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mem_table.go
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mem_table.go
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// Copyright 2011 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"
"fmt"
"os"
"sync"
"sync/atomic"
"github.com/cockroachdb/errors"
"github.com/cockroachdb/pebble/internal/arenaskl"
"github.com/cockroachdb/pebble/internal/base"
"github.com/cockroachdb/pebble/internal/keyspan"
"github.com/cockroachdb/pebble/internal/manual"
"github.com/cockroachdb/pebble/internal/rangedel"
"github.com/cockroachdb/pebble/internal/rangekey"
)
func memTableEntrySize(keyBytes, valueBytes int) uint64 {
return arenaskl.MaxNodeSize(uint32(keyBytes)+8, uint32(valueBytes))
}
// memTableEmptySize is the amount of allocated space in the arena when the
// memtable is empty.
var memTableEmptySize = func() uint32 {
var pointSkl arenaskl.Skiplist
var rangeDelSkl arenaskl.Skiplist
var rangeKeySkl arenaskl.Skiplist
arena := arenaskl.NewArena(make([]byte, 16<<10 /* 16 KB */))
pointSkl.Reset(arena, bytes.Compare)
rangeDelSkl.Reset(arena, bytes.Compare)
rangeKeySkl.Reset(arena, bytes.Compare)
return arena.Size()
}()
// A memTable implements an in-memory layer of the LSM. A memTable is mutable,
// but append-only. Records are added, but never removed. Deletion is supported
// via tombstones, but it is up to higher level code (see Iterator) to support
// processing those tombstones.
//
// A memTable is implemented on top of a lock-free arena-backed skiplist. An
// arena is a fixed size contiguous chunk of memory (see
// Options.MemTableSize). A memTable's memory consumption is thus fixed at the
// time of creation (with the exception of the cached fragmented range
// tombstones). The arena-backed skiplist provides both forward and reverse
// links which makes forward and reverse iteration the same speed.
//
// A batch is "applied" to a memTable in a two step process: prepare(batch) ->
// apply(batch). memTable.prepare() is not thread-safe and must be called with
// external synchronization. Preparation reserves space in the memTable for the
// batch. Note that we pessimistically compute how much space a batch will
// consume in the memTable (see memTableEntrySize and
// Batch.memTableSize). Preparation is an O(1) operation. Applying a batch to
// the memTable can be performed concurrently with other apply
// operations. Applying a batch is an O(n logm) operation where N is the number
// of records in the batch and M is the number of records in the memtable. The
// commitPipeline serializes batch preparation, and allows batch application to
// proceed concurrently.
//
// It is safe to call get, apply, newIter, and newRangeDelIter concurrently.
type memTable struct {
cmp Compare
formatKey base.FormatKey
equal Equal
arenaBuf []byte
skl arenaskl.Skiplist
rangeDelSkl arenaskl.Skiplist
rangeKeySkl arenaskl.Skiplist
// reserved tracks the amount of space used by the memtable, both by actual
// data stored in the memtable as well as inflight batch commit
// operations. This value is incremented pessimistically by prepare() in
// order to account for the space needed by a batch.
reserved uint32
// writerRefs tracks the write references on the memtable. The two sources of
// writer references are the memtable being on DB.mu.mem.queue and from
// inflight mutations that have reserved space in the memtable but not yet
// applied. The memtable cannot be flushed to disk until the writer refs
// drops to zero.
writerRefs atomic.Int32
tombstones keySpanCache
rangeKeys keySpanCache
// The current logSeqNum at the time the memtable was created. This is
// guaranteed to be less than or equal to any seqnum stored in the memtable.
logSeqNum base.SeqNum
releaseAccountingReservation func()
}
func (m *memTable) free() {
if m != nil {
m.releaseAccountingReservation()
manual.Free(manual.MemTable, m.arenaBuf)
m.arenaBuf = nil
}
}
// memTableOptions holds configuration used when creating a memTable. All of
// the fields are optional and will be filled with defaults if not specified
// which is used by tests.
type memTableOptions struct {
*Options
arenaBuf []byte
size int
logSeqNum base.SeqNum
releaseAccountingReservation func()
}
func checkMemTable(obj interface{}) {
m := obj.(*memTable)
if m.arenaBuf != nil {
fmt.Fprintf(os.Stderr, "%p: memTable buffer was not freed\n", m.arenaBuf)
os.Exit(1)
}
}
// newMemTable returns a new MemTable of the specified size. If size is zero,
// Options.MemTableSize is used instead.
