VictoriaMetrics/lib/logstorage/storage.go

533 lines
14 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/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
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
// 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
// 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
}
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,
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() {
ticker := time.NewTicker(time.Hour)
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)
}
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
// 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.
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 && ptwHot.pt != 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()
}
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))
}