LCOV - code coverage report
Current view: top level - pageserver/src/tenant - timeline.rs (source / functions) Coverage Total Hit
Test: 8ff8efadb0253cf618c612650348666c0c564111.info Lines: 63.1 % 3502 2209
Test Date: 2024-11-20 17:53:50 Functions: 56.3 % 343 193

            Line data    Source code
       1              : pub(crate) mod analysis;
       2              : pub(crate) mod compaction;
       3              : pub mod delete;
       4              : pub(crate) mod detach_ancestor;
       5              : mod eviction_task;
       6              : pub(crate) mod handle;
       7              : mod init;
       8              : pub mod layer_manager;
       9              : pub(crate) mod logical_size;
      10              : pub mod offload;
      11              : pub mod span;
      12              : pub mod uninit;
      13              : mod walreceiver;
      14              : 
      15              : use anyhow::{anyhow, bail, ensure, Context, Result};
      16              : use arc_swap::ArcSwap;
      17              : use bytes::Bytes;
      18              : use camino::Utf8Path;
      19              : use chrono::{DateTime, Utc};
      20              : use enumset::EnumSet;
      21              : use fail::fail_point;
      22              : use handle::ShardTimelineId;
      23              : use offload::OffloadError;
      24              : use once_cell::sync::Lazy;
      25              : use pageserver_api::{
      26              :     config::tenant_conf_defaults::DEFAULT_COMPACTION_THRESHOLD,
      27              :     key::{
      28              :         KEY_SIZE, METADATA_KEY_BEGIN_PREFIX, METADATA_KEY_END_PREFIX, NON_INHERITED_RANGE,
      29              :         NON_INHERITED_SPARSE_RANGE,
      30              :     },
      31              :     keyspace::{KeySpaceAccum, KeySpaceRandomAccum, SparseKeyPartitioning},
      32              :     models::{
      33              :         CompactionAlgorithm, CompactionAlgorithmSettings, DownloadRemoteLayersTaskInfo,
      34              :         DownloadRemoteLayersTaskSpawnRequest, EvictionPolicy, InMemoryLayerInfo, LayerMapInfo,
      35              :         LsnLease, TimelineState,
      36              :     },
      37              :     reltag::BlockNumber,
      38              :     shard::{ShardIdentity, ShardNumber, TenantShardId},
      39              : };
      40              : use rand::Rng;
      41              : use remote_storage::DownloadError;
      42              : use serde_with::serde_as;
      43              : use storage_broker::BrokerClientChannel;
      44              : use tokio::{
      45              :     runtime::Handle,
      46              :     sync::{oneshot, watch},
      47              : };
      48              : use tokio_util::sync::CancellationToken;
      49              : use tracing::*;
      50              : use utils::{
      51              :     fs_ext, pausable_failpoint,
      52              :     sync::gate::{Gate, GateGuard},
      53              : };
      54              : use wal_decoder::serialized_batch::SerializedValueBatch;
      55              : 
      56              : use std::sync::atomic::Ordering as AtomicOrdering;
      57              : use std::sync::{Arc, Mutex, RwLock, Weak};
      58              : use std::time::{Duration, Instant, SystemTime};
      59              : use std::{
      60              :     array,
      61              :     collections::{BTreeMap, HashMap, HashSet},
      62              :     sync::atomic::AtomicU64,
      63              : };
      64              : use std::{cmp::min, ops::ControlFlow};
      65              : use std::{
      66              :     collections::btree_map::Entry,
      67              :     ops::{Deref, Range},
      68              : };
      69              : use std::{pin::pin, sync::OnceLock};
      70              : 
      71              : use crate::{
      72              :     aux_file::AuxFileSizeEstimator,
      73              :     tenant::{
      74              :         config::AttachmentMode,
      75              :         layer_map::{LayerMap, SearchResult},
      76              :         metadata::TimelineMetadata,
      77              :         storage_layer::{inmemory_layer::IndexEntry, PersistentLayerDesc},
      78              :     },
      79              :     walingest::WalLagCooldown,
      80              :     walredo,
      81              : };
      82              : use crate::{
      83              :     context::{DownloadBehavior, RequestContext},
      84              :     disk_usage_eviction_task::DiskUsageEvictionInfo,
      85              :     pgdatadir_mapping::CollectKeySpaceError,
      86              : };
      87              : use crate::{
      88              :     disk_usage_eviction_task::finite_f32,
      89              :     tenant::storage_layer::{
      90              :         AsLayerDesc, DeltaLayerWriter, EvictionError, ImageLayerWriter, InMemoryLayer, Layer,
      91              :         LayerAccessStatsReset, LayerName, ResidentLayer, ValueReconstructState,
      92              :         ValuesReconstructState,
      93              :     },
      94              : };
      95              : use crate::{
      96              :     disk_usage_eviction_task::EvictionCandidate, tenant::storage_layer::delta_layer::DeltaEntry,
      97              : };
      98              : use crate::{
      99              :     l0_flush::{self, L0FlushGlobalState},
     100              :     metrics::GetKind,
     101              : };
     102              : use crate::{
     103              :     metrics::ScanLatencyOngoingRecording, tenant::timeline::logical_size::CurrentLogicalSize,
     104              : };
     105              : use crate::{
     106              :     pgdatadir_mapping::DirectoryKind,
     107              :     virtual_file::{MaybeFatalIo, VirtualFile},
     108              : };
     109              : use crate::{pgdatadir_mapping::LsnForTimestamp, tenant::tasks::BackgroundLoopKind};
     110              : use crate::{pgdatadir_mapping::MAX_AUX_FILE_V2_DELTAS, tenant::storage_layer::PersistentLayerKey};
     111              : use pageserver_api::config::tenant_conf_defaults::DEFAULT_PITR_INTERVAL;
     112              : 
     113              : use crate::config::PageServerConf;
     114              : use crate::keyspace::{KeyPartitioning, KeySpace};
     115              : use crate::metrics::TimelineMetrics;
     116              : use crate::pgdatadir_mapping::CalculateLogicalSizeError;
     117              : use crate::tenant::config::TenantConfOpt;
     118              : use pageserver_api::reltag::RelTag;
     119              : use pageserver_api::shard::ShardIndex;
     120              : 
     121              : use postgres_connection::PgConnectionConfig;
     122              : use postgres_ffi::{to_pg_timestamp, v14::xlog_utils, WAL_SEGMENT_SIZE};
     123              : use utils::{
     124              :     completion,
     125              :     generation::Generation,
     126              :     id::TimelineId,
     127              :     lsn::{AtomicLsn, Lsn, RecordLsn},
     128              :     seqwait::SeqWait,
     129              :     simple_rcu::{Rcu, RcuReadGuard},
     130              : };
     131              : 
     132              : use crate::task_mgr;
     133              : use crate::task_mgr::TaskKind;
     134              : use crate::tenant::gc_result::GcResult;
     135              : use crate::ZERO_PAGE;
     136              : use pageserver_api::key::Key;
     137              : 
     138              : use self::delete::DeleteTimelineFlow;
     139              : pub(super) use self::eviction_task::EvictionTaskTenantState;
     140              : use self::eviction_task::EvictionTaskTimelineState;
     141              : use self::layer_manager::LayerManager;
     142              : use self::logical_size::LogicalSize;
     143              : use self::walreceiver::{WalReceiver, WalReceiverConf};
     144              : 
     145              : use super::{
     146              :     config::TenantConf, storage_layer::LayerVisibilityHint, upload_queue::NotInitialized,
     147              :     MaybeOffloaded,
     148              : };
     149              : use super::{debug_assert_current_span_has_tenant_and_timeline_id, AttachedTenantConf};
     150              : use super::{remote_timeline_client::index::IndexPart, storage_layer::LayerFringe};
     151              : use super::{
     152              :     remote_timeline_client::RemoteTimelineClient, remote_timeline_client::WaitCompletionError,
     153              :     storage_layer::ReadableLayer,
     154              : };
     155              : use super::{
     156              :     secondary::heatmap::{HeatMapLayer, HeatMapTimeline},
     157              :     GcError,
     158              : };
     159              : 
     160              : #[cfg(test)]
     161              : use pageserver_api::value::Value;
     162              : 
     163              : #[derive(Debug, PartialEq, Eq, Clone, Copy)]
     164              : pub(crate) enum FlushLoopState {
     165              :     NotStarted,
     166              :     Running {
     167              :         #[cfg(test)]
     168              :         expect_initdb_optimization: bool,
     169              :         #[cfg(test)]
     170              :         initdb_optimization_count: usize,
     171              :     },
     172              :     Exited,
     173              : }
     174              : 
     175              : #[derive(Debug, Copy, Clone, PartialEq, Eq)]
     176              : pub enum ImageLayerCreationMode {
     177              :     /// Try to create image layers based on `time_for_new_image_layer`. Used in compaction code path.
     178              :     Try,
     179              :     /// Force creating the image layers if possible. For now, no image layers will be created
     180              :     /// for metadata keys. Used in compaction code path with force flag enabled.
     181              :     Force,
     182              :     /// Initial ingestion of the data, and no data should be dropped in this function. This
     183              :     /// means that no metadata keys should be included in the partitions. Used in flush frozen layer
     184              :     /// code path.
     185              :     Initial,
     186              : }
     187              : 
     188              : impl std::fmt::Display for ImageLayerCreationMode {
     189          716 :     fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
     190          716 :         write!(f, "{:?}", self)
     191          716 :     }
     192              : }
     193              : 
     194              : /// Temporary function for immutable storage state refactor, ensures we are dropping mutex guard instead of other things.
     195              : /// Can be removed after all refactors are done.
     196           28 : fn drop_rlock<T>(rlock: tokio::sync::RwLockReadGuard<T>) {
     197           28 :     drop(rlock)
     198           28 : }
     199              : 
     200              : /// Temporary function for immutable storage state refactor, ensures we are dropping mutex guard instead of other things.
     201              : /// Can be removed after all refactors are done.
     202          744 : fn drop_wlock<T>(rlock: tokio::sync::RwLockWriteGuard<'_, T>) {
     203          744 :     drop(rlock)
     204          744 : }
     205              : 
     206              : /// The outward-facing resources required to build a Timeline
     207              : pub struct TimelineResources {
     208              :     pub remote_client: RemoteTimelineClient,
     209              :     pub timeline_get_throttle:
     210              :         Arc<crate::tenant::throttle::Throttle<crate::metrics::tenant_throttling::TimelineGet>>,
     211              :     pub l0_flush_global_state: l0_flush::L0FlushGlobalState,
     212              : }
     213              : 
     214              : /// The relation size cache caches relation sizes at the end of the timeline. It speeds up WAL
     215              : /// ingestion considerably, because WAL ingestion needs to check on most records if the record
     216              : /// implicitly extends the relation.  At startup, `complete_as_of` is initialized to the current end
     217              : /// of the timeline (disk_consistent_lsn).  It's used on reads of relation sizes to check if the
     218              : /// value can be used to also update the cache, see [`Timeline::update_cached_rel_size`].
     219              : pub(crate) struct RelSizeCache {
     220              :     pub(crate) complete_as_of: Lsn,
     221              :     pub(crate) map: HashMap<RelTag, (Lsn, BlockNumber)>,
     222              : }
     223              : 
     224              : pub struct Timeline {
     225              :     pub(crate) conf: &'static PageServerConf,
     226              :     tenant_conf: Arc<ArcSwap<AttachedTenantConf>>,
     227              : 
     228              :     myself: Weak<Self>,
     229              : 
     230              :     pub(crate) tenant_shard_id: TenantShardId,
     231              :     pub timeline_id: TimelineId,
     232              : 
     233              :     /// The generation of the tenant that instantiated us: this is used for safety when writing remote objects.
     234              :     /// Never changes for the lifetime of this [`Timeline`] object.
     235              :     ///
     236              :     /// This duplicates the generation stored in LocationConf, but that structure is mutable:
     237              :     /// this copy enforces the invariant that generatio doesn't change during a Tenant's lifetime.
     238              :     pub(crate) generation: Generation,
     239              : 
     240              :     /// The detailed sharding information from our parent Tenant.  This enables us to map keys
     241              :     /// to shards, and is constant through the lifetime of this Timeline.
     242              :     shard_identity: ShardIdentity,
     243              : 
     244              :     pub pg_version: u32,
     245              : 
     246              :     /// The tuple has two elements.
     247              :     /// 1. `LayerFileManager` keeps track of the various physical representations of the layer files (inmem, local, remote).
     248              :     /// 2. `LayerMap`, the acceleration data structure for `get_reconstruct_data`.
     249              :     ///
     250              :     /// `LayerMap` maps out the `(PAGE,LSN) / (KEY,LSN)` space, which is composed of `(KeyRange, LsnRange)` rectangles.
     251              :     /// We describe these rectangles through the `PersistentLayerDesc` struct.
     252              :     ///
     253              :     /// When we want to reconstruct a page, we first find the `PersistentLayerDesc`'s that we need for page reconstruction,
     254              :     /// using `LayerMap`. Then, we use `LayerFileManager` to get the `PersistentLayer`'s that correspond to the
     255              :     /// `PersistentLayerDesc`'s.
     256              :     ///
     257              :     /// Hence, it's important to keep things coherent. The `LayerFileManager` must always have an entry for all
     258              :     /// `PersistentLayerDesc`'s in the `LayerMap`. If it doesn't, `LayerFileManager::get_from_desc` will panic at
     259              :     /// runtime, e.g., during page reconstruction.
     260              :     ///
     261              :     /// In the future, we'll be able to split up the tuple of LayerMap and `LayerFileManager`,
     262              :     /// so that e.g. on-demand-download/eviction, and layer spreading, can operate just on `LayerFileManager`.
     263              :     pub(crate) layers: tokio::sync::RwLock<LayerManager>,
     264              : 
     265              :     last_freeze_at: AtomicLsn,
     266              :     // Atomic would be more appropriate here.
     267              :     last_freeze_ts: RwLock<Instant>,
     268              : 
     269              :     pub(crate) standby_horizon: AtomicLsn,
     270              : 
     271              :     // WAL redo manager. `None` only for broken tenants.
     272              :     walredo_mgr: Option<Arc<super::WalRedoManager>>,
     273              : 
     274              :     /// Remote storage client.
     275              :     /// See [`remote_timeline_client`](super::remote_timeline_client) module comment for details.
     276              :     pub remote_client: Arc<RemoteTimelineClient>,
     277              : 
     278              :     // What page versions do we hold in the repository? If we get a
     279              :     // request > last_record_lsn, we need to wait until we receive all
     280              :     // the WAL up to the request. The SeqWait provides functions for
     281              :     // that. TODO: If we get a request for an old LSN, such that the
     282              :     // versions have already been garbage collected away, we should
     283              :     // throw an error, but we don't track that currently.
     284              :     //
     285              :     // last_record_lsn.load().last points to the end of last processed WAL record.
     286              :     //
     287              :     // We also remember the starting point of the previous record in
     288              :     // 'last_record_lsn.load().prev'. It's used to set the xl_prev pointer of the
     289              :     // first WAL record when the node is started up. But here, we just
     290              :     // keep track of it.
     291              :     last_record_lsn: SeqWait<RecordLsn, Lsn>,
     292              : 
     293              :     // All WAL records have been processed and stored durably on files on
     294              :     // local disk, up to this LSN. On crash and restart, we need to re-process
     295              :     // the WAL starting from this point.
     296              :     //
     297              :     // Some later WAL records might have been processed and also flushed to disk
     298              :     // already, so don't be surprised to see some, but there's no guarantee on
     299              :     // them yet.
     300              :     disk_consistent_lsn: AtomicLsn,
     301              : 
     302              :     // Parent timeline that this timeline was branched from, and the LSN
     303              :     // of the branch point.
     304              :     ancestor_timeline: Option<Arc<Timeline>>,
     305              :     ancestor_lsn: Lsn,
     306              : 
     307              :     pub(super) metrics: TimelineMetrics,
     308              : 
     309              :     // `Timeline` doesn't write these metrics itself, but it manages the lifetime.  Code
     310              :     // in `crate::page_service` writes these metrics.
     311              :     pub(crate) query_metrics: crate::metrics::SmgrQueryTimePerTimeline,
     312              : 
     313              :     directory_metrics: [AtomicU64; DirectoryKind::KINDS_NUM],
     314              : 
     315              :     /// Ensures layers aren't frozen by checkpointer between
     316              :     /// [`Timeline::get_layer_for_write`] and layer reads.
     317              :     /// Locked automatically by [`TimelineWriter`] and checkpointer.
     318              :     /// Must always be acquired before the layer map/individual layer lock
     319              :     /// to avoid deadlock.
     320              :     ///
     321              :     /// The state is cleared upon freezing.
     322              :     write_lock: tokio::sync::Mutex<Option<TimelineWriterState>>,
     323              : 
     324              :     /// Used to avoid multiple `flush_loop` tasks running
     325              :     pub(super) flush_loop_state: Mutex<FlushLoopState>,
     326              : 
     327              :     /// layer_flush_start_tx can be used to wake up the layer-flushing task.
     328              :     /// - The u64 value is a counter, incremented every time a new flush cycle is requested.
     329              :     ///   The flush cycle counter is sent back on the layer_flush_done channel when
     330              :     ///   the flush finishes. You can use that to wait for the flush to finish.
     331              :     /// - The LSN is updated to max() of its current value and the latest disk_consistent_lsn
     332              :     ///   read by whoever sends an update
     333              :     layer_flush_start_tx: tokio::sync::watch::Sender<(u64, Lsn)>,
     334              :     /// to be notified when layer flushing has finished, subscribe to the layer_flush_done channel
     335              :     layer_flush_done_tx: tokio::sync::watch::Sender<(u64, Result<(), FlushLayerError>)>,
     336              : 
     337              :     // Needed to ensure that we can't create a branch at a point that was already garbage collected
     338              :     pub latest_gc_cutoff_lsn: Rcu<Lsn>,
     339              : 
     340              :     // List of child timelines and their branch points. This is needed to avoid
     341              :     // garbage collecting data that is still needed by the child timelines.
     342              :     pub(crate) gc_info: std::sync::RwLock<GcInfo>,
     343              : 
     344              :     // It may change across major versions so for simplicity
     345              :     // keep it after running initdb for a timeline.
     346              :     // It is needed in checks when we want to error on some operations
     347              :     // when they are requested for pre-initdb lsn.
     348              :     // It can be unified with latest_gc_cutoff_lsn under some "first_valid_lsn",
     349              :     // though let's keep them both for better error visibility.
     350              :     pub initdb_lsn: Lsn,
     351              : 
     352              :     /// When did we last calculate the partitioning? Make it pub to test cases.
     353              :     pub(super) partitioning: tokio::sync::Mutex<((KeyPartitioning, SparseKeyPartitioning), Lsn)>,
     354              : 
     355              :     /// Configuration: how often should the partitioning be recalculated.
     356              :     repartition_threshold: u64,
     357              : 
     358              :     last_image_layer_creation_check_at: AtomicLsn,
     359              :     last_image_layer_creation_check_instant: std::sync::Mutex<Option<Instant>>,
     360              : 
     361              :     /// Current logical size of the "datadir", at the last LSN.
     362              :     current_logical_size: LogicalSize,
     363              : 
     364              :     /// Information about the last processed message by the WAL receiver,
     365              :     /// or None if WAL receiver has not received anything for this timeline
     366              :     /// yet.
     367              :     pub last_received_wal: Mutex<Option<WalReceiverInfo>>,
     368              :     pub walreceiver: Mutex<Option<WalReceiver>>,
     369              : 
     370              :     /// Relation size cache
     371              :     pub(crate) rel_size_cache: RwLock<RelSizeCache>,
     372              : 
     373              :     download_all_remote_layers_task_info: RwLock<Option<DownloadRemoteLayersTaskInfo>>,
     374              : 
     375              :     state: watch::Sender<TimelineState>,
     376              : 
     377              :     /// Prevent two tasks from deleting the timeline at the same time. If held, the
     378              :     /// timeline is being deleted. If 'true', the timeline has already been deleted.
     379              :     pub delete_progress: TimelineDeleteProgress,
     380              : 
     381              :     eviction_task_timeline_state: tokio::sync::Mutex<EvictionTaskTimelineState>,
     382              : 
     383              :     /// Load or creation time information about the disk_consistent_lsn and when the loading
     384              :     /// happened. Used for consumption metrics.
     385              :     pub(crate) loaded_at: (Lsn, SystemTime),
     386              : 
     387              :     /// Gate to prevent shutdown completing while I/O is still happening to this timeline's data
     388              :     pub(crate) gate: Gate,
     389              : 
     390              :     /// Cancellation token scoped to this timeline: anything doing long-running work relating
     391              :     /// to the timeline should drop out when this token fires.
     392              :     pub(crate) cancel: CancellationToken,
     393              : 
     394              :     /// Make sure we only have one running compaction at a time in tests.
     395              :     ///
     396              :     /// Must only be taken in two places:
     397              :     /// - [`Timeline::compact`] (this file)
     398              :     /// - [`delete::delete_local_timeline_directory`]
     399              :     ///
     400              :     /// Timeline deletion will acquire both compaction and gc locks in whatever order.
     401              :     compaction_lock: tokio::sync::Mutex<()>,
     402              : 
     403              :     /// Make sure we only have one running gc at a time.
     404              :     ///
     405              :     /// Must only be taken in two places:
     406              :     /// - [`Timeline::gc`] (this file)
     407              :     /// - [`delete::delete_local_timeline_directory`]
     408              :     ///
     409              :     /// Timeline deletion will acquire both compaction and gc locks in whatever order.
     410              :     gc_lock: tokio::sync::Mutex<()>,
     411              : 
     412              :     /// Cloned from [`super::Tenant::timeline_get_throttle`] on construction.
     413              :     timeline_get_throttle:
     414              :         Arc<crate::tenant::throttle::Throttle<crate::metrics::tenant_throttling::TimelineGet>>,
     415              : 
     416              :     /// Size estimator for aux file v2
     417              :     pub(crate) aux_file_size_estimator: AuxFileSizeEstimator,
     418              : 
     419              :     /// Some test cases directly place keys into the timeline without actually modifying the directory
     420              :     /// keys (i.e., DB_DIR). The test cases creating such keys will put the keyspaces here, so that
     421              :     /// these keys won't get garbage-collected during compaction/GC. This field only modifies the dense
     422              :     /// keyspace return value of `collect_keyspace`. For sparse keyspaces, use AUX keys for testing, and
     423              :     /// in the future, add `extra_test_sparse_keyspace` if necessary.
     424              :     #[cfg(test)]
     425              :     pub(crate) extra_test_dense_keyspace: ArcSwap<KeySpace>,
     426              : 
     427              :     pub(crate) l0_flush_global_state: L0FlushGlobalState,
     428              : 
     429              :     pub(crate) handles: handle::PerTimelineState<crate::page_service::TenantManagerTypes>,
     430              : 
     431              :     pub(crate) attach_wal_lag_cooldown: Arc<OnceLock<WalLagCooldown>>,
     432              : 
     433              :     /// Cf. [`crate::tenant::CreateTimelineIdempotency`].
     434              :     pub(crate) create_idempotency: crate::tenant::CreateTimelineIdempotency,
     435              : }
     436              : 
     437              : pub type TimelineDeleteProgress = Arc<tokio::sync::Mutex<DeleteTimelineFlow>>;
     438              : 
     439              : pub struct WalReceiverInfo {
     440              :     pub wal_source_connconf: PgConnectionConfig,
     441              :     pub last_received_msg_lsn: Lsn,
     442              :     pub last_received_msg_ts: u128,
     443              : }
     444              : 
     445              : /// Information about how much history needs to be retained, needed by
     446              : /// Garbage Collection.
     447              : #[derive(Default)]
     448              : pub(crate) struct GcInfo {
     449              :     /// Specific LSNs that are needed.
     450              :     ///
     451              :     /// Currently, this includes all points where child branches have
     452              :     /// been forked off from. In the future, could also include
     453              :     /// explicit user-defined snapshot points.
     454              :     pub(crate) retain_lsns: Vec<(Lsn, TimelineId, MaybeOffloaded)>,
     455              : 
     456              :     /// The cutoff coordinates, which are combined by selecting the minimum.
     457              :     pub(crate) cutoffs: GcCutoffs,
     458              : 
     459              :     /// Leases granted to particular LSNs.
     460              :     pub(crate) leases: BTreeMap<Lsn, LsnLease>,
     461              : 
     462              :     /// Whether our branch point is within our ancestor's PITR interval (for cost estimation)
     463              :     pub(crate) within_ancestor_pitr: bool,
     464              : }
     465              : 
     466              : impl GcInfo {
     467          228 :     pub(crate) fn min_cutoff(&self) -> Lsn {
     468          228 :         self.cutoffs.select_min()
     469          228 :     }
     470              : 
     471          232 :     pub(super) fn insert_child(
     472          232 :         &mut self,
     473          232 :         child_id: TimelineId,
     474          232 :         child_lsn: Lsn,
     475          232 :         is_offloaded: MaybeOffloaded,
     476          232 :     ) {
     477          232 :         self.retain_lsns.push((child_lsn, child_id, is_offloaded));
     478          232 :         self.retain_lsns.sort_by_key(|i| i.0);
     479          232 :     }
     480              : 
     481            4 :     pub(super) fn remove_child_maybe_offloaded(
     482            4 :         &mut self,
     483            4 :         child_id: TimelineId,
     484            4 :         maybe_offloaded: MaybeOffloaded,
     485            4 :     ) -> bool {
     486            4 :         // Remove at most one element. Needed for correctness if there is two live `Timeline` objects referencing
     487            4 :         // the same timeline. Shouldn't but maybe can occur when Arc's live longer than intended.
     488            4 :         let mut removed = false;
     489            6 :         self.retain_lsns.retain(|i| {
     490            6 :             if removed {
     491            2 :                 return true;
     492            4 :             }
     493            4 :             let remove = i.1 == child_id && i.2 == maybe_offloaded;
     494            4 :             removed |= remove;
     495            4 :             !remove
     496            6 :         });
     497            4 :         removed
     498            4 :     }
     499              : 
     500            4 :     pub(super) fn remove_child_not_offloaded(&mut self, child_id: TimelineId) -> bool {
     501            4 :         self.remove_child_maybe_offloaded(child_id, MaybeOffloaded::No)
     502            4 :     }
     503              : 
     504            0 :     pub(super) fn remove_child_offloaded(&mut self, child_id: TimelineId) -> bool {
     505            0 :         self.remove_child_maybe_offloaded(child_id, MaybeOffloaded::Yes)
     506            0 :     }
     507              : }
     508              : 
     509              : /// The `GcInfo` component describing which Lsns need to be retained.  Functionally, this
     510              : /// is a single number (the oldest LSN which we must retain), but it internally distinguishes
     511              : /// between time-based and space-based retention for observability and consumption metrics purposes.
     512              : #[derive(Debug, Clone)]
     513              : pub(crate) struct GcCutoffs {
     514              :     /// Calculated from the [`TenantConf::gc_horizon`], this LSN indicates how much
     515              :     /// history we must keep to retain a specified number of bytes of WAL.
     516              :     pub(crate) space: Lsn,
     517              : 
     518              :     /// Calculated from [`TenantConf::pitr_interval`], this LSN indicates how much
     519              :     /// history we must keep to enable reading back at least the PITR interval duration.
     520              :     pub(crate) time: Lsn,
     521              : }
     522              : 
     523              : impl Default for GcCutoffs {
     524          418 :     fn default() -> Self {
     525          418 :         Self {
     526          418 :             space: Lsn::INVALID,
     527          418 :             time: Lsn::INVALID,
     528          418 :         }
     529          418 :     }
     530              : }
     531              : 
     532              : impl GcCutoffs {
     533          268 :     fn select_min(&self) -> Lsn {
     534          268 :         std::cmp::min(self.space, self.time)
     535          268 :     }
     536              : }
     537              : 
     538              : pub(crate) struct TimelineVisitOutcome {
     539              :     completed_keyspace: KeySpace,
     540              :     image_covered_keyspace: KeySpace,
     541              : }
     542              : 
     543              : /// An error happened in a get() operation.
     544            2 : #[derive(thiserror::Error, Debug)]
     545              : pub(crate) enum PageReconstructError {
     546              :     #[error(transparent)]
     547              :     Other(anyhow::Error),
     548              : 
     549              :     #[error("Ancestor LSN wait error: {0}")]
     550              :     AncestorLsnTimeout(WaitLsnError),
     551              : 
     552              :     #[error("timeline shutting down")]
     553              :     Cancelled,
     554              : 
     555              :     /// An error happened replaying WAL records
     556              :     #[error(transparent)]
     557              :     WalRedo(anyhow::Error),
     558              : 
     559              :     #[error("{0}")]
     560              :     MissingKey(MissingKeyError),
     561              : }
     562              : 
     563              : impl From<anyhow::Error> for PageReconstructError {
     564            0 :     fn from(value: anyhow::Error) -> Self {
     565            0 :         // with walingest.rs many PageReconstructError are wrapped in as anyhow::Error
     566            0 :         match value.downcast::<PageReconstructError>() {
     567            0 :             Ok(pre) => pre,
     568            0 :             Err(other) => PageReconstructError::Other(other),
     569              :         }
     570            0 :     }
     571              : }
     572              : 
     573              : impl From<utils::bin_ser::DeserializeError> for PageReconstructError {
     574            0 :     fn from(value: utils::bin_ser::DeserializeError) -> Self {
     575            0 :         PageReconstructError::Other(anyhow::Error::new(value).context("deserialization failure"))
     576            0 :     }
     577              : }
     578              : 
     579              : impl From<layer_manager::Shutdown> for PageReconstructError {
     580            0 :     fn from(_: layer_manager::Shutdown) -> Self {
     581            0 :         PageReconstructError::Cancelled
     582            0 :     }
     583              : }
     584              : 
     585              : impl GetVectoredError {
     586              :     #[cfg(test)]
     587            6 :     pub(crate) fn is_missing_key_error(&self) -> bool {
     588            6 :         matches!(self, Self::MissingKey(_))
     589            6 :     }
     590              : }
     591              : 
     592              : impl From<layer_manager::Shutdown> for GetVectoredError {
     593            0 :     fn from(_: layer_manager::Shutdown) -> Self {
     594            0 :         GetVectoredError::Cancelled
     595            0 :     }
     596              : }
     597              : 
     598              : #[derive(thiserror::Error)]
     599              : pub struct MissingKeyError {
     600              :     key: Key,
     601              :     shard: ShardNumber,
     602              :     cont_lsn: Lsn,
     603              :     request_lsn: Lsn,
     604              :     ancestor_lsn: Option<Lsn>,
     605              :     backtrace: Option<std::backtrace::Backtrace>,
     606              : }
     607              : 
     608              : impl std::fmt::Debug for MissingKeyError {
     609            0 :     fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
     610            0 :         write!(f, "{}", self)
     611            0 :     }
     612              : }
     613              : 
     614              : impl std::fmt::Display for MissingKeyError {
     615            0 :     fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
     616            0 :         write!(
     617            0 :             f,
     618            0 :             "could not find data for key {} (shard {:?}) at LSN {}, request LSN {}",
     619            0 :             self.key, self.shard, self.cont_lsn, self.request_lsn
     620            0 :         )?;
     621            0 :         if let Some(ref ancestor_lsn) = self.ancestor_lsn {
     622            0 :             write!(f, ", ancestor {}", ancestor_lsn)?;
     623            0 :         }
     624              : 
     625            0 :         if let Some(ref backtrace) = self.backtrace {
     626            0 :             write!(f, "\n{}", backtrace)?;
     627            0 :         }
     628              : 
     629            0 :         Ok(())
     630            0 :     }
     631              : }
     632              : 
     633              : impl PageReconstructError {
     634              :     /// Returns true if this error indicates a tenant/timeline shutdown alike situation
     635            0 :     pub(crate) fn is_stopping(&self) -> bool {
     636              :         use PageReconstructError::*;
     637            0 :         match self {
     638            0 :             Cancelled => true,
     639            0 :             Other(_) | AncestorLsnTimeout(_) | WalRedo(_) | MissingKey(_) => false,
     640              :         }
     641            0 :     }
     642              : }
     643              : 
     644            0 : #[derive(thiserror::Error, Debug)]
     645              : pub(crate) enum CreateImageLayersError {
     646              :     #[error("timeline shutting down")]
     647              :     Cancelled,
     648              : 
     649              :     #[error("read failed")]
     650              :     GetVectoredError(#[source] GetVectoredError),
     651              : 
     652              :     #[error("reconstruction failed")]
     653              :     PageReconstructError(#[source] PageReconstructError),
     654              : 
     655              :     #[error(transparent)]
     656              :     Other(#[from] anyhow::Error),
     657              : }
     658              : 
     659              : impl From<layer_manager::Shutdown> for CreateImageLayersError {
     660            0 :     fn from(_: layer_manager::Shutdown) -> Self {
     661            0 :         CreateImageLayersError::Cancelled
     662            0 :     }
     663              : }
     664              : 
     665            0 : #[derive(thiserror::Error, Debug, Clone)]
     666              : pub(crate) enum FlushLayerError {
     667              :     /// Timeline cancellation token was cancelled
     668              :     #[error("timeline shutting down")]
     669              :     Cancelled,
     670              : 
     671              :     /// We tried to flush a layer while the Timeline is in an unexpected state
     672              :     #[error("cannot flush frozen layers when flush_loop is not running, state is {0:?}")]
     673              :     NotRunning(FlushLoopState),
     674              : 
     675              :     // Arc<> the following non-clonable error types: we must be Clone-able because the flush error is propagated from the flush
     676              :     // loop via a watch channel, where we can only borrow it.
     677              :     #[error("create image layers (shared)")]
     678              :     CreateImageLayersError(Arc<CreateImageLayersError>),
     679              : 
     680              :     #[error("other (shared)")]
     681              :     Other(#[from] Arc<anyhow::Error>),
     682              : }
     683              : 
     684              : impl FlushLayerError {
     685              :     // When crossing from generic anyhow errors to this error type, we explicitly check
     686              :     // for timeline cancellation to avoid logging inoffensive shutdown errors as warn/err.
     687            0 :     fn from_anyhow(timeline: &Timeline, err: anyhow::Error) -> Self {
     688            0 :         let cancelled = timeline.cancel.is_cancelled()
     689              :             // The upload queue might have been shut down before the official cancellation of the timeline.
     690            0 :             || err
     691            0 :                 .downcast_ref::<NotInitialized>()
     692            0 :                 .map(NotInitialized::is_stopping)
     693            0 :                 .unwrap_or_default();
     694            0 :         if cancelled {
     695            0 :             Self::Cancelled
     696              :         } else {
     697            0 :             Self::Other(Arc::new(err))
     698              :         }
     699            0 :     }
     700              : }
     701              : 
     702              : impl From<layer_manager::Shutdown> for FlushLayerError {
     703            0 :     fn from(_: layer_manager::Shutdown) -> Self {
     704            0 :         FlushLayerError::Cancelled
     705            0 :     }
     706              : }
     707              : 
     708            0 : #[derive(thiserror::Error, Debug)]
     709              : pub(crate) enum GetVectoredError {
     710              :     #[error("timeline shutting down")]
     711              :     Cancelled,
     712              : 
     713              :     #[error("requested too many keys: {0} > {}", Timeline::MAX_GET_VECTORED_KEYS)]
     714              :     Oversized(u64),
     715              : 
     716              :     #[error("requested at invalid LSN: {0}")]
     717              :     InvalidLsn(Lsn),
     718              : 
     719              :     #[error("requested key not found: {0}")]
     720              :     MissingKey(MissingKeyError),
     721              : 
     722              :     #[error("ancestry walk")]
     723              :     GetReadyAncestorError(#[source] GetReadyAncestorError),
     724              : 
     725              :     #[error(transparent)]
     726              :     Other(#[from] anyhow::Error),
     727              : }
     728              : 
     729              : impl From<GetReadyAncestorError> for GetVectoredError {
     730            2 :     fn from(value: GetReadyAncestorError) -> Self {
     731              :         use GetReadyAncestorError::*;
     732            2 :         match value {
     733            0 :             Cancelled => GetVectoredError::Cancelled,
     734              :             AncestorLsnTimeout(_) | BadState { .. } => {
     735            2 :                 GetVectoredError::GetReadyAncestorError(value)
     736              :             }
     737              :         }
     738            2 :     }
     739              : }
     740              : 
     741            2 : #[derive(thiserror::Error, Debug)]
     742              : pub(crate) enum GetReadyAncestorError {
     743              :     #[error("ancestor LSN wait error")]
     744              :     AncestorLsnTimeout(#[from] WaitLsnError),
     745              : 
     746              :     #[error("bad state on timeline {timeline_id}: {state:?}")]
     747              :     BadState {
     748              :         timeline_id: TimelineId,
     749              :         state: TimelineState,
     750              :     },
     751              : 
     752              :     #[error("cancelled")]
     753              :     Cancelled,
     754              : }
     755              : 
     756              : #[derive(Clone, Copy)]
     757              : pub enum LogicalSizeCalculationCause {
     758              :     Initial,
     759              :     ConsumptionMetricsSyntheticSize,
     760              :     EvictionTaskImitation,
     761              :     TenantSizeHandler,
     762              : }
     763              : 
     764              : pub enum GetLogicalSizePriority {
     765              :     User,
     766              :     Background,
     767              : }
     768              : 
     769            0 : #[derive(enumset::EnumSetType)]
     770              : pub(crate) enum CompactFlags {
     771              :     ForceRepartition,
     772              :     ForceImageLayerCreation,
     773              :     ForceL0Compaction,
     774              :     EnhancedGcBottomMostCompaction,
     775              :     DryRun,
     776              : }
     777              : 
     778              : #[serde_with::serde_as]
     779            0 : #[derive(Debug, Clone, serde::Deserialize)]
     780              : pub(crate) struct CompactRange {
     781              :     #[serde_as(as = "serde_with::DisplayFromStr")]
     782              :     pub start: Key,
     783              :     #[serde_as(as = "serde_with::DisplayFromStr")]
     784              :     pub end: Key,
     785              : }
     786              : 
     787              : #[derive(Clone, Default)]
     788              : pub(crate) struct CompactOptions {
     789              :     pub flags: EnumSet<CompactFlags>,
     790              :     pub compact_range: Option<CompactRange>,
     791              : }
     792              : 
     793              : impl std::fmt::Debug for Timeline {
     794            0 :     fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
     795            0 :         write!(f, "Timeline<{}>", self.timeline_id)
     796            0 :     }
     797              : }
     798              : 
     799            0 : #[derive(thiserror::Error, Debug)]
     800              : pub(crate) enum WaitLsnError {
     801              :     // Called on a timeline which is shutting down
     802              :     #[error("Shutdown")]
     803              :     Shutdown,
     804              : 
     805              :     // Called on an timeline not in active state or shutting down
     806              :     #[error("Bad timeline state: {0:?}")]
     807              :     BadState(TimelineState),
     808              : 
     809              :     // Timeout expired while waiting for LSN to catch up with goal.
     810              :     #[error("{0}")]
     811              :     Timeout(String),
     812              : }
     813              : 
     814              : // The impls below achieve cancellation mapping for errors.
