/*! This module handles the creation and processing of batch operations. A batch is a combination of multiple tasks that can be processed at once. Executing a batch operation should always be functionally equivalent to executing each of its tasks' operations individually and in order. For example, if the user sends two tasks: 1. import documents X 2. import documents Y We can combine the two tasks in a single batch: 1. import documents X and Y Processing this batch is functionally equivalent to processing the two tasks individally, but should be much faster since we are only performing one indexing operation. */ use std::collections::{BTreeSet, HashSet}; use std::ffi::OsStr; use std::fmt; use std::fs::{self, File}; use std::io::BufWriter; use dump::IndexMetadata; use log::{debug, error, info, trace}; use meilisearch_types::error::Code; use meilisearch_types::heed::{RoTxn, RwTxn}; use meilisearch_types::milli::documents::{obkv_to_object, DocumentsBatchReader}; use meilisearch_types::milli::heed::CompactionOption; use meilisearch_types::milli::update::{ IndexDocumentsConfig, IndexDocumentsMethod, IndexerConfig, Settings as MilliSettings, }; use meilisearch_types::milli::{self, Filter}; use meilisearch_types::settings::{apply_settings_to_builder, Settings, Unchecked}; use meilisearch_types::tasks::{Details, IndexSwap, Kind, KindWithContent, Status, Task}; use meilisearch_types::{compression, Index, VERSION_FILE_NAME}; use roaring::RoaringBitmap; use time::macros::format_description; use time::OffsetDateTime; use uuid::Uuid; use crate::autobatcher::{self, BatchKind}; use crate::utils::{self, swap_index_uid_in_task}; use crate::{Error, IndexScheduler, MustStopProcessing, ProcessingTasks, Result, TaskId}; /// Represents a combination of tasks that can all be processed at the same time. /// /// A batch contains the set of tasks that it represents (accessible through /// [`self.ids()`](Batch::ids)), as well as additional information on how to /// be processed. #[derive(Debug)] pub(crate) enum Batch { TaskCancelation { /// The task cancelation itself. task: Task, /// The date and time at which the previously processing tasks started. previous_started_at: OffsetDateTime, /// The list of tasks that were processing when this task cancelation appeared. previous_processing_tasks: RoaringBitmap, }, TaskDeletion(Task), SnapshotCreation(Vec), Dump(Task), IndexOperation { op: IndexOperation, must_create_index: bool, }, IndexCreation { index_uid: String, primary_key: Option, task: Task, }, IndexUpdate { index_uid: String, primary_key: Option, task: Task, }, IndexDeletion { index_uid: String, tasks: Vec, index_has_been_created: bool, }, IndexSwap { task: Task, }, } #[derive(Debug)] pub(crate) enum DocumentOperation { Add(Uuid), Delete(Vec), } /// A [batch](Batch) that combines multiple tasks operating on an index. #[derive(Debug)] pub(crate) enum IndexOperation { DocumentOperation { index_uid: String, primary_key: Option, method: IndexDocumentsMethod, documents_counts: Vec, operations: Vec, tasks: Vec, }, IndexDocumentDeletionByFilter { index_uid: String, task: Task, }, DocumentClear { index_uid: String, tasks: Vec, }, Settings { index_uid: String, // The boolean indicates if it's a settings deletion or creation. settings: Vec<(bool, Settings)>, tasks: Vec, }, DocumentClearAndSetting { index_uid: String, cleared_tasks: Vec, // The boolean indicates if it's a settings deletion or creation. settings: Vec<(bool, Settings)>, settings_tasks: Vec, }, SettingsAndDocumentOperation { index_uid: String, primary_key: Option, method: IndexDocumentsMethod, documents_counts: Vec, operations: Vec, document_import_tasks: Vec, // The boolean indicates if it's a settings deletion or creation. settings: Vec<(bool, Settings)>, settings_tasks: Vec, }, } impl Batch { /// Return the task ids associated with this batch. pub fn ids(&self) -> Vec { match self { Batch::TaskCancelation { task, .. } | Batch::TaskDeletion(task) | Batch::Dump(task) | Batch::IndexCreation { task, .. } | Batch::IndexUpdate { task, .. } => vec![task.uid], Batch::SnapshotCreation(tasks) | Batch::IndexDeletion { tasks, .. } => { tasks.iter().map(|task| task.uid).collect() } Batch::IndexOperation { op, .. } => match op { IndexOperation::DocumentOperation { tasks, .. } | IndexOperation::Settings { tasks, .. } | IndexOperation::DocumentClear { tasks, .. } => { tasks.iter().map(|task| task.uid).collect() } IndexOperation::IndexDocumentDeletionByFilter { task, .. } => vec![task.uid], IndexOperation::SettingsAndDocumentOperation { document_import_tasks: tasks, settings_tasks: other, .. } | IndexOperation::DocumentClearAndSetting { cleared_tasks: tasks, settings_tasks: other, .. } => tasks.iter().chain(other).map(|task| task.uid).collect(), }, Batch::IndexSwap { task } => vec![task.uid], } } /// Return the index UID associated with this batch pub fn index_uid(&self) -> Option<&str> { use Batch::*; match self { TaskCancelation { .. } | TaskDeletion(_) | SnapshotCreation(_) | Dump(_) | IndexSwap { .. } => None, IndexOperation { op, .. } => Some(op.index_uid()), IndexCreation { index_uid, .. } | IndexUpdate { index_uid, .. } | IndexDeletion { index_uid, .. } => Some(index_uid), } } } impl fmt::Display for Batch { /// A text used when we debug the profiling reports. fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { let index_uid = self.index_uid(); let tasks = self.ids(); match self { Batch::TaskCancelation { .. } => f.write_str("TaskCancelation")?, Batch::TaskDeletion(_) => f.write_str("TaskDeletion")?, Batch::SnapshotCreation(_) => f.write_str("SnapshotCreation")?, Batch::Dump(_) => f.write_str("Dump")?, Batch::IndexOperation { op, .. } => write!