VictoriaMetrics/lib/storage/partition.go
Nikolay 5eb5df96e2
lib/storage: creates parts.json on start-up if it not exists. (#4450)
* lib/storage: creates parts.json on start-up if it not exists.
It fixes migrations from versions below v1.90.0.
Previously parts.json was created only after successful merge.
But if merge was interruped for some reason (OOM or shutdown), parts.json wasn't created and partitions left after interruped merge weren't properly deleted.
Since VM cannot check if it must be removed or not.
https://github.com/VictoriaMetrics/VictoriaMetrics/issues/4336

* Apply suggestions from code review

Co-authored-by: Roman Khavronenko <roman@victoriametrics.com>

* Update lib/storage/partition.go

Co-authored-by: Roman Khavronenko <roman@victoriametrics.com>

---------

Co-authored-by: Roman Khavronenko <roman@victoriametrics.com>
2023-06-15 11:19:22 +02:00

1951 lines
53 KiB
Go

package storage
import (
"encoding/json"
"errors"
"fmt"
"os"
"path/filepath"
"sort"
"strings"
"sync"
"sync/atomic"
"time"
"unsafe"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/cgroup"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/encoding"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/fasttime"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/fs"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/logger"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/memory"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/mergeset"
)
// The maximum size of big part.
//
// This number limits the maximum time required for building big part.
// This time shouldn't exceed a few days.
const maxBigPartSize = 1e12
// The maximum number of inmemory parts in the partition.
//
// If the number of inmemory parts reaches this value, then assisted merge runs during data ingestion.
const maxInmemoryPartsPerPartition = 20
// The maximum number of small parts in the partition.
//
// If the number of small parts reaches this value, then assisted merge runs during data ingestion.
const maxSmallPartsPerPartition = 30
// Default number of parts to merge at once.
//
// This number has been obtained empirically - it gives the lowest possible overhead.
// See appendPartsToMerge tests for details.
const defaultPartsToMerge = 15
// The final number of parts to merge at once.
//
// It must be smaller than defaultPartsToMerge.
// Lower value improves select performance at the cost of increased
// write amplification.
const finalPartsToMerge = 3
// The number of shards for rawRow entries per partition.
//
// Higher number of shards reduces CPU contention and increases the max bandwidth on multi-core systems.
var rawRowsShardsPerPartition = (cgroup.AvailableCPUs() + 1) / 2
// The interval for flushing buffered rows into parts, so they become visible to search.
const pendingRowsFlushInterval = time.Second
// The interval for guaranteed flush of recently ingested data from memory to on-disk parts,
// so they survive process crash.
var dataFlushInterval = 5 * time.Second
// SetDataFlushInterval sets the interval for guaranteed flush of recently ingested data from memory to disk.
//
// The data can be flushed from memory to disk more frequently if it doesn't fit the memory limit.
//
// This function must be called before initializing the storage.
func SetDataFlushInterval(d time.Duration) {
if d > pendingRowsFlushInterval {
dataFlushInterval = d
mergeset.SetDataFlushInterval(d)
}
}
// getMaxRawRowsPerShard returns the maximum number of rows that haven't been converted into parts yet.
func getMaxRawRowsPerShard() int {
maxRawRowsPerPartitionOnce.Do(func() {
n := memory.Allowed() / rawRowsShardsPerPartition / 256 / int(unsafe.Sizeof(rawRow{}))
if n < 1e4 {
n = 1e4
}
if n > 500e3 {
n = 500e3
}
maxRawRowsPerPartition = n
})
return maxRawRowsPerPartition
}
var (
maxRawRowsPerPartition int
maxRawRowsPerPartitionOnce sync.Once
)
// partition represents a partition.
type partition struct {
// Put atomic counters to the top of struct, so they are aligned to 8 bytes on 32-bit arch.
// See https://github.com/VictoriaMetrics/VictoriaMetrics/issues/212
activeInmemoryMerges uint64
activeSmallMerges uint64
activeBigMerges uint64
inmemoryMergesCount uint64
smallMergesCount uint64
bigMergesCount uint64
inmemoryRowsMerged uint64
smallRowsMerged uint64
bigRowsMerged uint64
inmemoryRowsDeleted uint64
smallRowsDeleted uint64
bigRowsDeleted uint64
inmemoryAssistedMerges uint64
smallAssistedMerges uint64
mergeNeedFreeDiskSpace uint64
mergeIdx uint64
smallPartsPath string
bigPartsPath string
// The parent storage.
s *Storage
// Name is the name of the partition in the form YYYY_MM.
name string
// The time range for the partition. Usually this is a whole month.
tr TimeRange
// rawRows contains recently added rows that haven't been converted into parts yet.
// rawRows are periodically converted into inmemroyParts.
// rawRows aren't used in search for performance reasons.
rawRows rawRowsShards
// partsLock protects inmemoryParts, smallParts and bigParts.
partsLock sync.Mutex
// Contains inmemory parts with recently ingested data.
// It must be merged into either smallParts or bigParts to become visible to search.
inmemoryParts []*partWrapper
// Contains file-based parts with small number of items.
smallParts []*partWrapper
// Contains file-based parts with big number of items.
bigParts []*partWrapper
// This channel is used for signaling the background mergers that there are parts,
// which may need to be merged.
needMergeCh chan struct{}
stopCh chan struct{}
wg sync.WaitGroup
}
// partWrapper is a wrapper for the part.
type partWrapper struct {
// The number of references to the part.
refCount uint32
// The flag, which is set when the part must be deleted after refCount reaches zero.
// This field should be updated only after partWrapper
// was removed from the list of active parts.
mustBeDeleted uint32
// The part itself.
p *part
// non-nil if the part is inmemoryPart.
mp *inmemoryPart
// Whether the part is in merge now.
isInMerge bool
// The deadline when in-memory part must be flushed to disk.
flushToDiskDeadline time.Time
}
func (pw *partWrapper) incRef() {
atomic.AddUint32(&pw.refCount, 1)
}
func (pw *partWrapper) decRef() {
n := atomic.AddUint32(&pw.refCount, ^uint32(0))
if int32(n) < 0 {
logger.Panicf("BUG: pw.refCount must be bigger than 0; got %d", int32(n))
}
if n > 0 {
return
}
deletePath := ""
if pw.mp == nil && atomic.LoadUint32(&pw.mustBeDeleted) != 0 {
deletePath = pw.p.path
}
if pw.mp != nil {
putInmemoryPart(pw.mp)
pw.mp = nil
}
pw.p.MustClose()
pw.p = nil
if deletePath != "" {
fs.MustRemoveAll(deletePath)
}
}
// mustCreatePartition creates new partition for the given timestamp and the given paths
// to small and big partitions.
func mustCreatePartition(timestamp int64, smallPartitionsPath, bigPartitionsPath string, s *Storage) *partition {
name := timestampToPartitionName(timestamp)
smallPartsPath := filepath.Join(filepath.Clean(smallPartitionsPath), name)
bigPartsPath := filepath.Join(filepath.Clean(bigPartitionsPath), name)
logger.Infof("creating a partition %q with smallPartsPath=%q, bigPartsPath=%q", name, smallPartsPath, bigPartsPath)
fs.MustMkdirFailIfExist(smallPartsPath)
fs.MustMkdirFailIfExist(bigPartsPath)
pt := newPartition(name, smallPartsPath, bigPartsPath, s)
pt.tr.fromPartitionTimestamp(timestamp)
pt.startBackgroundWorkers()
logger.Infof("partition %q has been created", name)
return pt
}
func (pt *partition) startBackgroundWorkers() {
pt.startMergeWorkers()
pt.startInmemoryPartsFlusher()
pt.startPendingRowsFlusher()
pt.startStalePartsRemover()
}
// Drop drops all the data on the storage for the given pt.
