// Copyright 2017 The Prometheus Authors // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package tsdb import ( "context" "crypto/rand" "errors" "fmt" "io" "log/slog" "os" "path/filepath" "slices" "time" "github.com/oklog/ulid" "github.com/prometheus/client_golang/prometheus" "github.com/prometheus/common/promslog" "github.com/prometheus/prometheus/storage" "github.com/prometheus/prometheus/tsdb/chunkenc" "github.com/prometheus/prometheus/tsdb/chunks" tsdb_errors "github.com/prometheus/prometheus/tsdb/errors" "github.com/prometheus/prometheus/tsdb/fileutil" "github.com/prometheus/prometheus/tsdb/index" "github.com/prometheus/prometheus/tsdb/tombstones" ) // ExponentialBlockRanges returns the time ranges based on the stepSize. func ExponentialBlockRanges(minSize int64, steps, stepSize int) []int64 { ranges := make([]int64, 0, steps) curRange := minSize for i := 0; i < steps; i++ { ranges = append(ranges, curRange) curRange *= int64(stepSize) } return ranges } // Compactor provides compaction against an underlying storage // of time series data. type Compactor interface { // Plan returns a set of directories that can be compacted concurrently. // The directories can be overlapping. // Results returned when compactions are in progress are undefined. Plan(dir string) ([]string, error) // Write persists one or more Blocks into a directory. // No Block is written when resulting Block has 0 samples and returns an empty slice. // Prometheus always return one or no block. The interface allows returning more than one // block for downstream users to experiment with compactor. Write(dest string, b BlockReader, mint, maxt int64, base *BlockMeta) ([]ulid.ULID, error) // Compact runs compaction against the provided directories. Must // only be called concurrently with results of Plan(). // Can optionally pass a list of already open blocks, // to avoid having to reopen them. // Prometheus always return one or no block. The interface allows returning more than one // block for downstream users to experiment with compactor. // When one resulting Block has 0 samples // * No block is written. // * The source dirs are marked Deletable. // * Block is not included in the result. Compact(dest string, dirs []string, open []*Block) ([]ulid.ULID, error) } // LeveledCompactor implements the Compactor interface. type LeveledCompactor struct { metrics *CompactorMetrics logger *slog.Logger ranges []int64 chunkPool chunkenc.Pool ctx context.Context maxBlockChunkSegmentSize int64 mergeFunc storage.VerticalChunkSeriesMergeFunc postingsEncoder index.PostingsEncoder postingsDecoderFactory PostingsDecoderFactory enableOverlappingCompaction bool } type CompactorMetrics struct { Ran prometheus.Counter PopulatingBlocks prometheus.Gauge OverlappingBlocks prometheus.Counter Duration prometheus.Histogram ChunkSize prometheus.Histogram ChunkSamples prometheus.Histogram ChunkRange prometheus.Histogram } // NewCompactorMetrics initializes metrics for Compactor. func NewCompactorMetrics(r prometheus.Registerer) *CompactorMetrics { m := &CompactorMetrics{} m.Ran = prometheus.NewCounter(prometheus.CounterOpts{ Name: "prometheus_tsdb_compactions_total", Help: "Total number of compactions that were executed for the partition.", }) m.PopulatingBlocks = prometheus.NewGauge(prometheus.GaugeOpts{ Name: "prometheus_tsdb_compaction_populating_block", Help: "Set to 1 when a block is currently being written to the disk.", }) m.OverlappingBlocks = prometheus.NewCounter(prometheus.CounterOpts{ Name: "prometheus_tsdb_vertical_compactions_total", Help: "Total number of compactions done on overlapping