VictoriaMetrics/lib/logstorage/storage.go
Aliaksandr Valialkin d52fd73f18
all: add up to 10% random jitter to the interval between periodic tasks performed by various components
This should smooth CPU and RAM usage spikes related to these periodic tasks,
by reducing the probability that multiple concurrent periodic tasks are performed at the same time.
2024-01-22 18:39:16 +02:00

565 lines
16 KiB
Go

package logstorage
import (
"os"
"path/filepath"
"sort"
"sync"
"sync/atomic"
"time"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/fs"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/logger"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/memory"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/timeutil"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/workingsetcache"
)
// StorageStats represents stats for the storage. It may be obtained by calling Storage.UpdateStats().
type StorageStats struct {
// RowsDroppedTooBigTimestamp is the number of rows dropped during data ingestion because their timestamp is smaller than the minimum allowed
RowsDroppedTooBigTimestamp uint64
// RowsDroppedTooSmallTimestamp is the number of rows dropped during data ingestion because their timestamp is bigger than the maximum allowed
RowsDroppedTooSmallTimestamp uint64
// PartitionsCount is the number of partitions in the storage
PartitionsCount uint64
// IsReadOnly indicates whether the storage is read-only.
IsReadOnly bool
// PartitionStats contains partition stats.
PartitionStats
}
// Reset resets s.
func (s *StorageStats) Reset() {
*s = StorageStats{}
}
// StorageConfig is the config for the Storage.
type StorageConfig struct {
// Retention is the retention for the ingested data.
//
// Older data is automatically deleted.
Retention time.Duration
// FlushInterval is the interval for flushing the in-memory data to disk at the Storage
FlushInterval time.Duration
// FutureRetention is the allowed retention from the current time to future for the ingested data.
//
// Log entries with timestamps bigger than now+FutureRetention are ignored.
FutureRetention time.Duration
// MinFreeDiskSpaceBytes is the minimum free disk space at storage path after which the storage stops accepting new data.
MinFreeDiskSpaceBytes int64
// LogNewStreams indicates whether to log newly created log streams.
//
// This can be useful for debugging of high cardinality issues.
// https://docs.victoriametrics.com/VictoriaLogs/keyConcepts.html#high-cardinality
LogNewStreams bool
// LogIngestedRows indicates whether to log the ingested log entries.
//
// This can be useful for debugging of data ingestion.
LogIngestedRows bool
}
// Storage is the storage for log entries.
type Storage struct {
rowsDroppedTooBigTimestamp uint64
rowsDroppedTooSmallTimestamp uint64
// path is the path to the Storage directory
path string
// retention is the retention for the stored data
//
// older data is automatically deleted
retention time.Duration
// flushInterval is the interval for flushing in-memory data to disk
flushInterval time.Duration
// futureRetention is the maximum allowed interval to write data into the future
futureRetention time.Duration
// minFreeDiskSpaceBytes is the minimum free disk space at path after which the storage stops accepting new data
minFreeDiskSpaceBytes uint64
// logNewStreams instructs to log new streams if it is set to true
logNewStreams bool
// logIngestedRows instructs to log all the ingested log entries if it is set to true
logIngestedRows bool
// flockF is a file, which makes sure that the Storage is opened by a single process
flockF *os.File
// partitions is a list of partitions for the Storage.
//
// It must be accessed under partitionsLock.
partitions []*partitionWrapper
// ptwHot is the "hot" partition, were the last rows were ingested.
//
// It must be accessed under partitionsLock.
ptwHot *partitionWrapper
// partitionsLock protects partitions and ptwHot.
partitionsLock sync.Mutex
// stopCh is closed when the Storage must be stopped.
stopCh chan struct{}
// wg is used for waiting for background workers at MustClose().
wg sync.WaitGroup
// streamIDCache caches (partition, streamIDs) seen during data ingestion.
//
// It reduces the load on persistent storage during data ingestion by skipping
// the check whether the given stream is already registered in the persistent storage.
streamIDCache *workingsetcache.Cache
// streamTagsCache caches StreamTags entries keyed by streamID.
//
// There is no need to put partition into the key for StreamTags,
// since StreamTags are uniquely identified by streamID.
//
// It reduces the load on persistent storage during querying
// when StreamTags must be found for the particular streamID
streamTagsCache *workingsetcache.Cache
// streamFilterCache caches streamIDs keyed by (partition, []TenanID, StreamFilter).