//
// The pt must be detached from table before calling pt.Drop.
func (pt *partition) Drop() {
logger.Infof("dropping partition %q at smallPartsPath=%q, bigPartsPath=%q", pt.name, pt.smallPartsPath, pt.bigPartsPath)
fs.MustRemoveDirAtomic(pt.smallPartsPath)
fs.MustRemoveDirAtomic(pt.bigPartsPath)
logger.Infof("partition %q has been dropped", pt.name)
}
// mustOpenPartition opens the existing partition from the given paths.
func mustOpenPartition(smallPartsPath, bigPartsPath string, s *Storage) *partition {
smallPartsPath = filepath.Clean(smallPartsPath)
bigPartsPath = filepath.Clean(bigPartsPath)
name := filepath.Base(smallPartsPath)
if !strings.HasSuffix(bigPartsPath, name) {
logger.Panicf("FATAL: patititon name in bigPartsPath %q doesn't match smallPartsPath %q; want %q", bigPartsPath, smallPartsPath, name)
}
partNamesSmall, partNamesBig := mustReadPartNames(smallPartsPath, bigPartsPath)
smallParts := mustOpenParts(smallPartsPath, partNamesSmall)
bigParts := mustOpenParts(bigPartsPath, partNamesBig)
partNamesPath := filepath.Join(smallPartsPath, partsFilename)
if !fs.IsPathExist(partNamesPath) {
// create parts.json file on migration from previous versions before v1.90.0
mustWritePartNames(smallParts, bigParts, smallPartsPath)
}
pt := newPartition(name, smallPartsPath, bigPartsPath, s)
pt.smallParts = smallParts
pt.bigParts = bigParts
if err := pt.tr.fromPartitionName(name); err != nil {
logger.Panicf("FATAL: cannot obtain partition time range from smallPartsPath %q: %s", smallPartsPath, err)
}
pt.startBackgroundWorkers()
// Wake up a single background merger, so it could start merging parts if needed.
pt.notifyBackgroundMergers()
return pt
}
func newPartition(name, smallPartsPath, bigPartsPath string, s *Storage) *partition {
p := &partition{
name: name,
smallPartsPath: smallPartsPath,
bigPartsPath: bigPartsPath,
s: s,
mergeIdx: uint64(time.Now().UnixNano()),
needMergeCh: make(chan struct{}, cgroup.AvailableCPUs()),
stopCh: make(chan struct{}),
}
p.rawRows.init()
return p
}
// partitionMetrics contains essential metrics for the partition.
type partitionMetrics struct {
PendingRows uint64
IndexBlocksCacheSize uint64
IndexBlocksCacheSizeBytes uint64
IndexBlocksCacheSizeMaxBytes uint64
IndexBlocksCacheRequests uint64
IndexBlocksCacheMisses uint64
InmemorySizeBytes uint64
SmallSizeBytes uint64
BigSizeBytes uint64
InmemoryRowsCount uint64
SmallRowsCount uint64
BigRowsCount uint64
InmemoryBlocksCount uint64
SmallBlocksCount uint64
BigBlocksCount uint64
InmemoryPartsCount uint64
SmallPartsCount uint64
BigPartsCount uint64
ActiveInmemoryMerges uint64
ActiveSmallMerges uint64
ActiveBigMerges uint64
InmemoryMergesCount uint64
SmallMergesCount uint64
BigMergesCount uint64
InmemoryRowsMerged uint64
SmallRowsMerged uint64
BigRowsMerged uint64
InmemoryRowsDeleted uint64
SmallRowsDeleted uint64
BigRowsDeleted uint64
InmemoryPartsRefCount uint64
SmallPartsRefCount uint64
BigPartsRefCount uint64
InmemoryAssistedMerges uint64
SmallAssistedMerges uint64
MergeNeedFreeDiskSpace uint64
}
// TotalRowsCount returns total number of rows in tm.
func (pm *partitionMetrics) TotalRowsCount() uint64 {
return pm.PendingRows + pm.InmemoryRowsCount + pm.SmallRowsCount + pm.BigRowsCount
}
// UpdateMetrics updates m with metrics from pt.
func (pt *partition) UpdateMetrics(m *partitionMetrics) {
m.PendingRows += uint64(pt.rawRows.Len())
pt.partsLock.Lock()
for _, pw := range pt.inmemoryParts {
p := pw.p
m.InmemoryRowsCount += p.ph.RowsCount
m.InmemoryBlocksCount += p.ph.BlocksCount
m.InmemorySizeBytes += p.size
m.InmemoryPartsRefCount += uint64(atomic.LoadUint32(&pw.refCount))
}
for _, pw := range pt.smallParts {
p := pw.p
m.SmallRowsCount += p.ph.RowsCount
m.SmallBlocksCount += p.ph.BlocksCount
m.SmallSizeBytes += p.size
m.SmallPartsRefCount += uint64(atomic.LoadUint32(&pw.refCount))
}
for _, pw := range pt.bigParts {
p := pw.p
m.BigRowsCount += p.ph.RowsCount
m.BigBlocksCount += p.ph.BlocksCount
m.BigSizeBytes += p.size
m.BigPartsRefCount += uint64(atomic.LoadUint32(&pw.refCount))
}
m.InmemoryPartsCount += uint64(len(pt.inmemoryParts))
m.SmallPartsCount += uint64(len(pt.smallParts))
m.BigPartsCount += uint64(len(pt.bigParts))
pt.partsLock.Unlock()
m.IndexBlocksCacheSize = uint64(ibCache.Len())
m.IndexBlocksCacheSizeBytes = uint64(ibCache.SizeBytes())
m.IndexBlocksCacheSizeMaxBytes = uint64(ibCache.SizeMaxBytes())
m.IndexBlocksCacheRequests = ibCache.Requests()
m.IndexBlocksCacheMisses = ibCache.Misses()
m.ActiveInmemoryMerges += atomic.LoadUint64(&pt.activeInmemoryMerges)
m.ActiveSmallMerges += atomic.LoadUint64(&pt.activeSmallMerges)
m.ActiveBigMerges += atomic.LoadUint64(&pt.activeBigMerges)
m.InmemoryMergesCount += atomic.LoadUint64(&pt.inmemoryMergesCount)
m.SmallMergesCount += atomic.LoadUint64(&pt.smallMergesCount)
m.BigMergesCount += atomic.LoadUint64(&pt.bigMergesCount)
m.InmemoryRowsMerged += atomic.LoadUint64(&pt.inmemoryRowsMerged)
m.SmallRowsMerged += atomic.LoadUint64(&pt.smallRowsMerged)
m.BigRowsMerged += atomic.LoadUint64(&pt.bigRowsMerged)
m.InmemoryRowsDeleted += atomic.LoadUint64(&pt.inmemoryRowsDeleted)
m.SmallRowsDeleted += atomic.LoadUint64(&pt.smallRowsDeleted)
m.BigRowsDeleted += atomic.LoadUint64(&pt.bigRowsDeleted)
m.InmemoryAssistedMerges += atomic.LoadUint64(&pt.inmemoryAssistedMerges)
m.SmallAssistedMerges += atomic.LoadUint64(&pt.smallAssistedMerges)
m.MergeNeedFreeDiskSpace += atomic.LoadUint64(&pt.mergeNeedFreeDiskSpace)
}
// AddRows adds the given rows to the partition pt.
//
// All the rows must fit the partition by timestamp range
// and must have valid PrecisionBits.
func (pt *partition) AddRows(rows []rawRow) {
if len(rows) == 0 {
return
}
if isDebug {
// Validate all the rows.
for i := range rows {
r := &rows[i]
if !pt.HasTimestamp(r.Timestamp) {
logger.Panicf("BUG: row %+v has Timestamp outside partition %q range %+v", r, pt.smallPartsPath, &pt.tr)
}
if err := encoding.CheckPrecisionBits(r.PrecisionBits); err != nil {
logger.Panicf("BUG: row %+v has invalid PrecisionBits: %s", r, err)
}
}
}
pt.rawRows.addRows(pt, rows)
}
var isDebug = false
type rawRowsShards struct {
shardIdx uint32
// Shards reduce lock contention when adding rows on multi-CPU systems.
shards []rawRowsShard
}
func (rrss *rawRowsShards) init() {
rrss.shards = make([]rawRowsShard, rawRowsShardsPerPartition)
}
func (rrss *rawRowsShards) addRows(pt *partition, rows []rawRow) {
shards := rrss.shards
shardsLen := uint32(len(shards))
for len(rows) > 0 {
n := atomic.AddUint32(&rrss.shardIdx, 1)
idx := n % shardsLen
rows = shards[idx].addRows(pt, rows)
}
}
func (rrss *rawRowsShards) Len() int {
n := 0
for i := range rrss.shards[:] {
n += rrss.shards[i].Len()
}
return n
}
type rawRowsShardNopad struct {
// Put lastFlushTime to the top in order to avoid unaligned memory access on 32-bit architectures
lastFlushTime uint64
mu sync.Mutex
rows []rawRow
}
type rawRowsShard struct {
rawRowsShardNopad
// The padding prevents false sharing on widespread platforms with
// 128 mod (cache line size) = 0 .