     815              : // Perhaps there's a way of achieving this with less cruft.
     816              : 
     817              : impl From<CreateImageLayersError> for CompactionError {
     818            0 :     fn from(e: CreateImageLayersError) -> Self {
     819            0 :         match e {
     820            0 :             CreateImageLayersError::Cancelled => CompactionError::ShuttingDown,
     821            0 :             CreateImageLayersError::Other(e) => {
     822            0 :                 CompactionError::Other(e.context("create image layers"))
     823              :             }
     824            0 :             _ => CompactionError::Other(e.into()),
     825              :         }
     826            0 :     }
     827              : }
     828              : 
     829              : impl From<CreateImageLayersError> for FlushLayerError {
     830            0 :     fn from(e: CreateImageLayersError) -> Self {
     831            0 :         match e {
     832            0 :             CreateImageLayersError::Cancelled => FlushLayerError::Cancelled,
     833            0 :             any => FlushLayerError::CreateImageLayersError(Arc::new(any)),
     834              :         }
     835            0 :     }
     836              : }
     837              : 
     838              : impl From<PageReconstructError> for CreateImageLayersError {
     839            0 :     fn from(e: PageReconstructError) -> Self {
     840            0 :         match e {
     841            0 :             PageReconstructError::Cancelled => CreateImageLayersError::Cancelled,
     842            0 :             _ => CreateImageLayersError::PageReconstructError(e),
     843              :         }
     844            0 :     }
     845              : }
     846              : 
     847              : impl From<GetVectoredError> for CreateImageLayersError {
     848            0 :     fn from(e: GetVectoredError) -> Self {
     849            0 :         match e {
     850            0 :             GetVectoredError::Cancelled => CreateImageLayersError::Cancelled,
     851            0 :             _ => CreateImageLayersError::GetVectoredError(e),
     852              :         }
     853            0 :     }
     854              : }
     855              : 
     856              : impl From<GetVectoredError> for PageReconstructError {
     857            6 :     fn from(e: GetVectoredError) -> Self {
     858            6 :         match e {
     859            0 :             GetVectoredError::Cancelled => PageReconstructError::Cancelled,
     860            0 :             GetVectoredError::InvalidLsn(_) => PageReconstructError::Other(anyhow!("Invalid LSN")),
     861            0 :             err @ GetVectoredError::Oversized(_) => PageReconstructError::Other(err.into()),
     862            4 :             GetVectoredError::MissingKey(err) => PageReconstructError::MissingKey(err),
     863            2 :             GetVectoredError::GetReadyAncestorError(err) => PageReconstructError::from(err),
     864            0 :             GetVectoredError::Other(err) => PageReconstructError::Other(err),
     865              :         }
     866            6 :     }
     867              : }
     868              : 
     869              : impl From<GetReadyAncestorError> for PageReconstructError {
     870            2 :     fn from(e: GetReadyAncestorError) -> Self {
     871              :         use GetReadyAncestorError::*;
     872            2 :         match e {
     873            0 :             AncestorLsnTimeout(wait_err) => PageReconstructError::AncestorLsnTimeout(wait_err),
     874            2 :             bad_state @ BadState { .. } => PageReconstructError::Other(anyhow::anyhow!(bad_state)),
     875            0 :             Cancelled => PageReconstructError::Cancelled,
     876              :         }
     877            2 :     }
     878              : }
     879              : 
     880              : pub(crate) enum WaitLsnWaiter<'a> {
     881              :     Timeline(&'a Timeline),
     882              :     Tenant,
     883              :     PageService,
     884              : }
     885              : 
     886              : /// Argument to [`Timeline::shutdown`].
     887              : #[derive(Debug, Clone, Copy)]
     888              : pub(crate) enum ShutdownMode {
     889              :     /// Graceful shutdown, may do a lot of I/O as we flush any open layers to disk and then
     890              :     /// also to remote storage.  This method can easily take multiple seconds for a busy timeline.
     891              :     ///
     892              :     /// While we are flushing, we continue to accept read I/O for LSNs ingested before
     893              :     /// the call to [`Timeline::shutdown`].
     894              :     FreezeAndFlush,
     895              :     /// Only flush the layers to the remote storage without freezing any open layers. This is the
     896              :     /// mode used by ancestor detach and any other operations that reloads a tenant but not increasing
     897              :     /// the generation number.
     898              :     Flush,
     899              :     /// Shut down immediately, without waiting for any open layers to flush.
     900              :     Hard,
     901              : }
     902              : 
     903              : struct ImageLayerCreationOutcome {
     904              :     image: Option<ResidentLayer>,
     905              :     next_start_key: Key,
     906              : }
     907              : 
     908              : /// Public interface functions
     909              : impl Timeline {
     910              :     /// Get the LSN where this branch was created
     911            4 :     pub(crate) fn get_ancestor_lsn(&self) -> Lsn {
     912            4 :         self.ancestor_lsn
     913            4 :     }
     914              : 
     915              :     /// Get the ancestor's timeline id
     916           12 :     pub(crate) fn get_ancestor_timeline_id(&self) -> Option<TimelineId> {
     917           12 :         self.ancestor_timeline
     918           12 :             .as_ref()
     919           12 :             .map(|ancestor| ancestor.timeline_id)
     920           12 :     }
     921              : 
     922              :     /// Get the ancestor timeline
     923            2 :     pub(crate) fn ancestor_timeline(&self) -> Option<&Arc<Timeline>> {
     924            2 :         self.ancestor_timeline.as_ref()
     925            2 :     }
     926              : 
     927              :     /// Get the bytes written since the PITR cutoff on this branch, and
     928              :     /// whether this branch's ancestor_lsn is within its parent's PITR.
     929            0 :     pub(crate) fn get_pitr_history_stats(&self) -> (u64, bool) {
     930            0 :         let gc_info = self.gc_info.read().unwrap();
     931            0 :         let history = self
     932            0 :             .get_last_record_lsn()
     933            0 :             .checked_sub(gc_info.cutoffs.time)
     934            0 :             .unwrap_or(Lsn(0))
     935            0 :             .0;
     936            0 :         (history, gc_info.within_ancestor_pitr)
     937            0 :     }
     938              : 
     939              :     /// Lock and get timeline's GC cutoff
     940          248 :     pub(crate) fn get_latest_gc_cutoff_lsn(&self) -> RcuReadGuard<Lsn> {
     941          248 :         self.latest_gc_cutoff_lsn.read()
     942          248 :     }
     943              : 
     944              :     /// Look up given page version.
     945              :     ///
     946              :     /// If a remote layer file is needed, it is downloaded as part of this
     947              :     /// call.
     948              :     ///
     949              :     /// This method enforces [`Self::timeline_get_throttle`] internally.
     950              :     ///
     951              :     /// NOTE: It is considered an error to 'get' a key that doesn't exist. The
     952              :     /// abstraction above this needs to store suitable metadata to track what
     953              :     /// data exists with what keys, in separate metadata entries. If a
     954              :     /// non-existent key is requested, we may incorrectly return a value from
     955              :     /// an ancestor branch, for example, or waste a lot of cycles chasing the
     956              :     /// non-existing key.
     957              :     ///
     958              :     /// # Cancel-Safety
     959              :     ///
     960              :     /// This method is cancellation-safe.
     961              :     #[inline(always)]
     962       606776 :     pub(crate) async fn get(
     963       606776 :         &self,
     964       606776 :         key: Key,
     965       606776 :         lsn: Lsn,
     966       606776 :         ctx: &RequestContext,
     967       606776 :     ) -> Result<Bytes, PageReconstructError> {
     968       606776 :         if !lsn.is_valid() {
     969            0 :             return Err(PageReconstructError::Other(anyhow::anyhow!("Invalid LSN")));
     970       606776 :         }
     971       606776 : 
     972       606776 :         // This check is debug-only because of the cost of hashing, and because it's a double-check: we
     973       606776 :         // already checked the key against the shard_identity when looking up the Timeline from
     974       606776 :         // page_service.
     975       606776 :         debug_assert!(!self.shard_identity.is_key_disposable(&key));
     976              : 
     977       606776 :         self.timeline_get_throttle.throttle(ctx, 1).await;
     978              : 
     979       606776 :         let keyspace = KeySpace {
     980       606776 :             ranges: vec![key..key.next()],
     981       606776 :         };
     982       606776 : 
     983       606776 :         // Initialise the reconstruct state for the key with the cache
     984       606776 :         // entry returned above.
     985       606776 :         let mut reconstruct_state = ValuesReconstructState::new();
     986              : 
     987       606776 :         let vectored_res = self
     988       606776 :             .get_vectored_impl(keyspace.clone(), lsn, &mut reconstruct_state, ctx)
     989       182926 :             .await;
     990              : 
     991       606776 :         let key_value = vectored_res?.pop_first();
     992       606770 :         match key_value {
     993       606758 :             Some((got_key, value)) => {
     994       606758 :                 if got_key != key {
     995            0 :                     error!(
     996            0 :                         "Expected {}, but singular vectored get returned {}",
     997              :                         key, got_key
     998              :                     );
     999            0 :                     Err(PageReconstructError::Other(anyhow!(
    1000            0 :                         "Singular vectored get returned wrong key"
    1001            0 :                     )))
    1002              :                 } else {
    1003       606758 :                     value
    1004              :                 }
    1005              :             }
    1006           12 :             None => Err(PageReconstructError::MissingKey(MissingKeyError {
    1007           12 :                 key,
    1008           12 :                 shard: self.shard_identity.get_shard_number(&key),
    1009           12 :                 cont_lsn: Lsn(0),
    1010           12 :                 request_lsn: lsn,
    1011           12 :                 ancestor_lsn: None,
    1012           12 :                 backtrace: None,
    1013           12 :             })),
    1014              :         }
    1015       606776 :     }
    1016              : 
    1017              :     pub(crate) const MAX_GET_VECTORED_KEYS: u64 = 32;
    1018              :     pub(crate) const VEC_GET_LAYERS_VISITED_WARN_THRESH: f64 = 512.0;
    1019              : 
    1020              :     /// Look up multiple page versions at a given LSN
    1021              :     ///
    1022              :     /// This naive implementation will be replaced with a more efficient one
    1023              :     /// which actually vectorizes the read path.
    1024        19528 :     pub(crate) async fn get_vectored(
    1025        19528 :         &self,
    1026        19528 :         keyspace: KeySpace,
    1027        19528 :         lsn: Lsn,
    1028        19528 :         ctx: &RequestContext,
    1029        19528 :     ) -> Result<BTreeMap<Key, Result<Bytes, PageReconstructError>>, GetVectoredError> {
    1030        19528 :         if !lsn.is_valid() {
    1031            0 :             return Err(GetVectoredError::InvalidLsn(lsn));
    1032        19528 :         }
    1033        19528 : 
    1034        19528 :         let key_count = keyspace.total_raw_size().try_into().unwrap();
    1035        19528 :         if key_count > Timeline::MAX_GET_VECTORED_KEYS {
    1036            0 :             return Err(GetVectoredError::Oversized(key_count));
    1037        19528 :         }
    1038              : 
    1039        39056 :         for range in &keyspace.ranges {
    1040        19528 :             let mut key = range.start;
    1041        39262 :             while key != range.end {
    1042        19734 :                 assert!(!self.shard_identity.is_key_disposable(&key));
    1043        19734 :                 key = key.next();
    1044              :             }
    1045              :         }
    1046              : 
    1047        19528 :         trace!(
    1048            0 :             "get vectored request for {:?}@{} from task kind {:?}",
    1049            0 :             keyspace,
    1050            0 :             lsn,
    1051            0 :             ctx.task_kind(),
    1052              :         );
    1053              : 
    1054        19528 :         let start = crate::metrics::GET_VECTORED_LATENCY
    1055        19528 :             .for_task_kind(ctx.task_kind())
    1056        19528 :             .map(|metric| (metric, Instant::now()));
    1057              : 
    1058              :         // start counting after throttle so that throttle time
    1059              :         // is always less than observation time
    1060        19528 :         let throttled = self
    1061        19528 :             .timeline_get_throttle
    1062        19528 :             .throttle(ctx, key_count as usize)
    1063            0 :             .await;
    1064              : 
    1065        19528 :         let res = self
    1066        19528 :             .get_vectored_impl(
    1067        19528 :                 keyspace.clone(),
    1068        19528 :                 lsn,
    1069        19528 :                 &mut ValuesReconstructState::new(),
    1070        19528 :                 ctx,
    1071        19528 :             )
    1072         7037 :             .await;
    1073              : 
    1074        19528 :         if let Some((metric, start)) = start {
    1075            0 :             let elapsed = start.elapsed();
    1076            0 :             let ex_throttled = if let Some(throttled) = throttled {
    1077            0 :                 elapsed.checked_sub(throttled)
    1078              :             } else {
    1079            0 :                 Some(elapsed)
    1080              :             };
    1081              : 
    1082            0 :             if let Some(ex_throttled) = ex_throttled {
    1083            0 :                 metric.observe(ex_throttled.as_secs_f64());
    1084            0 :             } else {
    1085            0 :                 use utils::rate_limit::RateLimit;
    1086            0 :                 static LOGGED: Lazy<Mutex<RateLimit>> =
    1087            0 :                     Lazy::new(|| Mutex::new(RateLimit::new(Duration::from_secs(10))));
    1088            0 :                 let mut rate_limit = LOGGED.lock().unwrap();
    1089            0 :                 rate_limit.call(|| {
    1090            0 :                     warn!("error deducting time spent throttled; this message is logged at a global rate limit");
    1091            0 :                 });
    1092            0 :             }
    1093        19528 :         }
    1094              : 
    1095        19528 :         res
    1096        19528 :     }
    1097              : 
    1098              :     /// Scan the keyspace and return all existing key-values in the keyspace. This currently uses vectored
    1099              :     /// get underlying. Normal vectored get would throw an error when a key in the keyspace is not found
    1100              :     /// during the search, but for the scan interface, it returns all existing key-value pairs, and does
    1101              :     /// not expect each single key in the key space will be found. The semantics is closer to the RocksDB
    1102              :     /// scan iterator interface. We could optimize this interface later to avoid some checks in the vectored
    1103              :     /// get path to maintain and split the probing and to-be-probe keyspace. We also need to ensure that
    1104              :     /// the scan operation will not cause OOM in the future.
    1105           12 :     pub(crate) async fn scan(
    1106           12 :         &self,
    1107           12 :         keyspace: KeySpace,
    1108           12 :         lsn: Lsn,
    1109           12 :         ctx: &RequestContext,
    1110           12 :     ) -> Result<BTreeMap<Key, Result<Bytes, PageReconstructError>>, GetVectoredError> {
    1111           12 :         if !lsn.is_valid() {
    1112            0 :             return Err(GetVectoredError::InvalidLsn(lsn));
    1113           12 :         }
    1114           12 : 
    1115           12 :         trace!(
    1116            0 :             "key-value scan request for {:?}@{} from task kind {:?}",
    1117            0 :             keyspace,
    1118            0 :             lsn,
    1119            0 :             ctx.task_kind()
    1120              :         );
    1121              : 
    1122              :         // We should generalize this into Keyspace::contains in the future.
    1123           24 :         for range in &keyspace.ranges {
    1124           12 :             if range.start.field1 < METADATA_KEY_BEGIN_PREFIX
    1125           12 :                 || range.end.field1 > METADATA_KEY_END_PREFIX
    1126              :             {
    1127            0 :                 return Err(GetVectoredError::Other(anyhow::anyhow!(
    1128            0 :                     "only metadata keyspace can be scanned"
    1129            0 :                 )));
    1130           12 :             }
    1131              :         }
    1132              : 
    1133           12 :         let start = crate::metrics::SCAN_LATENCY
    1134           12 :             .for_task_kind(ctx.task_kind())
    1135           12 :             .map(ScanLatencyOngoingRecording::start_recording);
    1136              : 
    1137              :         // start counting after throttle so that throttle time
    1138              :         // is always less than observation time
    1139           12 :         let throttled = self
    1140           12 :             .timeline_get_throttle
    1141           12 :             // assume scan = 1 quota for now until we find a better way to process this
    1142           12 :             .throttle(ctx, 1)
    1143            0 :             .await;
    1144              : 
    1145           12 :         let vectored_res = self
    1146           12 :             .get_vectored_impl(
    1147           12 :                 keyspace.clone(),
    1148           12 :                 lsn,
    1149           12 :                 &mut ValuesReconstructState::default(),
    1150           12 :                 ctx,
    1151           12 :             )
    1152            0 :             .await;
    1153              : 
    1154           12 :         if let Some(recording) = start {
    1155            0 :             recording.observe(throttled);
    1156           12 :         }
    1157              : 
    1158           12 :         vectored_res
    1159           12 :     }
    1160              : 
    1161       626618 :     pub(super) async fn get_vectored_impl(
    1162       626618 :         &self,
    1163       626618 :         keyspace: KeySpace,
    1164       626618 :         lsn: Lsn,
    1165       626618 :         reconstruct_state: &mut ValuesReconstructState,
    1166       626618 :         ctx: &RequestContext,
    1167       626618 :     ) -> Result<BTreeMap<Key, Result<Bytes, PageReconstructError>>, GetVectoredError> {
    1168       626618 :         let get_kind = if keyspace.total_raw_size() == 1 {
    1169       626182 :             GetKind::Singular
    1170              :         } else {
    1171          436 :             GetKind::Vectored
    1172              :         };
    1173              : 
    1174       626618 :         let get_data_timer = crate::metrics::GET_RECONSTRUCT_DATA_TIME
    1175       626618 :             .for_get_kind(get_kind)
    1176       626618 :             .start_timer();
    1177       626618 :         self.get_vectored_reconstruct_data(keyspace.clone(), lsn, reconstruct_state, ctx)
    1178       192119 :             .await?;
    1179       626602 :         get_data_timer.stop_and_record();
    1180       626602 : 
    1181       626602 :         let reconstruct_timer = crate::metrics::RECONSTRUCT_TIME
    1182       626602 :             .for_get_kind(get_kind)
    1183       626602 :             .start_timer();
    1184       626602 :         let mut results: BTreeMap<Key, Result<Bytes, PageReconstructError>> = BTreeMap::new();
    1185       626602 :         let layers_visited = reconstruct_state.get_layers_visited();
    1186              : 
    1187       666928 :         for (key, res) in std::mem::take(&mut reconstruct_state.keys) {
    1188       666928 :             match res {
    1189            0 :                 Err(err) => {
    1190            0 :                     results.insert(key, Err(err));
    1191            0 :                 }
    1192       666928 :                 Ok(state) => {
    1193       666928 :                     let state = ValueReconstructState::from(state);
    1194              : 
    1195       666928 :                     let reconstruct_res = self.reconstruct_value(key, lsn, state).await;
    1196       666928 :                     results.insert(key, reconstruct_res);
    1197              :                 }
    1198              :             }
    1199              :         }
    1200       626602 :         reconstruct_timer.stop_and_record();
    1201       626602 : 
    1202       626602 :         // For aux file keys (v1 or v2) the vectored read path does not return an error
    1203       626602 :         // when they're missing. Instead they are omitted from the resulting btree
    1204       626602 :         // (this is a requirement, not a bug). Skip updating the metric in these cases
    1205       626602 :         // to avoid infinite results.
    1206       626602 :         if !results.is_empty() {
    1207       626396 :             let avg = layers_visited as f64 / results.len() as f64;
    1208       626396 :             if avg >= Self::VEC_GET_LAYERS_VISITED_WARN_THRESH {
    1209            0 :                 use utils::rate_limit::RateLimit;
    1210            0 :                 static LOGGED: Lazy<Mutex<RateLimit>> =
    1211            0 :                     Lazy::new(|| Mutex::new(RateLimit::new(Duration::from_secs(60))));
    1212            0 :                 let mut rate_limit = LOGGED.lock().unwrap();
    1213            0 :                 rate_limit.call(|| {
    1214            0 :                     tracing::info!(
    1215            0 :                       shard_id = %self.tenant_shard_id.shard_slug(),
    1216            0 :                       lsn = %lsn,
    1217            0 :                       "Vectored read for {} visited {} layers on average per key and {} in total. {}/{} pages were returned",
    1218            0 :                       keyspace, avg, layers_visited, results.len(), keyspace.total_raw_size());
    1219            0 :                 });
    1220       626396 :             }
    1221              : 
    1222              :             // Note that this is an approximation. Tracking the exact number of layers visited
    1223              :             // per key requires virtually unbounded memory usage and is inefficient
    1224              :             // (i.e. segment tree tracking each range queried from a layer)
    1225       626396 :             crate::metrics::VEC_READ_NUM_LAYERS_VISITED.observe(avg);
    1226          206 :         }
    1227              : 
    1228       626602 :         Ok(results)
    1229       626618 :     }
    1230              : 
    1231              :     /// Get last or prev record separately. Same as get_last_record_rlsn().last/prev.
    1232       274290 :     pub(crate) fn get_last_record_lsn(&self) -> Lsn {
    1233       274290 :         self.last_record_lsn.load().last
    1234       274290 :     }
    1235              : 
    1236            0 :     pub(crate) fn get_prev_record_lsn(&self) -> Lsn {
    1237            0 :         self.last_record_lsn.load().prev
    1238            0 :     }
    1239              : 
    1240              :     /// Atomically get both last and prev.
    1241          228 :     pub(crate) fn get_last_record_rlsn(&self) -> RecordLsn {
    1242          228 :         self.last_record_lsn.load()
    1243          228 :     }
    1244              : 
    1245              :     /// Subscribe to callers of wait_lsn(). The value of the channel is None if there are no
    1246              :     /// wait_lsn() calls in progress, and Some(Lsn) if there is an active waiter for wait_lsn().
    1247            0 :     pub(crate) fn subscribe_for_wait_lsn_updates(&self) -> watch::Receiver<Option<Lsn>> {
    1248            0 :         self.last_record_lsn.status_receiver()
    1249            0 :     }
    1250              : 
    1251          414 :     pub(crate) fn get_disk_consistent_lsn(&self) -> Lsn {
    1252          414 :         self.disk_consistent_lsn.load()
    1253          414 :     }
    1254              : 
    1255              :     /// remote_consistent_lsn from the perspective of the tenant's current generation,
    1256              :     /// not validated with control plane yet.
    1257              :     /// See [`Self::get_remote_consistent_lsn_visible`].
    1258            0 :     pub(crate) fn get_remote_consistent_lsn_projected(&self) -> Option<Lsn> {
    1259            0 :         self.remote_client.remote_consistent_lsn_projected()
    1260            0 :     }
    1261              : 
    1262              :     /// remote_consistent_lsn which the tenant is guaranteed not to go backward from,
    1263              :     /// i.e. a value of remote_consistent_lsn_projected which has undergone
    1264              :     /// generation validation in the deletion queue.
    1265            0 :     pub(crate) fn get_remote_consistent_lsn_visible(&self) -> Option<Lsn> {
    1266            0 :         self.remote_client.remote_consistent_lsn_visible()
    1267            0 :     }
    1268              : 
    1269              :     /// The sum of the file size of all historic layers in the layer map.
    1270              :     /// This method makes no distinction between local and remote layers.
    1271              :     /// Hence, the result **does not represent local filesystem usage**.
    1272            0 :     pub(crate) async fn layer_size_sum(&self) -> u64 {
    1273            0 :         let guard = self.layers.read().await;
    1274            0 :         guard.layer_size_sum()
    1275            0 :     }
    1276              : 
    1277            0 :     pub(crate) fn resident_physical_size(&self) -> u64 {
    1278            0 :         self.metrics.resident_physical_size_get()
    1279            0 :     }
    1280              : 
    1281            0 :     pub(crate) fn get_directory_metrics(&self) -> [u64; DirectoryKind::KINDS_NUM] {
    1282            0 :         array::from_fn(|idx| self.directory_metrics[idx].load(AtomicOrdering::Relaxed))
    1283            0 :     }
    1284              : 
    1285              :     ///
    1286              :     /// Wait until WAL has been received and processed up to this LSN.
    1287              :     ///
    1288              :     /// You should call this before any of the other get_* or list_* functions. Calling
    1289              :     /// those functions with an LSN that has been processed yet is an error.
    1290              :     ///
    1291       225946 :     pub(crate) async fn wait_lsn(
    1292       225946 :         &self,
    1293       225946 :         lsn: Lsn,
    1294       225946 :         who_is_waiting: WaitLsnWaiter<'_>,
    1295       225946 :         ctx: &RequestContext, /* Prepare for use by cancellation */
    1296       225946 :     ) -> Result<(), WaitLsnError> {
    1297       225946 :         let state = self.current_state();
    1298       225946 :         if self.cancel.is_cancelled() || matches!(state, TimelineState::Stopping) {
    1299            0 :             return Err(WaitLsnError::Shutdown);
    1300       225946 :         } else if !matches!(state, TimelineState::Active) {
    1301            0 :             return Err(WaitLsnError::BadState(state));
    1302       225946 :         }
    1303       225946 : 
    1304       225946 :         if cfg!(debug_assertions) {
    1305       225946 :             match ctx.task_kind() {
    1306              :                 TaskKind::WalReceiverManager
    1307              :                 | TaskKind::WalReceiverConnectionHandler
    1308              :                 | TaskKind::WalReceiverConnectionPoller => {
    1309            0 :                     let is_myself = match who_is_waiting {
    1310            0 :                         WaitLsnWaiter::Timeline(waiter) => Weak::ptr_eq(&waiter.myself, &self.myself),
    1311            0 :                         WaitLsnWaiter::Tenant | WaitLsnWaiter::PageService => unreachable!("tenant or page_service context are not expected to have task kind {:?}", ctx.task_kind()),
    1312              :                     };
    1313            0 :                     if is_myself {
    1314            0 :                         if let Err(current) = self.last_record_lsn.would_wait_for(lsn) {
    1315              :                             // walingest is the only one that can advance last_record_lsn; it should make sure to never reach here
    1316            0 :                             panic!("this timeline's walingest task is calling wait_lsn({lsn}) but we only have last_record_lsn={current}; would deadlock");
    1317            0 :                         }
    1318            0 :                     } else {
    1319            0 :                         // if another  timeline's  is waiting for us, there's no deadlock risk because
    1320            0 :                         // our walreceiver task can make progress independent of theirs
    1321            0 :                     }
    1322              :                 }
    1323       225946 :                 _ => {}
    1324              :             }
    1325            0 :         }
    1326              : 
    1327       225946 :         let _timer = crate::metrics::WAIT_LSN_TIME.start_timer();
    1328       225946 : 
    1329       225946 :         match self
    1330       225946 :             .last_record_lsn
    1331       225946 :             .wait_for_timeout(lsn, self.conf.wait_lsn_timeout)
    1332            0 :             .await
    1333              :         {
    1334       225946 :             Ok(()) => Ok(()),
    1335            0 :             Err(e) => {
    1336              :                 use utils::seqwait::SeqWaitError::*;
    1337            0 :                 match e {
    1338            0 :                     Shutdown => Err(WaitLsnError::Shutdown),
    1339              :                     Timeout => {
    1340              :                         // don't count the time spent waiting for lock below, and also in walreceiver.status(), towards the wait_lsn_time_histo
    1341            0 :                         drop(_timer);
    1342            0 :                         let walreceiver_status = self.walreceiver_status();
    1343            0 :                         Err(WaitLsnError::Timeout(format!(
    1344            0 :                         "Timed out while waiting for WAL record at LSN {} to arrive, last_record_lsn {} disk consistent LSN={}, WalReceiver status: {}",
    1345            0 :                         lsn,
    1346            0 :                         self.get_last_record_lsn(),
    1347            0 :                         self.get_disk_consistent_lsn(),
    1348            0 :                         walreceiver_status,
    1349            0 :                     )))
    1350              :                     }
    1351              :                 }
    1352              :             }
    1353              :         }
    1354       225946 :     }
    1355              : 
    1356            0 :     pub(crate) fn walreceiver_status(&self) -> String {
    1357            0 :         match &*self.walreceiver.lock().unwrap() {
    1358            0 :             None => "stopping or stopped".to_string(),
    1359            0 :             Some(walreceiver) => match walreceiver.status() {
    1360            0 :                 Some(status) => status.to_human_readable_string(),
    1361            0 :                 None => "Not active".to_string(),
    1362              :             },
    1363              :         }
    1364            0 :     }
    1365              : 
    1366              :     /// Check that it is valid to request operations with that lsn.
    1367          232 :     pub(crate) fn check_lsn_is_in_scope(
    1368          232 :         &self,
    1369          232 :         lsn: Lsn,
    1370          232 :         latest_gc_cutoff_lsn: &RcuReadGuard<Lsn>,
    1371          232 :     ) -> anyhow::Result<()> {
    1372          232 :         ensure!(
    1373          232 :             lsn >= **latest_gc_cutoff_lsn,
    1374            4 :             "LSN {} is earlier than latest GC cutoff {} (we might've already garbage collected needed data)",
    1375            4 :             lsn,
    1376            4 :             **latest_gc_cutoff_lsn,
    1377              :         );
    1378          228 :         Ok(())
    1379          232 :     }
    1380              : 
    1381              :     /// Initializes an LSN lease. The function will return an error if the requested LSN is less than the `latest_gc_cutoff_lsn`.
    1382           10 :     pub(crate) fn init_lsn_lease(
    1383           10 :         &self,
    1384           10 :         lsn: Lsn,
    1385           10 :         length: Duration,
    1386           10 :         ctx: &RequestContext,
    1387           10 :     ) -> anyhow::Result<LsnLease> {
    1388           10 :         self.make_lsn_lease(lsn, length, true, ctx)
    1389           10 :     }
    1390              : 
    1391              :     /// Renews a lease at a particular LSN. The requested LSN is not validated against the `latest_gc_cutoff_lsn` when we are in the grace period.
    1392            4 :     pub(crate) fn renew_lsn_lease(
    1393            4 :         &self,
    1394            4 :         lsn: Lsn,
    1395            4 :         length: Duration,
    1396            4 :         ctx: &RequestContext,
    1397            4 :     ) -> anyhow::Result<LsnLease> {
    1398            4 :         self.make_lsn_lease(lsn, length, false, ctx)
    1399            4 :     }
    1400              : 
    1401              :     /// Obtains a temporary lease blocking garbage collection for the given LSN.
    1402              :     ///
    1403              :     /// If we are in `AttachedSingle` mode and is not blocked by the lsn lease deadline, this function will error
    1404              :     /// if the requesting LSN is less than the `latest_gc_cutoff_lsn` and there is no existing request present.
    1405              :     ///
    1406              :     /// If there is an existing lease in the map, the lease will be renewed only if the request extends the lease.
    1407              :     /// The returned lease is therefore the maximum between the existing lease and the requesting lease.
    1408           14 :     fn make_lsn_lease(
    1409           14 :         &self,
    1410           14 :         lsn: Lsn,
    1411           14 :         length: Duration,
    1412           14 :         init: bool,
    1413           14 :         _ctx: &RequestContext,
    1414           14 :     ) -> anyhow::Result<LsnLease> {
    1415           12 :         let lease = {
    1416              :             // Normalize the requested LSN to be aligned, and move to the first record
    1417              :             // if it points to the beginning of the page (header).
    1418           14 :             let lsn = xlog_utils::normalize_lsn(lsn, WAL_SEGMENT_SIZE);
    1419           14 : 
    1420           14 :             let mut gc_info = self.gc_info.write().unwrap();
    1421           14 : 
    1422           14 :             let valid_until = SystemTime::now() + length;
    1423           14 : 
    1424           14 :             let entry = gc_info.leases.entry(lsn);
    1425           14 : 
    1426           14 :             match entry {
    1427            6 :                 Entry::Occupied(mut occupied) => {
    1428            6 :                     let existing_lease = occupied.get_mut();
    1429            6 :                     if valid_until > existing_lease.valid_until {
    1430            2 :                         existing_lease.valid_until = valid_until;
    1431            2 :                         let dt: DateTime<Utc> = valid_until.into();
    1432            2 :                         info!("lease extended to {}", dt);
    1433              :                     } else {
    1434            4 :                         let dt: DateTime<Utc> = existing_lease.valid_until.into();
    1435            4 :                         info!("existing lease covers greater length, valid until {}", dt);
    1436              :                     }
    1437              : 
    1438            6 :                     existing_lease.clone()
    1439              :                 }
    1440            8 :                 Entry::Vacant(vacant) => {
    1441              :                     // Reject already GC-ed LSN (lsn < latest_gc_cutoff) if we are in AttachedSingle and
    1442              :                     // not blocked by the lsn lease deadline.
    1443            8 :                     let validate = {
    1444            8 :                         let conf = self.tenant_conf.load();
    1445            8 :                         conf.location.attach_mode == AttachmentMode::Single
    1446            8 :                             && !conf.is_gc_blocked_by_lsn_lease_deadline()
    1447              :                     };
    1448              : 
    1449            8 :                     if init || validate {
    1450            8 :                         let latest_gc_cutoff_lsn = self.get_latest_gc_cutoff_lsn();
    1451            8 :                         if lsn < *latest_gc_cutoff_lsn {
    1452            2 :                             bail!("tried to request a page version that was garbage collected. requested at {} gc cutoff {}", lsn, *latest_gc_cutoff_lsn);
    1453            6 :                         }
    1454            0 :                     }
    1455              : 
    1456            6 :                     let dt: DateTime<Utc> = valid_until.into();
    1457            6 :                     info!("lease created, valid until {}", dt);
    1458            6 :                     vacant.insert(LsnLease { valid_until }).clone()
    1459              :                 }
    1460              :             }
    1461              :         };
    1462              : 
    1463           12 :         Ok(lease)
    1464           14 :     }
    1465              : 
    1466              :     /// Flush to disk all data that was written with the put_* functions
    1467         1092 :     #[instrument(skip(self), fields(tenant_id=%self.tenant_shard_id.tenant_id, shard_id=%self.tenant_shard_id.shard_slug(), timeline_id=%self.timeline_id))]
    1468              :     pub(crate) async fn freeze_and_flush(&self) -> Result<(), FlushLayerError> {
    1469              :         self.freeze_and_flush0().await
    1470              :     }
    1471              : 
    1472              :     // This exists to provide a non-span creating version of `freeze_and_flush` we can call without
    1473              :     // polluting the span hierarchy.
    1474         1092 :     pub(crate) async fn freeze_and_flush0(&self) -> Result<(), FlushLayerError> {
    1475         1092 :         let token = {
    1476              :             // Freeze the current open in-memory layer. It will be written to disk on next
    1477              :             // iteration.
    1478         1092 :             let mut g = self.write_lock.lock().await;
    1479              : 
    1480         1092 :             let to_lsn = self.get_last_record_lsn();
    1481         1092 :             self.freeze_inmem_layer_at(to_lsn, &mut g).await?
    1482              :         };
    1483         1092 :         self.wait_flush_completion(token).await
    1484         1092 :     }
    1485              : 
    1486              :     // Check if an open ephemeral layer should be closed: this provides
    1487              :     // background enforcement of checkpoint interval if there is no active WAL receiver, to avoid keeping
    1488              :     // an ephemeral layer open forever when idle.  It also freezes layers if the global limit on
    1489              :     // ephemeral layer bytes has been breached.
    1490            0 :     pub(super) async fn maybe_freeze_ephemeral_layer(&self) {
    1491            0 :         let Ok(mut write_guard) = self.write_lock.try_lock() else {
    1492              :             // If the write lock is held, there is an active wal receiver: rolling open layers
    1493              :             // is their responsibility while they hold this lock.
    1494            0 :             return;
    1495              :         };
    1496              : 
    1497              :         // FIXME: why not early exit? because before #7927 the state would had been cleared every
    1498              :         // time, and this was missed.
    1499              :         // if write_guard.is_none() { return; }
    1500              : 
    1501            0 :         let Ok(layers_guard) = self.layers.try_read() else {
    1502              :             // Don't block if the layer lock is busy
    1503            0 :             return;
    1504              :         };
    1505              : 
    1506            0 :         let Ok(lm) = layers_guard.layer_map() else {
    1507            0 :             return;
    1508              :         };
    1509              : 
    1510            0 :         let Some(open_layer) = &lm.open_layer else {
    1511              :             // If there is no open layer, we have no layer freezing to do.  However, we might need to generate
    1512              :             // some updates to disk_consistent_lsn and remote_consistent_lsn, in case we ingested some WAL regions
    1513              :             // that didn't result in writes to this shard.
    1514              : 
    1515              :             // Must not hold the layers lock while waiting for a flush.
    1516            0 :             drop(layers_guard);
    1517            0 : 
    1518            0 :             let last_record_lsn = self.get_last_record_lsn();
    1519            0 :             let disk_consistent_lsn = self.get_disk_consistent_lsn();
    1520            0 :             if last_record_lsn > disk_consistent_lsn {
    1521              :                 // We have no open layer, but disk_consistent_lsn is behind the last record: this indicates
    1522              :                 // we are a sharded tenant and have skipped some WAL
    1523            0 :                 let last_freeze_ts = *self.last_freeze_ts.read().unwrap();
    1524            0 :                 if last_freeze_ts.elapsed() >= self.get_checkpoint_timeout() {
    1525              :                     // Only do this if have been layer-less longer than get_checkpoint_timeout, so that a shard
    1526              :                     // without any data ingested (yet) doesn't write a remote index as soon as it
    1527              :                     // sees its LSN advance: we only do this if we've been layer-less
    1528              :                     // for some time.
    1529            0 :                     tracing::debug!(
    1530            0 :                         "Advancing disk_consistent_lsn past WAL ingest gap {} -> {}",
    1531              :                         disk_consistent_lsn,
    1532              :                         last_record_lsn
    1533              :                     );
    1534              : 
    1535              :                     // The flush loop will update remote consistent LSN as well as disk consistent LSN.
    1536              :                     // We know there is no open layer, so we can request freezing without actually
    1537              :                     // freezing anything. This is true even if we have dropped the layers_guard, we
    1538              :                     // still hold the write_guard.
    1539            0 :                     let _ = async {
    1540            0 :                         let token = self
    1541            0 :                             .freeze_inmem_layer_at(last_record_lsn, &mut write_guard)
    1542            0 :                             .await?;
    1543            0 :                         self.wait_flush_completion(token).await
    1544            0 :                     }
    1545            0 :                     .await;
    1546            0 :                 }
    1547            0 :             }
    1548              : 
    1549            0 :             return;
    1550              :         };
    1551              : 
    1552            0 :         let Some(current_size) = open_layer.try_len() else {
    1553              :             // Unexpected: since we hold the write guard, nobody else should be writing to this layer, so
    1554              :             // read lock to get size should always succeed.
    1555            0 :             tracing::warn!("Lock conflict while reading size of open layer");
    1556            0 :             return;
    1557              :         };
    1558              : 
    1559            0 :         let current_lsn = self.get_last_record_lsn();
    1560              : 
    1561            0 :         let checkpoint_distance_override = open_layer.tick().await;
    1562              : 
    1563            0 :         if let Some(size_override) = checkpoint_distance_override {
    1564            0 :             if current_size > size_override {
    1565              :                 // This is not harmful, but it only happens in relatively rare cases where
    1566              :                 // time-based checkpoints are not happening fast enough to keep the amount of
    1567              :                 // ephemeral data within configured limits.  It's a sign of stress on the system.