func newMemTable(opts memTableOptions) *memTable {
opts.Options = opts.Options.EnsureDefaults()
m := new(memTable)
m.init(opts)
return m
}
func (m *memTable) init(opts memTableOptions) {
if opts.size == 0 {
opts.size = int(opts.MemTableSize)
}
*m = memTable{
cmp: opts.Comparer.Compare,
formatKey: opts.Comparer.FormatKey,
equal: opts.Comparer.Equal,
arenaBuf: opts.arenaBuf,
logSeqNum: opts.logSeqNum,
releaseAccountingReservation: opts.releaseAccountingReservation,
}
m.writerRefs.Store(1)
m.tombstones = keySpanCache{
cmp: m.cmp,
formatKey: m.formatKey,
skl: &m.rangeDelSkl,
constructSpan: rangeDelConstructSpan,
}
m.rangeKeys = keySpanCache{
cmp: m.cmp,
formatKey: m.formatKey,
skl: &m.rangeKeySkl,
constructSpan: rangekey.Decode,
}
if m.arenaBuf == nil {
m.arenaBuf = make([]byte, opts.size)
}
arena := arenaskl.NewArena(m.arenaBuf)
m.skl.Reset(arena, m.cmp)
m.rangeDelSkl.Reset(arena, m.cmp)
m.rangeKeySkl.Reset(arena, m.cmp)
m.reserved = arena.Size()
}
func (m *memTable) writerRef() {
switch v := m.writerRefs.Add(1); {
case v <= 1:
panic(fmt.Sprintf("pebble: inconsistent reference count: %d", v))
}
}
// writerUnref drops a ref on the memtable. Returns true if this was the last ref.
func (m *memTable) writerUnref() (wasLastRef bool) {
switch v := m.writerRefs.Add(-1); {
case v < 0:
panic(fmt.Sprintf("pebble: inconsistent reference count: %d", v))
case v == 0:
return true
default:
return false
}
}
// readyForFlush is part of the flushable interface.
func (m *memTable) readyForFlush() bool {
return m.writerRefs.Load() == 0
}
// Prepare reserves space for the batch in the memtable and references the
// memtable preventing it from being flushed until the batch is applied. Note
// that prepare is not thread-safe, while apply is. The caller must call
// writerUnref() after the batch has been applied.
func (m *memTable) prepare(batch *Batch) error {
avail := m.availBytes()
if batch.memTableSize > uint64(avail) {
return arenaskl.ErrArenaFull
}
m.reserved += uint32(batch.memTableSize)
m.writerRef()
return nil
}
func (m *memTable) apply(batch *Batch, seqNum base.SeqNum) error {
if seqNum < m.logSeqNum {
return base.CorruptionErrorf("pebble: batch seqnum %d is less than memtable creation seqnum %d",
errors.Safe(seqNum), errors.Safe(m.logSeqNum))
}
var ins arenaskl.Inserter
var tombstoneCount, rangeKeyCount uint32
startSeqNum := seqNum
for r := batch.Reader(); ; seqNum++ {
kind, ukey, value, ok, err := r.Next()
if !ok {
if err != nil {
return err
}
break
}
ikey := base.MakeInternalKey(ukey, seqNum, kind)
switch kind {
case InternalKeyKindRangeDelete:
err = m.rangeDelSkl.Add(ikey, value)
tombstoneCount++
case InternalKeyKindRangeKeySet, InternalKeyKindRangeKeyUnset, InternalKeyKindRangeKeyDelete:
err = m.rangeKeySkl.Add(ikey, value)
rangeKeyCount++
case InternalKeyKindLogData:
// Don't increment seqNum for LogData, since these are not applied
// to the memtable.
seqNum--
case InternalKeyKindIngestSST, InternalKeyKindExcise:
panic("pebble: cannot apply ingested sstable or excise kind keys to memtable")
default:
err = ins.Add(&m.skl, ikey, value)
}
if err != nil {
return err
}
}
if seqNum != startSeqNum+base.SeqNum(batch.Count()) {
return base.CorruptionErrorf("pebble: inconsistent batch count: %d vs %d",
errors.Safe(seqNum), errors.Safe(startSeqNum+base.SeqNum(batch.Count())))
}
if tombstoneCount != 0 {
m.tombstones.invalidate(tombstoneCount)
}
if rangeKeyCount != 0 {
m.rangeKeys.invalidate(rangeKeyCount)
}
return nil
}
// newIter is part of the flushable interface. It returns an iterator that is
// unpositioned (Iterator.Valid() will return false). The iterator can be
// positioned via a call to SeekGE, SeekLT, First or Last.
func (m *memTable) newIter(o *IterOptions) internalIterator {
return m.skl.NewIter(o.GetLowerBound(), o.GetUpperBound())
}
// newFlushIter is part of the flushable interface.
func (m *memTable) newFlushIter(o *IterOptions) internalIterator {
return m.skl.NewFlushIter()
}
// newRangeDelIter is part of the flushable interface.
func (m *memTable) newRangeDelIter(*IterOptions) keyspan.FragmentIterator {
tombstones := m.tombstones.get()
if tombstones == nil {
return nil
}
return keyspan.NewIter(m.cmp, tombstones)
}
// newRangeKeyIter is part of the flushable interface.
func (m *memTable) newRangeKeyIter(*IterOptions) keyspan.FragmentIterator {
rangeKeys := m.rangeKeys.get()
if rangeKeys == nil {
return nil
}
return keyspan.NewIter(m.cmp, rangeKeys)
}
// containsRangeKeys is part of the flushable interface.
func (m *memTable) containsRangeKeys() bool {
return m.rangeKeys.count.Load() > 0
}
func (m *memTable) availBytes() uint32 {
a := m.skl.Arena()
if m.writerRefs.Load() == 1 {
// Note that one ref is maintained as long as the memtable is the
// current mutable memtable, so when evaluating whether the current
// mutable memtable has sufficient space for committing a batch, it is
// guaranteed that m.writerRefs() >= 1. This means a writerRefs() of 1
// indicates there are no other concurrent apply operations.
