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-rw-r--r--src/block/repair.rs444
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diff --git a/src/block/repair.rs b/src/block/repair.rs
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+use core::ops::Bound;
+use std::path::PathBuf;
+use std::sync::Arc;
+use std::time::Duration;
+
+use async_trait::async_trait;
+use serde::{Deserialize, Serialize};
+use tokio::fs;
+use tokio::select;
+use tokio::sync::mpsc;
+use tokio::sync::watch;
+
+use garage_util::background::*;
+use garage_util::data::*;
+use garage_util::error::*;
+use garage_util::persister::Persister;
+use garage_util::time::*;
+use garage_util::tranquilizer::Tranquilizer;
+
+use crate::manager::*;
+
+const SCRUB_INTERVAL: Duration = Duration::from_secs(3600 * 24 * 30); // full scrub every 30 days
+
+pub struct RepairWorker {
+ manager: Arc<BlockManager>,
+ next_start: Option<Hash>,
+ block_iter: Option<BlockStoreIterator>,
+}
+
+impl RepairWorker {
+ pub fn new(manager: Arc<BlockManager>) -> Self {
+ Self {
+ manager,
+ next_start: None,
+ block_iter: None,
+ }
+ }
+}
+
+#[async_trait]
+impl Worker for RepairWorker {
+ fn name(&self) -> String {
+ "Block repair worker".into()
+ }
+
+ fn info(&self) -> Option<String> {
+ match self.block_iter.as_ref() {
+ None => {
+ let idx_bytes = self
+ .next_start
+ .as_ref()
+ .map(|x| x.as_slice())
+ .unwrap_or(&[]);
+ let idx_bytes = if idx_bytes.len() > 4 {
+ &idx_bytes[..4]
+ } else {
+ idx_bytes
+ };
+ Some(format!("Phase 1: {}", hex::encode(idx_bytes)))
+ }
+ Some(bi) => Some(format!("Phase 2: {:.2}% done", bi.progress() * 100.)),
+ }
+ }
+
+ async fn work(&mut self, _must_exit: &mut watch::Receiver<bool>) -> Result<WorkerState, Error> {
+ match self.block_iter.as_mut() {
+ None => {
+ // Phase 1: Repair blocks from RC table.
+
+ // We have to do this complicated two-step process where we first read a bunch
+ // of hashes from the RC table, and then insert them in the to-resync queue,
+ // because of SQLite. Basically, as long as we have an iterator on a DB table,
+ // we can't do anything else on the DB. The naive approach (which we had previously)
+ // of just iterating on the RC table and inserting items one to one in the resync
+ // queue can't work here, it would just provoke a deadlock in the SQLite adapter code.
+ // This is mostly because the Rust bindings for SQLite assume a worst-case scenario
+ // where SQLite is not compiled in thread-safe mode, so we have to wrap everything
+ // in a mutex (see db/sqlite_adapter.rs and discussion in PR #322).
+ // TODO: maybe do this with tokio::task::spawn_blocking ?
+ let mut batch_of_hashes = vec![];
+ let start_bound = match self.next_start.as_ref() {
+ None => Bound::Unbounded,
+ Some(x) => Bound::Excluded(x.as_slice()),
+ };
+ for entry in self
+ .manager
+ .rc
+ .rc
+ .range::<&[u8], _>((start_bound, Bound::Unbounded))?
+ {
+ let (hash, _) = entry?;
+ let hash = Hash::try_from(&hash[..]).unwrap();
+ batch_of_hashes.push(hash);
+ if batch_of_hashes.len() >= 1000 {
+ break;
+ }
+ }
+ if batch_of_hashes.is_empty() {
+ // move on to phase 2
+ self.block_iter = Some(BlockStoreIterator::new(&self.manager));
+ return Ok(WorkerState::Busy);
+ }
+
+ for hash in batch_of_hashes.into_iter() {
+ self.manager.put_to_resync(&hash, Duration::from_secs(0))?;
+ self.next_start = Some(hash)
+ }
+
+ Ok(WorkerState::Busy)
+ }
+ Some(bi) => {
+ // Phase 2: Repair blocks actually on disk
+ // Lists all blocks on disk and adds them to the resync queue.
+ // This allows us to find blocks we are storing but don't actually need,
+ // so that we can offload them if necessary and then delete them locally.