    1568            0 :                 tracing::info!("Early-rolling open layer at size {current_size} (limit {size_override}) due to dirty data pressure");
    1569            0 :             }
    1570            0 :         }
    1571              : 
    1572            0 :         let checkpoint_distance =
    1573            0 :             checkpoint_distance_override.unwrap_or(self.get_checkpoint_distance());
    1574            0 : 
    1575            0 :         if self.should_roll(
    1576            0 :             current_size,
    1577            0 :             current_size,
    1578            0 :             checkpoint_distance,
    1579            0 :             self.get_last_record_lsn(),
    1580            0 :             self.last_freeze_at.load(),
    1581            0 :             open_layer.get_opened_at(),
    1582            0 :         ) {
    1583            0 :             match open_layer.info() {
    1584            0 :                 InMemoryLayerInfo::Frozen { lsn_start, lsn_end } => {
    1585            0 :                     // We may reach this point if the layer was already frozen by not yet flushed: flushing
    1586            0 :                     // happens asynchronously in the background.
    1587            0 :                     tracing::debug!(
    1588            0 :                         "Not freezing open layer, it's already frozen ({lsn_start}..{lsn_end})"
    1589              :                     );
    1590              :                 }
    1591              :                 InMemoryLayerInfo::Open { .. } => {
    1592              :                     // Upgrade to a write lock and freeze the layer
    1593            0 :                     drop(layers_guard);
    1594            0 :                     let res = self
    1595            0 :                         .freeze_inmem_layer_at(current_lsn, &mut write_guard)
    1596            0 :                         .await;
    1597              : 
    1598            0 :                     if let Err(e) = res {
    1599            0 :                         tracing::info!(
    1600            0 :                             "failed to flush frozen layer after background freeze: {e:#}"
    1601              :                         );
    1602            0 :                     }
    1603              :                 }
    1604              :             }
    1605            0 :         }
    1606            0 :     }
    1607              : 
    1608              :     /// Checks if the internal state of the timeline is consistent with it being able to be offloaded.
    1609              :     ///
    1610              :     /// This is neccessary but not sufficient for offloading of the timeline as it might have
    1611              :     /// child timelines that are not offloaded yet.
    1612            0 :     pub(crate) fn can_offload(&self) -> (bool, &'static str) {
    1613            0 :         if self.remote_client.is_archived() != Some(true) {
    1614            0 :             return (false, "the timeline is not archived");
    1615            0 :         }
    1616            0 :         if !self.remote_client.no_pending_work() {
    1617              :             // if the remote client is still processing some work, we can't offload
    1618            0 :             return (false, "the upload queue is not drained yet");
    1619            0 :         }
    1620            0 : 
    1621            0 :         (true, "ok")
    1622            0 :     }
    1623              : 
    1624              :     /// Outermost timeline compaction operation; downloads needed layers. Returns whether we have pending
    1625              :     /// compaction tasks.
    1626          364 :     pub(crate) async fn compact(
    1627          364 :         self: &Arc<Self>,
    1628          364 :         cancel: &CancellationToken,
    1629          364 :         flags: EnumSet<CompactFlags>,
    1630          364 :         ctx: &RequestContext,
    1631          364 :     ) -> Result<bool, CompactionError> {
    1632          364 :         self.compact_with_options(
    1633          364 :             cancel,
    1634          364 :             CompactOptions {
    1635          364 :                 flags,
    1636          364 :                 compact_range: None,
    1637          364 :             },
    1638          364 :             ctx,
    1639          364 :         )
    1640        37020 :         .await
    1641          364 :     }
    1642              : 
    1643              :     /// Outermost timeline compaction operation; downloads needed layers. Returns whether we have pending
    1644              :     /// compaction tasks.
    1645          364 :     pub(crate) async fn compact_with_options(
    1646          364 :         self: &Arc<Self>,
    1647          364 :         cancel: &CancellationToken,
    1648          364 :         options: CompactOptions,
    1649          364 :         ctx: &RequestContext,
    1650          364 :     ) -> Result<bool, CompactionError> {
    1651          364 :         // most likely the cancellation token is from background task, but in tests it could be the
    1652          364 :         // request task as well.
    1653          364 : 
    1654          364 :         let prepare = async move {
    1655          364 :             let guard = self.compaction_lock.lock().await;
    1656              : 
    1657          364 :             let permit = super::tasks::concurrent_background_tasks_rate_limit_permit(
    1658          364 :                 BackgroundLoopKind::Compaction,
    1659          364 :                 ctx,
    1660          364 :             )
    1661            0 :             .await;
    1662              : 
    1663          364 :             (guard, permit)
    1664          364 :         };
    1665              : 
    1666              :         // this wait probably never needs any "long time spent" logging, because we already nag if
    1667              :         // compaction task goes over it's period (20s) which is quite often in production.
    1668          364 :         let (_guard, _permit) = tokio::select! {
    1669          364 :             tuple = prepare => { tuple },
    1670          364 :             _ = self.cancel.cancelled() => return Ok(false),
    1671          364 :             _ = cancel.cancelled() => return Ok(false),
    1672              :         };
    1673              : 
    1674          364 :         let last_record_lsn = self.get_last_record_lsn();
    1675          364 : 
    1676          364 :         // Last record Lsn could be zero in case the timeline was just created
    1677          364 :         if !last_record_lsn.is_valid() {
    1678            0 :             warn!("Skipping compaction for potentially just initialized timeline, it has invalid last record lsn: {last_record_lsn}");
    1679            0 :             return Ok(false);
    1680          364 :         }
    1681          364 : 
    1682          364 :         match self.get_compaction_algorithm_settings().kind {
    1683              :             CompactionAlgorithm::Tiered => {
    1684            0 :                 self.compact_tiered(cancel, ctx).await?;
    1685            0 :                 Ok(false)
    1686              :             }
    1687        37020 :             CompactionAlgorithm::Legacy => self.compact_legacy(cancel, options, ctx).await,
    1688              :         }
    1689          364 :     }
    1690              : 
    1691              :     /// Mutate the timeline with a [`TimelineWriter`].
    1692      5133162 :     pub(crate) async fn writer(&self) -> TimelineWriter<'_> {
    1693      5133162 :         TimelineWriter {
    1694      5133162 :             tl: self,
    1695      5133162 :             write_guard: self.write_lock.lock().await,
    1696              :         }
    1697      5133162 :     }
    1698              : 
    1699            0 :     pub(crate) fn activate(
    1700            0 :         self: &Arc<Self>,
    1701            0 :         parent: Arc<crate::tenant::Tenant>,
    1702            0 :         broker_client: BrokerClientChannel,
    1703            0 :         background_jobs_can_start: Option<&completion::Barrier>,
    1704            0 :         ctx: &RequestContext,
    1705            0 :     ) {
    1706            0 :         if self.tenant_shard_id.is_shard_zero() {
    1707            0 :             // Logical size is only maintained accurately on shard zero.
    1708            0 :             self.spawn_initial_logical_size_computation_task(ctx);
    1709            0 :         }
    1710            0 :         self.launch_wal_receiver(ctx, broker_client);
    1711            0 :         self.set_state(TimelineState::Active);
    1712            0 :         self.launch_eviction_task(parent, background_jobs_can_start);
    1713            0 :     }
    1714              : 
    1715              :     /// After this function returns, there are no timeline-scoped tasks are left running.
    1716              :     ///
    1717              :     /// The preferred pattern for is:
    1718              :     /// - in any spawned tasks, keep Timeline::guard open + Timeline::cancel / child token
    1719              :     /// - if early shutdown (not just cancellation) of a sub-tree of tasks is required,
    1720              :     ///   go the extra mile and keep track of JoinHandles
    1721              :     /// - Keep track of JoinHandles using a passed-down `Arc<Mutex<Option<JoinSet>>>` or similar,
    1722              :     ///   instead of spawning directly on a runtime. It is a more composable / testable pattern.
    1723              :     ///
    1724              :     /// For legacy reasons, we still have multiple tasks spawned using
    1725              :     /// `task_mgr::spawn(X, Some(tenant_id), Some(timeline_id))`.
    1726              :     /// We refer to these as "timeline-scoped task_mgr tasks".
    1727              :     /// Some of these tasks are already sensitive to Timeline::cancel while others are
    1728              :     /// not sensitive to Timeline::cancel and instead respect [`task_mgr::shutdown_token`]
    1729              :     /// or [`task_mgr::shutdown_watcher`].
    1730              :     /// We want to gradually convert the code base away from these.
    1731              :     ///
    1732              :     /// Here is an inventory of timeline-scoped task_mgr tasks that are still sensitive to
    1733              :     /// `task_mgr::shutdown_{token,watcher}` (there are also tenant-scoped and global-scoped
    1734              :     /// ones that aren't mentioned here):
    1735              :     /// - [`TaskKind::TimelineDeletionWorker`]
    1736              :     ///    - NB: also used for tenant deletion
    1737              :     /// - [`TaskKind::RemoteUploadTask`]`
    1738              :     /// - [`TaskKind::InitialLogicalSizeCalculation`]
    1739              :     /// - [`TaskKind::DownloadAllRemoteLayers`] (can we get rid of it?)
    1740              :     // Inventory of timeline-scoped task_mgr tasks that use spawn but aren't sensitive:
    1741              :     /// - [`TaskKind::Eviction`]
    1742              :     /// - [`TaskKind::LayerFlushTask`]
    1743              :     /// - [`TaskKind::OndemandLogicalSizeCalculation`]
    1744              :     /// - [`TaskKind::GarbageCollector`] (immediate_gc is timeline-scoped)
    1745           10 :     pub(crate) async fn shutdown(&self, mode: ShutdownMode) {
    1746           10 :         debug_assert_current_span_has_tenant_and_timeline_id();
    1747           10 : 
    1748           10 :         // Regardless of whether we're going to try_freeze_and_flush
    1749           10 :         // or not, stop ingesting any more data. Walreceiver only provides
    1750           10 :         // cancellation but no "wait until gone", because it uses the Timeline::gate.
    1751           10 :         // So, only after the self.gate.close() below will we know for sure that
    1752           10 :         // no walreceiver tasks are left.
    1753           10 :         // For `try_freeze_and_flush=true`, this means that we might still be ingesting
    1754           10 :         // data during the call to `self.freeze_and_flush()` below.
    1755           10 :         // That's not ideal, but, we don't have the concept of a ChildGuard,
    1756           10 :         // which is what we'd need to properly model early shutdown of the walreceiver
    1757           10 :         // task sub-tree before the other Timeline task sub-trees.
    1758           10 :         let walreceiver = self.walreceiver.lock().unwrap().take();
    1759           10 :         tracing::debug!(
    1760            0 :             is_some = walreceiver.is_some(),
    1761            0 :             "Waiting for WalReceiverManager..."
    1762              :         );
    1763           10 :         if let Some(walreceiver) = walreceiver {
    1764            0 :             walreceiver.cancel();
    1765           10 :         }
    1766              :         // ... and inform any waiters for newer LSNs that there won't be any.
    1767           10 :         self.last_record_lsn.shutdown();
    1768           10 : 
    1769           10 :         if let ShutdownMode::FreezeAndFlush = mode {
    1770            6 :             if let Some((open, frozen)) = self
    1771            6 :                 .layers
    1772            6 :                 .read()
    1773            0 :                 .await
    1774            6 :                 .layer_map()
    1775            6 :                 .map(|lm| (lm.open_layer.is_some(), lm.frozen_layers.len()))
    1776            6 :                 .ok()
    1777            6 :                 .filter(|(open, frozen)| *open || *frozen > 0)
    1778              :             {
    1779            0 :                 tracing::info!(?open, frozen, "flushing and freezing on shutdown");
    1780            6 :             } else {
    1781            6 :                 // this is double-shutdown, ignore it
    1782            6 :             }
    1783              : 
    1784              :             // we shut down walreceiver above, so, we won't add anything more
    1785              :             // to the InMemoryLayer; freeze it and wait for all frozen layers
    1786              :             // to reach the disk & upload queue, then shut the upload queue and
    1787              :             // wait for it to drain.
    1788            6 :             match self.freeze_and_flush().await {
    1789              :                 Ok(_) => {
    1790              :                     // drain the upload queue
    1791              :                     // if we did not wait for completion here, it might be our shutdown process
    1792              :                     // didn't wait for remote uploads to complete at all, as new tasks can forever
    1793              :                     // be spawned.
    1794              :                     //
    1795              :                     // what is problematic is the shutting down of RemoteTimelineClient, because
    1796              :                     // obviously it does not make sense to stop while we wait for it, but what
    1797              :                     // about corner cases like s3 suddenly hanging up?
    1798            6 :                     self.remote_client.shutdown().await;
    1799              :                 }
    1800              :                 Err(FlushLayerError::Cancelled) => {
    1801              :                     // this is likely the second shutdown, ignore silently.
    1802              :                     // TODO: this can be removed once https://github.com/neondatabase/neon/issues/5080
    1803            0 :                     debug_assert!(self.cancel.is_cancelled());
    1804              :                 }
    1805            0 :                 Err(e) => {
    1806            0 :                     // Non-fatal.  Shutdown is infallible.  Failures to flush just mean that
    1807            0 :                     // we have some extra WAL replay to do next time the timeline starts.
    1808            0 :                     warn!("failed to freeze and flush: {e:#}");
    1809              :                 }
    1810              :             }
    1811              : 
    1812              :             // `self.remote_client.shutdown().await` above should have already flushed everything from the queue, but
    1813              :             // we also do a final check here to ensure that the queue is empty.
    1814            6 :             if !self.remote_client.no_pending_work() {
    1815            0 :                 warn!("still have pending work in remote upload queue, but continuing shutting down anyways");
    1816            6 :             }
    1817            4 :         }
    1818              : 
    1819           10 :         if let ShutdownMode::Flush = mode {
    1820              :             // drain the upload queue
    1821            2 :             self.remote_client.shutdown().await;
    1822            2 :             if !self.remote_client.no_pending_work() {
    1823            0 :                 warn!("still have pending work in remote upload queue, but continuing shutting down anyways");
    1824            2 :             }
    1825            8 :         }
    1826              : 
    1827              :         // Signal any subscribers to our cancellation token to drop out
    1828           10 :         tracing::debug!("Cancelling CancellationToken");
    1829           10 :         self.cancel.cancel();
    1830           10 : 
    1831           10 :         // Ensure Prevent new page service requests from starting.
    1832           10 :         self.handles.shutdown();
    1833           10 : 
    1834           10 :         // Transition the remote_client into a state where it's only useful for timeline deletion.
    1835           10 :         // (The deletion use case is why we can't just hook up remote_client to Self::cancel).)
    1836           10 :         self.remote_client.stop();
    1837           10 : 
    1838           10 :         // As documented in remote_client.stop()'s doc comment, it's our responsibility
    1839           10 :         // to shut down the upload queue tasks.
    1840           10 :         // TODO: fix that, task management should be encapsulated inside remote_client.
    1841           10 :         task_mgr::shutdown_tasks(
    1842           10 :             Some(TaskKind::RemoteUploadTask),
    1843           10 :             Some(self.tenant_shard_id),
    1844           10 :             Some(self.timeline_id),
    1845           10 :         )
    1846            0 :         .await;
    1847              : 
    1848              :         // TODO: work toward making this a no-op. See this function's doc comment for more context.
    1849           10 :         tracing::debug!("Waiting for tasks...");
    1850           10 :         task_mgr::shutdown_tasks(None, Some(self.tenant_shard_id), Some(self.timeline_id)).await;
    1851              : 
    1852              :         {
    1853              :             // Allow any remaining in-memory layers to do cleanup -- until that, they hold the gate
    1854              :             // open.
    1855           10 :             let mut write_guard = self.write_lock.lock().await;
    1856           10 :             self.layers.write().await.shutdown(&mut write_guard);
    1857           10 :         }
    1858           10 : 
    1859           10 :         // Finally wait until any gate-holders are complete.
    1860           10 :         //
    1861           10 :         // TODO: once above shutdown_tasks is a no-op, we can close the gate before calling shutdown_tasks
    1862           10 :         // and use a TBD variant of shutdown_tasks that asserts that there were no tasks left.
    1863           10 :         self.gate.close().await;
    1864              : 
    1865           10 :         self.metrics.shutdown();
    1866           10 :     }
    1867              : 
    1868          420 :     pub(crate) fn set_state(&self, new_state: TimelineState) {
    1869          420 :         match (self.current_state(), new_state) {
    1870          420 :             (equal_state_1, equal_state_2) if equal_state_1 == equal_state_2 => {
    1871            2 :                 info!("Ignoring new state, equal to the existing one: {equal_state_2:?}");
    1872              :             }
    1873            0 :             (st, TimelineState::Loading) => {
    1874            0 :                 error!("ignoring transition from {st:?} into Loading state");
    1875              :             }
    1876            0 :             (TimelineState::Broken { .. }, new_state) => {
    1877            0 :                 error!("Ignoring state update {new_state:?} for broken timeline");
    1878              :             }
    1879              :             (TimelineState::Stopping, TimelineState::Active) => {
    1880            0 :                 error!("Not activating a Stopping timeline");
    1881              :             }
    1882          418 :             (_, new_state) => {
    1883          418 :                 self.state.send_replace(new_state);
    1884          418 :             }
    1885              :         }
    1886          420 :     }
    1887              : 
    1888            2 :     pub(crate) fn set_broken(&self, reason: String) {
    1889            2 :         let backtrace_str: String = format!("{}", std::backtrace::Backtrace::force_capture());
    1890            2 :         let broken_state = TimelineState::Broken {
    1891            2 :             reason,
    1892            2 :             backtrace: backtrace_str,
    1893            2 :         };
    1894            2 :         self.set_state(broken_state);
    1895            2 : 
    1896            2 :         // Although the Broken state is not equivalent to shutdown() (shutdown will be called
    1897            2 :         // later when this tenant is detach or the process shuts down), firing the cancellation token
    1898            2 :         // here avoids the need for other tasks to watch for the Broken state explicitly.
    1899            2 :         self.cancel.cancel();
    1900            2 :     }
    1901              : 
    1902       226956 :     pub(crate) fn current_state(&self) -> TimelineState {
    1903       226956 :         self.state.borrow().clone()
    1904       226956 :     }
    1905              : 
    1906            6 :     pub(crate) fn is_broken(&self) -> bool {
    1907            6 :         matches!(&*self.state.borrow(), TimelineState::Broken { .. })
    1908            6 :     }
    1909              : 
    1910          222 :     pub(crate) fn is_active(&self) -> bool {
    1911          222 :         self.current_state() == TimelineState::Active
    1912          222 :     }
    1913              : 
    1914            2 :     pub(crate) fn is_archived(&self) -> Option<bool> {
    1915            2 :         self.remote_client.is_archived()
    1916            2 :     }
    1917              : 
    1918          368 :     pub(crate) fn is_stopping(&self) -> bool {
    1919          368 :         self.current_state() == TimelineState::Stopping
    1920          368 :     }
    1921              : 
    1922            0 :     pub(crate) fn subscribe_for_state_updates(&self) -> watch::Receiver<TimelineState> {
    1923            0 :         self.state.subscribe()
    1924            0 :     }
    1925              : 
    1926       225948 :     pub(crate) async fn wait_to_become_active(
    1927       225948 :         &self,
    1928       225948 :         _ctx: &RequestContext, // Prepare for use by cancellation
    1929       225948 :     ) -> Result<(), TimelineState> {
    1930       225948 :         let mut receiver = self.state.subscribe();
    1931              :         loop {
    1932       225948 :             let current_state = receiver.borrow().clone();
    1933       225948 :             match current_state {
    1934              :                 TimelineState::Loading => {
    1935            0 :                     receiver
    1936            0 :                         .changed()
    1937            0 :                         .await
    1938            0 :                         .expect("holding a reference to self");
    1939              :                 }
    1940              :                 TimelineState::Active { .. } => {
    1941       225946 :                     return Ok(());
    1942              :                 }
    1943              :                 TimelineState::Broken { .. } | TimelineState::Stopping => {
    1944              :                     // There's no chance the timeline can transition back into ::Active
    1945            2 :                     return Err(current_state);
    1946              :                 }
    1947              :             }
    1948              :         }
    1949       225948 :     }
    1950              : 
    1951            0 :     pub(crate) async fn layer_map_info(
    1952            0 :         &self,
    1953            0 :         reset: LayerAccessStatsReset,
    1954            0 :     ) -> Result<LayerMapInfo, layer_manager::Shutdown> {
    1955            0 :         let guard = self.layers.read().await;
    1956            0 :         let layer_map = guard.layer_map()?;
    1957            0 :         let mut in_memory_layers = Vec::with_capacity(layer_map.frozen_layers.len() + 1);
    1958            0 :         if let Some(open_layer) = &layer_map.open_layer {
    1959            0 :             in_memory_layers.push(open_layer.info());
    1960            0 :         }
    1961            0 :         for frozen_layer in &layer_map.frozen_layers {
    1962            0 :             in_memory_layers.push(frozen_layer.info());
    1963            0 :         }
    1964              : 
    1965            0 :         let historic_layers = layer_map
    1966            0 :             .iter_historic_layers()
    1967            0 :             .map(|desc| guard.get_from_desc(&desc).info(reset))
    1968            0 :             .collect();
    1969            0 : 
    1970            0 :         Ok(LayerMapInfo {
    1971            0 :             in_memory_layers,
    1972            0 :             historic_layers,
    1973            0 :         })
    1974            0 :     }
    1975              : 
    1976            0 :     #[instrument(skip_all, fields(tenant_id = %self.tenant_shard_id.tenant_id, shard_id = %self.tenant_shard_id.shard_slug(), timeline_id = %self.timeline_id))]
    1977              :     pub(crate) async fn download_layer(
    1978              :         &self,
    1979              :         layer_file_name: &LayerName,
    1980              :     ) -> anyhow::Result<Option<bool>> {
    1981              :         let Some(layer) = self.find_layer(layer_file_name).await? else {
    1982              :             return Ok(None);
    1983              :         };
    1984              : 
    1985              :         layer.download().await?;
    1986              : 
    1987              :         Ok(Some(true))
    1988              :     }
    1989              : 
    1990              :     /// Evict just one layer.
    1991              :     ///
    1992              :     /// Returns `Ok(None)` in the case where the layer could not be found by its `layer_file_name`.
    1993            0 :     pub(crate) async fn evict_layer(
    1994            0 :         &self,
    1995            0 :         layer_file_name: &LayerName,
    1996            0 :     ) -> anyhow::Result<Option<bool>> {
    1997            0 :         let _gate = self
    1998            0 :             .gate
    1999            0 :             .enter()
    2000            0 :             .map_err(|_| anyhow::anyhow!("Shutting down"))?;
    2001              : 
    2002            0 :         let Some(local_layer) = self.find_layer(layer_file_name).await? else {
    2003            0 :             return Ok(None);
    2004              :         };
    2005              : 
    2006              :         // curl has this by default
    2007            0 :         let timeout = std::time::Duration::from_secs(120);
    2008            0 : 
    2009            0 :         match local_layer.evict_and_wait(timeout).await {
    2010            0 :             Ok(()) => Ok(Some(true)),
    2011            0 :             Err(EvictionError::NotFound) => Ok(Some(false)),
    2012            0 :             Err(EvictionError::Downloaded) => Ok(Some(false)),
    2013            0 :             Err(EvictionError::Timeout) => Ok(Some(false)),
    2014              :         }
    2015            0 :     }
    2016              : 
    2017      4803010 :     fn should_roll(
    2018      4803010 :         &self,
    2019      4803010 :         layer_size: u64,
    2020      4803010 :         projected_layer_size: u64,
    2021      4803010 :         checkpoint_distance: u64,
    2022      4803010 :         projected_lsn: Lsn,
    2023      4803010 :         last_freeze_at: Lsn,
    2024      4803010 :         opened_at: Instant,
    2025      4803010 :     ) -> bool {
    2026      4803010 :         let distance = projected_lsn.widening_sub(last_freeze_at);
    2027      4803010 : 
    2028      4803010 :         // Rolling the open layer can be triggered by:
    2029      4803010 :         // 1. The distance from the last LSN we rolled at. This bounds the amount of WAL that
    2030      4803010 :         //    the safekeepers need to store.  For sharded tenants, we multiply by shard count to
    2031      4803010 :         //    account for how writes are distributed across shards: we expect each node to consume
    2032      4803010 :         //    1/count of the LSN on average.
    2033      4803010 :         // 2. The size of the currently open layer.
    2034      4803010 :         // 3. The time since the last roll. It helps safekeepers to regard pageserver as caught
    2035      4803010 :         //    up and suspend activity.
    2036      4803010 :         if distance >= checkpoint_distance as i128 * self.shard_identity.count.count() as i128 {
    2037            0 :             info!(
    2038            0 :                 "Will roll layer at {} with layer size {} due to LSN distance ({})",
    2039              :                 projected_lsn, layer_size, distance
    2040              :             );
    2041              : 
    2042            0 :             true
    2043      4803010 :         } else if projected_layer_size >= checkpoint_distance {
    2044              :             // NB: this check is relied upon by:
    2045           80 :             let _ = IndexEntry::validate_checkpoint_distance;
    2046           80 :             info!(
    2047            0 :                 "Will roll layer at {} with layer size {} due to layer size ({})",
    2048              :                 projected_lsn, layer_size, projected_layer_size
    2049              :             );
    2050              : 
    2051           80 :             true
    2052      4802930 :         } else if distance > 0 && opened_at.elapsed() >= self.get_checkpoint_timeout() {
    2053            0 :             info!(
    2054            0 :                 "Will roll layer at {} with layer size {} due to time since first write to the layer ({:?})",
    2055            0 :                 projected_lsn,
    2056            0 :                 layer_size,
    2057            0 :                 opened_at.elapsed()
    2058              :             );
    2059              : 
    2060            0 :             true
    2061              :         } else {
    2062      4802930 :             false
    2063              :         }
    2064      4803010 :     }
    2065              : }
    2066              : 
    2067              : /// Number of times we will compute partition within a checkpoint distance.
    2068              : const REPARTITION_FREQ_IN_CHECKPOINT_DISTANCE: u64 = 10;
    2069              : 
    2070              : // Private functions
    2071              : impl Timeline {
    2072           12 :     pub(crate) fn get_lsn_lease_length(&self) -> Duration {
    2073           12 :         let tenant_conf = self.tenant_conf.load();
    2074           12 :         tenant_conf
    2075           12 :             .tenant_conf
    2076           12 :             .lsn_lease_length
    2077           12 :             .unwrap_or(self.conf.default_tenant_conf.lsn_lease_length)
    2078           12 :     }
    2079              : 
    2080            0 :     pub(crate) fn get_lsn_lease_length_for_ts(&self) -> Duration {
    2081            0 :         let tenant_conf = self.tenant_conf.load();
    2082            0 :         tenant_conf
    2083            0 :             .tenant_conf
    2084            0 :             .lsn_lease_length_for_ts
    2085            0 :             .unwrap_or(self.conf.default_tenant_conf.lsn_lease_length_for_ts)
    2086            0 :     }
    2087              : 
    2088            0 :     pub(crate) fn get_lazy_slru_download(&self) -> bool {
    2089            0 :         let tenant_conf = self.tenant_conf.load();
    2090            0 :         tenant_conf
    2091            0 :             .tenant_conf
    2092            0 :             .lazy_slru_download
    2093            0 :             .unwrap_or(self.conf.default_tenant_conf.lazy_slru_download)
    2094            0 :     }
    2095              : 
    2096      4804616 :     fn get_checkpoint_distance(&self) -> u64 {
    2097      4804616 :         let tenant_conf = self.tenant_conf.load();
    2098      4804616 :         tenant_conf
    2099      4804616 :             .tenant_conf
    2100      4804616 :             .checkpoint_distance
    2101      4804616 :             .unwrap_or(self.conf.default_tenant_conf.checkpoint_distance)
    2102      4804616 :     }
    2103              : 
    2104      4802930 :     fn get_checkpoint_timeout(&self) -> Duration {
    2105      4802930 :         let tenant_conf = self.tenant_conf.load();
    2106      4802930 :         tenant_conf
    2107      4802930 :             .tenant_conf
    2108      4802930 :             .checkpoint_timeout
    2109      4802930 :             .unwrap_or(self.conf.default_tenant_conf.checkpoint_timeout)
    2110      4802930 :     }
    2111              : 
    2112          618 :     fn get_compaction_target_size(&self) -> u64 {
    2113          618 :         let tenant_conf = self.tenant_conf.load();
    2114          618 :         tenant_conf
    2115          618 :             .tenant_conf
    2116          618 :             .compaction_target_size
    2117          618 :             .unwrap_or(self.conf.default_tenant_conf.compaction_target_size)
    2118          618 :     }
    2119              : 
    2120         1536 :     fn get_compaction_threshold(&self) -> usize {
    2121         1536 :         let tenant_conf = self.tenant_conf.load();
    2122         1536 :         tenant_conf
    2123         1536 :             .tenant_conf
    2124         1536 :             .compaction_threshold
    2125         1536 :             .unwrap_or(self.conf.default_tenant_conf.compaction_threshold)
    2126         1536 :     }
    2127              : 
    2128           14 :     fn get_image_creation_threshold(&self) -> usize {
    2129           14 :         let tenant_conf = self.tenant_conf.load();
    2130           14 :         tenant_conf
    2131           14 :             .tenant_conf
    2132           14 :             .image_creation_threshold
    2133           14 :             .unwrap_or(self.conf.default_tenant_conf.image_creation_threshold)
    2134           14 :     }
    2135              : 
    2136          364 :     fn get_compaction_algorithm_settings(&self) -> CompactionAlgorithmSettings {
    2137          364 :         let tenant_conf = &self.tenant_conf.load();
    2138          364 :         tenant_conf
    2139          364 :             .tenant_conf
    2140          364 :             .compaction_algorithm
    2141          364 :             .as_ref()
    2142          364 :             .unwrap_or(&self.conf.default_tenant_conf.compaction_algorithm)
    2143          364 :             .clone()
    2144          364 :     }
    2145              : 
    2146            0 :     fn get_eviction_policy(&self) -> EvictionPolicy {
    2147            0 :         let tenant_conf = self.tenant_conf.load();
    2148            0 :         tenant_conf
    2149            0 :             .tenant_conf
    2150            0 :             .eviction_policy
    2151            0 :             .unwrap_or(self.conf.default_tenant_conf.eviction_policy)
    2152            0 :     }
    2153              : 
    2154          418 :     fn get_evictions_low_residence_duration_metric_threshold(
    2155          418 :         tenant_conf: &TenantConfOpt,
    2156          418 :         default_tenant_conf: &TenantConf,
    2157          418 :     ) -> Duration {
    2158          418 :         tenant_conf
    2159          418 :             .evictions_low_residence_duration_metric_threshold
    2160          418 :             .unwrap_or(default_tenant_conf.evictions_low_residence_duration_metric_threshold)
    2161          418 :     }
    2162              : 
    2163          716 :     fn get_image_layer_creation_check_threshold(&self) -> u8 {
    2164          716 :         let tenant_conf = self.tenant_conf.load();
    2165          716 :         tenant_conf
    2166          716 :             .tenant_conf
    2167          716 :             .image_layer_creation_check_threshold
    2168          716 :             .unwrap_or(
    2169          716 :                 self.conf
    2170          716 :                     .default_tenant_conf
    2171          716 :                     .image_layer_creation_check_threshold,
    2172          716 :             )
    2173          716 :     }
    2174              : 
    2175            0 :     pub(super) fn tenant_conf_updated(&self, new_conf: &TenantConfOpt) {
    2176            0 :         // NB: Most tenant conf options are read by background loops, so,
    2177            0 :         // changes will automatically be picked up.
    2178            0 : 
    2179            0 :         // The threshold is embedded in the metric. So, we need to update it.
    2180            0 :         {
    2181            0 :             let new_threshold = Self::get_evictions_low_residence_duration_metric_threshold(
    2182            0 :                 new_conf,
    2183            0 :                 &self.conf.default_tenant_conf,
    2184            0 :             );
    2185            0 : 
    2186            0 :             let tenant_id_str = self.tenant_shard_id.tenant_id.to_string();
    2187            0 :             let shard_id_str = format!("{}", self.tenant_shard_id.shard_slug());
    2188            0 : 
    2189            0 :             let timeline_id_str = self.timeline_id.to_string();
    2190            0 :             self.metrics
    2191            0 :                 .evictions_with_low_residence_duration
    2192            0 :                 .write()
    2193            0 :                 .unwrap()
    2194            0 :                 .change_threshold(
    2195            0 :                     &tenant_id_str,
    2196            0 :                     &shard_id_str,
    2197            0 :                     &timeline_id_str,
    2198            0 :                     new_threshold,
    2199            0 :                 );
    2200            0 :         }
    2201            0 :     }
    2202              : 
    2203              :     /// Open a Timeline handle.
    2204              :     ///
    2205              :     /// Loads the metadata for the timeline into memory, but not the layer map.
    2206              :     #[allow(clippy::too_many_arguments)]
    2207          418 :     pub(super) fn new(
    2208          418 :         conf: &'static PageServerConf,
    2209          418 :         tenant_conf: Arc<ArcSwap<AttachedTenantConf>>,
    2210          418 :         metadata: &TimelineMetadata,
    2211          418 :         ancestor: Option<Arc<Timeline>>,
    2212          418 :         timeline_id: TimelineId,
    2213          418 :         tenant_shard_id: TenantShardId,
    2214          418 :         generation: Generation,
    2215          418 :         shard_identity: ShardIdentity,
    2216          418 :         walredo_mgr: Option<Arc<super::WalRedoManager>>,
    2217          418 :         resources: TimelineResources,
    2218          418 :         pg_version: u32,
    2219          418 :         state: TimelineState,
    2220          418 :         attach_wal_lag_cooldown: Arc<OnceLock<WalLagCooldown>>,
    2221          418 :         create_idempotency: crate::tenant::CreateTimelineIdempotency,
    2222          418 :         cancel: CancellationToken,
    2223          418 :     ) -> Arc<Self> {
    2224          418 :         let disk_consistent_lsn = metadata.disk_consistent_lsn();
    2225          418 :         let (state, _) = watch::channel(state);
    2226          418 : 
    2227          418 :         let (layer_flush_start_tx, _) = tokio::sync::watch::channel((0, disk_consistent_lsn));
    2228          418 :         let (layer_flush_done_tx, _) = tokio::sync::watch::channel((0, Ok(())));
    2229          418 : 
    2230          418 :         let evictions_low_residence_duration_metric_threshold = {
    2231          418 :             let loaded_tenant_conf = tenant_conf.load();
    2232          418 :             Self::get_evictions_low_residence_duration_metric_threshold(
    2233          418 :                 &loaded_tenant_conf.tenant_conf,
    2234          418 :                 &conf.default_tenant_conf,
    2235          418 :             )
    2236              :         };
    2237              : 
    2238          418 :         if let Some(ancestor) = &ancestor {
    2239          230 :             let mut ancestor_gc_info = ancestor.gc_info.write().unwrap();
    2240          230 :             // If we construct an explicit timeline object, it's obviously not offloaded
    2241          230 :             let is_offloaded = MaybeOffloaded::No;
    2242          230 :             ancestor_gc_info.insert_child(timeline_id, metadata.ancestor_lsn(), is_offloaded);
    2243          230 :         }
    2244              : 
    2245          418 :         Arc::new_cyclic(|myself| {
    2246          418 :             let metrics = TimelineMetrics::new(
    2247          418 :                 &tenant_shard_id,
    2248          418 :                 &timeline_id,
    2249          418 :                 crate::metrics::EvictionsWithLowResidenceDurationBuilder::new(
    2250          418 :                     "mtime",
    2251          418 :                     evictions_low_residence_duration_metric_threshold,
    2252          418 :                 ),
    2253          418 :             );
    2254          418 :             let aux_file_metrics = metrics.aux_file_size_gauge.clone();
    2255              : 
    2256          418 :             let mut result = Timeline {
    2257          418 :                 conf,
    2258          418 :                 tenant_conf,
    2259          418 :                 myself: myself.clone(),
    2260          418 :                 timeline_id,
    2261          418 :                 tenant_shard_id,
    2262          418 :                 generation,
    2263          418 :                 shard_identity,
    2264          418 :                 pg_version,
    2265          418 :                 layers: Default::default(),
    2266          418 : 
    2267          418 :                 walredo_mgr,
    2268          418 :                 walreceiver: Mutex::new(None),
    2269          418 : 
    2270          418 :                 remote_client: Arc::new(resources.remote_client),
    2271          418 : 
    2272          418 :                 // initialize in-memory 'last_record_lsn' from 'disk_consistent_lsn'.
    2273          418 :                 last_record_lsn: SeqWait::new(RecordLsn {
    2274          418 :                     last: disk_consistent_lsn,
    2275          418 :                     prev: metadata.prev_record_lsn().unwrap_or(Lsn(0)),
    2276          418 :                 }),
    2277          418 :                 disk_consistent_lsn: AtomicLsn::new(disk_consistent_lsn.0),
    2278          418 : 
    2279          418 :                 last_freeze_at: AtomicLsn::new(disk_consistent_lsn.0),
    2280          418 :                 last_freeze_ts: RwLock::new(Instant::now()),
    2281          418 : 
    2282          418 :                 loaded_at: (disk_consistent_lsn, SystemTime::now()),
    2283          418 : 
    2284          418 :                 ancestor_timeline: ancestor,
    2285          418 :                 ancestor_lsn: metadata.ancestor_lsn(),
    2286          418 : 
    2287          418 :                 metrics,
    2288          418 : 
    2289          418 :                 query_metrics: crate::metrics::SmgrQueryTimePerTimeline::new(
    2290          418 :                     &tenant_shard_id,
    2291          418 :                     &timeline_id,
    2292          418 :                 ),
    2293          418 : 
    2294         2926 :                 directory_metrics: array::from_fn(|_| AtomicU64::new(0)),
    2295          418 : 
    2296          418 :                 flush_loop_state: Mutex::new(FlushLoopState::NotStarted),
    2297          418 : 
    2298          418 :                 layer_flush_start_tx,
    2299          418 :                 layer_flush_done_tx,
    2300          418 : 
    2301          418 :                 write_lock: tokio::sync::Mutex::new(None),
    2302          418 : 
    2303          418 :                 gc_info: std::sync::RwLock::new(GcInfo::default()),
    2304          418 : 
    2305          418 :                 latest_gc_cutoff_lsn: Rcu::new(metadata.latest_gc_cutoff_lsn()),
    2306          418 :                 initdb_lsn: metadata.initdb_lsn(),
    2307          418 : 
    2308          418 :                 current_logical_size: if disk_consistent_lsn.is_valid() {
    2309              :                     // we're creating timeline data with some layer files existing locally,
    2310              :                     // need to recalculate timeline's logical size based on data in the layers.
    2311          234 :                     LogicalSize::deferred_initial(disk_consistent_lsn)
    2312              :                 } else {
    2313              :                     // we're creating timeline data without any layers existing locally,
    2314              :                     // initial logical size is 0.
