//! Utility functions on the DBs. Mainly getter and setters. use std::ops::Bound; use meilisearch_types::heed::types::{DecodeIgnore, OwnedType}; use meilisearch_types::heed::{Database, RoTxn, RwTxn}; use meilisearch_types::milli::{CboRoaringBitmapCodec, BEU32}; use meilisearch_types::tasks::{Kind, KindWithContent, Status}; use roaring::{MultiOps, RoaringBitmap}; use time::OffsetDateTime; use crate::{Error, IndexScheduler, Result, Task, TaskId, BEI128}; impl IndexScheduler { pub(crate) fn all_task_ids(&self, rtxn: &RoTxn) -> Result { enum_iterator::all().map(|s| self.get_status(rtxn, s)).union() } pub(crate) fn last_task_id(&self, rtxn: &RoTxn) -> Result> { Ok(self.all_tasks.remap_data_type::().last(rtxn)?.map(|(k, _)| k.get() + 1)) } pub(crate) fn next_task_id(&self, rtxn: &RoTxn) -> Result { Ok(self.last_task_id(rtxn)?.unwrap_or_default()) } pub(crate) fn get_task(&self, rtxn: &RoTxn, task_id: TaskId) -> Result> { Ok(self.all_tasks.get(rtxn, &BEU32::new(task_id))?) } /// Convert an iterator to a `Vec` of tasks. The tasks MUST exist or a /// `CorruptedTaskQueue` error will be throwed. pub(crate) fn get_existing_tasks( &self, rtxn: &RoTxn, tasks: impl IntoIterator, ) -> Result> { tasks .into_iter() .map(|task_id| { self.get_task(rtxn, task_id).and_then(|task| task.ok_or(Error::CorruptedTaskQueue)) }) .collect::>() } pub(crate) fn update_task(&self, wtxn: &mut RwTxn, task: &Task) -> Result<()> { let old_task = self.get_task(wtxn, task.uid)?.ok_or(Error::CorruptedTaskQueue)?; debug_assert_eq!(old_task.uid, task.uid); if old_task == *task { return Ok(()); } if old_task.status != task.status { self.update_status(wtxn, old_task.status, |bitmap| { bitmap.remove(task.uid); })?; self.update_status(wtxn, task.status, |bitmap| { bitmap.insert(task.uid); })?; } if old_task.kind.as_kind() != task.kind.as_kind() { self.update_kind(wtxn, old_task.kind.as_kind(), |bitmap| { bitmap.remove(task.uid); })?; self.update_kind(wtxn, task.kind.as_kind(), |bitmap| { bitmap.insert(task.uid); })?; } assert_eq!( old_task.enqueued_at, task.enqueued_at, "Cannot update a task's enqueued_at time" ); if old_task.started_at != task.started_at { assert!(old_task.started_at.is_none(), "Cannot update a task's started_at time"); if let Some(started_at) = task.started_at { insert_task_datetime(wtxn, self.started_at, started_at, task.uid)?; } } if old_task.finished_at != task.finished_at { assert!(old_task.finished_at.is_none(), "Cannot update a task's finished_at time"); if let Some(finished_at) = task.finished_at { insert_task_datetime(wtxn, self.finished_at, finished_at, task.uid)?; } } self.all_tasks.put(wtxn, &BEU32::new(task.uid), task)?; Ok(()) } /// Returns the whole set of tasks that belongs to this index. pub(crate) fn index_tasks(&self, rtxn: &RoTxn, index: &str) -> Result { Ok(self.index_tasks.get(rtxn, index)?.unwrap_or_default()) } pub(crate) fn update_index( &self, wtxn: &mut RwTxn, index: &str, f: impl Fn(&mut RoaringBitmap), ) -> Result<()> { let mut tasks = self.index_tasks(wtxn, index)?; f(&mut tasks); if tasks.is_empty() { self.index_tasks.delete(wtxn, index)?; } else { self.index_tasks.put(wtxn, index, &tasks)?; } Ok(()) } pub(crate) fn get_status(&self, rtxn: &RoTxn, status: Status) -> Result { match status { Status::Processing => { let tasks = self .processing_tasks .read() .map_err(|_| Error::CorruptedTaskQueue)? .processing .clone(); Ok(tasks) } status => Ok(self.status.get(rtxn, &status)?.unwrap_or_default()), } } pub(crate) fn put_status( &self, wtxn: &mut RwTxn, status: Status, bitmap: &RoaringBitmap, ) -> Result<()> { Ok(self.status.put(wtxn, &status, bitmap)?) } pub(crate) fn update_status( &self, wtxn: &mut RwTxn, status: Status, f: impl Fn(&mut RoaringBitmap), ) -> Result<()> { let mut tasks = self.get_status(wtxn, status)?; f(&mut tasks); self.put_status(wtxn, status, &tasks)?; Ok(()) } pub(crate) fn get_kind(&self, rtxn: &RoTxn, kind: Kind) -> Result { Ok(self.kind.get(rtxn, &kind)?.unwrap_or_default()) } pub(crate) fn put_kind( &self, wtxn: &mut RwTxn, kind: Kind, bitmap: &RoaringBitmap, ) -> Result<()> { Ok(self.kind.put(wtxn, &kind, bitmap)?) } pub(crate) fn update_kind( &self, wtxn: &mut RwTxn, kind: Kind, f: impl Fn(&mut RoaringBitmap), ) -> Result<()> { let mut tasks = self.get_kind(wtxn, kind)?; f(&mut tasks); self.put_kind(wtxn, kind, &tasks)?; Ok(()) } } pub(crate) fn insert_task_datetime( wtxn: &mut RwTxn, database: Database, CboRoaringBitmapCodec>, time: OffsetDateTime, task_id: TaskId, ) -> Result<()> { let timestamp = BEI128::new(time.unix_timestamp_nanos()); let mut task_ids = database.get(wtxn, ×tamp)?.unwrap_or_default(); task_ids.insert(task_id); database.put(wtxn, ×tamp, &RoaringBitmap::from_iter([task_id]))?; Ok(()) } pub(crate) fn remove_task_datetime( wtxn: &mut RwTxn, database: Database, CboRoaringBitmapCodec>, time: OffsetDateTime, task_id: TaskId, ) -> Result<()> { let timestamp = BEI128::new(time.unix_timestamp_nanos()); if let Some(mut existing) = database.get(wtxn, ×tamp)? { existing.remove(task_id); if existing.is_empty() { database.delete(wtxn, ×tamp)?; } else { database.put(wtxn, ×tamp, &RoaringBitmap::from_iter([task_id]))?; } } Ok(()) } pub(crate) fn keep_tasks_within_datetimes( rtxn: &RoTxn, tasks: &mut RoaringBitmap, database: Database, CboRoaringBitmapCodec>, after: Option, before: Option, ) -> Result<()> { let (start, end) = match (&after, &before) { (None, None) => return Ok(()), (None, Some(before)) => (Bound::Unbounded, Bound::Excluded(*before)), (Some(after), None) => (Bound::Excluded(*after), Bound::Unbounded), (Some(after), Some(before)) => (Bound::Excluded(*after), Bound::Excluded(*before)), }; let mut collected_task_ids = RoaringBitmap::new(); let start = map_bound(start, |b| BEI128::new(b.unix_timestamp_nanos())); let end = map_bound(end, |b| BEI128::new(b.unix_timestamp_nanos())); let iter = database.range(rtxn, &(start, end))?; for r in iter { let (_timestamp, task_ids) = r?; collected_task_ids |= task_ids; } *tasks &= collected_task_ids; Ok(()) } // TODO: remove when Bound::map ( https://github.com/rust-lang/rust/issues/86026 ) is available on stable fn map_bound(bound: Bound, map: impl FnOnce(T) -> U) -> Bound { match bound { Bound::Included(x) => Bound::Included(map(x)), Bound::Excluded(x) => Bound::Excluded(map(x)), Bound::Unbounded => Bound::Unbounded, } } pub fn swap_index_uid_in_task(task: &mut Task, swap: (&str, &str)) { use KindWithContent as K; let mut index_uids = vec![]; match &mut task.kind { K::DocumentAdditionOrUpdate { index_uid, .. } => index_uids.push(index_uid), K::DocumentDeletion { index_uid, .. } => index_uids.push(index_uid), K::DocumentClear { index_uid } => index_uids.push(index_uid), K::SettingsUpdate { index_uid, .. } => index_uids.push(index_uid), K::IndexDeletion { index_uid } => index_uids.push(index_uid), K::IndexCreation { index_uid, .. } => index_uids.push(index_uid), K::IndexUpdate { index_uid, .. } => index_uids.push(index_uid), K::IndexSwap { swaps } => { for (lhs, rhs) in swaps.iter_mut() { if lhs == swap.0 || lhs == swap.1 { index_uids.push(lhs); } if rhs == swap.0 || rhs == swap.1 { index_uids.push(rhs); } } } K::TaskCancelation { .. } | K::TaskDeletion { .. } | K::DumpCreation { .. } | K::Snapshot => {} }; for index_uid in index_uids { if index_uid == swap.0 { *index_uid = swap.1.to_owned(); } else if index_uid == swap.1 { *index_uid = swap.0.to_owned(); } } } #[cfg(test)] use meilisearch_types::tasks::Details; #[cfg(test)] impl IndexScheduler { /// Asserts that the index scheduler's content is internally consistent. pub fn assert_internally_consistent(&self) { let rtxn = self.env.read_txn().unwrap(); for task in self.all_tasks.iter(&rtxn).unwrap() { let (task_id, task) = task.unwrap(); let task_id = task_id.get(); let task_index_uid = task.index_uid().map(ToOwned::to_owned); let Task { uid, enqueued_at, started_at, finished_at, error: _, canceled_by, details, status, kind, } = task; assert_eq!(uid, task.uid); if let Some(task_index_uid) = &task_index_uid { assert!(self .index_tasks .get(&rtxn, task_index_uid.as_str()) .unwrap() .unwrap() .contains(task.uid)); } let db_enqueued_at = self .enqueued_at .get(&rtxn, &BEI128::new(enqueued_at.unix_timestamp_nanos())) .unwrap() .unwrap(); assert!