(f, "{op}")?, Batch::IndexCreation { .. } => f.write_str("IndexCreation")?, Batch::IndexUpdate { .. } => f.write_str("IndexUpdate")?, Batch::IndexDeletion { .. } => f.write_str("IndexDeletion")?, Batch::IndexSwap { .. } => f.write_str("IndexSwap")?, }; match index_uid { Some(name) => f.write_fmt(format_args!(" on {name:?} from tasks: {tasks:?}")), None => f.write_fmt(format_args!(" from tasks: {tasks:?}")), } } } impl IndexOperation { pub fn index_uid(&self) -> &str { match self { IndexOperation::DocumentOperation { index_uid, .. } | IndexOperation::IndexDocumentDeletionByFilter { index_uid, .. } | IndexOperation::DocumentClear { index_uid, .. } | IndexOperation::Settings { index_uid, .. } | IndexOperation::DocumentClearAndSetting { index_uid, .. } | IndexOperation::SettingsAndDocumentOperation { index_uid, .. } => index_uid, } } } impl fmt::Display for IndexOperation { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { match self { IndexOperation::DocumentOperation { .. } => { f.write_str("IndexOperation::DocumentOperation") } IndexOperation::IndexDocumentDeletionByFilter { .. } => { f.write_str("IndexOperation::IndexDocumentDeletionByFilter") } IndexOperation::DocumentClear { .. } => f.write_str("IndexOperation::DocumentClear"), IndexOperation::Settings { .. } => f.write_str("IndexOperation::Settings"), IndexOperation::DocumentClearAndSetting { .. } => { f.write_str("IndexOperation::DocumentClearAndSetting") } IndexOperation::SettingsAndDocumentOperation { .. } => { f.write_str("IndexOperation::SettingsAndDocumentOperation") } } } } impl IndexScheduler { /// Convert an [`BatchKind`](crate::autobatcher::BatchKind) into a [`Batch`]. /// /// ## Arguments /// - `rtxn`: read transaction /// - `index_uid`: name of the index affected by the operations of the autobatch /// - `batch`: the result of the autobatcher pub(crate) fn create_next_batch_index( &self, rtxn: &RoTxn, index_uid: String, batch: BatchKind, must_create_index: bool, ) -> Result> { match batch { BatchKind::DocumentClear { ids } => Ok(Some(Batch::IndexOperation { op: IndexOperation::DocumentClear { tasks: self.get_existing_tasks(rtxn, ids)?, index_uid, }, must_create_index, })), BatchKind::DocumentDeletionByFilter { id } => { let task = self.get_task(rtxn, id)?.ok_or(Error::CorruptedTaskQueue)?; match &task.kind { KindWithContent::DocumentDeletionByFilter { index_uid, .. } => { Ok(Some(Batch::IndexOperation { op: IndexOperation::IndexDocumentDeletionByFilter { index_uid: index_uid.clone(), task, }, must_create_index: false, })) } _ => unreachable!(), } } BatchKind::DocumentOperation { method, operation_ids, .. } => { let tasks = self.get_existing_tasks(rtxn, operation_ids)?; let primary_key = tasks .iter() .find_map(|task| match task.kind { KindWithContent::DocumentAdditionOrUpdate { ref primary_key, .. } => { // we want to stop on the first document addition Some(primary_key.clone()) } KindWithContent::DocumentDeletion { .. } => None, _ => unreachable!(), }) .flatten(); let mut documents_counts = Vec::new(); let mut operations = Vec::new(); for task in tasks.iter() { match task.kind { KindWithContent::DocumentAdditionOrUpdate { content_file, documents_count, .. } => { documents_counts.push(documents_count); operations.push(DocumentOperation::Add(content_file)); } KindWithContent::DocumentDeletion { ref documents_ids, .. } => { documents_counts.push(documents_ids.len() as u64); operations.push(DocumentOperation::Delete(documents_ids.clone())); } _ => unreachable!(), } } Ok(Some(Batch::IndexOperation { op: IndexOperation::DocumentOperation { index_uid, primary_key, method, documents_counts, operations, tasks, }, must_create_index, })) } BatchKind::DocumentDeletion { deletion_ids } => { let tasks = self.get_existing_tasks(rtxn, deletion_ids)?; let mut operations = Vec::with_capacity(tasks.len()); let mut documents_counts = Vec::with_capacity(tasks.len()); for task in &tasks { match task.kind { KindWithContent::DocumentDeletion { ref documents_ids, .. } => { operations.push(DocumentOperation::Delete(documents_ids.clone())); documents_counts.push(documents_ids.len() as u64); } _ => unreachable!(), } } Ok(Some(Batch::IndexOperation { op: IndexOperation::DocumentOperation { index_uid, primary_key: None, method: IndexDocumentsMethod::ReplaceDocuments, documents_counts, operations, tasks, }, must_create_index, })) } BatchKind::Settings { settings_ids, .. } => { let tasks = self.get_existing_tasks(rtxn, settings_ids)?; let mut settings = Vec::new(); for task in &tasks { match task.kind { KindWithContent::SettingsUpdate { ref new_settings, is_deletion, .. } => settings.push((is_deletion, *new_settings.clone())), _ => unreachable!(), } } Ok(Some(Batch::IndexOperation { op: IndexOperation::Settings { index_uid, settings, tasks }, must_create_index, })) } BatchKind::ClearAndSettings { other, settings_ids, allow_index_creation } => { let (index_uid, settings, settings_tasks) = match self .create_next_batch_index( rtxn, index_uid, BatchKind::Settings { settings_ids, allow_index_creation }, must_create_index, )? .unwrap() { Batch::IndexOperation { op: IndexOperation::Settings { index_uid, settings, tasks, .. }, .. } => (index_uid, settings, tasks), _ => unreachable!(), }; let (index_uid, cleared_tasks) = match self .create_next_batch_index( rtxn, index_uid, BatchKind::DocumentClear { ids: other }, must_create_index, )? .unwrap() { Batch::IndexOperation { op: IndexOperation::DocumentClear { index_uid, tasks }, .. } => (index_uid, tasks), _ => unreachable!