    2315          184 :                     LogicalSize::empty_initial()
    2316              :                 },
    2317          418 :                 partitioning: tokio::sync::Mutex::new((
    2318          418 :                     (KeyPartitioning::new(), KeyPartitioning::new().into_sparse()),
    2319          418 :                     Lsn(0),
    2320          418 :                 )),
    2321          418 :                 repartition_threshold: 0,
    2322          418 :                 last_image_layer_creation_check_at: AtomicLsn::new(0),
    2323          418 :                 last_image_layer_creation_check_instant: Mutex::new(None),
    2324          418 : 
    2325          418 :                 last_received_wal: Mutex::new(None),
    2326          418 :                 rel_size_cache: RwLock::new(RelSizeCache {
    2327          418 :                     complete_as_of: disk_consistent_lsn,
    2328          418 :                     map: HashMap::new(),
    2329          418 :                 }),
    2330          418 : 
    2331          418 :                 download_all_remote_layers_task_info: RwLock::new(None),
    2332          418 : 
    2333          418 :                 state,
    2334          418 : 
    2335          418 :                 eviction_task_timeline_state: tokio::sync::Mutex::new(
    2336          418 :                     EvictionTaskTimelineState::default(),
    2337          418 :                 ),
    2338          418 :                 delete_progress: TimelineDeleteProgress::default(),
    2339          418 : 
    2340          418 :                 cancel,
    2341          418 :                 gate: Gate::default(),
    2342          418 : 
    2343          418 :                 compaction_lock: tokio::sync::Mutex::default(),
    2344          418 :                 gc_lock: tokio::sync::Mutex::default(),
    2345          418 : 
    2346          418 :                 standby_horizon: AtomicLsn::new(0),
    2347          418 : 
    2348          418 :                 timeline_get_throttle: resources.timeline_get_throttle,
    2349          418 : 
    2350          418 :                 aux_file_size_estimator: AuxFileSizeEstimator::new(aux_file_metrics),
    2351          418 : 
    2352          418 :                 #[cfg(test)]
    2353          418 :                 extra_test_dense_keyspace: ArcSwap::new(Arc::new(KeySpace::default())),
    2354          418 : 
    2355          418 :                 l0_flush_global_state: resources.l0_flush_global_state,
    2356          418 : 
    2357          418 :                 handles: Default::default(),
    2358          418 : 
    2359          418 :                 attach_wal_lag_cooldown,
    2360          418 : 
    2361          418 :                 create_idempotency,
    2362          418 :             };
    2363          418 : 
    2364          418 :             result.repartition_threshold =
    2365          418 :                 result.get_checkpoint_distance() / REPARTITION_FREQ_IN_CHECKPOINT_DISTANCE;
    2366          418 : 
    2367          418 :             result
    2368          418 :                 .metrics
    2369          418 :                 .last_record_gauge
    2370          418 :                 .set(disk_consistent_lsn.0 as i64);
    2371          418 :             result
    2372          418 :         })
    2373          418 :     }
    2374              : 
    2375          588 :     pub(super) fn maybe_spawn_flush_loop(self: &Arc<Self>) {
    2376          588 :         let Ok(guard) = self.gate.enter() else {
    2377            0 :             info!("cannot start flush loop when the timeline gate has already been closed");
    2378            0 :             return;
    2379              :         };
    2380          588 :         let mut flush_loop_state = self.flush_loop_state.lock().unwrap();
    2381          588 :         match *flush_loop_state {
    2382          412 :             FlushLoopState::NotStarted => (),
    2383              :             FlushLoopState::Running { .. } => {
    2384          176 :                 info!(
    2385            0 :                     "skipping attempt to start flush_loop twice {}/{}",
    2386            0 :                     self.tenant_shard_id, self.timeline_id
    2387              :                 );
    2388          176 :                 return;
    2389              :             }
    2390              :             FlushLoopState::Exited => {
    2391            0 :                 warn!(
    2392            0 :                     "ignoring attempt to restart exited flush_loop {}/{}",
    2393            0 :                     self.tenant_shard_id, self.timeline_id
    2394              :                 );
    2395            0 :                 return;
    2396              :             }
    2397              :         }
    2398              : 
    2399          412 :         let layer_flush_start_rx = self.layer_flush_start_tx.subscribe();
    2400          412 :         let self_clone = Arc::clone(self);
    2401          412 : 
    2402          412 :         debug!("spawning flush loop");
    2403          412 :         *flush_loop_state = FlushLoopState::Running {
    2404          412 :             #[cfg(test)]
    2405          412 :             expect_initdb_optimization: false,
    2406          412 :             #[cfg(test)]
    2407          412 :             initdb_optimization_count: 0,
    2408          412 :         };
    2409          412 :         task_mgr::spawn(
    2410          412 :             task_mgr::BACKGROUND_RUNTIME.handle(),
    2411          412 :             task_mgr::TaskKind::LayerFlushTask,
    2412          412 :             self.tenant_shard_id,
    2413          412 :             Some(self.timeline_id),
    2414          412 :             "layer flush task",
    2415          412 :             async move {
    2416          412 :                 let _guard = guard;
    2417          412 :                 let background_ctx = RequestContext::todo_child(TaskKind::LayerFlushTask, DownloadBehavior::Error);
    2418        18028 :                 self_clone.flush_loop(layer_flush_start_rx, &background_ctx).await;
    2419           10 :                 let mut flush_loop_state = self_clone.flush_loop_state.lock().unwrap();
    2420           10 :                 assert!(matches!(*flush_loop_state, FlushLoopState::Running{..}));
    2421           10 :                 *flush_loop_state  = FlushLoopState::Exited;
    2422           10 :                 Ok(())
    2423           10 :             }
    2424          412 :             .instrument(info_span!(parent: None, "layer flush task", tenant_id = %self.tenant_shard_id.tenant_id, shard_id = %self.tenant_shard_id.shard_slug(), timeline_id = %self.timeline_id))
    2425              :         );
    2426          588 :     }
    2427              : 
    2428              :     /// Creates and starts the wal receiver.
    2429              :     ///
    2430              :     /// This function is expected to be called at most once per Timeline's lifecycle
    2431              :     /// when the timeline is activated.
    2432            0 :     fn launch_wal_receiver(
    2433            0 :         self: &Arc<Self>,
    2434            0 :         ctx: &RequestContext,
    2435            0 :         broker_client: BrokerClientChannel,
    2436            0 :     ) {
    2437            0 :         info!(
    2438            0 :             "launching WAL receiver for timeline {} of tenant {}",
    2439            0 :             self.timeline_id, self.tenant_shard_id
    2440              :         );
    2441              : 
    2442            0 :         let tenant_conf = self.tenant_conf.load();
    2443            0 :         let wal_connect_timeout = tenant_conf
    2444            0 :             .tenant_conf
    2445            0 :             .walreceiver_connect_timeout
    2446            0 :             .unwrap_or(self.conf.default_tenant_conf.walreceiver_connect_timeout);
    2447            0 :         let lagging_wal_timeout = tenant_conf
    2448            0 :             .tenant_conf
    2449            0 :             .lagging_wal_timeout
    2450            0 :             .unwrap_or(self.conf.default_tenant_conf.lagging_wal_timeout);
    2451            0 :         let max_lsn_wal_lag = tenant_conf
    2452            0 :             .tenant_conf
    2453            0 :             .max_lsn_wal_lag
    2454            0 :             .unwrap_or(self.conf.default_tenant_conf.max_lsn_wal_lag);
    2455            0 : 
    2456            0 :         let mut guard = self.walreceiver.lock().unwrap();
    2457            0 :         assert!(
    2458            0 :             guard.is_none(),
    2459            0 :             "multiple launches / re-launches of WAL receiver are not supported"
    2460              :         );
    2461            0 :         *guard = Some(WalReceiver::start(
    2462            0 :             Arc::clone(self),
    2463            0 :             WalReceiverConf {
    2464            0 :                 wal_connect_timeout,
    2465            0 :                 lagging_wal_timeout,
    2466            0 :                 max_lsn_wal_lag,
    2467            0 :                 auth_token: crate::config::SAFEKEEPER_AUTH_TOKEN.get().cloned(),
    2468            0 :                 availability_zone: self.conf.availability_zone.clone(),
    2469            0 :                 ingest_batch_size: self.conf.ingest_batch_size,
    2470            0 :             },
    2471            0 :             broker_client,
    2472            0 :             ctx,
    2473            0 :         ));
    2474            0 :     }
    2475              : 
    2476              :     /// Initialize with an empty layer map. Used when creating a new timeline.
    2477          412 :     pub(super) fn init_empty_layer_map(&self, start_lsn: Lsn) {
    2478          412 :         let mut layers = self.layers.try_write().expect(
    2479          412 :             "in the context where we call this function, no other task has access to the object",
    2480          412 :         );
    2481          412 :         layers
    2482          412 :             .open_mut()
    2483          412 :             .expect("in this context the LayerManager must still be open")
    2484          412 :             .initialize_empty(Lsn(start_lsn.0));
    2485          412 :     }
    2486              : 
    2487              :     /// Scan the timeline directory, cleanup, populate the layer map, and schedule uploads for local-only
    2488              :     /// files.
    2489            6 :     pub(super) async fn load_layer_map(
    2490            6 :         &self,
    2491            6 :         disk_consistent_lsn: Lsn,
    2492            6 :         index_part: IndexPart,
    2493            6 :     ) -> anyhow::Result<()> {
    2494              :         use init::{Decision::*, Discovered, DismissedLayer};
    2495              :         use LayerName::*;
    2496              : 
    2497            6 :         let mut guard = self.layers.write().await;
    2498              : 
    2499            6 :         let timer = self.metrics.load_layer_map_histo.start_timer();
    2500            6 : 
    2501            6 :         // Scan timeline directory and create ImageLayerName and DeltaFilename
    2502            6 :         // structs representing all files on disk
    2503            6 :         let timeline_path = self
    2504            6 :             .conf
    2505            6 :             .timeline_path(&self.tenant_shard_id, &self.timeline_id);
    2506            6 :         let conf = self.conf;
    2507            6 :         let span = tracing::Span::current();
    2508            6 : 
    2509            6 :         // Copy to move into the task we're about to spawn
    2510            6 :         let this = self.myself.upgrade().expect("&self method holds the arc");
    2511              : 
    2512            6 :         let (loaded_layers, needs_cleanup, total_physical_size) = tokio::task::spawn_blocking({
    2513            6 :             move || {
    2514            6 :                 let _g = span.entered();
    2515            6 :                 let discovered = init::scan_timeline_dir(&timeline_path)?;
    2516            6 :                 let mut discovered_layers = Vec::with_capacity(discovered.len());
    2517            6 :                 let mut unrecognized_files = Vec::new();
    2518            6 : 
    2519            6 :                 let mut path = timeline_path;
    2520              : 
    2521           22 :                 for discovered in discovered {
    2522           16 :                     let (name, kind) = match discovered {
    2523           16 :                         Discovered::Layer(layer_file_name, local_metadata) => {
    2524           16 :                             discovered_layers.push((layer_file_name, local_metadata));
    2525           16 :                             continue;
    2526              :                         }
    2527            0 :                         Discovered::IgnoredBackup(path) => {
    2528            0 :                             std::fs::remove_file(path)
    2529            0 :                                 .or_else(fs_ext::ignore_not_found)
    2530            0 :                                 .fatal_err("Removing .old file");
    2531            0 :                             continue;
    2532              :                         }
    2533            0 :                         Discovered::Unknown(file_name) => {
    2534            0 :                             // we will later error if there are any
    2535            0 :                             unrecognized_files.push(file_name);
    2536            0 :                             continue;
    2537              :                         }
    2538            0 :                         Discovered::Ephemeral(name) => (name, "old ephemeral file"),
    2539            0 :                         Discovered::Temporary(name) => (name, "temporary timeline file"),
    2540            0 :                         Discovered::TemporaryDownload(name) => (name, "temporary download"),
    2541              :                     };
    2542            0 :                     path.push(Utf8Path::new(&name));
    2543            0 :                     init::cleanup(&path, kind)?;
    2544            0 :                     path.pop();
    2545              :                 }
    2546              : 
    2547            6 :                 if !unrecognized_files.is_empty() {
    2548              :                     // assume that if there are any there are many many.
    2549            0 :                     let n = unrecognized_files.len();
    2550            0 :                     let first = &unrecognized_files[..n.min(10)];
    2551            0 :                     anyhow::bail!(
    2552            0 :                         "unrecognized files in timeline dir (total {n}), first 10: {first:?}"
    2553            0 :                     );
    2554            6 :                 }
    2555            6 : 
    2556            6 :                 let decided = init::reconcile(discovered_layers, &index_part, disk_consistent_lsn);
    2557            6 : 
    2558            6 :                 let mut loaded_layers = Vec::new();
    2559            6 :                 let mut needs_cleanup = Vec::new();
    2560            6 :                 let mut total_physical_size = 0;
    2561              : 
    2562           22 :                 for (name, decision) in decided {
    2563           16 :                     let decision = match decision {
    2564           16 :                         Ok(decision) => decision,
    2565            0 :                         Err(DismissedLayer::Future { local }) => {
    2566            0 :                             if let Some(local) = local {
    2567            0 :                                 init::cleanup_future_layer(
    2568            0 :                                     &local.local_path,
    2569            0 :                                     &name,
    2570            0 :                                     disk_consistent_lsn,
    2571            0 :                                 )?;
    2572            0 :                             }
    2573            0 :                             needs_cleanup.push(name);
    2574            0 :                             continue;
    2575              :                         }
    2576            0 :                         Err(DismissedLayer::LocalOnly(local)) => {
    2577            0 :                             init::cleanup_local_only_file(&name, &local)?;
    2578              :                             // this file never existed remotely, we will have to do rework
    2579            0 :                             continue;
    2580              :                         }
    2581            0 :                         Err(DismissedLayer::BadMetadata(local)) => {
    2582            0 :                             init::cleanup_local_file_for_remote(&local)?;
    2583              :                             // this file never existed remotely, we will have to do rework
    2584            0 :                             continue;
    2585              :                         }
    2586              :                     };
    2587              : 
    2588           16 :                     match &name {
    2589           12 :                         Delta(d) => assert!(d.lsn_range.end <= disk_consistent_lsn + 1),
    2590            4 :                         Image(i) => assert!(i.lsn <= disk_consistent_lsn),
    2591              :                     }
    2592              : 
    2593           16 :                     tracing::debug!(layer=%name, ?decision, "applied");
    2594              : 
    2595           16 :                     let layer = match decision {
    2596           16 :                         Resident { local, remote } => {
    2597           16 :                             total_physical_size += local.file_size;
    2598           16 :                             Layer::for_resident(conf, &this, local.local_path, name, remote)
    2599           16 :                                 .drop_eviction_guard()
    2600              :                         }
    2601            0 :                         Evicted(remote) => Layer::for_evicted(conf, &this, name, remote),
    2602              :                     };
    2603              : 
    2604           16 :                     loaded_layers.push(layer);
    2605              :                 }
    2606            6 :                 Ok((loaded_layers, needs_cleanup, total_physical_size))
    2607            6 :             }
    2608            6 :         })
    2609            5 :         .await
    2610            6 :         .map_err(anyhow::Error::new)
    2611            6 :         .and_then(|x| x)?;
    2612              : 
    2613            6 :         let num_layers = loaded_layers.len();
    2614            6 : 
    2615            6 :         guard
    2616            6 :             .open_mut()
    2617            6 :             .expect("layermanager must be open during init")
    2618            6 :             .initialize_local_layers(loaded_layers, disk_consistent_lsn + 1);
    2619            6 : 
    2620            6 :         self.remote_client
    2621            6 :             .schedule_layer_file_deletion(&needs_cleanup)?;
    2622            6 :         self.remote_client
    2623            6 :             .schedule_index_upload_for_file_changes()?;
    2624              :         // This barrier orders above DELETEs before any later operations.
    2625              :         // This is critical because code executing after the barrier might
    2626              :         // create again objects with the same key that we just scheduled for deletion.
    2627              :         // For example, if we just scheduled deletion of an image layer "from the future",
    2628              :         // later compaction might run again and re-create the same image layer.
    2629              :         // "from the future" here means an image layer whose LSN is > IndexPart::disk_consistent_lsn.
    2630              :         // "same" here means same key range and LSN.
    2631              :         //
    2632              :         // Without a barrier between above DELETEs and the re-creation's PUTs,
    2633              :         // the upload queue may execute the PUT first, then the DELETE.
    2634              :         // In our example, we will end up with an IndexPart referencing a non-existent object.
    2635              :         //
    2636              :         // 1. a future image layer is created and uploaded
    2637              :         // 2. ps restart
    2638              :         // 3. the future layer from (1) is deleted during load layer map
    2639              :         // 4. image layer is re-created and uploaded
    2640              :         // 5. deletion queue would like to delete (1) but actually deletes (4)
    2641              :         // 6. delete by name works as expected, but it now deletes the wrong (later) version
    2642              :         //
    2643              :         // See https://github.com/neondatabase/neon/issues/5878
    2644              :         //
    2645              :         // NB: generation numbers naturally protect against this because they disambiguate
    2646              :         //     (1) and (4)
    2647            6 :         self.remote_client.schedule_barrier()?;
    2648              :         // Tenant::create_timeline will wait for these uploads to happen before returning, or
    2649              :         // on retry.
    2650              : 
    2651              :         // Now that we have the full layer map, we may calculate the visibility of layers within it (a global scan)
    2652            6 :         drop(guard); // drop write lock, update_layer_visibility will take a read lock.
    2653            6 :         self.update_layer_visibility().await?;
    2654              : 
    2655            6 :         info!(
    2656            0 :             "loaded layer map with {} layers at {}, total physical size: {}",
    2657              :             num_layers, disk_consistent_lsn, total_physical_size
    2658              :         );
    2659              : 
    2660            6 :         timer.stop_and_record();
    2661            6 :         Ok(())
    2662            6 :     }
    2663              : 
    2664              :     /// Retrieve current logical size of the timeline.
    2665              :     ///
    2666              :     /// The size could be lagging behind the actual number, in case
    2667              :     /// the initial size calculation has not been run (gets triggered on the first size access).
    2668              :     ///
    2669              :     /// return size and boolean flag that shows if the size is exact
    2670            0 :     pub(crate) fn get_current_logical_size(
    2671            0 :         self: &Arc<Self>,
    2672            0 :         priority: GetLogicalSizePriority,
    2673            0 :         ctx: &RequestContext,
    2674            0 :     ) -> logical_size::CurrentLogicalSize {
    2675            0 :         if !self.tenant_shard_id.is_shard_zero() {
    2676              :             // Logical size is only accurately maintained on shard zero: when called elsewhere, for example
    2677              :             // when HTTP API is serving a GET for timeline zero, return zero
    2678            0 :             return logical_size::CurrentLogicalSize::Approximate(logical_size::Approximate::zero());
    2679            0 :         }
    2680            0 : 
    2681            0 :         let current_size = self.current_logical_size.current_size();
    2682            0 :         debug!("Current size: {current_size:?}");
    2683              : 
    2684            0 :         match (current_size.accuracy(), priority) {
    2685            0 :             (logical_size::Accuracy::Exact, _) => (), // nothing to do
    2686            0 :             (logical_size::Accuracy::Approximate, GetLogicalSizePriority::Background) => {
    2687            0 :                 // background task will eventually deliver an exact value, we're in no rush
    2688            0 :             }
    2689              :             (logical_size::Accuracy::Approximate, GetLogicalSizePriority::User) => {
    2690              :                 // background task is not ready, but user is asking for it now;
    2691              :                 // => make the background task skip the line
    2692              :                 // (The alternative would be to calculate the size here, but,
    2693              :                 //  it can actually take a long time if the user has a lot of rels.
    2694              :                 //  And we'll inevitable need it again; So, let the background task do the work.)
    2695            0 :                 match self
    2696            0 :                     .current_logical_size
    2697            0 :                     .cancel_wait_for_background_loop_concurrency_limit_semaphore
    2698            0 :                     .get()
    2699              :                 {
    2700            0 :                     Some(cancel) => cancel.cancel(),
    2701              :                     None => {
    2702            0 :                         let state = self.current_state();
    2703            0 :                         if matches!(
    2704            0 :                             state,
    2705              :                             TimelineState::Broken { .. } | TimelineState::Stopping
    2706            0 :                         ) {
    2707            0 : 
    2708            0 :                             // Can happen when timeline detail endpoint is used when deletion is ongoing (or its broken).
    2709            0 :                             // Don't make noise.
    2710            0 :                         } else {
    2711            0 :                             warn!("unexpected: cancel_wait_for_background_loop_concurrency_limit_semaphore not set, priority-boosting of logical size calculation will not work");
    2712            0 :                             debug_assert!(false);
    2713              :                         }
    2714              :                     }
    2715              :                 };
    2716              :             }
    2717              :         }
    2718              : 
    2719            0 :         if let CurrentLogicalSize::Approximate(_) = &current_size {
    2720            0 :             if ctx.task_kind() == TaskKind::WalReceiverConnectionHandler {
    2721            0 :                 let first = self
    2722            0 :                     .current_logical_size
    2723            0 :                     .did_return_approximate_to_walreceiver
    2724            0 :                     .compare_exchange(
    2725            0 :                         false,
    2726            0 :                         true,
    2727            0 :                         AtomicOrdering::Relaxed,
    2728            0 :                         AtomicOrdering::Relaxed,
    2729            0 :                     )
    2730            0 :                     .is_ok();
    2731            0 :                 if first {
    2732            0 :                     crate::metrics::initial_logical_size::TIMELINES_WHERE_WALRECEIVER_GOT_APPROXIMATE_SIZE.inc();
    2733            0 :                 }
    2734            0 :             }
    2735            0 :         }
    2736              : 
    2737            0 :         current_size
    2738            0 :     }
    2739              : 
    2740            0 :     fn spawn_initial_logical_size_computation_task(self: &Arc<Self>, ctx: &RequestContext) {
    2741            0 :         let Some(initial_part_end) = self.current_logical_size.initial_part_end else {
    2742              :             // nothing to do for freshly created timelines;
    2743            0 :             assert_eq!(
    2744            0 :                 self.current_logical_size.current_size().accuracy(),
    2745            0 :                 logical_size::Accuracy::Exact,
    2746            0 :             );
    2747            0 :             self.current_logical_size.initialized.add_permits(1);
    2748            0 :             return;
    2749              :         };
    2750              : 
    2751            0 :         let cancel_wait_for_background_loop_concurrency_limit_semaphore = CancellationToken::new();
    2752            0 :         let token = cancel_wait_for_background_loop_concurrency_limit_semaphore.clone();
    2753            0 :         self.current_logical_size
    2754            0 :             .cancel_wait_for_background_loop_concurrency_limit_semaphore.set(token)
    2755            0 :             .expect("initial logical size calculation task must be spawned exactly once per Timeline object");
    2756            0 : 
    2757            0 :         let self_clone = Arc::clone(self);
    2758            0 :         let background_ctx = ctx.detached_child(
    2759            0 :             TaskKind::InitialLogicalSizeCalculation,
    2760            0 :             DownloadBehavior::Download,
    2761            0 :         );
    2762            0 :         task_mgr::spawn(
    2763            0 :             task_mgr::BACKGROUND_RUNTIME.handle(),
    2764            0 :             task_mgr::TaskKind::InitialLogicalSizeCalculation,
    2765            0 :             self.tenant_shard_id,
    2766            0 :             Some(self.timeline_id),
    2767            0 :             "initial size calculation",
    2768              :             // NB: don't log errors here, task_mgr will do that.
    2769            0 :             async move {
    2770            0 :                 let cancel = task_mgr::shutdown_token();
    2771            0 :                 self_clone
    2772            0 :                     .initial_logical_size_calculation_task(
    2773            0 :                         initial_part_end,
    2774            0 :                         cancel_wait_for_background_loop_concurrency_limit_semaphore,
    2775            0 :                         cancel,
    2776            0 :                         background_ctx,
    2777            0 :                     )
    2778            0 :                     .await;
    2779            0 :                 Ok(())
    2780            0 :             }
    2781            0 :             .instrument(info_span!(parent: None, "initial_size_calculation", tenant_id=%self.tenant_shard_id.tenant_id, shard_id=%self.tenant_shard_id.shard_slug(), timeline_id=%self.timeline_id)),
    2782              :         );
    2783            0 :     }
    2784              : 
    2785            0 :     async fn initial_logical_size_calculation_task(
    2786            0 :         self: Arc<Self>,
    2787            0 :         initial_part_end: Lsn,
    2788            0 :         skip_concurrency_limiter: CancellationToken,
    2789            0 :         cancel: CancellationToken,
    2790            0 :         background_ctx: RequestContext,
    2791            0 :     ) {
    2792            0 :         scopeguard::defer! {
    2793            0 :             // Irrespective of the outcome of this operation, we should unblock anyone waiting for it.
    2794            0 :             self.current_logical_size.initialized.add_permits(1);
    2795            0 :         }
    2796            0 : 
    2797            0 :         let try_once = |attempt: usize| {
    2798            0 :             let background_ctx = &background_ctx;
    2799            0 :             let self_ref = &self;
    2800            0 :             let skip_concurrency_limiter = &skip_concurrency_limiter;
    2801            0 :             async move {
    2802            0 :                 let cancel = task_mgr::shutdown_token();
    2803            0 :                 let wait_for_permit = super::tasks::concurrent_background_tasks_rate_limit_permit(
    2804            0 :                     BackgroundLoopKind::InitialLogicalSizeCalculation,
    2805            0 :                     background_ctx,
    2806            0 :                 );
    2807              : 
    2808              :                 use crate::metrics::initial_logical_size::StartCircumstances;
    2809            0 :                 let (_maybe_permit, circumstances) = tokio::select! {
    2810            0 :                     permit = wait_for_permit => {
    2811            0 :                         (Some(permit), StartCircumstances::AfterBackgroundTasksRateLimit)
    2812              :                     }
    2813            0 :                     _ = self_ref.cancel.cancelled() => {
    2814            0 :                         return Err(CalculateLogicalSizeError::Cancelled);
    2815              :                     }
    2816            0 :                     _ = cancel.cancelled() => {
    2817            0 :                         return Err(CalculateLogicalSizeError::Cancelled);
    2818              :                     },
    2819            0 :                     () = skip_concurrency_limiter.cancelled() => {
    2820              :                         // Some action that is part of a end user interaction requested logical size
    2821              :                         // => break out of the rate limit
    2822              :                         // TODO: ideally we'd not run on BackgroundRuntime but the requester's runtime;
    2823              :                         // but then again what happens if they cancel; also, we should just be using
    2824              :                         // one runtime across the entire process, so, let's leave this for now.
    2825            0 :                         (None, StartCircumstances::SkippedConcurrencyLimiter)
    2826              :                     }
    2827              :                 };
    2828              : 
    2829            0 :                 let metrics_guard = if attempt == 1 {
    2830            0 :                     crate::metrics::initial_logical_size::START_CALCULATION.first(circumstances)
    2831              :                 } else {
    2832            0 :                     crate::metrics::initial_logical_size::START_CALCULATION.retry(circumstances)
    2833              :                 };
    2834              : 
    2835            0 :                 let calculated_size = self_ref
    2836            0 :                     .logical_size_calculation_task(
    2837            0 :                         initial_part_end,
    2838            0 :                         LogicalSizeCalculationCause::Initial,
    2839            0 :                         background_ctx,
    2840            0 :                     )
    2841            0 :                     .await?;
    2842              : 
    2843            0 :                 self_ref
    2844            0 :                     .trigger_aux_file_size_computation(initial_part_end, background_ctx)
    2845            0 :                     .await?;
    2846              : 
    2847              :                 // TODO: add aux file size to logical size
    2848              : 
    2849            0 :                 Ok((calculated_size, metrics_guard))
    2850            0 :             }
    2851            0 :         };
    2852              : 
    2853            0 :         let retrying = async {
    2854            0 :             let mut attempt = 0;
    2855              :             loop {
    2856            0 :                 attempt += 1;
    2857            0 : 
    2858            0 :                 match try_once(attempt).await {
    2859            0 :                     Ok(res) => return ControlFlow::Continue(res),
    2860            0 :                     Err(CalculateLogicalSizeError::Cancelled) => return ControlFlow::Break(()),
    2861              :                     Err(
    2862            0 :                         e @ (CalculateLogicalSizeError::Decode(_)
    2863            0 :                         | CalculateLogicalSizeError::PageRead(_)),
    2864            0 :                     ) => {
    2865            0 :                         warn!(attempt, "initial size calculation failed: {e:?}");
    2866              :                         // exponential back-off doesn't make sense at these long intervals;
    2867              :                         // use fixed retry interval with generous jitter instead
    2868            0 :                         let sleep_duration = Duration::from_secs(
    2869            0 :                             u64::try_from(
    2870            0 :                                 // 1hour base
    2871            0 :                                 (60_i64 * 60_i64)
    2872            0 :                                     // 10min jitter
    2873            0 :                                     + rand::thread_rng().gen_range(-10 * 60..10 * 60),
    2874            0 :                             )
    2875            0 :                             .expect("10min < 1hour"),
    2876            0 :                         );
    2877            0 :                         tokio::time::sleep(sleep_duration).await;
    2878              :                     }
    2879              :                 }
    2880              :             }
    2881            0 :         };
    2882              : 
    2883            0 :         let (calculated_size, metrics_guard) = tokio::select! {
    2884            0 :             res = retrying  => {
    2885            0 :                 match res {
    2886            0 :                     ControlFlow::Continue(calculated_size) => calculated_size,
    2887            0 :                     ControlFlow::Break(()) => return,
    2888              :                 }
    2889              :             }
    2890            0 :             _ = cancel.cancelled() => {
    2891            0 :                 return;
    2892              :             }
    2893              :         };
    2894              : 
    2895              :         // we cannot query current_logical_size.current_size() to know the current
    2896              :         // *negative* value, only truncated to u64.
    2897            0 :         let added = self
    2898            0 :             .current_logical_size
    2899            0 :             .size_added_after_initial
    2900            0 :             .load(AtomicOrdering::Relaxed);
    2901            0 : 
    2902            0 :         let sum = calculated_size.saturating_add_signed(added);
    2903            0 : 
    2904            0 :         // set the gauge value before it can be set in `update_current_logical_size`.
    2905            0 :         self.metrics.current_logical_size_gauge.set(sum);
    2906            0 : 
    2907            0 :         self.current_logical_size
    2908            0 :             .initial_logical_size
    2909            0 :             .set((calculated_size, metrics_guard.calculation_result_saved()))
    2910            0 :             .ok()
    2911            0 :             .expect("only this task sets it");
    2912            0 :     }
    2913              : 
    2914            0 :     pub(crate) fn spawn_ondemand_logical_size_calculation(
    2915            0 :         self: &Arc<Self>,
    2916            0 :         lsn: Lsn,
    2917            0 :         cause: LogicalSizeCalculationCause,
    2918            0 :         ctx: RequestContext,
    2919            0 :     ) -> oneshot::Receiver<Result<u64, CalculateLogicalSizeError>> {
    2920            0 :         let (sender, receiver) = oneshot::channel();
    2921            0 :         let self_clone = Arc::clone(self);
    2922            0 :         // XXX if our caller loses interest, i.e., ctx is cancelled,
    2923            0 :         // we should stop the size calculation work and return an error.
    2924            0 :         // That would require restructuring this function's API to
    2925            0 :         // return the result directly, instead of a Receiver for the result.
    2926            0 :         let ctx = ctx.detached_child(
    2927            0 :             TaskKind::OndemandLogicalSizeCalculation,
    2928            0 :             DownloadBehavior::Download,
    2929            0 :         );
    2930            0 :         task_mgr::spawn(
    2931            0 :             task_mgr::BACKGROUND_RUNTIME.handle(),
    2932            0 :             task_mgr::TaskKind::OndemandLogicalSizeCalculation,
    2933            0 :             self.tenant_shard_id,
    2934            0 :             Some(self.timeline_id),
    2935            0 :             "ondemand logical size calculation",
    2936            0 :             async move {
    2937            0 :                 let res = self_clone
    2938            0 :                     .logical_size_calculation_task(lsn, cause, &ctx)
    2939            0 :                     .await;
    2940            0 :                 let _ = sender.send(res).ok();
    2941            0 :                 Ok(()) // Receiver is responsible for handling errors
    2942            0 :             }
    2943            0 :             .in_current_span(),
    2944            0 :         );
    2945            0 :         receiver
    2946            0 :     }
    2947              : 
    2948              :     /// # Cancel-Safety
    2949              :     ///
    2950              :     /// This method is cancellation-safe.
    2951            0 :     #[instrument(skip_all)]
    2952              :     async fn logical_size_calculation_task(
    2953              :         self: &Arc<Self>,
    2954              :         lsn: Lsn,
    2955              :         cause: LogicalSizeCalculationCause,
    2956              :         ctx: &RequestContext,
    2957              :     ) -> Result<u64, CalculateLogicalSizeError> {
    2958              :         crate::span::debug_assert_current_span_has_tenant_and_timeline_id();
    2959              :         // We should never be calculating logical sizes on shard !=0, because these shards do not have
    2960              :         // accurate relation sizes, and they do not emit consumption metrics.
    2961              :         debug_assert!(self.tenant_shard_id.is_shard_zero());
    2962              : 
    2963              :         let guard = self
    2964              :             .gate
    2965              :             .enter()
    2966            0 :             .map_err(|_| CalculateLogicalSizeError::Cancelled)?;
    2967              : 
    2968              :         let self_calculation = Arc::clone(self);
    2969              : 
    2970            0 :         let mut calculation = pin!(async {
    2971            0 :             let ctx = ctx.attached_child();
    2972            0 :             self_calculation
    2973            0 :                 .calculate_logical_size(lsn, cause, &guard, &ctx)
    2974            0 :                 .await
    2975            0 :         });
    2976              : 
    2977              :         tokio::select! {
    2978              :             res = &mut calculation => { res }
    2979              :             _ = self.cancel.cancelled() => {
    2980              :                 debug!("cancelling logical size calculation for timeline shutdown");
    2981              :                 calculation.await
    2982              :             }
    2983              :         }
    2984              :     }
    2985              : 
    2986              :     /// Calculate the logical size of the database at the latest LSN.
    2987              :     ///
    2988              :     /// NOTE: counted incrementally, includes ancestors. This can be a slow operation,
    2989              :     /// especially if we need to download remote layers.
    2990              :     ///
    2991              :     /// # Cancel-Safety
    2992              :     ///
    2993              :     /// This method is cancellation-safe.
    2994            0 :     async fn calculate_logical_size(
    2995            0 :         &self,
    2996            0 :         up_to_lsn: Lsn,
    2997            0 :         cause: LogicalSizeCalculationCause,
    2998            0 :         _guard: &GateGuard,
    2999            0 :         ctx: &RequestContext,
    3000            0 :     ) -> Result<u64, CalculateLogicalSizeError> {
    3001            0 :         info!(
    3002            0 :             "Calculating logical size for timeline {} at {}",
    3003              :             self.timeline_id, up_to_lsn
    3004              :         );
    3005              : 
    3006            0 :         pausable_failpoint!("timeline-calculate-logical-size-pause");
    3007              : 
    3008              :         // See if we've already done the work for initial size calculation.
    3009              :         // This is a short-cut for timelines that are mostly unused.
    3010            0 :         if let Some(size) = self.current_logical_size.initialized_size(up_to_lsn) {
    3011            0 :             return Ok(size);
    3012            0 :         }
    3013            0 :         let storage_time_metrics = match cause {
    3014              :             LogicalSizeCalculationCause::Initial
    3015              :             | LogicalSizeCalculationCause::ConsumptionMetricsSyntheticSize
    3016            0 :             | LogicalSizeCalculationCause::TenantSizeHandler => &self.metrics.logical_size_histo,
    3017              :             LogicalSizeCalculationCause::EvictionTaskImitation => {
    3018            0 :                 &self.metrics.imitate_logical_size_histo
    3019              :             }
    3020              :         };
    3021            0 :         let timer = storage_time_metrics.start_timer();
    3022            0 :         let logical_size = self
    3023            0 :             .get_current_logical_size_non_incremental(up_to_lsn, ctx)
    3024            0 :             .await?;
    3025            0 :         debug!("calculated logical size: {logical_size}");
    3026            0 :         timer.stop_and_record();
    3027            0 :         Ok(logical_size)
    3028            0 :     }
    3029              : 
    3030              :     /// Update current logical size, adding `delta' to the old value.
    3031       270570 :     fn update_current_logical_size(&self, delta: i64) {
    3032       270570 :         let logical_size = &self.current_logical_size;
    3033       270570 :         logical_size.increment_size(delta);
    3034       270570 : 
    3035       270570 :         // Also set the value in the prometheus gauge. Note that
    3036       270570 :         // there is a race condition here: if this is is called by two
    3037       270570 :         // threads concurrently, the prometheus gauge might be set to
    3038       270570 :         // one value while current_logical_size is set to the
    3039       270570 :         // other.
    3040       270570 :         match logical_size.current_size() {
    3041       270570 :             CurrentLogicalSize::Exact(ref new_current_size) => self
    3042       270570 :                 .metrics
    3043       270570 :                 .current_logical_size_gauge
    3044       270570 :                 .set(new_current_size.into()),
    3045            0 :             CurrentLogicalSize::Approximate(_) => {
    3046            0 :                 // don't update the gauge yet, this allows us not to update the gauge back and
    3047            0 :                 // forth between the initial size calculation task.
    3048            0 :             }
    3049              :         }
    3050       270570 :     }
    3051              : 
    3052         2834 :     pub(crate) fn update_directory_entries_count(&self, kind: DirectoryKind, count: u64) {
    3053         2834 :         self.directory_metrics[kind.offset()].store(count, AtomicOrdering::Relaxed);
    3054         2834 :         let aux_metric =
    3055         2834 :             self.directory_metrics[DirectoryKind::AuxFiles.offset()].load(AtomicOrdering::Relaxed);
    3056         2834 : 
    3057         2834 :         let sum_of_entries = self
    3058         2834 :             .directory_metrics
    3059         2834 :             .iter()
    3060        19838 :             .map(|v| v.load(AtomicOrdering::Relaxed))
    3061         2834 :             .sum();
    3062              :         // Set a high general threshold and a lower threshold for the auxiliary files,
    3063              :         // as we can have large numbers of relations in the db directory.
    3064              :         const SUM_THRESHOLD: u64 = 5000;
    3065              :         const AUX_THRESHOLD: u64 = 1000;
    3066         2834 :         if sum_of_entries >= SUM_THRESHOLD || aux_metric >= AUX_THRESHOLD {
    3067            0 :             self.metrics
    3068            0 :                 .directory_entries_count_gauge
    3069            0 :                 .set(sum_of_entries);
    3070         2834 :         } else if let Some(metric) = Lazy::get(&self.metrics.directory_entries_count_gauge) {
    3071            0 :             metric.set(sum_of_entries);
    3072         2834 :         }
    3073         2834 :     }
    3074              : 
    3075            0 :     async fn find_layer(
    3076            0 :         &self,
    3077            0 :         layer_name: &LayerName,
    3078            0 :     ) -> Result<Option<Layer>, layer_manager::Shutdown> {
    3079            0 :         let guard = self.layers.read().await;
    3080            0 :         let layer = guard
    3081            0 :             .layer_map()?
