Line data Source code
1 : use std::time::{Duration, SystemTime};
2 :
3 : use bytes::{Buf, BufMut, Bytes, BytesMut};
4 : use pq_proto::{read_cstr, PG_EPOCH};
5 : use serde::{Deserialize, Serialize};
6 : use tracing::{trace, warn};
7 :
8 : use crate::lsn::Lsn;
9 :
10 : /// Feedback pageserver sends to safekeeper and safekeeper resends to compute.
11 : /// Serialized in custom flexible key/value format. In replication protocol, it
12 : /// is marked with NEON_STATUS_UPDATE_TAG_BYTE to differentiate from postgres
13 : /// Standby status update / Hot standby feedback messages.
14 : ///
15 : /// serde Serialize is used only for human readable dump to json (e.g. in
16 : /// safekeepers debug_dump).
17 0 : #[derive(Debug, Clone, Copy, PartialEq, Eq, Serialize, Deserialize)]
18 : pub struct PageserverFeedback {
19 : /// Last known size of the timeline. Used to enforce timeline size limit.
20 : pub current_timeline_size: u64,
21 : /// LSN last received and ingested by the pageserver. Controls backpressure.
22 : pub last_received_lsn: Lsn,
23 : /// LSN up to which data is persisted by the pageserver to its local disc.
24 : /// Controls backpressure.
25 : pub disk_consistent_lsn: Lsn,
26 : /// LSN up to which data is persisted by the pageserver on s3; safekeepers
27 : /// consider WAL before it can be removed.
28 : pub remote_consistent_lsn: Lsn,
29 : // Serialize with RFC3339 format.
30 : #[serde(with = "serde_systemtime")]
31 : pub replytime: SystemTime,
32 : /// Used to track feedbacks from different shards. Always zero for unsharded tenants.
33 : pub shard_number: u32,
34 : }
35 :
36 : impl PageserverFeedback {
37 6 : pub fn empty() -> PageserverFeedback {
38 6 : PageserverFeedback {
39 6 : current_timeline_size: 0,
40 6 : last_received_lsn: Lsn::INVALID,
41 6 : remote_consistent_lsn: Lsn::INVALID,
42 6 : disk_consistent_lsn: Lsn::INVALID,
43 6 : replytime: *PG_EPOCH,
44 6 : shard_number: 0,
45 6 : }
46 6 : }
47 :
48 : // Serialize PageserverFeedback using custom format
49 : // to support protocol extensibility.
50 : //
51 : // Following layout is used:
52 : // char - number of key-value pairs that follow.
53 : //
54 : // key-value pairs:
55 : // null-terminated string - key,
56 : // uint32 - value length in bytes
57 : // value itself
58 : //
59 : // TODO: change serialized fields names once all computes migrate to rename.
60 2 : pub fn serialize(&self, buf: &mut BytesMut) {
61 2 : let buf_ptr = buf.len();
62 2 : buf.put_u8(0); // # of keys, will be filled later
63 2 : let mut nkeys = 0;
64 2 :
65 2 : nkeys += 1;
66 2 : buf.put_slice(b"current_timeline_size\0");
67 2 : buf.put_i32(8);
68 2 : buf.put_u64(self.current_timeline_size);
69 2 :
70 2 : nkeys += 1;
71 2 : buf.put_slice(b"ps_writelsn\0");
72 2 : buf.put_i32(8);
73 2 : buf.put_u64(self.last_received_lsn.0);
74 2 :
75 2 : nkeys += 1;
76 2 : buf.put_slice(b"ps_flushlsn\0");
77 2 : buf.put_i32(8);
78 2 : buf.put_u64(self.disk_consistent_lsn.0);
79 2 :
80 2 : nkeys += 1;
81 2 : buf.put_slice(b"ps_applylsn\0");
82 2 : buf.put_i32(8);
83 2 : buf.put_u64(self.remote_consistent_lsn.0);
84 2 :
85 2 : let timestamp = self
86 2 : .replytime
87 2 : .duration_since(*PG_EPOCH)
88 2 : .expect("failed to serialize pg_replytime earlier than PG_EPOCH")
89 2 : .as_micros() as i64;
90 2 :
91 2 : nkeys += 1;
92 2 : buf.put_slice(b"ps_replytime\0");
93 2 : buf.put_i32(8);
94 2 : buf.put_i64(timestamp);
95 2 :
96 2 : if self.shard_number > 0 {
97 0 : nkeys += 1;
98 0 : buf.put_slice(b"shard_number\0");
99 0 : buf.put_i32(4);
100 0 : buf.put_u32(self.shard_number);
101 2 : }
102 :
103 2 : buf[buf_ptr] = nkeys;
104 2 : }
105 :
106 : // Deserialize PageserverFeedback message
107 : // TODO: change serialized fields names once all computes migrate to rename.
