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open.go
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open.go
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// Copyright 2012 The LevelDB-Go and Pebble Authors. All rights reserved. Use
// of this source code is governed by a BSD-style license that can be found in
// the LICENSE file.
package pebble
import (
"bytes"
"context"
"encoding/binary"
"fmt"
"io"
"math"
"os"
"slices"
"sync/atomic"
"time"
"github.com/cockroachdb/errors"
"github.com/cockroachdb/errors/oserror"
"github.com/cockroachdb/pebble/batchrepr"
"github.com/cockroachdb/pebble/internal/arenaskl"
"github.com/cockroachdb/pebble/internal/base"
"github.com/cockroachdb/pebble/internal/cache"
"github.com/cockroachdb/pebble/internal/constants"
"github.com/cockroachdb/pebble/internal/invariants"
"github.com/cockroachdb/pebble/internal/manifest"
"github.com/cockroachdb/pebble/internal/manual"
"github.com/cockroachdb/pebble/objstorage"
"github.com/cockroachdb/pebble/objstorage/objstorageprovider"
"github.com/cockroachdb/pebble/objstorage/remote"
"github.com/cockroachdb/pebble/record"
"github.com/cockroachdb/pebble/sstable"
"github.com/cockroachdb/pebble/vfs"
"github.com/cockroachdb/pebble/wal"
"github.com/prometheus/client_golang/prometheus"
)
const (
initialMemTableSize = 256 << 10 // 256 KB
// The max batch size is limited by the uint32 offsets stored in
// internal/batchskl.node, DeferredBatchOp, and flushableBatchEntry.
//
// We limit the size to MaxUint32 (just short of 4GB) so that the exclusive
// end of an allocation fits in uint32.
//
// On 32-bit systems, slices are naturally limited to MaxInt (just short of
// 2GB).
maxBatchSize = constants.MaxUint32OrInt
// The max memtable size is limited by the uint32 offsets stored in
// internal/arenaskl.node, DeferredBatchOp, and flushableBatchEntry.
//
// We limit the size to MaxUint32 (just short of 4GB) so that the exclusive
// end of an allocation fits in uint32.
//
// On 32-bit systems, slices are naturally limited to MaxInt (just short of
// 2GB).
maxMemTableSize = constants.MaxUint32OrInt
)
// TableCacheSize can be used to determine the table
// cache size for a single db, given the maximum open
// files which can be used by a table cache which is
// only used by a single db.
func TableCacheSize(maxOpenFiles int) int {
tableCacheSize := maxOpenFiles - numNonTableCacheFiles
if tableCacheSize < minTableCacheSize {
tableCacheSize = minTableCacheSize
}
return tableCacheSize
}
// Open opens a DB whose files live in the given directory.
func Open(dirname string, opts *Options) (db *DB, err error) {
// Make a copy of the options so that we don't mutate the passed in options.
opts = opts.Clone()
opts = opts.EnsureDefaults()
if err := opts.Validate(); err != nil {
return nil, err
}
if opts.LoggerAndTracer == nil {
opts.LoggerAndTracer = &base.LoggerWithNoopTracer{Logger: opts.Logger}
} else {
opts.Logger = opts.LoggerAndTracer
}
// In all error cases, we return db = nil; this is used by various
// deferred cleanups.
// Open the database and WAL directories first.
walDirname, dataDir, err := prepareAndOpenDirs(dirname, opts)
if err != nil {
return nil, errors.Wrapf(err, "error opening database at %q", dirname)
}
defer func() {
if db == nil {
dataDir.Close()
}
}()
// Lock the database directory.
var fileLock *Lock
if opts.Lock != nil {
// The caller already acquired the database lock. Ensure that the
// directory matches.
if err := opts.Lock.pathMatches(dirname); err != nil {
return nil, err
}
if err := opts.Lock.refForOpen(); err != nil {
return nil, err
}
fileLock = opts.Lock
} else {
fileLock, err = LockDirectory(dirname, opts.FS)
if err != nil {
return nil, err
}
}
defer func() {
if db == nil {
fileLock.Close()
}
}()
// List the directory contents. This also happens to include WAL log files, if
// they are in the same dir, but we will ignore those below. The provider is
// also given this list, but it ignores non sstable files.
