///! Load balanced communication with a group of web3 providers use super::blockchain::{ArcBlock, BlockHashesCache}; use super::connection::Web3Connection; use super::request::{ OpenRequestHandle, OpenRequestHandleMetrics, OpenRequestResult, RequestRevertHandler, }; use super::synced_connections::ConsensusConnections; use crate::app::{flatten_handle, AnyhowJoinHandle}; use crate::config::{BlockAndRpc, TxHashAndRpc, Web3ConnectionConfig}; use crate::frontend::authorization::{Authorization, RequestMetadata}; use crate::frontend::rpc_proxy_ws::ProxyMode; use crate::jsonrpc::{JsonRpcForwardedResponse, JsonRpcRequest}; use crate::rpcs::transactions::TxStatus; use counter::Counter; use derive_more::From; use ethers::prelude::{ProviderError, TxHash, H256, U64}; use futures::future::{join_all, try_join_all}; use futures::stream::FuturesUnordered; use futures::StreamExt; use hashbrown::{HashMap, HashSet}; use log::{debug, error, info, trace, warn, Level}; use migration::sea_orm::DatabaseConnection; use moka::future::{Cache, ConcurrentCacheExt}; use serde::ser::{SerializeStruct, Serializer}; use serde::Serialize; use serde_json::json; use serde_json::value::RawValue; use std::collections::BTreeMap; use std::sync::atomic::Ordering; use std::sync::Arc; use std::{cmp, fmt}; use thread_fast_rng::rand::seq::SliceRandom; use tokio::sync::{broadcast, watch}; use tokio::task; use tokio::time::{interval, sleep, sleep_until, Duration, Instant, MissedTickBehavior}; /// A collection of web3 connections. Sends requests either the current best server or all servers. #[derive(From)] pub struct Web3Connections { /// any requests will be forwarded to one (or more) of these connections pub(crate) conns: HashMap>, /// all providers with the same consensus head block. won't update if there is no `self.watch_consensus_head_sender` pub(super) watch_consensus_connections_sender: watch::Sender>, /// this head receiver makes it easy to wait until there is a new block pub(super) watch_consensus_head_receiver: Option>, pub(super) pending_transactions: Cache, /// TODO: this map is going to grow forever unless we do some sort of pruning. maybe store pruned in redis? /// all blocks, including orphans pub(super) block_hashes: BlockHashesCache, /// blocks on the heaviest chain pub(super) block_numbers: Cache, pub(super) min_head_rpcs: usize, pub(super) min_sum_soft_limit: u32, } impl Web3Connections { /// Spawn durable connections to multiple Web3 providers. #[allow(clippy::too_many_arguments)] pub async fn spawn( chain_id: u64, db_conn: Option, server_configs: HashMap, http_client: Option, redis_pool: Option, block_map: BlockHashesCache, watch_consensus_head_sender: Option>, min_sum_soft_limit: u32, min_head_rpcs: usize, pending_tx_sender: Option>, pending_transactions: Cache, open_request_handle_metrics: Arc, ) -> anyhow::Result<(Arc, AnyhowJoinHandle<()>)> { let (pending_tx_id_sender, pending_tx_id_receiver) = flume::unbounded(); let (block_sender, block_receiver) = flume::unbounded::(); // TODO: query the rpc to get the actual expected block time, or get from config? let expected_block_time_ms = match chain_id { // ethereum 1 => 12_000, // polygon 137 => 2_000, // fantom 250 => 1_000, // arbitrum 42161 => 500, // anything else _ => { warn!("unexpected chain_id. polling every {} seconds", 10); 10_000 } }; let http_interval_sender = if http_client.is_some() { let (sender, receiver) = broadcast::channel(1); drop(receiver); // TODO: what interval? follow a websocket also? maybe by watching synced connections with a timeout. will need debounce let mut interval = interval(Duration::from_millis(expected_block_time_ms)); interval.set_missed_tick_behavior(MissedTickBehavior::Delay); let sender = Arc::new(sender); let f = { let sender = sender.clone(); async move { loop { // TODO: every time a head_block arrives (with a small delay for known slow servers), or on the interval. interval.tick().await; // // trace!("http interval ready"); // errors are okay. they mean that all receivers have been dropped let _ = sender.send(()); } } }; // TODO: do something with this handle? tokio::spawn(f); Some(sender) } else { None }; // turn configs into connections (in parallel) // TODO: move this into a helper function. then we can use it when configs change (will need a remove function too) let spawn_handles: Vec<_> = server_configs .into_iter() .filter_map(|(server_name, server_config)| { if server_config.disabled { return None; } let db_conn = db_conn.clone(); let http_client = http_client.clone(); let redis_pool = redis_pool.clone(); let http_interval_sender = http_interval_sender.clone(); let block_sender = if watch_consensus_head_sender.is_some() { Some(block_sender.clone()) } else { None }; let pending_tx_id_sender = Some(pending_tx_id_sender.clone()); let block_map = block_map.clone(); let