dynomite/net/server.rs
1//! SERVER-role connection driver.
2//!
3//! The SERVER role holds an outbound connection to the backend
4//! datastore (RESP or memcache). The driver pulls requests off
5//! the connection's in-queue, encodes them onto the wire, and
6//! parses response bytes back into [`Msg`]s that it dispatches to
7//! the originating client.
8//!
9//! The driver is transport-agnostic and is wired to the cluster's
10//! [`Dispatcher`] so client / server connections form a complete
11//! request-response pipeline.
12//!
13//! [`Dispatcher`]: crate::net::Dispatcher
14//! [`Msg`]: crate::msg::Msg
15
16use tokio::io::{AsyncReadExt, AsyncWriteExt};
17use tokio::sync::mpsc;
18use tracing::Instrument as _;
19
20use crate::conf::DataStore;
21use crate::core::types::MsgId;
22use crate::io::reactor::ConnRole;
23use crate::msg::{Msg, MsgParseResult, MsgType};
24use crate::net::conn::Conn;
25use crate::net::dispatcher::OutboundEnvelope;
26use crate::net::NetError;
27use crate::proto::dnode::DmsgType;
28
29/// Outbound server-side connection driver.
30///
31/// The struct owns the transport-bound [`Conn`] plus the receiving
32/// half of the request channel that feeds it.
33pub struct ServerConn {
34 conn: Conn,
35 requests: mpsc::Receiver<OutboundRequest>,
36 data_store: DataStore,
37 pending_responses: std::collections::VecDeque<(MsgId, tracing::Span, Option<u32>)>,
38}
39
40/// Envelope sent into the server driver.
41///
42/// The driver writes `bytes` to the transport then awaits a
43/// response, which it forwards as an [`OutboundEnvelope`] on
44/// `responder` along with `req_id`.
45///
46/// `span` carries the originating client request's
47/// [`tracing::Span`] across the mpsc channel boundary so the
48/// receiving task's work nests under the originating client
49/// span when distributed tracing is enabled. The default value
50/// is [`tracing::Span::none`], which has no overhead when no
51/// subscriber is installed.
52///
53/// `ty` selects the dnode message-type header emitted on the
54/// peer plane. Data-plane callers leave it at
55/// [`DmsgType::Req`]; the gossip task uses
56/// [`DmsgType::GossipSyn`] / [`DmsgType::GossipShutdown`] for
57/// fire-and-forget control frames whose `responder` is never
58/// signalled.
59#[derive(Debug)]
60pub struct OutboundRequest {
61 /// Wire bytes already encoded by the dispatcher.
62 pub bytes: Vec<u8>,
63 /// Request id for response tagging.
64 pub req_id: MsgId,
65 /// Channel the driver pushes the parsed response onto.
66 pub responder: mpsc::Sender<OutboundEnvelope>,
67 /// Originating client request span; entered by the receiver
68 /// to nest backend / peer work under the request tree.
69 pub span: tracing::Span,
70 /// dnode message-type header emitted by the peer driver.
71 /// Defaults to [`DmsgType::Req`] for data-plane requests.
72 pub ty: DmsgType,
73 /// Index of the target peer the dispatcher is forwarding the
74 /// request to. The local backend driver and dnode-peer driver
75 /// stamp this onto the [`OutboundEnvelope`] they produce so
76 /// the reply coalescer can identify the responding replica.
77 /// `None` is used for single-target paths where the responder
78 /// already implies the source.
79 pub target_peer_idx: Option<u32>,
80}
81
82impl ServerConn {
83 /// Wrap an outbound [`Conn`] with the given request-channel
84 /// receiver and data-store flavor.
85 ///
86 /// # Examples
87 ///
88 /// ```no_run
89 /// use dynomite::conf::DataStore;
90 /// use dynomite::io::reactor::{ConnRole, TcpTransport};
91 /// use dynomite::net::{Conn, ServerConn};
92 /// use tokio::sync::mpsc;
93 /// # tokio::runtime::Builder::new_current_thread().enable_all().build().unwrap().block_on(async {
94 /// let s = tokio::net::TcpStream::connect("127.0.0.1:6379").await.unwrap();
95 /// let conn = Conn::new(Box::new(TcpTransport::new(s, ConnRole::Server)), ConnRole::Server);
96 /// let (_tx, rx) = mpsc::channel(8);
97 /// let _ = ServerConn::new(conn, rx, DataStore::Valkey);
98 /// # });
99 /// ```
100 #[must_use]
101 pub fn new(
102 conn: Conn,
103 requests: mpsc::Receiver<OutboundRequest>,
104 data_store: DataStore,
105 ) -> Self {
106 debug_assert!(matches!(
107 conn.role(),
108 ConnRole::Server | ConnRole::DnodePeerServer
109 ));
110 Self {
111 conn,
112 requests,
113 data_store,
114 pending_responses: std::collections::VecDeque::new(),
115 }
116 }
117
118 /// Borrow the underlying connection.
119 #[must_use]
120 pub fn conn(&self) -> &Conn {
121 &self.conn
122 }
123
124 /// Mutably borrow the underlying connection.
125 pub fn conn_mut(&mut self) -> &mut Conn {
126 &mut self.conn
127 }
128
129 /// Drive the server FSM until either the request channel is
130 /// closed or the transport hits EOF / error.
131 ///
132 /// # Errors
133 /// Surfaces transport- and protocol-level errors.
