forked from Deuxfleurs/garage
664 lines
19 KiB
Rust
664 lines
19 KiB
Rust
//! Contain structs related to making RPCs
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use std::collections::HashMap;
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use std::sync::{Arc, RwLock};
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use std::time::Duration;
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use futures::future::join_all;
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use futures::stream::futures_unordered::FuturesUnordered;
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use futures::stream::StreamExt;
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use tokio::select;
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use opentelemetry::KeyValue;
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use opentelemetry::{
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trace::{FutureExt as OtelFutureExt, Span, TraceContextExt, Tracer},
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Context,
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};
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pub use garage_net::endpoint::{Endpoint, EndpointHandler, StreamingEndpointHandler};
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pub use garage_net::message::{
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IntoReq, Message as Rpc, OrderTag, Req, RequestPriority, Resp, PRIO_BACKGROUND, PRIO_HIGH,
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PRIO_NORMAL, PRIO_SECONDARY,
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};
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use garage_net::peering::PeeringManager;
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pub use garage_net::{self, NetApp, NodeID};
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use garage_util::data::*;
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use garage_util::error::Error;
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use garage_util::metrics::RecordDuration;
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use crate::layout::{LayoutHelper, LayoutVersion};
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use crate::metrics::RpcMetrics;
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// Default RPC timeout = 5 minutes
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const DEFAULT_TIMEOUT: Duration = Duration::from_secs(300);
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/// Strategy to apply when making RPC
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#[derive(Copy, Clone)]
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pub struct RequestStrategy {
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/// Min number of response to consider the request successful
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rs_quorum: Option<usize>,
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/// Send all requests at once
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rs_send_all_at_once: Option<bool>,
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/// Request priority
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rs_priority: RequestPriority,
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/// Custom timeout for this request
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rs_timeout: Timeout,
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}
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#[derive(Copy, Clone)]
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enum Timeout {
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None,
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Default,
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Custom(Duration),
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}
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impl RequestStrategy {
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/// Create a RequestStrategy with default timeout and not interrupting when quorum reached
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pub fn with_priority(prio: RequestPriority) -> Self {
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RequestStrategy {
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rs_quorum: None,
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rs_send_all_at_once: None,
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rs_priority: prio,
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rs_timeout: Timeout::Default,
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}
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}
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/// Set quorum to be reached for request
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pub fn with_quorum(mut self, quorum: usize) -> Self {
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self.rs_quorum = Some(quorum);
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self
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}
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/// Set quorum to be reached for request
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pub fn send_all_at_once(mut self, value: bool) -> Self {
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self.rs_send_all_at_once = Some(value);
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self
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}
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/// Deactivate timeout for this request
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pub fn without_timeout(mut self) -> Self {
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self.rs_timeout = Timeout::None;
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self
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}
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/// Set custom timeout for this request
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pub fn with_custom_timeout(mut self, timeout: Duration) -> Self {
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self.rs_timeout = Timeout::Custom(timeout);
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self
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}
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}
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#[derive(Clone)]
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pub struct RpcHelper(Arc<RpcHelperInner>);
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struct RpcHelperInner {
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our_node_id: Uuid,
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peering: Arc<PeeringManager>,
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layout: Arc<RwLock<LayoutHelper>>,
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metrics: RpcMetrics,
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rpc_timeout: Duration,
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}
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impl RpcHelper {
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pub(crate) fn new(
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our_node_id: Uuid,
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peering: Arc<PeeringManager>,
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layout: Arc<RwLock<LayoutHelper>>,
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rpc_timeout: Option<Duration>,
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) -> Self {
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let metrics = RpcMetrics::new();
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Self(Arc::new(RpcHelperInner {
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our_node_id,
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peering,
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layout,
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metrics,
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rpc_timeout: rpc_timeout.unwrap_or(DEFAULT_TIMEOUT),
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}))
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}
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pub fn rpc_timeout(&self) -> Duration {
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self.0.rpc_timeout
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}
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pub async fn call<M, N, H, S>(
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&self,
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endpoint: &Endpoint<M, H>,
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to: Uuid,
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msg: N,
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strat: RequestStrategy,
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) -> Result<S, Error>
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where
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M: Rpc<Response = Result<S, Error>>,
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N: IntoReq<M> + Send,