open_request_handle_metrics = open_request_handle_metrics.clone(); let handle = tokio::spawn(async move { server_config .spawn( server_name, db_conn, redis_pool, chain_id, http_client, http_interval_sender, block_map, block_sender, pending_tx_id_sender, open_request_handle_metrics, ) .await }); Some(handle) }) .collect(); // map of connection names to their connection let mut connections = HashMap::new(); let mut handles = vec![]; // TODO: do we need to join this? for x in join_all(spawn_handles).await { // TODO: how should we handle errors here? one rpc being down shouldn't cause the program to exit match x { Ok(Ok((connection, handle))) => { connections.insert(connection.name.clone(), connection); handles.push(handle); } Ok(Err(err)) => { // if we got an error here, it is not retryable // TODO: include context about which connection failed error!("Unable to create connection. err={:?}", err); } Err(err) => { return Err(err.into()); } } } // TODO: max_capacity and time_to_idle from config // all block hashes are the same size, so no need for weigher let block_hashes = Cache::builder() .time_to_idle(Duration::from_secs(600)) .max_capacity(10_000) .build_with_hasher(hashbrown::hash_map::DefaultHashBuilder::default()); // all block numbers are the same size, so no need for weigher let block_numbers = Cache::builder() .time_to_idle(Duration::from_secs(600)) .max_capacity(10_000) .build_with_hasher(hashbrown::hash_map::DefaultHashBuilder::default()); let (watch_consensus_connections_sender, _) = watch::channel(Default::default()); let watch_consensus_head_receiver = watch_consensus_head_sender.as_ref().map(|x| x.subscribe()); let connections = Arc::new(Self { conns: connections, watch_consensus_connections_sender, watch_consensus_head_receiver, pending_transactions, block_hashes, block_numbers, min_sum_soft_limit, min_head_rpcs, }); let authorization = Arc::new(Authorization::internal(db_conn.clone())?); let handle = { let connections = connections.clone(); tokio::spawn(async move { // TODO: try_join_all with the other handles here connections .subscribe( authorization, pending_tx_id_receiver, block_receiver, watch_consensus_head_sender, pending_tx_sender, ) .await }) }; Ok((connections, handle)) } pub fn get(&self, conn_name: &str) -> Option<&Arc> { self.conns.get(conn_name) } /// subscribe to blocks and transactions from all the backend rpcs. /// blocks are processed by all the `Web3Connection`s and then sent to the `block_receiver` /// transaction ids from all the `Web3Connection`s are deduplicated and forwarded to `pending_tx_sender` async fn subscribe( self: Arc, authorization: Arc, pending_tx_id_receiver: flume::Receiver, block_receiver: flume::Receiver, head_block_sender: Option>, pending_tx_sender: Option>, ) -> anyhow::Result<()> { let mut futures = vec![]; // setup the transaction funnel // it skips any duplicates (unless they are being orphaned) // fetches new transactions from the notifying rpc // forwards new transacitons to pending_tx_receipt_sender if let Some(pending_tx_sender) = pending_tx_sender.clone() { let clone = self.clone(); let authorization = authorization.clone(); let handle = task::spawn(async move { // TODO: set up this future the same as the block funnel while let Ok((pending_tx_id, rpc)) = pending_tx_id_receiver.recv_async().await { let f = clone.clone().process_incoming_tx_id( authorization.clone(), rpc, pending_tx_id, pending_tx_sender.clone(), ); tokio::spawn(f); } Ok(()) }); futures.push(flatten_handle(handle)); } // setup the block funnel if let Some(head_block_sender) = head_block_sender { let connections = Arc::clone(&self); let pending_tx_sender = pending_tx_sender.clone(); let handle = task::Builder::default() .name("process_incoming_blocks") .spawn(async move { connections .process_incoming_blocks( &authorization, block_receiver, head_block_sender, pending_tx_sender, ) .await })?; futures.push(flatten_handle(handle)); } if futures.is_empty() { // no transaction or block subscriptions. let handle = task::Builder::default().name("noop").spawn(async move { loop { sleep(Duration::from_secs(600)).await; // TODO: "every interval, check that the provider is still connected" } })?; futures.push(flatten_handle(handle)); } if let Err(e) = try_join_all(futures).await { error!("subscriptions over: {:?}", self); return Err(e); } info!("subscriptions over: {:?}", self); Ok(()) } /// Send the same request to all the handles. Returning the most common success or most common error. /// TODO: option to return the fastest response and handles for all the others instead? pub async fn try_send_parallel_requests( &self, active_request_handles: Vec, id: Box, method: &str, params: Option<&serde_json::Value>, error_level: Level, // TODO: remove this box once i figure out how to do the options ) -> anyhow::Result { // TODO: if only 1 active_request_handles, do self.try_send_request? let responses = active_request_handles .into_iter() .map(|active_request_handle| async move { let result: Result, _> = active_request_handle .request(method, &json!