    3082            0 :             .iter_historic_layers()
    3083            0 :             .find(|l| &l.layer_name() == layer_name)
    3084            0 :             .map(|found| guard.get_from_desc(&found));
    3085            0 :         Ok(layer)
    3086            0 :     }
    3087              : 
    3088              :     /// The timeline heatmap is a hint to secondary locations from the primary location,
    3089              :     /// indicating which layers are currently on-disk on the primary.
    3090              :     ///
    3091              :     /// None is returned if the Timeline is in a state where uploading a heatmap
    3092              :     /// doesn't make sense, such as shutting down or initializing.  The caller
    3093              :     /// should treat this as a cue to simply skip doing any heatmap uploading
    3094              :     /// for this timeline.
    3095            2 :     pub(crate) async fn generate_heatmap(&self) -> Option<HeatMapTimeline> {
    3096            2 :         if !self.is_active() {
    3097            0 :             return None;
    3098            2 :         }
    3099              : 
    3100            2 :         let guard = self.layers.read().await;
    3101              : 
    3102           10 :         let resident = guard.likely_resident_layers().filter_map(|layer| {
    3103           10 :             match layer.visibility() {
    3104              :                 LayerVisibilityHint::Visible => {
    3105              :                     // Layer is visible to one or more read LSNs: elegible for inclusion in layer map
    3106            8 :                     let last_activity_ts = layer.latest_activity();
    3107            8 :                     Some((layer.layer_desc(), layer.metadata(), last_activity_ts))
    3108              :                 }
    3109              :                 LayerVisibilityHint::Covered => {
    3110              :                     // Layer is resident but unlikely to be read: not elegible for inclusion in heatmap.
    3111            2 :                     None
    3112              :                 }
    3113              :             }
    3114           10 :         });
    3115            2 : 
    3116            2 :         let mut layers = resident.collect::<Vec<_>>();
    3117            2 : 
    3118            2 :         // Sort layers in order of which to download first.  For a large set of layers to download, we
    3119            2 :         // want to prioritize those layers which are most likely to still be in the resident many minutes
    3120            2 :         // or hours later:
    3121            2 :         // - Download L0s last, because they churn the fastest: L0s on a fast-writing tenant might
    3122            2 :         //   only exist for a few minutes before being compacted into L1s.
    3123            2 :         // - For L1 & image layers, download most recent LSNs first: the older the LSN, the sooner
    3124            2 :         //   the layer is likely to be covered by an image layer during compaction.
    3125           24 :         layers.sort_by_key(|(desc, _meta, _atime)| {
    3126           24 :             std::cmp::Reverse((
    3127           24 :                 !LayerMap::is_l0(&desc.key_range, desc.is_delta),
    3128           24 :                 desc.lsn_range.end,
    3129           24 :             ))
    3130           24 :         });
    3131            2 : 
    3132            2 :         let layers = layers
    3133            2 :             .into_iter()
    3134            8 :             .map(|(desc, meta, atime)| HeatMapLayer::new(desc.layer_name(), meta, atime))
    3135            2 :             .collect();
    3136            2 : 
    3137            2 :         Some(HeatMapTimeline::new(self.timeline_id, layers))
    3138            2 :     }
    3139              : 
    3140              :     /// Returns true if the given lsn is or was an ancestor branchpoint.
    3141            0 :     pub(crate) fn is_ancestor_lsn(&self, lsn: Lsn) -> bool {
    3142            0 :         // upon timeline detach, we set the ancestor_lsn to Lsn::INVALID and the store the original
    3143            0 :         // branchpoint in the value in IndexPart::lineage
    3144            0 :         self.ancestor_lsn == lsn
    3145            0 :             || (self.ancestor_lsn == Lsn::INVALID
    3146            0 :                 && self.remote_client.is_previous_ancestor_lsn(lsn))
    3147            0 :     }
    3148              : }
    3149              : 
    3150              : impl Timeline {
    3151              :     #[allow(clippy::doc_lazy_continuation)]
    3152              :     /// Get the data needed to reconstruct all keys in the provided keyspace
    3153              :     ///
    3154              :     /// The algorithm is as follows:
    3155              :     /// 1.   While some keys are still not done and there's a timeline to visit:
    3156              :     /// 2.   Visit the timeline (see [`Timeline::get_vectored_reconstruct_data_timeline`]:
    3157              :     /// 2.1: Build the fringe for the current keyspace
    3158              :     /// 2.2  Visit the newest layer from the fringe to collect all values for the range it
    3159              :     ///      intersects
    3160              :     /// 2.3. Pop the timeline from the fringe
    3161              :     /// 2.4. If the fringe is empty, go back to 1
    3162       626618 :     async fn get_vectored_reconstruct_data(
    3163       626618 :         &self,
    3164       626618 :         mut keyspace: KeySpace,
    3165       626618 :         request_lsn: Lsn,
    3166       626618 :         reconstruct_state: &mut ValuesReconstructState,
    3167       626618 :         ctx: &RequestContext,
    3168       626618 :     ) -> Result<(), GetVectoredError> {
    3169       626618 :         let mut timeline_owned: Arc<Timeline>;
    3170       626618 :         let mut timeline = self;
    3171       626618 : 
    3172       626618 :         let mut cont_lsn = Lsn(request_lsn.0 + 1);
    3173              : 
    3174       626616 :         let missing_keyspace = loop {
    3175       852564 :             if self.cancel.is_cancelled() {
    3176            0 :                 return Err(GetVectoredError::Cancelled);
    3177       852564 :             }
    3178              : 
    3179              :             let TimelineVisitOutcome {
    3180       852564 :                 completed_keyspace: completed,
    3181       852564 :                 image_covered_keyspace,
    3182       852564 :             } = Self::get_vectored_reconstruct_data_timeline(
    3183       852564 :                 timeline,
    3184       852564 :                 keyspace.clone(),
    3185       852564 :                 cont_lsn,
    3186       852564 :                 reconstruct_state,
    3187       852564 :                 &self.cancel,
    3188       852564 :                 ctx,
    3189       852564 :             )
    3190       192119 :             .await?;
    3191              : 
    3192       852564 :             keyspace.remove_overlapping_with(&completed);
    3193       852564 : 
    3194       852564 :             // Do not descend into the ancestor timeline for aux files.
    3195       852564 :             // We don't return a blanket [`GetVectoredError::MissingKey`] to avoid
    3196       852564 :             // stalling compaction.
    3197       852564 :             keyspace.remove_overlapping_with(&KeySpace {
    3198       852564 :                 ranges: vec![NON_INHERITED_RANGE, NON_INHERITED_SPARSE_RANGE],
    3199       852564 :             });
    3200       852564 : 
    3201       852564 :             // Keyspace is fully retrieved
    3202       852564 :             if keyspace.is_empty() {
    3203       626602 :                 break None;
    3204       225962 :             }
    3205              : 
    3206       225962 :             let Some(ancestor_timeline) = timeline.ancestor_timeline.as_ref() else {
    3207              :                 // Not fully retrieved but no ancestor timeline.
    3208           14 :                 break Some(keyspace);
    3209              :             };
    3210              : 
    3211              :             // Now we see if there are keys covered by the image layer but does not exist in the
    3212              :             // image layer, which means that the key does not exist.
    3213              : 
    3214              :             // The block below will stop the vectored search if any of the keys encountered an image layer
    3215              :             // which did not contain a snapshot for said key. Since we have already removed all completed
    3216              :             // keys from `keyspace`, we expect there to be no overlap between it and the image covered key
    3217              :             // space. If that's not the case, we had at least one key encounter a gap in the image layer
    3218              :             // and stop the search as a result of that.
    3219       225948 :             let removed = keyspace.remove_overlapping_with(&image_covered_keyspace);
    3220       225948 :             if !removed.is_empty() {
    3221            0 :                 break Some(removed);
    3222       225948 :             }
    3223       225948 :             // If we reached this point, `remove_overlapping_with` should not have made any change to the
    3224       225948 :             // keyspace.
    3225       225948 : 
    3226       225948 :             // Take the min to avoid reconstructing a page with data newer than request Lsn.
    3227       225948 :             cont_lsn = std::cmp::min(Lsn(request_lsn.0 + 1), Lsn(timeline.ancestor_lsn.0 + 1));
    3228       225948 :             timeline_owned = timeline
    3229       225948 :                 .get_ready_ancestor_timeline(ancestor_timeline, ctx)
    3230            2 :                 .await?;
    3231       225946 :             timeline = &*timeline_owned;
    3232              :         };
    3233              : 
    3234       626616 :         if let Some(missing_keyspace) = missing_keyspace {
    3235           14 :             return Err(GetVectoredError::MissingKey(MissingKeyError {
    3236           14 :                 key: missing_keyspace.start().unwrap(), /* better if we can store the full keyspace */
    3237           14 :                 shard: self
    3238           14 :                     .shard_identity
    3239           14 :                     .get_shard_number(&missing_keyspace.start().unwrap()),
    3240           14 :                 cont_lsn,
    3241           14 :                 request_lsn,
    3242           14 :                 ancestor_lsn: Some(timeline.ancestor_lsn),
    3243           14 :                 backtrace: None,
    3244           14 :             }));
    3245       626602 :         }
    3246       626602 : 
    3247       626602 :         Ok(())
    3248       626618 :     }
    3249              : 
    3250              :     /// Collect the reconstruct data for a keyspace from the specified timeline.
    3251              :     ///
    3252              :     /// Maintain a fringe [`LayerFringe`] which tracks all the layers that intersect
    3253              :     /// the current keyspace. The current keyspace of the search at any given timeline
    3254              :     /// is the original keyspace minus all the keys that have been completed minus
    3255              :     /// any keys for which we couldn't find an intersecting layer. It's not tracked explicitly,
    3256              :     /// but if you merge all the keyspaces in the fringe, you get the "current keyspace".
    3257              :     ///
    3258              :     /// This is basically a depth-first search visitor implementation where a vertex
    3259              :     /// is the (layer, lsn range, key space) tuple. The fringe acts as the stack.
    3260              :     ///
    3261              :     /// At each iteration pop the top of the fringe (the layer with the highest Lsn)
    3262              :     /// and get all the required reconstruct data from the layer in one go.
    3263              :     ///
    3264              :     /// Returns the completed keyspace and the keyspaces with image coverage. The caller
    3265              :     /// decides how to deal with these two keyspaces.
    3266       852564 :     async fn get_vectored_reconstruct_data_timeline(
    3267       852564 :         timeline: &Timeline,
    3268       852564 :         keyspace: KeySpace,
    3269       852564 :         mut cont_lsn: Lsn,
    3270       852564 :         reconstruct_state: &mut ValuesReconstructState,
    3271       852564 :         cancel: &CancellationToken,
    3272       852564 :         ctx: &RequestContext,
    3273       852564 :     ) -> Result<TimelineVisitOutcome, GetVectoredError> {
    3274       852564 :         let mut unmapped_keyspace = keyspace.clone();
    3275       852564 :         let mut fringe = LayerFringe::new();
    3276       852564 : 
    3277       852564 :         let mut completed_keyspace = KeySpace::default();
    3278       852564 :         let mut image_covered_keyspace = KeySpaceRandomAccum::new();
    3279              : 
    3280              :         loop {
    3281      1698615 :             if cancel.is_cancelled() {
    3282            0 :                 return Err(GetVectoredError::Cancelled);
    3283      1698615 :             }
    3284      1698615 : 
    3285      1698615 :             let (keys_done_last_step, keys_with_image_coverage) =
    3286      1698615 :                 reconstruct_state.consume_done_keys();
    3287      1698615 :             unmapped_keyspace.remove_overlapping_with(&keys_done_last_step);
    3288      1698615 :             completed_keyspace.merge(&keys_done_last_step);
    3289      1698615 :             if let Some(keys_with_image_coverage) = keys_with_image_coverage {
    3290        21808 :                 unmapped_keyspace
    3291        21808 :                     .remove_overlapping_with(&KeySpace::single(keys_with_image_coverage.clone()));
    3292        21808 :                 image_covered_keyspace.add_range(keys_with_image_coverage);
    3293      1676807 :             }
    3294              : 
    3295              :             // Do not descent any further if the last layer we visited
    3296              :             // completed all keys in the keyspace it inspected. This is not
    3297              :             // required for correctness, but avoids visiting extra layers
    3298              :             // which turns out to be a perf bottleneck in some cases.
    3299      1698615 :             if !unmapped_keyspace.is_empty() {
    3300      1074257 :                 let guard = timeline.layers.read().await;
    3301      1074257 :                 let layers = guard.layer_map()?;
    3302              : 
    3303      1074257 :                 let in_memory_layer = layers.find_in_memory_layer(|l| {
    3304       914296 :                     let start_lsn = l.get_lsn_range().start;
    3305       914296 :                     cont_lsn > start_lsn
    3306      1074257 :                 });
    3307      1074257 : 
    3308      1074257 :                 match in_memory_layer {
    3309       606321 :                     Some(l) => {
    3310       606321 :                         let lsn_range = l.get_lsn_range().start..cont_lsn;
    3311       606321 :                         fringe.update(
    3312       606321 :                             ReadableLayer::InMemoryLayer(l),
    3313       606321 :                             unmapped_keyspace.clone(),
    3314       606321 :                             lsn_range,
    3315       606321 :                         );
    3316       606321 :                     }
    3317              :                     None => {
    3318       467958 :                         for range in unmapped_keyspace.ranges.iter() {
    3319       467958 :                             let results = layers.range_search(range.clone(), cont_lsn);
    3320       467958 : 
    3321       467958 :                             results
    3322       467958 :                                 .found
    3323       467958 :                                 .into_iter()
    3324       467958 :                                 .map(|(SearchResult { layer, lsn_floor }, keyspace_accum)| {
    3325       239744 :                                     (
    3326       239744 :                                         ReadableLayer::PersistentLayer(guard.get_from_desc(&layer)),
    3327       239744 :                                         keyspace_accum.to_keyspace(),
    3328       239744 :                                         lsn_floor..cont_lsn,
    3329       239744 :                                     )
    3330       467958 :                                 })
    3331       467958 :                                 .for_each(|(layer, keyspace, lsn_range)| {
    3332       239744 :                                     fringe.update(layer, keyspace, lsn_range)
    3333       467958 :                                 });
    3334       467958 :                         }
    3335              :                     }
    3336              :                 }
    3337              : 
    3338              :                 // It's safe to drop the layer map lock after planning the next round of reads.
    3339              :                 // The fringe keeps readable handles for the layers which are safe to read even
    3340              :                 // if layers were compacted or flushed.
    3341              :                 //
    3342              :                 // The more interesting consideration is: "Why is the read algorithm still correct
    3343              :                 // if the layer map changes while it is operating?". Doing a vectored read on a
    3344              :                 // timeline boils down to pushing an imaginary lsn boundary downwards for each range
    3345              :                 // covered by the read. The layer map tells us how to move the lsn downwards for a
    3346              :                 // range at *a particular point in time*. It is fine for the answer to be different
    3347              :                 // at two different time points.
    3348      1074257 :                 drop(guard);
    3349       624358 :             }
    3350              : 
    3351      1698615 :             if let Some((layer_to_read, keyspace_to_read, lsn_range)) = fringe.next_layer() {
    3352       846051 :                 let next_cont_lsn = lsn_range.start;
    3353       846051 :                 layer_to_read
    3354       846051 :                     .get_values_reconstruct_data(
    3355       846051 :                         keyspace_to_read.clone(),
    3356       846051 :                         lsn_range,
    3357       846051 :                         reconstruct_state,
    3358       846051 :                         ctx,
    3359       846051 :                     )
    3360       182987 :                     .await?;
    3361              : 
    3362       846051 :                 unmapped_keyspace = keyspace_to_read;
    3363       846051 :                 cont_lsn = next_cont_lsn;
    3364       846051 : 
    3365       846051 :                 reconstruct_state.on_layer_visited(&layer_to_read);
    3366              :             } else {
    3367       852564 :                 break;
    3368       852564 :             }
    3369       852564 :         }
    3370       852564 : 
    3371       852564 :         Ok(TimelineVisitOutcome {
    3372       852564 :             completed_keyspace,
    3373       852564 :             image_covered_keyspace: image_covered_keyspace.consume_keyspace(),
    3374       852564 :         })
    3375       852564 :     }
    3376              : 
    3377       225948 :     async fn get_ready_ancestor_timeline(
    3378       225948 :         &self,
    3379       225948 :         ancestor: &Arc<Timeline>,
    3380       225948 :         ctx: &RequestContext,
    3381       225948 :     ) -> Result<Arc<Timeline>, GetReadyAncestorError> {
    3382       225948 :         // It's possible that the ancestor timeline isn't active yet, or
    3383       225948 :         // is active but hasn't yet caught up to the branch point. Wait
    3384       225948 :         // for it.
    3385       225948 :         //
    3386       225948 :         // This cannot happen while the pageserver is running normally,
    3387       225948 :         // because you cannot create a branch from a point that isn't
    3388       225948 :         // present in the pageserver yet. However, we don't wait for the
    3389       225948 :         // branch point to be uploaded to cloud storage before creating
    3390       225948 :         // a branch. I.e., the branch LSN need not be remote consistent
    3391       225948 :         // for the branching operation to succeed.
    3392       225948 :         //
    3393       225948 :         // Hence, if we try to load a tenant in such a state where
    3394       225948 :         // 1. the existence of the branch was persisted (in IndexPart and/or locally)
    3395       225948 :         // 2. but the ancestor state is behind branch_lsn because it was not yet persisted
    3396       225948 :         // then we will need to wait for the ancestor timeline to
    3397       225948 :         // re-stream WAL up to branch_lsn before we access it.
    3398       225948 :         //
    3399       225948 :         // How can a tenant get in such a state?
    3400       225948 :         // - ungraceful pageserver process exit
    3401       225948 :         // - detach+attach => this is a bug, https://github.com/neondatabase/neon/issues/4219
    3402       225948 :         //
    3403       225948 :         // NB: this could be avoided by requiring
    3404       225948 :         //   branch_lsn >= remote_consistent_lsn
    3405       225948 :         // during branch creation.
    3406       225948 :         match ancestor.wait_to_become_active(ctx).await {
    3407       225946 :             Ok(()) => {}
    3408              :             Err(TimelineState::Stopping) => {
    3409              :                 // If an ancestor is stopping, it means the tenant is stopping: handle this the same as if this timeline was stopping.
    3410            0 :                 return Err(GetReadyAncestorError::Cancelled);
    3411              :             }
    3412            2 :             Err(state) => {
    3413            2 :                 return Err(GetReadyAncestorError::BadState {
    3414            2 :                     timeline_id: ancestor.timeline_id,
    3415            2 :                     state,
    3416            2 :                 });
    3417              :             }
    3418              :         }
    3419       225946 :         ancestor
    3420       225946 :             .wait_lsn(self.ancestor_lsn, WaitLsnWaiter::Timeline(self), ctx)
    3421            0 :             .await
    3422       225946 :             .map_err(|e| match e {
    3423            0 :                 e @ WaitLsnError::Timeout(_) => GetReadyAncestorError::AncestorLsnTimeout(e),
    3424            0 :                 WaitLsnError::Shutdown => GetReadyAncestorError::Cancelled,
    3425            0 :                 WaitLsnError::BadState(state) => GetReadyAncestorError::BadState {
    3426            0 :                     timeline_id: ancestor.timeline_id,
    3427            0 :                     state,
    3428            0 :                 },
    3429       225946 :             })?;
    3430              : 
    3431       225946 :         Ok(ancestor.clone())
    3432       225948 :     }
    3433              : 
    3434       151304 :     pub(crate) fn get_shard_identity(&self) -> &ShardIdentity {
    3435       151304 :         &self.shard_identity
    3436       151304 :     }
    3437              : 
    3438              :     #[inline(always)]
    3439            0 :     pub(crate) fn shard_timeline_id(&self) -> ShardTimelineId {
    3440            0 :         ShardTimelineId {
    3441            0 :             shard_index: ShardIndex {
    3442            0 :                 shard_number: self.shard_identity.number,
    3443            0 :                 shard_count: self.shard_identity.count,
    3444            0 :             },
    3445            0 :             timeline_id: self.timeline_id,
    3446            0 :         }
    3447            0 :     }
    3448              : 
    3449              :     /// Returns a non-frozen open in-memory layer for ingestion.
    3450              :     ///
    3451              :     /// Takes a witness of timeline writer state lock being held, because it makes no sense to call
    3452              :     /// this function without holding the mutex.
    3453         1268 :     async fn get_layer_for_write(
    3454         1268 :         &self,
    3455         1268 :         lsn: Lsn,
    3456         1268 :         _guard: &tokio::sync::MutexGuard<'_, Option<TimelineWriterState>>,
    3457         1268 :         ctx: &RequestContext,
    3458         1268 :     ) -> anyhow::Result<Arc<InMemoryLayer>> {
    3459         1268 :         let mut guard = self.layers.write().await;
    3460         1268 :         let gate_guard = self.gate.enter().context("enter gate for inmem layer")?;
    3461              : 
    3462         1268 :         let last_record_lsn = self.get_last_record_lsn();
    3463         1268 :         ensure!(
    3464         1268 :             lsn > last_record_lsn,
    3465            0 :             "cannot modify relation after advancing last_record_lsn (incoming_lsn={}, last_record_lsn={})",
    3466              :             lsn,
    3467              :             last_record_lsn,
    3468              :         );
    3469              : 
    3470         1268 :         let layer = guard
    3471         1268 :             .open_mut()?
    3472         1268 :             .get_layer_for_write(
    3473         1268 :                 lsn,
    3474         1268 :                 self.conf,
    3475         1268 :                 self.timeline_id,
    3476         1268 :                 self.tenant_shard_id,
    3477         1268 :                 gate_guard,
    3478         1268 :                 ctx,
    3479         1268 :             )
    3480          719 :             .await?;
    3481         1268 :         Ok(layer)
    3482         1268 :     }
    3483              : 
    3484      5279064 :     pub(crate) fn finish_write(&self, new_lsn: Lsn) {
    3485      5279064 :         assert!(new_lsn.is_aligned());
    3486              : 
    3487      5279064 :         self.metrics.last_record_gauge.set(new_lsn.0 as i64);
    3488      5279064 :         self.last_record_lsn.advance(new_lsn);
    3489      5279064 :     }
    3490              : 
    3491              :     /// Freeze any existing open in-memory layer and unconditionally notify the flush loop.
    3492              :     ///
    3493              :     /// Unconditional flush loop notification is given because in sharded cases we will want to
    3494              :     /// leave an Lsn gap. Unsharded tenants do not have Lsn gaps.
    3495         1172 :     async fn freeze_inmem_layer_at(
    3496         1172 :         &self,
    3497         1172 :         at: Lsn,
    3498         1172 :         write_lock: &mut tokio::sync::MutexGuard<'_, Option<TimelineWriterState>>,
    3499         1172 :     ) -> Result<u64, FlushLayerError> {
    3500         1172 :         let frozen = {
    3501         1172 :             let mut guard = self.layers.write().await;
    3502         1172 :             guard
    3503         1172 :                 .open_mut()?
    3504         1172 :                 .try_freeze_in_memory_layer(at, &self.last_freeze_at, write_lock)
    3505            1 :                 .await
    3506              :         };
    3507              : 
    3508         1172 :         if frozen {
    3509         1144 :             let now = Instant::now();
    3510         1144 :             *(self.last_freeze_ts.write().unwrap()) = now;
    3511         1144 :         }
    3512              : 
    3513              :         // Increment the flush cycle counter and wake up the flush task.
    3514              :         // Remember the new value, so that when we listen for the flush
    3515              :         // to finish, we know when the flush that we initiated has
    3516              :         // finished, instead of some other flush that was started earlier.
    3517         1172 :         let mut my_flush_request = 0;
    3518         1172 : 
    3519         1172 :         let flush_loop_state = { *self.flush_loop_state.lock().unwrap() };
    3520         1172 :         if !matches!(flush_loop_state, FlushLoopState::Running { .. }) {
    3521            0 :             return Err(FlushLayerError::NotRunning(flush_loop_state));
    3522         1172 :         }
    3523         1172 : 
    3524         1172 :         self.layer_flush_start_tx.send_modify(|(counter, lsn)| {
    3525         1172 :             my_flush_request = *counter + 1;
    3526         1172 :             *counter = my_flush_request;
    3527         1172 :             *lsn = std::cmp::max(at, *lsn);
    3528         1172 :         });
    3529         1172 : 
    3530         1172 :         assert_ne!(my_flush_request, 0);
    3531              : 
    3532         1172 :         Ok(my_flush_request)
    3533         1172 :     }
    3534              : 
    3535              :     /// Layer flusher task's main loop.
    3536          412 :     async fn flush_loop(
    3537          412 :         self: &Arc<Self>,
    3538          412 :         mut layer_flush_start_rx: tokio::sync::watch::Receiver<(u64, Lsn)>,
    3539          412 :         ctx: &RequestContext,
    3540          412 :     ) {
    3541          412 :         info!("started flush loop");
    3542              :         loop {
    3543         1545 :             tokio::select! {
    3544         1545 :                 _ = self.cancel.cancelled() => {
    3545           10 :                     info!("shutting down layer flush task due to Timeline::cancel");
    3546           10 :                     break;
    3547              :                 },
    3548         1545 :                 _ = layer_flush_start_rx.changed() => {}
    3549         1133 :             }
    3550         1133 :             trace!("waking up");
    3551         1133 :             let (flush_counter, frozen_to_lsn) = *layer_flush_start_rx.borrow();
    3552         1133 : 
    3553         1133 :             // The highest LSN to which we flushed in the loop over frozen layers
    3554         1133 :             let mut flushed_to_lsn = Lsn(0);
    3555              : 
    3556         1133 :             let result = loop {
    3557         2277 :                 if self.cancel.is_cancelled() {
    3558            0 :                     info!("dropping out of flush loop for timeline shutdown");
    3559              :                     // Note: we do not bother transmitting into [`layer_flush_done_tx`], because
    3560              :                     // anyone waiting on that will respect self.cancel as well: they will stop
    3561              :                     // waiting at the same time we as drop out of this loop.
    3562            0 :                     return;
    3563         2277 :                 }
    3564         2277 : 
    3565         2277 :                 let timer = self.metrics.flush_time_histo.start_timer();
    3566              : 
    3567              :                 let num_frozen_layers;
    3568              :                 let frozen_layer_total_size;
    3569         2277 :                 let layer_to_flush = {
    3570         2277 :                     let guard = self.layers.read().await;
    3571         2277 :                     let Ok(lm) = guard.layer_map() else {
    3572            0 :                         info!("dropping out of flush loop for timeline shutdown");
    3573            0 :                         return;
    3574              :                     };
    3575         2277 :                     num_frozen_layers = lm.frozen_layers.len();
    3576         2277 :                     frozen_layer_total_size = lm
    3577         2277 :                         .frozen_layers
    3578         2277 :                         .iter()
    3579         2277 :                         .map(|l| l.estimated_in_mem_size())
    3580         2277 :                         .sum::<u64>();
    3581         2277 :                     lm.frozen_layers.front().cloned()
    3582              :                     // drop 'layers' lock to allow concurrent reads and writes
    3583              :                 };
    3584         2277 :                 let Some(layer_to_flush) = layer_to_flush else {
    3585         1133 :                     break Ok(());
    3586              :                 };
    3587         1144 :                 if num_frozen_layers
    3588         1144 :                     > std::cmp::max(
    3589         1144 :                         self.get_compaction_threshold(),
    3590         1144 :                         DEFAULT_COMPACTION_THRESHOLD,
    3591         1144 :                     )
    3592            0 :                     && frozen_layer_total_size >= /* 128 MB */ 128000000
    3593              :                 {
    3594            0 :                     tracing::warn!(
    3595            0 :                         "too many frozen layers: {num_frozen_layers} layers with estimated in-mem size of {frozen_layer_total_size} bytes",
    3596              :                     );
    3597         1144 :                 }
    3598        17076 :                 match self.flush_frozen_layer(layer_to_flush, ctx).await {
    3599         1144 :                     Ok(this_layer_to_lsn) => {
    3600         1144 :                         flushed_to_lsn = std::cmp::max(flushed_to_lsn, this_layer_to_lsn);
    3601         1144 :                     }
    3602              :                     Err(FlushLayerError::Cancelled) => {
    3603            0 :                         info!("dropping out of flush loop for timeline shutdown");
    3604            0 :                         return;
    3605              :                     }
    3606            0 :                     err @ Err(
    3607            0 :                         FlushLayerError::NotRunning(_)
    3608            0 :                         | FlushLayerError::Other(_)
    3609            0 :                         | FlushLayerError::CreateImageLayersError(_),
    3610            0 :                     ) => {
    3611            0 :                         error!("could not flush frozen layer: {err:?}");
    3612            0 :                         break err.map(|_| ());
    3613              :                     }
    3614              :                 }
    3615         1144 :                 timer.stop_and_record();
    3616              :             };
    3617              : 
    3618              :             // Unsharded tenants should never advance their LSN beyond the end of the
    3619              :             // highest layer they write: such gaps between layer data and the frozen LSN
    3620              :             // are only legal on sharded tenants.
    3621         1133 :             debug_assert!(
    3622         1133 :                 self.shard_identity.count.count() > 1
    3623         1133 :                     || flushed_to_lsn >= frozen_to_lsn
    3624           66 :                     || !flushed_to_lsn.is_valid()
    3625              :             );
    3626              : 
    3627         1133 :             if flushed_to_lsn < frozen_to_lsn && self.shard_identity.count.count() > 1 {
    3628              :                 // If our layer flushes didn't carry disk_consistent_lsn up to the `to_lsn` advertised
    3629              :                 // to us via layer_flush_start_rx, then advance it here.
    3630              :                 //
    3631              :                 // This path is only taken for tenants with multiple shards: single sharded tenants should
    3632              :                 // never encounter a gap in the wal.
    3633            0 :                 let old_disk_consistent_lsn = self.disk_consistent_lsn.load();
    3634            0 :                 tracing::debug!("Advancing disk_consistent_lsn across layer gap {old_disk_consistent_lsn}->{frozen_to_lsn}");
    3635            0 :                 if self.set_disk_consistent_lsn(frozen_to_lsn) {
    3636            0 :                     if let Err(e) = self.schedule_uploads(frozen_to_lsn, vec![]) {
    3637            0 :                         tracing::warn!("Failed to schedule metadata upload after updating disk_consistent_lsn: {e}");
    3638            0 :                     }
    3639            0 :                 }
    3640         1133 :             }
    3641              : 
    3642              :             // Notify any listeners that we're done
    3643         1133 :             let _ = self
    3644         1133 :                 .layer_flush_done_tx
    3645         1133 :                 .send_replace((flush_counter, result));
    3646              :         }
    3647           10 :     }
    3648              : 
    3649              :     /// Waits any flush request created by [`Self::freeze_inmem_layer_at`] to complete.
    3650         1092 :     async fn wait_flush_completion(&self, request: u64) -> Result<(), FlushLayerError> {
    3651         1092 :         let mut rx = self.layer_flush_done_tx.subscribe();
    3652              :         loop {
    3653              :             {
    3654         2182 :                 let (last_result_counter, last_result) = &*rx.borrow();
    3655         2182 :                 if *last_result_counter >= request {
    3656         1092 :                     if let Err(err) = last_result {
    3657              :                         // We already logged the original error in
    3658              :                         // flush_loop. We cannot propagate it to the caller
    3659              :                         // here, because it might not be Cloneable
    3660            0 :                         return Err(err.clone());
    3661              :                     } else {
    3662         1092 :                         return Ok(());
    3663              :                     }
    3664         1090 :                 }
    3665         1090 :             }
    3666         1090 :             trace!("waiting for flush to complete");
    3667         1090 :             tokio::select! {
    3668         1090 :                 rx_e = rx.changed() => {
    3669         1090 :                     rx_e.map_err(|_| FlushLayerError::NotRunning(*self.flush_loop_state.lock().unwrap()))?;
    3670              :                 },
    3671              :                 // Cancellation safety: we are not leaving an I/O in-flight for the flush, we're just ignoring
    3672              :                 // the notification from [`flush_loop`] that it completed.
    3673         1090 :                 _ = self.cancel.cancelled() => {
    3674            0 :                     tracing::info!("Cancelled layer flush due on timeline shutdown");
    3675            0 :                     return Ok(())
    3676              :                 }
    3677              :             };
    3678         1090 :             trace!("done")
    3679              :         }
    3680         1092 :     }
    3681              : 
    3682              :     /// Flush one frozen in-memory layer to disk, as a new delta layer.
    3683              :     ///
    3684              :     /// Return value is the last lsn (inclusive) of the layer that was frozen.
    3685         1144 :     #[instrument(skip_all, fields(layer=%frozen_layer))]
    3686              :     async fn flush_frozen_layer(
    3687              :         self: &Arc<Self>,
    3688              :         frozen_layer: Arc<InMemoryLayer>,
    3689              :         ctx: &RequestContext,
    3690              :     ) -> Result<Lsn, FlushLayerError> {
    3691              :         debug_assert_current_span_has_tenant_and_timeline_id();
    3692              : 
    3693              :         // As a special case, when we have just imported an image into the repository,
    3694              :         // instead of writing out a L0 delta layer, we directly write out image layer
    3695              :         // files instead. This is possible as long as *all* the data imported into the
    3696              :         // repository have the same LSN.
    3697              :         let lsn_range = frozen_layer.get_lsn_range();
    3698              : 
    3699              :         // Whether to directly create image layers for this flush, or flush them as delta layers
    3700              :         let create_image_layer =
    3701              :             lsn_range.start == self.initdb_lsn && lsn_range.end == Lsn(self.initdb_lsn.0 + 1);
    3702              : 
    3703              :         #[cfg(test)]
    3704              :         {
    3705              :             match &mut *self.flush_loop_state.lock().unwrap() {
    3706              :                 FlushLoopState::NotStarted | FlushLoopState::Exited => {
    3707              :                     panic!("flush loop not running")
    3708              :                 }
    3709              :                 FlushLoopState::Running {
    3710              :                     expect_initdb_optimization,
    3711              :                     initdb_optimization_count,
    3712              :                     ..
    3713              :                 } => {
    3714              :                     if create_image_layer {
    3715              :                         *initdb_optimization_count += 1;
    3716              :                     } else {
    3717              :                         assert!(!*expect_initdb_optimization, "expected initdb optimization");
    3718              :                     }
    3719              :                 }
    3720              :             }
    3721              :         }
    3722              : 
    3723              :         let (layers_to_upload, delta_layer_to_add) = if create_image_layer {
    3724              :             // Note: The 'ctx' in use here has DownloadBehavior::Error. We should not
    3725              :             // require downloading anything during initial import.
    3726              :             let ((rel_partition, metadata_partition), _lsn) = self
    3727              :                 .repartition(
    3728              :                     self.initdb_lsn,
    3729              :                     self.get_compaction_target_size(),
    3730              :                     EnumSet::empty(),
    3731              :                     ctx,
    3732              :                 )
    3733              :                 .await
    3734            0 :                 .map_err(|e| FlushLayerError::from_anyhow(self, e.into()))?;
    3735              : 
    3736              :             if self.cancel.is_cancelled() {
    3737              :                 return Err(FlushLayerError::Cancelled);
    3738              :             }
    3739              : 
    3740              :             let mut layers_to_upload = Vec::new();
    3741              :             layers_to_upload.extend(
    3742              :                 self.create_image_layers(
    3743              :                     &rel_partition,
    3744              :                     self.initdb_lsn,
    3745              :                     ImageLayerCreationMode::Initial,
    3746              :                     ctx,
    3747              :                 )
    3748              :                 .await?,
    3749              :             );
    3750              :             if !metadata_partition.parts.is_empty() {
    3751              :                 assert_eq!(
    3752              :                     metadata_partition.parts.len(),
    3753              :                     1,
    3754              :                     "currently sparse keyspace should only contain a single metadata keyspace"
    3755              :                 );
    3756              :                 layers_to_upload.extend(
    3757              :                     self.create_image_layers(
    3758              :                         // Safety: create_image_layers treat sparse keyspaces differently that it does not scan
    3759              :                         // every single key within the keyspace, and therefore, it's safe to force converting it
    3760              :                         // into a dense keyspace before calling this function.
    3761              :                         &metadata_partition.into_dense(),
    3762              :                         self.initdb_lsn,
    3763              :                         ImageLayerCreationMode::Initial,
    3764              :                         ctx,
    3765              :                     )
    3766              :                     .await?,
    3767              :                 );
    3768              :             }
    3769              : 
    3770              :             (layers_to_upload, None)
    3771              :         } else {
    3772              :             // Normal case, write out a L0 delta layer file.
    3773              :             // `create_delta_layer` will not modify the layer map.
    3774              :             // We will remove frozen layer and add delta layer in one atomic operation later.
    3775              :             let Some(layer) = self
    3776              :                 .create_delta_layer(&frozen_layer, None, ctx)
    3777              :                 .await
    3778            0 :                 .map_err(|e| FlushLayerError::from_anyhow(self, e))?
    3779              :             else {
    3780              :                 panic!("delta layer cannot be empty if no filter is applied");
    3781              :             };
    3782              :             (
    3783              :                 // FIXME: even though we have a single image and single delta layer assumption
    3784              :                 // we push them to vec
    3785              :                 vec![layer.clone()],
    3786              :                 Some(layer),
    3787              :             )
    3788              :         };
    3789              : 
    3790              :         pausable_failpoint!("flush-layer-cancel-after-writing-layer-out-pausable");
    3791              : 
    3792              :         if self.cancel.is_cancelled() {
    3793              :             return Err(FlushLayerError::Cancelled);
    3794              :         }
    3795              : 
    3796              :         let disk_consistent_lsn = Lsn(lsn_range.end.0 - 1);
    3797              : 
    3798              :         // The new on-disk layers are now in the layer map. We can remove the
    3799              :         // in-memory layer from the map now. The flushed layer is stored in
    3800              :         // the mapping in `create_delta_layer`.
    3801              :         {
    3802              :             let mut guard = self.layers.write().await;
    3803              : 
    3804              :             guard.open_mut()?.finish_flush_l0_layer(
    3805              :                 delta_layer_to_add.as_ref(),
    3806              :                 &frozen_layer,
    3807              :                 &self.metrics,
    3808              :             );
    3809              : 
    3810              :             if self.set_disk_consistent_lsn(disk_consistent_lsn) {
    3811              :                 // Schedule remote uploads that will reflect our new disk_consistent_lsn
    3812              :                 self.schedule_uploads(disk_consistent_lsn, layers_to_upload)
    3813            0 :                     .map_err(|e| FlushLayerError::from_anyhow(self, e))?;
    3814              :             }
    3815              :             // release lock on 'layers'
    3816              :         };
    3817              : 
    3818              :         // Backpressure mechanism: wait with continuation of the flush loop until we have uploaded all layer files.