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H: StreamingEndpointHandler<M>,
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{
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let tracer = opentelemetry::global::tracer("garage");
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let span_name = format!("RPC [{}] to {:?}", endpoint.path(), to);
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let mut span = tracer.start(span_name);
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span.set_attribute(KeyValue::new("from", format!("{:?}", self.0.our_node_id)));
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span.set_attribute(KeyValue::new("to", format!("{:?}", to)));
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let metric_tags = [
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KeyValue::new("rpc_endpoint", endpoint.path().to_string()),
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KeyValue::new("from", format!("{:?}", self.0.our_node_id)),
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KeyValue::new("to", format!("{:?}", to)),
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];
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self.0.metrics.rpc_counter.add(1, &metric_tags);
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let node_id = to.into();
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let rpc_call = endpoint
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.call_streaming(&node_id, msg, strat.rs_priority)
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.with_context(Context::current_with_span(span))
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.record_duration(&self.0.metrics.rpc_duration, &metric_tags);
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let timeout = async {
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match strat.rs_timeout {
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Timeout::None => futures::future::pending().await,
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Timeout::Default => tokio::time::sleep(self.0.rpc_timeout).await,
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Timeout::Custom(t) => tokio::time::sleep(t).await,
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}
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};
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select! {
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res = rpc_call => {
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if res.is_err() {
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self.0.metrics.rpc_netapp_error_counter.add(1, &metric_tags);
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}
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let res = res?.into_msg();
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if res.is_err() {
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self.0.metrics.rpc_garage_error_counter.add(1, &metric_tags);
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}
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Ok(res?)
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}
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() = timeout => {
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self.0.metrics.rpc_timeout_counter.add(1, &metric_tags);
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Err(Error::Timeout)
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}
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}
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}
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pub async fn call_many<M, N, H, S>(
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&self,
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endpoint: &Endpoint<M, H>,
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to: &[Uuid],
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msg: N,
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strat: RequestStrategy,
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) -> Result<Vec<(Uuid, Result<S, Error>)>, Error>
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where
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M: Rpc<Response = Result<S, Error>>,
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N: IntoReq<M>,
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H: StreamingEndpointHandler<M>,
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{
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let tracer = opentelemetry::global::tracer("garage");
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let span_name = format!("RPC [{}] call_many {} nodes", endpoint.path(), to.len());
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let span = tracer.start(span_name);
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let msg = msg.into_req().map_err(garage_net::error::Error::from)?;
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let resps = join_all(
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to.iter()
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.map(|to| self.call(endpoint, *to, msg.clone(), strat)),
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)
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.with_context(Context::current_with_span(span))
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.await;
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Ok(to
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.iter()
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.cloned()
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.zip(resps.into_iter())
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.collect::<Vec<_>>())
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}
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pub async fn broadcast<M, N, H, S>(
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&self,
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endpoint: &Endpoint<M, H>,
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msg: N,
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strat: RequestStrategy,
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) -> Result<Vec<(Uuid, Result<S, Error>)>, Error>
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where
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M: Rpc<Response = Result<S, Error>>,
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N: IntoReq<M>,
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H: StreamingEndpointHandler<M>,
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{
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let to = self
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.0
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.peering
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.get_peer_list()
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.iter()
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.map(|p| p.id.into())
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.collect::<Vec<_>>();
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self.call_many(endpoint, &to[..], msg, strat).await
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}
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/// Make a RPC call to multiple servers, returning either a Vec of responses,
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/// or an error if quorum could not be reached due to too many errors
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///
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/// If RequestStrategy has send_all_at_once set, then all requests will be
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/// sent at once, and `try_call_many` will return as soon as a quorum of
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/// responses is achieved, dropping and cancelling the remaining requests.
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///
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/// Otherwise, `quorum` requests will be sent at the same time, and if an
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/// error response is received, a new request will be sent to replace it.
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/// The ordering of nodes to which requests are sent is determined by
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/// the `RpcHelper::request_order` function, which takes into account
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/// parameters such as node zones and measured ping values.
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///
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/// In both cases, the basic contract of this function is that even in the
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/// absence of failures, the RPC call might not be driven to completion
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/// on all of the specified nodes. It is therefore unfit for broadcast
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/// write operations where we expect all nodes to successfully store
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/// the written date.