blocks.", }) m.Duration = prometheus.NewHistogram(prometheus.HistogramOpts{ Name: "prometheus_tsdb_compaction_duration_seconds", Help: "Duration of compaction runs", Buckets: prometheus.ExponentialBuckets(1, 2, 14), NativeHistogramBucketFactor: 1.1, NativeHistogramMaxBucketNumber: 100, NativeHistogramMinResetDuration: 1 * time.Hour, }) m.ChunkSize = prometheus.NewHistogram(prometheus.HistogramOpts{ Name: "prometheus_tsdb_compaction_chunk_size_bytes", Help: "Final size of chunks on their first compaction", Buckets: prometheus.ExponentialBuckets(32, 1.5, 12), }) m.ChunkSamples = prometheus.NewHistogram(prometheus.HistogramOpts{ Name: "prometheus_tsdb_compaction_chunk_samples", Help: "Final number of samples on their first compaction", Buckets: prometheus.ExponentialBuckets(4, 1.5, 12), }) m.ChunkRange = prometheus.NewHistogram(prometheus.HistogramOpts{ Name: "prometheus_tsdb_compaction_chunk_range_seconds", Help: "Final time range of chunks on their first compaction", Buckets: prometheus.ExponentialBuckets(100, 4, 10), }) if r != nil { r.MustRegister( m.Ran, m.PopulatingBlocks, m.OverlappingBlocks, m.Duration, m.ChunkRange, m.ChunkSamples, m.ChunkSize, ) } return m } type LeveledCompactorOptions struct { // PE specifies the postings encoder. It is called when compactor is writing out the postings for a label name/value pair during compaction. // If it is nil then the default encoder is used. At the moment that is the "raw" encoder. See index.EncodePostingsRaw for more. PE index.PostingsEncoder // PD specifies the postings decoder factory to return different postings decoder based on BlockMeta. It is called when opening a block or opening the index file. // If it is nil then a default decoder is used, compatible with Prometheus v2. PD PostingsDecoderFactory // MaxBlockChunkSegmentSize is the max block chunk segment size. If it is 0 then the default chunks.DefaultChunkSegmentSize is used. MaxBlockChunkSegmentSize int64 // MergeFunc is used for merging series together in vertical compaction. By default storage.NewCompactingChunkSeriesMerger(storage.ChainedSeriesMerge) is used. MergeFunc storage.VerticalChunkSeriesMergeFunc // EnableOverlappingCompaction enables compaction of overlapping blocks. In Prometheus it is always enabled. // It is useful for downstream projects like Mimir, Cortex, Thanos where they have a separate component that does compaction. EnableOverlappingCompaction bool } type PostingsDecoderFactory func(meta *BlockMeta) index.PostingsDecoder func DefaultPostingsDecoderFactory(_ *BlockMeta) index.PostingsDecoder { return index.DecodePostingsRaw } func NewLeveledCompactorWithChunkSize(ctx context.Context, r prometheus.Registerer, l *slog.Logger, ranges []int64, pool chunkenc.Pool, maxBlockChunkSegmentSize int64, mergeFunc storage.VerticalChunkSeriesMergeFunc) (*LeveledCompactor, error) { return NewLeveledCompactorWithOptions(ctx, r, l, ranges, pool, LeveledCompactorOptions{ MaxBlockChunkSegmentSize: maxBlockChunkSegmentSize, MergeFunc: mergeFunc, EnableOverlappingCompaction: true, }) } func NewLeveledCompactor(ctx context.Context, r prometheus.Registerer, l *slog.Logger, ranges []int64, pool chunkenc.Pool, mergeFunc storage.VerticalChunkSeriesMergeFunc) (*LeveledCompactor, error) { return NewLeveledCompactorWithOptions(ctx, r, l, ranges, pool, LeveledCompactorOptions{ MergeFunc: mergeFunc, EnableOverlappingCompaction: true, }) } func NewLeveledCompactorWithOptions(ctx context.Context, r prometheus.Registerer, l *slog.Logger, ranges []int64, pool chunkenc.Pool, opts LeveledCompactorOptions) (*LeveledCompactor, error) { if len(ranges) == 