134 pub async fn run(mut self) -> Result<(), NetError> {
135 let mut read_buf = vec![0u8; 4096];
136 let mut accumulated = Vec::<u8>::new();
137 let mut pending_responder: Option<mpsc::Sender<OutboundEnvelope>> = None;
138
139 loop {
140 if self.conn.is_eof() && self.pending_responses.is_empty() {
141 self.conn.set_done();
142 return Ok(());
143 }
144
145 tokio::select! {
146 res = self.requests.recv() => {
147 let Some(out_req) = res else {
148 // Channel closed; drain pending responses and exit.
149 if self.pending_responses.is_empty() {
150 self.conn.set_done();
151 return Ok(());
152 }
153 continue;
154 };
155 let send_span = tracing::info_span!(
156 parent: &out_req.span,
157 "backend.send",
158 req_id = out_req.req_id,
159 bytes = out_req.bytes.len(),
160 );
161 let req_span = out_req.span.clone();
162 let req_bytes = out_req.bytes;
163 let transport = self.conn.transport_mut().ok_or(NetError::Closed)?;
164 let write_res = async { transport.write_all(&req_bytes).await }
165 .instrument(send_span)
166 .await;
167 write_res?;
168 self.conn.record_send(req_bytes.len());
169 self.pending_responses
170 .push_back((out_req.req_id, req_span, out_req.target_peer_idx));
171 pending_responder = Some(out_req.responder);
172 }
173 read_res = async {
174 if let Some(t) = self.conn.transport_mut() {
175 t.read(&mut read_buf).await
176 } else {
177 Ok(0)
178 }
179 } => {
180 let n = read_res?;
181 if n == 0 {
182 self.conn.set_eof();
183 continue;
184 }
185 self.conn.record_recv(n);
186 accumulated.extend_from_slice(&read_buf[..n]);
187 self.drive_response_parser(&mut accumulated, &mut pending_responder).await?;
188 }
189 }
190 }
191 }
192
193 async fn drive_response_parser(
194 &mut self,
195 accumulated: &mut Vec<u8>,
196 responder: &mut Option<mpsc::Sender<OutboundEnvelope>>,
197 ) -> Result<(), NetError> {
198 use crate::proto::memcache::memcache_parse_rsp;
199 use crate::proto::redis::redis_parse_rsp;
200
201 while !accumulated.is_empty() {
202 let head_span = self
203 .pending_responses
204 .front()
205 .map_or_else(tracing::Span::current, |(_, s, _)| s.clone());
206 let id = self.pending_responses.front().map_or(0, |(i, _, _)| *i);
207 let mut msg = Msg::new(id, MsgType::Unknown, false);
208 let result = match self.data_store {
209 DataStore::Valkey | DataStore::Dyniak => redis_parse_rsp(&mut msg, accumulated),
210 DataStore::Memcache => memcache_parse_rsp(&mut msg, accumulated),
211 };
212 match result {
213 MsgParseResult::Ok => {
214 let consumed = msg.parser_pos();
215 if consumed == 0 {
216 return Err(NetError::Parse("server parser stalled".into()));
217 }
218 let bytes = accumulated[..consumed].to_vec();
219 accumulated.drain(0..consumed);
220 let (req_id, req_span, source_peer_idx) = self
221 .pending_responses
222 .pop_front()
223 .unwrap_or((0, head_span, None));
224 let parse_span = tracing::info_span!(
225 parent: &req_span,
226 "backend.parse",
227 req_id,
228 bytes = consumed,
229 );
230 let env = parse_span.in_scope(|| {
231 let mut rsp = msg;
232 let pool = self.conn.mbuf_pool().clone();
233 let mut buf = pool.get();
234 buf.recv(&bytes);
235 rsp.mbufs_mut().push_back(buf);
236 rsp.recompute_mlen();
237 OutboundEnvelope {
238 req_id,
239 rsp,
240 span: req_span,
241 source_peer_idx,
242 }
243 });
244 if let Some(sender) = responder.as_ref() {
245 let _ = sender.send(env).await;
246 }
247 }
248 MsgParseResult::Again => return Ok(()),
249 MsgParseResult::Repair | MsgParseResult::Noop | MsgParseResult::Fragment => {
250 let consumed = msg.parser_pos();
251 if consumed > 0 {
252 accumulated.drain(0..consumed);
253 } else {
254 return Ok(());
255 }
256 }
257 MsgParseResult::Error | MsgParseResult::OomError | MsgParseResult::DynoConfig => {
258 return Err(NetError::Parse(format!("{result:?}")));
259 }
260 }
261 }
262 Ok(())
263 }
264}
265
266#[cfg(test)]
267mod tests {
268 use super::*;
269 use crate::io::reactor::TcpTransport;
270 use tokio::net::{TcpListener, TcpStream};
271
272 #[tokio::test]
273 async fn build_server_conn() {
274 let listener = TcpListener::bind("127.0.0.1:0").await.unwrap();
275 let addr = listener.local_addr().unwrap();
276 let _accept = tokio::spawn(async move {
277 let (s, _) = listener.accept().await.unwrap();
278 drop(s);
279 });
280 let s = TcpStream::connect(addr).await.unwrap();
281 let conn = Conn::new(
282 Box::new(TcpTransport::new(s, ConnRole::Server)),
283 ConnRole::Server,
284 );
285 let (_tx, rx) = mpsc::channel(1);
286 let server = ServerConn::new(conn, rx, DataStore::Valkey);
287 assert_eq!(server.conn().role(), ConnRole::Server);
288 }
289}