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pub async fn try_call_many<M, N, 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: N,
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strategy: RequestStrategy,
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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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N: IntoReq<M>,
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H: StreamingEndpointHandler<M> + 'static,
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S: Send + 'static,
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{
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let quorum = strategy.rs_quorum.unwrap_or(to.len());
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let tracer = opentelemetry::global::tracer("garage");
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let span_name = format!(
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"RPC [{}] try_call_many (quorum {}/{})",
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endpoint.path(),
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quorum,
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to.len()
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);
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let mut span = tracer.start(span_name);
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span.set_attribute(KeyValue::new("from", format!("{:?}", self.0.our_node_id)));
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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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self.try_call_many_inner(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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async fn try_call_many_inner<M, N, 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: N,
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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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N: IntoReq<M>,
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H: StreamingEndpointHandler<M> + 'static,
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S: Send + 'static,
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{
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// 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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// TODO: this could be made more aggressive, e.g. if after 2x the
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// average ping of a given request, the response is not yet received,
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// preemptively send an additional request to any remaining nodes.
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// Reorder requests to priorize closeness / low latency
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let request_order =
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self.request_order(&self.0.layout.read().unwrap().current(), to.iter().copied());
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let send_all_at_once = strategy.rs_send_all_at_once.unwrap_or(false);
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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 msg = msg.into_req().map_err(garage_net::error::Error::from)?;
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let mut requests = request_order.into_iter().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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async move { self2.call(&endpoint2, to, msg, strategy).await }
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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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// 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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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 send_all_at_once || successes.len() + resp_stream.len() < quorum {
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if let Some(fut) = requests.next() {
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resp_stream.push(fut)
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} else {
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break;
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}
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}
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if successes.len() + resp_stream.len() < quorum {
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// We know we won't ever reach quorum
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break;
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}
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// Wait for one request to terminate
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match resp_stream.next().await.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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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(
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quorum,
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None,
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successes.len(),
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to.len(),
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errors,
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))
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}
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}
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/// Make a RPC call to multiple servers, returning either a Vec of responses,
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/// or an error if quorum could not be reached due to too many errors
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///
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/// Contrary to try_call_many, this fuction is especially made for broadcast
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/// write operations. In particular:
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///
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/// - The request are sent to all specified nodes as soon as `try_write_many_sets`
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/// is invoked.
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///
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/// - When `try_write_many_sets` returns, all remaining requests that haven't
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/// completed move to a background task so that they have a chance to
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/// complete successfully if there are no failures.
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///
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/// In addition, the nodes to which requests should be sent are divided in
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/// "quorum sets", and `try_write_many_sets` only returns once a quorum
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/// has been validated in each set. This is used in the case of cluster layout
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/// changes, where data has to be written both in the old layout and in the
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/// new one as long as all nodes have not successfully tranisitionned and
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/// moved all data to the new layout.
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pub async fn try_write_many_sets<M, N, H, S>(
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&self,
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endpoint: &Arc<Endpoint<M, H>>,
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to_sets: &[Vec<Uuid>],
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msg: N,
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strategy: RequestStrategy,
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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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N: IntoReq<M>,
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H: StreamingEndpointHandler<M> + 'static,
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S: Send + 'static,
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{
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let quorum = strategy
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.rs_quorum
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.expect("internal error: missing quorum value in try_write_many_sets");
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let tracer = opentelemetry::global::tracer("garage");
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let span_name = format!(
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"RPC [{}] try_write_many_sets (quorum {} in {} sets)",
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endpoint.path(),
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quorum,
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to_sets.len()
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);
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let mut span = tracer.start(span_name);
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span.set_attribute(KeyValue::new("from", format!("{:?}", self.0.our_node_id)));
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span.set_attribute(KeyValue::new("to", format!("{:?}", to_sets)));
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span.set_attribute(KeyValue::new("quorum", quorum as i64));
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self.try_write_many_sets_inner(endpoint, to_sets, 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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async fn try_write_many_sets_inner<M, N, H, S>(
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&self,
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endpoint: &Arc<Endpoint<M, H>>,
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to_sets: &[Vec<Uuid>],
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msg: N,
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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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N: IntoReq<M>,
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H: StreamingEndpointHandler<M> + 'static,
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S: Send + 'static,
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{
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// Peers may appear in many quorum sets. Here, build a list of peers,
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// mapping to the index of the quorum sets in which they appear.