0 { return nil, errors.New("at least one range must be provided") } if pool == nil { pool = chunkenc.NewPool() } if l == nil { l = promslog.NewNopLogger() } mergeFunc := opts.MergeFunc if mergeFunc == nil { mergeFunc = storage.NewCompactingChunkSeriesMerger(storage.ChainedSeriesMerge) } maxBlockChunkSegmentSize := opts.MaxBlockChunkSegmentSize if maxBlockChunkSegmentSize == 0 { maxBlockChunkSegmentSize = chunks.DefaultChunkSegmentSize } pe := opts.PE if pe == nil { pe = index.EncodePostingsRaw } return &LeveledCompactor{ ranges: ranges, chunkPool: pool, logger: l, metrics: NewCompactorMetrics(r), ctx: ctx, maxBlockChunkSegmentSize: maxBlockChunkSegmentSize, mergeFunc: mergeFunc, postingsEncoder: pe, postingsDecoderFactory: opts.PD, enableOverlappingCompaction: opts.EnableOverlappingCompaction, }, nil } type dirMeta struct { dir string meta *BlockMeta } // Plan returns a list of compactable blocks in the provided directory. func (c *LeveledCompactor) Plan(dir string) ([]string, error) { dirs, err := blockDirs(dir) if err != nil { return nil, err } if len(dirs) < 1 { return nil, nil } var dms []dirMeta for _, dir := range dirs { meta, _, err := readMetaFile(dir) if err != nil { return nil, err } dms = append(dms, dirMeta{dir, meta}) } return c.plan(dms) } func (c *LeveledCompactor) plan(dms []dirMeta) ([]string, error) { slices.SortFunc(dms, func(a, b dirMeta) int { switch { case a.meta.MinTime < b.meta.MinTime: return -1 case a.meta.MinTime > b.meta.MinTime: return 1 default: return 0 } }) res := c.selectOverlappingDirs(dms) if len(res) > 0 { return res, nil } // No overlapping blocks, do compaction the usual way. // We do not include a recently created block with max(minTime), so the block which was just created from WAL. // This gives users a window of a full block size to piece-wise backup new data without having to care about data overlap. dms = dms[:len(dms)-1] for _, dm := range c.selectDirs(dms) { res = append(res, dm.dir) } if len(res) > 0 { return res, nil } // Compact any blocks with big enough time range that have >5% tombstones. for i := len(dms) - 1; i >= 0; i-- { meta := dms[i].meta if meta.MaxTime-meta.MinTime < c.ranges[len(c.ranges)/2] { // If the block is entirely deleted, then we don't care about the block being big enough. // TODO: This is assuming a single tombstone is for a distinct series, which might not be true. if meta.Stats.NumTombstones > 0 && meta.Stats.NumTombstones >= meta.Stats.NumSeries { return []string{dms[i].dir}, nil } break } if float64(meta.Stats.NumTombstones)/float64(meta.Stats.NumSeries+1) > 0.05 { return []string{dms[i].dir}, nil } } return nil, nil } // selectDirs returns the dir metas that should be compacted into a single new block. // If only a single block range is configured, the result is always nil. func (c *LeveledCompactor) selectDirs(ds []dirMeta) []dirMeta { if len(c.ranges) < 2 || len(ds) < 1 { return nil } highTime := ds[len(ds)-1].meta.MinTime for _, iv := range c.ranges[1:] { parts := splitByRange(ds, iv) if len(parts) == 0 { continue } Outer: for _, p := range parts { // Do not select the range if it has a block whose compaction failed. for _, dm := range p { if dm.meta.Compaction.Failed { continue Outer } } mint := p[0].meta.MinTime maxt := p[len(p)-1].meta.MaxTime // Pick the range of blocks if it spans the full range (potentially with gaps) // or is before the most recent block. // This ensures we don't compact blocks prematurely when another one of the same // size still fits in the range. if (maxt-mint == iv || maxt <= highTime) && len(p) > 1 { return p } } } return nil } // selectOverlappingDirs returns all dirs with overlapping time ranges. // It expects sorted input by mint and returns the overlapping dirs in the same order as received. func (c *LeveledCompactor) selectOverlappingDirs(ds []dirMeta) []string { if !c.enableOverlappingCompaction { return nil } if len(ds) < 2 { return nil } var overlappingDirs []string globalMaxt := ds[0].meta.MaxTime for i, d := range ds[1:] { if d.meta.MinTime < globalMaxt { if len(overlappingDirs) == 0 { // When it is the first overlap, need to add the last one as well. overlappingDirs = append(overlappingDirs, ds[i].dir) } overlappingDirs = append(overlappingDirs, d.dir) } else if len(overlappingDirs) > 0 { break } if d.meta.MaxTime > globalMaxt { globalMaxt = d.meta.MaxTime } } return overlappingDirs } // splitByRange splits the directories by the time range. The range sequence starts at 0. // // For example, if we have blocks [0-10, 10-20, 50-60, 90-100] and the split range tr is 30 // it returns [0-10, 10-20], [50-60], [90-100]. func splitByRange(ds []dirMeta, tr int64) [][]dirMeta { var splitDirs [][]dirMeta for i := 0; i < len(ds); { var ( group []dirMeta t0 int64 m = ds[i].meta ) // Compute start of aligned time range of size tr closest to the current block's start. if m.MinTime >= 0 { t0 = tr * (m.MinTime / tr) } else { t0 = tr * ((m.MinTime - tr + 1) / tr) } // Skip blocks that don't fall into the range. This can happen via mis-alignment or // by being a multiple of the intended range. if m.MaxTime > t0+tr { i++ continue } // Add all dirs to the current group that are within [t0, t0+tr]. for ; i < len(ds); i++ { // Either the block falls into the next range or doesn't fit at all (checked above). if ds[i].meta.MaxTime > t0+tr { break } group = append(group, ds[i]) } if len(group) > 0 { splitDirs = append(splitDirs, group) } } return splitDirs } // CompactBlockMetas merges many block metas into one, combining its source blocks together // and adjusting compaction level. Min/Max time of result block meta covers all input blocks. func CompactBlockMetas(uid ulid.ULID, blocks ...*BlockMeta) *BlockMeta { res := &BlockMeta{ ULID: uid, } sources := map[ulid.ULID]struct{}{} mint := blocks[0].MinTime maxt := blocks[0].MaxTime for _, b := range blocks { if b.MinTime < mint { mint = b.MinTime } if b.MaxTime > maxt { maxt = b.MaxTime } if b.Compaction.Level > res.Compaction.Level { res.Compaction.Level = b.Compaction.Level } for _, s := range b.Compaction.Sources { sources[s] = struct{}{} } res.Compaction.Parents = append(res.Compaction.Parents, BlockDesc{ ULID: b.ULID, MinTime: b.MinTime, MaxTime: b.MaxTime, }) } res.Compaction.Level++ for s := range sources { res.Compaction.Sources = append(res.Compaction.Sources, s) } slices.SortFunc(res.Compaction.Sources, func(a, b ulid.ULID) int { return a.Compare(b) }) res.MinTime = mint res.MaxTime = maxt return res } // Compact creates a new block in the compactor's directory from the blocks in the // provided directories. func (c *LeveledCompactor) Compact(dest string, dirs []string, open []*Block) ([]ulid.ULID, error) { return c.CompactWithBlockPopulator(dest, dirs, open, DefaultBlockPopulator{}) } func (c *LeveledCompactor) CompactWithBlockPopulator(dest string, dirs []string, open []*Block, blockPopulator BlockPopulator) ([]ulid.ULID, error) { var ( blocks []BlockReader bs []*Block metas []*BlockMeta uids []string ) start := time.Now() for _, d := range dirs { meta, _, err := readMetaFile(d) if err != nil { return nil, err } var b *Block // Use already open blocks if we can, to avoid // having the index data in memory twice. for _, o := range open { if meta.ULID == o.Meta().ULID { b = o break } } if b == nil { var err error b, err = OpenBlock(c.logger, d, c.chunkPool, c.postingsDecoderFactory) if err != nil { return nil, err } defer b.Close() } metas = append(metas, meta) blocks = append(blocks, b) bs = append(bs, b) uids = append(uids, meta.ULID.String()) } uid := ulid.MustNew(ulid.Now(), rand.Reader) meta := CompactBlockMetas(uid, metas...) err := c.write(dest, meta, blockPopulator, blocks...) if err == nil { if meta.Stats.NumSamples == 0 { for _, b := range bs { b.meta.Compaction.Deletable = true n, err := writeMetaFile(c.logger, b.dir, &b.meta) if err != nil { c.logger.Error( "Failed to write 'Deletable' to meta file after compaction", "ulid", b.meta.ULID, ) } b.numBytesMeta = n } c.logger.Info( "compact blocks resulted in empty block", "count", len(blocks), "sources", fmt.Sprintf("%v", uids), "duration", time.Since(start), ) return nil, nil } c.logger.Info( "compact blocks", "count", len(blocks), "mint", meta.MinTime, "maxt", meta.MaxTime, "ulid", meta.ULID, "sources", fmt.Sprintf("%v", uids), "duration", time.Since(start), ) return []ulid.ULID{uid}, nil } errs := tsdb_errors.NewMulti(err) if !errors.Is(err, context.Canceled) { for _, b := range bs { if err := b.setCompactionFailed(); err != nil { errs.Add(fmt.Errorf("setting compaction failed for block: %s: %w", b.Dir(), err)) } } } return nil, errs.Err() } func (c *LeveledCompactor) Write(dest string, b BlockReader, mint, maxt int64, base *BlockMeta) ([]ulid.ULID, error) { start := time.Now() uid := ulid.MustNew(ulid.Now(), rand.Reader) meta := &BlockMeta{ ULID: uid, MinTime: mint, MaxTime: maxt, } meta.Compaction.Level = 1 meta.Compaction.Sources = []ulid.ULID{uid} if base != nil { meta.Compaction.Parents = []BlockDesc{ {ULID: base.ULID, MinTime: base.MinTime, MaxTime: base.MaxTime}, } if base.Compaction.FromOutOfOrder() { meta.Compaction.SetOutOfOrder() } } err := c.write(dest, meta, DefaultBlockPopulator{}, b) if err != nil { return nil, err } if meta.Stats.NumSamples == 0 { c.logger.Info( "write block resulted in empty block", "mint", meta.MinTime, "maxt", meta.MaxTime, "duration", time.Since(start), ) return nil, nil } c.logger.Info( "write block", "mint", meta.MinTime, "maxt", meta.MaxTime, "ulid", meta.ULID, "duration", time.Since(start), "ooo", meta.Compaction.FromOutOfOrder(), ) return []ulid.ULID{uid}, nil } // instrumentedChunkWriter is used for level 1 compactions to record statistics // about compacted chunks. type instrumentedChunkWriter struct { ChunkWriter size prometheus.Histogram samples prometheus.Histogram trange prometheus.Histogram } func (w *instrumentedChunkWriter) WriteChunks(chunks ...chunks.Meta) error { for _, c := range chunks { w.size.Observe(float64(len(c.Chunk.Bytes()))) w.samples.Observe(float64(c.Chunk.NumSamples())) w.trange.Observe(float64(c.MaxTime - c.MinTime)) } return w.ChunkWriter.WriteChunks(chunks...) } // write creates a new block that is the union of the provided blocks into dir. func (c *LeveledCompactor) write(dest string, meta *BlockMeta, blockPopulator BlockPopulator, blocks ...BlockReader) (err error) { dir := filepath.Join(dest, meta.ULID.String()) tmp := dir + tmpForCreationBlockDirSuffix var closers []io.Closer defer func(t time.Time) { err = tsdb_errors.NewMulti(err, tsdb_errors.CloseAll(closers)).Err() // RemoveAll returns no error when tmp doesn't exist so it is safe to always run it. if err := os.RemoveAll(tmp); err != nil { c.logger.Error("removed tmp folder after failed compaction", "err", err.Error()) } c.metrics.Ran.Inc() c.metrics.Duration.Observe(time.Since(t).Seconds()) }(time.Now()) if