forked from Deuxfleurs/garage
616 lines
18 KiB
Rust
616 lines
18 KiB
Rust
use std::collections::HashSet;
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use std::convert::TryInto;
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use std::sync::{Arc, Mutex};
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use std::time::Duration;
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use async_trait::async_trait;
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use serde::{Deserialize, Serialize};
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use tokio::select;
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use tokio::sync::{watch, Notify};
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use opentelemetry::{
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trace::{FutureExt as OtelFutureExt, TraceContextExt, Tracer},
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Context, KeyValue,
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};
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use garage_db as db;
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use garage_db::counted_tree_hack::CountedTree;
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use garage_util::background::*;
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use garage_util::data::*;
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use garage_util::error::*;
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use garage_util::metrics::RecordDuration;
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use garage_util::persister::PersisterShared;
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use garage_util::time::*;
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use garage_util::tranquilizer::Tranquilizer;
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use garage_rpc::system::System;
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use garage_rpc::*;
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use garage_table::replication::TableReplication;
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use crate::manager::*;
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// The delay between the time where a resync operation fails
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// and the time when it is retried, with exponential backoff
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// (multiplied by 2, 4, 8, 16, etc. for every consecutive failure).
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pub(crate) const RESYNC_RETRY_DELAY: Duration = Duration::from_secs(60);
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// The minimum retry delay is 60 seconds = 1 minute
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// The maximum retry delay is 60 seconds * 2^6 = 60 seconds << 6 = 64 minutes (~1 hour)
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pub(crate) const RESYNC_RETRY_DELAY_MAX_BACKOFF_POWER: u64 = 6;
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// No more than 4 resync workers can be running in the system
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pub(crate) const MAX_RESYNC_WORKERS: usize = 8;
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// Resync tranquility is initially set to 2, but can be changed in the CLI
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// and the updated version is persisted over Garage restarts
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const INITIAL_RESYNC_TRANQUILITY: u32 = 2;
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pub struct BlockResyncManager {
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pub(crate) queue: CountedTree,
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pub(crate) notify: Arc<Notify>,
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pub(crate) errors: CountedTree,
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busy_set: BusySet,
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persister: PersisterShared<ResyncPersistedConfig>,
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}
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#[derive(Serialize, Deserialize, Clone, Copy)]
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struct ResyncPersistedConfig {
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n_workers: usize,
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tranquility: u32,
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}
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impl garage_util::migrate::InitialFormat for ResyncPersistedConfig {}
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impl Default for ResyncPersistedConfig {
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fn default() -> Self {
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ResyncPersistedConfig {
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n_workers: 1,
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tranquility: INITIAL_RESYNC_TRANQUILITY,
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}
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}
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}
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enum ResyncIterResult {
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BusyDidSomething,
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BusyDidNothing,
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IdleFor(Duration),
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}
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type BusySet = Arc<Mutex<HashSet<Vec<u8>>>>;
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struct BusyBlock {
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time_bytes: Vec<u8>,
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hash_bytes: Vec<u8>,
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busy_set: BusySet,
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}
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impl BlockResyncManager {
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pub(crate) fn new(db: &db::Db, system: &System) -> Self {
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let queue = db
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.open_tree("block_local_resync_queue")
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.expect("Unable to open block_local_resync_queue tree");
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let queue = CountedTree::new(queue).expect("Could not count block_local_resync_queue");
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let errors = db
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.open_tree("block_local_resync_errors")
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.expect("Unable to open block_local_resync_errors tree");
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let errors = CountedTree::new(errors).expect("Could not count block_local_resync_errors");
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let persister = PersisterShared::new(&system.metadata_dir, "resync_cfg");
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Self {
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queue,
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notify: Arc::new(Notify::new()),
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errors,
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busy_set: Arc::new(Mutex::new(HashSet::new())),
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persister,
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}
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}
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/// Get lenght of resync queue
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pub fn queue_len(&self) -> Result<usize, Error> {
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// This currently can't return an error because the CountedTree hack
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// doesn't error on .len(), but this will change when we remove the hack
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// (hopefully someday!)