+ if let Some(hash) = bi.next().await? {
+ self.manager.put_to_resync(&hash, Duration::from_secs(0))?;
+ Ok(WorkerState::Busy)
+ } else {
+ Ok(WorkerState::Done)
+ }
+ }
+ }
+ }
+
+ async fn wait_for_work(&mut self, _must_exit: &watch::Receiver<bool>) -> WorkerState {
+ unreachable!()
+ }
+}
+
+// ----
+
+pub struct ScrubWorker {
+ manager: Arc<BlockManager>,
+ rx_cmd: mpsc::Receiver<ScrubWorkerCommand>,
+
+ work: ScrubWorkerState,
+ tranquilizer: Tranquilizer,
+
+ persister: Persister<ScrubWorkerPersisted>,
+ persisted: ScrubWorkerPersisted,
+}
+
+#[derive(Serialize, Deserialize)]
+struct ScrubWorkerPersisted {
+ tranquility: u32,
+ time_last_complete_scrub: u64,
+ corruptions_detected: u64,
+}
+
+enum ScrubWorkerState {
+ Running(BlockStoreIterator),
+ Paused(BlockStoreIterator, u64), // u64 = time when to resume scrub
+ Finished,
+}
+
+impl Default for ScrubWorkerState {
+ fn default() -> Self {
+ ScrubWorkerState::Finished
+ }
+}
+
+#[derive(Debug)]
+pub enum ScrubWorkerCommand {
+ Start,
+ Pause(Duration),
+ Resume,
+ Cancel,
+ SetTranquility(u32),
+}
+
+impl ScrubWorker {
+ pub fn new(manager: Arc<BlockManager>, rx_cmd: mpsc::Receiver<ScrubWorkerCommand>) -> Self {
+ let persister = Persister::new(&manager.system.metadata_dir, "scrub_info");
+ let persisted = match persister.load() {
+ Ok(v) => v,
+ Err(_) => ScrubWorkerPersisted {
+ time_last_complete_scrub: 0,
+ tranquility: 4,
+ corruptions_detected: 0,
+ },
+ };
+ Self {
+ manager,
+ rx_cmd,
+ work: ScrubWorkerState::Finished,
+ tranquilizer: Tranquilizer::new(30),
+ persister,
+ persisted,
+ }
+ }
+
+ async fn handle_cmd(&mut self, cmd: ScrubWorkerCommand) {
+ match cmd {
+ ScrubWorkerCommand::Start => {
+ self.work = match std::mem::take(&mut self.work) {
+ ScrubWorkerState::Finished => {
+ let iterator = BlockStoreIterator::new(&self.manager);
+ ScrubWorkerState::Running(iterator)
+ }
+ work => {
+ error!("Cannot start scrub worker: already running!");
+ work
+ }
+ };
+ }
+ ScrubWorkerCommand::Pause(dur) => {
+ self.work = match std::mem::take(&mut self.work) {
+ ScrubWorkerState::Running(it) | ScrubWorkerState::Paused(it, _) => {
+ ScrubWorkerState::Paused(it, now_msec() + dur.as_millis() as u64)
+ }
+ work => {
+ error!("Cannot pause scrub worker: not running!");
+ work
+ }
+ };
+ }
+ ScrubWorkerCommand::Resume => {
+ self.work = match std::mem::take(&mut self.work) {
+ ScrubWorkerState::Paused(it, _) => ScrubWorkerState::Running(it),
+ work => {
+ error!("Cannot resume scrub worker: not paused!");
+ work
+ }
+ };
+ }
+ ScrubWorkerCommand::Cancel => {
+ self.work = match std::mem::take(&mut self.work) {
+ ScrubWorkerState::Running(_) | ScrubWorkerState::Paused(_, _) => {
+ ScrubWorkerState::Finished
+ }
+ work => {
+ error!("Cannot cancel scrub worker: not running!");
+ work
+ }
+ }
+ }
+ ScrubWorkerCommand::SetTranquility(t) => {
+ self.persisted.tranquility = t;
+ if let Err(e) = self.persister.save_async(&self.persisted).await {
+ error!("Could not save new tranquilitiy value: {}", e);
+ }
+ }
+ }
+ }
+}
+
+#[async_trait]
+impl Worker for ScrubWorker {
+ fn name(&self) -> String {
+ "Block scrub worker".into()
+ }
+
+ fn info(&self) -> Option<String> {
+ let s = match &self.work {
+ ScrubWorkerState::Running(bsi) => format!(
+ "{:.2}% done (tranquility = {})",
+ bsi.progress() * 100.,
+ self.persisted.tranquility
+ ),
+ ScrubWorkerState::Paused(bsi, rt) => {
+ format!(
+ "Paused, {:.2}% done, resumes at {}",
+ bsi.progress() * 100.,
+ msec_to_rfc3339(*rt)
+ )
+ }
+ ScrubWorkerState::Finished => format!(
+ "Last completed scrub: {}",
+ msec_to_rfc3339(self.persisted.time_last_complete_scrub)
+ ),
+ };
+ Some(format!(
+ "{} ; corruptions detected: {}",
+ s, self.persisted.corruptions_detected
+ ))
+ }
+
+ async fn work(&mut self, _must_exit: &mut watch::Receiver<bool>) -> Result<WorkerState, Error> {
+ match self.rx_cmd.try_recv() {
+ Ok(cmd) => self.handle_cmd(cmd).await,
