package logstorage import ( "encoding/json" "fmt" "math" "os" "path/filepath" "sort" "sync" "sync/atomic" "time" "github.com/VictoriaMetrics/VictoriaMetrics/lib/cgroup" "github.com/VictoriaMetrics/VictoriaMetrics/lib/fs" "github.com/VictoriaMetrics/VictoriaMetrics/lib/logger" "github.com/VictoriaMetrics/VictoriaMetrics/lib/memory" ) // 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. // // The actual number of inmemory parts may exceed this value if in-memory mergers // cannot keep up with the rate of creating new in-memory parts. const maxInmemoryPartsPerPartition = 20 // 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 // 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 // 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 // datadb represents a database with log data type datadb struct { // mergeIdx is used for generating unique directory names for parts mergeIdx atomic.Uint64 inmemoryMergesTotal atomic.Uint64 inmemoryActiveMerges atomic.Int64 smallPartMergesTotal atomic.Uint64 smallPartActiveMerges atomic.Int64 bigPartMergesTotal atomic.Uint64 bigPartActiveMerges atomic.Int64 // pt is the partition the datadb belongs to pt *partition // path is the path to the directory with log data path string // flushInterval is interval for flushing the inmemory parts to disk flushInterval time.Duration // inmemoryParts contains a list of inmemory parts inmemoryParts []*partWrapper // smallParts contains a list of file-based small parts smallParts []*partWrapper // bigParts contains a list of file-based big parts bigParts []*partWrapper // partsLock protects parts from concurrent access partsLock sync.Mutex // wg is used for determining when background workers stop // // wg.Add() must be called under partsLock after checking whether stopCh isn't closed. // This should prevent from calling wg.Add() after stopCh is closed and wg.Wait() is called. wg sync.WaitGroup // stopCh is used for notifying background workers to stop // // It must be closed under partsLock in order to prevent from calling wg.Add() // after stopCh is closed. stopCh chan struct{} } // partWrapper is a wrapper for opened part. type partWrapper struct { // refCount is the number of references to p. // // When the number of references reaches zero, then p is closed. refCount atomic.Int32 // The flag, which is set when the part must be deleted after refCount reaches zero. mustDrop atomic.Bool // p is an opened part p *part // mp references inmemory part used for initializing p. mp *inmemoryPart // isInMerge is set to true if the part takes part in merge. isInMerge bool // The deadline when in-memory part must be flushed to disk. flushDeadline time.Time } func (pw *partWrapper) incRef() { pw.refCount.Add(1) } func (pw *partWrapper) decRef() { n := pw.refCount.Add(-1) if n > 0 { return } deletePath := "" if pw.mp == nil { if pw.mustDrop.Load() { deletePath = pw.p.path } } else { putInmemoryPart(pw.mp) pw.mp = nil } mustClosePart(pw.p) pw.p = nil if deletePath != "" { fs.MustRemoveAll(deletePath) } } func mustCreateDatadb(path string) { fs.MustMkdirFailIfExist(path) mustWritePartNames(path, nil, nil) } // mustOpenDatadb opens datadb at the given path with the given flushInterval for in-memory data. func mustOpenDatadb(pt *partition, path string, flushInterval time.Duration) *datadb { // Remove temporary directories, which may be left after unclean shutdown. fs.MustRemoveTemporaryDirs(path) partNames := mustReadPartNames(path) mustRemoveUnusedDirs(path, partNames) var