//
// It reduces the load on persistent storage during querying by _stream:{...} filter.
streamFilterCache *workingsetcache.Cache
}
type partitionWrapper struct {
// refCount is the number of active references to p.
// When it reaches zero, then the p is closed.
refCount int32
// The flag, which is set when the partition must be deleted after refCount reaches zero.
mustBeDeleted uint32
// day is the day for the partition in the unix timestamp divided by the number of seconds in the day.
day int64
// pt is the wrapped partition.
pt *partition
}
func newPartitionWrapper(pt *partition, day int64) *partitionWrapper {
pw := &partitionWrapper{
day: day,
pt: pt,
}
pw.incRef()
return pw
}
func (ptw *partitionWrapper) incRef() {
atomic.AddInt32(&ptw.refCount, 1)
}
func (ptw *partitionWrapper) decRef() {
n := atomic.AddInt32(&ptw.refCount, -1)
if n > 0 {
return
}
deletePath := ""
if atomic.LoadUint32(&ptw.mustBeDeleted) != 0 {
deletePath = ptw.pt.path
}
// Close pw.pt, since nobody refers to it.
mustClosePartition(ptw.pt)
ptw.pt = nil
// Delete partition if needed.
if deletePath != "" {
mustDeletePartition(deletePath)
}
}
func (ptw *partitionWrapper) canAddAllRows(lr *LogRows) bool {
minTimestamp := ptw.day * nsecPerDay
maxTimestamp := minTimestamp + nsecPerDay - 1
for _, ts := range lr.timestamps {
if ts < minTimestamp || ts > maxTimestamp {
return false
}
}
return true
}
// mustCreateStorage creates Storage at the given path.
func mustCreateStorage(path string) {
fs.MustMkdirFailIfExist(path)
partitionsPath := filepath.Join(path, partitionsDirname)
fs.MustMkdirFailIfExist(partitionsPath)
}
// MustOpenStorage opens Storage at the given path.
//
// MustClose must be called on the returned Storage when it is no longer needed.
func MustOpenStorage(path string, cfg *StorageConfig) *Storage {
flushInterval := cfg.FlushInterval
if flushInterval < time.Second {
flushInterval = time.Second
}
retention := cfg.Retention
if retention < 24*time.Hour {
retention = 24 * time.Hour
}
futureRetention := cfg.FutureRetention
if futureRetention < 24*time.Hour {
futureRetention = 24 * time.Hour
}
var minFreeDiskSpaceBytes uint64
if cfg.MinFreeDiskSpaceBytes >= 0 {
minFreeDiskSpaceBytes = uint64(cfg.MinFreeDiskSpaceBytes)
}
if !fs.IsPathExist(path) {
mustCreateStorage(path)
}
flockF := fs.MustCreateFlockFile(path)
// Load caches
mem := memory.Allowed()
streamIDCachePath := filepath.Join(path, cacheDirname, streamIDCacheFilename)
streamIDCache := workingsetcache.Load(streamIDCachePath, mem/16)
streamTagsCache := workingsetcache.New(mem / 10)
streamFilterCache := workingsetcache.New(mem / 10)
s := &Storage{
path: path,
retention: retention,
flushInterval: flushInterval,
futureRetention: futureRetention,
minFreeDiskSpaceBytes: minFreeDiskSpaceBytes,
logNewStreams: cfg.LogNewStreams,
logIngestedRows: cfg.LogIngestedRows,
flockF: flockF,
stopCh: make(chan struct{}),
streamIDCache: streamIDCache,
streamTagsCache: streamTagsCache,
streamFilterCache: streamFilterCache,
}
partitionsPath := filepath.Join(path, partitionsDirname)
fs.MustMkdirIfNotExist(partitionsPath)
des := fs.MustReadDir(partitionsPath)
ptws := make([]*partitionWrapper, len(des))
for i, de := range des {
fname := de.Name()
// Parse the day for the partition
t, err := time.Parse(partitionNameFormat, fname)
if err != nil {
logger.Panicf("FATAL: cannot parse partition filename %q at %q; it must be in the form YYYYMMDD: %s", fname, partitionsPath, err)
}
day := t.UTC().UnixNano() / nsecPerDay
partitionPath := filepath.Join(partitionsPath, fname)
pt := mustOpenPartition(s, partitionPath)
ptws[i] = newPartitionWrapper(pt, day)
}
sort.Slice(ptws, func(i, j int) bool {
return ptws[i].day < ptws[j].day
})
// Delete partitions from the future if needed
maxAllowedDay := s.getMaxAllowedDay()
j := len(ptws) - 1
for j >= 0 {
ptw := ptws[j]
if ptw.day <= maxAllowedDay {
break
}
logger.Infof("the partition %s is scheduled to be deleted because it is outside the -futureRetention=%dd", ptw.pt.path, durationToDays(s.futureRetention))
atomic.StoreUint32(&ptw.mustBeDeleted, 1)
ptw.decRef()
j--
}
j++
for i := j; i < len(ptws); i++ {
ptws[i] = nil
}
ptws = ptws[:j]
s.partitions = ptws
s.runRetentionWatcher()
return s
}
const partitionNameFormat = "20060102"
func (s *Storage) runRetentionWatcher() {
s.wg.Add(1)
go func() {
s.watchRetention()
s.wg.Done()
}()
}
func (s *Storage) watchRetention() {
d := timeutil.AddJitterToDuration(time.Hour)
ticker := time.NewTicker(d)
defer ticker.Stop()
for {
var ptwsToDelete []*partitionWrapper
minAllowedDay := s.getMinAllowedDay()
s.partitionsLock.Lock()
// Delete outdated partitions.