ls, err := opts.FS.List(dirname)
if err != nil {
return nil, err
}
// Establish the format major version.
formatVersion, formatVersionMarker, err := lookupFormatMajorVersion(opts.FS, dirname, ls)
if err != nil {
return nil, err
}
defer func() {
if db == nil {
formatVersionMarker.Close()
}
}()
noFormatVersionMarker := formatVersion == FormatDefault
if noFormatVersionMarker {
// We will initialize the store at the minimum possible format, then upgrade
// the format to the desired one. This helps test the format upgrade code.
formatVersion = FormatMinSupported
if opts.Experimental.CreateOnShared != remote.CreateOnSharedNone {
formatVersion = FormatMinForSharedObjects
}
// There is no format version marker file. There are three cases:
// - we are trying to open an existing store that was created at
// FormatMostCompatible (the only one without a version marker file)
// - we are creating a new store;
// - we are retrying a failed creation.
//
// To error in the first case, we set ErrorIfNotPristine.
opts.ErrorIfNotPristine = true
defer func() {
if err != nil && errors.Is(err, ErrDBNotPristine) {
// We must be trying to open an existing store at FormatMostCompatible.
// Correct the error in this case -we
err = errors.Newf(
"pebble: database %q written in format major version 1 which is no longer supported",
dirname)
}
}()
} else {
if opts.Experimental.CreateOnShared != remote.CreateOnSharedNone && formatVersion < FormatMinForSharedObjects {
return nil, errors.Newf(
"pebble: database %q configured with shared objects but written in too old format major version %d",
formatVersion)
}
}
// Find the currently active manifest, if there is one.
manifestMarker, manifestFileNum, manifestExists, err := findCurrentManifest(opts.FS, dirname, ls)
if err != nil {
return nil, errors.Wrapf(err, "pebble: database %q", dirname)
}
defer func() {
if db == nil {
manifestMarker.Close()
}
}()
// Atomic markers may leave behind obsolete files if there's a crash
// mid-update. Clean these up if we're not in read-only mode.
if !opts.ReadOnly {
if err := formatVersionMarker.RemoveObsolete(); err != nil {
return nil, err
}
if err := manifestMarker.RemoveObsolete(); err != nil {
return nil, err
}
}
if opts.Cache == nil {
opts.Cache = cache.New(cacheDefaultSize)
} else {
opts.Cache.Ref()
}
d := &DB{
cacheID: opts.Cache.NewID(),
dirname: dirname,
opts: opts,
cmp: opts.Comparer.Compare,
equal: opts.Comparer.Equal,
merge: opts.Merger.Merge,
split: opts.Comparer.Split,
abbreviatedKey: opts.Comparer.AbbreviatedKey,
largeBatchThreshold: (opts.MemTableSize - uint64(memTableEmptySize)) / 2,
fileLock: fileLock,
dataDir: dataDir,
closed: new(atomic.Value),
closedCh: make(chan struct{}),
}
d.mu.versions = &versionSet{}
d.diskAvailBytes.Store(math.MaxUint64)
defer func() {
// If an error or panic occurs during open, attempt to release the manually
// allocated memory resources. Note that rather than look for an error, we
// look for the return of a nil DB pointer.
if r := recover(); db == nil {
// Release our references to the Cache. Note that both the DB, and
// tableCache have a reference. When we release the reference to
// the tableCache, and if there are no other references to
// the tableCache, then the tableCache will also release its
// reference to the cache.
opts.Cache.Unref()
if d.tableCache != nil {
_ = d.tableCache.close()
}
for _, mem := range d.mu.mem.queue {
switch t := mem.flushable.(type) {
case *memTable:
manual.Free(t.arenaBuf)
t.arenaBuf = nil
}
}
if d.cleanupManager != nil {
d.cleanupManager.Close()
}
if d.objProvider != nil {
d.objProvider.Close()
}
if r != nil {
panic(r)
}
}
}()
d.commit = newCommitPipeline(commitEnv{
logSeqNum: &d.mu.versions.logSeqNum,
visibleSeqNum: &d.mu.versions.visibleSeqNum,
apply: d.commitApply,
write: d.commitWrite,
})
d.mu.nextJobID = 1
d.mu.mem.nextSize = opts.MemTableSize
if d.mu.mem.nextSize > initialMemTableSize {
d.mu.mem.nextSize = initialMemTableSize
}
d.mu.compact.cond.L = &d.mu.Mutex
d.mu.compact.inProgress = make(map[*compaction]struct{})
d.mu.compact.noOngoingFlushStartTime = time.Now()
d.mu.snapshots.init()
// logSeqNum is the next sequence number that will be assigned.