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Ok(self.queue.len())
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}
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/// Get number of blocks that have an error
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pub fn errors_len(&self) -> Result<usize, Error> {
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// (see queue_len comment)
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Ok(self.errors.len())
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}
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/// Clear the error counter for a block and put it in queue immediately
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pub fn clear_backoff(&self, hash: &Hash) -> Result<(), Error> {
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let now = now_msec();
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if let Some(ec) = self.errors.get(hash)? {
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let mut ec = ErrorCounter::decode(&ec);
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if ec.errors > 0 {
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ec.last_try = now - ec.delay_msec();
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self.errors.insert(hash, ec.encode())?;
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self.put_to_resync_at(hash, now)?;
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return Ok(());
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}
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}
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Err(Error::Message(format!(
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"Block {:?} was not in an errored state",
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hash
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)))
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}
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pub fn register_bg_vars(&self, vars: &mut vars::BgVars) {
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let notify = self.notify.clone();
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vars.register_rw(
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&self.persister,
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"resync-worker-count",
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|p| p.get_with(|x| x.n_workers),
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move |p, n_workers| {
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if !(1..=MAX_RESYNC_WORKERS).contains(&n_workers) {
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return Err(Error::Message(format!(
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"Invalid number of resync workers, must be between 1 and {}",
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MAX_RESYNC_WORKERS
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)));
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}
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p.set_with(|x| x.n_workers = n_workers)?;
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notify.notify_waiters();
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Ok(())
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},
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);
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let notify = self.notify.clone();
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vars.register_rw(
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&self.persister,
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"resync-tranquility",
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|p| p.get_with(|x| x.tranquility),
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move |p, tranquility| {
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p.set_with(|x| x.tranquility = tranquility)?;
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notify.notify_waiters();
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Ok(())
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},
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);
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}
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// ---- Resync loop ----
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// This part manages a queue of blocks that need to be
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// "resynchronized", i.e. that need to have a check that
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// they are at present if we need them, or that they are
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// deleted once the garbage collection delay has passed.
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//
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// Here are some explanations on how the resync queue works.
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// There are two Sled trees that are used to have information
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// about the status of blocks that need to be resynchronized:
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//
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// - resync.queue: a tree that is ordered first by a timestamp
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// (in milliseconds since Unix epoch) that is the time at which
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// the resync must be done, and second by block hash.
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// The key in this tree is just:
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// concat(timestamp (8 bytes), hash (32 bytes))
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// The value is the same 32-byte hash.
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//
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// - resync.errors: a tree that indicates for each block
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// if the last resync resulted in an error, and if so,
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// the following two informations (see the ErrorCounter struct):
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// - how many consecutive resync errors for this block?
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// - when was the last try?
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// These two informations are used to implement an
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// exponential backoff retry strategy.
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// The key in this tree is the 32-byte hash of the block,
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// and the value is the encoded ErrorCounter value.
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//
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// We need to have these two trees, because the resync queue
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// is not just a queue of items to process, but a set of items
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// that are waiting a specific delay until we can process them
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// (the delay being necessary both internally for the exponential
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// backoff strategy, and exposed as a parameter when adding items
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// to the queue, e.g. to wait until the GC delay has passed).
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// This is why we need one tree ordered by time, and one
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// ordered by identifier of item to be processed (block hash).
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//
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// When the worker wants to process an item it takes from
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// resync.queue, it checks in resync.errors that if there is an
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// exponential back-off delay to await, it has passed before we
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// process the item. If not, the item in the queue is skipped
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// (but added back for later processing after the time of the
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// delay).
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//
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// An alternative that would have seemed natural is to
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// only add items to resync.queue with a processing time that is
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// after the delay, but there are several issues with this:
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// - This requires to synchronize updates to resync.queue and
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// resync.errors (with the current model, there is only one thread,
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// the worker thread, that accesses resync.errors,
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// so no need to synchronize) by putting them both in a lock.
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// This would mean that block_incref might need to take a lock
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// before doing its thing, meaning it has much more chances of
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// not completing successfully if something bad happens to Garage.
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// Currently Garage is not able to recover from block_incref that
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// doesn't complete successfully, because it is necessary to ensure
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// the consistency between the state of the block manager and
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// information in the BlockRef table.
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// - If a resync fails, we put that block in the resync.errors table,
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// and also add it back to resync.queue to be processed after
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// the exponential back-off delay,
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// but maybe the block is already scheduled to be resynced again
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// at another time that is before the exponential back-off delay,
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// and we have no way to check that easily. This means that
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// in all cases, we need to check the resync.errors table
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// in the resync loop at the time when a block is popped from
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// the resync.queue.