_ [128 - unsafe.Sizeof(rawRowsShardNopad{})%128]byte
}
func (rrs *rawRowsShard) Len() int {
rrs.mu.Lock()
n := len(rrs.rows)
rrs.mu.Unlock()
return n
}
func (rrs *rawRowsShard) addRows(pt *partition, rows []rawRow) []rawRow {
var rrb *rawRowsBlock
rrs.mu.Lock()
if cap(rrs.rows) == 0 {
rrs.rows = newRawRows()
}
n := copy(rrs.rows[len(rrs.rows):cap(rrs.rows)], rows)
rrs.rows = rrs.rows[:len(rrs.rows)+n]
rows = rows[n:]
if len(rows) > 0 {
rrb = getRawRowsBlock()
rrb.rows, rrs.rows = rrs.rows, rrb.rows
n = copy(rrs.rows[:cap(rrs.rows)], rows)
rrs.rows = rrs.rows[:n]
rows = rows[n:]
atomic.StoreUint64(&rrs.lastFlushTime, fasttime.UnixTimestamp())
}
rrs.mu.Unlock()
if rrb != nil {
pt.flushRowsToParts(rrb.rows)
putRawRowsBlock(rrb)
// Run assisted merges if needed.
flushConcurrencyCh <- struct{}{}
pt.assistedMergeForInmemoryParts()
pt.assistedMergeForSmallParts()
// There is no need in assisted merges for big parts,
// since the bottleneck is possible only at inmemory and small parts.
<-flushConcurrencyCh
}
return rows
}
type rawRowsBlock struct {
rows []rawRow
}
func newRawRows() []rawRow {
n := getMaxRawRowsPerShard()
return make([]rawRow, 0, n)
}
func getRawRowsBlock() *rawRowsBlock {
v := rawRowsBlockPool.Get()
if v == nil {
return &rawRowsBlock{
rows: newRawRows(),
}
}
return v.(*rawRowsBlock)
}
func putRawRowsBlock(rrb *rawRowsBlock) {
rrb.rows = rrb.rows[:0]
rawRowsBlockPool.Put(rrb)
}
var rawRowsBlockPool sync.Pool
func (pt *partition) flushRowsToParts(rows []rawRow) {
if len(rows) == 0 {
return
}
maxRows := getMaxRawRowsPerShard()
var pwsLock sync.Mutex
pws := make([]*partWrapper, 0, (len(rows)+maxRows-1)/maxRows)
wg := getWaitGroup()
for len(rows) > 0 {
n := maxRows
if n > len(rows) {
n = len(rows)
}
wg.Add(1)
flushConcurrencyCh <- struct{}{}
go func(rowsChunk []rawRow) {
defer func() {
<-flushConcurrencyCh
wg.Done()
}()
pw := pt.createInmemoryPart(rowsChunk)
if pw == nil {
return
}
pwsLock.Lock()
pws = append(pws, pw)
pwsLock.Unlock()
}(rows[:n])
rows = rows[n:]
}
wg.Wait()
putWaitGroup(wg)
pt.partsLock.Lock()
pt.inmemoryParts = append(pt.inmemoryParts, pws...)
for range pws {
if !pt.notifyBackgroundMergers() {
break
}
}
pt.partsLock.Unlock()
}
func (pt *partition) notifyBackgroundMergers() bool {
select {
case pt.needMergeCh <- struct{}{}:
return true
default:
return false
}
}
var flushConcurrencyLimit = func() int {
n := cgroup.AvailableCPUs()
if n < 3 {
// Allow at least 3 concurrent flushers on systems with a single CPU core
// in order to guarantee that in-memory data flushes and background merges can be continued
// when a single flusher is busy with the long merge of big parts,
// while another flusher is busy with the long merge of small parts.
n = 3
}
return n
}()
var flushConcurrencyCh = make(chan struct{}, flushConcurrencyLimit)
func needAssistedMerge(pws []*partWrapper, maxParts int) bool {
if len(pws) < maxParts {
return false
}
return getNotInMergePartsCount(pws) >= defaultPartsToMerge
}
func (pt *partition) assistedMergeForInmemoryParts() {
for {
pt.partsLock.Lock()
needMerge := needAssistedMerge(pt.inmemoryParts, maxInmemoryPartsPerPartition)
pt.partsLock.Unlock()
if !needMerge {
return
}
atomic.AddUint64(&pt.inmemoryAssistedMerges, 1)
err := pt.mergeInmemoryParts()
if err == nil {
continue
}
if errors.Is(err, errNothingToMerge) || errors.Is(err, errForciblyStopped) {
return
}
logger.Panicf("FATAL: cannot merge inmemory parts: %s", err)
}
}
func (pt *partition) assistedMergeForSmallParts() {
for {
pt.partsLock.Lock()
needMerge := needAssistedMerge(pt.smallParts, maxSmallPartsPerPartition)
pt.partsLock.Unlock()
if !needMerge {
return
}
atomic.AddUint64(&pt.smallAssistedMerges, 1)
err := pt.mergeExistingParts(false)
if err == nil {
continue
}
if errors.Is(err, errNothingToMerge) || errors.Is(err, errForciblyStopped) || errors.Is(err, errReadOnlyMode) {
return
}
logger.Panicf("FATAL: cannot merge small parts: %s", err)
}
}
func getNotInMergePartsCount(pws []*partWrapper) int {
n := 0
for _, pw := range pws {
if !pw.isInMerge {
n++
}
}
return n
}
func getWaitGroup() *sync.WaitGroup {
v := wgPool.Get()
if v == nil {
return &sync.WaitGroup{}
}
return v.(*sync.WaitGroup)
}
func putWaitGroup(wg *sync.WaitGroup) {
wgPool.Put(wg)
}
var wgPool sync.Pool
func (pt *partition) createInmemoryPart(rows []rawRow) *partWrapper {
if len(rows) == 0 {
return nil
}
mp := getInmemoryPart()
mp.InitFromRows(rows)
// Make sure the part may be added.
if mp.ph.MinTimestamp > mp.ph.MaxTimestamp {
logger.Panicf("BUG: the part %q cannot be added to partition %q because its MinTimestamp exceeds MaxTimestamp; %d vs %d",
&mp.ph, pt.smallPartsPath, mp.ph.MinTimestamp, mp.ph.MaxTimestamp)
}
if mp.ph.MinTimestamp < pt.tr.MinTimestamp {
logger.Panicf("BUG: the part %q cannot be added to partition %q because of too small MinTimestamp; got %d; want at least %d",
&mp.ph, pt.smallPartsPath, mp.ph.MinTimestamp, pt.tr.MinTimestamp)
}
if mp.ph.MaxTimestamp > pt.tr.MaxTimestamp {
logger.Panicf("BUG: the part %q cannot be added to partition %q because of too big MaxTimestamp; got %d; want at least %d",
&mp.ph, pt.smallPartsPath, mp.ph.MaxTimestamp, pt.tr.MaxTimestamp)
}
flushToDiskDeadline := time.Now().Add(dataFlushInterval)
return newPartWrapperFromInmemoryPart(mp, flushToDiskDeadline)
}
func newPartWrapperFromInmemoryPart(mp *inmemoryPart, flushToDiskDeadline time.Time) *partWrapper {
p := mp.NewPart()
pw := &partWrapper{
p: p,
mp: mp,
refCount: 1,
flushToDiskDeadline: flushToDiskDeadline,
}
return pw
}
// HasTimestamp returns true if the pt contains the given timestamp.
func (pt *partition) HasTimestamp(timestamp int64) bool {
return timestamp >= pt.tr.MinTimestamp && timestamp <= pt.tr.MaxTimestamp
}
// GetParts appends parts snapshot to dst and returns it.