// Start assigning sequence numbers from base.SeqNumStart to leave
// room for reserved sequence numbers (see comments around
// SeqNumStart).
d.mu.versions.logSeqNum.Store(base.SeqNumStart)
d.mu.formatVers.vers.Store(uint64(formatVersion))
d.mu.formatVers.marker = formatVersionMarker
d.timeNow = time.Now
d.openedAt = d.timeNow()
d.mu.Lock()
defer d.mu.Unlock()
jobID := d.newJobIDLocked()
providerSettings := objstorageprovider.Settings{
Logger: opts.Logger,
FS: opts.FS,
FSDirName: dirname,
FSDirInitialListing: ls,
FSCleaner: opts.Cleaner,
NoSyncOnClose: opts.NoSyncOnClose,
BytesPerSync: opts.BytesPerSync,
}
providerSettings.Remote.StorageFactory = opts.Experimental.RemoteStorage
providerSettings.Remote.CreateOnShared = opts.Experimental.CreateOnShared
providerSettings.Remote.CreateOnSharedLocator = opts.Experimental.CreateOnSharedLocator
providerSettings.Remote.CacheSizeBytes = opts.Experimental.SecondaryCacheSizeBytes
d.objProvider, err = objstorageprovider.Open(providerSettings)
if err != nil {
return nil, err
}
if !manifestExists {
// DB does not exist.
if d.opts.ErrorIfNotExists || d.opts.ReadOnly {
return nil, errors.Wrapf(ErrDBDoesNotExist, "dirname=%q", dirname)
}
// Create the DB.
if err := d.mu.versions.create(
jobID, dirname, d.objProvider, opts, manifestMarker, d.FormatMajorVersion, &d.mu.Mutex); err != nil {
return nil, err
}
} else {
if opts.ErrorIfExists {
return nil, errors.Wrapf(ErrDBAlreadyExists, "dirname=%q", dirname)
}
// Load the version set.
if err := d.mu.versions.load(
dirname, d.objProvider, opts, manifestFileNum, manifestMarker, d.FormatMajorVersion, &d.mu.Mutex); err != nil {
return nil, err
}
if opts.ErrorIfNotPristine {
liveFileNums := make(map[base.DiskFileNum]struct{})
d.mu.versions.addLiveFileNums(liveFileNums)
if len(liveFileNums) != 0 {
return nil, errors.Wrapf(ErrDBNotPristine, "dirname=%q", dirname)
}
}
}
// In read-only mode, we replay directly into the mutable memtable but never
// flush it. We need to delay creation of the memtable until we know the
// sequence number of the first batch that will be inserted.
if !d.opts.ReadOnly {
var entry *flushableEntry
d.mu.mem.mutable, entry = d.newMemTable(0 /* logNum */, d.mu.versions.logSeqNum.Load())
d.mu.mem.queue = append(d.mu.mem.queue, entry)
}
d.mu.log.metrics.fsyncLatency = prometheus.NewHistogram(prometheus.HistogramOpts{
Buckets: FsyncLatencyBuckets,
})
walOpts := wal.Options{
Primary: wal.Dir{FS: opts.FS, Dirname: walDirname},
Secondary: wal.Dir{},
MinUnflushedWALNum: wal.NumWAL(d.mu.versions.minUnflushedLogNum),
MaxNumRecyclableLogs: opts.MemTableStopWritesThreshold + 1,
NoSyncOnClose: opts.NoSyncOnClose,
BytesPerSync: opts.WALBytesPerSync,
PreallocateSize: d.walPreallocateSize,
MinSyncInterval: opts.WALMinSyncInterval,
FsyncLatency: d.mu.log.metrics.fsyncLatency,
QueueSemChan: d.commit.logSyncQSem,
Logger: opts.Logger,
EventListener: walEventListenerAdaptor{l: opts.EventListener},
}
if opts.WALFailover != nil {
walOpts.Secondary = opts.WALFailover.Secondary
walOpts.FailoverOptions = opts.WALFailover.FailoverOptions
}
walDirs := append(walOpts.Dirs(), opts.WALRecoveryDirs...)