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// Overall, the current design is therefore simpler and more robust
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// because it tolerates inconsistencies between the resync.queue
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// and resync.errors table (items being scheduled in resync.queue
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// for times that are earlier than the exponential back-off delay
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// is a natural condition that is handled properly).
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pub(crate) fn put_to_resync(&self, hash: &Hash, delay: Duration) -> db::Result<()> {
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let when = now_msec() + delay.as_millis() as u64;
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self.put_to_resync_at(hash, when)
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}
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pub(crate) fn put_to_resync_at(&self, hash: &Hash, when: u64) -> db::Result<()> {
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trace!("Put resync_queue: {} {:?}", when, hash);
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let mut key = u64::to_be_bytes(when).to_vec();
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key.extend(hash.as_ref());
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self.queue.insert(key, hash.as_ref())?;
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self.notify.notify_waiters();
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Ok(())
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}
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async fn resync_iter(&self, manager: &BlockManager) -> Result<ResyncIterResult, db::Error> {
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if let Some(block) = self.get_block_to_resync()? {
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let time_msec = u64::from_be_bytes(block.time_bytes[0..8].try_into().unwrap());
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let now = now_msec();
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if now >= time_msec {
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let hash = Hash::try_from(&block.hash_bytes[..]).unwrap();
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if let Some(ec) = self.errors.get(hash.as_slice())? {
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let ec = ErrorCounter::decode(&ec);
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if now < ec.next_try() {
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// if next retry after an error is not yet,
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// don't do resync and return early, but still
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// make sure the item is still in queue at expected time
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self.put_to_resync_at(&hash, ec.next_try())?;
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// ec.next_try() > now >= time_msec, so this remove
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// is not removing the one we added just above
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// (we want to do the remove after the insert to ensure
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// that the item is not lost if we crash in-between)
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self.queue.remove(&block.time_bytes)?;
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return Ok(ResyncIterResult::BusyDidNothing);
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}
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}
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let tracer = opentelemetry::global::tracer("garage");
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let trace_id = gen_uuid();
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let span = tracer
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.span_builder("Resync block")
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.with_trace_id(
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opentelemetry::trace::TraceId::from_hex(&hex::encode(
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&trace_id.as_slice()[..16],
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))
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.unwrap(),
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)
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.with_attributes(vec![KeyValue::new("block", format!("{:?}", hash))])
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.start(&tracer);
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let res = self
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.resync_block(manager, &hash)
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.with_context(Context::current_with_span(span))
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.bound_record_duration(&manager.metrics.resync_duration)
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.await;
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manager.metrics.resync_counter.add(1);
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if let Err(e) = &res {
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manager.metrics.resync_error_counter.add(1);
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error!("Error when resyncing {:?}: {}", hash, e);
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let err_counter = match self.errors.get(hash.as_slice())? {
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Some(ec) => ErrorCounter::decode(&ec).add1(now + 1),
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None => ErrorCounter::new(now + 1),
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};
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self.errors.insert(hash.as_slice(), err_counter.encode())?;
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self.put_to_resync_at(&hash, err_counter.next_try())?;
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// err_counter.next_try() >= now + 1 > now,
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// the entry we remove from the queue is not
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// the entry we inserted with put_to_resync_at
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self.queue.remove(&block.time_bytes)?;
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} else {
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self.errors.remove(hash.as_slice())?;
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self.queue.remove(&block.time_bytes)?;
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}
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Ok(ResyncIterResult::BusyDidSomething)
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} else {
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Ok(ResyncIterResult::IdleFor(Duration::from_millis(
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time_msec - now,
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)))
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}
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} else {
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// Here we wait either for a notification that an item has been
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// added to the queue, or for a constant delay of 10 secs to expire.
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// The delay avoids a race condition where the notification happens
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// between the time we checked the queue and the first poll
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// to resync_notify.notified(): if that happens, we'll just loop
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// back 10 seconds later, which is fine.