(db_enqueued_at.contains(task_id)); if let Some(started_at) = started_at { let db_started_at = self .started_at .get(&rtxn, &BEI128::new(started_at.unix_timestamp_nanos())) .unwrap() .unwrap(); assert!(db_started_at.contains(task_id)); } if let Some(finished_at) = finished_at { let db_finished_at = self .finished_at .get(&rtxn, &BEI128::new(finished_at.unix_timestamp_nanos())) .unwrap() .unwrap(); assert!(db_finished_at.contains(task_id)); } if let Some(canceled_by) = canceled_by { let db_canceled_tasks = self.get_status(&rtxn, Status::Canceled).unwrap(); assert!(db_canceled_tasks.contains(canceled_by)); let db_canceling_task = self.get_task(&rtxn, canceled_by).unwrap().unwrap(); assert_eq!(db_canceling_task.status, Status::Succeeded); match db_canceling_task.kind { KindWithContent::TaskCancelation { query: _, tasks } => { assert!(tasks.contains(uid)); } _ => panic!(), } } match details { Some(details) => match details { Details::IndexSwap { swaps } => { todo!() } Details::DocumentAdditionOrUpdate { received_documents, indexed_documents } => { assert_eq!(kind.as_kind(), Kind::DocumentAdditionOrUpdate); if let Some(indexed_documents) = indexed_documents { assert_eq!(status, Status::Succeeded); assert!(indexed_documents <= received_documents); } else { assert_ne!(status, Status::Succeeded); } } Details::SettingsUpdate { settings: _ } => { assert_eq!(kind.as_kind(), Kind::SettingsUpdate); } Details::IndexInfo { primary_key: pk1 } => match &kind { KindWithContent::IndexCreation { index_uid, primary_key: pk2 } | KindWithContent::IndexUpdate { index_uid, primary_key: pk2 } => { self.index_tasks .get(&rtxn, index_uid.as_str()) .unwrap() .unwrap() .contains(uid); assert_eq!(&pk1, pk2); } _ => panic!(), }, Details::DocumentDeletion { received_document_ids, deleted_documents } => { if let Some(deleted_documents) = deleted_documents { assert_eq!(status, Status::Succeeded); assert!(deleted_documents <= received_document_ids as u64); assert_eq!(kind.as_kind(), Kind::DocumentDeletion); match &kind { KindWithContent::DocumentDeletion { index_uid, documents_ids } => { assert_eq!(&task_index_uid.unwrap(), index_uid); assert!(documents_ids.len() >= received_document_ids); } _ => panic!(), } } else { assert_ne!(status, Status::Succeeded); } } Details::ClearAll { deleted_documents } => { assert!(matches!( kind.as_kind(), Kind::DocumentDeletion | Kind::IndexDeletion )); if deleted_documents.is_some() { assert_eq!(status, Status::Succeeded); } else { assert_ne!(status, Status::Succeeded); } } Details::TaskCancelation { matched_tasks, canceled_tasks, original_query } => { if let Some(canceled_tasks) = canceled_tasks { assert_eq!(status, Status::Succeeded); assert!(canceled_tasks <= matched_tasks); match &kind { KindWithContent::TaskCancelation { query, tasks } => { assert_eq!(query, &original_query); assert_eq!(tasks.len(), matched_tasks); } _ => panic!(), } } else { assert_ne!(status, Status::Succeeded); } } Details::TaskDeletion { matched_tasks, deleted_tasks, original_query } => { if let Some(deleted_tasks) = deleted_tasks { assert_eq!(status, Status::Succeeded); assert!(deleted_tasks <= matched_tasks); match &kind { KindWithContent::TaskDeletion { query, tasks } => { assert_eq!(query, &original_query); assert_eq!(tasks.len(), matched_tasks); } _ => panic!(), } } else { assert_ne!(status, Status::Succeeded); } } Details::Dump { dump_uid: d1 } => { assert!( matches!(&kind, KindWithContent::DumpExport { dump_uid: d2, keys: _, instance_uid: _ } if &d1 == d2 ) ); } }, None => (), } assert!(self.get_status(&rtxn, status).unwrap().contains(uid)); assert!(self.get_kind(&rtxn, kind.as_kind()).unwrap().contains(uid)); match kind { KindWithContent::DocumentAdditionOrUpdate { content_file, .. } => match status { Status::Enqueued | Status::Processing => { assert!(self.file_store.__all_uuids().contains(&content_file)); } Status::Succeeded | Status::Failed | Status::Canceled => { assert!(!self.file_store.__all_uuids().contains(&content_file)); } }, _ => (), } } } }