Refactoring: rename config files, make modifications less invasive
This commit is contained in:
parent
d9a35359bf
commit
dc8d0496cc
5 changed files with 155 additions and 141 deletions
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@ -45,8 +45,8 @@ bind_addr = "0.0.0.0:$((3920+$count))"
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root_domain = ".web.garage.localhost"
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index = "index.html"
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[admin_api]
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bind_addr = "0.0.0.0:$((9900+$count))"
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[admin]
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api_bind_addr = "0.0.0.0:$((9900+$count))"
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EOF
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echo -en "$LABEL configuration written to $CONF_PATH\n"
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@ -47,7 +47,7 @@ pub async fn run_server(config_file: PathBuf) -> Result<(), Error> {
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let garage = Garage::new(config.clone(), db, background);
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info!("Initialize tracing...");
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if let Some(export_to) = config.admin_api.otlp_export_traces_to {
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if let Some(export_to) = config.admin.trace_sink {
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init_tracing(&export_to, garage.system.id)?;
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}
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@ -70,7 +70,7 @@ pub async fn run_server(config_file: PathBuf) -> Result<(), Error> {
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info!("Configure and run admin web server...");
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let admin_server = tokio::spawn(
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admin_server_init.run(config.admin_api.bind_addr, wait_from(watch_cancel.clone())),
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admin_server_init.run(config.admin.api_bind_addr, wait_from(watch_cancel.clone())),
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);
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// Stuff runs
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@ -66,8 +66,8 @@ bind_addr = "127.0.0.1:{web_port}"
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root_domain = ".web.garage"
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index = "index.html"
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[admin_api]
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bind_addr = "127.0.0.1:{admin_port}"
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[admin]
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api_bind_addr = "127.0.0.1:{admin_port}"
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"#,
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path = path.display(),
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secret = GARAGE_TEST_SECRET,
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@ -238,154 +238,168 @@ impl RpcHelper {
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span.set_attribute(KeyValue::new("to", format!("{:?}", to)));
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span.set_attribute(KeyValue::new("quorum", quorum as i64));
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async {
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let msg = Arc::new(msg);
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self.try_call_many_internal(endpoint, to, msg, strategy, quorum)
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.with_context(Context::current_with_span(span))
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.await
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}
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// Build future for each request
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// They are not started now: they are added below in a FuturesUnordered
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// object that will take care of polling them (see below)
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let requests = to.iter().cloned().map(|to| {
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let self2 = self.clone();
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let msg = msg.clone();
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let endpoint2 = endpoint.clone();
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(to, async move {
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self2.call_arc(&endpoint2, to, msg, strategy).await
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async fn try_call_many_internal<M, H, S>(
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&self,
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endpoint: &Arc<Endpoint<M, H>>,
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to: &[Uuid],
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msg: M,
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strategy: RequestStrategy,
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quorum: usize,
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) -> Result<Vec<S>, Error>
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where
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M: Rpc<Response = Result<S, Error>> + 'static,
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H: EndpointHandler<M> + 'static,
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S: Send + 'static,
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{
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let msg = Arc::new(msg);
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// Build future for each request
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// They are not started now: they are added below in a FuturesUnordered
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// object that will take care of polling them (see below)
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let requests = to.iter().cloned().map(|to| {
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let self2 = self.clone();
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let msg = msg.clone();
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let endpoint2 = endpoint.clone();
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(to, async move {
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self2.call_arc(&endpoint2, to, msg, strategy).await
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})
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});
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// Vectors in which success results and errors will be collected
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let mut successes = vec![];
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let mut errors = vec![];
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if strategy.rs_interrupt_after_quorum {
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// Case 1: once quorum is reached, other requests don't matter.
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// What we do here is only send the required number of requests
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// to reach a quorum, priorizing nodes with the lowest latency.
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// When there are errors, we start new requests to compensate.
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// Retrieve some status variables that we will use to sort requests
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let peer_list = self.0.fullmesh.get_peer_list();
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let ring: Arc<Ring> = self.0.ring.borrow().clone();
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let our_zone = match ring.layout.node_role(&self.0.our_node_id) {
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Some(pc) => &pc.zone,
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None => "",
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};
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// Augment requests with some information used to sort them.
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// The tuples are as follows:
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// (is another node?, is another zone?, latency, node ID, request future)
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// We store all of these tuples in a vec that we can sort.