//
// The appended parts must be released with PutParts.
func (pt *partition) GetParts(dst []*partWrapper, addInMemory bool) []*partWrapper {
pt.partsLock.Lock()
if addInMemory {
incRefForParts(pt.inmemoryParts)
dst = append(dst, pt.inmemoryParts...)
}
incRefForParts(pt.smallParts)
dst = append(dst, pt.smallParts...)
incRefForParts(pt.bigParts)
dst = append(dst, pt.bigParts...)
pt.partsLock.Unlock()
return dst
}
// PutParts releases the given pws obtained via GetParts.
func (pt *partition) PutParts(pws []*partWrapper) {
for _, pw := range pws {
pw.decRef()
}
}
func incRefForParts(pws []*partWrapper) {
for _, pw := range pws {
pw.incRef()
}
}
// MustClose closes the pt, so the app may safely exit.
//
// The pt must be detached from table before calling pt.MustClose.
func (pt *partition) MustClose() {
close(pt.stopCh)
// Waiting for service workers to stop
pt.wg.Wait()
pt.flushInmemoryRows()
// Remove references from inmemoryParts, smallParts and bigParts, so they may be eventually closed
// after all the searches are done.
pt.partsLock.Lock()
inmemoryParts := pt.inmemoryParts
smallParts := pt.smallParts
bigParts := pt.bigParts
pt.inmemoryParts = nil
pt.smallParts = nil
pt.bigParts = nil
pt.partsLock.Unlock()
for _, pw := range inmemoryParts {
pw.decRef()
}
for _, pw := range smallParts {
pw.decRef()
}
for _, pw := range bigParts {
pw.decRef()
}
}
func (pt *partition) startInmemoryPartsFlusher() {
pt.wg.Add(1)
go func() {
pt.inmemoryPartsFlusher()
pt.wg.Done()
}()
}
func (pt *partition) startPendingRowsFlusher() {
pt.wg.Add(1)
go func() {
pt.pendingRowsFlusher()
pt.wg.Done()
}()
}
func (pt *partition) inmemoryPartsFlusher() {
ticker := time.NewTicker(dataFlushInterval)
defer ticker.Stop()
for {
select {
case <-pt.stopCh:
return
case <-ticker.C:
pt.flushInmemoryParts(false)
}
}
}
func (pt *partition) pendingRowsFlusher() {
ticker := time.NewTicker(pendingRowsFlushInterval)
defer ticker.Stop()
var rows []rawRow
for {
select {
case <-pt.stopCh:
return
case <-ticker.C:
rows = pt.flushPendingRows(rows[:0], false)
}
}
}
func (pt *partition) flushPendingRows(dst []rawRow, isFinal bool) []rawRow {
return pt.rawRows.flush(pt, dst, isFinal)
}
func (pt *partition) flushInmemoryRows() {
pt.rawRows.flush(pt, nil, true)
pt.flushInmemoryParts(true)
}
func (pt *partition) flushInmemoryParts(isFinal bool) {
currentTime := time.Now()
var pws []*partWrapper
pt.partsLock.Lock()
for _, pw := range pt.inmemoryParts {
if !pw.isInMerge && (isFinal || pw.flushToDiskDeadline.Before(currentTime)) {
pw.isInMerge = true
pws = append(pws, pw)
}
}
pt.partsLock.Unlock()
if err := pt.mergePartsOptimal(pws, nil); err != nil {
logger.Panicf("FATAL: cannot merge in-memory parts: %s", err)
}
}
func (rrss *rawRowsShards) flush(pt *partition, dst []rawRow, isFinal bool) []rawRow {
for i := range rrss.shards {
dst = rrss.shards[i].appendRawRowsToFlush(dst, pt, isFinal)
}
pt.flushRowsToParts(dst)
return dst
}
func (rrs *rawRowsShard) appendRawRowsToFlush(dst []rawRow, pt *partition, isFinal bool) []rawRow {
currentTime := fasttime.UnixTimestamp()
flushSeconds := int64(pendingRowsFlushInterval.Seconds())
if flushSeconds <= 0 {
flushSeconds = 1
}
lastFlushTime := atomic.LoadUint64(&rrs.lastFlushTime)
if !isFinal && currentTime < lastFlushTime+uint64(flushSeconds) {
// Fast path - nothing to flush
return dst
}
// Slow path - move rrs.rows to dst.
rrs.mu.Lock()
dst = append(dst, rrs.rows...)
rrs.rows = rrs.rows[:0]
atomic.StoreUint64(&rrs.lastFlushTime, currentTime)
rrs.mu.Unlock()
return dst
}
func (pt *partition) mergePartsOptimal(pws []*partWrapper, stopCh <-chan struct{}) error {
sortPartsForOptimalMerge(pws)
for len(pws) > 0 {
n := defaultPartsToMerge
if n > len(pws) {
n = len(pws)
}
pwsChunk := pws[:n]
pws = pws[n:]
err := pt.mergeParts(pwsChunk, stopCh, true)
if err == nil {
continue
}
pt.releasePartsToMerge(pws)
if errors.Is(err, errForciblyStopped) {
return nil
}
return fmt.Errorf("cannot merge parts optimally: %w", err)
}
return nil
}
// ForceMergeAllParts runs merge for all the parts in pt.
func (pt *partition) ForceMergeAllParts() error {
pws := pt.getAllPartsForMerge()
if len(pws) == 0 {
// Nothing to merge.
return nil
}
for {
// Check whether there is enough disk space for merging pws.
newPartSize := getPartsSize(pws)
maxOutBytes := fs.MustGetFreeSpace(pt.bigPartsPath)
if newPartSize > maxOutBytes {
freeSpaceNeededBytes := newPartSize - maxOutBytes
forceMergeLogger.Warnf("cannot initiate force merge for the partition %s; additional space needed: %d bytes", pt.name, freeSpaceNeededBytes)
pt.releasePartsToMerge(pws)
return nil
}
// If len(pws) == 1, then the merge must run anyway.
// This allows applying the configured retention, removing the deleted series
// and performing de-duplication if needed.
if err := pt.mergePartsOptimal(pws, pt.stopCh); err != nil {
return fmt.Errorf("cannot force merge %d parts from partition %q: %w", len(pws), pt.name, err)
}
pws = pt.getAllPartsForMerge()
if len(pws) <= 1 {
pt.releasePartsToMerge(pws)
return nil
}
}
}
var forceMergeLogger = logger.WithThrottler("forceMerge", time.Minute)
func (pt *partition) getAllPartsForMerge() []*partWrapper {
var pws []*partWrapper
pt.partsLock.Lock()
if !hasActiveMerges(pt.inmemoryParts) && !hasActiveMerges(pt.smallParts) && !hasActiveMerges(pt.bigParts) {
pws = appendAllPartsForMerge(pws, pt.inmemoryParts)
pws = appendAllPartsForMerge(pws, pt.smallParts)
pws = appendAllPartsForMerge(pws, pt.bigParts)
}
pt.partsLock.Unlock()
return pws
}
func appendAllPartsForMerge(dst, src []*partWrapper) []*partWrapper {
for _, pw := range src {
if pw.isInMerge {
logger.Panicf("BUG: part %q is already in merge", pw.p.path)
}
pw.isInMerge = true
dst = append(dst, pw)
}
return dst
}
func hasActiveMerges(pws []*partWrapper) bool {
for _, pw := range pws {
if pw.isInMerge {
return true
}
}
return false
}
var mergeWorkersLimitCh = make(chan struct{}, getDefaultMergeConcurrency(16))
func getDefaultMergeConcurrency(max int) int {
v := (cgroup.AvailableCPUs() + 1) / 2
if v > max {
v = max
}
return adjustMergeWorkersLimit(v)
}
// SetMergeWorkersCount sets the maximum number of concurrent mergers for parts.