(), }; Ok(Some(Batch::IndexOperation { op: IndexOperation::DocumentClearAndSetting { index_uid, cleared_tasks, settings, settings_tasks, }, must_create_index, })) } BatchKind::SettingsAndDocumentOperation { settings_ids, method, allow_index_creation, primary_key, operation_ids, } => { let settings = self.create_next_batch_index( rtxn, index_uid.clone(), BatchKind::Settings { settings_ids, allow_index_creation }, must_create_index, )?; let document_import = self.create_next_batch_index( rtxn, index_uid.clone(), BatchKind::DocumentOperation { method, allow_index_creation, primary_key, operation_ids, }, must_create_index, )?; match (document_import, settings) { ( Some(Batch::IndexOperation { op: IndexOperation::DocumentOperation { primary_key, documents_counts, operations, tasks: document_import_tasks, .. }, .. }), Some(Batch::IndexOperation { op: IndexOperation::Settings { settings, tasks: settings_tasks, .. }, .. }), ) => Ok(Some(Batch::IndexOperation { op: IndexOperation::SettingsAndDocumentOperation { index_uid, primary_key, method, documents_counts, operations, document_import_tasks, settings, settings_tasks, }, must_create_index, })), _ => unreachable!(), } } BatchKind::IndexCreation { id } => { let task = self.get_task(rtxn, id)?.ok_or(Error::CorruptedTaskQueue)?; let (index_uid, primary_key) = match &task.kind { KindWithContent::IndexCreation { index_uid, primary_key } => { (index_uid.clone(), primary_key.clone()) } _ => unreachable!(), }; Ok(Some(Batch::IndexCreation { index_uid, primary_key, task })) } BatchKind::IndexUpdate { id } => { let task = self.get_task(rtxn, id)?.ok_or(Error::CorruptedTaskQueue)?; let primary_key = match &task.kind { KindWithContent::IndexUpdate { primary_key, .. } => primary_key.clone(), _ => unreachable!(), }; Ok(Some(Batch::IndexUpdate { index_uid, primary_key, task })) } BatchKind::IndexDeletion { ids } => Ok(Some(Batch::IndexDeletion { index_uid, index_has_been_created: must_create_index, tasks: self.get_existing_tasks(rtxn, ids)?, })), BatchKind::IndexSwap { id } => { let task = self.get_task(rtxn, id)?.ok_or(Error::CorruptedTaskQueue)?; Ok(Some(Batch::IndexSwap { task })) } } } /// Create the next batch to be processed; /// 1. We get the *last* task to cancel. /// 2. We get the *next* task to delete. /// 3. We get the *next* snapshot to process. /// 4. We get the *next* dump to process. /// 5. We get the *next* tasks to process for a specific index. pub(crate) fn create_next_batch(&self, rtxn: &RoTxn) -> Result> { #[cfg(test)] self.maybe_fail(crate::tests::FailureLocation::InsideCreateBatch)?; puffin::profile_function!(); let enqueued = &self.get_status(rtxn, Status::Enqueued)?; let to_cancel = self.get_kind(rtxn, Kind::TaskCancelation)? & enqueued; // 1. we get the last task to cancel. if let Some(task_id) = to_cancel.max() { // We retrieve the tasks that were processing before this tasks cancelation started. // We must *not* reset the processing tasks before calling this method. let ProcessingTasks { started_at, processing } = &*self.processing_tasks.read().unwrap(); return Ok(Some(Batch::TaskCancelation { task: self.get_task(rtxn, task_id)?.ok_or(Error::CorruptedTaskQueue)?, previous_started_at: *started_at, previous_processing_tasks: processing.clone(), })); } // 2. we get the next task to delete let to_delete = self.get_kind(rtxn, Kind::TaskDeletion)? & enqueued; if let Some(task_id) = to_delete.min() { let task = self.get_task(rtxn, task_id)?.ok_or(Error::CorruptedTaskQueue)?; return Ok(Some(Batch::TaskDeletion(task))); } // 3. we batch the snapshot. let to_snapshot = self.get_kind(rtxn, Kind::SnapshotCreation)? & enqueued; if !to_snapshot.is_empty() { return Ok(Some(Batch::SnapshotCreation(self.get_existing_tasks(rtxn, to_snapshot)?))); } // 4. we batch the dumps. let to_dump = self.get_kind(rtxn, Kind::DumpCreation)? & enqueued; if let Some(to_dump) = to_dump.min() { return Ok(Some(Batch::Dump( self.get_task(rtxn, to_dump)?.ok_or(Error::CorruptedTaskQueue)?, ))); } // 5. We make a batch from the unprioritised tasks. Start by taking the next enqueued task. let task_id = if let Some(task_id) = enqueued.min() { task_id } else { return Ok(None) }; let task = self.get_task(rtxn, task_id)?.ok_or(Error::CorruptedTaskQueue)?; // If the task is not associated with any index, verify that it is an index swap and // create the batch directly. Otherwise, get the index name associated with the task // and use the autobatcher to batch the enqueued tasks associated with it let index_name = if let Some(&index_name) = task.indexes().first() { index_name } else { assert!(matches!(&task.kind, KindWithContent::IndexSwap { swaps } if swaps.is_empty())); return Ok(Some(Batch::IndexSwap { task })); }; let index_already_exists = self.index_mapper.exists(rtxn, index_name)?; let mut primary_key = None; if index_already_exists { let index = self.index_mapper.index(rtxn, index_name)?; let rtxn = index.read_txn()?; primary_key = index.primary_key(&rtxn)?.map(|pk| pk.to_string()); } let index_tasks = self.index_tasks(rtxn, index_name)? & enqueued; // If autobatching is disabled we only take one task at a time. // Otherwise, we take only a maximum of tasks to create batches. let tasks_limit = if self.autobatching_enabled { self.max_number_of_batched_tasks } else { 1 }; let enqueued = index_tasks .into_iter() .take(tasks_limit) .map(|task_id| { self.get_task(rtxn, task_id) .and_then(|task| task.ok_or(Error::CorruptedTaskQueue)) .map(|task| (task.uid, task.kind)) }) .collect::>>()?; if let Some((batchkind, create_index)) = autobatcher::autobatch(enqueued, index_already_exists, primary_key.as_deref()) { return self.create_next_batch_index( rtxn, index_name.to_string(), batchkind, create_index, ); } // If we found no tasks then we were notified for something that got autobatched // somehow and there is nothing to do. Ok(None) } /// Apply the operation associated with the given batch. /// /// ## Return /// The list of tasks that were processed. The metadata of each task in the returned /// list is updated accordingly, with the exception of the its date fields /// [`finished_at`](meilisearch_types::tasks::Task::finished_at) and [`started_at`](meilisearch_types::tasks::Task::started_at). pub(crate) fn process_batch(&self, batch: Batch) -> Result> { #[cfg(test)] { self.maybe_fail(crate::tests::FailureLocation::InsideProcessBatch)?; self.maybe_fail(crate::tests::FailureLocation::PanicInsideProcessBatch)?; self.breakpoint(crate::Breakpoint::InsideProcessBatch); } puffin::profile_function!