smallParts []*partWrapper var bigParts []*partWrapper for _, partName := range partNames { // Make sure the partName exists on disk. // If it is missing, then manual action from the user is needed, // since this is unexpected state, which cannot occur under normal operation, // including unclean shutdown. partPath := filepath.Join(path, partName) if !fs.IsPathExist(partPath) { partsFile := filepath.Join(path, partsFilename) logger.Panicf("FATAL: part %q is listed in %q, but is missing on disk; "+ "ensure %q contents is not corrupted; remove %q to rebuild its' content from the list of existing parts", partPath, partsFile, partsFile, partsFile) } p := mustOpenFilePart(pt, partPath) pw := newPartWrapper(p, nil, time.Time{}) if p.ph.CompressedSizeBytes > getMaxInmemoryPartSize() { bigParts = append(bigParts, pw) } else { smallParts = append(smallParts, pw) } } ddb := &datadb{ pt: pt, flushInterval: flushInterval, path: path, smallParts: smallParts, bigParts: bigParts, stopCh: make(chan struct{}), } ddb.mergeIdx.Store(uint64(time.Now().UnixNano())) ddb.startBackgroundWorkers() return ddb } func (ddb *datadb) startBackgroundWorkers() { // Start file parts mergers, so they could start merging unmerged parts if needed. // There is no need in starting in-memory parts mergers, since there are no in-memory parts yet. ddb.startSmallPartsMergers() ddb.startBigPartsMergers() ddb.startInmemoryPartsFlusher() } var ( inmemoryPartsConcurrencyCh = make(chan struct{}, cgroup.AvailableCPUs()) smallPartsConcurrencyCh = make(chan struct{}, cgroup.AvailableCPUs()) bigPartsConcurrencyCh = make(chan struct{}, cgroup.AvailableCPUs()) ) func (ddb *datadb) startSmallPartsMergers() { ddb.partsLock.Lock() for i := 0; i < cap(smallPartsConcurrencyCh); i++ { ddb.startSmallPartsMergerLocked() } ddb.partsLock.Unlock() } func (ddb *datadb) startBigPartsMergers() { ddb.partsLock.Lock() for i := 0; i < cap(bigPartsConcurrencyCh); i++ { ddb.startBigPartsMergerLocked() } ddb.partsLock.Unlock() } func (ddb *datadb) startInmemoryPartsMergerLocked() { if needStop(ddb.stopCh) { return } ddb.wg.Add(1) go func() { ddb.inmemoryPartsMerger() ddb.wg.Done() }() } func (ddb *datadb) startSmallPartsMergerLocked() { if needStop(ddb.stopCh) { return } ddb.wg.Add(1) go func() { ddb.smallPartsMerger() ddb.wg.Done() }() } func (ddb *datadb) startBigPartsMergerLocked() { if needStop(ddb.stopCh) { return } ddb.wg.Add(1) go func() { ddb.bigPartsMerger() ddb.wg.Done() }() } func (ddb *datadb) startInmemoryPartsFlusher() { ddb.wg.Add(1) go func() { ddb.inmemoryPartsFlusher() ddb.wg.Done() }() } func (ddb *datadb) inmemoryPartsFlusher() { // Do not add jitter to d in order to guarantee the flush interval ticker := time.NewTicker(dataFlushInterval) defer ticker.Stop() for { select { case <-ddb.stopCh: return case <-ticker.C: ddb.mustFlushInmemoryPartsToFiles(false) } } } func (ddb *datadb) mustFlushInmemoryPartsToFiles(isFinal bool) { currentTime := time.Now() var pws []*partWrapper ddb.partsLock.Lock() for _, pw := range ddb.inmemoryParts { if !pw.isInMerge && (isFinal || pw.flushDeadline.Before(currentTime)) { pw.isInMerge = true pws = append(pws, pw) } } ddb.partsLock.Unlock() ddb.mustMergePartsToFiles(pws) } func (ddb *datadb) mustMergePartsToFiles(pws []*partWrapper) { wg := getWaitGroup() for len(pws) > 0 { pwsToMerge, pwsRemaining := getPartsForOptimalMerge(pws) wg.Add(1) inmemoryPartsConcurrencyCh <- struct{}{} go func(pwsChunk []*partWrapper) { defer func() { <-inmemoryPartsConcurrencyCh wg.Done() }() ddb.mustMergeParts(pwsChunk, true) }(pwsToMerge) pws = pwsRemaining } wg.Wait() putWaitGroup(wg) } // getPartsForOptimalMerge returns parts from pws for optimal merge, plus the remaining parts. // // the pws items are replaced by nil after the call. This is needed for helping Go GC to reclaim the referenced items. func getPartsForOptimalMerge(pws []*partWrapper) ([]*partWrapper, []*partWrapper) { pwsToMerge := appendPartsToMerge(nil, pws, math.MaxUint64) if len(pwsToMerge) == 0 { return pws, nil } m := partsToMap(pwsToMerge) pwsRemaining := make([]*partWrapper, 0, len(pws)-len(pwsToMerge)) for _, pw := range pws { if _, ok := m[pw]; !ok { pwsRemaining = append(pwsRemaining, pw) } } // Clear references to pws items, so they could be reclaimed faster by Go GC. for i := range pws { pws[i] = nil } return pwsToMerge, pwsRemaining } 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 (ddb *datadb) inmemoryPartsMerger() { for { if needStop(ddb.stopCh) { return } maxOutBytes := ddb.getMaxBigPartSize() ddb.partsLock.Lock() pws := getPartsToMergeLocked(ddb.inmemoryParts, maxOutBytes) ddb.partsLock.Unlock() if len(pws) == 0 { // Nothing to merge return } inmemoryPartsConcurrencyCh <- struct{}{} ddb.mustMergeParts(pws, false) <-inmemoryPartsConcurrencyCh } } func (ddb *datadb) smallPartsMerger() { for { if needStop(ddb.stopCh) { return } maxOutBytes := ddb.getMaxBigPartSize() ddb.partsLock.Lock() pws := getPartsToMergeLocked(ddb.smallParts, maxOutBytes) ddb.partsLock.Unlock() if len(pws) == 0 { // Nothing to merge return } smallPartsConcurrencyCh <- struct{}{} ddb.mustMergeParts(pws, false) <-smallPartsConcurrencyCh } } func (ddb *datadb) bigPartsMerger() { for { if needStop(ddb.stopCh) { return } maxOutBytes := ddb.getMaxBigPartSize() ddb.partsLock.Lock() pws := getPartsToMergeLocked(ddb.bigParts, maxOutBytes) ddb.partsLock.Unlock() if len(pws) == 0 { // Nothing to merge return } bigPartsConcurrencyCh <- struct{}{} ddb.mustMergeParts(pws, false) <-bigPartsConcurrencyCh } } // getPartsToMergeLocked returns optimal parts to merge from pws. // // The summary size of the returned parts must be smaller than maxOutBytes. func getPartsToMergeLocked(pws []*partWrapper, maxOutBytes uint64) []*partWrapper { pwsRemaining := make([]*partWrapper, 0, len(pws)) for _, pw := range pws { if !pw.isInMerge { pwsRemaining = append(pwsRemaining, pw) } } pwsToMerge := appendPartsToMerge(nil, pwsRemaining, maxOutBytes) for _, pw := range pwsToMerge { if pw.isInMerge { logger.Panicf("BUG: partWrapper.isInMerge cannot be set") } pw.isInMerge = true } return pwsToMerge } func assertIsInMerge(pws []*partWrapper) { for _, pw := range pws { if !pw.isInMerge { logger.Panicf("BUG: partWrapper.isInMerge unexpectedly set to false") } } } // mustMergeParts merges pws to a single resulting part. // // if isFinal is set, then the resulting part is guaranteed to be saved to disk. // The pws may remain unmerged after returning from the function if there is no enough disk space. // // All the parts inside pws must have isInMerge field set to true. // The isInMerge field inside pws parts is set to false before returning from the function. func (ddb *datadb) mustMergeParts(pws []*partWrapper, isFinal bool) { if len(pws) == 0 { // Nothing to merge. return } assertIsInMerge(pws) defer ddb.releasePartsToMerge(pws) startTime := time.Now() dstPartType := ddb.getDstPartType(pws, isFinal) if dstPartType != partInmemory { // Make sure there is enough disk space for performing the merge partsSize := getCompressedSize(pws) needReleaseDiskSpace := tryReserveDiskSpace(ddb.path, partsSize) if needReleaseDiskSpace { defer releaseDiskSpace(partsSize) } else { if !isFinal { // There is no enough disk space for performing the non-final merge. return } // Try performing final merge even if there is no enough disk space // in order to persist in-memory data to disk. // It is better to crash on out of memory error in this case. } } switch dstPartType { case partInmemory: ddb.inmemoryMergesTotal.Add(1) ddb.inmemoryActiveMerges.Add(1) defer ddb.inmemoryActiveMerges.Add(-1) case partSmall: ddb.smallPartMergesTotal.Add(1) ddb.smallPartActiveMerges.Add(1) defer ddb.smallPartActiveMerges.Add(-1) case partBig: ddb.bigPartMergesTotal.Add(1) ddb.bigPartActiveMerges.Add(1) defer ddb.bigPartActiveMerges.Add(-1) default: logger.Panicf("BUG: unknown partType=%d", dstPartType) } // Initialize destination paths. mergeIdx := ddb.nextMergeIdx() dstPartPath := ddb.getDstPartPath(dstPartType, mergeIdx) if 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 := ddb.openCreatedPart(&mp.ph, pws, nil, dstPartPath) ddb.swapSrcWithDstParts(pws, pwNew, dstPartType) return } // 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.ph.CompressedSizeBytes srcRowsCount += pw.p.ph.RowsCount srcBlocksCount += pw.p.ph.BlocksCount } bsw := getBlockStreamWriter() var mpNew *inmemoryPart if dstPartType == partInmemory { mpNew = getInmemoryPart() bsw.MustInitForInmemoryPart(mpNew) } else { nocache := dstPartType == partBig bsw.MustInitForFilePart(dstPartPath, nocache) } // Merge source parts to destination part. var ph partHeader stopCh := ddb.stopCh if isFinal { // The final merge shouldn't be stopped even if ddb.stopCh is closed. stopCh = nil } mustMergeBlockStreams(&ph, bsw, bsrs, stopCh) putBlockStreamWriter(bsw) for _, bsr := range bsrs { putBlockStreamReader(bsr) } // Persist partHeader for destination part after the merge. if mpNew != nil { mpNew.ph = ph } else { ph.mustWriteMetadata(dstPartPath) // Make sure the created part directory listing is synced. fs.MustSyncPath(dstPartPath) } if needStop(stopCh) { // Remove incomplete destination part if dstPartType != partInmemory { fs.MustRemoveAll(dstPartPath) } return } // Atomically swap the source parts with the newly created part. pwNew := ddb.openCreatedPart(&ph, pws, mpNew, dstPartPath) dstSize := uint64(0) dstRowsCount := uint64(0) dstBlocksCount := uint64(0) if pwNew != nil { pDst := pwNew.p dstSize = pDst.ph.CompressedSizeBytes dstRowsCount = pDst.ph.RowsCount dstBlocksCount = pDst.ph.BlocksCount } ddb.swapSrcWithDstParts(pws, pwNew, dstPartType) d := time.Since(startTime) if d <= time.Minute { return } // 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) } func (ddb *datadb) nextMergeIdx() uint64 { return ddb.mergeIdx.Add(1) } type partType int var ( partInmemory = partType(0) partSmall = partType(1) partBig = partType(2) ) func (ddb *datadb) getDstPartType(pws []*partWrapper, isFinal bool) partType { dstPartSize := getCompressedSize(pws) if dstPartSize > ddb.