wals, err := wal.Scan(walDirs...)
if err != nil {
return nil, err
}
walManager, err := wal.Init(walOpts, wals)
if err != nil {
return nil, err
}
defer func() {
if db == nil {
walManager.Close()
}
}()
d.mu.log.manager = walManager
d.cleanupManager = openCleanupManager(opts, d.objProvider, d.onObsoleteTableDelete, d.getDeletionPacerInfo)
if manifestExists && !opts.DisableConsistencyCheck {
curVersion := d.mu.versions.currentVersion()
if err := checkConsistency(curVersion, dirname, d.objProvider); err != nil {
return nil, err
}
}
tableCacheSize := TableCacheSize(opts.MaxOpenFiles)
d.tableCache = newTableCacheContainer(
opts.TableCache, d.cacheID, d.objProvider, d.opts, tableCacheSize,
&sstable.CategoryStatsCollector{})
d.newIters = d.tableCache.newIters
d.tableNewRangeKeyIter = tableNewRangeKeyIter(context.TODO(), d.newIters)
var previousOptionsFileNum base.DiskFileNum
var previousOptionsFilename string
for _, filename := range ls {
ft, fn, ok := base.ParseFilename(opts.FS, filename)
if !ok {
continue
}
// Don't reuse any obsolete file numbers to avoid modifying an
// ingested sstable's original external file.
d.mu.versions.markFileNumUsed(fn)
switch ft {
case fileTypeLog:
// Ignore.
case fileTypeOptions:
if previousOptionsFileNum < fn {
previousOptionsFileNum = fn
previousOptionsFilename = filename
}
case fileTypeTemp, fileTypeOldTemp:
if !d.opts.ReadOnly {
// Some codepaths write to a temporary file and then
// rename it to its final location when complete. A
// temp file is leftover if a process exits before the
// rename. Remove it.
err := opts.FS.Remove(opts.FS.PathJoin(dirname, filename))
if err != nil {
return nil, err
}
}
}
}
if n := len(wals); n > 0 {
// Don't reuse any obsolete file numbers to avoid modifying an
// ingested sstable's original external file.
d.mu.versions.markFileNumUsed(base.DiskFileNum(wals[n-1].Num))
}
// Ratchet d.mu.versions.nextFileNum ahead of all known objects in the
// objProvider. This avoids FileNum collisions with obsolete sstables.
objects := d.objProvider.List()
for _, obj := range objects {
d.mu.versions.markFileNumUsed(obj.DiskFileNum)
}
// Validate the most-recent OPTIONS file, if there is one.
if previousOptionsFilename != "" {
path := opts.FS.PathJoin(dirname, previousOptionsFilename)
previousOptions, err := readOptionsFile(opts, path)
if err != nil {
return nil, err
}
if err := opts.CheckCompatibility(previousOptions); err != nil {
return nil, err
}
}
// Replay any newer log files than the ones named in the manifest.
var replayWALs wal.Logs
for i, w := range wals {
if base.DiskFileNum(w.Num) >= d.mu.versions.minUnflushedLogNum {
replayWALs = wals[i:]
break
}
}
var ve versionEdit
var toFlush flushableList
for i, lf := range replayWALs {
// WALs other than the last one would have been closed cleanly.
//
// Note: we used to never require strict WAL tails when reading from older
// versions: RocksDB 6.2.1 and the version of Pebble included in CockroachDB
// 20.1 do not guarantee that closed WALs end cleanly. But the earliest
// compatible Pebble format is newer and guarantees a clean EOF.
strictWALTail := i < len(replayWALs)-1
flush, maxSeqNum, err := d.replayWAL(jobID, &ve, lf, strictWALTail)
if err != nil {
return nil, err
}
toFlush = append(toFlush, flush...)
if d.mu.versions.logSeqNum.Load() < maxSeqNum {
d.mu.versions.logSeqNum.Store(maxSeqNum)
}
}
d.mu.versions.visibleSeqNum.Store(d.mu.versions.logSeqNum.Load())
if !d.opts.ReadOnly {
// Create an empty .log file.