(batch.to_string()); match batch { Batch::TaskCancelation { mut task, previous_started_at, previous_processing_tasks } => { // 1. Retrieve the tasks that matched the query at enqueue-time. let matched_tasks = if let KindWithContent::TaskCancelation { tasks, query: _ } = &task.kind { tasks } else { unreachable!() }; let mut wtxn = self.env.write_txn()?; let canceled_tasks_content_uuids = self.cancel_matched_tasks( &mut wtxn, task.uid, matched_tasks, previous_started_at, &previous_processing_tasks, )?; task.status = Status::Succeeded; match &mut task.details { Some(Details::TaskCancelation { matched_tasks: _, canceled_tasks, original_filter: _, }) => { *canceled_tasks = Some(canceled_tasks_content_uuids.len() as u64); } _ => unreachable!(), } // We must only remove the content files if the transaction is successfully committed // and if errors occurs when we are deleting files we must do our best to delete // everything. We do not return the encountered errors when deleting the content // files as it is not a breaking operation and we can safely continue our job. match wtxn.commit() { Ok(()) => { for content_uuid in canceled_tasks_content_uuids { if let Err(error) = self.delete_update_file(content_uuid) { error!( "We failed deleting the content file indentified as {}: {}", content_uuid, error ) } } } Err(e) => return Err(e.into()), } Ok(vec![task]) } Batch::TaskDeletion(mut task) => { // 1. Retrieve the tasks that matched the query at enqueue-time. let matched_tasks = if let KindWithContent::TaskDeletion { tasks, query: _ } = &task.kind { tasks } else { unreachable!() }; let mut wtxn = self.env.write_txn()?; let deleted_tasks_count = self.delete_matched_tasks(&mut wtxn, matched_tasks)?; task.status = Status::Succeeded; match &mut task.details { Some(Details::TaskDeletion { matched_tasks: _, deleted_tasks, original_filter: _, }) => { *deleted_tasks = Some(deleted_tasks_count); } _ => unreachable!(), } wtxn.commit()?; Ok(vec![task]) } Batch::SnapshotCreation(mut tasks) => { fs::create_dir_all(&self.snapshots_path)?; let temp_snapshot_dir = tempfile::tempdir()?; // 1. Snapshot the version file. let dst = temp_snapshot_dir.path().join(VERSION_FILE_NAME); fs::copy(&self.version_file_path, dst)?; // 2. Snapshot the index-scheduler LMDB env // // When we call copy_to_file, LMDB opens a read transaction by itself, // we can't provide our own. It is an issue as we would like to know // the update files to copy but new ones can be enqueued between the copy // of the env and the new transaction we open to retrieve the enqueued tasks. // So we prefer opening a new transaction after copying the env and copy more // update files than not enough. // // Note that there cannot be any update files deleted between those // two read operations as the task processing is synchronous. // 2.1 First copy the LMDB env of the index-scheduler let dst = temp_snapshot_dir.path().join("tasks"); fs::create_dir_all(&dst)?; self.env.copy_to_file(dst.join("data.mdb"), CompactionOption::Enabled)?; // 2.2 Create a read transaction on the index-scheduler let rtxn = self.env.read_txn()?; // 2.3 Create the update files directory let update_files_dir = temp_snapshot_dir.path().join("update_files"); fs::create_dir_all(&update_files_dir)?; // 2.4 Only copy the update files of the enqueued tasks for task_id in self.get_status(&rtxn, Status::Enqueued)? { let task = self.get_task(&rtxn, task_id)?.ok_or(Error::CorruptedTaskQueue)?; if let Some(content_uuid) = task.content_uuid() { let src = self.file_store.get_update_path(content_uuid); let dst = update_files_dir.join(content_uuid.to_string()); fs::copy(src, dst)?; } } // 3. Snapshot every indexes for result in self.index_mapper.index_mapping.iter(&rtxn)? { let (name, uuid) = result?; let index = self.index_mapper.index(&rtxn, name)?; let dst = temp_snapshot_dir.path().join("indexes").join(uuid.to_string()); fs::create_dir_all(&dst)?; index.copy_to_file(dst.join("data.mdb"), CompactionOption::Enabled)?; } drop(rtxn); // 4. Snapshot the auth LMDB env let dst = temp_snapshot_dir.path().join("auth"); fs::create_dir_all(&dst)?; // TODO We can't use the open_auth_store_env function here but we should let auth = milli::heed::EnvOpenOptions::new() .map_size(1024 * 1024 * 1024) // 1 GiB .max_dbs(2) .open(&self.auth_path)?; auth.copy_to_file(dst.join("data.mdb"), CompactionOption::Enabled)?; // 5. Copy and tarball the flat snapshot // 5.1 Find the original name of the database // TODO find a better way to get this path let mut base_path = self.env.path().to_owned(); base_path.pop(); let db_name = base_path.file_name().and_then(OsStr::to_str).unwrap_or("data.ms"); // 5.2 Tarball the content of the snapshot in a tempfile with a .snapshot extension let snapshot_path = self.snapshots_path.join(format!