// s.partitions are sorted by day, so the partitions, which can become outdated, are located at the beginning of the list
for _, ptw := range s.partitions {
if ptw.day >= minAllowedDay {
break
}
ptwsToDelete = append(ptwsToDelete, ptw)
if ptw == s.ptwHot {
s.ptwHot = nil
}
}
for i := range ptwsToDelete {
s.partitions[i] = nil
}
s.partitions = s.partitions[len(ptwsToDelete):]
s.partitionsLock.Unlock()
for _, ptw := range ptwsToDelete {
logger.Infof("the partition %s is scheduled to be deleted because it is outside the -retentionPeriod=%dd", ptw.pt.path, durationToDays(s.retention))
atomic.StoreUint32(&ptw.mustBeDeleted, 1)
ptw.decRef()
}
select {
case <-s.stopCh:
return
case <-ticker.C:
}
}
}
func (s *Storage) getMinAllowedDay() int64 {
return time.Now().UTC().Add(-s.retention).UnixNano() / nsecPerDay
}
func (s *Storage) getMaxAllowedDay() int64 {
return time.Now().UTC().Add(s.futureRetention).UnixNano() / nsecPerDay
}
// MustClose closes s.
//
// It is expected that nobody uses the storage at the close time.
func (s *Storage) MustClose() {
// Stop background workers
close(s.stopCh)
s.wg.Wait()
// Close partitions
for _, pw := range s.partitions {
pw.decRef()
if pw.refCount != 0 {
logger.Panicf("BUG: there are %d users of partition", pw.refCount)
}
}
s.partitions = nil
s.ptwHot = nil
// Save caches
streamIDCachePath := filepath.Join(s.path, cacheDirname, streamIDCacheFilename)
if err := s.streamIDCache.Save(streamIDCachePath); err != nil {
logger.Panicf("FATAL: cannot save streamID cache to %q: %s", streamIDCachePath, err)
}
s.streamIDCache.Stop()
s.streamIDCache = nil
s.streamTagsCache.Stop()
s.streamTagsCache = nil
s.streamFilterCache.Stop()
s.streamFilterCache = nil
// release lock file
fs.MustClose(s.flockF)
s.flockF = nil
s.path = ""
}
// MustAddRows adds lr to s.
//
// It is recommended checking whether the s is in read-only mode by calling IsReadOnly()
// before calling MustAddRows.