newLogNum := d.mu.versions.getNextDiskFileNum()
// This logic is slightly different than RocksDB's. Specifically, RocksDB
// sets MinUnflushedLogNum to max-recovered-log-num + 1. We set it to the
// newLogNum. There should be no difference in using either value.
ve.MinUnflushedLogNum = newLogNum
// Create the manifest with the updated MinUnflushedLogNum before
// creating the new log file. If we created the log file first, a
// crash before the manifest is synced could leave two WALs with
// unclean tails.
d.mu.versions.logLock()
if err := d.mu.versions.logAndApply(jobID, &ve, newFileMetrics(ve.NewFiles), false /* forceRotation */, func() []compactionInfo {
return nil
}); err != nil {
return nil, err
}
for _, entry := range toFlush {
entry.readerUnrefLocked(true)
}
d.mu.log.writer, err = d.mu.log.manager.Create(wal.NumWAL(newLogNum), int(jobID))
if err != nil {
return nil, err
}
// This isn't strictly necessary as we don't use the log number for
// memtables being flushed, only for the next unflushed memtable.
d.mu.mem.queue[len(d.mu.mem.queue)-1].logNum = newLogNum
}
d.updateReadStateLocked(d.opts.DebugCheck)
if !d.opts.ReadOnly {
// If the Options specify a format major version higher than the
// loaded database's, upgrade it. If this is a new database, this
// code path also performs an initial upgrade from the starting
// implicit MinSupported version.
//
// We ratchet the version this far into Open so that migrations have a read
// state available. Note that this also results in creating/updating the
// format version marker file.
if opts.FormatMajorVersion > d.FormatMajorVersion() {
if err := d.ratchetFormatMajorVersionLocked(opts.FormatMajorVersion); err != nil {
return nil, err
}
} else if noFormatVersionMarker {
// We are creating a new store. Create the format version marker file.
if err := d.writeFormatVersionMarker(d.FormatMajorVersion()); err != nil {
return nil, err
}
}
// Write the current options to disk.
d.optionsFileNum = d.mu.versions.getNextDiskFileNum()
tmpPath := base.MakeFilepath(opts.FS, dirname, fileTypeTemp, d.optionsFileNum)
optionsPath := base.MakeFilepath(opts.FS, dirname, fileTypeOptions, d.optionsFileNum)
// Write them to a temporary file first, in case we crash before
// we're done. A corrupt options file prevents opening the
// database.
optionsFile, err := opts.FS.Create(tmpPath, vfs.WriteCategoryUnspecified)
if err != nil {
return nil, err
}
serializedOpts := []byte(opts.String())
if _, err := optionsFile.Write(serializedOpts); err != nil {
return nil, errors.CombineErrors(err, optionsFile.Close())
}
d.optionsFileSize = uint64(len(serializedOpts))
if err := optionsFile.Sync(); err != nil {
return nil, errors.CombineErrors(err, optionsFile.Close())
}
if err := optionsFile.Close(); err != nil {
return nil, err
}
// Atomically rename to the OPTIONS-XXXXXX path. This rename is
// guaranteed to be atomic because the destination path does not
// exist.
if err := opts.FS.Rename(tmpPath, optionsPath); err != nil {
return nil, err
}
if err := d.dataDir.Sync(); err != nil {
return nil, err
}
}
if !d.opts.ReadOnly {
d.scanObsoleteFiles(ls)
d.deleteObsoleteFiles(jobID)
}
// Else, nothing is obsolete.
d.mu.tableStats.cond.L = &d.mu.Mutex
d.mu.tableValidation.cond.L = &d.mu.Mutex
if !d.opts.ReadOnly {
d.maybeCollectTableStatsLocked()
}
d.calculateDiskAvailableBytes()
d.maybeScheduleFlush()
d.maybeScheduleCompaction()
// Note: this is a no-op if invariants are disabled or race is enabled.
//
// Setting a finalizer on *DB causes *DB to never be reclaimed and the
// finalizer to never be run. The problem is due to this limitation of
// finalizers mention in the SetFinalizer docs:
//
// If a cyclic structure includes a block with a finalizer, that cycle is
// not guaranteed to be garbage collected and the finalizer is not
// guaranteed to run, because there is no ordering that respects the
// dependencies.