//
// The function must be called before opening or creating any storage.
func SetMergeWorkersCount(n int) {
if n <= 0 {
// Do nothing
return
}
n = adjustMergeWorkersLimit(n)
mergeWorkersLimitCh = make(chan struct{}, n)
}
func adjustMergeWorkersLimit(n int) int {
if n < 4 {
// Allow at least 4 merge workers on systems with small CPUs count
// in order to guarantee that background merges can be continued
// when multiple workers are busy with big merges.
n = 4
}
return n
}
func (pt *partition) startMergeWorkers() {
// The actual number of concurrent merges is limited inside mergeWorker() below.
for i := 0; i < cap(mergeWorkersLimitCh); i++ {
pt.wg.Add(1)
go func() {
pt.mergeWorker()
pt.wg.Done()
}()
}
}
func (pt *partition) mergeWorker() {
var lastMergeTime uint64
isFinal := false
for {
// Limit the number of concurrent calls to mergeExistingParts, since the total number of merge workers
// across partitions may exceed the the cap(mergeWorkersLimitCh).
mergeWorkersLimitCh <- struct{}{}
err := pt.mergeExistingParts(isFinal)
<-mergeWorkersLimitCh
if err == nil {
// Try merging additional parts.
lastMergeTime = fasttime.UnixTimestamp()
isFinal = false
continue
}
if errors.Is(err, errForciblyStopped) {
// The merger has been stopped.
return
}
if !errors.Is(err, errNothingToMerge) && !errors.Is(err, errReadOnlyMode) {
// Unexpected error.
logger.Panicf("FATAL: unrecoverable error when merging parts in the partition (%q, %q): %s", pt.smallPartsPath, pt.bigPartsPath, err)
}
if finalMergeDelaySeconds > 0 && fasttime.UnixTimestamp()-lastMergeTime > finalMergeDelaySeconds {
// We have free time for merging into bigger parts.
// This should improve select performance.
lastMergeTime = fasttime.UnixTimestamp()
isFinal = true
continue
}
// Nothing to merge. Wait for the notification of new merge.
select {
case <-pt.stopCh:
return
case <-pt.needMergeCh:
}
}
}
// Disable final merge by default, since it may lead to high disk IO and CPU usage
// at the beginning of every month when merging data for the previous month.
var finalMergeDelaySeconds = uint64(0)
// SetFinalMergeDelay sets the delay before doing final merge for partitions without newly ingested data.
//
// This function may be called only before Storage initialization.
func SetFinalMergeDelay(delay time.Duration) {
if delay <= 0 {
return
}
finalMergeDelaySeconds = uint64(delay.Seconds() + 1)
mergeset.SetFinalMergeDelay(delay)
}
func getMaxInmemoryPartSize() uint64 {
// Allocate 10% of allowed memory for in-memory parts.
n := uint64(0.1 * float64(memory.Allowed()) / maxInmemoryPartsPerPartition)
if n < 1e6 {
n = 1e6
}
return n
}
func (pt *partition) getMaxSmallPartSize() uint64 {
// Small parts are cached in the OS page cache,
// so limit their size by the remaining free RAM.
mem := memory.Remaining()
// It is expected no more than defaultPartsToMerge/2 parts exist
// in the OS page cache before they are merged into bigger part.
// Half of the remaining RAM must be left for lib/mergeset parts,
// so the maxItems is calculated using the below code:
n := uint64(mem) / defaultPartsToMerge
if n < 10e6 {
n = 10e6
}
// Make sure the output part fits available disk space for small parts.
sizeLimit := getMaxOutBytes(pt.smallPartsPath, cap(mergeWorkersLimitCh))
if n > sizeLimit {
n = sizeLimit
}
return n
}
func (pt *partition) getMaxBigPartSize() uint64 {
workersCount := getDefaultMergeConcurrency(4)
return getMaxOutBytes(pt.bigPartsPath, workersCount)
}
func getMaxOutBytes(path string, workersCount int) uint64 {
n := fs.MustGetFreeSpace(path)
// Do not subtract freeDiskSpaceLimitBytes from n before calculating the maxOutBytes,
// since this will result in sub-optimal merges - e.g. many small parts will be left unmerged.
// Divide free space by the max number of concurrent merges.
maxOutBytes := n / uint64(workersCount)
if maxOutBytes > maxBigPartSize {
maxOutBytes = maxBigPartSize
}
return maxOutBytes
}
func (pt *partition) canBackgroundMerge() bool {
return atomic.LoadUint32(&pt.s.isReadOnly) == 0
}
var errReadOnlyMode = fmt.Errorf("storage is in readonly mode")
func (pt *partition) mergeInmemoryParts() error {
maxOutBytes := pt.getMaxBigPartSize()
pt.partsLock.Lock()
pws, needFreeSpace := getPartsToMerge(pt.inmemoryParts, maxOutBytes, false)
pt.partsLock.Unlock()
atomicSetBool(&pt.mergeNeedFreeDiskSpace, needFreeSpace)
return pt.mergeParts(pws, pt.stopCh, false)
}
func (pt *partition) mergeExistingParts(isFinal bool) error {
if !pt.canBackgroundMerge() {
// Do not perform merge in read-only mode, since this may result in disk space shortage.
// See https://github.com/VictoriaMetrics/VictoriaMetrics/issues/2603
return errReadOnlyMode
}
maxOutBytes := pt.getMaxBigPartSize()
pt.partsLock.Lock()
dst := make([]*partWrapper, 0, len(pt.inmemoryParts)+len(pt.smallParts)+len(pt.bigParts))
dst = append(dst, pt.inmemoryParts...)
dst = append(dst, pt.smallParts...)
dst = append(dst, pt.bigParts...)
pws, needFreeSpace := getPartsToMerge(dst, maxOutBytes, isFinal)
pt.partsLock.Unlock()
atomicSetBool(&pt.mergeNeedFreeDiskSpace, needFreeSpace)
return pt.mergeParts(pws, pt.stopCh, isFinal)
}
func (pt *partition) releasePartsToMerge(pws []*partWrapper) {
pt.partsLock.Lock()
for _, pw := range pws {
if !pw.isInMerge {
logger.Panicf("BUG: missing isInMerge flag on the part %q", pw.p.path)
}
pw.isInMerge = false
}
pt.partsLock.Unlock()
}
var errNothingToMerge = fmt.Errorf("nothing to merge")
func atomicSetBool(p *uint64, b bool) {
v := uint64(0)
if b {
v = 1
}
atomic.StoreUint64(p, v)
}
func (pt *partition) runFinalDedup() error {
requiredDedupInterval, actualDedupInterval := pt.getRequiredDedupInterval()
t := time.Now()
logger.Infof("starting final dedup for partition %s using requiredDedupInterval=%d ms, since the partition has smaller actualDedupInterval=%d ms",
pt.bigPartsPath, requiredDedupInterval, actualDedupInterval)
if err := pt.ForceMergeAllParts(); err != nil {
return fmt.Errorf("cannot perform final dedup for partition %s: %w", pt.bigPartsPath, err)
}
logger.Infof("final dedup for partition %s has been finished in %.3f seconds", pt.bigPartsPath, time.Since(t).Seconds())
return nil
}
func (pt *partition) isFinalDedupNeeded() bool {
requiredDedupInterval, actualDedupInterval := pt.getRequiredDedupInterval()
return requiredDedupInterval > actualDedupInterval
}
func (pt *partition) getRequiredDedupInterval() (int64, int64) {
pws := pt.GetParts(nil, false)
defer pt.PutParts(pws)
dedupInterval := GetDedupInterval()
minDedupInterval := getMinDedupInterval(pws)
return dedupInterval, minDedupInterval
}
func getMinDedupInterval(pws []*partWrapper) int64 {
if len(pws) == 0 {
return 0
}
dMin := pws[0].p.ph.MinDedupInterval
for _, pw := range pws[1:] {
d := pw.p.ph.MinDedupInterval
if d < dMin {
dMin = d
}
}
return dMin
}
// mergeParts merges pws to a single resulting part.