err = os.RemoveAll(tmp); err != nil { return err } if err = os.MkdirAll(tmp, 0o777); err != nil { return err } // Populate chunk and index files into temporary directory with // data of all blocks. var chunkw ChunkWriter chunkw, err = chunks.NewWriterWithSegSize(chunkDir(tmp), c.maxBlockChunkSegmentSize) if err != nil { return fmt.Errorf("open chunk writer: %w", err) } closers = append(closers, chunkw) // Record written chunk sizes on level 1 compactions. if meta.Compaction.Level == 1 { chunkw = &instrumentedChunkWriter{ ChunkWriter: chunkw, size: c.metrics.ChunkSize, samples: c.metrics.ChunkSamples, trange: c.metrics.ChunkRange, } } indexw, err := index.NewWriterWithEncoder(c.ctx, filepath.Join(tmp, indexFilename), c.postingsEncoder) if err != nil { return fmt.Errorf("open index writer: %w", err) } closers = append(closers, indexw) if err := blockPopulator.PopulateBlock(c.ctx, c.metrics, c.logger, c.chunkPool, c.mergeFunc, blocks, meta, indexw, chunkw, AllSortedPostings); err != nil { return fmt.Errorf("populate block: %w", err) } select { case <-c.ctx.Done(): return c.ctx.Err() default: } // We are explicitly closing them here to check for error even // though these are covered under defer. This is because in Windows, // you cannot delete these unless they are closed and the defer is to // make sure they are closed if the function exits due to an error above. errs := tsdb_errors.NewMulti() for _, w := range closers { errs.Add(w.Close()) } closers = closers[:0] // Avoid closing the writers twice in the defer. if errs.Err() != nil { return errs.Err() } // Populated block is empty, so exit early. if meta.Stats.NumSamples == 0 { return nil } if _, err = writeMetaFile(c.logger, tmp, meta); err != nil { return fmt.Errorf("write merged meta: %w", err) } // Create an empty tombstones file. if _, err := tombstones.WriteFile(c.logger, tmp, tombstones.NewMemTombstones()); err != nil { return fmt.Errorf("write new tombstones file: %w", err) } df, err := fileutil.OpenDir(tmp) if err != nil { return fmt.Errorf("open temporary block dir: %w", err) } defer func() { if df != nil { df.Close() } }() if err := df.Sync(); err != nil { return fmt.Errorf("sync temporary dir file: %w", err) } // Close temp dir before rename block dir (for windows platform). if err = df.Close(); err != nil { return fmt.Errorf("close temporary dir: %w", err) } df = nil // Block successfully written, make it visible in destination dir by moving it from tmp one. if err := fileutil.Replace(tmp, dir); err != nil { return fmt.Errorf("rename block dir: %w", err) } return nil } type BlockPopulator interface { PopulateBlock(ctx context.Context, metrics *CompactorMetrics, logger *slog.Logger, chunkPool chunkenc.Pool, mergeFunc storage.VerticalChunkSeriesMergeFunc, blocks []BlockReader, meta *BlockMeta, indexw IndexWriter, chunkw ChunkWriter, postingsFunc IndexReaderPostingsFunc) error } // IndexReaderPostingsFunc is a function to get a sorted posting iterator from a given index reader. type IndexReaderPostingsFunc func(ctx context.Context, reader IndexReader) index.Postings // AllSortedPostings returns a sorted all posting iterator from the input index reader. func AllSortedPostings(ctx context.Context, reader IndexReader) index.Postings { k, v := index.AllPostingsKey() all, err := reader.Postings(ctx, k, v) if err != nil { return index.ErrPostings(err) } return reader.SortedPostings(all) } type DefaultBlockPopulator struct{} // PopulateBlock fills the index and chunk writers with new data gathered as the union // of the provided blocks. It returns meta information for the new