//
// DB has cycles with several of its internal structures: readState,
// newIters, tableCache, versions, etc. Each of this individually cause a
// cycle and prevent the finalizer from being run. But we can workaround this
// finializer limitation by setting a finalizer on another object that is
// tied to the lifetime of DB: the DB.closed atomic.Value.
dPtr := fmt.Sprintf("%p", d)
invariants.SetFinalizer(d.closed, func(obj interface{}) {
v := obj.(*atomic.Value)
if err := v.Load(); err == nil {
fmt.Fprintf(os.Stderr, "%s: unreferenced DB not closed\n", dPtr)
os.Exit(1)
}
})
return d, nil
}
// prepareAndOpenDirs opens the directories for the store (and creates them if
// necessary).
//
// Returns an error if ReadOnly is set and the directories don't exist.
func prepareAndOpenDirs(
dirname string, opts *Options,
) (walDirname string, dataDir vfs.File, err error) {
walDirname = opts.WALDir
if opts.WALDir == "" {
walDirname = dirname
}
// Create directories if needed.
if !opts.ReadOnly {
f, err := mkdirAllAndSyncParents(opts.FS, dirname)
if err != nil {
return "", nil, err
}
f.Close()
if walDirname != dirname {
f, err := mkdirAllAndSyncParents(opts.FS, walDirname)
if err != nil {
return "", nil, err
}
f.Close()
}
if opts.WALFailover != nil {
secondary := opts.WALFailover.Secondary
f, err := mkdirAllAndSyncParents(secondary.FS, secondary.Dirname)
if err != nil {
return "", nil, err
}
f.Close()
}
}
dataDir, err = opts.FS.OpenDir(dirname)
if err != nil {
if opts.ReadOnly && oserror.IsNotExist(err) {
return "", nil, errors.Errorf("pebble: database %q does not exist", dirname)
}
return "", nil, err
}
if opts.ReadOnly && walDirname != dirname {
// Check that the wal dir exists.
walDir, err := opts.FS.OpenDir(walDirname)
if err != nil {
dataDir.Close()
return "", nil, err
}
walDir.Close()
}
return walDirname, dataDir, nil
}
// GetVersion returns the engine version string from the latest options
// file present in dir. Used to check what Pebble or RocksDB version was last
// used to write to the database stored in this directory. An empty string is
// returned if no valid OPTIONS file with a version key was found.
func GetVersion(dir string, fs vfs.FS) (string, error) {
ls, err := fs.List(dir)
if err != nil {
return "", err
}
var version string
lastOptionsSeen := base.DiskFileNum(0)
for _, filename := range ls {
ft, fn, ok := base.ParseFilename(fs, filename)
if !ok {
continue
}
switch ft {
case fileTypeOptions:
// If this file has a higher number than the last options file
// processed, reset version. This is because rocksdb often
// writes multiple options files without deleting previous ones.
// Otherwise, skip parsing this options file.
if fn > lastOptionsSeen {
version = ""
lastOptionsSeen = fn
} else {
continue
}
f, err := fs.Open(fs.PathJoin(dir, filename))
if err != nil {
return "", err
}
data, err := io.ReadAll(f)
f.Close()
if err != nil {
return "", err
}
err = parseOptions(string(data), func(section, key, value string) error {
switch {
case section == "Version":
switch key {
case "pebble_version":
version = value
case "rocksdb_version":
version = fmt.Sprintf("rocksdb v%s", value)
}
}
return nil
})
if err != nil {
return "", err
}
}
}
return version, nil
}
// replayWAL replays the edits in the specified WAL. If the DB is in read
// only mode, then the WALs are replayed into memtables and not flushed. If
// the DB is not in read only mode, then the contents of the WAL are
// guaranteed to be flushed. Note that this flushing is very important for
// guaranteeing durability: the application may have had a number of pending
// fsyncs to the WAL before the process crashed, and those fsyncs may not have
// happened but the corresponding data may now be readable from the WAL (while
// sitting in write-back caches in the kernel or the storage device). By
// reading the WAL (including the non-fsynced data) and then flushing all
// these changes (flush does fsyncs), we are able to guarantee that the
// initial state of the DB is durable.
//
// The toFlush return value is a list of flushables associated with the WAL
// being replayed which will be flushed. Once the version edit has been applied
// to the manifest, it is up to the caller of replayWAL to unreference the
// toFlush flushables returned by replayWAL.