    3819              :         // This makes us refuse ingest until the new layers have been persisted to the remote.
    3820              :         self.remote_client
    3821              :             .wait_completion()
    3822              :             .await
    3823            0 :             .map_err(|e| match e {
    3824              :                 WaitCompletionError::UploadQueueShutDownOrStopped
    3825              :                 | WaitCompletionError::NotInitialized(
    3826              :                     NotInitialized::ShuttingDown | NotInitialized::Stopped,
    3827            0 :                 ) => FlushLayerError::Cancelled,
    3828              :                 WaitCompletionError::NotInitialized(NotInitialized::Uninitialized) => {
    3829            0 :                     FlushLayerError::Other(anyhow!(e).into())
    3830              :                 }
    3831            0 :             })?;
    3832              : 
    3833              :         // FIXME: between create_delta_layer and the scheduling of the upload in `update_metadata_file`,
    3834              :         // a compaction can delete the file and then it won't be available for uploads any more.
    3835              :         // We still schedule the upload, resulting in an error, but ideally we'd somehow avoid this
    3836              :         // race situation.
    3837              :         // See https://github.com/neondatabase/neon/issues/4526
    3838              :         pausable_failpoint!("flush-frozen-pausable");
    3839              : 
    3840              :         // This failpoint is used by another test case `test_pageserver_recovery`.
    3841              :         fail_point!("flush-frozen-exit");
    3842              : 
    3843              :         Ok(Lsn(lsn_range.end.0 - 1))
    3844              :     }
    3845              : 
    3846              :     /// Return true if the value changed
    3847              :     ///
    3848              :     /// This function must only be used from the layer flush task.
    3849         1144 :     fn set_disk_consistent_lsn(&self, new_value: Lsn) -> bool {
    3850         1144 :         let old_value = self.disk_consistent_lsn.fetch_max(new_value);
    3851         1144 :         assert!(new_value >= old_value, "disk_consistent_lsn must be growing monotonously at runtime; current {old_value}, offered {new_value}");
    3852         1144 :         new_value != old_value
    3853         1144 :     }
    3854              : 
    3855              :     /// Update metadata file
    3856         1146 :     fn schedule_uploads(
    3857         1146 :         &self,
    3858         1146 :         disk_consistent_lsn: Lsn,
    3859         1146 :         layers_to_upload: impl IntoIterator<Item = ResidentLayer>,
    3860         1146 :     ) -> anyhow::Result<()> {
    3861         1146 :         // We can only save a valid 'prev_record_lsn' value on disk if we
    3862         1146 :         // flushed *all* in-memory changes to disk. We only track
    3863         1146 :         // 'prev_record_lsn' in memory for the latest processed record, so we
    3864         1146 :         // don't remember what the correct value that corresponds to some old
    3865         1146 :         // LSN is. But if we flush everything, then the value corresponding
    3866         1146 :         // current 'last_record_lsn' is correct and we can store it on disk.
    3867         1146 :         let RecordLsn {
    3868         1146 :             last: last_record_lsn,
    3869         1146 :             prev: prev_record_lsn,
    3870         1146 :         } = self.last_record_lsn.load();
    3871         1146 :         let ondisk_prev_record_lsn = if disk_consistent_lsn == last_record_lsn {
    3872         1066 :             Some(prev_record_lsn)
    3873              :         } else {
    3874           80 :             None
    3875              :         };
    3876              : 
    3877         1146 :         let update = crate::tenant::metadata::MetadataUpdate::new(
    3878         1146 :             disk_consistent_lsn,
    3879         1146 :             ondisk_prev_record_lsn,
    3880         1146 :             *self.latest_gc_cutoff_lsn.read(),
    3881         1146 :         );
    3882         1146 : 
    3883         1146 :         fail_point!("checkpoint-before-saving-metadata", |x| bail!(
    3884            0 :             "{}",
    3885            0 :             x.unwrap()
    3886         1146 :         ));
    3887              : 
    3888         2302 :         for layer in layers_to_upload {
    3889         1156 :             self.remote_client.schedule_layer_file_upload(layer)?;
    3890              :         }
    3891         1146 :         self.remote_client
    3892         1146 :             .schedule_index_upload_for_metadata_update(&update)?;
    3893              : 
    3894         1146 :         Ok(())
    3895         1146 :     }
    3896              : 
    3897            0 :     pub(crate) async fn preserve_initdb_archive(&self) -> anyhow::Result<()> {
    3898            0 :         self.remote_client
    3899            0 :             .preserve_initdb_archive(
    3900            0 :                 &self.tenant_shard_id.tenant_id,
    3901            0 :                 &self.timeline_id,
    3902            0 :                 &self.cancel,
    3903            0 :             )
    3904            0 :             .await
    3905            0 :     }
    3906              : 
    3907              :     // Write out the given frozen in-memory layer as a new L0 delta file. This L0 file will not be tracked
    3908              :     // in layer map immediately. The caller is responsible to put it into the layer map.
    3909          968 :     async fn create_delta_layer(
    3910          968 :         self: &Arc<Self>,
    3911          968 :         frozen_layer: &Arc<InMemoryLayer>,
    3912          968 :         key_range: Option<Range<Key>>,
    3913          968 :         ctx: &RequestContext,
    3914          968 :     ) -> anyhow::Result<Option<ResidentLayer>> {
    3915          968 :         let self_clone = Arc::clone(self);
    3916          968 :         let frozen_layer = Arc::clone(frozen_layer);
    3917          968 :         let ctx = ctx.attached_child();
    3918          968 :         let work = async move {
    3919          968 :             let Some((desc, path)) = frozen_layer
    3920          968 :                 .write_to_disk(&ctx, key_range, self_clone.l0_flush_global_state.inner())
    3921        10248 :                 .await?
    3922              :             else {
    3923            0 :                 return Ok(None);
    3924              :             };
    3925          968 :             let new_delta = Layer::finish_creating(self_clone.conf, &self_clone, desc, &path)?;
    3926              : 
    3927              :             // The write_to_disk() above calls writer.finish() which already did the fsync of the inodes.
    3928              :             // We just need to fsync the directory in which these inodes are linked,
    3929              :             // which we know to be the timeline directory.
    3930              :             //
    3931              :             // We use fatal_err() below because the after write_to_disk returns with success,
    3932              :             // the in-memory state of the filesystem already has the layer file in its final place,
    3933              :             // and subsequent pageserver code could think it's durable while it really isn't.
    3934          968 :             let timeline_dir = VirtualFile::open(
    3935          968 :                 &self_clone
    3936          968 :                     .conf
    3937          968 :                     .timeline_path(&self_clone.tenant_shard_id, &self_clone.timeline_id),
    3938          968 :                 &ctx,
    3939          968 :             )
    3940          486 :             .await
    3941          968 :             .fatal_err("VirtualFile::open for timeline dir fsync");
    3942          968 :             timeline_dir
    3943          968 :                 .sync_all()
    3944          484 :                 .await
    3945          968 :                 .fatal_err("VirtualFile::sync_all timeline dir");
    3946          968 :             anyhow::Ok(Some(new_delta))
    3947          968 :         };
    3948              :         // Before tokio-epoll-uring, we ran write_to_disk & the sync_all inside spawn_blocking.
    3949              :         // Preserve that behavior to maintain the same behavior for `virtual_file_io_engine=std-fs`.
    3950              :         use crate::virtual_file::io_engine::IoEngine;
    3951          968 :         match crate::virtual_file::io_engine::get() {
    3952            0 :             IoEngine::NotSet => panic!("io engine not set"),
    3953              :             IoEngine::StdFs => {
    3954          484 :                 let span = tracing::info_span!("blocking");
    3955          484 :                 tokio::task::spawn_blocking({
    3956          484 :                     move || Handle::current().block_on(work.instrument(span))
    3957          484 :                 })
    3958          484 :                 .await
    3959          484 :                 .context("spawn_blocking")
    3960          484 :                 .and_then(|x| x)
    3961              :             }
    3962              :             #[cfg(target_os = "linux")]
    3963        11213 :             IoEngine::TokioEpollUring => work.await,
    3964              :         }
    3965          968 :     }
    3966              : 
    3967          540 :     async fn repartition(
    3968          540 :         &self,
    3969          540 :         lsn: Lsn,
    3970          540 :         partition_size: u64,
    3971          540 :         flags: EnumSet<CompactFlags>,
    3972          540 :         ctx: &RequestContext,
    3973          540 :     ) -> Result<((KeyPartitioning, SparseKeyPartitioning), Lsn), CompactionError> {
    3974          540 :         let Ok(mut partitioning_guard) = self.partitioning.try_lock() else {
    3975              :             // NB: there are two callers, one is the compaction task, of which there is only one per struct Tenant and hence Timeline.
    3976              :             // The other is the initdb optimization in flush_frozen_layer, used by `boostrap_timeline`, which runs before `.activate()`
    3977              :             // and hence before the compaction task starts.
    3978            0 :             return Err(CompactionError::Other(anyhow!(
    3979            0 :                 "repartition() called concurrently, this should not happen"
    3980            0 :             )));
    3981              :         };
    3982          540 :         let ((dense_partition, sparse_partition), partition_lsn) = &*partitioning_guard;
    3983          540 :         if lsn < *partition_lsn {
    3984            0 :             return Err(CompactionError::Other(anyhow!(
    3985            0 :                 "repartition() called with LSN going backwards, this should not happen"
    3986            0 :             )));
    3987          540 :         }
    3988          540 : 
    3989          540 :         let distance = lsn.0 - partition_lsn.0;
    3990          540 :         if *partition_lsn != Lsn(0)
    3991          262 :             && distance <= self.repartition_threshold
    3992          262 :             && !flags.contains(CompactFlags::ForceRepartition)
    3993              :         {
    3994          248 :             debug!(
    3995              :                 distance,
    3996              :                 threshold = self.repartition_threshold,
    3997            0 :                 "no repartitioning needed"
    3998              :             );
    3999          248 :             return Ok((
    4000          248 :                 (dense_partition.clone(), sparse_partition.clone()),
    4001          248 :                 *partition_lsn,
    4002          248 :             ));
    4003          292 :         }
    4004              : 
    4005        15679 :         let (dense_ks, sparse_ks) = self.collect_keyspace(lsn, ctx).await?;
    4006          292 :         let dense_partitioning = dense_ks.partition(&self.shard_identity, partition_size);
    4007          292 :         let sparse_partitioning = SparseKeyPartitioning {
    4008          292 :             parts: vec![sparse_ks],
    4009          292 :         }; // no partitioning for metadata keys for now
    4010          292 :         *partitioning_guard = ((dense_partitioning, sparse_partitioning), lsn);
    4011          292 : 
    4012          292 :         Ok((partitioning_guard.0.clone(), partitioning_guard.1))
    4013          540 :     }
    4014              : 
    4015              :     // Is it time to create a new image layer for the given partition?
    4016           14 :     async fn time_for_new_image_layer(&self, partition: &KeySpace, lsn: Lsn) -> bool {
    4017           14 :         let threshold = self.get_image_creation_threshold();
    4018              : 
    4019           14 :         let guard = self.layers.read().await;
    4020           14 :         let Ok(layers) = guard.layer_map() else {
    4021            0 :             return false;
    4022              :         };
    4023              : 
    4024           14 :         let mut max_deltas = 0;
    4025           28 :         for part_range in &partition.ranges {
    4026           14 :             let image_coverage = layers.image_coverage(part_range, lsn);
    4027           28 :             for (img_range, last_img) in image_coverage {
    4028           14 :                 let img_lsn = if let Some(last_img) = last_img {
    4029            0 :                     last_img.get_lsn_range().end
    4030              :                 } else {
    4031           14 :                     Lsn(0)
    4032              :                 };
    4033              :                 // Let's consider an example:
    4034              :                 //
    4035              :                 // delta layer with LSN range 71-81
    4036              :                 // delta layer with LSN range 81-91
    4037              :                 // delta layer with LSN range 91-101
    4038              :                 // image layer at LSN 100
    4039              :                 //
    4040              :                 // If 'lsn' is still 100, i.e. no new WAL has been processed since the last image layer,
    4041              :                 // there's no need to create a new one. We check this case explicitly, to avoid passing
    4042              :                 // a bogus range to count_deltas below, with start > end. It's even possible that there
    4043              :                 // are some delta layers *later* than current 'lsn', if more WAL was processed and flushed
    4044              :                 // after we read last_record_lsn, which is passed here in the 'lsn' argument.
    4045           14 :                 if img_lsn < lsn {
    4046           14 :                     let num_deltas =
    4047           14 :                         layers.count_deltas(&img_range, &(img_lsn..lsn), Some(threshold));
    4048           14 : 
    4049           14 :                     max_deltas = max_deltas.max(num_deltas);
    4050           14 :                     if num_deltas >= threshold {
    4051            0 :                         debug!(
    4052            0 :                             "key range {}-{}, has {} deltas on this timeline in LSN range {}..{}",
    4053              :                             img_range.start, img_range.end, num_deltas, img_lsn, lsn
    4054              :                         );
    4055            0 :                         return true;
    4056           14 :                     }
    4057            0 :                 }
    4058              :             }
    4059              :         }
    4060              : 
    4061           14 :         debug!(
    4062              :             max_deltas,
    4063            0 :             "none of the partitioned ranges had >= {threshold} deltas"
    4064              :         );
    4065           14 :         false
    4066           14 :     }
    4067              : 
    4068              :     /// Create image layers for Postgres data. Assumes the caller passes a partition that is not too large,
    4069              :     /// so that at most one image layer will be produced from this function.
    4070          202 :     async fn create_image_layer_for_rel_blocks(
    4071          202 :         self: &Arc<Self>,
    4072          202 :         partition: &KeySpace,
    4073          202 :         mut image_layer_writer: ImageLayerWriter,
    4074          202 :         lsn: Lsn,
    4075          202 :         ctx: &RequestContext,
    4076          202 :         img_range: Range<Key>,
    4077          202 :         start: Key,
    4078          202 :     ) -> Result<ImageLayerCreationOutcome, CreateImageLayersError> {
    4079          202 :         let mut wrote_keys = false;
    4080          202 : 
    4081          202 :         let mut key_request_accum = KeySpaceAccum::new();
    4082         1344 :         for range in &partition.ranges {
    4083         1142 :             let mut key = range.start;
    4084         2472 :             while key < range.end {
    4085              :                 // Decide whether to retain this key: usually we do, but sharded tenants may
    4086              :                 // need to drop keys that don't belong to them.  If we retain the key, add it
    4087              :                 // to `key_request_accum` for later issuing a vectored get
    4088         1330 :                 if self.shard_identity.is_key_disposable(&key) {
    4089            0 :                     debug!(
    4090            0 :                         "Dropping key {} during compaction (it belongs on shard {:?})",
    4091            0 :                         key,
    4092            0 :                         self.shard_identity.get_shard_number(&key)
    4093              :                     );
    4094         1330 :                 } else {
    4095         1330 :                     key_request_accum.add_key(key);
    4096         1330 :                 }
    4097              : 
    4098         1330 :                 let last_key_in_range = key.next() == range.end;
    4099         1330 :                 key = key.next();
    4100         1330 : 
    4101         1330 :                 // Maybe flush `key_rest_accum`
    4102         1330 :                 if key_request_accum.raw_size() >= Timeline::MAX_GET_VECTORED_KEYS
    4103         1330 :                     || (last_key_in_range && key_request_accum.raw_size() > 0)
    4104              :                 {
    4105         1142 :                     let results = self
    4106         1142 :                         .get_vectored(key_request_accum.consume_keyspace(), lsn, ctx)
    4107           49 :                         .await?;
    4108              : 
    4109         1142 :                     if self.cancel.is_cancelled() {
    4110            0 :                         return Err(CreateImageLayersError::Cancelled);
    4111         1142 :                     }
    4112              : 
    4113         2472 :                     for (img_key, img) in results {
    4114         1330 :                         let img = match img {
    4115         1330 :                             Ok(img) => img,
    4116            0 :                             Err(err) => {
    4117            0 :                                 // If we fail to reconstruct a VM or FSM page, we can zero the
    4118            0 :                                 // page without losing any actual user data. That seems better
    4119            0 :                                 // than failing repeatedly and getting stuck.
    4120            0 :                                 //
    4121            0 :                                 // We had a bug at one point, where we truncated the FSM and VM
    4122            0 :                                 // in the pageserver, but the Postgres didn't know about that
    4123            0 :                                 // and continued to generate incremental WAL records for pages
    4124            0 :                                 // that didn't exist in the pageserver. Trying to replay those
    4125            0 :                                 // WAL records failed to find the previous image of the page.
    4126            0 :                                 // This special case allows us to recover from that situation.
    4127            0 :                                 // See https://github.com/neondatabase/neon/issues/2601.
    4128            0 :                                 //
    4129            0 :                                 // Unfortunately we cannot do this for the main fork, or for
    4130            0 :                                 // any metadata keys, keys, as that would lead to actual data
    4131            0 :                                 // loss.
    4132            0 :                                 if img_key.is_rel_fsm_block_key() || img_key.is_rel_vm_block_key() {
    4133            0 :                                     warn!("could not reconstruct FSM or VM key {img_key}, filling with zeros: {err:?}");
    4134            0 :                                     ZERO_PAGE.clone()
    4135              :                                 } else {
    4136            0 :                                     return Err(CreateImageLayersError::from(err));
    4137              :                                 }
    4138              :                             }
    4139              :                         };
    4140              : 
    4141              :                         // Write all the keys we just read into our new image layer.
    4142         1449 :                         image_layer_writer.put_image(img_key, img, ctx).await?;
    4143         1330 :                         wrote_keys = true;
    4144              :                     }
    4145          188 :                 }
    4146              :             }
    4147              :         }
    4148              : 
    4149          202 :         if wrote_keys {
    4150              :             // Normal path: we have written some data into the new image layer for this
    4151              :             // partition, so flush it to disk.
    4152          410 :             let (desc, path) = image_layer_writer.finish(ctx).await?;
    4153          202 :             let image_layer = Layer::finish_creating(self.conf, self, desc, &path)?;
    4154          202 :             info!("created image layer for rel {}", image_layer.local_path());
    4155          202 :             Ok(ImageLayerCreationOutcome {
    4156          202 :                 image: Some(image_layer),
    4157          202 :                 next_start_key: img_range.end,
    4158          202 :             })
    4159              :         } else {
    4160              :             // Special case: the image layer may be empty if this is a sharded tenant and the
    4161              :             // partition does not cover any keys owned by this shard.  In this case, to ensure
    4162              :             // we don't leave gaps between image layers, leave `start` where it is, so that the next
    4163              :             // layer we write will cover the key range that we just scanned.
    4164            0 :             tracing::debug!("no data in range {}-{}", img_range.start, img_range.end);
    4165            0 :             Ok(ImageLayerCreationOutcome {
    4166            0 :                 image: None,
    4167            0 :                 next_start_key: start,
    4168            0 :             })
    4169              :         }
    4170          202 :     }
    4171              : 
    4172              :     /// Create an image layer for metadata keys. This function produces one image layer for all metadata
    4173              :     /// keys for now. Because metadata keys cannot exceed basebackup size limit, the image layer for it
    4174              :     /// would not be too large to fit in a single image layer.
    4175              :     #[allow(clippy::too_many_arguments)]
    4176          192 :     async fn create_image_layer_for_metadata_keys(
    4177          192 :         self: &Arc<Self>,
    4178          192 :         partition: &KeySpace,
    4179          192 :         mut image_layer_writer: ImageLayerWriter,
    4180          192 :         lsn: Lsn,
    4181          192 :         ctx: &RequestContext,
    4182          192 :         img_range: Range<Key>,
    4183          192 :         mode: ImageLayerCreationMode,
    4184          192 :         start: Key,
    4185          192 :     ) -> Result<ImageLayerCreationOutcome, CreateImageLayersError> {
    4186          192 :         // Metadata keys image layer creation.
    4187          192 :         let mut reconstruct_state = ValuesReconstructState::default();
    4188          192 :         let begin = Instant::now();
    4189          192 :         let data = self
    4190          192 :             .get_vectored_impl(partition.clone(), lsn, &mut reconstruct_state, ctx)
    4191         1065 :             .await?;
    4192          192 :         let (data, total_kb_retrieved, total_keys_retrieved) = {
    4193          192 :             let mut new_data = BTreeMap::new();
    4194          192 :             let mut total_kb_retrieved = 0;
    4195          192 :             let mut total_keys_retrieved = 0;
    4196        10204 :             for (k, v) in data {
    4197        10012 :                 let v = v?;
    4198        10012 :                 total_kb_retrieved += KEY_SIZE + v.len();
    4199        10012 :                 total_keys_retrieved += 1;
    4200        10012 :                 new_data.insert(k, v);
    4201              :             }
    4202          192 :             (new_data, total_kb_retrieved / 1024, total_keys_retrieved)
    4203          192 :         };
    4204          192 :         let delta_files_accessed = reconstruct_state.get_delta_layers_visited();
    4205          192 :         let elapsed = begin.elapsed();
    4206          192 : 
    4207          192 :         let trigger_generation = delta_files_accessed as usize >= MAX_AUX_FILE_V2_DELTAS;
    4208          192 :         info!(
    4209            0 :             "metadata key compaction: trigger_generation={trigger_generation}, delta_files_accessed={delta_files_accessed}, total_kb_retrieved={total_kb_retrieved}, total_keys_retrieved={total_keys_retrieved}, read_time={}s", elapsed.as_secs_f64()
    4210              :         );
    4211              : 
    4212          192 :         if !trigger_generation && mode == ImageLayerCreationMode::Try {
    4213            2 :             return Ok(ImageLayerCreationOutcome {
    4214            2 :                 image: None,
    4215            2 :                 next_start_key: img_range.end,
    4216            2 :             });
    4217          190 :         }
    4218          190 :         if self.cancel.is_cancelled() {
    4219            0 :             return Err(CreateImageLayersError::Cancelled);
    4220          190 :         }
    4221          190 :         let mut wrote_any_image = false;
    4222        10202 :         for (k, v) in data {
    4223        10012 :             if v.is_empty() {
    4224              :                 // the key has been deleted, it does not need an image
    4225              :                 // in metadata keyspace, an empty image == tombstone
    4226            8 :                 continue;
    4227        10004 :             }
    4228        10004 :             wrote_any_image = true;
    4229        10004 : 
    4230        10004 :             // No need to handle sharding b/c metadata keys are always on the 0-th shard.
    4231        10004 : 
    4232        10004 :             // TODO: split image layers to avoid too large layer files. Too large image files are not handled
    4233        10004 :             // on the normal data path either.
    4234        10162 :             image_layer_writer.put_image(k, v, ctx).await?;
    4235              :         }
    4236              : 
    4237          190 :         if wrote_any_image {
    4238              :             // Normal path: we have written some data into the new image layer for this
    4239              :             // partition, so flush it to disk.
    4240           24 :             let (desc, path) = image_layer_writer.finish(ctx).await?;
    4241           12 :             let image_layer = Layer::finish_creating(self.conf, self, desc, &path)?;
    4242           12 :             info!(
    4243            0 :                 "created image layer for metadata {}",
    4244            0 :                 image_layer.local_path()
    4245              :             );
    4246           12 :             Ok(ImageLayerCreationOutcome {
    4247           12 :                 image: Some(image_layer),
    4248           12 :                 next_start_key: img_range.end,
    4249           12 :             })
    4250              :         } else {
    4251              :             // Special case: the image layer may be empty if this is a sharded tenant and the
    4252              :             // partition does not cover any keys owned by this shard. In this case, to ensure
    4253              :             // we don't leave gaps between image layers, leave `start` where it is, so that the next
    4254              :             // layer we write will cover the key range that we just scanned.
    4255          178 :             tracing::debug!("no data in range {}-{}", img_range.start, img_range.end);
    4256          178 :             Ok(ImageLayerCreationOutcome {
    4257          178 :                 image: None,
    4258          178 :                 next_start_key: start,
    4259          178 :             })
    4260              :         }
    4261          192 :     }
    4262              : 
    4263              :     /// Predicate function which indicates whether we should check if new image layers
    4264              :     /// are required. Since checking if new image layers are required is expensive in
    4265              :     /// terms of CPU, we only do it in the following cases:
    4266              :     /// 1. If the timeline has ingested sufficient WAL to justify the cost
    4267              :     /// 2. If enough time has passed since the last check:
    4268              :     ///     1. For large tenants, we wish to perform the check more often since they
    4269              :     ///        suffer from the lack of image layers
    4270              :     ///     2. For small tenants (that can mostly fit in RAM), we use a much longer interval
    4271          716 :     fn should_check_if_image_layers_required(self: &Arc<Timeline>, lsn: Lsn) -> bool {
    4272              :         const LARGE_TENANT_THRESHOLD: u64 = 2 * 1024 * 1024 * 1024;
    4273              : 
    4274          716 :         let last_checks_at = self.last_image_layer_creation_check_at.load();
    4275          716 :         let distance = lsn
    4276          716 :             .checked_sub(last_checks_at)
    4277          716 :             .expect("Attempt to compact with LSN going backwards");
    4278          716 :         let min_distance =
    4279          716 :             self.get_image_layer_creation_check_threshold() as u64 * self.get_checkpoint_distance();
    4280          716 : 
    4281          716 :         let distance_based_decision = distance.0 >= min_distance;
    4282          716 : 
    4283          716 :         let mut time_based_decision = false;
    4284          716 :         let mut last_check_instant = self.last_image_layer_creation_check_instant.lock().unwrap();
    4285          716 :         if let CurrentLogicalSize::Exact(logical_size) = self.current_logical_size.current_size() {
    4286          614 :             let check_required_after = if Into::<u64>::into(&logical_size) >= LARGE_TENANT_THRESHOLD
    4287              :             {
    4288            0 :                 self.get_checkpoint_timeout()
    4289              :             } else {
    4290          614 :                 Duration::from_secs(3600 * 48)
    4291              :             };
    4292              : 
    4293          614 :             time_based_decision = match *last_check_instant {
    4294          438 :                 Some(last_check) => {
    4295          438 :                     let elapsed = last_check.elapsed();
    4296          438 :                     elapsed >= check_required_after
    4297              :                 }
    4298          176 :                 None => true,
    4299              :             };
    4300          102 :         }
    4301              : 
    4302              :         // Do the expensive delta layer counting only if this timeline has ingested sufficient
    4303              :         // WAL since the last check or a checkpoint timeout interval has elapsed since the last
    4304              :         // check.
    4305          716 :         let decision = distance_based_decision || time_based_decision;
    4306              : 
    4307          716 :         if decision {
    4308          178 :             self.last_image_layer_creation_check_at.store(lsn);
    4309          178 :             *last_check_instant = Some(Instant::now());
    4310          538 :         }
    4311              : 
    4312          716 :         decision
    4313          716 :     }
    4314              : 
    4315          716 :     #[tracing::instrument(skip_all, fields(%lsn, %mode))]
    4316              :     async fn create_image_layers(
    4317              :         self: &Arc<Timeline>,
    4318              :         partitioning: &KeyPartitioning,
    4319              :         lsn: Lsn,
    4320              :         mode: ImageLayerCreationMode,
    4321              :         ctx: &RequestContext,
    4322              :     ) -> Result<Vec<ResidentLayer>, CreateImageLayersError> {
    4323              :         let timer = self.metrics.create_images_time_histo.start_timer();
    4324              :         let mut image_layers = Vec::new();
    4325              : 
    4326              :         // We need to avoid holes between generated image layers.
    4327              :         // Otherwise LayerMap::image_layer_exists will return false if key range of some layer is covered by more than one
    4328              :         // image layer with hole between them. In this case such layer can not be utilized by GC.
    4329              :         //
    4330              :         // How such hole between partitions can appear?
    4331              :         // if we have relation with relid=1 and size 100 and relation with relid=2 with size 200 then result of
    4332              :         // KeySpace::partition may contain partitions <100000000..100000099> and <200000000..200000199>.
    4333              :         // If there is delta layer <100000000..300000000> then it never be garbage collected because
    4334              :         // image layers  <100000000..100000099> and <200000000..200000199> are not completely covering it.
    4335              :         let mut start = Key::MIN;
    4336              : 
    4337              :         let check_for_image_layers = self.should_check_if_image_layers_required(lsn);
    4338              : 
    4339              :         for partition in partitioning.parts.iter() {
    4340              :             if self.cancel.is_cancelled() {
    4341              :                 return Err(CreateImageLayersError::Cancelled);
    4342              :             }
    4343              : 
    4344              :             let img_range = start..partition.ranges.last().unwrap().end;
    4345              :             let compact_metadata = partition.overlaps(&Key::metadata_key_range());
    4346              :             if compact_metadata {
    4347              :                 for range in &partition.ranges {
    4348              :                     assert!(
    4349              :                         range.start.field1 >= METADATA_KEY_BEGIN_PREFIX
    4350              :                             && range.end.field1 <= METADATA_KEY_END_PREFIX,
    4351              :                         "metadata keys must be partitioned separately"
    4352              :                     );
    4353              :                 }
    4354              :                 if mode == ImageLayerCreationMode::Try && !check_for_image_layers {
    4355              :                     // Skip compaction if there are not enough updates. Metadata compaction will do a scan and
    4356              :                     // might mess up with evictions.
    4357              :                     start = img_range.end;
    4358              :                     continue;
    4359              :                 }
    4360              :                 // For initial and force modes, we always generate image layers for metadata keys.
    4361              :             } else if let ImageLayerCreationMode::Try = mode {
    4362              :                 // check_for_image_layers = false -> skip
    4363              :                 // check_for_image_layers = true -> check time_for_new_image_layer -> skip/generate
    4364              :                 if !check_for_image_layers || !self.time_for_new_image_layer(partition, lsn).await {
    4365              :                     start = img_range.end;
    4366              :                     continue;
    4367              :                 }
    4368              :             }
    4369              :             if let ImageLayerCreationMode::Force = mode {
    4370              :                 // When forced to create image layers, we might try and create them where they already
    4371              :                 // exist.  This mode is only used in tests/debug.
    4372              :                 let layers = self.layers.read().await;
    4373              :                 if layers.contains_key(&PersistentLayerKey {
    4374              :                     key_range: img_range.clone(),
    4375              :                     lsn_range: PersistentLayerDesc::image_layer_lsn_range(lsn),
    4376              :                     is_delta: false,
    4377              :                 }) {
    4378              :                     tracing::info!(
    4379              :                         "Skipping image layer at {lsn} {}..{}, already exists",
    4380              :                         img_range.start,
    4381              :                         img_range.end
    4382              :                     );
    4383              :                     start = img_range.end;
    4384              :                     continue;
    4385              :                 }
    4386              :             }
    4387              : 
    4388              :             let image_layer_writer = ImageLayerWriter::new(
    4389              :                 self.conf,
    4390              :                 self.timeline_id,
    4391              :                 self.tenant_shard_id,
    4392              :                 &img_range,
    4393              :                 lsn,
    4394              :                 ctx,
    4395              :             )
    4396              :             .await?;
    4397              : 
    4398            0 :             fail_point!("image-layer-writer-fail-before-finish", |_| {
    4399            0 :                 Err(CreateImageLayersError::Other(anyhow::anyhow!(
    4400            0 :                     "failpoint image-layer-writer-fail-before-finish"
    4401            0 :                 )))
    4402            0 :             });
    4403              : 
    4404              :             if !compact_metadata {
    4405              :                 let ImageLayerCreationOutcome {
    4406              :                     image,
    4407              :                     next_start_key,
    4408              :                 } = self
    4409              :                     .create_image_layer_for_rel_blocks(
    4410              :                         partition,
    4411              :                         image_layer_writer,
    4412              :                         lsn,
    4413              :                         ctx,
    4414              :                         img_range,
    4415              :                         start,
    4416              :                     )
    4417              :                     .await?;
    4418              : 
    4419              :                 start = next_start_key;
    4420              :                 image_layers.extend(image);
    4421              :             } else {
    4422              :                 let ImageLayerCreationOutcome {
    4423              :                     image,
    4424              :                     next_start_key,
    4425              :                 } = self
    4426              :                     .create_image_layer_for_metadata_keys(
    4427              :                         partition,
    4428              :                         image_layer_writer,
    4429              :                         lsn,
    4430              :                         ctx,
    4431              :                         img_range,
    4432              :                         mode,
    4433              :                         start,
    4434              :                     )
    4435              :                     .await?;
    4436              :                 start = next_start_key;
    4437              :                 image_layers.extend(image);
    4438              :             }
    4439              :         }
    4440              : 
    4441              :         let mut guard = self.layers.write().await;
    4442              : 
    4443              :         // FIXME: we could add the images to be uploaded *before* returning from here, but right
    4444              :         // now they are being scheduled outside of write lock; current way is inconsistent with
    4445              :         // compaction lock order.
    4446              :         guard
    4447              :             .open_mut()?
    4448              :             .track_new_image_layers(&image_layers, &self.metrics);
    4449              :         drop_wlock(guard);
    4450              :         timer.stop_and_record();
    4451              : 
    4452              :         // Creating image layers may have caused some previously visible layers to be covered
    4453              :         if !image_layers.is_empty() {
    4454              :             self.update_layer_visibility().await?;
    4455              :         }
    4456              : 
    4457              :         Ok(image_layers)
    4458              :     }
    4459              : 
    4460              :     /// Wait until the background initial logical size calculation is complete, or
    4461              :     /// this Timeline is shut down.  Calling this function will cause the initial
    4462              :     /// logical size calculation to skip waiting for the background jobs barrier.
    4463            0 :     pub(crate) async fn await_initial_logical_size(self: Arc<Self>) {
    4464            0 :         if !self.shard_identity.is_shard_zero() {
    4465              :             // We don't populate logical size on shard >0: skip waiting for it.
    4466            0 :             return;
    4467            0 :         }
    4468            0 : 
    4469            0 :         if self.remote_client.is_deleting() {
    4470              :             // The timeline was created in a deletion-resume state, we don't expect logical size to be populated
    4471            0 :             return;
    4472            0 :         }
    4473            0 : 
    4474            0 :         if self.current_logical_size.current_size().is_exact() {
    4475              :             // root timelines are initialized with exact count, but never start the background
    4476              :             // calculation
    4477            0 :             return;
    4478            0 :         }
    4479              : 
    4480            0 :         if let Some(await_bg_cancel) = self
    4481            0 :             .current_logical_size
    4482            0 :             .cancel_wait_for_background_loop_concurrency_limit_semaphore
    4483            0 :             .get()
    4484            0 :         {
    4485            0 :             await_bg_cancel.cancel();
    4486            0 :         } else {
    4487              :             // We should not wait if we were not able to explicitly instruct
    4488              :             // the logical size cancellation to skip the concurrency limit semaphore.
    4489              :             // TODO: this is an unexpected case.  We should restructure so that it
    4490              :             // can't happen.
    4491            0 :             tracing::warn!(
    4492            0 :                 "await_initial_logical_size: can't get semaphore cancel token, skipping"
    4493              :             );
    4494            0 :             debug_assert!(false);
    4495              :         }
    4496              : 
    4497            0 :         tokio::select!(
    4498            0 :             _ = self.current_logical_size.initialized.acquire() => {},
    4499            0 :             _ = self.cancel.cancelled() => {}
    4500              :         )
    4501            0 :     }
    4502              : 
    4503              :     /// Detach this timeline from its ancestor by copying all of ancestors layers as this
    4504              :     /// Timelines layers up to the ancestor_lsn.
    4505              :     ///
    4506              :     /// Requires a timeline that:
    4507              :     /// - has an ancestor to detach from
    4508              :     /// - the ancestor does not have an ancestor -- follows from the original RFC limitations, not
    4509              :     ///   a technical requirement
    4510              :     ///
    4511              :     /// After the operation has been started, it cannot be canceled. Upon restart it needs to be
    4512              :     /// polled again until completion.
    4513              :     ///
    4514              :     /// During the operation all timelines sharing the data with this timeline will be reparented
    4515              :     /// from our ancestor to be branches of this timeline.
    4516            0 :     pub(crate) async fn prepare_to_detach_from_ancestor(
    4517            0 :         self: &Arc<Timeline>,
    4518            0 :         tenant: &crate::tenant::Tenant,
    4519            0 :         options: detach_ancestor::Options,
    4520            0 :         ctx: &RequestContext,
    4521            0 :     ) -> Result<detach_ancestor::Progress, detach_ancestor::Error> {
    4522            0 :         detach_ancestor::prepare(self, tenant, options, ctx).await
    4523            0 :     }
    4524              : 
    4525              :     /// Second step of detach from ancestor; detaches the `self` from it's current ancestor and
    4526              :     /// reparents any reparentable children of previous ancestor.
    4527              :     ///
    4528              :     /// This method is to be called while holding the TenantManager's tenant slot, so during this
    4529              :     /// method we cannot be deleted nor can any timeline be deleted. After this method returns
    4530              :     /// successfully, tenant must be reloaded.
    4531              :     ///
    4532              :     /// Final step will be to [`Self::complete_detaching_timeline_ancestor`] after optionally
    4533              :     /// resetting the tenant.
    4534            0 :     pub(crate) async fn detach_from_ancestor_and_reparent(
    4535            0 :         self: &Arc<Timeline>,
    4536            0 :         tenant: &crate::tenant::Tenant,
    4537            0 :         prepared: detach_ancestor::PreparedTimelineDetach,
    4538            0 :         ctx: &RequestContext,
    4539            0 :     ) -> Result<detach_ancestor::DetachingAndReparenting, detach_ancestor::Error> {
    4540            0 :         detach_ancestor::detach_and_reparent(self, tenant, prepared, ctx).await
    4541            0 :     }
    4542              : 
    4543              :     /// Final step which unblocks the GC.
    4544              :     ///
    4545              :     /// The tenant must've been reset if ancestry was modified previously (in tenant manager).
    4546            0 :     pub(crate) async fn complete_detaching_timeline_ancestor(
    4547            0 :         self: &Arc<Timeline>,
    4548            0 :         tenant: &crate::tenant::Tenant,
    4549            0 :         attempt: detach_ancestor::Attempt,
    4550            0 :         ctx: &RequestContext,
    4551            0 :     ) -> Result<(), detach_ancestor::Error> {
    4552            0 :         detach_ancestor::complete(self, tenant, attempt, ctx).await
    4553            0 :     }
    4554              : }
    4555              : 
    4556              : impl Drop for Timeline {
    4557           10 :     fn drop(&mut self) {
    4558           10 :         if let Some(ancestor) = &self.ancestor_timeline {
    4559              :             // This lock should never be poisoned, but in case it is we do a .map() instead of
    4560              :             // an unwrap(), to avoid panicking in a destructor and thereby aborting the process.
    4561            4 :             if let Ok(mut gc_info) = ancestor.gc_info.write() {
    4562            4 :                 if !gc_info.remove_child_not_offloaded(self.timeline_id) {
    4563            0 :                     tracing::error!(tenant_id = %self.tenant_shard_id.tenant_id, shard_id = %self.tenant_shard_id.shard_slug(), timeline_id = %self.timeline_id,
    4564            0 :                         "Couldn't remove retain_lsn entry from offloaded timeline's parent: already removed");
    4565            4 :                 }
    4566            0 :             }
    4567            6 :         }
    4568           10 :     }
    4569              : }
    4570              : 
    4571              : /// Top-level failure to compact.