(¶ms), error_level.into()) .await; result }) .collect::>() .collect::, ProviderError>>>() .await; // TODO: Strings are not great keys, but we can't use RawValue or ProviderError as keys because they don't implement Hash or Eq let mut count_map: HashMap = HashMap::new(); let mut counts: Counter = Counter::new(); let mut any_ok_with_json_result = false; let mut any_ok_but_maybe_json_error = false; for partial_response in responses { if partial_response.is_ok() { any_ok_with_json_result = true; } let response = JsonRpcForwardedResponse::try_from_response_result(partial_response, id.clone()); // TODO: better key? let s = format!("{:?}", response); if count_map.get(&s).is_none() { if response.is_ok() { any_ok_but_maybe_json_error = true; } count_map.insert(s.clone(), response); } counts.update([s].into_iter()); } for (most_common, _) in counts.most_common_ordered() { let most_common = count_map .remove(&most_common) .expect("most_common key must exist"); match most_common { Ok(x) => { if any_ok_with_json_result && x.error.is_some() { // this one may be an "Ok", but the json has an error inside it continue; } // return the most common success return Ok(x); } Err(err) => { if any_ok_but_maybe_json_error { // the most common is an error, but there is an Ok in here somewhere. loop to find it continue; } return Err(err); } } } // TODO: what should we do if we get here? i don't think we will unimplemented!("this shouldn't be possible") } pub async fn best_consensus_head_connection( &self, authorization: &Arc, request_metadata: Option<&Arc>, skip: &[Arc], min_block_needed: Option<&U64>, ) -> anyhow::Result { if let Ok(without_backups) = self ._best_consensus_head_connection( false, authorization, request_metadata, skip, min_block_needed, ) .await { return Ok(without_backups); } self._best_consensus_head_connection( true, authorization, request_metadata, skip, min_block_needed, ) .await } /// get the best available rpc server with the consensus head block. it might have blocks after the consensus head async fn _best_consensus_head_connection( &self, allow_backups: bool, authorization: &Arc, request_metadata: Option<&Arc>, skip: &[Arc], min_block_needed: Option<&U64>, ) -> anyhow::Result { let usable_rpcs_by_head_num_and_weight: BTreeMap< (Option, u64), Vec>, > = { let synced_connections = self.watch_consensus_connections_sender.borrow().clone(); let head_block_num = if let Some(head_block) = synced_connections.head_block.as_ref() { head_block.number() } else { // TODO: optionally wait for a head block >= min_block_needed return Ok(OpenRequestResult::NotReady); }; let min_block_needed = min_block_needed.unwrap_or(&head_block_num); let mut m = BTreeMap::new(); match min_block_needed.cmp(&head_block_num) { cmp::Ordering::Less => { // need an old block. check all the rpcs. prefer the most synced for x in self .conns .values() .filter(|x| if allow_backups { true } else { !x.backup }) .filter(|x| !skip.contains(x)) .filter(|x| x.has_block_data(min_block_needed)) .cloned() { let x_head_block = x.head_block.read().clone(); match x_head_block { None => continue, Some(x_head) => { let key = (Some(x_head.number()), u64::MAX - x.tier); m.entry(key).or_insert_with(Vec::new).push(x); } } } } cmp::Ordering::Equal => { // need the consensus head block. filter the synced rpcs for x in synced_connections .conns .iter() .filter(|x| !skip.contains(x)) { let key = (None, u64::MAX - x.tier); m.entry(key).or_insert_with(Vec::new).push(x.clone()); } } cmp::Ordering::Greater => { // TODO? if the blocks is close and wait_for_sync and allow_backups, wait for change on a watch_consensus_connections_receiver().subscribe() return Ok(OpenRequestResult::NotReady); } } m }; let mut earliest_retry_at = None; for usable_rpcs in usable_rpcs_by_head_num_and_weight.into_values().rev() { // under heavy load, it is possible for even our best server to be negative let mut minimum = f64::MAX; let mut maximum = f64::MIN; // we sort on a combination of values. cache them here so that we don't do this math multiple times. let mut available_request_map: HashMap<_, f64> = usable_rpcs .iter() .map(|rpc| { // TODO: are active requests what we want? do we want a counter for requests in the last second + any actives longer than that? // TODO: get active requests out of redis (that's definitely too slow) // TODO: do something with hard limit instead? (but that is hitting redis too much) let active_requests = rpc.active_requests() as f64; let soft_limit = rpc.soft_limit as f64; let available_requests = soft_limit - active_requests; trace!