("{}.snapshot", db_name)); let temp_snapshot_file = tempfile::NamedTempFile::new_in(&self.snapshots_path)?; compression::to_tar_gz(temp_snapshot_dir.path(), temp_snapshot_file.path())?; let file = temp_snapshot_file.persist(snapshot_path)?; // 5.3 Change the permission to make the snapshot readonly let mut permissions = file.metadata()?.permissions(); permissions.set_readonly(true); #[cfg(unix)] { use std::os::unix::fs::PermissionsExt; #[allow(clippy::non_octal_unix_permissions)] // rwxrwxrwx permissions.set_mode(0b100100100); } file.set_permissions(permissions)?; for task in &mut tasks { task.status = Status::Succeeded; } Ok(tasks) } Batch::Dump(mut task) => { let started_at = OffsetDateTime::now_utc(); let (keys, instance_uid) = if let KindWithContent::DumpCreation { keys, instance_uid } = &task.kind { (keys, instance_uid) } else { unreachable!(); }; let dump = dump::DumpWriter::new(*instance_uid)?; // 1. dump the keys let mut dump_keys = dump.create_keys()?; for key in keys { dump_keys.push_key(key)?; } dump_keys.flush()?; let rtxn = self.env.read_txn()?; // 2. dump the tasks let mut dump_tasks = dump.create_tasks_queue()?; for ret in self.all_tasks.iter(&rtxn)? { if self.must_stop_processing.get() { return Err(Error::AbortedTask); } let (_, mut t) = ret?; let status = t.status; let content_file = t.content_uuid(); // In the case we're dumping ourselves we want to be marked as finished // to not loop over ourselves indefinitely. if t.uid == task.uid { let finished_at = OffsetDateTime::now_utc(); // We're going to fake the date because we don't know if everything is going to go well. // But we need to dump the task as finished and successful. // If something fail everything will be set appropriately in the end. t.status = Status::Succeeded; t.started_at = Some(started_at); t.finished_at = Some(finished_at); } let mut dump_content_file = dump_tasks.push_task(&t.into())?; // 2.1. Dump the `content_file` associated with the task if there is one and the task is not finished yet. if let Some(content_file) = content_file { if self.must_stop_processing.get() { return Err(Error::AbortedTask); } if status == Status::Enqueued { let content_file = self.file_store.get_update(content_file)?; let reader = DocumentsBatchReader::from_reader(content_file) .map_err(milli::Error::from)?; let (mut cursor, documents_batch_index) = reader.into_cursor_and_fields_index(); while let Some(doc) = cursor.next_document().map_err(milli::Error::from)? { dump_content_file.push_document(&obkv_to_object( &doc, &documents_batch_index, )?)?; } dump_content_file.flush()?; } } } dump_tasks.flush()?; // 3. Dump the indexes self.index_mapper.try_for_each_index(&rtxn, |uid, index| -> Result<()> { let rtxn = index.read_txn()?; let metadata = IndexMetadata { uid: uid.to_owned(), primary_key: index.primary_key(&rtxn)?.map(String::from), created_at: index.created_at(&rtxn)?, updated_at: index.updated_at(&rtxn)?, }; let mut index_dumper = dump.create_index(uid, &metadata)?; let fields_ids_map = index.fields_ids_map(&rtxn)?; let all_fields: Vec<_> = fields_ids_map.iter().map(|(id, _)| id).collect(); // 3.1. Dump the documents for ret in index.all_documents(&rtxn)? { if self.must_stop_processing.get() { return Err(Error::AbortedTask); } let (_id, doc) = ret?; let document = milli::obkv_to_json(&all_fields, &fields_ids_map, doc)?; index_dumper.push_document(&document)?; } // 3.2. Dump the settings let settings = meilisearch_types::settings::settings(index, &rtxn)?; index_dumper.settings(&settings)?; Ok(()) })?; // 4. Dump experimental feature settings let features = self.features().runtime_features(); dump.create_experimental_features(features)?; let dump_uid = started_at.format(format_description!( "[year repr:full][month repr:numerical][day padding:zero]-[hour padding:zero][minute padding:zero][second padding:zero][subsecond digits:3]" )).unwrap(); if self.must_stop_processing.get() { return Err(Error::AbortedTask); } let path = self.dumps_path.join(format!("{}.dump", dump_uid)); let file = File::create(path)?; dump.persist_to(BufWriter::new(file))?; // if we reached this step we can tell the scheduler we succeeded to dump ourselves. task.status = Status::Succeeded; task.details = Some(Details::Dump { dump_uid: Some(dump_uid) }); Ok(vec![task]) } Batch::IndexOperation { op, must_create_index } => { let index_uid = op.index_uid().to_string(); let index = if must_create_index { // create the index if it doesn't already exist let wtxn = self.env.write_txn()?; self.index_mapper.create_index(wtxn, &index_uid, None)? } else { let rtxn = self.env.read_txn()?; self.index_mapper.index(&rtxn, &index_uid)? }; // the index operation can take a long time, so save this handle to make it available to the search for the duration of the tick *self.currently_updating_index.write().unwrap() = Some((index_uid.clone(), index.clone())); let mut index_wtxn = index.write_txn()?; let tasks = self.apply_index_operation(&mut index_wtxn, &index, op)?; index_wtxn.commit()?; // if the update processed successfully, we're going to store the new // stats of the index. Since the tasks have already been processed and // this is a non-critical operation. If it fails, we should not fail // the entire batch. let res = || -> Result<()> { let index_rtxn = index.read_txn()?; let stats = crate::index_mapper::IndexStats::new(&index, &index_rtxn)?; let mut wtxn = self.env.write_txn()?; self.index_mapper.store_stats_of(&mut wtxn, &index_uid, &stats)?; wtxn.commit()?; Ok(()) }(); match res { Ok(_) => (), Err(e) => error!