The Prometheus monitoring system and time series database.
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// 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"
"fmt"
"io"
"math"
"os"
"path/filepath"
"sort"
"time"
"github.com/go-kit/kit/log"
"github.com/go-kit/kit/log/level"
"github.com/oklog/ulid"
"github.com/pkg/errors"
"github.com/prometheus/client_golang/prometheus"
"github.com/prometheus/prometheus/pkg/labels"
"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 = 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 a Block into a directory.
// No Block is written when resulting Block has 0 samples, and returns empty ulid.ULID{}.
Write(dest string, b BlockReader, mint, maxt int64, parent *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.
// When resulting Block has 0 samples
// * No block is written.
// * The source dirs are marked Deletable.
// * Returns empty ulid.ULID{}.
Compact(dest string, dirs []string, open []*Block) (ulid.ULID, error)
}
// LeveledCompactor implements the Compactor interface.
type LeveledCompactor struct {
metrics *compactorMetrics
logger log.Logger
ranges []int64
chunkPool chunkenc.Pool
ctx context.Context
}
type compactorMetrics struct {
ran prometheus.Counter
populatingBlocks prometheus.Gauge
overlappingBlocks prometheus.Counter
duration prometheus.Histogram
chunkSize prometheus.Histogram
chunkSamples prometheus.Histogram
chunkRange prometheus.Histogram
}
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, 10),
})
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
}
// NewLeveledCompactor returns a LeveledCompactor.
func NewLeveledCompactor(ctx context.Context, r prometheus.Registerer, l log.Logger, ranges []int64, pool chunkenc.Pool) (*LeveledCompactor, error) {
if len(ranges) == 0 {
return nil, errors.Errorf("at least one range must be provided")
}
if pool == nil {
pool = chunkenc.NewPool()
}
if l == nil {
l = log.NewNopLogger()
}
return &LeveledCompactor{
ranges: ranges,
chunkPool: pool,
logger: l,
metrics: newCompactorMetrics(r),
ctx: ctx,
}, 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) {
sort.Slice(dms, func(i, j int) bool {
return dms[i].meta.MinTime < dms[j].meta.MinTime
})
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] {
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 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 the 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
}
func compactBlockMetas(uid ulid.ULID, blocks ...*BlockMeta) *BlockMeta {
res := &BlockMeta{
ULID: uid,
MinTime: blocks[0].MinTime,
}
sources := map[ulid.ULID]struct{}{}
// For overlapping blocks, the Maxt can be
// in any block so we track it globally.
maxt := int64(math.MinInt64)
for _, b := range blocks {
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)
}
sort.Slice(res.Compaction.Sources, func(i, j int) bool {
return res.Compaction.Sources[i].Compare(res.Compaction.Sources[j]) < 0
})
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) (uid ulid.ULID, err 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 uid, 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)
if err != nil {
return uid, 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, 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 {
level.Error(c.logger).Log(
"msg", "Failed to write 'Deletable' to meta file after compaction",
"ulid", b.meta.ULID,
)
}
b.numBytesMeta = n
}
uid = ulid.ULID{}
level.Info(c.logger).Log(
"msg", "compact blocks resulted in empty block",
"count", len(blocks),
"sources", fmt.Sprintf("%v", uids),
"duration", time.Since(start),
)
} else {
level.Info(c.logger).Log(
"msg", "compact blocks",
"count", len(blocks),
"mint", meta.MinTime,
"maxt", meta.MaxTime,
"ulid", meta.ULID,
"sources", fmt.Sprintf("%v", uids),
"duration", time.Since(start),
)
}
return uid, nil
}
var merr tsdb_errors.MultiError
merr.Add(err)
if err != context.Canceled {
for _, b := range bs {
if err := b.setCompactionFailed(); err != nil {
merr.Add(errors.Wrapf(err, "setting compaction failed for block: %s", b.Dir()))
}
}
}
return uid, merr
}
func (c *LeveledCompactor) Write(dest string, b BlockReader, mint, maxt int64, parent *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 parent != nil {
meta.Compaction.Parents = []BlockDesc{
{ULID: parent.ULID, MinTime: parent.MinTime, MaxTime: parent.MaxTime},
}
}
err := c.write(dest, meta, b)
if err != nil {
return uid, err
}
if meta.Stats.NumSamples == 0 {
return ulid.ULID{}, nil
}
level.Info(c.logger).Log(
"msg", "write block",
"mint", meta.MinTime,
"maxt", meta.MaxTime,
"ulid", meta.ULID,
"duration", time.Since(start),
)
return 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.