//
// Merging is immediately stopped if stopCh is closed.
//
// if isFinal is set, then the resulting part will be saved to disk.
//
// All the parts inside pws must have isInMerge field set to true.
func (pt *partition) mergeParts(pws []*partWrapper, stopCh <-chan struct{}, isFinal bool) error {
if len(pws) == 0 {
// Nothing to merge.
return errNothingToMerge
}
startTime := time.Now()
// Initialize destination paths.
dstPartType := pt.getDstPartType(pws, isFinal)
mergeIdx := pt.nextMergeIdx()
dstPartPath := pt.getDstPartPath(dstPartType, mergeIdx)
if !isDedupEnabled() && isFinal && len(pws) == 1 && pws[0].mp != nil {
// Fast path: flush a single in-memory part to disk.
mp := pws[0].mp
mp.MustStoreToDisk(dstPartPath)
pwNew := pt.openCreatedPart(&mp.ph, pws, nil, dstPartPath)
pt.swapSrcWithDstParts(pws, pwNew, dstPartType)
return nil
}
// Prepare BlockStreamReaders for source parts.
bsrs := mustOpenBlockStreamReaders(pws)
// Prepare BlockStreamWriter for destination part.
srcSize := uint64(0)
srcRowsCount := uint64(0)
srcBlocksCount := uint64(0)
for _, pw := range pws {
srcSize += pw.p.size
srcRowsCount += pw.p.ph.RowsCount
srcBlocksCount += pw.p.ph.BlocksCount
}
rowsPerBlock := float64(srcRowsCount) / float64(srcBlocksCount)
compressLevel := getCompressLevel(rowsPerBlock)
bsw := getBlockStreamWriter()
var mpNew *inmemoryPart
if dstPartType == partInmemory {
mpNew = getInmemoryPart()
bsw.MustInitFromInmemoryPart(mpNew, compressLevel)
} else {
if dstPartPath == "" {
logger.Panicf("BUG: dstPartPath must be non-empty")
}
nocache := dstPartType == partBig
bsw.MustInitFromFilePart(dstPartPath, nocache, compressLevel)
}
// Merge source parts to destination part.
ph, err := pt.mergePartsInternal(dstPartPath, bsw, bsrs, dstPartType, stopCh)
putBlockStreamWriter(bsw)
for _, bsr := range bsrs {
putBlockStreamReader(bsr)
}
if err != nil {
pt.releasePartsToMerge(pws)
return err
}
if mpNew != nil {
// Update partHeader for destination inmemory part after the merge.
mpNew.ph = *ph
} else {
// Make sure the created part directory listing is synced.
fs.MustSyncPath(dstPartPath)
}
// Atomically swap the source parts with the newly created part.
pwNew := pt.openCreatedPart(ph, pws, mpNew, dstPartPath)
dstRowsCount := uint64(0)
dstBlocksCount := uint64(0)
dstSize := uint64(0)
if pwNew != nil {
pDst := pwNew.p
dstRowsCount = pDst.ph.RowsCount
dstBlocksCount = pDst.ph.BlocksCount
dstSize = pDst.size
}
pt.swapSrcWithDstParts(pws, pwNew, dstPartType)
d := time.Since(startTime)
if d <= 30*time.Second {
return nil
}
// Log stats for long merges.
durationSecs := d.Seconds()
rowsPerSec := int(float64(srcRowsCount) / durationSecs)
logger.Infof("merged (%d parts, %d rows, %d blocks, %d bytes) into (1 part, %d rows, %d blocks, %d bytes) in %.3f seconds at %d rows/sec to %q",
len(pws), srcRowsCount, srcBlocksCount, srcSize, dstRowsCount, dstBlocksCount, dstSize, durationSecs, rowsPerSec, dstPartPath)
return nil
}
func getFlushToDiskDeadline(pws []*partWrapper) time.Time {
d := time.Now().Add(dataFlushInterval)
for _, pw := range pws {
if pw.mp != nil && pw.flushToDiskDeadline.Before(d) {
d = pw.flushToDiskDeadline
}
}
return d
}
type partType int
var (
partInmemory = partType(0)
partSmall = partType(1)
partBig = partType(2)
)
func (pt *partition) getDstPartType(pws []*partWrapper, isFinal bool) partType {
dstPartSize := getPartsSize(pws)
if dstPartSize > pt.getMaxSmallPartSize() {
return partBig
}
if isFinal || dstPartSize > getMaxInmemoryPartSize() {
return partSmall
}
if !areAllInmemoryParts(pws) {
// If at least a single source part is located in file,
// then the destination part must be in file for durability reasons.
return partSmall
}
return partInmemory
}
func (pt *partition) getDstPartPath(dstPartType partType, mergeIdx uint64) string {
ptPath := ""
switch dstPartType {
case partSmall:
ptPath = pt.smallPartsPath
case partBig:
ptPath = pt.bigPartsPath
case partInmemory:
ptPath = pt.smallPartsPath
default:
logger.Panicf("BUG: unknown partType=%d", dstPartType)
}
dstPartPath := ""
if dstPartType != partInmemory {
dstPartPath = filepath.Join(ptPath, fmt.Sprintf("%016X", mergeIdx))
}
return dstPartPath
}
func mustOpenBlockStreamReaders(pws []*partWrapper) []*blockStreamReader {
bsrs := make([]*blockStreamReader, 0, len(pws))
for _, pw := range pws {
bsr := getBlockStreamReader()
if pw.mp != nil {
bsr.MustInitFromInmemoryPart(pw.mp)
} else {
bsr.MustInitFromFilePart(pw.p.path)
}
bsrs = append(bsrs, bsr)
}
return bsrs
}
func (pt *partition) mergePartsInternal(dstPartPath string, bsw *blockStreamWriter, bsrs []*blockStreamReader, dstPartType partType, stopCh <-chan struct{}) (*partHeader, error) {
var ph partHeader
var rowsMerged *uint64
var rowsDeleted *uint64
var mergesCount *uint64
var activeMerges *uint64
switch dstPartType {
case partInmemory:
rowsMerged = &pt.inmemoryRowsMerged
rowsDeleted = &pt.inmemoryRowsDeleted
mergesCount = &pt.inmemoryMergesCount
activeMerges = &pt.activeInmemoryMerges
case partSmall:
rowsMerged = &pt.smallRowsMerged
rowsDeleted = &pt.smallRowsDeleted
mergesCount = &pt.smallMergesCount
activeMerges = &pt.activeSmallMerges
case partBig:
rowsMerged = &pt.bigRowsMerged
rowsDeleted = &pt.bigRowsDeleted
mergesCount = &pt.bigMergesCount
activeMerges = &pt.activeBigMerges
default:
logger.Panicf("BUG: unknown partType=%d", dstPartType)
}
retentionDeadline := timestampFromTime(time.Now()) - pt.s.retentionMsecs
atomic.AddUint64(activeMerges, 1)
err := mergeBlockStreams(&ph, bsw, bsrs, stopCh, pt.s, retentionDeadline, rowsMerged, rowsDeleted)
atomic.AddUint64(activeMerges, ^uint64(0))
atomic.AddUint64(mergesCount, 1)
if err != nil {
return nil, fmt.Errorf("cannot merge %d parts to %s: %w", len(bsrs), dstPartPath, err)
}
if dstPartPath != "" {
ph.MinDedupInterval = GetDedupInterval()
ph.MustWriteMetadata(dstPartPath)
}
return &ph, nil
}
func (pt *partition) openCreatedPart(ph *partHeader, pws []*partWrapper, mpNew *inmemoryPart, dstPartPath string) *partWrapper {
// Open the created part.
if ph.RowsCount == 0 {
// The created part is empty. Remove it
if mpNew == nil {
fs.MustRemoveAll(dstPartPath)
}
return nil
}
if mpNew != nil {
// Open the created part from memory.