func (s *Storage) MustAddRows(lr *LogRows) {
// Fast path - try adding all the rows to the hot partition
s.partitionsLock.Lock()
ptwHot := s.ptwHot
if ptwHot != nil {
ptwHot.incRef()
}
s.partitionsLock.Unlock()
if ptwHot != nil {
if ptwHot.canAddAllRows(lr) {
ptwHot.pt.mustAddRows(lr)
ptwHot.decRef()
return
}
ptwHot.decRef()
}
// Slow path - rows cannot be added to the hot partition, so split rows among available partitions
minAllowedDay := s.getMinAllowedDay()
maxAllowedDay := s.getMaxAllowedDay()
m := make(map[int64]*LogRows)
for i, ts := range lr.timestamps {
day := ts / nsecPerDay
if day < minAllowedDay {
rf := RowFormatter(lr.rows[i])
tsf := TimeFormatter(ts)
minAllowedTsf := TimeFormatter(minAllowedDay * nsecPerDay)
tooSmallTimestampLogger.Warnf("skipping log entry with too small timestamp=%s; it must be bigger than %s according "+
"to the configured -retentionPeriod=%dd. See https://docs.victoriametrics.com/VictoriaLogs/#retention ; "+
"log entry: %s", &tsf, &minAllowedTsf, durationToDays(s.retention), &rf)
atomic.AddUint64(&s.rowsDroppedTooSmallTimestamp, 1)
continue
}
if day > maxAllowedDay {
rf := RowFormatter(lr.rows[i])
tsf := TimeFormatter(ts)
maxAllowedTsf := TimeFormatter(maxAllowedDay * nsecPerDay)
tooBigTimestampLogger.Warnf("skipping log entry with too big timestamp=%s; it must be smaller than %s according "+
"to the configured -futureRetention=%dd; see https://docs.victoriametrics.com/VictoriaLogs/#retention ; "+
"log entry: %s", &tsf, &maxAllowedTsf, durationToDays(s.futureRetention), &rf)
atomic.AddUint64(&s.rowsDroppedTooBigTimestamp, 1)
continue
}
lrPart := m[day]
if lrPart == nil {
lrPart = GetLogRows(nil, nil)
m[day] = lrPart
}
lrPart.mustAddInternal(lr.streamIDs[i], ts, lr.rows[i], lr.streamTagsCanonicals[i])
}
for day, lrPart := range m {
ptw := s.getPartitionForDay(day)
ptw.pt.mustAddRows(lrPart)
ptw.decRef()
PutLogRows(lrPart)
}
}
var tooSmallTimestampLogger = logger.WithThrottler("too_small_timestamp", 5*time.Second)
var tooBigTimestampLogger = logger.WithThrottler("too_big_timestamp", 5*time.Second)
const nsecPerDay = 24 * 3600 * 1e9
// TimeFormatter implements fmt.Stringer for timestamp in nanoseconds
type TimeFormatter int64
// String returns human-readable representation for tf.
func (tf *TimeFormatter) String() string {
ts := int64(*tf)
t := time.Unix(0, ts).UTC()
return t.Format(time.RFC3339Nano)
}
func (s *Storage) getPartitionForDay(day int64) *partitionWrapper {
s.partitionsLock.Lock()
// Search for the partition using binary search
ptws := s.partitions
n := sort.Search(len(ptws), func(i int) bool {
return ptws[i].day >= day
})
var ptw *partitionWrapper
if n < len(ptws) {
ptw = ptws[n]
if ptw.day != day {
ptw = nil
}
}
if ptw == nil {
// Missing partition for the given day. Create it.
fname := time.Unix(0, day*nsecPerDay).UTC().Format(partitionNameFormat)
partitionPath := filepath.Join(s.path, partitionsDirname, fname)
mustCreatePartition(partitionPath)
pt := mustOpenPartition(s, partitionPath)
ptw = newPartitionWrapper(pt, day)
if n == len(ptws) {
ptws = append(ptws, ptw)
} else {
ptws = append(ptws[:n+1], ptws[n:]...)
ptws[n] = ptw
}
s.partitions = ptws
}
s.ptwHot = ptw
ptw.incRef()
s.partitionsLock.Unlock()
return ptw
}
// UpdateStats updates ss for the given s.
func (s *Storage) UpdateStats(ss *StorageStats) {
ss.RowsDroppedTooBigTimestamp += atomic.LoadUint64(&s.rowsDroppedTooBigTimestamp)
ss.RowsDroppedTooSmallTimestamp += atomic.LoadUint64(&s.rowsDroppedTooSmallTimestamp)
s.partitionsLock.Lock()
ss.PartitionsCount += uint64(len(s.partitions))
for _, ptw := range s.partitions {
ptw.pt.updateStats(&ss.PartitionStats)
}
s.partitionsLock.Unlock()
ss.IsReadOnly = s.IsReadOnly()
}
// IsReadOnly returns true if s is in read-only mode.
func (s *Storage) IsReadOnly() bool {
available := fs.MustGetFreeSpace(s.path)
return available < s.minFreeDiskSpaceBytes
}
func (s *Storage) debugFlush() {
s.partitionsLock.Lock()
ptws := append([]*partitionWrapper{}, s.partitions...)
for _, ptw := range ptws {
ptw.incRef()
}
s.partitionsLock.Unlock()
for _, ptw := range ptws {
ptw.pt.debugFlush()
ptw.decRef()
}
}
func durationToDays(d time.Duration) int64 {
return int64(d / (time.Hour * 24))
}