("Could not write the stats of the index {}", e), } Ok(tasks) } Batch::IndexCreation { index_uid, primary_key, task } => { let wtxn = self.env.write_txn()?; if self.index_mapper.exists(&wtxn, &index_uid)? { return Err(Error::IndexAlreadyExists(index_uid)); } self.index_mapper.create_index(wtxn, &index_uid, None)?; self.process_batch(Batch::IndexUpdate { index_uid, primary_key, task }) } Batch::IndexUpdate { index_uid, primary_key, mut task } => { let rtxn = self.env.read_txn()?; let index = self.index_mapper.index(&rtxn, &index_uid)?; if let Some(primary_key) = primary_key.clone() { let mut index_wtxn = index.write_txn()?; let mut builder = MilliSettings::new( &mut index_wtxn, &index, self.index_mapper.indexer_config(), ); builder.set_primary_key(primary_key); let must_stop_processing = self.must_stop_processing.clone(); builder.execute( |indexing_step| debug!("update: {:?}", indexing_step), || must_stop_processing.get(), )?; index_wtxn.commit()?; } // drop rtxn before starting a new wtxn on the same db rtxn.commit()?; task.status = Status::Succeeded; task.details = Some(Details::IndexInfo { primary_key }); // if the update processed successfully, we're going to store the new // stats of the index. Since the tasks have already been processed and // this is a non-critical operation. If it fails, we should not fail // the entire batch. let res = || -> Result<()> { let mut wtxn = self.env.write_txn()?; let index_rtxn = index.read_txn()?; let stats = crate::index_mapper::IndexStats::new(&index, &index_rtxn)?; self.index_mapper.store_stats_of(&mut wtxn, &index_uid, &stats)?; wtxn.commit()?; Ok(()) }(); match res { Ok(_) => (), Err(e) => error!("Could not write the stats of the index {}", e), } Ok(vec![task]) } Batch::IndexDeletion { index_uid, index_has_been_created, mut tasks } => { let wtxn = self.env.write_txn()?; // it's possible that the index doesn't exist let number_of_documents = || -> Result { let index = self.index_mapper.index(&wtxn, &index_uid)?; let index_rtxn = index.read_txn()?; Ok(index.number_of_documents(&index_rtxn)?) }() .unwrap_or_default(); // The write transaction is directly owned and committed inside. match self.index_mapper.delete_index(wtxn, &index_uid) { Ok(()) => (), Err(Error::IndexNotFound(_)) if index_has_been_created => (), Err(e) => return Err(e), } // We set all the tasks details to the default value. for task in &mut tasks { task.status = Status::Succeeded; task.details = match &task.kind { KindWithContent::IndexDeletion { .. } => { Some(Details::ClearAll { deleted_documents: Some(number_of_documents) }) } otherwise => otherwise.default_finished_details(), }; } Ok(tasks) } Batch::IndexSwap { mut task } => { let mut wtxn = self.env.write_txn()?; let swaps = if let KindWithContent::IndexSwap { swaps } = &task.kind { swaps } else { unreachable!() }; let mut not_found_indexes = BTreeSet::new(); for IndexSwap { indexes: (lhs, rhs) } in swaps { for index in [lhs, rhs] { let index_exists = self.index_mapper.index_exists(&wtxn, index)?; if !index_exists { not_found_indexes.insert(index); } } } if !not_found_indexes.is_empty() { if not_found_indexes.len() == 1 { return Err(Error::SwapIndexNotFound( not_found_indexes.into_iter().next().unwrap().clone(), )); } else { return Err(Error::SwapIndexesNotFound( not_found_indexes.into_iter().cloned().collect(), )); } } for swap in swaps { self.apply_index_swap(&mut wtxn, task.uid, &swap.indexes.0, &swap.indexes.1)?; } wtxn.commit()?; task.status = Status::Succeeded; Ok(vec![task]) } } } /// Swap the index `lhs` with the index `rhs`. fn apply_index_swap(&self, wtxn: &mut RwTxn, task_id: u32, lhs: &str, rhs: &str) -> Result<()> { // 1. Verify that both lhs and rhs are existing indexes let index_lhs_exists = self.index_mapper.index_exists(wtxn, lhs)?; if !index_lhs_exists { return Err(Error::IndexNotFound(lhs.to_owned())); } let index_rhs_exists = self.index_mapper.index_exists(wtxn, rhs)?; if !index_rhs_exists { return Err(Error::IndexNotFound(rhs.to_owned())); } // 2. Get the task set for index = name that appeared before the index swap task let mut index_lhs_task_ids = self.index_tasks(wtxn, lhs)?; index_lhs_task_ids.remove_range(task_id..); let mut index_rhs_task_ids = self.index_tasks(wtxn, rhs)?; index_rhs_task_ids.remove_range(task_id..); // 3. before_name -> new_name in the task's KindWithContent for task_id in &index_lhs_task_ids | &index_rhs_task_ids { let mut task = self.get_task(wtxn, task_id)?.ok_or(Error::CorruptedTaskQueue)?; swap_index_uid_in_task(&mut task, (lhs, rhs)); self.all_tasks.put(wtxn, &task_id, &task)?; } // 4. remove the task from indexuid = before_name // 5. add the task to indexuid = after_name self.update_index(wtxn, lhs, |lhs_tasks| { *lhs_tasks -= &index_lhs_task_ids; *lhs_tasks |= &index_rhs_task_ids; })?; self.update_index(wtxn, rhs, |rhs_tasks| { *rhs_tasks -= &index_rhs_task_ids; *rhs_tasks |= &index_lhs_task_ids; })?; // 6. Swap in the index mapper self.index_mapper.swap(wtxn, lhs, rhs)?; Ok(()) } /// Process the index operation on the given index. /// /// ## Return /// The list of processed tasks. fn apply_index_operation<'i>( &self, index_wtxn: &mut RwTxn<'i>, index: &'i Index, operation: IndexOperation, ) -> Result> { puffin::profile_function!