//
// If there are no other concurrent apply operations, we can update the
// reserved bytes setting to accurately reflect how many bytes of been
// allocated vs the over-estimation present in memTableEntrySize.
m.reserved = a.Size()
}
return a.Capacity() - m.reserved
}
// inuseBytes is part of the flushable interface.
func (m *memTable) inuseBytes() uint64 {
return uint64(m.skl.Size() - memTableEmptySize)
}
// totalBytes is part of the flushable interface.
func (m *memTable) totalBytes() uint64 {
return uint64(m.skl.Arena().Capacity())
}
// empty returns whether the MemTable has no key/value pairs.
func (m *memTable) empty() bool {
return m.skl.Size() == memTableEmptySize
}
// computePossibleOverlaps is part of the flushable interface.
func (m *memTable) computePossibleOverlaps(fn func(bounded) shouldContinue, bounded ...bounded) {
computePossibleOverlapsGenericImpl[*memTable](m, m.cmp, fn, bounded)
}
// A keySpanFrags holds a set of fragmented keyspan.Spans with a particular key
// kind at a particular moment for a memtable.
//
// When a new span of a particular kind is added to the memtable, it may overlap
// with other spans of the same kind. Instead of performing the fragmentation
// whenever an iterator requires it, fragments are cached within a keySpanCache
// type. The keySpanCache uses keySpanFrags to hold the cached fragmented spans.
//
// The count of keys (and keys of any given kind) in a memtable only
// monotonically increases. The count of key spans of a particular kind is used
// as a stand-in for a 'sequence number'. A keySpanFrags represents the
// fragmented state of the memtable's keys of a given kind at the moment while
// there existed `count` keys of that kind in the memtable.
//
// It's currently only used to contain fragmented range deletion tombstones.
type keySpanFrags struct {
count uint32
once sync.Once
spans []keyspan.Span
}
type constructSpan func(ik base.InternalKey, v []byte, keysDst []keyspan.Key) (keyspan.Span, error)
func rangeDelConstructSpan(
ik base.InternalKey, v []byte, keysDst []keyspan.Key,
) (keyspan.Span, error) {
return rangedel.Decode(ik, v, keysDst), nil
}
// get retrieves the fragmented spans, populating them if necessary. Note that
// the populated span fragments may be built from more than f.count memTable
// spans, but that is ok for correctness. All we're requiring is that the
// memTable contains at least f.count keys of the configured kind. This
// situation can occur if there are multiple concurrent additions of the key
// kind and a concurrent reader. The reader can load a keySpanFrags and populate
// it even though is has been invalidated (i.e. replaced with a newer
// keySpanFrags).
func (f *keySpanFrags) get(
skl *arenaskl.Skiplist, cmp Compare, formatKey base.FormatKey, constructSpan constructSpan,
) []keyspan.Span {
f.once.Do(func() {
frag := &keyspan.Fragmenter{
Cmp: cmp,
Format: formatKey,
Emit: func(fragmented keyspan.Span) {
f.spans = append(f.spans, fragmented)
},
}
it := skl.NewIter(nil, nil)
var keysDst []keyspan.Key
for kv := it.First(); kv != nil; kv = it.Next() {
s, err := constructSpan(kv.K, kv.InPlaceValue(), keysDst)
if err != nil {
panic(err)
}
frag.Add(s)
keysDst = s.Keys[len(s.Keys):]
}
frag.Finish()
})
return f.spans
}
// A keySpanCache is used to cache a set of fragmented spans. The cache is
// invalidated whenever a key of the same kind is added to a memTable, and
// populated when empty when a span iterator of that key kind is created.
type keySpanCache struct {
count atomic.Uint32
frags atomic.Pointer[keySpanFrags]
cmp Compare
formatKey base.FormatKey
constructSpan constructSpan
skl *arenaskl.Skiplist
}
// Invalidate the current set of cached spans, indicating the number of
// spans that were added.
func (c *keySpanCache) invalidate(count uint32) {
newCount := c.count.Add(count)
var frags *keySpanFrags
for {
oldFrags := c.frags.Load()
if oldFrags != nil && oldFrags.count >= newCount {
// Someone else invalidated the cache before us and their invalidation
// subsumes ours.
break
}
if frags == nil {
frags = &keySpanFrags{count: newCount}
}
if c.frags.CompareAndSwap(oldFrags, frags) {
// We successfully invalidated the cache.
break
}
// Someone else invalidated the cache. Loop and try again.
}
}
func (c *keySpanCache) get() []keyspan.Span {
frags := c.frags.Load()
if frags == nil {
return nil
}
return frags.get(c.skl, c.cmp, c.formatKey, c.constructSpan)
}