//
// d.mu must be held when calling this, but the mutex may be dropped and
// re-acquired during the course of this method.
func (d *DB) replayWAL(
jobID JobID, ve *versionEdit, ll wal.LogicalLog, strictWALTail bool,
) (toFlush flushableList, maxSeqNum uint64, err error) {
rr := ll.OpenForRead()
defer rr.Close()
var (
b Batch
buf bytes.Buffer
mem *memTable
entry *flushableEntry
offset int64 // byte offset in rr
lastFlushOffset int64
keysReplayed int64 // number of keys replayed
batchesReplayed int64 // number of batches replayed
)
// TODO(jackson): This function is interspersed with panics, in addition to
// corruption error propagation. Audit them to ensure we're truly only
// panicking where the error points to Pebble bug and not user or
// hardware-induced corruption.
if d.opts.ReadOnly {
// In read-only mode, we replay directly into the mutable memtable which will
// never be flushed.
mem = d.mu.mem.mutable
if mem != nil {
entry = d.mu.mem.queue[len(d.mu.mem.queue)-1]
}
}
// Flushes the current memtable, if not nil.
flushMem := func() {
if mem == nil {
return
}
var logSize uint64
if offset >= lastFlushOffset {
logSize = uint64(offset - lastFlushOffset)
}
// Else, this was the initial memtable in the read-only case which must have
// been empty, but we need to flush it since we don't want to add to it later.
lastFlushOffset = offset
entry.logSize = logSize
if !d.opts.ReadOnly {
toFlush = append(toFlush, entry)
}
mem, entry = nil, nil
}
// Creates a new memtable if there is no current memtable.
ensureMem := func(seqNum uint64) {
if mem != nil {
return
}
mem, entry = d.newMemTable(base.DiskFileNum(ll.Num), seqNum)
if d.opts.ReadOnly {
d.mu.mem.mutable = mem
d.mu.mem.queue = append(d.mu.mem.queue, entry)
}
}
// updateVE is used to update ve with information about new files created
// during the flush of any flushable not of type ingestedFlushable. For the
// flushable of type ingestedFlushable we use custom handling below.
updateVE := func() error {
// TODO(bananabrick): See if we can use the actual base level here,
// instead of using 1.
c, err := newFlush(d.opts, d.mu.versions.currentVersion(),
1 /* base level */, toFlush, d.timeNow())
if err != nil {
return err
}
newVE, _, _, err := d.runCompaction(jobID, c)
if err != nil {
return errors.Wrapf(err, "running compaction during WAL replay")
}
ve.NewFiles = append(ve.NewFiles, newVE.NewFiles...)
return nil
}
defer func() {
if err != nil {
err = errors.WithDetailf(err, "replaying wal %d, offset %d", ll.Num, offset)
}
}()
for {
r, offset, err := rr.NextRecord()
if err == nil {
_, err = io.Copy(&buf, r)
}
if err != nil {
// It is common to encounter a zeroed or invalid chunk due to WAL
// preallocation and WAL recycling. We need to distinguish these
// errors from EOF in order to recognize that the record was
// truncated and to avoid replaying subsequent WALs, but want
// to otherwise treat them like EOF.
if err == io.EOF {
break
} else if record.IsInvalidRecord(err) && !strictWALTail {
break
}
return nil, 0, errors.Wrap(err, "pebble: error when replaying WAL")
}
if buf.Len() < batchrepr.HeaderLen {
return nil, 0, base.CorruptionErrorf("pebble: corrupt wal %s (offset %s)",
errors.Safe(base.DiskFileNum(ll.Num)), offset)
}
if d.opts.ErrorIfNotPristine {
return nil, 0, errors.WithDetailf(ErrDBNotPristine, "location: %q", d.dirname)
}
// Specify Batch.db so that Batch.SetRepr will compute Batch.memTableSize
// which is used below.
b = Batch{}
b.db = d
b.SetRepr(buf.Bytes())
seqNum := b.SeqNum()
maxSeqNum = seqNum + uint64(b.Count())
keysReplayed += int64(b.Count())
batchesReplayed++
{
br := b.Reader()
if kind, encodedFileNum, _, ok, err := br.Next(); err != nil {
return nil, 0, err
} else if ok && kind == InternalKeyKindIngestSST {
fileNums := make([]base.DiskFileNum, 0, b.Count())
addFileNum := func(encodedFileNum []byte) {
fileNum, n := binary.Uvarint(encodedFileNum)
if n <= 0 {
panic("pebble: ingest sstable file num is invalid.")