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Ok(ResyncIterResult::IdleFor(Duration::from_secs(10)))
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}
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}
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fn get_block_to_resync(&self) -> Result<Option<BusyBlock>, db::Error> {
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let mut busy = self.busy_set.lock().unwrap();
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for it in self.queue.iter()? {
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let (time_bytes, hash_bytes) = it?;
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if !busy.contains(&time_bytes) {
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busy.insert(time_bytes.clone());
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return Ok(Some(BusyBlock {
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time_bytes,
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hash_bytes,
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busy_set: self.busy_set.clone(),
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}));
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}
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}
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Ok(None)
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}
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async fn resync_block(&self, manager: &BlockManager, hash: &Hash) -> Result<(), Error> {
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let existing_path = manager.find_block(hash).await;
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let exists = existing_path.is_some();
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let rc = manager.rc.get_block_rc(hash)?;
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if exists != rc.is_needed() || exists != rc.is_nonzero() {
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debug!(
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"Resync block {:?}: exists {}, nonzero rc {}, deletable {}",
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hash,
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exists,
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rc.is_nonzero(),
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rc.is_deletable(),
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);
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}
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if exists && rc.is_deletable() {
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info!("Resync block {:?}: offloading and deleting", hash);
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let existing_path = existing_path.unwrap();
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let mut who = manager.replication.storage_nodes(hash);
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if who.len() < manager.replication.write_quorum() {
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return Err(Error::Message("Not trying to offload block because we don't have a quorum of nodes to write to".to_string()));
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}
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who.retain(|id| *id != manager.system.id);
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let who_needs_resps = manager
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.system
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.rpc_helper()
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.call_many(
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&manager.endpoint,
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&who,
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BlockRpc::NeedBlockQuery(*hash),
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RequestStrategy::with_priority(PRIO_BACKGROUND),
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)
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.await?;
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let mut need_nodes = vec![];
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for (node, needed) in who_needs_resps {
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match needed.err_context("NeedBlockQuery RPC")? {
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BlockRpc::NeedBlockReply(needed) => {
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if needed {
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need_nodes.push(node);
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}
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}
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m => {
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return Err(Error::unexpected_rpc_message(m));
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}
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}
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}
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if !need_nodes.is_empty() {
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trace!(
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"Block {:?} needed by {} nodes, sending",
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hash,
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need_nodes.len()
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);
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for node in need_nodes.iter() {
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manager
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.metrics
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.resync_send_counter
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.add(1, &[KeyValue::new("to", format!("{:?}", node))]);
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}
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let block = manager.read_block_from(hash, &existing_path).await?;
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let (header, bytes) = block.into_parts();
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let put_block_message = Req::new(BlockRpc::PutBlock {
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hash: *hash,
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header,
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})?
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.with_stream_from_buffer(bytes);
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manager
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.system
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.rpc_helper()
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.try_call_many(
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&manager.endpoint,
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&need_nodes,
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put_block_message,