("available requests on {}: {}", rpc, available_requests); minimum = minimum.min(available_requests); maximum = maximum.max(available_requests); (rpc, available_requests) }) .collect(); trace!("minimum available requests: {}", minimum); trace!("maximum available requests: {}", maximum); if maximum < 0.0 { // TODO: if maximum < 0 and there are other tiers on the same block, we should include them now warn!("soft limits overloaded: {} to {}", minimum, maximum) } // choose_multiple_weighted can't have negative numbers. shift up if any are negative // TODO: is this a correct way to shift? if minimum < 0.0 { available_request_map = available_request_map .into_iter() .map(|(rpc, available_requests)| { // TODO: is simple addition the right way to shift everyone? // TODO: probably want something non-linear // minimum is negative, so we subtract to make available requests bigger let x = available_requests - minimum; (rpc, x) }) .collect() } let sorted_rpcs = { if usable_rpcs.len() == 1 { // TODO: return now instead? we shouldn't need another alloc vec![usable_rpcs.get(0).expect("there should be 1")] } else { let mut rng = thread_fast_rng::thread_fast_rng(); usable_rpcs .choose_multiple_weighted(&mut rng, usable_rpcs.len(), |rpc| { *available_request_map .get(rpc) .expect("rpc should always be in available_request_map") }) .unwrap() .collect::>() } }; // now that the rpcs are sorted, try to get an active request handle for one of them for best_rpc in sorted_rpcs.into_iter() { // increment our connection counter match best_rpc .try_request_handle(authorization, min_block_needed.is_none()) .await { Ok(OpenRequestResult::Handle(handle)) => { trace!("opened handle: {}", best_rpc); return Ok(OpenRequestResult::Handle(handle)); } Ok(OpenRequestResult::RetryAt(retry_at)) => { earliest_retry_at = earliest_retry_at.min(Some(retry_at)); } Ok(OpenRequestResult::NotReady) => { // TODO: log a warning? emit a stat? } Err(err) => { warn!("No request handle for {}. err={:?}", best_rpc, err) } } } } if let Some(request_metadata) = request_metadata { request_metadata.no_servers.fetch_add(1, Ordering::Release); } match earliest_retry_at { None => { // none of the servers gave us a time to retry at // TODO: bring this back? need to think about how to do this with `allow_backups` // we could return an error here, but maybe waiting a second will fix the problem // TODO: configurable max wait? the whole max request time, or just some portion? // let handle = sorted_rpcs // .get(0) // .expect("at least 1 is available") // .wait_for_request_handle(authorization, Duration::from_secs(3), false) // .await?; // Ok(OpenRequestResult::Handle(handle)) // TODO: should we log here? Ok(OpenRequestResult::NotReady) } Some(earliest_retry_at) => { warn!("no servers on {:?}! {:?}", self, earliest_retry_at); Ok(OpenRequestResult::RetryAt(earliest_retry_at)) } } } /// get all rpc servers that are not rate limited /// this prefers synced servers, but it will return servers even if they aren't fully in sync. /// This is useful for broadcasting signed transactions. // TODO: better type on this that can return an anyhow::Result pub async fn all_connections( &self, authorization: &Arc, block_needed: Option<&U64>, max_count: Option, ) -> Result, Option> { if let Ok(without_backups) = self ._all_connections(false, authorization, block_needed, max_count) .await { return Ok(without_backups); } self._all_connections(true, authorization, block_needed, max_count) .await } async fn _all_connections( &self, allow_backups: bool, authorization: &Arc, block_needed: Option<&U64>, max_count: Option, ) -> Result, Option> { let mut earliest_retry_at = None; // TODO: with capacity? let mut selected_rpcs = vec![]; let mut max_count = if let Some(max_count) = max_count { max_count } else { self.conns.len() }; let mut tried = HashSet::new(); let conns_to_try = itertools::chain( // TODO: sort by tier self.watch_consensus_connections_sender .borrow() .conns .clone(), // TODO: sort by tier self.conns.values().cloned(), ); for connection in conns_to_try { if max_count == 0 { break; } if tried.contains(&connection.name) { continue; } tried.insert(connection.name.clone()); if !allow_backups && connection.backup { continue; } if let Some(block_needed) = block_needed { if !connection.has_block_data(block_needed) { continue; } } // check rate limits and increment our connection counter match connection .try_request_handle(authorization, block_needed.is_none()) .await { Ok(OpenRequestResult::RetryAt(retry_at)) => { // this rpc is not available. skip it earliest_retry_at = earliest_retry_at.min(Some(retry_at)); } Ok(OpenRequestResult::Handle(handle)) => { max_count -= 1; selected_rpcs.push(handle) } Ok(OpenRequestResult::NotReady) => { warn!("no request handle for {}", connection) } Err(err) => { warn!( "error getting request handle for {}. err={:?