    4572            0 : #[derive(Debug, thiserror::Error)]
    4573              : pub(crate) enum CompactionError {
    4574              :     #[error("The timeline or pageserver is shutting down")]
    4575              :     ShuttingDown,
    4576              :     /// Compaction tried to offload a timeline and failed
    4577              :     #[error("Failed to offload timeline: {0}")]
    4578              :     Offload(OffloadError),
    4579              :     /// Compaction cannot be done right now; page reconstruction and so on.
    4580              :     #[error(transparent)]
    4581              :     Other(anyhow::Error),
    4582              : }
    4583              : 
    4584              : impl From<OffloadError> for CompactionError {
    4585            0 :     fn from(e: OffloadError) -> Self {
    4586            0 :         match e {
    4587            0 :             OffloadError::Cancelled => Self::ShuttingDown,
    4588            0 :             _ => Self::Offload(e),
    4589              :         }
    4590            0 :     }
    4591              : }
    4592              : 
    4593              : impl CompactionError {
    4594            0 :     pub fn is_cancelled(&self) -> bool {
    4595            0 :         matches!(self, CompactionError::ShuttingDown)
    4596            0 :     }
    4597              : }
    4598              : 
    4599              : impl From<CollectKeySpaceError> for CompactionError {
    4600            0 :     fn from(err: CollectKeySpaceError) -> Self {
    4601            0 :         match err {
    4602              :             CollectKeySpaceError::Cancelled
    4603              :             | CollectKeySpaceError::PageRead(PageReconstructError::Cancelled) => {
    4604            0 :                 CompactionError::ShuttingDown
    4605              :             }
    4606            0 :             e => CompactionError::Other(e.into()),
    4607              :         }
    4608            0 :     }
    4609              : }
    4610              : 
    4611              : impl From<super::upload_queue::NotInitialized> for CompactionError {
    4612            0 :     fn from(value: super::upload_queue::NotInitialized) -> Self {
    4613            0 :         match value {
    4614              :             super::upload_queue::NotInitialized::Uninitialized => {
    4615            0 :                 CompactionError::Other(anyhow::anyhow!(value))
    4616              :             }
    4617              :             super::upload_queue::NotInitialized::ShuttingDown
    4618            0 :             | super::upload_queue::NotInitialized::Stopped => CompactionError::ShuttingDown,
    4619              :         }
    4620            0 :     }
    4621              : }
    4622              : 
    4623              : impl From<super::storage_layer::layer::DownloadError> for CompactionError {
    4624            0 :     fn from(e: super::storage_layer::layer::DownloadError) -> Self {
    4625            0 :         match e {
    4626              :             super::storage_layer::layer::DownloadError::TimelineShutdown
    4627              :             | super::storage_layer::layer::DownloadError::DownloadCancelled => {
    4628            0 :                 CompactionError::ShuttingDown
    4629              :             }
    4630              :             super::storage_layer::layer::DownloadError::ContextAndConfigReallyDeniesDownloads
    4631              :             | super::storage_layer::layer::DownloadError::DownloadRequired
    4632              :             | super::storage_layer::layer::DownloadError::NotFile(_)
    4633              :             | super::storage_layer::layer::DownloadError::DownloadFailed
    4634              :             | super::storage_layer::layer::DownloadError::PreStatFailed(_) => {
    4635            0 :                 CompactionError::Other(anyhow::anyhow!(e))
    4636              :             }
    4637              :             #[cfg(test)]
    4638              :             super::storage_layer::layer::DownloadError::Failpoint(_) => {
    4639            0 :                 CompactionError::Other(anyhow::anyhow!(e))
    4640              :             }
    4641              :         }
    4642            0 :     }
    4643              : }
    4644              : 
    4645              : impl From<layer_manager::Shutdown> for CompactionError {
    4646            0 :     fn from(_: layer_manager::Shutdown) -> Self {
    4647            0 :         CompactionError::ShuttingDown
    4648            0 :     }
    4649              : }
    4650              : 
    4651              : #[serde_as]
    4652          196 : #[derive(serde::Serialize)]
    4653              : struct RecordedDuration(#[serde_as(as = "serde_with::DurationMicroSeconds")] Duration);
    4654              : 
    4655              : #[derive(Default)]
    4656              : enum DurationRecorder {
    4657              :     #[default]
    4658              :     NotStarted,
    4659              :     Recorded(RecordedDuration, tokio::time::Instant),
    4660              : }
    4661              : 
    4662              : impl DurationRecorder {
    4663          504 :     fn till_now(&self) -> DurationRecorder {
    4664          504 :         match self {
    4665              :             DurationRecorder::NotStarted => {
    4666            0 :                 panic!("must only call on recorded measurements")
    4667              :             }
    4668          504 :             DurationRecorder::Recorded(_, ended) => {
    4669          504 :                 let now = tokio::time::Instant::now();
    4670          504 :                 DurationRecorder::Recorded(RecordedDuration(now - *ended), now)
    4671          504 :             }
    4672          504 :         }
    4673          504 :     }
    4674          196 :     fn into_recorded(self) -> Option<RecordedDuration> {
    4675          196 :         match self {
    4676            0 :             DurationRecorder::NotStarted => None,
    4677          196 :             DurationRecorder::Recorded(recorded, _) => Some(recorded),
    4678              :         }
    4679          196 :     }
    4680              : }
    4681              : 
    4682              : /// Descriptor for a delta layer used in testing infra. The start/end key/lsn range of the
    4683              : /// delta layer might be different from the min/max key/lsn in the delta layer. Therefore,
    4684              : /// the layer descriptor requires the user to provide the ranges, which should cover all
    4685              : /// keys specified in the `data` field.
    4686              : #[cfg(test)]
    4687              : #[derive(Clone)]
    4688              : pub struct DeltaLayerTestDesc {
    4689              :     pub lsn_range: Range<Lsn>,
    4690              :     pub key_range: Range<Key>,
    4691              :     pub data: Vec<(Key, Lsn, Value)>,
    4692              : }
    4693              : 
    4694              : #[cfg(test)]
    4695              : impl DeltaLayerTestDesc {
    4696            2 :     pub fn new(lsn_range: Range<Lsn>, key_range: Range<Key>, data: Vec<(Key, Lsn, Value)>) -> Self {
    4697            2 :         Self {
    4698            2 :             lsn_range,
    4699            2 :             key_range,
    4700            2 :             data,
    4701            2 :         }
    4702            2 :     }
    4703              : 
    4704           72 :     pub fn new_with_inferred_key_range(
    4705           72 :         lsn_range: Range<Lsn>,
    4706           72 :         data: Vec<(Key, Lsn, Value)>,
    4707           72 :     ) -> Self {
    4708          196 :         let key_min = data.iter().map(|(key, _, _)| key).min().unwrap();
    4709          196 :         let key_max = data.iter().map(|(key, _, _)| key).max().unwrap();
    4710           72 :         Self {
    4711           72 :             key_range: (*key_min)..(key_max.next()),
    4712           72 :             lsn_range,
    4713           72 :             data,
    4714           72 :         }
    4715           72 :     }
    4716              : 
    4717           10 :     pub(crate) fn layer_name(&self) -> LayerName {
    4718           10 :         LayerName::Delta(super::storage_layer::DeltaLayerName {
    4719           10 :             key_range: self.key_range.clone(),
    4720           10 :             lsn_range: self.lsn_range.clone(),
    4721           10 :         })
    4722           10 :     }
    4723              : }
    4724              : 
    4725              : impl Timeline {
    4726           28 :     async fn finish_compact_batch(
    4727           28 :         self: &Arc<Self>,
    4728           28 :         new_deltas: &[ResidentLayer],
    4729           28 :         new_images: &[ResidentLayer],
    4730           28 :         layers_to_remove: &[Layer],
    4731           28 :     ) -> Result<(), CompactionError> {
    4732           28 :         let mut guard = tokio::select! {
    4733           28 :             guard = self.layers.write() => guard,
    4734           28 :             _ = self.cancel.cancelled() => {
    4735            0 :                 return Err(CompactionError::ShuttingDown);
    4736              :             }
    4737              :         };
    4738              : 
    4739           28 :         let mut duplicated_layers = HashSet::new();
    4740           28 : 
    4741           28 :         let mut insert_layers = Vec::with_capacity(new_deltas.len());
    4742              : 
    4743          336 :         for l in new_deltas {
    4744          308 :             if guard.contains(l.as_ref()) {
    4745              :                 // expected in tests
    4746            0 :                 tracing::error!(layer=%l, "duplicated L1 layer");
    4747              : 
    4748              :                 // good ways to cause a duplicate: we repeatedly error after taking the writelock
    4749              :                 // `guard`  on self.layers. as of writing this, there are no error returns except
    4750              :                 // for compact_level0_phase1 creating an L0, which does not happen in practice
    4751              :                 // because we have not implemented L0 => L0 compaction.
    4752            0 :                 duplicated_layers.insert(l.layer_desc().key());
    4753          308 :             } else if LayerMap::is_l0(&l.layer_desc().key_range, l.layer_desc().is_delta) {
    4754            0 :                 return Err(CompactionError::Other(anyhow::anyhow!("compaction generates a L0 layer file as output, which will cause infinite compaction.")));
    4755          308 :             } else {
    4756          308 :                 insert_layers.push(l.clone());
    4757          308 :             }
    4758              :         }
    4759              : 
    4760              :         // only remove those inputs which were not outputs
    4761           28 :         let remove_layers: Vec<Layer> = layers_to_remove
    4762           28 :             .iter()
    4763          402 :             .filter(|l| !duplicated_layers.contains(&l.layer_desc().key()))
    4764           28 :             .cloned()
    4765           28 :             .collect();
    4766           28 : 
    4767           28 :         if !new_images.is_empty() {
    4768            0 :             guard
    4769            0 :                 .open_mut()?
    4770            0 :                 .track_new_image_layers(new_images, &self.metrics);
    4771           28 :         }
    4772              : 
    4773           28 :         guard
    4774           28 :             .open_mut()?
    4775           28 :             .finish_compact_l0(&remove_layers, &insert_layers, &self.metrics);
    4776           28 : 
    4777           28 :         self.remote_client
    4778           28 :             .schedule_compaction_update(&remove_layers, new_deltas)?;
    4779              : 
    4780           28 :         drop_wlock(guard);
    4781           28 : 
    4782           28 :         Ok(())
    4783           28 :     }
    4784              : 
    4785            0 :     async fn rewrite_layers(
    4786            0 :         self: &Arc<Self>,
    4787            0 :         mut replace_layers: Vec<(Layer, ResidentLayer)>,
    4788            0 :         mut drop_layers: Vec<Layer>,
    4789            0 :     ) -> Result<(), CompactionError> {
    4790            0 :         let mut guard = self.layers.write().await;
    4791              : 
    4792              :         // Trim our lists in case our caller (compaction) raced with someone else (GC) removing layers: we want
    4793              :         // to avoid double-removing, and avoid rewriting something that was removed.
    4794            0 :         replace_layers.retain(|(l, _)| guard.contains(l));
    4795            0 :         drop_layers.retain(|l| guard.contains(l));
    4796            0 : 
    4797            0 :         guard
    4798            0 :             .open_mut()?
    4799            0 :             .rewrite_layers(&replace_layers, &drop_layers, &self.metrics);
    4800            0 : 
    4801            0 :         let upload_layers: Vec<_> = replace_layers.into_iter().map(|r| r.1).collect();
    4802            0 : 
    4803            0 :         self.remote_client
    4804            0 :             .schedule_compaction_update(&drop_layers, &upload_layers)?;
    4805              : 
    4806            0 :         Ok(())
    4807            0 :     }
    4808              : 
    4809              :     /// Schedules the uploads of the given image layers
    4810          364 :     fn upload_new_image_layers(
    4811          364 :         self: &Arc<Self>,
    4812          364 :         new_images: impl IntoIterator<Item = ResidentLayer>,
    4813          364 :     ) -> Result<(), super::upload_queue::NotInitialized> {
    4814          390 :         for layer in new_images {
    4815           26 :             self.remote_client.schedule_layer_file_upload(layer)?;
    4816              :         }
    4817              :         // should any new image layer been created, not uploading index_part will
    4818              :         // result in a mismatch between remote_physical_size and layermap calculated
    4819              :         // size, which will fail some tests, but should not be an issue otherwise.
    4820          364 :         self.remote_client
    4821          364 :             .schedule_index_upload_for_file_changes()?;
    4822          364 :         Ok(())
    4823          364 :     }
    4824              : 
    4825            0 :     async fn find_gc_time_cutoff(
    4826            0 :         &self,
    4827            0 :         pitr: Duration,
    4828            0 :         cancel: &CancellationToken,
    4829            0 :         ctx: &RequestContext,
    4830            0 :     ) -> Result<Option<Lsn>, PageReconstructError> {
    4831            0 :         debug_assert_current_span_has_tenant_and_timeline_id();
    4832            0 :         if self.shard_identity.is_shard_zero() {
    4833              :             // Shard Zero has SLRU data and can calculate the PITR time -> LSN mapping itself
    4834            0 :             let now = SystemTime::now();
    4835            0 :             let time_range = if pitr == Duration::ZERO {
    4836            0 :                 humantime::parse_duration(DEFAULT_PITR_INTERVAL).expect("constant is invalid")
    4837              :             } else {
    4838            0 :                 pitr
    4839              :             };
    4840              : 
    4841              :             // If PITR is so large or `now` is so small that this underflows, we will retain no history (highly unexpected case)
    4842            0 :             let time_cutoff = now.checked_sub(time_range).unwrap_or(now);
    4843            0 :             let timestamp = to_pg_timestamp(time_cutoff);
    4844              : 
    4845            0 :             let time_cutoff = match self.find_lsn_for_timestamp(timestamp, cancel, ctx).await? {
    4846            0 :                 LsnForTimestamp::Present(lsn) => Some(lsn),
    4847            0 :                 LsnForTimestamp::Future(lsn) => {
    4848            0 :                     // The timestamp is in the future. That sounds impossible,
    4849            0 :                     // but what it really means is that there hasn't been
    4850            0 :                     // any commits since the cutoff timestamp.
    4851            0 :                     //
    4852            0 :                     // In this case we should use the LSN of the most recent commit,
    4853            0 :                     // which is implicitly the last LSN in the log.
    4854            0 :                     debug!("future({})", lsn);
    4855            0 :                     Some(self.get_last_record_lsn())
    4856              :                 }
    4857            0 :                 LsnForTimestamp::Past(lsn) => {
    4858            0 :                     debug!("past({})", lsn);
    4859            0 :                     None
    4860              :                 }
    4861            0 :                 LsnForTimestamp::NoData(lsn) => {
    4862            0 :                     debug!("nodata({})", lsn);
    4863            0 :                     None
    4864              :                 }
    4865              :             };
    4866            0 :             Ok(time_cutoff)
    4867              :         } else {
    4868              :             // Shards other than shard zero cannot do timestamp->lsn lookups, and must instead learn their GC cutoff
    4869              :             // from shard zero's index.  The index doesn't explicitly tell us the time cutoff, but we may assume that
    4870              :             // the point up to which shard zero's last_gc_cutoff has advanced will either be the time cutoff, or a
    4871              :             // space cutoff that we would also have respected ourselves.
    4872            0 :             match self
    4873            0 :                 .remote_client
    4874            0 :                 .download_foreign_index(ShardNumber(0), cancel)
    4875            0 :                 .await
    4876              :             {
    4877            0 :                 Ok((index_part, index_generation, _index_mtime)) => {
    4878            0 :                     tracing::info!("GC loaded shard zero metadata (gen {index_generation:?}): latest_gc_cutoff_lsn: {}",
    4879            0 :                         index_part.metadata.latest_gc_cutoff_lsn());
    4880            0 :                     Ok(Some(index_part.metadata.latest_gc_cutoff_lsn()))
    4881              :                 }
    4882              :                 Err(DownloadError::NotFound) => {
    4883              :                     // This is unexpected, because during timeline creations shard zero persists to remote
    4884              :                     // storage before other shards are called, and during timeline deletion non-zeroth shards are
    4885              :                     // deleted before the zeroth one.  However, it should be harmless: if we somehow end up in this
    4886              :                     // state, then shard zero should _eventually_ write an index when it GCs.
    4887            0 :                     tracing::warn!("GC couldn't find shard zero's index for timeline");
    4888            0 :                     Ok(None)
    4889              :                 }
    4890            0 :                 Err(e) => {
    4891            0 :                     // TODO: this function should return a different error type than page reconstruct error
    4892            0 :                     Err(PageReconstructError::Other(anyhow::anyhow!(e)))
    4893              :                 }
    4894              :             }
    4895              : 
    4896              :             // TODO: after reading shard zero's GC cutoff, we should validate its generation with the storage
    4897              :             // controller.  Otherwise, it is possible that we see the GC cutoff go backwards while shard zero
    4898              :             // is going through a migration if we read the old location's index and it has GC'd ahead of the
    4899              :             // new location.  This is legal in principle, but problematic in practice because it might result
    4900              :             // in a timeline creation succeeding on shard zero ('s new location) but then failing on other shards
    4901              :             // because they have GC'd past the branch point.
    4902              :         }
    4903            0 :     }
    4904              : 
    4905              :     /// Find the Lsns above which layer files need to be retained on
    4906              :     /// garbage collection.
    4907              :     ///
    4908              :     /// We calculate two cutoffs, one based on time and one based on WAL size.  `pitr`
    4909              :     /// controls the time cutoff (or ZERO to disable time-based retention), and `space_cutoff` controls
    4910              :     /// the space-based retention.
    4911              :     ///
    4912              :     /// This function doesn't simply to calculate time & space based retention: it treats time-based
    4913              :     /// retention as authoritative if enabled, and falls back to space-based retention if calculating
    4914              :     /// the LSN for a time point isn't possible.  Therefore the GcCutoffs::horizon in the response might
    4915              :     /// be different to the `space_cutoff` input.  Callers should treat the min() of the two cutoffs
    4916              :     /// in the response as the GC cutoff point for the timeline.
    4917            4 :     #[instrument(skip_all, fields(timeline_id=%self.timeline_id))]
    4918              :     pub(super) async fn find_gc_cutoffs(
    4919              :         &self,
    4920              :         space_cutoff: Lsn,
    4921              :         pitr: Duration,
    4922              :         cancel: &CancellationToken,
    4923              :         ctx: &RequestContext,
    4924              :     ) -> Result<GcCutoffs, PageReconstructError> {
    4925              :         let _timer = self
    4926              :             .metrics
    4927              :             .find_gc_cutoffs_histo
    4928              :             .start_timer()
    4929              :             .record_on_drop();
    4930              : 
    4931              :         pausable_failpoint!("Timeline::find_gc_cutoffs-pausable");
    4932              : 
    4933              :         if cfg!(test) {
    4934              :             // Unit tests which specify zero PITR interval expect to avoid doing any I/O for timestamp lookup
    4935              :             if pitr == Duration::ZERO {
    4936              :                 return Ok(GcCutoffs {
    4937              :                     time: self.get_last_record_lsn(),
    4938              :                     space: space_cutoff,
    4939              :                 });
    4940              :             }
    4941              :         }
    4942              : 
    4943              :         // Calculate a time-based limit on how much to retain:
    4944              :         // - if PITR interval is set, then this is our cutoff.
    4945              :         // - if PITR interval is not set, then we do a lookup
    4946              :         //   based on DEFAULT_PITR_INTERVAL, so that size-based retention does not result in keeping history around permanently on idle databases.
    4947              :         let time_cutoff = self.find_gc_time_cutoff(pitr, cancel, ctx).await?;
    4948              : 
    4949              :         Ok(match (pitr, time_cutoff) {
    4950              :             (Duration::ZERO, Some(time_cutoff)) => {
    4951              :                 // PITR is not set. Retain the size-based limit, or the default time retention,
    4952              :                 // whichever requires less data.
    4953              :                 GcCutoffs {
    4954              :                     time: self.get_last_record_lsn(),
    4955              :                     space: std::cmp::max(time_cutoff, space_cutoff),
    4956              :                 }
    4957              :             }
    4958              :             (Duration::ZERO, None) => {
    4959              :                 // PITR is not set, and time lookup failed
    4960              :                 GcCutoffs {
    4961              :                     time: self.get_last_record_lsn(),
    4962              :                     space: space_cutoff,
    4963              :                 }
    4964              :             }
    4965              :             (_, None) => {
    4966              :                 // PITR interval is set & we didn't look up a timestamp successfully.  Conservatively assume PITR
    4967              :                 // cannot advance beyond what was already GC'd, and respect space-based retention
    4968              :                 GcCutoffs {
    4969              :                     time: *self.get_latest_gc_cutoff_lsn(),
    4970              :                     space: space_cutoff,
    4971              :                 }
    4972              :             }
    4973              :             (_, Some(time_cutoff)) => {
    4974              :                 // PITR interval is set and we looked up timestamp successfully.  Ignore
    4975              :                 // size based retention and make time cutoff authoritative
    4976              :                 GcCutoffs {
    4977              :                     time: time_cutoff,
    4978              :                     space: time_cutoff,
    4979              :                 }
    4980              :             }
    4981              :         })
    4982              :     }
    4983              : 
    4984              :     /// Garbage collect layer files on a timeline that are no longer needed.
    4985              :     ///
    4986              :     /// Currently, we don't make any attempt at removing unneeded page versions
    4987              :     /// within a layer file. We can only remove the whole file if it's fully
    4988              :     /// obsolete.
    4989            4 :     pub(super) async fn gc(&self) -> Result<GcResult, GcError> {
    4990              :         // this is most likely the background tasks, but it might be the spawned task from
    4991              :         // immediate_gc
    4992            4 :         let _g = tokio::select! {
    4993            4 :             guard = self.gc_lock.lock() => guard,
    4994            4 :             _ = self.cancel.cancelled() => return Ok(GcResult::default()),
    4995              :         };
    4996            4 :         let timer = self.metrics.garbage_collect_histo.start_timer();
    4997            4 : 
    4998            4 :         fail_point!("before-timeline-gc");
    4999            4 : 
    5000            4 :         // Is the timeline being deleted?
    5001            4 :         if self.is_stopping() {
    5002            0 :             return Err(GcError::TimelineCancelled);
    5003            4 :         }
    5004            4 : 
    5005            4 :         let (space_cutoff, time_cutoff, retain_lsns, max_lsn_with_valid_lease) = {
    5006            4 :             let gc_info = self.gc_info.read().unwrap();
    5007            4 : 
    5008            4 :             let space_cutoff = min(gc_info.cutoffs.space, self.get_disk_consistent_lsn());
    5009            4 :             let time_cutoff = gc_info.cutoffs.time;
    5010            4 :             let retain_lsns = gc_info
    5011            4 :                 .retain_lsns
    5012            4 :                 .iter()
    5013            4 :                 .map(|(lsn, _child_id, _is_offloaded)| *lsn)
    5014            4 :                 .collect();
    5015            4 : 
    5016            4 :             // Gets the maximum LSN that holds the valid lease.
    5017            4 :             //
    5018            4 :             // Caveat: `refresh_gc_info` is in charged of updating the lease map.
    5019            4 :             // Here, we do not check for stale leases again.
    5020            4 :             let max_lsn_with_valid_lease = gc_info.leases.last_key_value().map(|(lsn, _)| *lsn);
    5021            4 : 
    5022            4 :             (
    5023            4 :                 space_cutoff,
    5024            4 :                 time_cutoff,
    5025            4 :                 retain_lsns,
    5026            4 :                 max_lsn_with_valid_lease,
    5027            4 :             )
    5028            4 :         };
    5029            4 : 
    5030            4 :         let mut new_gc_cutoff = Lsn::min(space_cutoff, time_cutoff);
    5031            4 :         let standby_horizon = self.standby_horizon.load();
    5032            4 :         // Hold GC for the standby, but as a safety guard do it only within some
    5033            4 :         // reasonable lag.
    5034            4 :         if standby_horizon != Lsn::INVALID {
    5035            0 :             if let Some(standby_lag) = new_gc_cutoff.checked_sub(standby_horizon) {
    5036              :                 const MAX_ALLOWED_STANDBY_LAG: u64 = 10u64 << 30; // 10 GB
    5037            0 :                 if standby_lag.0 < MAX_ALLOWED_STANDBY_LAG {
    5038            0 :                     new_gc_cutoff = Lsn::min(standby_horizon, new_gc_cutoff);
    5039            0 :                     trace!("holding off GC for standby apply LSN {}", standby_horizon);
    5040              :                 } else {
    5041            0 :                     warn!(
    5042            0 :                         "standby is lagging for more than {}MB, not holding gc for it",
    5043            0 :                         MAX_ALLOWED_STANDBY_LAG / 1024 / 1024
    5044              :                     )
    5045              :                 }
    5046            0 :             }
    5047            4 :         }
    5048              : 
    5049              :         // Reset standby horizon to ignore it if it is not updated till next GC.
    5050              :         // It is an easy way to unset it when standby disappears without adding
    5051              :         // more conf options.
    5052            4 :         self.standby_horizon.store(Lsn::INVALID);
    5053            4 :         self.metrics
    5054            4 :             .standby_horizon_gauge
    5055            4 :             .set(Lsn::INVALID.0 as i64);
    5056              : 
    5057            4 :         let res = self
    5058            4 :             .gc_timeline(
    5059            4 :                 space_cutoff,
    5060            4 :                 time_cutoff,
    5061            4 :                 retain_lsns,
    5062            4 :                 max_lsn_with_valid_lease,
    5063            4 :                 new_gc_cutoff,
    5064            4 :             )
    5065            4 :             .instrument(
    5066            4 :                 info_span!("gc_timeline", timeline_id = %self.timeline_id, cutoff = %new_gc_cutoff),
    5067              :             )
    5068            0 :             .await?;
    5069              : 
    5070              :         // only record successes
    5071            4 :         timer.stop_and_record();
    5072            4 : 
    5073            4 :         Ok(res)
    5074            4 :     }
    5075              : 
    5076            4 :     async fn gc_timeline(
    5077            4 :         &self,
    5078            4 :         space_cutoff: Lsn,
    5079            4 :         time_cutoff: Lsn,
    5080            4 :         retain_lsns: Vec<Lsn>,
    5081            4 :         max_lsn_with_valid_lease: Option<Lsn>,
    5082            4 :         new_gc_cutoff: Lsn,
    5083            4 :     ) -> Result<GcResult, GcError> {
    5084            4 :         // FIXME: if there is an ongoing detach_from_ancestor, we should just skip gc
    5085            4 : 
    5086            4 :         let now = SystemTime::now();
    5087            4 :         let mut result: GcResult = GcResult::default();
    5088            4 : 
    5089            4 :         // Nothing to GC. Return early.
    5090            4 :         let latest_gc_cutoff = *self.get_latest_gc_cutoff_lsn();
    5091            4 :         if latest_gc_cutoff >= new_gc_cutoff {
    5092            0 :             info!(
    5093            0 :                 "Nothing to GC: new_gc_cutoff_lsn {new_gc_cutoff}, latest_gc_cutoff_lsn {latest_gc_cutoff}",
    5094              :             );
    5095            0 :             return Ok(result);
    5096            4 :         }
    5097              : 
    5098              :         // We need to ensure that no one tries to read page versions or create
    5099              :         // branches at a point before latest_gc_cutoff_lsn. See branch_timeline()
    5100              :         // for details. This will block until the old value is no longer in use.
    5101              :         //
    5102              :         // The GC cutoff should only ever move forwards.
    5103            4 :         let waitlist = {
    5104            4 :             let write_guard = self.latest_gc_cutoff_lsn.lock_for_write();
    5105            4 :             if *write_guard > new_gc_cutoff {
    5106            0 :                 return Err(GcError::BadLsn {
    5107            0 :                     why: format!(
    5108            0 :                         "Cannot move GC cutoff LSN backwards (was {}, new {})",
    5109            0 :                         *write_guard, new_gc_cutoff
    5110            0 :                     ),
    5111            0 :                 });
    5112            4 :             }
    5113            4 : 
    5114            4 :             write_guard.store_and_unlock(new_gc_cutoff)
    5115            4 :         };
    5116            4 :         waitlist.wait().await;
    5117              : 
    5118            4 :         info!("GC starting");
    5119              : 
    5120            4 :         debug!("retain_lsns: {:?}", retain_lsns);
    5121              : 
    5122            4 :         let mut layers_to_remove = Vec::new();
    5123              : 
    5124              :         // Scan all layers in the timeline (remote or on-disk).
    5125              :         //
    5126              :         // Garbage collect the layer if all conditions are satisfied:
    5127              :         // 1. it is older than cutoff LSN;
    5128              :         // 2. it is older than PITR interval;
    5129              :         // 3. it doesn't need to be retained for 'retain_lsns';
    5130              :         // 4. it does not need to be kept for LSNs holding valid leases.
    5131              :         // 5. newer on-disk image layers cover the layer's whole key range
    5132              :         //
    5133              :         // TODO holding a write lock is too agressive and avoidable
    5134            4 :         let mut guard = self.layers.write().await;
    5135            4 :         let layers = guard.layer_map()?;
    5136           24 :         'outer: for l in layers.iter_historic_layers() {
    5137           24 :             result.layers_total += 1;
    5138           24 : 
    5139           24 :             // 1. Is it newer than GC horizon cutoff point?
    5140           24 :             if l.get_lsn_range().end > space_cutoff {
    5141            2 :                 info!(
    5142            0 :                     "keeping {} because it's newer than space_cutoff {}",
    5143            0 :                     l.layer_name(),
    5144              :                     space_cutoff,
    5145              :                 );
    5146            2 :                 result.layers_needed_by_cutoff += 1;
    5147            2 :                 continue 'outer;
    5148           22 :             }
    5149           22 : 
    5150           22 :             // 2. It is newer than PiTR cutoff point?
    5151           22 :             if l.get_lsn_range().end > time_cutoff {
    5152            0 :                 info!(
    5153            0 :                     "keeping {} because it's newer than time_cutoff {}",
    5154            0 :                     l.layer_name(),
    5155              :                     time_cutoff,
    5156              :                 );
    5157            0 :                 result.layers_needed_by_pitr += 1;
    5158            0 :                 continue 'outer;
    5159           22 :             }
    5160              : 
    5161              :             // 3. Is it needed by a child branch?
    5162              :             // NOTE With that we would keep data that
    5163              :             // might be referenced by child branches forever.
    5164              :             // We can track this in child timeline GC and delete parent layers when
    5165              :             // they are no longer needed. This might be complicated with long inheritance chains.
    5166              :             //
    5167              :             // TODO Vec is not a great choice for `retain_lsns`
    5168           22 :             for retain_lsn in &retain_lsns {
    5169              :                 // start_lsn is inclusive
    5170            0 :                 if &l.get_lsn_range().start <= retain_lsn {
    5171            0 :                     info!(
    5172            0 :                         "keeping {} because it's still might be referenced by child branch forked at {} is_dropped: xx is_incremental: {}",
    5173            0 :                         l.layer_name(),
    5174            0 :                         retain_lsn,
    5175            0 :                         l.is_incremental(),
    5176              :                     );
    5177            0 :                     result.layers_needed_by_branches += 1;
    5178            0 :                     continue 'outer;
    5179            0 :                 }
    5180              :             }
    5181              : 
    5182              :             // 4. Is there a valid lease that requires us to keep this layer?
    5183           22 :             if let Some(lsn) = &max_lsn_with_valid_lease {
    5184              :                 // keep if layer start <= any of the lease
    5185           18 :                 if &l.get_lsn_range().start <= lsn {
    5186           14 :                     info!(
    5187            0 :                         "keeping {} because there is a valid lease preventing GC at {}",
    5188            0 :                         l.layer_name(),
    5189              :                         lsn,
    5190              :                     );
    5191           14 :                     result.layers_needed_by_leases += 1;
    5192           14 :                     continue 'outer;
    5193            4 :                 }
    5194            4 :             }
    5195              : 
    5196              :             // 5. Is there a later on-disk layer for this relation?
    5197              :             //
    5198              :             // The end-LSN is exclusive, while disk_consistent_lsn is
    5199              :             // inclusive. For example, if disk_consistent_lsn is 100, it is
    5200              :             // OK for a delta layer to have end LSN 101, but if the end LSN
    5201              :             // is 102, then it might not have been fully flushed to disk
    5202              :             // before crash.
    5203              :             //
    5204              :             // For example, imagine that the following layers exist:
    5205              :             //
    5206              :             // 1000      - image (A)
    5207              :             // 1000-2000 - delta (B)
    5208              :             // 2000      - image (C)
    5209              :             // 2000-3000 - delta (D)
    5210              :             // 3000      - image (E)
    5211              :             //
    5212              :             // If GC horizon is at 2500, we can remove layers A and B, but
    5213              :             // we cannot remove C, even though it's older than 2500, because
    5214              :             // the delta layer 2000-3000 depends on it.
    5215            8 :             if !layers
    5216            8 :                 .image_layer_exists(&l.get_key_range(), &(l.get_lsn_range().end..new_gc_cutoff))
    5217              :             {
    5218            6 :                 info!("keeping {} because it is the latest layer", l.layer_name());
    5219            6 :                 result.layers_not_updated += 1;
    5220            6 :                 continue 'outer;
    5221            2 :             }
    5222            2 : 
    5223            2 :             // We didn't find any reason to keep this file, so remove it.
    5224            2 :             info!(
    5225            0 :                 "garbage collecting {} is_dropped: xx is_incremental: {}",
    5226            0 :                 l.layer_name(),
    5227            0 :                 l.is_incremental(),
    5228              :             );
    5229            2 :             layers_to_remove.push(l);
    5230              :         }
    5231              : 
    5232            4 :         if !layers_to_remove.is_empty() {
    5233              :             // Persist the new GC cutoff value before we actually remove anything.
    5234              :             // This unconditionally schedules also an index_part.json update, even though, we will
    5235              :             // be doing one a bit later with the unlinked gc'd layers.
    5236            2 :             let disk_consistent_lsn = self.disk_consistent_lsn.load();
    5237            2 :             self.schedule_uploads(disk_consistent_lsn, None)
    5238            2 :                 .map_err(|e| {
    5239            0 :                     if self.cancel.is_cancelled() {
    5240            0 :                         GcError::TimelineCancelled
    5241              :                     } else {
    5242            0 :                         GcError::Remote(e)
    5243              :                     }
    5244            2 :                 })?;
    5245              : 
    5246            2 :             let gc_layers = layers_to_remove
    5247            2 :                 .iter()
    5248            2 :                 .map(|x| guard.get_from_desc(x))
    5249            2 :                 .collect::<Vec<Layer>>();
    5250            2 : 
    5251            2 :             result.layers_removed = gc_layers.len() as u64;
    5252            2 : 
    5253            2 :             self.remote_client.schedule_gc_update(&gc_layers)?;
    5254              : 
    5255            2 :             guard.open_mut()?.finish_gc_timeline(&gc_layers);
    5256            2 : 
    5257            2 :             #[cfg(feature = "testing")]
    5258            2 :             {
    5259            2 :                 result.doomed_layers = gc_layers;
    5260            2 :             }
    5261            2 :         }
    5262              : 
    5263            4 :         info!(
    5264            0 :             "GC completed removing {} layers, cutoff {}",
    5265              :             result.layers_removed, new_gc_cutoff
    5266              :         );
    5267              : 
    5268            4 :         result.elapsed = now.elapsed().unwrap_or(Duration::ZERO);
    5269            4 :         Ok(result)
    5270            4 :     }
    5271              : 
    5272              :     /// Reconstruct a value, using the given base image and WAL records in 'data'.
    5273       667454 :     async fn reconstruct_value(
    5274       667454 :         &self,
    5275       667454 :         key: Key,
    5276       667454 :         request_lsn: Lsn,
    5277       667454 :         mut data: ValueReconstructState,
    5278       667454 :     ) -> Result<Bytes, PageReconstructError> {
    5279       667454 :         // Perform WAL redo if needed
    5280       667454 :         data.records.reverse();
    5281       667454 : 
    5282       667454 :         // If we have a page image, and no WAL, we're all set
    5283       667454 :         if data.records.is_empty() {
    5284       667044 :             if let Some((img_lsn, img)) = &data.img {
    5285       667044 :                 trace!(
    5286            0 :                     "found page image for key {} at {}, no WAL redo required, req LSN {}",
    5287              :                     key,
    5288              :                     img_lsn,
    5289              :                     request_lsn,
    5290              :                 );
    5291       667044 :                 Ok(img.clone())
    5292              :             } else {
    5293            0 :                 Err(PageReconstructError::from(anyhow!(
    5294            0 :                     "base image for {key} at {request_lsn} not found"
    5295            0 :                 )))
    5296              :             }
    5297              :         } else {
    5298              :             // We need to do WAL redo.
    5299              :             //
    5300              :             // If we don't have a base image, then the oldest WAL record better initialize
    5301              :             // the page
    5302          410 :             if data.img.is_none() && !data.records.first().unwrap().1.will_init() {
    5303            0 :                 Err(PageReconstructError::from(anyhow!(
    5304            0 :                     "Base image for {} at {} not found, but got {} WAL records",
    5305            0 :                     key,
    5306            0 :                     request_lsn,
    5307            0 :                     data.records.len()
    5308            0 :                 )))
    5309              :             } else {
    5310          410 :                 if data.img.is_some() {
    5311          344 :                     trace!(
    5312            0 :                         "found {} WAL records and a base image for {} at {}, performing WAL redo",
    5313            0 :                         data.records.len(),
    5314              :                         key,
    5315              :                         request_lsn
    5316              :                     );
    5317              :                 } else {
    5318           66 :                     trace!("found {} WAL records that will init the page for {} at {}, performing WAL redo", data.records.len(), key, request_lsn);
    5319              :                 };
    5320          410 :                 let res = self
    5321          410 :                     .walredo_mgr
    5322          410 :                     .as_ref()
    5323          410 :                     .context("timeline has no walredo manager")
    5324          410 :                     .map_err(PageReconstructError::WalRedo)?
    5325          410 :                     .request_redo(key, request_lsn, data.img, data.records, self.pg_version)
    5326            0 :                     .await;
    5327          410 :                 let img = match res {
    5328          410 :                     Ok(img) => img,
    5329            0 :                     Err(walredo::Error::Cancelled) => return Err(PageReconstructError::Cancelled),
    5330            0 :                     Err(walredo::Error::Other(e)) => {
    5331            0 :                         return Err(PageReconstructError::WalRedo(
    5332            0 :                             e.context("reconstruct a page image"),
    5333            0 :                         ))
    5334              :                     }
    5335              :                 };
    5336          410 :                 Ok(img)
    5337              :             }
    5338              :         }
    5339       667454 :     }
    5340              : 
    5341            0 :     pub(crate) async fn spawn_download_all_remote_layers(
    5342            0 :         self: Arc<Self>,
    5343            0 :         request: DownloadRemoteLayersTaskSpawnRequest,
    5344            0 :     ) -> Result<DownloadRemoteLayersTaskInfo, DownloadRemoteLayersTaskInfo> {
    5345              :         use pageserver_api::models::DownloadRemoteLayersTaskState;
    5346              : 
    5347              :         // this is not really needed anymore; it has tests which really check the return value from
    5348              :         // http api. it would be better not to maintain this anymore.
