc<RGSSLogger>>::round_down_to_nearest_multiple(current_timestamp, SYMLINK_GRANULARITY_INTERVAL as u64) as u32;
+ blob_timestamp.write(&mut blob).unwrap();
+
+ 0u32.write(&mut blob).unwrap(); // node count
+ 0u32.write(&mut blob).unwrap(); // announcement count
+ 0u32.write(&mut blob).unwrap(); // update count
+
+ blob
+}
+
+async fn serialize_delta<L: Deref + Clone>(network_graph: Arc<NetworkGraph<L>>, last_sync_timestamp: u32, snapshot_reference_timestamp: Option<u64>, logger: L) -> SerializedResponse where L::Target: Logger {
+ let client = connect_to_db().await;
+
+ network_graph.remove_stale_channels_and_tracking();
+
let mut output: Vec<u8> = vec![];
+ let snapshot_interval = config::snapshot_generation_interval();
// set a flag if the chain hash is prepended
// chain hash only necessary if either channel announcements or non-incremental updates are present
// for announcement-free incremental-only updates, chain hash can be skipped
- let mut node_id_set: HashSet<[u8; 33]> = HashSet::new();
- let mut node_id_indices: HashMap<[u8; 33], usize> = HashMap::new();
- let mut node_ids: Vec<PublicKey> = Vec::new();
+ let mut node_id_set: HashSet<NodeId> = HashSet::new();
+ let mut node_id_indices: HashMap<NodeId, usize> = HashMap::new();
+ let mut node_ids: Vec<NodeId> = Vec::new();
let mut duplicate_node_ids: i32 = 0;
- let mut get_node_id_index = |node_id: PublicKey| {
- let serialized_node_id = node_id.serialize();
- if node_id_set.insert(serialized_node_id) {
+ let mut get_node_id_index = |node_id: NodeId| {
+ if node_id_set.insert(node_id) {
node_ids.push(node_id);
let index = node_ids.len() - 1;
- node_id_indices.insert(serialized_node_id, index);
+ node_id_indices.insert(node_id, index);
return index;
}
duplicate_node_ids += 1;
- node_id_indices[&serialized_node_id]
+ node_id_indices[&node_id]
};
let mut delta_set = DeltaSet::new();
- lookup::fetch_channel_announcements(&mut delta_set, network_graph, &client, last_sync_timestamp).await;
- println!("announcement channel count: {}", delta_set.len());
- lookup::fetch_channel_updates(&mut delta_set, &client, last_sync_timestamp, consider_intermediate_updates).await;
- println!("update-fetched channel count: {}", delta_set.len());
- lookup::filter_delta_set(&mut delta_set);
- println!("update-filtered channel count: {}", delta_set.len());
+ lookup::fetch_channel_announcements(&mut delta_set, network_graph, &client, last_sync_timestamp, snapshot_reference_timestamp, logger.clone()).await;
+ log_info!(logger, "announcement channel count: {}", delta_set.len());
+ lookup::fetch_channel_updates(&mut delta_set, &client, last_sync_timestamp, logger.clone()).await;
+ log_info!(logger, "update-fetched channel count: {}", delta_set.len());
+ lookup::filter_delta_set(&mut delta_set, logger.clone());
+ log_info!(logger, "update-filtered channel count: {}", delta_set.len());
let serialization_details = serialization::serialize_delta_set(delta_set, last_sync_timestamp);
// process announcements
let mut update_count_full = 0;
let mut update_count_incremental = 0;
for current_update in serialization_details.updates {
- match ¤t_update.mechanism {
- UpdateSerializationMechanism::Full => {
+ match ¤t_update {
+ UpdateSerialization::Full(_) => {
update_count_full += 1;
}
- UpdateSerializationMechanism::Incremental(_) => {
+ UpdateSerialization::Incremental(_, _) | UpdateSerialization::Reminder(_, _) => {
update_count_incremental += 1;
}
};
let mut stripped_update = serialization::serialize_stripped_channel_update(¤t_update, &default_update_values, previous_update_scid);
output.append(&mut stripped_update);
- previous_update_scid = current_update.update.short_channel_id;
+ previous_update_scid = current_update.scid();
}
// some stats
let message_count = announcement_count + update_count;
- let mut prefixed_output = vec![76, 68, 75, 1];
+ let mut prefixed_output = GOSSIP_PREFIX.to_vec();
// always write the chain hash
serialization_details.chain_hash.write(&mut prefixed_output).unwrap();
// always write the latest seen timestamp
let latest_seen_timestamp = serialization_details.latest_seen;
- let overflow_seconds = latest_seen_timestamp % config::SNAPSHOT_CALCULATION_INTERVAL;
+ let overflow_seconds = latest_seen_timestamp % snapshot_interval;
let serialized_seen_timestamp = latest_seen_timestamp.saturating_sub(overflow_seconds);
serialized_seen_timestamp.write(&mut prefixed_output).unwrap();
prefixed_output.append(&mut output);
- println!("duplicated node ids: {}", duplicate_node_ids);
- println!("latest seen timestamp: {:?}", serialization_details.latest_seen);
+ log_info!(logger, "duplicated node ids: {}", duplicate_node_ids);
+ log_info!(logger, "latest seen timestamp: {:?}", serialization_details.latest_seen);
SerializedResponse {
data: prefixed_output,