}", connection, err ) } } } if !selected_rpcs.is_empty() { return Ok(selected_rpcs); } // return the earliest retry_after (if no rpcs are synced, this will be None) Err(earliest_retry_at) } /// be sure there is a timeout on this or it might loop forever /// TODO: think more about wait_for_sync pub async fn try_send_best_consensus_head_connection( &self, authorization: &Arc, request: JsonRpcRequest, request_metadata: Option<&Arc>, min_block_needed: Option<&U64>, wait_for_sync: bool, ) -> anyhow::Result { let mut skip_rpcs = vec![]; let mut method_not_available_response = None; let mut watch_consensus_connections = if wait_for_sync { Some(self.watch_consensus_connections_sender.subscribe()) } else { None }; // TODO: maximum retries? right now its the total number of servers loop { // TODO: is self.conns still right now that we split main and backup servers? // TODO: if a new block arrives, we probably want to reset the skip list if skip_rpcs.len() == self.conns.len() { break; } match self .best_consensus_head_connection( authorization, request_metadata, &skip_rpcs, min_block_needed, ) .await? { OpenRequestResult::Handle(active_request_handle) => { // save the rpc in case we get an error and want to retry on another server // TODO: look at backend_requests instead skip_rpcs.push(active_request_handle.clone_connection()); if let Some(request_metadata) = request_metadata { let rpc = active_request_handle.clone_connection(); request_metadata .response_from_backup_rpc .store(rpc.backup, Ordering::Release); request_metadata.backend_requests.lock().push(rpc); } // TODO: get the log percent from the user data let response_result = active_request_handle .request( &request.method, &json!(request.params), RequestRevertHandler::Save, ) .await; match JsonRpcForwardedResponse::try_from_response_result( response_result, request.id.clone(), ) { Ok(response) => { if let Some(error) = &response.error.as_ref() { // trace!(?response, "rpc error"); if let Some(request_metadata) = request_metadata { request_metadata .error_response .store(true, Ordering::Release); } // some errors should be retried on other nodes let error_msg = error.message.as_str(); // different providers do different codes. check all of them // TODO: there's probably more strings to add here let rate_limit_substrings = ["limit", "exceeded"]; for rate_limit_substr in rate_limit_substrings { if error_msg.contains(rate_limit_substr) { warn!("rate limited by {}", skip_rpcs.last().unwrap()); continue; } } match error.code { -32000 => { // TODO: regex? let retry_prefixes = [ "header not found", "header for hash not found", "missing trie node", "node not started", "RPC timeout", ]; for retry_prefix in retry_prefixes { if error_msg.starts_with(retry_prefix) { continue; } } } -32601 => { let error_msg = error.message.as_str(); // sometimes a provider does not support all rpc methods // we check other connections rather than returning the error // but sometimes the method is something that is actually unsupported, // so we save the response here to return it later // some providers look like this if error_msg.starts_with("the method") && error_msg.ends_with("is not available") { method_not_available_response = Some(response); continue; } // others look like this if error_msg == "Method not found" { method_not_available_response = Some(response); continue; } } _ => {} } } else { // trace!(?response, "rpc success"); } return Ok(response); } Err(err) => { let rpc = skip_rpcs .last() .expect("there must have been a provider if we got an error"); // TODO: emit a stat. if a server is getting skipped a lot, something is not right debug!( "Backend server error on {}! Retrying on another. err={:?}", rpc, err ); continue; } } } OpenRequestResult::RetryAt(retry_at) => { // TODO: move this to a helper function // sleep (TODO: with a lock?) until our rate limits should be available // TODO: if a server catches up sync while we are waiting, we could stop waiting warn!("All rate limits exceeded. Sleeping until {:?}", retry_at); // TODO: have a separate column for rate limited? if let Some(request_metadata) = request_metadata { request_metadata.no_servers.fetch_add(1, Ordering::Release); } // TODO: if there are other servers in synced_connections, we should continue now if let Some(watch_consensus_connections) = watch_consensus_connections.as_mut() { // wait until retry_at OR synced_connections changes trace!("waiting for change in synced servers or retry_at"); tokio::select! { _ = sleep_until(retry_at) => { skip_rpcs.pop(); } _ = watch_consensus_connections.changed() => { // TODO: would be nice to save this retry_at so we don't keep hitting limits let _ = watch_consensus_connections.borrow_and_update(); } } } else { sleep_until(retry_at).await; } } OpenRequestResult::NotReady => { if let Some(request_metadata) = request_metadata { request_metadata.no_servers.fetch_add(1, Ordering::Release); } if wait_for_sync { trace!