// It cleans up all files of the old blocks after completing successfully.
func (c *LeveledCompactor) write(dest string, meta *BlockMeta, blocks ...BlockReader) (err error) {
dir := filepath.Join(dest, meta.ULID.String())
tmp := dir + ".tmp"
var closers []io.Closer
defer func(t time.Time) {
var merr tsdb_errors.MultiError
merr.Add(err)
merr.Add(closeAll(closers))
err = merr.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 {
level.Error(c.logger).Log("msg", "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, 0777); err != nil {
return err
}
// Populate chunk and index files into temporary directory with
// data of all blocks.
var chunkw ChunkWriter
chunkw, err = chunks.NewWriter(chunkDir(tmp))
if err != nil {
return errors.Wrap(err, "open chunk writer")
}
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.NewWriter(c.ctx, filepath.Join(tmp, indexFilename))
if err != nil {
return errors.Wrap(err, "open index writer")
}
closers = append(closers, indexw)
if err := c.populateBlock(blocks, meta, indexw, chunkw); err != nil {
return errors.Wrap(err, "write compaction")
}
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.
var merr tsdb_errors.MultiError
for _, w := range closers {
merr.Add(w.Close())
}
closers = closers[:0] // Avoid closing the writers twice in the defer.
if merr.Err() != nil {
return merr.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 errors.Wrap(err, "write merged meta")
}
// Create an empty tombstones file.
if _, err := tombstones.WriteFile(c.logger, tmp, tombstones.NewMemTombstones()); err != nil {
return errors.Wrap(err, "write new tombstones file")
}
df, err := fileutil.OpenDir(tmp)
if err != nil {
return errors.Wrap(err, "open temporary block dir")
}
defer func() {
if df != nil {
df.Close()
}
}()
if err := df.Sync(); err != nil {
return errors.Wrap(err, "sync temporary dir file")
}
// Close temp dir before rename block dir (for windows platform).
if err = df.Close(); err != nil {
return errors.Wrap(err, "close temporary dir")
}
df = nil
// Block successfully written, make visible and remove old ones.
if err := fileutil.Replace(tmp, dir); err != nil {
return errors.Wrap(err, "rename block dir")
}
return nil
}
// 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 *LeveledCompactor) populateBlock(blocks []BlockReader, meta *BlockMeta, indexw IndexWriter, chunkw ChunkWriter) (err error) {
if len(blocks) == 0 {
return errors.New("cannot populate block from no readers")
}
var (
set storage.DeprecatedChunkSeriesSet
symbols index.StringIter
closers = []io.Closer{}
overlapping bool
)
defer func() {
var merr tsdb_errors.MultiError
merr.Add(err)
merr.Add(closeAll(closers))
err = merr.Err()
c.metrics.populatingBlocks.Set(0)
}()
c.metrics.populatingBlocks.Set(1)
globalMaxt := blocks[0].Meta().MaxTime
for i, b := range blocks {
select {
case <-c.ctx.Done():
return c.ctx.Err()
default:
}
if !overlapping {
if i > 0 && b.Meta().MinTime < globalMaxt {
c.metrics.overlappingBlocks.Inc()
overlapping = true
level.Warn(c.logger).Log("msg", "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 errors.Wrapf(err, "open index reader for block %+v", b.Meta())
}
closers = append(closers, indexr)
chunkr, err := b.Chunks()
if err != nil {
return errors.Wrapf(err, "open chunk reader for block %+v", b.Meta())
}
closers = append(closers, chunkr)
tombsr, err := b.Tombstones()
if err != nil {
return errors.Wrapf(err, "open tombstone reader for block %+v", b.Meta())
}
closers = append(closers, tombsr)
k, v := index.AllPostingsKey()
all, err := indexr.Postings(k, v)
if err != nil {
return err
}
all = indexr.SortedPostings(all)
s := newCompactionSeriesSet(indexr, chunkr, tombsr, all)
syms := indexr.Symbols()
if i == 0 {
set = s
symbols = syms
continue
}
set, err = newCompactionMerger(set, s)
if err != nil {
return err
}
symbols = newMergedStringIter(symbols, syms)
}
for symbols.Next() {
if err := indexw.AddSymbol(symbols.At()); err != nil {
return errors.Wrap(err, "add symbol")
}
}
if symbols.Err() != nil {
return errors.Wrap(symbols.Err(), "next symbol")
}
delIter := &deletedIterator{}
ref := uint64(0)
for set.Next() {
select {
case <-c.ctx.Done():
return c.ctx.Err()
default:
}
lset, chks, dranges := set.At() // The chunks here are not fully deleted.