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// By sorting this vec, we priorize ourself, then nodes in the same zone,
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// and within a same zone we priorize nodes with the lowest latency.
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let mut requests = requests
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.map(|(to, fut)| {
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let peer_zone = match ring.layout.node_role(&to) {
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Some(pc) => &pc.zone,
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None => "",
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};
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let peer_avg_ping = peer_list
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.iter()
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.find(|x| x.id.as_ref() == to.as_slice())
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.map(|pi| pi.avg_ping)
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.flatten()
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.unwrap_or_else(|| Duration::from_secs(1));
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(
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to != self.0.our_node_id,
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peer_zone != our_zone,
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peer_avg_ping,
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to,
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fut,
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)
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})
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});
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.collect::<Vec<_>>();
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// Vectors in which success results and errors will be collected
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let mut successes = vec![];
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let mut errors = vec![];
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// Sort requests by (priorize ourself, priorize same zone, priorize low latency)
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requests
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.sort_by_key(|(diffnode, diffzone, ping, _to, _fut)| (*diffnode, *diffzone, *ping));
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if strategy.rs_interrupt_after_quorum {
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// Case 1: once quorum is reached, other requests don't matter.
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// What we do here is only send the required number of requests
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// to reach a quorum, priorizing nodes with the lowest latency.
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// When there are errors, we start new requests to compensate.
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// Make an iterator to take requests in their sorted order
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let mut requests = requests.into_iter();
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// Retrieve some status variables that we will use to sort requests
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let peer_list = self.0.fullmesh.get_peer_list();
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let ring: Arc<Ring> = self.0.ring.borrow().clone();
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let our_zone = match ring.layout.node_role(&self.0.our_node_id) {
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Some(pc) => &pc.zone,
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None => "",
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};
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// resp_stream will contain all of the requests that are currently in flight.
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// (for the moment none, they will be added in the loop below)
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let mut resp_stream = FuturesUnordered::new();
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// Augment requests with some information used to sort them.
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// The tuples are as follows:
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// (is another node?, is another zone?, latency, node ID, request future)
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// We store all of these tuples in a vec that we can sort.
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// By sorting this vec, we priorize ourself, then nodes in the same zone,
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// and within a same zone we priorize nodes with the lowest latency.
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let mut requests = requests
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.map(|(to, fut)| {
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let peer_zone = match ring.layout.node_role(&to) {
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Some(pc) => &pc.zone,
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None => "",
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};
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let peer_avg_ping = peer_list
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.iter()
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.find(|x| x.id.as_ref() == to.as_slice())
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.map(|pi| pi.avg_ping)
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.flatten()
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.unwrap_or_else(|| Duration::from_secs(1));
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(
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to != self.0.our_node_id,
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peer_zone != our_zone,
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peer_avg_ping,
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to,
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fut,
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)
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})
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.collect::<Vec<_>>();
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// Sort requests by (priorize ourself, priorize same zone, priorize low latency)
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requests.sort_by_key(|(diffnode, diffzone, ping, _to, _fut)| {
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(*diffnode, *diffzone, *ping)
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});
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// Make an iterator to take requests in their sorted order
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let mut requests = requests.into_iter();
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// resp_stream will contain all of the requests that are currently in flight.
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// (for the moment none, they will be added in the loop below)
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let mut resp_stream = FuturesUnordered::new();
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// Do some requests and collect results
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'request_loop: while successes.len() < quorum {
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// If the current set of requests that are running is not enough to possibly
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// reach quorum, start some new requests.
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while successes.len() + resp_stream.len() < quorum {
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if let Some((_, _, _, req_to, fut)) = requests.next() {
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let span = tracer.start(format!("RPC to {:?}", req_to));
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resp_stream.push(tokio::spawn(
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fut.with_context(Context::current_with_span(span)),
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));
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} else {
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// If we have no request to add, we know that we won't ever
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// reach quorum: bail out now.
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break 'request_loop;
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}
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}
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assert!(!resp_stream.is_empty()); // because of loop invariants
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// Wait for one request to terminate
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match resp_stream.next().await.unwrap().unwrap() {
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Ok(msg) => {
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successes.push(msg);
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}
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Err(e) => {
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errors.push(e);
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}
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// Do some requests and collect results
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'request_loop: while successes.len() < quorum {
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// If the current set of requests that are running is not enough to possibly
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// reach quorum, start some new requests.