("waiting for change in synced servers"); // TODO: race here. there might have been a change while we were waiting on the previous server self.watch_consensus_connections_sender .subscribe() .changed() .await?; } } } } if let Some(r) = method_not_available_response { // TODO: emit a stat for unsupported methods? return Ok(r); } // TODO: do we need this here, or do we do it somewhere else? if let Some(request_metadata) = request_metadata { request_metadata .error_response .store(true, Ordering::Release); } let num_conns = self.conns.len(); if skip_rpcs.is_empty() { error!("No servers synced ({} known)", num_conns); Err(anyhow::anyhow!("No servers synced ({} known)", num_conns)) } else { Err(anyhow::anyhow!( "{}/{} servers erred", skip_rpcs.len(), num_conns )) } } /// be sure there is a timeout on this or it might loop forever pub async fn try_send_all_synced_connections( &self, authorization: &Arc, request: &JsonRpcRequest, request_metadata: Option>, block_needed: Option<&U64>, error_level: Level, max_count: Option, ) -> anyhow::Result { loop { match self .all_connections(authorization, block_needed, max_count) .await { Ok(active_request_handles) => { // TODO: benchmark this compared to waiting on unbounded futures // TODO: do something with this handle? // TODO: this is not working right. simplify if let Some(request_metadata) = request_metadata { let mut backup_used = false; request_metadata.backend_requests.lock().extend( active_request_handles.iter().map(|x| { let rpc = x.clone_connection(); if rpc.backup { // TODO: its possible we serve from a synced connection though. think about this more backup_used = true; } x.clone_connection() }), ); request_metadata .response_from_backup_rpc .store(true, Ordering::Release); } return self .try_send_parallel_requests( active_request_handles, request.id.clone(), request.method.as_ref(), request.params.as_ref(), error_level, ) .await; } Err(None) => { warn!("No servers in sync on {:?}! Retrying", self); if let Some(request_metadata) = &request_metadata { request_metadata.no_servers.fetch_add(1, Ordering::Release); } // TODO: i don't think this will ever happen // TODO: return a 502? if it does? // return Err(anyhow::anyhow!("no available rpcs!")); // TODO: sleep how long? // TODO: subscribe to something in ConsensusConnections instead sleep(Duration::from_millis(200)).await; continue; } Err(Some(retry_at)) => { // TODO: move this to a helper function // sleep (TODO: with a lock?) until our rate limits should be available // TODO: if a server catches up sync while we are waiting, we could stop waiting warn!("All rate limits exceeded. Sleeping"); if let Some(request_metadata) = &request_metadata { request_metadata.no_servers.fetch_add(1, Ordering::Release); } sleep_until(retry_at).await; continue; } } } } pub async fn try_proxy_connection( &self, proxy_mode: ProxyMode, authorization: &Arc, request: JsonRpcRequest, request_metadata: Option<&Arc>, min_block_needed: Option<&U64>, ) -> anyhow::Result { match proxy_mode { ProxyMode::Best => { self.try_send_best_consensus_head_connection( authorization, request, request_metadata, min_block_needed, true, ) .await } ProxyMode::Fastest(x) => todo!("Fastest"), ProxyMode::Versus => todo!("Versus"), } } } impl fmt::Debug for Web3Connections { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { // TODO: the default formatter takes forever to write. this is too quiet though f.debug_struct("Web3Connections") .field("conns", &self.conns) .finish_non_exhaustive() } } impl Serialize for Web3Connections { fn serialize(&self, serializer: S) -> Result where S: Serializer, { let mut state = serializer.serialize_struct("Web3Connections", 6)?; let conns: Vec<&Web3Connection> = self.conns.values().map(|x| x.as_ref()).collect(); state.serialize_field("conns", &conns)?; { let consensus_connections = self.watch_consensus_connections_sender.borrow().clone(); // TODO: rename synced_connections to consensus_connections? state.serialize_field("synced_connections", &consensus_connections)?; } self.block_hashes.sync(); self.block_numbers.sync(); state.serialize_field("block_hashes_count", &self.block_hashes.entry_count())?; state.serialize_field("block_hashes_size", &self.block_hashes.weighted_size())?; state.serialize_field("block_numbers_count", &self.block_numbers.entry_count())?; state.serialize_field("block_numbers_size", &self.block_numbers.weighted_size())?; state.end() } } mod tests { // TODO: why is this allow needed? does tokio::test get in the way somehow? #![allow(unused_imports)] use super::*; use crate::rpcs::{ blockchain::{ConsensusFinder, SavedBlock}, connection::ProviderState, provider::Web3Provider, }; use ethers::types::{Block, U256}; use log::{trace, LevelFilter}; use parking_lot::RwLock; use