use std::sync::Arc;
use std::time::Duration;
use async_trait::async_trait;
use tokio::sync::watch;
use garage_block::repair::ScrubWorkerCommand;
use garage_model::garage::Garage;
use garage_model::s3::block_ref_table::*;
use garage_model::s3::mpu_table::*;
use garage_model::s3::object_table::*;
use garage_model::s3::version_table::*;
use garage_table::replication::*;
use garage_table::*;
use garage_util::background::*;
use garage_util::error::Error;
use garage_util::migrate::Migrate;
use crate::*;
pub async fn launch_online_repair(
garage: &Arc<Garage>,
bg: &BackgroundRunner,
opt: RepairOpt,
) -> Result<(), Error> {
match opt.what {
RepairWhat::Tables => {
info!("Launching a full sync of tables");
garage.bucket_table.syncer.add_full_sync()?;
garage.object_table.syncer.add_full_sync()?;
garage.version_table.syncer.add_full_sync()?;
garage.block_ref_table.syncer.add_full_sync()?;
garage.key_table.syncer.add_full_sync()?;
}
RepairWhat::Versions => {
info!("Repairing the versions table");
bg.spawn_worker(TableRepairWorker::new(garage.clone(), RepairVersions));
}
RepairWhat::MultipartUploads => {
info!("Repairing the multipart uploads table");
bg.spawn_worker(TableRepairWorker::new(garage.clone(), RepairMpu));
}
RepairWhat::BlockRefs => {
info!("Repairing the block refs table");
bg.spawn_worker(TableRepairWorker::new(garage.clone(), RepairBlockRefs));
}
RepairWhat::Blocks => {
info!("Repairing the stored blocks");
bg.spawn_worker(garage_block::repair::RepairWorker::new(
garage.block_manager.clone(),
));
}
RepairWhat::Scrub { cmd } => {
let cmd = match cmd {
ScrubCmd::Start => ScrubWorkerCommand::Start,
ScrubCmd::Pause => ScrubWorkerCommand::Pause(Duration::from_secs(3600 * 24)),
ScrubCmd::Resume => ScrubWorkerCommand::Resume,
ScrubCmd::Cancel => ScrubWorkerCommand::Cancel,
ScrubCmd::SetTranquility { tranquility } => {
garage
.block_manager
.scrub_persister
.set_with(|x| x.tranquility = tranquility)?;
return Ok(());
}
};
info!("Sending command to scrub worker: {:?}", cmd);
garage.block_manager.send_scrub_command(cmd).await?;
}
}
Ok(())
}
// ----
#[async_trait]
trait TableRepair: Send + Sync + 'static {
type T: TableSchema;
fn table(garage: &Garage) -> &Table<Self::T, TableShardedReplication>;
async fn process(
&mut self,
garage: &Garage,
entry: <<Self as TableRepair>::T as TableSchema>::E,
) -> Result<bool, Error>;
}
struct TableRepairWorker<T: TableRepair> {
garage: Arc<Garage>,
pos: Vec<u8>,
counter: usize,
repairs: usize,
inner: T,
}
impl<R: TableRepair> TableRepairWorker<R> {
fn new(garage: Arc<Garage>, inner: R) -> Self {
Self {
garage,
inner,
pos: vec![],
counter: 0,
repairs: 0,
}
}
}
#[async_trait]
impl<R: TableRepair> Worker for TableRepairWorker<R> {
fn name(&self) -> String {
format!("{} repair worker", R::T::TABLE_NAME)
}
fn status(&self) -> WorkerStatus {
WorkerStatus {
progress: Some(format!("{} ({})", self.counter, self.repairs)),
..Default::default()
}
}
async fn work(&mut self, _must_exit: &mut watch::Receiver<bool>) -> Result<WorkerState, Error> {
let (item_bytes, next_pos) = match R::table(&self.garage).data.store.get_gt(&self.pos)? {
Some((k, v)) => (v, k),
None => {
info!(
"{}: finished, done {}, fixed {}",
self.name(),
self.counter,
self.repairs
);
return Ok(WorkerState::Done);
}
};
let entry = <R::T as TableSchema>::E::decode(&item_bytes)
.ok_or_message("Cannot decode table entry")?;
if self.inner.process(&self.garage, entry).await? {
self.repairs += 1;
}
self.counter += 1;
self.pos = next_pos;
Ok(WorkerState::Busy)
}
async fn wait_for_work(&mut self) -> WorkerState {
unreachable!()
}
}
// ----
struct RepairVersions;
#[async_trait]
impl TableRepair for RepairVersions {
type T = VersionTable;
fn table(garage: &Garage) -> &Table<Self::T, TableShardedReplication> {
&garage.version_table
}
async fn process(&mut self, garage: &Garage, version: Version) -> Result<bool, Error> {
if !version.deleted.get() {
let ref_exists = match &version.backlink {
VersionBacklink::Object { bucket_id, key } => garage
.object_table
.get(bucket_id, key)
.await?
.map(|o| {
o.versions().iter().any(|x| {
x.uuid == version.uuid && x.state != ObjectVersionState::Aborted
})
})
.unwrap_or(false),
VersionBacklink::MultipartUpload { upload_id } => garage
.mpu_table
.get(upload_id, &EmptyKey)
.await?
.map(|u| !u.deleted.get())
.unwrap_or(false),
};
if !ref_exists {
info!("Repair versions: marking version as deleted: {:?}", version);
garage
.version_table
.insert(&Version::new(version.uuid, version.backlink, true))
.await?;
return Ok(true);
}
}
Ok(false)
}
}
// ----
struct RepairBlockRefs;
#[async_trait]
impl TableRepair for RepairBlockRefs {
type T = BlockRefTable;
fn table(garage: &Garage) -> &Table<Self::T, TableShardedReplication> {
&garage.block_ref_table
}
async fn process(&mut self, garage: &Garage, mut block_ref: BlockRef) -> Result<bool, Error> {
if !block_ref.deleted.get() {
let ref_exists = garage
.version_table
.get(&block_ref.version, &EmptyKey)
.await?
.map(|v| !v.deleted.get())
.unwrap_or(false);
if !ref_exists {
info!(
"Repair block ref: marking block_ref as deleted: {:?}",
block_ref
);
block_ref.deleted.set();
garage.block_ref_table.insert(&block_ref).await?;
return Ok(true);
}
}
Ok(false)
}
}
// ----
struct RepairMpu;
#[async_trait]
impl TableRepair for RepairMpu {
type T = MultipartUploadTable;
fn table(garage: &Garage) -> &Table<Self::T, TableShardedReplication> {
&garage.mpu_table
}
async fn process(&mut self, garage: &Garage, mut mpu: MultipartUpload) -> Result<bool, Error> {
if !mpu.deleted.get() {
let ref_exists = garage
.object_table
.get(&mpu.bucket_id, &mpu.key)
.await?
.map(|o| {
o.versions()
.iter()
.any(|x| x.uuid == mpu.upload_id && x.is_uploading(Some(true)))
})
.unwrap_or(false);
if !ref_exists {
info!(
"Repair multipart uploads: marking mpu as deleted: {:?}",
mpu
);
mpu.parts.clear();
mpu.deleted.set();
garage.mpu_table.insert(&mpu).await?;
return Ok(true);
}
}
Ok(false)
}
}