(); match operation { IndexOperation::DocumentClear { mut tasks, .. } => { let count = milli::update::ClearDocuments::new(index_wtxn, index).execute()?; let mut first_clear_found = false; for task in &mut tasks { task.status = Status::Succeeded; // The first document clear will effectively delete every documents // in the database but the next ones will clear 0 documents. task.details = match &task.kind { KindWithContent::DocumentClear { .. } => { let count = if first_clear_found { 0 } else { count }; first_clear_found = true; Some(Details::ClearAll { deleted_documents: Some(count) }) } otherwise => otherwise.default_details(), }; } Ok(tasks) } IndexOperation::DocumentOperation { index_uid: _, primary_key, method, documents_counts: _, operations, mut tasks, } => { let mut primary_key_has_been_set = false; let must_stop_processing = self.must_stop_processing.clone(); let indexer_config = self.index_mapper.indexer_config(); if let Some(primary_key) = primary_key { match index.primary_key(index_wtxn)? { // if a primary key was set AND had already been defined in the index // but to a different value, we can make the whole batch fail. Some(pk) => { if primary_key != pk { return Err(milli::Error::from( milli::UserError::PrimaryKeyCannotBeChanged(pk.to_string()), ) .into()); } } // if the primary key was set and there was no primary key set for this index // we set it to the received value before starting the indexing process. None => { let mut builder = milli::update::Settings::new(index_wtxn, index, indexer_config); builder.set_primary_key(primary_key); builder.execute( |indexing_step| debug!("update: {:?}", indexing_step), || must_stop_processing.clone().get(), )?; primary_key_has_been_set = true; } } } let config = IndexDocumentsConfig { update_method: method, ..Default::default() }; let mut builder = milli::update::IndexDocuments::new( index_wtxn, index, indexer_config, config, |indexing_step| trace!("update: {:?}", indexing_step), || must_stop_processing.get(), )?; for (operation, task) in operations.into_iter().zip(tasks.iter_mut()) { match operation { DocumentOperation::Add(content_uuid) => { let content_file = self.file_store.get_update(content_uuid)?; let reader = DocumentsBatchReader::from_reader(content_file) .map_err(milli::Error::from)?; let (new_builder, user_result) = builder.add_documents(reader)?; builder = new_builder; let received_documents = if let Some(Details::DocumentAdditionOrUpdate { received_documents, .. }) = task.details { received_documents } else { // In the case of a `documentAdditionOrUpdate` the details MUST be set unreachable!(); }; match user_result { Ok(count) => { task.status = Status::Succeeded; task.details = Some(Details::DocumentAdditionOrUpdate { received_documents, indexed_documents: Some(count), }) } Err(e) => { task.status = Status::Failed; task.details = Some(Details::DocumentAdditionOrUpdate { received_documents, indexed_documents: Some(0), }); task.error = Some(milli::Error::from(e).into()); } } } DocumentOperation::Delete(document_ids) => { let (new_builder, user_result) = builder.remove_documents(document_ids)?; builder = new_builder; // Uses Invariant: remove documents actually always returns Ok for the inner result let count = user_result.unwrap(); let provided_ids = if let Some(Details::DocumentDeletion { provided_ids, .. }) = task.details { provided_ids } else { // In the case of a `documentAdditionOrUpdate` the details MUST be set unreachable!(); }; task.status = Status::Succeeded; task.details = Some(Details::DocumentDeletion { provided_ids, deleted_documents: Some(count), }); } } } if !tasks.iter().all(|res| res.error.is_some()) { let addition = builder.execute()?; info!("document addition done: {:?}", addition); } else if primary_key_has_been_set { // Everything failed but we've set a primary key. // We need to remove it. let mut builder = milli::update::Settings::new(index_wtxn, index, indexer_config); builder.reset_primary_key(); builder.execute( |indexing_step| trace!("update: {:?}", indexing_step), || must_stop_processing.clone().get(), )?; } Ok(tasks) } IndexOperation::IndexDocumentDeletionByFilter { mut task, index_uid: _ } => { let filter = if let KindWithContent::DocumentDeletionByFilter { filter_expr, .. } = &task.kind { filter_expr } else { unreachable!() }; let deleted_documents = delete_document_by_filter( index_wtxn, filter, self.index_mapper.indexer_config(), self.must_stop_processing.clone(), index, ); let original_filter = if let Some(Details::DocumentDeletionByFilter { original_filter, deleted_documents: _, }) = task.details { original_filter } else { // In the case of a `documentDeleteByFilter` the details MUST be set unreachable!(); }; match deleted_documents { Ok(deleted_documents) => { task.status = Status::Succeeded; task.details = Some(Details::DocumentDeletionByFilter { original_filter, deleted_documents: Some(deleted_documents), }); } Err(e) => { task.status = Status::Failed; task.details = Some(Details::DocumentDeletionByFilter { original_filter, deleted_documents: Some(0), }); task.error = Some(e.into()); } } Ok(vec![task]) } IndexOperation::Settings { index_uid: _, settings, mut tasks } => { let indexer_config = self.index_mapper.indexer_config(); let mut builder = milli::update::Settings::new(index_wtxn, index, indexer_config); for (task, (_, settings)) in tasks.iter_mut().zip(settings) { let checked_settings = settings.clone().check(); task.details = Some(Details::SettingsUpdate { settings: Box::new(settings) }); apply_settings_to_builder(&checked_settings, &mut builder); // We can apply the status right now and if an update fail later // the whole batch will be marked as failed. task.status = Status::Succeeded; } let must_stop_processing = self.must_stop_processing.clone(); builder.execute( |indexing_step| debug!("update: {:?