flushToDiskDeadline := getFlushToDiskDeadline(pws)
pwNew := newPartWrapperFromInmemoryPart(mpNew, flushToDiskDeadline)
return pwNew
}
// Open the created part from disk.
pNew := mustOpenFilePart(dstPartPath)
pwNew := &partWrapper{
p: pNew,
refCount: 1,
}
return pwNew
}
func areAllInmemoryParts(pws []*partWrapper) bool {
for _, pw := range pws {
if pw.mp == nil {
return false
}
}
return true
}
func (pt *partition) swapSrcWithDstParts(pws []*partWrapper, pwNew *partWrapper, dstPartType partType) {
// Atomically unregister old parts and add new part to pt.
m := make(map[*partWrapper]bool, len(pws))
for _, pw := range pws {
m[pw] = true
}
if len(m) != len(pws) {
logger.Panicf("BUG: %d duplicate parts found when merging %d parts", len(pws)-len(m), len(pws))
}
removedInmemoryParts := 0
removedSmallParts := 0
removedBigParts := 0
pt.partsLock.Lock()
pt.inmemoryParts, removedInmemoryParts = removeParts(pt.inmemoryParts, m)
pt.smallParts, removedSmallParts = removeParts(pt.smallParts, m)
pt.bigParts, removedBigParts = removeParts(pt.bigParts, m)
if pwNew != nil {
switch dstPartType {
case partInmemory:
pt.inmemoryParts = append(pt.inmemoryParts, pwNew)
case partSmall:
pt.smallParts = append(pt.smallParts, pwNew)
case partBig:
pt.bigParts = append(pt.bigParts, pwNew)
default:
logger.Panicf("BUG: unknown partType=%d", dstPartType)
}
pt.notifyBackgroundMergers()
}
// Atomically store the updated list of file-based parts on disk.
// This must be performed under partsLock in order to prevent from races
// when multiple concurrently running goroutines update the list.
if removedSmallParts > 0 || removedBigParts > 0 || pwNew != nil && (dstPartType == partSmall || dstPartType == partBig) {
mustWritePartNames(pt.smallParts, pt.bigParts, pt.smallPartsPath)
}
pt.partsLock.Unlock()
removedParts := removedInmemoryParts + removedSmallParts + removedBigParts
if removedParts != len(m) {
logger.Panicf("BUG: unexpected number of parts removed; got %d, want %d", removedParts, len(m))
}
// Mark old parts as must be deleted and decrement reference count,
// so they are eventually closed and deleted.
for _, pw := range pws {
atomic.StoreUint32(&pw.mustBeDeleted, 1)
pw.decRef()
}
}
func getCompressLevel(rowsPerBlock float64) int {
// See https://github.com/facebook/zstd/releases/tag/v1.3.4 about negative compression levels.
if rowsPerBlock <= 10 {
return -5
}
if rowsPerBlock <= 50 {
return -2
}
if rowsPerBlock <= 200 {
return -1
}
if rowsPerBlock <= 500 {
return 1
}
if rowsPerBlock <= 1000 {
return 2
}
if rowsPerBlock <= 2000 {
return 3
}
if rowsPerBlock <= 4000 {
return 4
}
return 5
}
func (pt *partition) nextMergeIdx() uint64 {
return atomic.AddUint64(&pt.mergeIdx, 1)
}
func removeParts(pws []*partWrapper, partsToRemove map[*partWrapper]bool) ([]*partWrapper, int) {
dst := pws[:0]
for _, pw := range pws {
if !partsToRemove[pw] {
dst = append(dst, pw)
}
}
for i := len(dst); i < len(pws); i++ {
pws[i] = nil
}
return dst, len(pws) - len(dst)
}
func (pt *partition) startStalePartsRemover() {
pt.wg.Add(1)
go func() {
pt.stalePartsRemover()
pt.wg.Done()
}()
}
func (pt *partition) stalePartsRemover() {
ticker := time.NewTicker(7 * time.Minute)
defer ticker.Stop()
for {
select {
case <-pt.stopCh:
return
case <-ticker.C:
pt.removeStaleParts()
}
}
}
func (pt *partition) removeStaleParts() {
startTime := time.Now()
retentionDeadline := timestampFromTime(startTime) - pt.s.retentionMsecs
var pws []*partWrapper
pt.partsLock.Lock()
for _, pw := range pt.inmemoryParts {
if !pw.isInMerge && pw.p.ph.MaxTimestamp < retentionDeadline {
atomic.AddUint64(&pt.inmemoryRowsDeleted, pw.p.ph.RowsCount)
pw.isInMerge = true
pws = append(pws, pw)
}
}
for _, pw := range pt.smallParts {
if !pw.isInMerge && pw.p.ph.MaxTimestamp < retentionDeadline {
atomic.AddUint64(&pt.smallRowsDeleted, pw.p.ph.RowsCount)
pw.isInMerge = true
pws = append(pws, pw)
}
}
for _, pw := range pt.bigParts {
if !pw.isInMerge && pw.p.ph.MaxTimestamp < retentionDeadline {
atomic.AddUint64(&pt.bigRowsDeleted, pw.p.ph.RowsCount)
pw.isInMerge = true
pws = append(pws, pw)
}
}
pt.partsLock.Unlock()
pt.swapSrcWithDstParts(pws, nil, partSmall)
}
// getPartsToMerge returns optimal parts to merge from pws.
//
// The summary size of the returned parts must be smaller than maxOutBytes.
// The function returns true if pws contains parts, which cannot be merged because of maxOutBytes limit.
func getPartsToMerge(pws []*partWrapper, maxOutBytes uint64, isFinal bool) ([]*partWrapper, bool) {
pwsRemaining := make([]*partWrapper, 0, len(pws))
for _, pw := range pws {
if !pw.isInMerge {
pwsRemaining = append(pwsRemaining, pw)
}
}
maxPartsToMerge := defaultPartsToMerge
var pms []*partWrapper
needFreeSpace := false
if isFinal {
for len(pms) == 0 && maxPartsToMerge >= finalPartsToMerge {
pms, needFreeSpace = appendPartsToMerge(pms[:0], pwsRemaining, maxPartsToMerge, maxOutBytes)
maxPartsToMerge--
}
} else {
pms, needFreeSpace = appendPartsToMerge(pms[:0], pwsRemaining, maxPartsToMerge, maxOutBytes)
}
for _, pw := range pms {
if pw.isInMerge {
logger.Panicf("BUG: partWrapper.isInMerge cannot be set")
}
pw.isInMerge = true
}
return pms, needFreeSpace
}
// minMergeMultiplier is the minimum multiplier for the size of the output part
// compared to the size of the maximum input part for the merge.
//
// Higher value reduces write amplification (disk write IO induced by the merge),
// while increases the number of unmerged parts.
// The 1.7 is good enough for production workloads.
const minMergeMultiplier = 1.7
// appendPartsToMerge finds optimal parts to merge from src, appends
// them to dst and returns the result.
// The function returns true if src contains parts, which cannot be merged because of maxOutBytes limit.
func appendPartsToMerge(dst, src []*partWrapper, maxPartsToMerge int, maxOutBytes uint64) ([]*partWrapper, bool) {
if len(src) < 2 {
// There is no need in merging zero or one part :)
return dst, false
}
if maxPartsToMerge < 2 {
logger.Panicf("BUG: maxPartsToMerge cannot be smaller than 2; got %d", maxPartsToMerge)
}
// Filter out too big parts.