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while successes.len() + resp_stream.len() < quorum {
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if let Some((_, _, _, req_to, fut)) = requests.next() {
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let tracer = opentelemetry::global::tracer("garage");
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let span = tracer.start(format!("RPC to {:?}", req_to));
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resp_stream.push(tokio::spawn(
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fut.with_context(Context::current_with_span(span)),
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));
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} else {
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// If we have no request to add, we know that we won't ever
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// reach quorum: bail out now.
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break 'request_loop;
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}
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}
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} else {
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// Case 2: all of the requests need to be sent in all cases,
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// and need to terminate. (this is the case for writes that
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// must be spread to n nodes)
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// Just start all the requests in parallel and return as soon
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// as the quorum is reached.
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let mut resp_stream = requests
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.map(|(_, fut)| fut)
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.collect::<FuturesUnordered<_>>();
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assert!(!resp_stream.is_empty()); // because of loop invariants
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while let Some(resp) = resp_stream.next().await {
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match resp {
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Ok(msg) => {
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successes.push(msg);
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if successes.len() >= quorum {
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break;
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}
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}
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Err(e) => {
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errors.push(e);
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}
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// Wait for one request to terminate
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match resp_stream.next().await.unwrap().unwrap() {
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Ok(msg) => {
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successes.push(msg);
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}
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Err(e) => {
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errors.push(e);
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}
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}
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}
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} else {
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// Case 2: all of the requests need to be sent in all cases,
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// and need to terminate. (this is the case for writes that
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// must be spread to n nodes)
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// Just start all the requests in parallel and return as soon
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// as the quorum is reached.
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let mut resp_stream = requests
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.map(|(_, fut)| fut)
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.collect::<FuturesUnordered<_>>();
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if !resp_stream.is_empty() {
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// Continue remaining requests in background.
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// Continue the remaining requests immediately using tokio::spawn
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// but enqueue a task in the background runner
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// to ensure that the process won't exit until the requests are done
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// (if we had just enqueued the resp_stream.collect directly in the background runner,
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// the requests might have been put on hold in the background runner's queue,
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// in which case they might timeout or otherwise fail)
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let wait_finished_fut = tokio::spawn(async move {
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resp_stream.collect::<Vec<Result<_, _>>>().await;
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});
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self.0.background.spawn(wait_finished_fut.map(|_| Ok(())));
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while let Some(resp) = resp_stream.next().await {
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match resp {
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Ok(msg) => {
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successes.push(msg);
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if successes.len() >= quorum {
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break;
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}
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}
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Err(e) => {
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errors.push(e);
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}
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}
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}
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if successes.len() >= quorum {
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Ok(successes)
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} else {
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let errors = errors.iter().map(|e| format!("{}", e)).collect::<Vec<_>>();
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Err(Error::Quorum(quorum, successes.len(), to.len(), errors))
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if !resp_stream.is_empty() {
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// Continue remaining requests in background.
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// Continue the remaining requests immediately using tokio::spawn
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// but enqueue a task in the background runner
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// to ensure that the process won't exit until the requests are done
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// (if we had just enqueued the resp_stream.collect directly in the background runner,
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// the requests might have been put on hold in the background runner's queue,
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// in which case they might timeout or otherwise fail)
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let wait_finished_fut = tokio::spawn(async move {
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resp_stream.collect::<Vec<Result<_, _>>>().await;
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});
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self.0.background.spawn(wait_finished_fut.map(|_| Ok(())));
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}
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}
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.with_context(Context::current_with_span(span))
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.await
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if successes.len() >= quorum {
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Ok(successes)
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} else {
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let errors = errors.iter().map(|e| format!("{}", e)).collect::<Vec<_>>();
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Err(Error::Quorum(quorum, successes.len(), to.len(), errors))
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}
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}
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}
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@ -75,7 +75,7 @@ pub struct Config {
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pub s3_web: WebConfig,
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/// Configuration for the admin API endpoint
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pub admin_api: AdminConfig,
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pub admin: AdminConfig,
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}
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/// Configuration for S3 api
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@ -103,9 +103,9 @@ pub struct WebConfig {
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#[derive(Deserialize, Debug, Clone)]
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pub struct AdminConfig {
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/// Address and port to bind for admin API serving
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pub bind_addr: SocketAddr,
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pub api_bind_addr: SocketAddr,
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/// OTLP server to where to export traces
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pub otlp_export_traces_to: Option<String>,
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pub trace_sink: Option<String>,
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}
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fn default_sled_cache_capacity() -> u64 {
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