108 2 : pub fn parse(mut buf: Bytes) -> PageserverFeedback {
109 2 : let mut rf = PageserverFeedback::empty();
110 2 : let nfields = buf.get_u8();
111 2 : for _ in 0..nfields {
112 11 : let key = read_cstr(&mut buf).unwrap();
113 11 : match key.as_ref() {
114 11 : b"current_timeline_size" => {
115 2 : let len = buf.get_i32();
116 2 : assert_eq!(len, 8);
117 2 : rf.current_timeline_size = buf.get_u64();
118 : }
119 9 : b"ps_writelsn" => {
120 2 : let len = buf.get_i32();
121 2 : assert_eq!(len, 8);
122 2 : rf.last_received_lsn = Lsn(buf.get_u64());
123 : }
124 : b"ps_flushlsn" => {
125 2 : let len = buf.get_i32();
126 2 : assert_eq!(len, 8);
127 2 : rf.disk_consistent_lsn = Lsn(buf.get_u64());
128 : }
129 : b"ps_applylsn" => {
130 2 : let len = buf.get_i32();
131 2 : assert_eq!(len, 8);
132 2 : rf.remote_consistent_lsn = Lsn(buf.get_u64());
133 : }
134 3 : b"ps_replytime" => {
135 2 : let len = buf.get_i32();
136 2 : assert_eq!(len, 8);
137 2 : let raw_time = buf.get_i64();
138 2 : if raw_time > 0 {
139 2 : rf.replytime = *PG_EPOCH + Duration::from_micros(raw_time as u64);
140 2 : } else {
141 0 : rf.replytime = *PG_EPOCH - Duration::from_micros(-raw_time as u64);
142 0 : }
143 : }
144 : b"shard_number" => {
145 0 : let len = buf.get_i32();
146 0 : assert_eq!(len, 4);
147 0 : rf.shard_number = buf.get_u32();
148 : }
149 : _ => {
150 1 : let len = buf.get_i32();
151 1 : warn!(
152 0 : "PageserverFeedback parse. unknown key {} of len {len}. Skip it.",
153 0 : String::from_utf8_lossy(key.as_ref())
154 : );
155 1 : buf.advance(len as usize);
156 : }
157 : }
158 : }
159 2 : trace!("PageserverFeedback parsed is {:?}", rf);
160 2 : rf
161 2 : }
162 : }
163 :
164 : mod serde_systemtime {
165 : use std::time::SystemTime;
166 :
167 : use chrono::{DateTime, Utc};
168 : use serde::{Deserialize, Deserializer, Serializer};
169 :
170 0 : pub fn serialize<S>(ts: &SystemTime, serializer: S) -> Result<S::Ok, S::Error>
171 0 : where
172 0 : S: Serializer,
173 0 : {
174 0 : let chrono_dt: DateTime<Utc> = (*ts).into();
175 0 : serializer.serialize_str(&chrono_dt.to_rfc3339())
176 0 : }
177 :
178 0 : pub fn deserialize<'de, D>(deserializer: D) -> Result<SystemTime, D::Error>
179 0 : where
180 0 : D: Deserializer<'de>,
181 0 : {
182 0 : let time: String = Deserialize::deserialize(deserializer)?;
183 0 : Ok(DateTime::parse_from_rfc3339(&time)
184 0 : .map_err(serde::de::Error::custom)?
185 0 : .into())
186 0 : }
187 : }
188 :
189 : #[cfg(test)]
190 : mod tests {
191 : use super::*;
192 :
193 : #[test]
194 1 : fn test_replication_feedback_serialization() {
195 1 : let mut rf = PageserverFeedback::empty();
196 1 : // Fill rf with some values
197 1 : rf.current_timeline_size = 12345678;
198 1 : // Set rounded time to be able to compare it with deserialized value,
199 1 : // because it is rounded up to microseconds during serialization.
200 1 : rf.replytime = *PG_EPOCH + Duration::from_secs(100_000_000);
201 1 : let mut data = BytesMut::new();
202 1 : rf.serialize(&mut data);
203 1 :
204 1 : let rf_parsed = PageserverFeedback::parse(data.freeze());
205 1 : assert_eq!(rf, rf_parsed);
206 1 : }
207 :
208 : #[test]
209 1 : fn test_replication_feedback_unknown_key() {
210 1 : let mut rf = PageserverFeedback::empty();
211 1 : // Fill rf with some values
212 1 : rf.current_timeline_size = 12345678;
213 1 : // Set rounded time to be able to compare it with deserialized value,
214 1 : // because it is rounded up to microseconds during serialization.
215 1 : rf.replytime = *PG_EPOCH + Duration::from_secs(100_000_000);
216 1 : let mut data = BytesMut::new();
217 1 : rf.serialize(&mut data);
218 1 :
219 1 : // Add an extra field to the buffer and adjust number of keys
220 1 : data[0] += 1;
221 1 : data.put_slice(b"new_field_one\0");
222 1 : data.put_i32(8);
223 1 : data.put_u64(42);
224 1 :
225 1 : // Parse serialized data and check that new field is not parsed
226 1 : let rf_parsed = PageserverFeedback::parse(data.freeze());
227 1 : assert_eq!(rf, rf_parsed);
228 1 : }
229 : }
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