// This should reduce N for O(N^2) algorithm below.
skippedBigParts := 0
maxInPartBytes := uint64(float64(maxOutBytes) / minMergeMultiplier)
tmp := make([]*partWrapper, 0, len(src))
for _, pw := range src {
if pw.p.size > maxInPartBytes {
skippedBigParts++
continue
}
tmp = append(tmp, pw)
}
src = tmp
needFreeSpace := skippedBigParts > 1
sortPartsForOptimalMerge(src)
maxSrcParts := maxPartsToMerge
if maxSrcParts > len(src) {
maxSrcParts = len(src)
}
minSrcParts := (maxSrcParts + 1) / 2
if minSrcParts < 2 {
minSrcParts = 2
}
// Exhaustive search for parts giving the lowest write amplification when merged.
var pws []*partWrapper
maxM := float64(0)
for i := minSrcParts; i <= maxSrcParts; i++ {
for j := 0; j <= len(src)-i; j++ {
a := src[j : j+i]
outSize := getPartsSize(a)
if outSize > maxOutBytes {
needFreeSpace = true
}
if a[0].p.size*uint64(len(a)) < a[len(a)-1].p.size {
// Do not merge parts with too big difference in size,
// since this results in unbalanced merges.
continue
}
if outSize > maxOutBytes {
// There is no need in verifying remaining parts with bigger sizes.
break
}
m := float64(outSize) / float64(a[len(a)-1].p.size)
if m < maxM {
continue
}
maxM = m
pws = a
}
}
minM := float64(maxPartsToMerge) / 2
if minM < minMergeMultiplier {
minM = minMergeMultiplier
}
if maxM < minM {
// There is no sense in merging parts with too small m,
// since this leads to high disk write IO.
return dst, needFreeSpace
}
return append(dst, pws...), needFreeSpace
}
func sortPartsForOptimalMerge(pws []*partWrapper) {
// Sort src parts by size and backwards timestamp.
// This should improve adjanced points' locality in the merged parts.
sort.Slice(pws, func(i, j int) bool {
a := pws[i].p
b := pws[j].p
if a.size == b.size {
return a.ph.MinTimestamp > b.ph.MinTimestamp
}
return a.size < b.size
})
}
func getPartsSize(pws []*partWrapper) uint64 {
n := uint64(0)
for _, pw := range pws {
n += pw.p.size
}
return n
}
func mustOpenParts(path string, partNames []string) []*partWrapper {
// The path can be missing after restoring from backup, so create it if needed.
fs.MustMkdirIfNotExist(path)
fs.MustRemoveTemporaryDirs(path)
// Remove txn and tmp directories, which may be left after the upgrade
// to v1.90.0 and newer versions.
fs.MustRemoveAll(filepath.Join(path, "txn"))
fs.MustRemoveAll(filepath.Join(path, "tmp"))
// Remove dirs missing in partNames. These dirs may be left after unclean shutdown
// or after the update from versions prior to v1.90.0.
des := fs.MustReadDir(path)
m := make(map[string]struct{}, len(partNames))
for _, partName := range partNames {
m[partName] = struct{}{}
}
for _, de := range des {
if !fs.IsDirOrSymlink(de) {
// Skip non-directories.
continue
}
fn := de.Name()
if _, ok := m[fn]; !ok {
deletePath := filepath.Join(path, fn)
fs.MustRemoveAll(deletePath)
}
}
fs.MustSyncPath(path)
// Open parts
var pws []*partWrapper
for _, partName := range partNames {
partPath := filepath.Join(path, partName)
p := mustOpenFilePart(partPath)
pw := &partWrapper{
p: p,
refCount: 1,
}
pws = append(pws, pw)
}
return pws
}
// MustCreateSnapshotAt creates pt snapshot at the given smallPath and bigPath dirs.
//
// Snapshot is created using linux hard links, so it is usually created very quickly.
func (pt *partition) MustCreateSnapshotAt(smallPath, bigPath string) {
logger.Infof("creating partition snapshot of %q and %q...", pt.smallPartsPath, pt.bigPartsPath)
startTime := time.Now()
// Flush inmemory data to disk.
pt.flushInmemoryRows()
pt.partsLock.Lock()
incRefForParts(pt.smallParts)
pwsSmall := append([]*partWrapper{}, pt.smallParts...)
incRefForParts(pt.bigParts)
pwsBig := append([]*partWrapper{}, pt.bigParts...)
pt.partsLock.Unlock()
defer func() {
pt.PutParts(pwsSmall)
pt.PutParts(pwsBig)
}()
fs.MustMkdirFailIfExist(smallPath)
fs.MustMkdirFailIfExist(bigPath)
// Create a file with part names at smallPath
mustWritePartNames(pwsSmall, pwsBig, smallPath)
pt.mustCreateSnapshot(pt.smallPartsPath, smallPath, pwsSmall)
pt.mustCreateSnapshot(pt.bigPartsPath, bigPath, pwsBig)
logger.Infof("created partition snapshot of %q and %q at %q and %q in %.3f seconds",
pt.smallPartsPath, pt.bigPartsPath, smallPath, bigPath, time.Since(startTime).Seconds())
}
// mustCreateSnapshot creates a snapshot from srcDir to dstDir.
func (pt *partition) mustCreateSnapshot(srcDir, dstDir string, pws []*partWrapper) {
// Make hardlinks for pws at dstDir
for _, pw := range pws {
srcPartPath := pw.p.path
dstPartPath := filepath.Join(dstDir, filepath.Base(srcPartPath))
fs.MustHardLinkFiles(srcPartPath, dstPartPath)
}
// Copy the appliedRetentionFilename to dstDir.
// This file can be created by VictoriaMetrics enterprise.
// See https://docs.victoriametrics.com/#retention-filters .
// Do not make hard link to this file, since it can be modified over time.
srcPath := filepath.Join(srcDir, appliedRetentionFilename)
if fs.IsPathExist(srcPath) {
dstPath := filepath.Join(dstDir, filepath.Base(srcPath))
fs.MustCopyFile(srcPath, dstPath)
}
fs.MustSyncPath(dstDir)
parentDir := filepath.Dir(dstDir)
fs.MustSyncPath(parentDir)
}
type partNamesJSON struct {
Small []string
Big []string
}
func mustWritePartNames(pwsSmall, pwsBig []*partWrapper, dstDir string) {
partNamesSmall := getPartNames(pwsSmall)
partNamesBig := getPartNames(pwsBig)
partNames := &partNamesJSON{
Small: partNamesSmall,
Big: partNamesBig,
}
data, err := json.Marshal(partNames)
if err != nil {
logger.Panicf("BUG: cannot marshal partNames to JSON: %s", err)
}
partNamesPath := filepath.Join(dstDir, partsFilename)
fs.MustWriteAtomic(partNamesPath, data, true)
}
func getPartNames(pws []*partWrapper) []string {
partNames := make([]string, 0, len(pws))
for _, pw := range pws {
if pw.mp != nil {
// Skip in-memory parts
continue
}
partName := filepath.Base(pw.p.path)
partNames = append(partNames, partName)
}
sort.Strings(partNames)
return partNames
}
func mustReadPartNames(smallPartsPath, bigPartsPath string) ([]string, []string) {
partNamesPath := filepath.Join(smallPartsPath, partsFilename)
if fs.IsPathExist(partNamesPath) {
data, err := os.ReadFile(partNamesPath)
if err != nil {
logger.Panicf("FATAL: cannot read %s file: %s", partsFilename, err)
}
var partNames partNamesJSON
if err := json.Unmarshal(data, &partNames); err != nil {
logger.Panicf("FATAL: cannot parse %s: %s", partNamesPath, err)
}
return partNames.Small, partNames.Big
}
// The partsFilename is missing. This is the upgrade from versions previous to v1.90.0.
// Read part names from smallPartsPath and bigPartsPath directories
partNamesSmall := mustReadPartNamesFromDir(smallPartsPath)
partNamesBig := mustReadPartNamesFromDir(bigPartsPath)
return partNamesSmall, partNamesBig
}
func mustReadPartNamesFromDir(srcDir string) []string {
if !fs.IsPathExist(srcDir) {
return nil
}
des := fs.MustReadDir(srcDir)
var partNames []string
for _, de := range des {
if !fs.IsDirOrSymlink(de) {
// Skip non-directories.
continue
}
partName := de.Name()
if isSpecialDir(partName) {
// Skip special dirs.
continue
}
partNames = append(partNames, partName)
}
return partNames
}
func isSpecialDir(name string) bool {
return name == "tmp" || name == "txn" || name == snapshotsDirname || fs.IsScheduledForRemoval(name)
}