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let mut result_tracker = QuorumSetResultTracker::new(to_sets, quorum);
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// Send one request to each peer of the quorum sets
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let msg = msg.into_req().map_err(garage_net::error::Error::from)?;
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let requests = result_tracker.nodes.keys().map(|peer| {
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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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let to = *peer;
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async move { (to, self2.call(&endpoint2, to, msg, strategy).await) }
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});
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let mut resp_stream = requests.collect::<FuturesUnordered<_>>();
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// Drive requests to completion
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while let Some((node, resp)) = resp_stream.next().await {
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// Store the response in the correct vector and increment the
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// appropriate counters
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result_tracker.register_result(node, resp);
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// If we have a quorum of ok in all quorum sets, then it's a success!
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if result_tracker.all_quorums_ok() {
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// Continue all other requets in background
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tokio::spawn(async move {
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resp_stream.collect::<Vec<(Uuid, Result<_, _>)>>().await;
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});
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return Ok(result_tracker.success_values());
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}
|
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|
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// If there is a quorum set for which too many errors were received,
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// we know it's impossible to get a quorum, so return immediately.
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if result_tracker.too_many_failures() {
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break;
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}
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}
|
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|
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// At this point, there is no quorum and we know that a quorum
|
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// will never be achieved. Currently, we drop all remaining requests.
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// Should we still move them to background so that they can continue
|
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// for non-failed nodes? Not doing so has no impact on correctness,
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// but it means that more cancellation messages will be sent. Idk.
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// (When an in-progress request future is dropped, Netapp automatically
|
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// sends a cancellation message to the remote node to inform it that
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// the result is no longer needed. In turn, if the remote node receives
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// the cancellation message in time, it interrupts the task of the
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// running request handler.)
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// Failure, could not get quorum
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Err(result_tracker.quorum_error())
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}
|
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|
|
// ---- functions not related to MAKING RPCs, but just determining to what nodes
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|
// they should be made and in which order ----
|
|
|
|
pub fn block_read_nodes_of(&self, position: &Hash, rpc_helper: &RpcHelper) -> Vec<Uuid> {
|
|
let layout = self.0.layout.read().unwrap();
|
|
|
|
let mut ret = Vec::with_capacity(12);
|
|
let ver_iter = layout
|
|
.versions()
|
|
.iter()
|
|
.rev()
|
|
.chain(layout.inner().old_versions.iter().rev());
|
|
for ver in ver_iter {
|
|
if ver.version > layout.sync_map_min() {
|
|
continue;
|
|
}
|
|
let nodes = ver.nodes_of(position, ver.replication_factor);
|
|
for node in rpc_helper.request_order(layout.current(), nodes) {
|
|
if !ret.contains(&node) {
|
|
ret.push(node);
|
|
}
|
|
}
|
|
}
|
|
ret
|
|
}
|
|
|
|
fn request_order(
|
|
&self,
|
|
layout: &LayoutVersion,
|
|
nodes: impl Iterator<Item = Uuid>,
|
|
) -> Vec<Uuid> {
|
|
// Retrieve some status variables that we will use to sort requests
|
|
let peer_list = self.0.peering.get_peer_list();
|
|
let our_zone = layout.get_node_zone(&self.0.our_node_id).unwrap_or("");
|
|
|
|
// Augment requests with some information used to sort them.
|
|
// The tuples are as follows:
|
|
// (is another node?, is another zone?, latency, node ID, request future)
|
|
// We store all of these tuples in a vec that we can sort.
|
|
// By sorting this vec, we priorize ourself, then nodes in the same zone,
|
|
// and within a same zone we priorize nodes with the lowest latency.