block. // It expects sorted blocks input by mint. func (c DefaultBlockPopulator) PopulateBlock(ctx context.Context, metrics *CompactorMetrics, logger *slog.Logger, chunkPool chunkenc.Pool, mergeFunc storage.VerticalChunkSeriesMergeFunc, blocks []BlockReader, meta *BlockMeta, indexw IndexWriter, chunkw ChunkWriter, postingsFunc IndexReaderPostingsFunc) (err error) { if len(blocks) == 0 { return errors.New("cannot populate block from no readers") } var ( sets []storage.ChunkSeriesSet symbols index.StringIter closers []io.Closer overlapping bool ) defer func() { errs := tsdb_errors.NewMulti(err) if cerr := tsdb_errors.CloseAll(closers); cerr != nil { errs.Add(fmt.Errorf("close: %w", cerr)) } err = errs.Err() metrics.PopulatingBlocks.Set(0) }() metrics.PopulatingBlocks.Set(1) globalMaxt := blocks[0].Meta().MaxTime for i, b := range blocks { select { case <-ctx.Done(): return ctx.Err() default: } if !overlapping { if i > 0 && b.Meta().MinTime < globalMaxt { metrics.OverlappingBlocks.Inc() overlapping = true logger.Info("Found overlapping blocks during compaction", "ulid", meta.ULID) } if b.Meta().MaxTime > globalMaxt { globalMaxt = b.Meta().MaxTime } } indexr, err := b.Index() if err != nil { return fmt.Errorf("open index reader for block %+v: %w", b.Meta(), err) } closers = append(closers, indexr) chunkr, err := b.Chunks() if err != nil { return fmt.Errorf("open chunk reader for block %+v: %w", b.Meta(), err) } closers = append(closers, chunkr) tombsr, err := b.Tombstones() if err != nil { return fmt.Errorf("open tombstone reader for block %+v: %w", b.Meta(), err) } closers = append(closers, tombsr) postings := postingsFunc(ctx, indexr) // Blocks meta is half open: [min, max), so subtract 1 to ensure we don't hold samples with exact meta.MaxTime timestamp. sets = append(sets, NewBlockChunkSeriesSet(b.Meta().ULID, indexr, chunkr, tombsr, postings, meta.MinTime, meta.MaxTime-1, false)) syms := indexr.Symbols() if i == 0 { symbols = syms continue } symbols = NewMergedStringIter(symbols, syms) } for symbols.Next() { if err := indexw.AddSymbol(symbols.At()); err != nil { return fmt.Errorf("add symbol: %w", err) } } if err := symbols.Err(); err != nil { return fmt.Errorf("next symbol: %w", err) } var ( ref = storage.SeriesRef(0) chks []chunks.Meta chksIter chunks.Iterator ) set := sets[0] if len(sets) > 1 { // Merge series using specified chunk series merger. // The default one is the compacting series merger. set = storage.NewMergeChunkSeriesSet(sets, 0, mergeFunc) } // Iterate over all sorted chunk series. for set.Next() { select { case <-ctx.Done(): return ctx.Err() default: } s := set.At() chksIter = s.Iterator(chksIter) chks = chks[:0] for chksIter.Next() { // We are not iterating in a streaming way over chunks as // it's more efficient to do bulk write for index and // chunk file purposes. chks = append(chks, chksIter.At()) } if err := chksIter.Err(); err != nil { return fmt.Errorf("chunk iter: %w", err) } // Skip series with all deleted chunks. if len(chks) == 0 { continue } if err := chunkw.WriteChunks(chks...); err != nil { return fmt.Errorf("write chunks: %w", err) } if err := indexw.AddSeries(ref, s.Labels(), chks...); err != nil { return fmt.Errorf("add series: %w", err) } meta.Stats.NumChunks += uint64(len(chks)) meta.Stats.NumSeries++ for _, chk := range chks { meta.Stats.NumSamples += uint64(chk.Chunk.NumSamples()) } for _, chk := range chks { if err := chunkPool.Put(chk.Chunk); err != nil { return fmt.Errorf("put chunk: %w", err) } } ref++ } if err := set.Err(); err != nil { return fmt.Errorf("iterate compaction set: %w", err) } return nil }