+ Err(mpsc::error::TryRecvError::Disconnected) => return Ok(WorkerState::Done),
+ Err(mpsc::error::TryRecvError::Empty) => (),
+ };
+
+ match &mut self.work {
+ ScrubWorkerState::Running(bsi) => {
+ self.tranquilizer.reset();
+ if let Some(hash) = bsi.next().await? {
+ match self.manager.read_block(&hash).await {
+ Err(Error::CorruptData(_)) => {
+ error!("Found corrupt data block during scrub: {:?}", hash);
+ self.persisted.corruptions_detected += 1;
+ self.persister.save_async(&self.persisted).await?;
+ }
+ Err(e) => return Err(e),
+ _ => (),
+ };
+ Ok(self
+ .tranquilizer
+ .tranquilize_worker(self.persisted.tranquility))
+ } else {
+ self.persisted.time_last_complete_scrub = now_msec();
+ self.persister.save_async(&self.persisted).await?;
+ self.work = ScrubWorkerState::Finished;
+ self.tranquilizer.clear();
+ Ok(WorkerState::Idle)
+ }
+ }
+ _ => Ok(WorkerState::Idle),
+ }
+ }
+
+ async fn wait_for_work(&mut self, _must_exit: &watch::Receiver<bool>) -> WorkerState {
+ let (wait_until, command) = match &self.work {
+ ScrubWorkerState::Running(_) => return WorkerState::Busy,
+ ScrubWorkerState::Paused(_, resume_time) => (*resume_time, ScrubWorkerCommand::Resume),
+ ScrubWorkerState::Finished => (
+ self.persisted.time_last_complete_scrub + SCRUB_INTERVAL.as_millis() as u64,
+ ScrubWorkerCommand::Start,
+ ),
+ };
+
+ let now = now_msec();
+ if now >= wait_until {
+ self.handle_cmd(command).await;
+ return WorkerState::Busy;
+ }
+ let delay = Duration::from_millis(wait_until - now);
+ select! {
+ _ = tokio::time::sleep(delay) => self.handle_cmd(command).await,
+ cmd = self.rx_cmd.recv() => if let Some(cmd) = cmd {
+ self.handle_cmd(cmd).await;
+ } else {
+ return WorkerState::Done;
+ }
+ }
+
+ match &self.work {
+ ScrubWorkerState::Running(_) => WorkerState::Busy,
+ _ => WorkerState::Idle,
+ }
+ }
+}
+
+// ----
+
+struct BlockStoreIterator {
+ path: Vec<ReadingDir>,
+}
+
+enum ReadingDir {
+ Pending(PathBuf),
+ Read {
+ subpaths: Vec<fs::DirEntry>,
+ pos: usize,
+ },
+}
+
+impl BlockStoreIterator {
+ fn new(manager: &BlockManager) -> Self {
+ let root_dir = manager.data_dir.clone();
+ Self {
+ path: vec![ReadingDir::Pending(root_dir)],
+ }
+ }
+
+ /// Returns progress done, between 0 and 1
+ fn progress(&self) -> f32 {
+ if self.path.is_empty() {
+ 1.0
+ } else {
+ let mut ret = 0.0;
+ let mut next_div = 1;
+ for p in self.path.iter() {
+ match p {
+ ReadingDir::Pending(_) => break,
+ ReadingDir::Read { subpaths, pos } => {
+ next_div *= subpaths.len();
+ ret += ((*pos - 1) as f32) / (next_div as f32);
+ }
+ }
+ }
+ ret
+ }
+ }
+
+ async fn next(&mut self) -> Result<Option<Hash>, Error> {
+ loop {
+ let last_path = match self.path.last_mut() {
+ None => return Ok(None),
+ Some(lp) => lp,
+ };
+
+ if let ReadingDir::Pending(path) = last_path {
+ let mut reader = fs::read_dir(&path).await?;
+ let mut subpaths = vec![];
+ while let Some(ent) = reader.next_entry().await? {
+ subpaths.push(ent);
+ }
+ *last_path = ReadingDir::Read { subpaths, pos: 0 };
+ }
+
+ let (subpaths, pos) = match *last_path {
+ ReadingDir::Read {
+ ref subpaths,
+ ref mut pos,
+ } => (subpaths, pos),
+ ReadingDir::Pending(_) => unreachable!(),
+ };
+
+ let data_dir_ent = match subpaths.get(*pos) {
+ None => {
+ self.path.pop();
+ continue;
+ }
+ Some(ent) => {
+ *pos += 1;
+ ent
+ }
+ };
+
+ let name = data_dir_ent.file_name();
+ let name = if let Ok(n) = name.into_string() {
+ n
+ } else {
+ continue;
+ };
+ let ent_type = data_dir_ent.file_type().await?;
+
+ let name = name.strip_suffix(".zst").unwrap_or(&name);
+ if name.len() == 2 && hex::decode(&name).is_ok() && ent_type.is_dir() {
+ let path = data_dir_ent.path();
+ self.path.push(ReadingDir::Pending(path));
+ } else if name.len() == 64 {
+ if let Ok(h) = hex::decode(&name) {
+ let mut hash = [0u8; 32];
+ hash.copy_from_slice(&h);
+ return Ok(Some(hash.into()));
+ }
+ }
+ }
+ }
+}