}", indexing_step), || must_stop_processing.get(), )?; Ok(tasks) } IndexOperation::SettingsAndDocumentOperation { index_uid, primary_key, method, documents_counts, operations, document_import_tasks, settings, settings_tasks, } => { let settings_tasks = self.apply_index_operation( index_wtxn, index, IndexOperation::Settings { index_uid: index_uid.clone(), settings, tasks: settings_tasks, }, )?; let mut import_tasks = self.apply_index_operation( index_wtxn, index, IndexOperation::DocumentOperation { index_uid, primary_key, method, documents_counts, operations, tasks: document_import_tasks, }, )?; let mut tasks = settings_tasks; tasks.append(&mut import_tasks); Ok(tasks) } IndexOperation::DocumentClearAndSetting { index_uid, cleared_tasks, settings, settings_tasks, } => { let mut import_tasks = self.apply_index_operation( index_wtxn, index, IndexOperation::DocumentClear { index_uid: index_uid.clone(), tasks: cleared_tasks, }, )?; let settings_tasks = self.apply_index_operation( index_wtxn, index, IndexOperation::Settings { index_uid, settings, tasks: settings_tasks }, )?; let mut tasks = settings_tasks; tasks.append(&mut import_tasks); Ok(tasks) } } } /// Delete each given task from all the databases (if it is deleteable). /// /// Return the number of tasks that were actually deleted. fn delete_matched_tasks(&self, wtxn: &mut RwTxn, matched_tasks: &RoaringBitmap) -> Result { // 1. Remove from this list the tasks that we are not allowed to delete let enqueued_tasks = self.get_status(wtxn, Status::Enqueued)?; let processing_tasks = &self.processing_tasks.read().unwrap().processing.clone(); let all_task_ids = self.all_task_ids(wtxn)?; let mut to_delete_tasks = all_task_ids & matched_tasks; to_delete_tasks -= processing_tasks; to_delete_tasks -= enqueued_tasks; // 2. We now have a list of tasks to delete, delete them let mut affected_indexes = HashSet::new(); let mut affected_statuses = HashSet::new(); let mut affected_kinds = HashSet::new(); let mut affected_canceled_by = RoaringBitmap::new(); for task_id in to_delete_tasks.iter() { let task = self.get_task(wtxn, task_id)?.ok_or(Error::CorruptedTaskQueue)?; affected_indexes.extend(task.indexes().into_iter().map(|x| x.to_owned())); affected_statuses.insert(task.status); affected_kinds.insert(task.kind.as_kind()); // Note: don't delete the persisted task data since // we can only delete succeeded, failed, and canceled tasks. // In each of those cases, the persisted data is supposed to // have been deleted already. utils::remove_task_datetime(wtxn, self.enqueued_at, task.enqueued_at, task.uid)?; if let Some(started_at) = task.started_at { utils::remove_task_datetime(wtxn, self.started_at, started_at, task.uid)?; } if let Some(finished_at) = task.finished_at { utils::remove_task_datetime(wtxn, self.finished_at, finished_at, task.uid)?; } if let Some(canceled_by) = task.canceled_by { affected_canceled_by.insert(canceled_by); } } for index in affected_indexes { self.update_index(wtxn, &index, |bitmap| *bitmap -= &to_delete_tasks)?; } for status in affected_statuses { self.update_status(wtxn, status, |bitmap| *bitmap -= &to_delete_tasks)?; } for kind in affected_kinds { self.update_kind(wtxn, kind, |bitmap| *bitmap -= &to_delete_tasks)?; } for task in to_delete_tasks.iter() { self.all_tasks.delete(wtxn, &task)?; } for canceled_by in affected_canceled_by { if let Some(mut tasks) = self.canceled_by.get(wtxn, &canceled_by)? { tasks -= &to_delete_tasks; if tasks.is_empty() { self.canceled_by.delete(wtxn, &canceled_by)?; } else { self.canceled_by.put(wtxn, &canceled_by, &tasks)?; } } } Ok(to_delete_tasks.len()) } /// Cancel each given task from all the databases (if it is cancelable). /// /// Returns the content files that the transaction owner must delete if the commit is successful. fn cancel_matched_tasks( &self, wtxn: &mut RwTxn, cancel_task_id: TaskId, matched_tasks: &RoaringBitmap, previous_started_at: OffsetDateTime, previous_processing_tasks: &RoaringBitmap, ) -> Result> { let now = OffsetDateTime::now_utc(); // 1. Remove from this list the tasks that we are not allowed to cancel // Notice that only the _enqueued_ ones are cancelable and we should // have already aborted the indexation of the _processing_ ones let cancelable_tasks = self.get_status(wtxn, Status::Enqueued)?; let tasks_to_cancel = cancelable_tasks & matched_tasks; // 2. We now have a list of tasks to cancel, cancel them let mut content_files_to_delete = Vec::new(); for mut task in self.get_existing_tasks(wtxn, tasks_to_cancel.iter())? { if let Some(uuid) = task.content_uuid() { content_files_to_delete.push(uuid); } if previous_processing_tasks.contains(task.uid) { task.started_at = Some(previous_started_at); } task.status = Status::Canceled; task.canceled_by = Some(cancel_task_id); task.finished_at = Some(now); task.details = task.details.map(|d| d.to_failed()); self.update_task(wtxn, &task)?; } self.canceled_by.put(wtxn, &cancel_task_id, &tasks_to_cancel)?; Ok(content_files_to_delete) } } fn delete_document_by_filter<'a>( wtxn: &mut RwTxn<'a>, filter: &serde_json::Value, indexer_config: &IndexerConfig, must_stop_processing: MustStopProcessing, index: &'a Index, ) -> Result { let filter = Filter::from_json(filter)?; Ok(if let Some(filter) = filter { let candidates = filter.evaluate(wtxn, index).map_err(|err| match err { milli::Error::UserError(milli::UserError::InvalidFilter(_)) => { Error::from(err).with_custom_error_code(Code::InvalidDocumentFilter) } e => e.into(), })?; let config = IndexDocumentsConfig { update_method: IndexDocumentsMethod::ReplaceDocuments, ..Default::default() }; let mut builder = milli::update::IndexDocuments::new( wtxn, index, indexer_config, config, |indexing_step| debug!("update: {:?}", indexing_step), || must_stop_processing.get(), )?; let (new_builder, count) = builder.remove_documents_from_db_no_batch(&candidates)?; builder = new_builder; let _ = builder.execute()?; count } else { 0 }) }