std::time::{SystemTime, UNIX_EPOCH}; use tokio::sync::RwLock as AsyncRwLock; #[tokio::test] async fn test_server_selection_by_height() { // TODO: do this better. can test_env_logger and tokio test be stacked? let _ = env_logger::builder() .filter_level(LevelFilter::Error) .filter_module("web3_proxy", LevelFilter::Trace) .is_test(true) .try_init(); let now: U256 = SystemTime::now() .duration_since(UNIX_EPOCH) .unwrap() .as_secs() .into(); let lagged_block = Block { hash: Some(H256::random()), number: Some(0.into()), timestamp: now - 1, ..Default::default() }; let head_block = Block { hash: Some(H256::random()), number: Some(1.into()), parent_hash: lagged_block.hash.unwrap(), timestamp: now, ..Default::default() }; let lagged_block = Arc::new(lagged_block); let head_block = Arc::new(head_block); // TODO: write a impl From for Block -> BlockId? let mut lagged_block: SavedBlock = lagged_block.into(); let mut head_block: SavedBlock = head_block.into(); let block_data_limit = u64::MAX; let head_rpc = Web3Connection { name: "synced".to_string(), db_conn: None, display_name: None, url: "ws://example.com/synced".to_string(), http_client: None, active_requests: 0.into(), frontend_requests: 0.into(), internal_requests: 0.into(), provider_state: AsyncRwLock::new(ProviderState::Ready(Arc::new(Web3Provider::Mock))), hard_limit: None, soft_limit: 1_000, automatic_block_limit: true, backup: false, block_data_limit: block_data_limit.into(), tier: 0, head_block: RwLock::new(Some(head_block.clone())), open_request_handle_metrics: Arc::new(Default::default()), }; let lagged_rpc = Web3Connection { name: "lagged".to_string(), db_conn: None, display_name: None, url: "ws://example.com/lagged".to_string(), http_client: None, active_requests: 0.into(), frontend_requests: 0.into(), internal_requests: 0.into(), provider_state: AsyncRwLock::new(ProviderState::Ready(Arc::new(Web3Provider::Mock))), hard_limit: None, soft_limit: 1_000, automatic_block_limit: false, backup: false, block_data_limit: block_data_limit.into(), tier: 0, head_block: RwLock::new(Some(lagged_block.clone())), open_request_handle_metrics: Arc::new(Default::default()), }; assert!(head_rpc.has_block_data(&lagged_block.number())); assert!(head_rpc.has_block_data(&head_block.number())); assert!(lagged_rpc.has_block_data(&lagged_block.number())); assert!(!lagged_rpc.has_block_data(&head_block.number())); let head_rpc = Arc::new(head_rpc); let lagged_rpc = Arc::new(lagged_rpc); let conns = HashMap::from([ (head_rpc.name.clone(), head_rpc.clone()), (lagged_rpc.name.clone(), lagged_rpc.clone()), ]); let (watch_consensus_connections_sender, _) = watch::channel(Default::default()); // TODO: make a Web3Connections::new let conns = Web3Connections { conns, watch_consensus_head_receiver: None, watch_consensus_connections_sender, pending_transactions: Cache::builder() .max_capacity(10_000) .build_with_hasher(hashbrown::hash_map::DefaultHashBuilder::default()), block_hashes: Cache::builder() .max_capacity(10_000) .build_with_hasher(hashbrown::hash_map::DefaultHashBuilder::default()), block_numbers: Cache::builder() .max_capacity(10_000) .build_with_hasher(hashbrown::hash_map::DefaultHashBuilder::default()), min_head_rpcs: 1, min_sum_soft_limit: 1, }; let authorization = Arc::new(Authorization::internal(None).unwrap()); let (head_block_sender, _head_block_receiver) = watch::channel::(Default::default()); let mut connection_heads = ConsensusFinder::default(); // process None so that conns .process_block_from_rpc( &authorization, &mut connection_heads, None, lagged_rpc.clone(), &head_block_sender, &None, ) .await .unwrap(); conns .process_block_from_rpc( &authorization, &mut connection_heads, None, head_rpc.clone(), &head_block_sender, &None, ) .await .unwrap(); // no head block because the rpcs haven't communicated through their channels assert!(conns.head_block_hash().is_none()); // all_backend_connections gives everything regardless of sync status assert_eq!( conns .all_connections(&authorization, None, None) .await .unwrap() .len(), 2 ); // best_synced_backend_connection requires servers to be synced with the head block let x = conns .best_consensus_head_connection(&authorization, None, &[], None) .await .unwrap(); dbg!(&x); assert!(matches!(x, OpenRequestResult::NotReady)); // add lagged blocks to the conns. both servers should be allowed lagged_block.block = conns.save_block(lagged_block.block, true).await.unwrap(); conns .process_block_from_rpc( &authorization, &mut connection_heads, Some(lagged_block.clone()), lagged_rpc, &head_block_sender, &None, ) .await .unwrap(); conns .process_block_from_rpc( &authorization, &mut connection_heads, Some(lagged_block.clone()), head_rpc.clone(), &head_block_sender, &None, ) .await .unwrap(); assert_eq!