|
|
let mut nodes = nodes
|
|
.map(|to| {
|
|
let peer_zone = layout.get_node_zone(&to).unwrap_or("");
|
|
let peer_avg_ping = peer_list
|
|
.iter()
|
|
.find(|x| x.id.as_ref() == to.as_slice())
|
|
.and_then(|pi| pi.avg_ping)
|
|
.unwrap_or_else(|| Duration::from_secs(10));
|
|
(
|
|
to != self.0.our_node_id,
|
|
peer_zone != our_zone,
|
|
peer_avg_ping,
|
|
to,
|
|
)
|
|
})
|
|
.collect::<Vec<_>>();
|
|
|
|
// Sort requests by (priorize ourself, priorize same zone, priorize low latency)
|
|
nodes.sort_by_key(|(diffnode, diffzone, ping, _to)| (*diffnode, *diffzone, *ping));
|
|
|
|
nodes
|
|
.into_iter()
|
|
.map(|(_, _, _, to)| to)
|
|
.collect::<Vec<_>>()
|
|
}
|
|
}
|
|
|
|
// ------- utility for tracking successes/errors among write sets --------
|
|
|
|
pub struct QuorumSetResultTracker<S, E> {
|
|
/// The set of nodes and the index of the quorum sets they belong to
|
|
pub nodes: HashMap<Uuid, Vec<usize>>,
|
|
/// The quorum value, i.e. number of success responses to await in each set
|
|
pub quorum: usize,
|
|
|
|
/// The success responses received
|
|
pub successes: Vec<(Uuid, S)>,
|
|
/// The error responses received
|
|
pub failures: Vec<(Uuid, E)>,
|
|
|
|
/// The counters for successes in each set
|
|
pub success_counters: Box<[usize]>,
|
|
/// The counters for failures in each set
|
|
pub failure_counters: Box<[usize]>,
|
|
/// The total number of nodes in each set
|
|
pub set_lens: Box<[usize]>,
|
|
}
|
|
|
|
impl<S, E> QuorumSetResultTracker<S, E>
|
|
where
|
|
E: std::fmt::Display,
|
|
{
|
|
pub fn new<A>(sets: &[A], quorum: usize) -> Self
|
|
where
|
|
A: AsRef<[Uuid]>,
|
|
{
|
|
let mut nodes = HashMap::<Uuid, Vec<usize>>::new();
|
|
for (i, set) in sets.iter().enumerate() {
|
|
for node in set.as_ref().iter() {
|
|
nodes.entry(*node).or_default().push(i);
|
|
}
|
|
}
|
|
|
|
let num_nodes = nodes.len();
|
|
Self {
|
|
nodes,
|
|
quorum,
|
|
successes: Vec::with_capacity(num_nodes),
|
|
failures: vec![],
|
|
success_counters: vec![0; sets.len()].into_boxed_slice(),
|
|
failure_counters: vec![0; sets.len()].into_boxed_slice(),
|
|
set_lens: sets
|
|
.iter()
|
|
.map(|x| x.as_ref().len())
|
|
.collect::<Vec<_>>()
|
|
.into_boxed_slice(),
|
|
}
|
|
}
|
|
|
|
pub fn register_result(&mut self, node: Uuid, result: Result<S, E>) {
|
|
match result {
|
|
Ok(s) => {
|
|
self.successes.push((node, s));
|
|
for set in self.nodes.get(&node).unwrap().iter() {
|
|
self.success_counters[*set] += 1;
|
|
}
|
|
}
|
|
Err(e) => {
|
|
self.failures.push((node, e));
|
|
for set in self.nodes.get(&node).unwrap().iter() {
|
|
self.failure_counters[*set] += 1;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
pub fn all_quorums_ok(&self) -> bool {
|
|
self.success_counters
|
|
.iter()
|
|
.all(|ok_cnt| *ok_cnt >= self.quorum)
|
|
}
|
|
|
|
pub fn too_many_failures(&self) -> bool {
|
|
self.failure_counters
|
|
.iter()
|
|
.zip(self.set_lens.iter())
|
|
.any(|(err_cnt, set_len)| *err_cnt + self.quorum > *set_len)
|
|
}
|
|
|
|
pub fn success_values(self) -> Vec<S> {
|
|
self.successes
|
|
.into_iter()
|
|
.map(|(_, x)| x)
|
|
.collect::<Vec<_>>()
|
|
}
|
|
|
|
pub fn quorum_error(self) -> Error {
|
|
let errors = self
|
|
.failures
|
|
.iter()
|
|
.map(|(n, e)| format!("{:?}: {}", n, e))
|
|
.collect::<Vec<_>>();
|
|
Error::Quorum(
|
|
self.quorum,
|
|
Some(self.set_lens.len()),
|
|
self.successes.len(),
|
|
self.nodes.len(),
|
|
errors,
|
|
)
|
|
}
|
|
}
|