    5349              : 
    5350            0 :         let mut status_guard = self.download_all_remote_layers_task_info.write().unwrap();
    5351            0 :         if let Some(st) = &*status_guard {
    5352            0 :             match &st.state {
    5353              :                 DownloadRemoteLayersTaskState::Running => {
    5354            0 :                     return Err(st.clone());
    5355              :                 }
    5356              :                 DownloadRemoteLayersTaskState::ShutDown
    5357            0 :                 | DownloadRemoteLayersTaskState::Completed => {
    5358            0 :                     *status_guard = None;
    5359            0 :                 }
    5360              :             }
    5361            0 :         }
    5362              : 
    5363            0 :         let self_clone = Arc::clone(&self);
    5364            0 :         let task_id = task_mgr::spawn(
    5365            0 :             task_mgr::BACKGROUND_RUNTIME.handle(),
    5366            0 :             task_mgr::TaskKind::DownloadAllRemoteLayers,
    5367            0 :             self.tenant_shard_id,
    5368            0 :             Some(self.timeline_id),
    5369            0 :             "download all remote layers task",
    5370            0 :             async move {
    5371            0 :                 self_clone.download_all_remote_layers(request).await;
    5372            0 :                 let mut status_guard = self_clone.download_all_remote_layers_task_info.write().unwrap();
    5373            0 :                  match &mut *status_guard {
    5374              :                     None => {
    5375            0 :                         warn!("tasks status is supposed to be Some(), since we are running");
    5376              :                     }
    5377            0 :                     Some(st) => {
    5378            0 :                         let exp_task_id = format!("{}", task_mgr::current_task_id().unwrap());
    5379            0 :                         if st.task_id != exp_task_id {
    5380            0 :                             warn!("task id changed while we were still running, expecting {} but have {}", exp_task_id, st.task_id);
    5381            0 :                         } else {
    5382            0 :                             st.state = DownloadRemoteLayersTaskState::Completed;
    5383            0 :                         }
    5384              :                     }
    5385              :                 };
    5386            0 :                 Ok(())
    5387            0 :             }
    5388            0 :             .instrument(info_span!(parent: None, "download_all_remote_layers", tenant_id = %self.tenant_shard_id.tenant_id, shard_id = %self.tenant_shard_id.shard_slug(), timeline_id = %self.timeline_id))
    5389              :         );
    5390              : 
    5391            0 :         let initial_info = DownloadRemoteLayersTaskInfo {
    5392            0 :             task_id: format!("{task_id}"),
    5393            0 :             state: DownloadRemoteLayersTaskState::Running,
    5394            0 :             total_layer_count: 0,
    5395            0 :             successful_download_count: 0,
    5396            0 :             failed_download_count: 0,
    5397            0 :         };
    5398            0 :         *status_guard = Some(initial_info.clone());
    5399            0 : 
    5400            0 :         Ok(initial_info)
    5401            0 :     }
    5402              : 
    5403            0 :     async fn download_all_remote_layers(
    5404            0 :         self: &Arc<Self>,
    5405            0 :         request: DownloadRemoteLayersTaskSpawnRequest,
    5406            0 :     ) {
    5407              :         use pageserver_api::models::DownloadRemoteLayersTaskState;
    5408              : 
    5409            0 :         let remaining = {
    5410            0 :             let guard = self.layers.read().await;
    5411            0 :             let Ok(lm) = guard.layer_map() else {
    5412              :                 // technically here we could look into iterating accessible layers, but downloading
    5413              :                 // all layers of a shutdown timeline makes no sense regardless.
    5414            0 :                 tracing::info!("attempted to download all layers of shutdown timeline");
    5415            0 :                 return;
    5416              :             };
    5417            0 :             lm.iter_historic_layers()
    5418            0 :                 .map(|desc| guard.get_from_desc(&desc))
    5419            0 :                 .collect::<Vec<_>>()
    5420            0 :         };
    5421            0 :         let total_layer_count = remaining.len();
    5422              : 
    5423              :         macro_rules! lock_status {
    5424              :             ($st:ident) => {
    5425              :                 let mut st = self.download_all_remote_layers_task_info.write().unwrap();
    5426              :                 let st = st
    5427              :                     .as_mut()
    5428              :                     .expect("this function is only called after the task has been spawned");
    5429              :                 assert_eq!(
    5430              :                     st.task_id,
    5431              :                     format!(
    5432              :                         "{}",
    5433              :                         task_mgr::current_task_id().expect("we run inside a task_mgr task")
    5434              :                     )
    5435              :                 );
    5436              :                 let $st = st;
    5437              :             };
    5438              :         }
    5439              : 
    5440              :         {
    5441            0 :             lock_status!(st);
    5442            0 :             st.total_layer_count = total_layer_count as u64;
    5443            0 :         }
    5444            0 : 
    5445            0 :         let mut remaining = remaining.into_iter();
    5446            0 :         let mut have_remaining = true;
    5447            0 :         let mut js = tokio::task::JoinSet::new();
    5448            0 : 
    5449            0 :         let cancel = task_mgr::shutdown_token();
    5450            0 : 
    5451            0 :         let limit = request.max_concurrent_downloads;
    5452              : 
    5453              :         loop {
    5454            0 :             while js.len() < limit.get() && have_remaining && !cancel.is_cancelled() {
    5455            0 :                 let Some(next) = remaining.next() else {
    5456            0 :                     have_remaining = false;
    5457            0 :                     break;
    5458              :                 };
    5459              : 
    5460            0 :                 let span = tracing::info_span!("download", layer = %next);
    5461              : 
    5462            0 :                 js.spawn(
    5463            0 :                     async move {
    5464            0 :                         let res = next.download().await;
    5465            0 :                         (next, res)
    5466            0 :                     }
    5467            0 :                     .instrument(span),
    5468            0 :                 );
    5469            0 :             }
    5470              : 
    5471            0 :             while let Some(res) = js.join_next().await {
    5472            0 :                 match res {
    5473              :                     Ok((_, Ok(_))) => {
    5474            0 :                         lock_status!(st);
    5475            0 :                         st.successful_download_count += 1;
    5476              :                     }
    5477            0 :                     Ok((layer, Err(e))) => {
    5478            0 :                         tracing::error!(%layer, "download failed: {e:#}");
    5479            0 :                         lock_status!(st);
    5480            0 :                         st.failed_download_count += 1;
    5481              :                     }
    5482            0 :                     Err(je) if je.is_cancelled() => unreachable!("not used here"),
    5483            0 :                     Err(je) if je.is_panic() => {
    5484            0 :                         lock_status!(st);
    5485            0 :                         st.failed_download_count += 1;
    5486              :                     }
    5487            0 :                     Err(je) => tracing::warn!("unknown joinerror: {je:?}"),
    5488              :                 }
    5489              :             }
    5490              : 
    5491            0 :             if js.is_empty() && (!have_remaining || cancel.is_cancelled()) {
    5492            0 :                 break;
    5493            0 :             }
    5494              :         }
    5495              : 
    5496              :         {
    5497            0 :             lock_status!(st);
    5498            0 :             st.state = DownloadRemoteLayersTaskState::Completed;
    5499              :         }
    5500            0 :     }
    5501              : 
    5502            0 :     pub(crate) fn get_download_all_remote_layers_task_info(
    5503            0 :         &self,
    5504            0 :     ) -> Option<DownloadRemoteLayersTaskInfo> {
    5505            0 :         self.download_all_remote_layers_task_info
    5506            0 :             .read()
    5507            0 :             .unwrap()
    5508            0 :             .clone()
    5509            0 :     }
    5510              : }
    5511              : 
    5512              : impl Timeline {
    5513              :     /// Returns non-remote layers for eviction.
    5514            0 :     pub(crate) async fn get_local_layers_for_disk_usage_eviction(&self) -> DiskUsageEvictionInfo {
    5515            0 :         let guard = self.layers.read().await;
    5516            0 :         let mut max_layer_size: Option<u64> = None;
    5517            0 : 
    5518            0 :         let resident_layers = guard
    5519            0 :             .likely_resident_layers()
    5520            0 :             .map(|layer| {
    5521            0 :                 let file_size = layer.layer_desc().file_size;
    5522            0 :                 max_layer_size = max_layer_size.map_or(Some(file_size), |m| Some(m.max(file_size)));
    5523            0 : 
    5524            0 :                 let last_activity_ts = layer.latest_activity();
    5525            0 : 
    5526            0 :                 EvictionCandidate {
    5527            0 :                     layer: layer.to_owned().into(),
    5528            0 :                     last_activity_ts,
    5529            0 :                     relative_last_activity: finite_f32::FiniteF32::ZERO,
    5530            0 :                     visibility: layer.visibility(),
    5531            0 :                 }
    5532            0 :             })
    5533            0 :             .collect();
    5534            0 : 
    5535            0 :         DiskUsageEvictionInfo {
    5536            0 :             max_layer_size,
    5537            0 :             resident_layers,
    5538            0 :         }
    5539            0 :     }
    5540              : 
    5541         1730 :     pub(crate) fn get_shard_index(&self) -> ShardIndex {
    5542         1730 :         ShardIndex {
    5543         1730 :             shard_number: self.tenant_shard_id.shard_number,
    5544         1730 :             shard_count: self.tenant_shard_id.shard_count,
    5545         1730 :         }
    5546         1730 :     }
    5547              : 
    5548              :     /// Persistently blocks gc for `Manual` reason.
    5549              :     ///
    5550              :     /// Returns true if no such block existed before, false otherwise.
    5551            0 :     pub(crate) async fn block_gc(&self, tenant: &super::Tenant) -> anyhow::Result<bool> {
    5552              :         use crate::tenant::remote_timeline_client::index::GcBlockingReason;
    5553            0 :         assert_eq!(self.tenant_shard_id, tenant.tenant_shard_id);
    5554            0 :         tenant.gc_block.insert(self, GcBlockingReason::Manual).await
    5555            0 :     }
    5556              : 
    5557              :     /// Persistently unblocks gc for `Manual` reason.
    5558            0 :     pub(crate) async fn unblock_gc(&self, tenant: &super::Tenant) -> anyhow::Result<()> {
    5559              :         use crate::tenant::remote_timeline_client::index::GcBlockingReason;
    5560            0 :         assert_eq!(self.tenant_shard_id, tenant.tenant_shard_id);
    5561            0 :         tenant.gc_block.remove(self, GcBlockingReason::Manual).await
    5562            0 :     }
    5563              : 
    5564              :     #[cfg(test)]
    5565           40 :     pub(super) fn force_advance_lsn(self: &Arc<Timeline>, new_lsn: Lsn) {
    5566           40 :         self.last_record_lsn.advance(new_lsn);
    5567           40 :     }
    5568              : 
    5569              :     #[cfg(test)]
    5570            2 :     pub(super) fn force_set_disk_consistent_lsn(&self, new_value: Lsn) {
    5571            2 :         self.disk_consistent_lsn.store(new_value);
    5572            2 :     }
    5573              : 
    5574              :     /// Force create an image layer and place it into the layer map.
    5575              :     ///
    5576              :     /// DO NOT use this function directly. Use [`Tenant::branch_timeline_test_with_layers`]
    5577              :     /// or [`Tenant::create_test_timeline_with_layers`] to ensure all these layers are
    5578              :     /// placed into the layer map in one run AND be validated.
    5579              :     #[cfg(test)]
    5580           52 :     pub(super) async fn force_create_image_layer(
    5581           52 :         self: &Arc<Timeline>,
    5582           52 :         lsn: Lsn,
    5583           52 :         mut images: Vec<(Key, Bytes)>,
    5584           52 :         check_start_lsn: Option<Lsn>,
    5585           52 :         ctx: &RequestContext,
    5586           52 :     ) -> anyhow::Result<()> {
    5587           52 :         let last_record_lsn = self.get_last_record_lsn();
    5588           52 :         assert!(
    5589           52 :             lsn <= last_record_lsn,
    5590            0 :             "advance last record lsn before inserting a layer, lsn={lsn}, last_record_lsn={last_record_lsn}"
    5591              :         );
    5592           52 :         if let Some(check_start_lsn) = check_start_lsn {
    5593           52 :             assert!(lsn >= check_start_lsn);
    5594            0 :         }
    5595          126 :         images.sort_unstable_by(|(ka, _), (kb, _)| ka.cmp(kb));
    5596           52 :         let min_key = *images.first().map(|(k, _)| k).unwrap();
    5597           52 :         let end_key = images.last().map(|(k, _)| k).unwrap().next();
    5598           52 :         let mut image_layer_writer = ImageLayerWriter::new(
    5599           52 :             self.conf,
    5600           52 :             self.timeline_id,
    5601           52 :             self.tenant_shard_id,
    5602           52 :             &(min_key..end_key),
    5603           52 :             lsn,
    5604           52 :             ctx,
    5605           52 :         )
    5606           26 :         .await?;
    5607          230 :         for (key, img) in images {
    5608          178 :             image_layer_writer.put_image(key, img, ctx).await?;
    5609              :         }
    5610          104 :         let (desc, path) = image_layer_writer.finish(ctx).await?;
    5611           52 :         let image_layer = Layer::finish_creating(self.conf, self, desc, &path)?;
    5612           52 :         info!("force created image layer {}", image_layer.local_path());
    5613              :         {
    5614           52 :             let mut guard = self.layers.write().await;
    5615           52 :             guard.open_mut().unwrap().force_insert_layer(image_layer);
    5616           52 :         }
    5617           52 : 
    5618           52 :         Ok(())
    5619           52 :     }
    5620              : 
    5621              :     /// Force create a delta layer and place it into the layer map.
    5622              :     ///
    5623              :     /// DO NOT use this function directly. Use [`Tenant::branch_timeline_test_with_layers`]
    5624              :     /// or [`Tenant::create_test_timeline_with_layers`] to ensure all these layers are
    5625              :     /// placed into the layer map in one run AND be validated.
    5626              :     #[cfg(test)]
    5627           74 :     pub(super) async fn force_create_delta_layer(
    5628           74 :         self: &Arc<Timeline>,
    5629           74 :         mut deltas: DeltaLayerTestDesc,
    5630           74 :         check_start_lsn: Option<Lsn>,
    5631           74 :         ctx: &RequestContext,
    5632           74 :     ) -> anyhow::Result<()> {
    5633           74 :         let last_record_lsn = self.get_last_record_lsn();
    5634           74 :         deltas
    5635           74 :             .data
    5636          124 :             .sort_unstable_by(|(ka, la, _), (kb, lb, _)| (ka, la).cmp(&(kb, lb)));
    5637           74 :         assert!(deltas.data.first().unwrap().0 >= deltas.key_range.start);
    5638           74 :         assert!(deltas.data.last().unwrap().0 < deltas.key_range.end);
    5639          272 :         for (_, lsn, _) in &deltas.data {
    5640          198 :             assert!(deltas.lsn_range.start <= *lsn && *lsn < deltas.lsn_range.end);
    5641              :         }
    5642           74 :         assert!(
    5643           74 :             deltas.lsn_range.end <= last_record_lsn,
    5644            0 :             "advance last record lsn before inserting a layer, end_lsn={}, last_record_lsn={}",
    5645              :             deltas.lsn_range.end,
    5646              :             last_record_lsn
    5647              :         );
    5648           74 :         if let Some(check_start_lsn) = check_start_lsn {
    5649           74 :             assert!(deltas.lsn_range.start >= check_start_lsn);
    5650            0 :         }
    5651           74 :         let mut delta_layer_writer = DeltaLayerWriter::new(
    5652           74 :             self.conf,
    5653           74 :             self.timeline_id,
    5654           74 :             self.tenant_shard_id,
    5655           74 :             deltas.key_range.start,
    5656           74 :             deltas.lsn_range,
    5657           74 :             ctx,
    5658           74 :         )
    5659           37 :         .await?;
    5660          272 :         for (key, lsn, val) in deltas.data {
    5661          198 :             delta_layer_writer.put_value(key, lsn, val, ctx).await?;
    5662              :         }
    5663          185 :         let (desc, path) = delta_layer_writer.finish(deltas.key_range.end, ctx).await?;
    5664           74 :         let delta_layer = Layer::finish_creating(self.conf, self, desc, &path)?;
    5665           74 :         info!("force created delta layer {}", delta_layer.local_path());
    5666              :         {
    5667           74 :             let mut guard = self.layers.write().await;
    5668           74 :             guard.open_mut().unwrap().force_insert_layer(delta_layer);
    5669           74 :         }
    5670           74 : 
    5671           74 :         Ok(())
    5672           74 :     }
    5673              : 
    5674              :     /// Return all keys at the LSN in the image layers
    5675              :     #[cfg(test)]
    5676            6 :     pub(crate) async fn inspect_image_layers(
    5677            6 :         self: &Arc<Timeline>,
    5678            6 :         lsn: Lsn,
    5679            6 :         ctx: &RequestContext,
    5680            6 :     ) -> anyhow::Result<Vec<(Key, Bytes)>> {
    5681            6 :         let mut all_data = Vec::new();
    5682            6 :         let guard = self.layers.read().await;
    5683           34 :         for layer in guard.layer_map()?.iter_historic_layers() {
    5684           34 :             if !layer.is_delta() && layer.image_layer_lsn() == lsn {
    5685            8 :                 let layer = guard.get_from_desc(&layer);
    5686            8 :                 let mut reconstruct_data = ValuesReconstructState::default();
    5687            8 :                 layer
    5688            8 :                     .get_values_reconstruct_data(
    5689            8 :                         KeySpace::single(Key::MIN..Key::MAX),
    5690            8 :                         lsn..Lsn(lsn.0 + 1),
    5691            8 :                         &mut reconstruct_data,
    5692            8 :                         ctx,
    5693            8 :                     )
    5694           13 :                     .await?;
    5695           74 :                 for (k, v) in reconstruct_data.keys {
    5696           66 :                     all_data.push((k, v?.img.unwrap().1));
    5697              :                 }
    5698           26 :             }
    5699              :         }
    5700            6 :         all_data.sort();
    5701            6 :         Ok(all_data)
    5702            6 :     }
    5703              : 
    5704              :     /// Get all historic layer descriptors in the layer map
    5705              :     #[cfg(test)]
    5706           12 :     pub(crate) async fn inspect_historic_layers(
    5707           12 :         self: &Arc<Timeline>,
    5708           12 :     ) -> anyhow::Result<Vec<super::storage_layer::PersistentLayerKey>> {
    5709           12 :         let mut layers = Vec::new();
    5710           12 :         let guard = self.layers.read().await;
    5711           70 :         for layer in guard.layer_map()?.iter_historic_layers() {
    5712           70 :             layers.push(layer.key());
    5713           70 :         }
    5714           12 :         Ok(layers)
    5715           12 :     }
    5716              : 
    5717              :     #[cfg(test)]
    5718           10 :     pub(crate) fn add_extra_test_dense_keyspace(&self, ks: KeySpace) {
    5719           10 :         let mut keyspace = self.extra_test_dense_keyspace.load().as_ref().clone();
    5720           10 :         keyspace.merge(&ks);
    5721           10 :         self.extra_test_dense_keyspace.store(Arc::new(keyspace));
    5722           10 :     }
    5723              : }
    5724              : 
    5725              : /// Tracking writes ingestion does to a particular in-memory layer.
    5726              : ///
    5727              : /// Cleared upon freezing a layer.
    5728              : pub(crate) struct TimelineWriterState {
    5729              :     open_layer: Arc<InMemoryLayer>,
    5730              :     current_size: u64,
    5731              :     // Previous Lsn which passed through
    5732              :     prev_lsn: Option<Lsn>,
    5733              :     // Largest Lsn which passed through the current writer
    5734              :     max_lsn: Option<Lsn>,
    5735              :     // Cached details of the last freeze. Avoids going trough the atomic/lock on every put.
    5736              :     cached_last_freeze_at: Lsn,
    5737              : }
    5738              : 
    5739              : impl TimelineWriterState {
    5740         1268 :     fn new(open_layer: Arc<InMemoryLayer>, current_size: u64, last_freeze_at: Lsn) -> Self {
    5741         1268 :         Self {
    5742         1268 :             open_layer,
    5743         1268 :             current_size,
    5744         1268 :             prev_lsn: None,
    5745         1268 :             max_lsn: None,
    5746         1268 :             cached_last_freeze_at: last_freeze_at,
    5747         1268 :         }
    5748         1268 :     }
    5749              : }
    5750              : 
    5751              : /// Various functions to mutate the timeline.
    5752              : // TODO Currently, Deref is used to allow easy access to read methods from this trait.
    5753              : // This is probably considered a bad practice in Rust and should be fixed eventually,
    5754              : // but will cause large code changes.
    5755              : pub(crate) struct TimelineWriter<'a> {
    5756              :     tl: &'a Timeline,
    5757              :     write_guard: tokio::sync::MutexGuard<'a, Option<TimelineWriterState>>,
    5758              : }
    5759              : 
    5760              : impl Deref for TimelineWriter<'_> {
    5761              :     type Target = Timeline;
    5762              : 
    5763      4807192 :     fn deref(&self) -> &Self::Target {
    5764      4807192 :         self.tl
    5765      4807192 :     }
    5766              : }
    5767              : 
    5768              : #[derive(PartialEq)]
    5769              : enum OpenLayerAction {
    5770              :     Roll,
    5771              :     Open,
    5772              :     None,
    5773              : }
    5774              : 
    5775              : impl<'a> TimelineWriter<'a> {
    5776      4804204 :     async fn handle_open_layer_action(
    5777      4804204 :         &mut self,
    5778      4804204 :         at: Lsn,
    5779      4804204 :         action: OpenLayerAction,
    5780      4804204 :         ctx: &RequestContext,
    5781      4804204 :     ) -> anyhow::Result<&Arc<InMemoryLayer>> {
    5782      4804204 :         match action {
    5783              :             OpenLayerAction::Roll => {
    5784           80 :                 let freeze_at = self.write_guard.as_ref().unwrap().max_lsn.unwrap();
    5785           80 :                 self.roll_layer(freeze_at).await?;
    5786           80 :                 self.open_layer(at, ctx).await?;
    5787              :             }
    5788         1188 :             OpenLayerAction::Open => self.open_layer(at, ctx).await?,
    5789              :             OpenLayerAction::None => {
    5790      4802936 :                 assert!(self.write_guard.is_some());
    5791              :             }
    5792              :         }
    5793              : 
    5794      4804204 :         Ok(&self.write_guard.as_ref().unwrap().open_layer)
    5795      4804204 :     }
    5796              : 
    5797         1268 :     async fn open_layer(&mut self, at: Lsn, ctx: &RequestContext) -> anyhow::Result<()> {
    5798         1268 :         let layer = self
    5799         1268 :             .tl
    5800         1268 :             .get_layer_for_write(at, &self.write_guard, ctx)
    5801          719 :             .await?;
    5802         1268 :         let initial_size = layer.size().await?;
    5803              : 
    5804         1268 :         let last_freeze_at = self.last_freeze_at.load();
    5805         1268 :         self.write_guard.replace(TimelineWriterState::new(
    5806         1268 :             layer,
    5807         1268 :             initial_size,
    5808         1268 :             last_freeze_at,
    5809         1268 :         ));
    5810         1268 : 
    5811         1268 :         Ok(())
    5812         1268 :     }
    5813              : 
    5814           80 :     async fn roll_layer(&mut self, freeze_at: Lsn) -> Result<(), FlushLayerError> {
    5815           80 :         let current_size = self.write_guard.as_ref().unwrap().current_size;
    5816           80 : 
    5817           80 :         // self.write_guard will be taken by the freezing
    5818           80 :         self.tl
    5819           80 :             .freeze_inmem_layer_at(freeze_at, &mut self.write_guard)
    5820            8 :             .await?;
    5821              : 
    5822           80 :         assert!(self.write_guard.is_none());
    5823              : 
    5824           80 :         if current_size >= self.get_checkpoint_distance() * 2 {
    5825            0 :             warn!("Flushed oversized open layer with size {}", current_size)
    5826           80 :         }
    5827              : 
    5828           80 :         Ok(())
    5829           80 :     }
    5830              : 
    5831      4804204 :     fn get_open_layer_action(&self, lsn: Lsn, new_value_size: u64) -> OpenLayerAction {
    5832      4804204 :         let state = &*self.write_guard;
    5833      4804204 :         let Some(state) = &state else {
    5834         1188 :             return OpenLayerAction::Open;
    5835              :         };
    5836              : 
    5837              :         #[cfg(feature = "testing")]
    5838      4803016 :         if state.cached_last_freeze_at < self.tl.last_freeze_at.load() {
    5839              :             // this check and assertion are not really needed because
    5840              :             // LayerManager::try_freeze_in_memory_layer will always clear out the
    5841              :             // TimelineWriterState if something is frozen. however, we can advance last_freeze_at when there
    5842              :             // is no TimelineWriterState.
    5843            0 :             assert!(
    5844            0 :                 state.open_layer.end_lsn.get().is_some(),
    5845            0 :                 "our open_layer must be outdated"
    5846              :             );
    5847              : 
    5848              :             // this would be a memory leak waiting to happen because the in-memory layer always has
    5849              :             // an index
    5850            0 :             panic!("BUG: TimelineWriterState held on to frozen in-memory layer.");
    5851      4803016 :         }
    5852      4803016 : 
    5853      4803016 :         if state.prev_lsn == Some(lsn) {
    5854              :             // Rolling mid LSN is not supported by [downstream code].
    5855              :             // Hence, only roll at LSN boundaries.
    5856              :             //
    5857              :             // [downstream code]: https://github.com/neondatabase/neon/pull/7993#discussion_r1633345422
    5858            6 :             return OpenLayerAction::None;
    5859      4803010 :         }
    5860      4803010 : 
    5861      4803010 :         if state.current_size == 0 {
    5862              :             // Don't roll empty layers
    5863            0 :             return OpenLayerAction::None;
    5864      4803010 :         }
    5865      4803010 : 
    5866      4803010 :         if self.tl.should_roll(
    5867      4803010 :             state.current_size,
    5868      4803010 :             state.current_size + new_value_size,
    5869      4803010 :             self.get_checkpoint_distance(),
    5870      4803010 :             lsn,
    5871      4803010 :             state.cached_last_freeze_at,
    5872      4803010 :             state.open_layer.get_opened_at(),
    5873      4803010 :         ) {
    5874           80 :             OpenLayerAction::Roll
    5875              :         } else {
    5876      4802930 :             OpenLayerAction::None
    5877              :         }
    5878      4804204 :     }
    5879              : 
    5880              :     /// Put a batch of keys at the specified Lsns.
    5881      4804202 :     pub(crate) async fn put_batch(
    5882      4804202 :         &mut self,
    5883      4804202 :         batch: SerializedValueBatch,
    5884      4804202 :         ctx: &RequestContext,
    5885      4804202 :     ) -> anyhow::Result<()> {
    5886      4804202 :         if batch.is_empty() {
    5887            0 :             return Ok(());
    5888      4804202 :         }
    5889      4804202 : 
    5890      4804202 :         let batch_max_lsn = batch.max_lsn;
    5891      4804202 :         let buf_size: u64 = batch.buffer_size() as u64;
    5892      4804202 : 
    5893      4804202 :         let action = self.get_open_layer_action(batch_max_lsn, buf_size);
    5894      4804202 :         let layer = self
    5895      4804202 :             .handle_open_layer_action(batch_max_lsn, action, ctx)
    5896          727 :             .await?;
    5897              : 
    5898      4804202 :         let res = layer.put_batch(batch, ctx).await;
    5899              : 
    5900      4804202 :         if res.is_ok() {
    5901      4804202 :             // Update the current size only when the entire write was ok.
    5902      4804202 :             // In case of failures, we may have had partial writes which
    5903      4804202 :             // render the size tracking out of sync. That's ok because
    5904      4804202 :             // the checkpoint distance should be significantly smaller
    5905      4804202 :             // than the S3 single shot upload limit of 5GiB.
    5906      4804202 :             let state = self.write_guard.as_mut().unwrap();
    5907      4804202 : 
    5908      4804202 :             state.current_size += buf_size;
    5909      4804202 :             state.prev_lsn = Some(batch_max_lsn);
    5910      4804202 :             state.max_lsn = std::cmp::max(state.max_lsn, Some(batch_max_lsn));
    5911      4804202 :         }
    5912              : 
    5913      4804202 :         res
    5914      4804202 :     }
    5915              : 
    5916              :     #[cfg(test)]
    5917              :     /// Test helper, for tests that would like to poke individual values without composing a batch
    5918      4390154 :     pub(crate) async fn put(
    5919      4390154 :         &mut self,
    5920      4390154 :         key: Key,
    5921      4390154 :         lsn: Lsn,
    5922      4390154 :         value: &Value,
    5923      4390154 :         ctx: &RequestContext,
    5924      4390154 :     ) -> anyhow::Result<()> {
    5925              :         use utils::bin_ser::BeSer;
    5926      4390154 :         if !key.is_valid_key_on_write_path() {
    5927            0 :             bail!(
    5928            0 :                 "the request contains data not supported by pageserver at TimelineWriter::put: {}",
    5929            0 :                 key
    5930            0 :             );
    5931      4390154 :         }
    5932      4390154 :         let val_ser_size = value.serialized_size().unwrap() as usize;
    5933      4390154 :         let batch = SerializedValueBatch::from_values(vec![(
    5934      4390154 :             key.to_compact(),
    5935      4390154 :             lsn,
    5936      4390154 :             val_ser_size,
    5937      4390154 :             value.clone(),
    5938      4390154 :         )]);
    5939      4390154 : 
    5940      4390154 :         self.put_batch(batch, ctx).await
    5941      4390154 :     }
    5942              : 
    5943            2 :     pub(crate) async fn delete_batch(
    5944            2 :         &mut self,
    5945            2 :         batch: &[(Range<Key>, Lsn)],
    5946            2 :         ctx: &RequestContext,
    5947            2 :     ) -> anyhow::Result<()> {
    5948            2 :         if let Some((_, lsn)) = batch.first() {
    5949            2 :             let action = self.get_open_layer_action(*lsn, 0);
    5950            2 :             let layer = self.handle_open_layer_action(*lsn, action, ctx).await?;
    5951            2 :             layer.put_tombstones(batch).await?;
    5952            0 :         }
    5953              : 
    5954            2 :         Ok(())
    5955            2 :     }
    5956              : 
    5957              :     /// Track the end of the latest digested WAL record.
    5958              :     /// Remember the (end of) last valid WAL record remembered in the timeline.
    5959              :     ///
    5960              :     /// Call this after you have finished writing all the WAL up to 'lsn'.
    5961              :     ///
    5962              :     /// 'lsn' must be aligned. This wakes up any wait_lsn() callers waiting for
    5963              :     /// the 'lsn' or anything older. The previous last record LSN is stored alongside
    5964              :     /// the latest and can be read.
    5965      5279064 :     pub(crate) fn finish_write(&self, new_lsn: Lsn) {
    5966      5279064 :         self.tl.finish_write(new_lsn);
    5967      5279064 :     }
    5968              : 
    5969       270570 :     pub(crate) fn update_current_logical_size(&self, delta: i64) {
    5970       270570 :         self.tl.update_current_logical_size(delta)
    5971       270570 :     }
    5972              : }
    5973              : 
    5974              : // We need TimelineWriter to be send in upcoming conversion of
    5975              : // Timeline::layers to tokio::sync::RwLock.
    5976              : #[test]
    5977            2 : fn is_send() {
    5978            2 :     fn _assert_send<T: Send>() {}
    5979            2 :     _assert_send::<TimelineWriter<'_>>();
    5980            2 : }
    5981              : 
    5982              : #[cfg(test)]
    5983              : mod tests {
    5984              :     use pageserver_api::key::Key;
    5985              :     use pageserver_api::value::Value;
    5986              :     use utils::{id::TimelineId, lsn::Lsn};
    5987              : 
    5988              :     use crate::tenant::{
    5989              :         harness::{test_img, TenantHarness},
    5990              :         layer_map::LayerMap,
    5991              :         storage_layer::{Layer, LayerName},
    5992              :         timeline::{DeltaLayerTestDesc, EvictionError},
    5993              :         Timeline,
    5994              :     };
    5995              : 
    5996              :     #[tokio::test]
    5997            2 :     async fn test_heatmap_generation() {
    5998            2 :         let harness = TenantHarness::create("heatmap_generation").await.unwrap();
    5999            2 : 
    6000            2 :         let covered_delta = DeltaLayerTestDesc::new_with_inferred_key_range(
    6001            2 :             Lsn(0x10)..Lsn(0x20),
    6002            2 :             vec![(
    6003            2 :                 Key::from_hex("620000000033333333444444445500000000").unwrap(),
    6004            2 :                 Lsn(0x11),
    6005            2 :                 Value::Image(test_img("foo")),
    6006            2 :             )],
    6007            2 :         );
    6008            2 :         let visible_delta = DeltaLayerTestDesc::new_with_inferred_key_range(
    6009            2 :             Lsn(0x10)..Lsn(0x20),
    6010            2 :             vec![(
    6011            2 :                 Key::from_hex("720000000033333333444444445500000000").unwrap(),
    6012            2 :                 Lsn(0x11),
    6013            2 :                 Value::Image(test_img("foo")),
    6014            2 :             )],
    6015            2 :         );
    6016            2 :         let l0_delta = DeltaLayerTestDesc::new(
    6017            2 :             Lsn(0x20)..Lsn(0x30),
    6018            2 :             Key::from_hex("000000000000000000000000000000000000").unwrap()
    6019            2 :                 ..Key::from_hex("FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF").unwrap(),
    6020            2 :             vec![(
    6021            2 :                 Key::from_hex("720000000033333333444444445500000000").unwrap(),
    6022            2 :                 Lsn(0x25),
    6023            2 :                 Value::Image(test_img("foo")),
    6024            2 :             )],
    6025            2 :         );
    6026            2 :         let delta_layers = vec![
    6027            2 :             covered_delta.clone(),
    6028            2 :             visible_delta.clone(),
    6029            2 :             l0_delta.clone(),
    6030            2 :         ];
    6031            2 : 
    6032            2 :         let image_layer = (
    6033            2 :             Lsn(0x40),
    6034            2 :             vec![(
    6035            2 :                 Key::from_hex("620000000033333333444444445500000000").unwrap(),
    6036            2 :                 test_img("bar"),
    6037            2 :             )],
    6038            2 :         );
    6039            2 :         let image_layers = vec![image_layer];
    6040            2 : 
    6041           20 :         let (tenant, ctx) = harness.load().await;
    6042            2 :         let timeline = tenant
    6043            2 :             .create_test_timeline_with_layers(
    6044            2 :                 TimelineId::generate(),
    6045            2 :                 Lsn(0x10),
    6046            2 :                 14,
    6047            2 :                 &ctx,
    6048            2 :                 delta_layers,
    6049            2 :                 image_layers,
    6050            2 :                 Lsn(0x100),
    6051            2 :             )
    6052           31 :             .await
    6053            2 :             .unwrap();
    6054            2 : 
    6055            2 :         // Layer visibility is an input to heatmap generation, so refresh it first
    6056            2 :         timeline.update_layer_visibility().await.unwrap();
    6057            2 : 
    6058            2 :         let heatmap = timeline
    6059            2 :             .generate_heatmap()
    6060            2 :             .await
    6061            2 :             .expect("Infallible while timeline is not shut down");
    6062            2 : 
    6063            2 :         assert_eq!(heatmap.timeline_id, timeline.timeline_id);
    6064            2 : 
    6065            2 :         // L0 should come last
    6066            2 :         assert_eq!(heatmap.layers.last().unwrap().name, l0_delta.layer_name());
    6067            2 : 
    6068            2 :         let mut last_lsn = Lsn::MAX;
    6069           10 :         for layer in heatmap.layers {
    6070            2 :             // Covered layer should be omitted
    6071            8 :             assert!(layer.name != covered_delta.layer_name());
    6072            2 : 
    6073            8 :             let layer_lsn = match &layer.name {
    6074            4 :                 LayerName::Delta(d) => d.lsn_range.end,
    6075            4 :                 LayerName::Image(i) => i.lsn,
    6076            2 :             };
    6077            2 : 
    6078            2 :             // Apart from L0s, newest Layers should come first
    6079            8 :             if !LayerMap::is_l0(layer.name.key_range(), layer.name.is_delta()) {
    6080            6 :                 assert!(layer_lsn <= last_lsn);
    6081            6 :                 last_lsn = layer_lsn;
    6082            2 :             }
    6083            2 :         }
    6084            2 :     }
    6085              : 
    6086              :     #[tokio::test]
    6087            2 :     async fn two_layer_eviction_attempts_at_the_same_time() {
    6088            2 :         let harness = TenantHarness::create("two_layer_eviction_attempts_at_the_same_time")
    6089            2 :             .await
    6090            2 :             .unwrap();
    6091            2 : 
    6092           20 :         let (tenant, ctx) = harness.load().await;
    6093            2 :         let timeline = tenant
    6094            2 :             .create_test_timeline(TimelineId::generate(), Lsn(0x10), 14, &ctx)
    6095            6 :             .await
    6096            2 :             .unwrap();
    6097            2 : 
    6098            2 :         let layer = find_some_layer(&timeline).await;
    6099            2 :         let layer = layer
    6100            2 :             .keep_resident()
    6101            2 :             .await
    6102            2 :             .expect("no download => no downloading errors")
    6103            2 :             .drop_eviction_guard();
    6104            2 : 
    6105            2 :         let forever = std::time::Duration::from_secs(120);
    6106            2 : 
    6107            2 :         let first = layer.evict_and_wait(forever);
    6108            2 :         let second = layer.evict_and_wait(forever);
    6109            2 : 
    6110            2 :         let (first, second) = tokio::join!(first, second);
    6111            2 : 
    6112            2 :         let res = layer.keep_resident().await;
    6113            2 :         assert!(res.is_none(), "{res:?}");
    6114            2 : 
    6115            2 :         match (first, second) {
    6116            2 :             (Ok(()), Ok(())) => {
    6117            2 :                 // because there are no more timeline locks being taken on eviction path, we can
    6118            2 :                 // witness all three outcomes here.
    6119            2 :             }
    6120            2 :             (Ok(()), Err(EvictionError::NotFound)) | (Err(EvictionError::NotFound), Ok(())) => {
    6121            0 :                 // if one completes before the other, this is fine just as well.
    6122            0 :             }
    6123            2 :             other => unreachable!("unexpected {:?}", other),
    6124            2 :         }
    6125            2 :     }
    6126              : 
    6127            2 :     async fn find_some_layer(timeline: &Timeline) -> Layer {
    6128            2 :         let layers = timeline.layers.read().await;
    6129            2 :         let desc = layers
    6130            2 :             .layer_map()
    6131            2 :             .unwrap()
    6132            2 :             .iter_historic_layers()
    6133            2 :             .next()
    6134            2 :             .expect("must find one layer to evict");
    6135            2 : 
    6136            2 :         layers.get_from_desc(&desc)
    6137            2 :     }
    6138              : }
        

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