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RequestStrategy::with_priority(PRIO_BACKGROUND)
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.with_quorum(need_nodes.len()),
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)
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.await
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.err_context("PutBlock RPC")?;
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}
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info!(
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"Deleting unneeded block {:?}, offload finished ({} / {})",
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hash,
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need_nodes.len(),
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who.len()
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);
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manager.delete_if_unneeded(hash).await?;
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manager.rc.clear_deleted_block_rc(hash)?;
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}
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if rc.is_nonzero() && !exists {
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info!(
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"Resync block {:?}: fetching absent but needed block (refcount > 0)",
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hash
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);
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let block_data = manager.rpc_get_raw_block(hash, None).await?;
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manager.metrics.resync_recv_counter.add(1);
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manager.write_block(hash, &block_data).await?;
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}
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Ok(())
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}
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}
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impl Drop for BusyBlock {
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fn drop(&mut self) {
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let mut busy = self.busy_set.lock().unwrap();
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busy.remove(&self.time_bytes);
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}
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}
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pub(crate) struct ResyncWorker {
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index: usize,
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manager: Arc<BlockManager>,
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tranquilizer: Tranquilizer,
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next_delay: Duration,
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persister: PersisterShared<ResyncPersistedConfig>,
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}
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|
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impl ResyncWorker {
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pub(crate) fn new(index: usize, manager: Arc<BlockManager>) -> Self {
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let persister = manager.resync.persister.clone();
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Self {
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|
index,
|
|
manager,
|
|
tranquilizer: Tranquilizer::new(30),
|
|
next_delay: Duration::from_secs(10),
|
|
persister,
|
|
}
|
|
}
|
|
}
|
|
|
|
#[async_trait]
|
|
impl Worker for ResyncWorker {
|
|
fn name(&self) -> String {
|
|
format!("Block resync worker #{}", self.index + 1)
|
|
}
|
|
|
|
fn status(&self) -> WorkerStatus {
|
|
let (n_workers, tranquility) = self.persister.get_with(|x| (x.n_workers, x.tranquility));
|
|
|
|
if self.index >= n_workers {
|
|
return WorkerStatus {
|
|
freeform: vec!["This worker is currently disabled".into()],
|
|
..Default::default()
|
|
};
|
|
}
|
|
|
|
WorkerStatus {
|
|
queue_length: Some(self.manager.resync.queue_len().unwrap_or(0) as u64),
|
|
tranquility: Some(tranquility),
|
|
persistent_errors: Some(self.manager.resync.errors_len().unwrap_or(0) as u64),
|
|
..Default::default()
|
|
}
|
|
}
|
|
|
|
async fn work(&mut self, _must_exit: &mut watch::Receiver<bool>) -> Result<WorkerState, Error> {
|
|
let (n_workers, tranquility) = self.persister.get_with(|x| (x.n_workers, x.tranquility));
|
|
|
|
if self.index >= n_workers {
|
|
return Ok(WorkerState::Idle);
|
|
}
|
|
|
|
self.tranquilizer.reset();
|
|
match self.manager.resync.resync_iter(&self.manager).await {
|
|
Ok(ResyncIterResult::BusyDidSomething) => {
|
|
Ok(self.tranquilizer.tranquilize_worker(tranquility))
|
|
}
|
|
Ok(ResyncIterResult::BusyDidNothing) => Ok(WorkerState::Busy),
|
|
Ok(ResyncIterResult::IdleFor(delay)) => {
|
|
self.next_delay = delay;
|
|
Ok(WorkerState::Idle)
|
|
}
|
|
Err(e) => {
|
|
// The errors that we have here are only Sled errors
|
|
// We don't really know how to handle them so just ¯\_(ツ)_/¯
|
|
// (there is kind of an assumption that Sled won't error on us,
|
|
// if it does there is not much we can do -- TODO should we just panic?)
|
|
// Here we just give the error to the worker manager,
|
|
// it will print it to the logs and increment a counter
|
|
Err(e.into())
|
|
}
|
|
}
|
|
}
|
|
|
|
async fn wait_for_work(&mut self) -> WorkerState {
|
|
while self.index >= self.persister.get_with(|x| x.n_workers) {
|
|
self.manager.resync.notify.notified().await
|
|
}
|
|
|
|
select! {
|
|
_ = tokio::time::sleep(self.next_delay) => (),
|
|
_ = self.manager.resync.notify.notified() => (),
|
|
};
|
|
|
|
WorkerState::Busy
|
|
}
|
|
}
|
|
|
|
/// Counts the number of errors when resyncing a block,
|
|
/// and the time of the last try.
|
|
/// Used to implement exponential backoff.
|
|
#[derive(Clone, Copy, Debug)]
|
|
pub(crate) struct ErrorCounter {
|
|
pub(crate) errors: u64,
|
|
pub(crate) last_try: u64,
|
|
}
|
|
|
|
impl ErrorCounter {
|
|
fn new(now: u64) -> Self {
|
|
Self {
|
|
errors: 1,
|
|
last_try: now,
|
|
}
|
|
}
|
|
|
|
pub(crate) fn decode(data: &[u8]) -> Self {
|
|
Self {
|
|
errors: u64::from_be_bytes(data[0..8].try_into().unwrap()),
|
|
last_try: u64::from_be_bytes(data[8..16].try_into().unwrap()),
|
|
}
|
|
}
|
|
|
|
fn encode(&self) -> Vec<u8> {
|
|
[
|
|
u64::to_be_bytes(self.errors),
|
|
u64::to_be_bytes(self.last_try),
|
|
]
|
|
.concat()
|
|
}
|
|
|
|
fn add1(self, now: u64) -> Self {
|
|
Self {
|
|
errors: self.errors + 1,
|
|
last_try: now,
|
|
}
|
|
}
|
|
|
|
fn delay_msec(&self) -> u64 {
|
|
(RESYNC_RETRY_DELAY.as_millis() as u64)
|
|
<< std::cmp::min(self.errors - 1, RESYNC_RETRY_DELAY_MAX_BACKOFF_POWER)
|
|
}
|
|
|
|
pub(crate) fn next_try(&self) -> u64 {
|
|
self.last_try + self.delay_msec()
|
|
}
|
|
}
|