if overlapping {
// If blocks are overlapping, it is possible to have unsorted chunks.
sort.Slice(chks, func(i, j int) bool {
return chks[i].MinTime < chks[j].MinTime
})
}
// Skip the series with all deleted chunks.
if len(chks) == 0 {
continue
}
for i, chk := range chks {
// Re-encode head chunks that are still open (being appended to) or
// outside the compacted MaxTime range.
// The chunk.Bytes() method is not safe for open chunks hence the re-encoding.
// This happens when snapshotting the head block.
//
// Block time range is half-open: [meta.MinTime, meta.MaxTime) and
// chunks are closed hence the chk.MaxTime >= meta.MaxTime check.
//
// TODO think how to avoid the typecasting to verify when it is head block.
if _, isHeadChunk := chk.Chunk.(*safeChunk); isHeadChunk && chk.MaxTime >= meta.MaxTime {
dranges = append(dranges, tombstones.Interval{Mint: meta.MaxTime, Maxt: math.MaxInt64})
} else
// Sanity check for disk blocks.
// chk.MaxTime == meta.MaxTime shouldn't happen as well, but will brake many users so not checking for that.
if chk.MinTime < meta.MinTime || chk.MaxTime > meta.MaxTime {
return errors.Errorf("found chunk with minTime: %d maxTime: %d outside of compacted minTime: %d maxTime: %d",
chk.MinTime, chk.MaxTime, meta.MinTime, meta.MaxTime)
}
if len(dranges) > 0 {
// Re-encode the chunk to not have deleted values.
if !chk.OverlapsClosedInterval(dranges[0].Mint, dranges[len(dranges)-1].Maxt) {
continue
}
newChunk := chunkenc.NewXORChunk()
app, err := newChunk.Appender()
if err != nil {
return err
}
delIter.it = chk.Chunk.Iterator(delIter.it)
delIter.intervals = dranges
var (
t int64
v float64
)
for delIter.Next() {
t, v = delIter.At()
app.Append(t, v)
}
if err := delIter.Err(); err != nil {
return errors.Wrap(err, "iterate chunk while re-encoding")
}
chks[i].Chunk = newChunk
chks[i].MaxTime = t
}
}
mergedChks := chks
if overlapping {
mergedChks, err = chunks.MergeOverlappingChunks(chks)
if err != nil {
return errors.Wrap(err, "merge overlapping chunks")
}
}
if err := chunkw.WriteChunks(mergedChks...); err != nil {
return errors.Wrap(err, "write chunks")
}
if err := indexw.AddSeries(ref, lset, mergedChks...); err != nil {
return errors.Wrap(err, "add series")
}
meta.Stats.NumChunks += uint64(len(mergedChks))
meta.Stats.NumSeries++
for _, chk := range mergedChks {
meta.Stats.NumSamples += uint64(chk.Chunk.NumSamples())
}
for _, chk := range mergedChks {
if err := c.chunkPool.Put(chk.Chunk); err != nil {
return errors.Wrap(err, "put chunk")
}
}
ref++
}
if set.Err() != nil {
return errors.Wrap(set.Err(), "iterate compaction set")
}
return nil
}
type compactionSeriesSet struct {
p index.Postings
index IndexReader
chunks ChunkReader
tombstones tombstones.Reader
l labels.Labels
c []chunks.Meta
intervals tombstones.Intervals
err error
}
func newCompactionSeriesSet(i IndexReader, c ChunkReader, t tombstones.Reader, p index.Postings) *compactionSeriesSet {
return &compactionSeriesSet{
index: i,
chunks: c,
tombstones: t,
p: p,
}
}
func (c *compactionSeriesSet) Next() bool {
if !c.p.Next() {
return false
}
var err error
c.intervals, err = c.tombstones.Get(c.p.At())
if err != nil {
c.err = errors.Wrap(err, "get tombstones")
return false
}
if err = c.index.Series(c.p.At(), &c.l, &c.c); err != nil {
c.err = errors.Wrapf(err, "get series %d", c.p.At())
return false
}
// Remove completely deleted chunks.