(conns.num_synced_rpcs(), 2); // add head block to the conns. lagged_rpc should not be available head_block.block = conns.save_block(head_block.block, true).await.unwrap(); conns .process_block_from_rpc( &authorization, &mut connection_heads, Some(head_block.clone()), head_rpc, &head_block_sender, &None, ) .await .unwrap(); assert_eq!(conns.num_synced_rpcs(), 1); assert!(matches!( conns .best_consensus_head_connection(&authorization, None, &[], None) .await, Ok(OpenRequestResult::Handle(_)) )); assert!(matches!( conns .best_consensus_head_connection(&authorization, None, &[], Some(&0.into())) .await, Ok(OpenRequestResult::Handle(_)) )); assert!(matches!( conns .best_consensus_head_connection(&authorization, None, &[], Some(&1.into())) .await, Ok(OpenRequestResult::Handle(_)) )); // future block should not get a handle assert!(matches!( conns .best_consensus_head_connection(&authorization, None, &[], Some(&2.into())) .await, Ok(OpenRequestResult::NotReady) )); } #[tokio::test] async fn test_server_selection_by_archive() { // TODO: do this better. can test_env_logger and tokio test be stacked? let _ = env_logger::builder() .filter_level(LevelFilter::Error) .filter_module("web3_proxy", LevelFilter::Trace) .is_test(true) .try_init(); let now: U256 = SystemTime::now() .duration_since(UNIX_EPOCH) .unwrap() .as_secs() .into(); let head_block = Block { hash: Some(H256::random()), number: Some(1_000_000.into()), parent_hash: H256::random(), timestamp: now, ..Default::default() }; let head_block: SavedBlock = Arc::new(head_block).into(); let pruned_rpc = Web3Connection { name: "pruned".to_string(), db_conn: None, display_name: None, url: "ws://example.com/pruned".to_string(), http_client: None, active_requests: 0.into(), frontend_requests: 0.into(), internal_requests: 0.into(), provider_state: AsyncRwLock::new(ProviderState::Ready(Arc::new(Web3Provider::Mock))), hard_limit: None, soft_limit: 3_000, automatic_block_limit: false, backup: false, block_data_limit: 64.into(), tier: 1, head_block: RwLock::new(Some(head_block.clone())), open_request_handle_metrics: Arc::new(Default::default()), }; let archive_rpc = Web3Connection { name: "archive".to_string(), db_conn: None, display_name: None, url: "ws://example.com/archive".to_string(), http_client: None, active_requests: 0.into(), frontend_requests: 0.into(), internal_requests: 0.into(), provider_state: AsyncRwLock::new(ProviderState::Ready(Arc::new(Web3Provider::Mock))), hard_limit: None, soft_limit: 1_000, automatic_block_limit: false, backup: false, block_data_limit: u64::MAX.into(), tier: 2, head_block: RwLock::new(Some(head_block.clone())), open_request_handle_metrics: Arc::new(Default::default()), }; assert!(pruned_rpc.has_block_data(&head_block.number())); assert!(archive_rpc.has_block_data(&head_block.number())); assert!(!pruned_rpc.has_block_data(&1.into())); assert!(archive_rpc.has_block_data(&1.into())); let pruned_rpc = Arc::new(pruned_rpc); let archive_rpc = Arc::new(archive_rpc); let conns = HashMap::from([ (pruned_rpc.name.clone(), pruned_rpc.clone()), (archive_rpc.name.clone(), archive_rpc.clone()), ]); let (watch_consensus_connections_sender, _) = watch::channel(Default::default()); // TODO: make a Web3Connections::new let conns = Web3Connections { conns, watch_consensus_head_receiver: None, watch_consensus_connections_sender, pending_transactions: Cache::builder() .max_capacity(10) .build_with_hasher(hashbrown::hash_map::DefaultHashBuilder::default()), block_hashes: Cache::builder() .max_capacity(10) .build_with_hasher(hashbrown::hash_map::DefaultHashBuilder::default()), block_numbers: Cache::builder() .max_capacity(10) .build_with_hasher(hashbrown::hash_map::DefaultHashBuilder::default()), min_head_rpcs: 1, min_sum_soft_limit: 3_000, }; let authorization = Arc::new(Authorization::internal(None).unwrap()); let (head_block_sender, _head_block_receiver) = watch::channel::(Default::default()); let mut connection_heads = ConsensusFinder::default(); conns .process_block_from_rpc( &authorization, &mut connection_heads, Some(head_block.clone()), pruned_rpc.clone(), &head_block_sender, &None, ) .await .unwrap(); conns .process_block_from_rpc( &authorization, &mut connection_heads, Some(head_block.clone()), archive_rpc.clone(), &head_block_sender, &None, ) .await .unwrap(); assert_eq!(conns.num_synced_rpcs(), 2); // best_synced_backend_connection requires servers to be synced with the head block let best_head_server = conns .best_consensus_head_connection(&authorization, None, &[], Some(&head_block.number())) .await; assert!(matches!( best_head_server.unwrap(), OpenRequestResult::Handle(_) )); let best_archive_server = conns .best_consensus_head_connection(&authorization, None, &[], Some(&1.into())) .await; match best_archive_server { Ok(OpenRequestResult::Handle(x)) => { assert_eq!(x.clone_connection().name, "archive".to_string()) } x => { error!("unexpected result: {:?}", x); } } } }