}
fileNums = append(fileNums, base.DiskFileNum(fileNum))
}
addFileNum(encodedFileNum)
for i := 1; i < int(b.Count()); i++ {
kind, encodedFileNum, _, ok, err := br.Next()
if err != nil {
return nil, 0, err
}
if kind != InternalKeyKindIngestSST {
panic("pebble: invalid batch key kind.")
}
if !ok {
panic("pebble: invalid batch count.")
}
addFileNum(encodedFileNum)
}
if _, _, _, ok, err := br.Next(); err != nil {
return nil, 0, err
} else if ok {
panic("pebble: invalid number of entries in batch.")
}
meta := make([]*fileMetadata, len(fileNums))
for i, n := range fileNums {
var readable objstorage.Readable
objMeta, err := d.objProvider.Lookup(fileTypeTable, n)
if err != nil {
return nil, 0, errors.Wrap(err, "pebble: error when looking up ingested SSTs")
}
if objMeta.IsRemote() {
readable, err = d.objProvider.OpenForReading(context.TODO(), fileTypeTable, n, objstorage.OpenOptions{MustExist: true})
if err != nil {
return nil, 0, errors.Wrap(err, "pebble: error when opening flushable ingest files")
}
} else {
path := base.MakeFilepath(d.opts.FS, d.dirname, fileTypeTable, n)
f, err := d.opts.FS.Open(path)
if err != nil {
return nil, 0, err
}
readable, err = sstable.NewSimpleReadable(f)
if err != nil {
return nil, 0, err
}
}
// NB: ingestLoad1 will close readable.
meta[i], err = ingestLoad1(d.opts, d.FormatMajorVersion(), readable, d.cacheID, base.PhysicalTableFileNum(n))
if err != nil {
return nil, 0, errors.Wrap(err, "pebble: error when loading flushable ingest files")
}
}
if uint32(len(meta)) != b.Count() {
panic("pebble: couldn't load all files in WAL entry.")
}
entry, err = d.newIngestedFlushableEntry(meta, seqNum, base.DiskFileNum(ll.Num), KeyRange{})
if err != nil {
return nil, 0, err
}
if d.opts.ReadOnly {
d.mu.mem.queue = append(d.mu.mem.queue, entry)
// We added the IngestSST flushable to the queue. But there
// must be at least one WAL entry waiting to be replayed. We
// have to ensure this newer WAL entry isn't replayed into
// the current value of d.mu.mem.mutable because the current
// mutable memtable exists before this flushable entry in
// the memtable queue. To ensure this, we just need to unset
// d.mu.mem.mutable. When a newer WAL is replayed, we will
// set d.mu.mem.mutable to a newer value.
d.mu.mem.mutable = nil
} else {
toFlush = append(toFlush, entry)
// During WAL replay, the lsm only has L0, hence, the
// baseLevel is 1. For the sake of simplicity, we place the
// ingested files in L0 here, instead of finding their
// target levels. This is a simplification for the sake of
// simpler code. It is expected that WAL replay should be
// rare, and that flushables of type ingestedFlushable
// should also be rare. So, placing the ingested files in L0
// is alright.
//
// TODO(bananabrick): Maybe refactor this function to allow
// us to easily place ingested files in levels as low as
// possible during WAL replay. It would require breaking up
// the application of ve to the manifest into chunks and is
// not pretty w/o a refactor to this function and how it's
// used.
c, err := newFlush(
d.opts, d.mu.versions.currentVersion(),
1, /* base level */
[]*flushableEntry{entry},
d.timeNow(),
)
if err != nil {
return nil, 0, err
}
for _, file := range c.flushing[0].flushable.(*ingestedFlushable).files {
ve.NewFiles = append(ve.NewFiles, newFileEntry{Level: 0, Meta: file.FileMetadata})
}
}
return toFlush, maxSeqNum, nil
}
}
if b.memTableSize >= uint64(d.largeBatchThreshold) {
flushMem()
// Make a copy of the data slice since it is currently owned by buf and will
// be reused in the next iteration.
b.data = slices.Clone(b.data)