if len(c.intervals) > 0 {
chks := make([]chunks.Meta, 0, len(c.c))
for _, chk := range c.c {
if !(tombstones.Interval{Mint: chk.MinTime, Maxt: chk.MaxTime}.IsSubrange(c.intervals)) {
chks = append(chks, chk)
}
}
c.c = chks
}
for i := range c.c {
chk := &c.c[i]
chk.Chunk, err = c.chunks.Chunk(chk.Ref)
if err != nil {
c.err = errors.Wrapf(err, "chunk %d not found", chk.Ref)
return false
}
}
return true
}
func (c *compactionSeriesSet) Err() error {
if c.err != nil {
return c.err
}
return c.p.Err()
}
func (c *compactionSeriesSet) At() (labels.Labels, []chunks.Meta, tombstones.Intervals) {
return c.l, c.c, c.intervals
}
type compactionMerger struct {
a, b storage.DeprecatedChunkSeriesSet
aok, bok bool
l labels.Labels
c []chunks.Meta
intervals tombstones.Intervals
}
// TODO(bwplotka): Move to storage mergers.
func newCompactionMerger(a, b storage.DeprecatedChunkSeriesSet) (*compactionMerger, error) {
c := &compactionMerger{
a: a,
b: b,
}
// Initialize first elements of both sets as Next() needs
// one element look-ahead.
c.aok = c.a.Next()
c.bok = c.b.Next()
return c, c.Err()
}
func (c *compactionMerger) compare() int {
if !c.aok {
return 1
}
if !c.bok {
return -1
}
a, _, _ := c.a.At()
b, _, _ := c.b.At()
return labels.Compare(a, b)
}
func (c *compactionMerger) Next() bool {
if !c.aok && !c.bok || c.Err() != nil {
return false
}
// While advancing child iterators the memory used for labels and chunks
// may be reused. When picking a series we have to store the result.
var lset labels.Labels
var chks []chunks.Meta
d := c.compare()
if d > 0 {
lset, chks, c.intervals = c.b.At()
c.l = append(c.l[:0], lset...)
c.c = append(c.c[:0], chks...)
c.bok = c.b.Next()
} else if d < 0 {
lset, chks, c.intervals = c.a.At()
c.l = append(c.l[:0], lset...)
c.c = append(c.c[:0], chks...)
c.aok = c.a.Next()
} else {
// Both sets contain the current series. Chain them into a single one.
l, ca, ra := c.a.At()
_, cb, rb := c.b.At()
for _, r := range rb {
ra = ra.Add(r)
}
c.l = append(c.l[:0], l...)
c.c = append(append(c.c[:0], ca...), cb...)
c.intervals = ra
c.aok = c.a.Next()
c.bok = c.b.Next()
}
return true
}
func (c *compactionMerger) Err() error {
if c.a.Err() != nil {
return c.a.Err()
}
return c.b.Err()
}
func (c *compactionMerger) At() (labels.Labels, []chunks.Meta, tombstones.Intervals) {
return c.l, c.c, c.intervals
}
func newMergedStringIter(a index.StringIter, b index.StringIter) index.StringIter {
return &mergedStringIter{a: a, b: b, aok: a.Next(), bok: b.Next()}
}
type mergedStringIter struct {
a index.StringIter
b index.StringIter
aok, bok bool
cur string
}
func (m *mergedStringIter) Next() bool {
if (!m.aok && !m.bok) || (m.Err() != nil) {
return false
}
if !m.aok {
m.cur = m.b.At()
m.bok = m.b.Next()
} else if !m.bok {
m.cur = m.a.At()
m.aok = m.a.Next()
} else if m.b.At() > m.a.At() {
m.cur = m.a.At()
m.aok = m.a.Next()
} else if m.a.At() > m.b.At() {
m.cur = m.b.At()
m.bok = m.b.Next()
} else { // Equal.
m.cur = m.b.At()
m.aok = m.a.Next()
m.bok = m.b.Next()
}
return true
}
func (m mergedStringIter) At() string { return m.cur }
func (m mergedStringIter) Err() error {
if m.a.Err() != nil {
return m.a.Err()
}
return m.b.Err()
}