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 (ddb *datadb) getDstPartPath(dstPartType partType, mergeIdx uint64) string { ptPath := ddb.path dstPartPath := "" if dstPartType != partInmemory { dstPartPath = filepath.Join(ptPath, fmt.Sprintf("%016X", mergeIdx)) } return dstPartPath } func (ddb *datadb) 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 } var p *part var flushDeadline time.Time if mpNew != nil { // Open the created part from memory. p = mustOpenInmemoryPart(ddb.pt, mpNew) flushDeadline = ddb.getFlushToDiskDeadline(pws) } else { // Open the created part from disk. p = mustOpenFilePart(ddb.pt, dstPartPath) } return newPartWrapper(p, mpNew, flushDeadline) } func (ddb *datadb) mustAddRows(lr *LogRows) { if len(lr.streamIDs) == 0 { return } inmemoryPartsConcurrencyCh <- struct{}{} mp := getInmemoryPart() mp.mustInitFromRows(lr) p := mustOpenInmemoryPart(ddb.pt, mp) <-inmemoryPartsConcurrencyCh flushDeadline := time.Now().Add(ddb.flushInterval) pw := newPartWrapper(p, mp, flushDeadline) ddb.partsLock.Lock() ddb.inmemoryParts = append(ddb.inmemoryParts, pw) ddb.startInmemoryPartsMergerLocked() ddb.partsLock.Unlock() } // DatadbStats contains various stats for datadb. type DatadbStats struct { // InmemoryMergesTotal is the number of inmemory merges performed in the given datadb. InmemoryMergesTotal uint64 // InmemoryActiveMerges is the number of currently active inmemory merges performed by the given datadb. InmemoryActiveMerges uint64 // SmallPartMergesTotal is the number of small file merges performed in the given datadb. SmallPartMergesTotal uint64 // SmallPartActiveMerges is the number of currently active small file merges performed by the given datadb. SmallPartActiveMerges uint64 // BigPartMergesTotal is the number of big file merges performed in the given datadb. BigPartMergesTotal uint64 // BigPartActiveMerges is the number of currently active big file merges performed by the given datadb. BigPartActiveMerges uint64 // InmemoryRowsCount is the number of rows, which weren't flushed to disk yet. InmemoryRowsCount uint64 // SmallPartRowsCount is the number of rows stored on disk in small parts. SmallPartRowsCount uint64 // BigPartRowsCount is the number of rows stored on disk in big parts. BigPartRowsCount uint64 // InmemoryParts is the number of in-memory parts, which weren't flushed to disk yet. InmemoryParts uint64 // SmallParts is the number of file-based small parts stored on disk. SmallParts uint64 // BigParts is the number of file-based big parts stored on disk. BigParts uint64 // InmemoryBlocks is the number of in-memory blocks, which weren't flushed to disk yet. InmemoryBlocks uint64 // SmallPartBlocks is the number of file-based small blocks stored on disk. SmallPartBlocks uint64 // BigPartBlocks is the number of file-based big blocks stored on disk. BigPartBlocks uint64 // CompressedInmemorySize is the size of compressed data stored in memory. CompressedInmemorySize uint64 // CompressedSmallPartSize is the size of compressed small parts data stored on disk. CompressedSmallPartSize uint64 // CompressedBigPartSize is the size of compressed big data stored on disk. CompressedBigPartSize uint64 // UncompressedInmemorySize is the size of uncompressed data stored in memory. UncompressedInmemorySize uint64 // UncompressedSmallPartSize is the size of uncompressed small data stored on disk. UncompressedSmallPartSize uint64 // UncompressedBigPartSize is the size of uncompressed big data stored on disk. UncompressedBigPartSize uint64 } func (s *DatadbStats) reset() { *s = DatadbStats{} } // RowsCount returns the number of rows stored in datadb. func (s *DatadbStats) RowsCount() uint64 { return s.InmemoryRowsCount + s.SmallPartRowsCount + s.BigPartRowsCount } // updateStats updates s with ddb stats. func (ddb *datadb) updateStats(s *DatadbStats) { s.InmemoryMergesTotal += ddb.inmemoryMergesTotal.Load() s.InmemoryActiveMerges += uint64(ddb.inmemoryActiveMerges.Load()) s.SmallPartMergesTotal += ddb.smallPartMergesTotal.Load() s.SmallPartActiveMerges += uint64(ddb.smallPartActiveMerges.Load()) s.BigPartMergesTotal += ddb.bigPartMergesTotal.Load() s.BigPartActiveMerges += uint64(ddb.bigPartActiveMerges.Load()) ddb.partsLock.Lock() s.InmemoryRowsCount += getRowsCount(ddb.inmemoryParts) s.SmallPartRowsCount += getRowsCount(ddb.smallParts) s.BigPartRowsCount += getRowsCount(ddb.bigParts) s.InmemoryParts += uint64(len(ddb.inmemoryParts)) s.SmallParts += uint64(len(ddb.smallParts)) s.BigParts += uint64(len(ddb.bigParts)) s.InmemoryBlocks += getBlocksCount(ddb.inmemoryParts) s.SmallPartBlocks += getBlocksCount(ddb.smallParts) s.BigPartBlocks += getBlocksCount(ddb.bigParts) s.CompressedInmemorySize += getCompressedSize(ddb.inmemoryParts) s.CompressedSmallPartSize += getCompressedSize(ddb.smallParts) s.CompressedBigPartSize += getCompressedSize(ddb.bigParts) s.UncompressedInmemorySize += getUncompressedSize(ddb.inmemoryParts) s.UncompressedSmallPartSize += getUncompressedSize(ddb.smallParts) s.UncompressedBigPartSize += getUncompressedSize(ddb.bigParts) ddb.partsLock.Unlock() } // debugFlush() makes sure that the recently ingested data is availalbe for search. func (ddb *datadb) debugFlush() { // Nothing to do, since all the ingested data is available for search via ddb.inmemoryParts. } func (ddb *datadb) swapSrcWithDstParts(pws []*partWrapper, pwNew *partWrapper, dstPartType partType) { // Atomically unregister old parts and add new part to pt. partsToRemove := partsToMap(pws) removedInmemoryParts := 0 removedSmallParts := 0 removedBigParts := 0 ddb.partsLock.Lock() ddb.inmemoryParts, removedInmemoryParts = removeParts(ddb.inmemoryParts, partsToRemove) ddb.smallParts, removedSmallParts = removeParts(ddb.smallParts, partsToRemove) ddb.bigParts, removedBigParts = removeParts(ddb.bigParts, partsToRemove) if pwNew != nil { switch dstPartType { case partInmemory: ddb.inmemoryParts = append(ddb.inmemoryParts, pwNew) ddb.startInmemoryPartsMergerLocked() case partSmall: ddb.smallParts = append(ddb.smallParts, pwNew) ddb.startSmallPartsMergerLocked() case partBig: ddb.bigParts = append(ddb.bigParts, pwNew) ddb.startBigPartsMergerLocked() default: logger.Panicf("BUG: unknown partType=%d", dstPartType) } } // 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 != partInmemory { smallPartNames := getPartNames(ddb.smallParts) bigPartNames := getPartNames(ddb.bigParts) mustWritePartNames(ddb.path, smallPartNames, bigPartNames) } ddb.partsLock.Unlock() removedParts := removedInmemoryParts + removedSmallParts + removedBigParts if removedParts != len(partsToRemove) { logger.Panicf("BUG: unexpected number of parts removed; got %d, want %d", removedParts, len(partsToRemove)) } // Mark old parts as must be deleted and decrement reference count, so they are eventually closed and deleted. for _, pw := range pws { pw.mustDrop.Store(true) pw.decRef() } } func partsToMap(pws []*partWrapper) map[*partWrapper]struct{} { m := make(map[*partWrapper]struct{}, len(pws)) for _, pw := range pws { m[pw] = struct{}{} } if len(m) != len(pws) { logger.Panicf("BUG: %d duplicate parts found out of %d parts", len(pws)-len(m), len(pws)) } return m } func removeParts(pws []*partWrapper, partsToRemove map[*partWrapper]struct{}) ([]*partWrapper, int) { dst := pws[:0] for _, pw := range pws { if _, ok := partsToRemove[pw]; !ok { dst = append(dst, pw) } } for i := len(dst); i < len(pws); i++ { pws[i] = nil } return dst, len(pws) - len(dst) } 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 newPartWrapper(p *part, mp *inmemoryPart, flushDeadline time.Time) *partWrapper { pw := &partWrapper{ p: p, mp: mp, flushDeadline: flushDeadline, } // Increase reference counter for newly created part - it is decreased when the part // is removed from the list of open parts. pw.incRef() return pw } func (ddb *datadb) getFlushToDiskDeadline(pws []*partWrapper) time.Time { d := time.Now().Add(ddb.flushInterval) for _, pw := range pws { if pw.mp != nil && pw.flushDeadline.Before(d) { d = pw.flushDeadline } } return d } 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 areAllInmemoryParts(pws []*partWrapper) bool { for _, pw := range pws { if pw.mp == nil { return false } } return true } func (ddb *datadb) releasePartsToMerge(pws []*partWrapper) { ddb.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 } ddb.partsLock.Unlock() } func (ddb *datadb) getMaxBigPartSize() uint64 { return getMaxOutBytes(ddb.path) } func (ddb *datadb) getMaxSmallPartSize() uint64 { // Small parts are cached in the OS page cache, // so limit their size by the remaining free RAM. mem := memory.Remaining() n := uint64(mem) / defaultPartsToMerge if n < 10e6 { n = 10e6 } // Make sure the output part fits available disk space for small parts. sizeLimit := getMaxOutBytes(ddb.path) if n > sizeLimit { n = sizeLimit } return n } func getMaxOutBytes(path string) uint64 { n := availableDiskSpace(path) if n > maxBigPartSize { n = maxBigPartSize } return n } func availableDiskSpace(path string) uint64 { available := fs.MustGetFreeSpace(path) reserved := reservedDiskSpace.Load() if available < reserved { return 0 } return available - reserved } func tryReserveDiskSpace(path string, n uint64) bool { available := fs.MustGetFreeSpace(path) reserved := reserveDiskSpace(n) if available >= reserved { return true } releaseDiskSpace(n) return false } func reserveDiskSpace(n uint64) uint64 { return reservedDiskSpace.Add(n) } func releaseDiskSpace(n uint64) { reservedDiskSpace.Add(^(n - 1)) } // reservedDiskSpace tracks global reserved disk space for currently executed // background merges across all the partitions. // // It should allow avoiding background merges when there is no free disk space. var reservedDiskSpace atomic.Uint64 func needStop(stopCh <-chan struct{}) bool { select { case <-stopCh: return true default: return false } } // mustCloseDatadb can be called only when nobody accesses ddb. func mustCloseDatadb(ddb *datadb) { // Notify background workers to stop. // Make it under ddb.partsLock in order to prevent from calling ddb.wg.Add() // after ddb.stopCh is closed and ddb.wg.Wait() is called. ddb.partsLock.Lock() close(ddb.stopCh) ddb.partsLock.Unlock() // Wait for background workers to stop. ddb.wg.Wait() // flush in-memory data to disk ddb.mustFlushInmemoryPartsToFiles(true) if len(ddb.inmemoryParts) > 0 { logger.Panicf("BUG: the number of in-memory parts must be zero after flushing them to disk; got %d", len(ddb.inmemoryParts)) } ddb.inmemoryParts = nil // close small parts for _, pw := range ddb.smallParts { pw.decRef() if n := pw.refCount.Load(); n != 0 { logger.Panicf("BUG: there are %d references to smallPart", n) } } ddb.smallParts = nil // close big parts for _, pw := range ddb.bigParts { pw.decRef() if n := pw.refCount.Load(); n != 0 { logger.Panicf("BUG: there are %d references to bigPart", n) } } ddb.bigParts = nil ddb.path = "" ddb.pt = nil } 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 mustWritePartNames(path string, smallPartNames, bigPartNames []string) { partNames := append([]string{}, smallPartNames...) partNames = append(partNames, bigPartNames...) data, err := json.Marshal(partNames) if err != nil { logger.Panicf("BUG: cannot marshal partNames to JSON: %s", err) } partNamesPath := filepath.Join(path, partsFilename) fs.MustWriteAtomic(partNamesPath, data, true) } func mustReadPartNames(path string) []string { partNamesPath := filepath.Join(path, partsFilename) data, err := os.ReadFile(partNamesPath) if err != nil { logger.Panicf("FATAL: cannot read %s: %s", partNamesPath, err) } var partNames []string if err := json.Unmarshal(data, &partNames); err != nil { logger.Panicf("FATAL: cannot parse %s: %s", partNamesPath, err) } return partNames } // mustRemoveUnusedDirs removes dirs at path, which are missing in partNames. // // These dirs may be left after unclean shutdown. func mustRemoveUnusedDirs(path string, partNames []string) { des := fs.MustReadDir(path) m := make(map[string]struct{}, len(partNames)) for _, partName := range partNames { m[partName] = struct{}{} } removedDirs := 0 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) removedDirs++ } } if removedDirs > 0 { fs.MustSyncPath(path) } } // appendPartsToMerge finds optimal parts to merge from src, // appends them to dst and returns the result. func appendPartsToMerge(dst, src []*partWrapper, maxOutBytes uint64) []*partWrapper { if len(src) < 2 { // There is no need in merging zero or one part :) return dst } // Filter out too big parts. // This should reduce N for O(N^2) algorithm below. maxInPartBytes := uint64(float64(maxOutBytes) / minMergeMultiplier) tmp := make([]*partWrapper, 0, len(src)) for _, pw := range src { if pw.p.ph.CompressedSizeBytes > maxInPartBytes { continue } tmp = append(tmp, pw) } src = tmp sortPartsForOptimalMerge(src) maxSrcParts := defaultPartsToMerge 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] if a[0].p.ph.CompressedSizeBytes*uint64(len(a)) < a[len(a)-1].p.ph.CompressedSizeBytes { // Do not merge parts with too big difference in size, // since this results in unbalanced merges. continue } outSize := getCompressedSize(a) if outSize > maxOutBytes { // There is no need in verifying remaining parts with bigger sizes. break } m := float64(outSize) / float64(a[len(a)-1].p.ph.CompressedSizeBytes) if m < maxM { continue } maxM = m pws = a } } minM := float64(defaultPartsToMerge) / 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 } return append(dst, pws...) } 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.ph b := &pws[j].p.ph if a.CompressedSizeBytes == b.CompressedSizeBytes { return a.MinTimestamp > b.MinTimestamp } return a.CompressedSizeBytes < b.CompressedSizeBytes }) } func getCompressedSize(pws []*partWrapper) uint64 { n := uint64(0) for _, pw := range pws { n += pw.p.ph.CompressedSizeBytes } return n } func getUncompressedSize(pws []*partWrapper) uint64 { n := uint64(0) for _, pw := range pws { n += pw.p.ph.UncompressedSizeBytes } return n } func getRowsCount(pws []*partWrapper) uint64 { n := uint64(0) for _, pw := range pws { n += pw.p.ph.RowsCount } return n } func getBlocksCount(pws []*partWrapper) uint64 { n := uint64(0) for _, pw := range pws { n += pw.p.ph.BlocksCount } return n }