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prometheus/tsdb/querier.go

1247 lines
35 KiB

// 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"
"errors"
"fmt"
"math"
"slices"
"github.com/oklog/ulid"
"github.com/prometheus/prometheus/model/histogram"
"github.com/prometheus/prometheus/model/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/index"
"github.com/prometheus/prometheus/tsdb/tombstones"
"github.com/prometheus/prometheus/util/annotations"
)
// checkContextEveryNIterations is used in some tight loops to check if the context is done.
const checkContextEveryNIterations = 100
type blockBaseQuerier struct {
blockID ulid.ULID
index IndexReader
chunks ChunkReader
tombstones tombstones.Reader
closed bool
mint, maxt int64
}
func newBlockBaseQuerier(b BlockReader, mint, maxt int64) (*blockBaseQuerier, error) {
indexr, err := b.Index()
if err != nil {
return nil, fmt.Errorf("open index reader: %w", err)
}
chunkr, err := b.Chunks()
if err != nil {
indexr.Close()
return nil, fmt.Errorf("open chunk reader: %w", err)
}
tombsr, err := b.Tombstones()
if err != nil {
indexr.Close()
chunkr.Close()
return nil, fmt.Errorf("open tombstone reader: %w", err)
}
if tombsr == nil {
tombsr = tombstones.NewMemTombstones()
}
return &blockBaseQuerier{
blockID: b.Meta().ULID,
mint: mint,
maxt: maxt,
index: indexr,
chunks: chunkr,
tombstones: tombsr,
}, nil
}
func (q *blockBaseQuerier) LabelValues(ctx context.Context, name string, hints *storage.LabelHints, matchers ...*labels.Matcher) ([]string, annotations.Annotations, error) {
res, err := q.index.SortedLabelValues(ctx, name, matchers...)
return res, nil, err
}
func (q *blockBaseQuerier) LabelNames(ctx context.Context, hints *storage.LabelHints, matchers ...*labels.Matcher) ([]string, annotations.Annotations, error) {
res, err := q.index.LabelNames(ctx, matchers...)
return res, nil, err
}
func (q *blockBaseQuerier) Close() error {
if q.closed {
return errors.New("block querier already closed")
}
errs := tsdb_errors.NewMulti(
q.index.Close(),
q.chunks.Close(),
q.tombstones.Close(),
)
q.closed = true
return errs.Err()
}
type blockQuerier struct {
*blockBaseQuerier
}
// NewBlockQuerier returns a querier against the block reader and requested min and max time range.
func NewBlockQuerier(b BlockReader, mint, maxt int64) (storage.Querier, error) {
q, err := newBlockBaseQuerier(b, mint, maxt)
if err != nil {
return nil, err
}
return &blockQuerier{blockBaseQuerier: q}, nil
}
func (q *blockQuerier) Select(ctx context.Context, sortSeries bool, hints *storage.SelectHints, ms ...*labels.Matcher) storage.SeriesSet {
mint := q.mint
maxt := q.maxt
disableTrimming := false
sharded := hints != nil && hints.ShardCount > 0
p, err := PostingsForMatchers(ctx, q.index, ms...)
if err != nil {
return storage.ErrSeriesSet(err)
}
if sharded {
p = q.index.ShardedPostings(p, hints.ShardIndex, hints.ShardCount)
}
if sortSeries {
p = q.index.SortedPostings(p)
}
if hints != nil {
mint = hints.Start
maxt = hints.End
disableTrimming = hints.DisableTrimming
if hints.Func == "series" {
// When you're only looking up metadata (for example series API), you don't need to load any chunks.
return newBlockSeriesSet(q.index, newNopChunkReader(), q.tombstones, p, mint, maxt, disableTrimming)
}
}
return newBlockSeriesSet(q.index, q.chunks, q.tombstones, p, mint, maxt, disableTrimming)
}
// blockChunkQuerier provides chunk querying access to a single block database.
type blockChunkQuerier struct {
*blockBaseQuerier
}
// NewBlockChunkQuerier returns a chunk querier against the block reader and requested min and max time range.
func NewBlockChunkQuerier(b BlockReader, mint, maxt int64) (storage.ChunkQuerier, error) {
q, err := newBlockBaseQuerier(b, mint, maxt)
if err != nil {
return nil, err
}
return &blockChunkQuerier{blockBaseQuerier: q}, nil
}
func (q *blockChunkQuerier) Select(ctx context.Context, sortSeries bool, hints *storage.SelectHints, ms ...*labels.Matcher) storage.ChunkSeriesSet {
mint := q.mint
maxt := q.maxt
disableTrimming := false
sharded := hints != nil && hints.ShardCount > 0
if hints != nil {
mint = hints.Start
maxt = hints.End
disableTrimming = hints.DisableTrimming
}
p, err := PostingsForMatchers(ctx, q.index, ms...)
if err != nil {
return storage.ErrChunkSeriesSet(err)
}
if sharded {
p = q.index.ShardedPostings(p, hints.ShardIndex, hints.ShardCount)
}
if sortSeries {
p = q.index.SortedPostings(p)
}
return NewBlockChunkSeriesSet(q.blockID, q.index, q.chunks, q.tombstones, p, mint, maxt, disableTrimming)
}
// PostingsForMatchers assembles a single postings iterator against the index reader
// based on the given matchers. The resulting postings are not ordered by series.
func PostingsForMatchers(ctx context.Context, ix IndexReader, ms ...*labels.Matcher) (index.Postings, error) {
var its, notIts []index.Postings
// See which label must be non-empty.
// Optimization for case like {l=~".", l!="1"}.
labelMustBeSet := make(map[string]bool, len(ms))
for _, m := range ms {
if !m.Matches("") {
labelMustBeSet[m.Name] = true
}
}
isSubtractingMatcher := func(m *labels.Matcher) bool {
if !labelMustBeSet[m.Name] {
return true
}
return (m.Type == labels.MatchNotEqual || m.Type == labels.MatchNotRegexp) && m.Matches("")
}
hasSubtractingMatchers, hasIntersectingMatchers := false, false
for _, m := range ms {
if isSubtractingMatcher(m) {
hasSubtractingMatchers = true
} else {
hasIntersectingMatchers = true
}
}
if hasSubtractingMatchers && !hasIntersectingMatchers {
// If there's nothing to subtract from, add in everything and remove the notIts later.
// We prefer to get AllPostings so that the base of subtraction (i.e. allPostings)
// doesn't include series that may be added to the index reader during this function call.
k, v := index.AllPostingsKey()
allPostings, err := ix.Postings(ctx, k, v)
if err != nil {
return nil, err
}
its = append(its, allPostings)
}
// Sort matchers to have the intersecting matchers first.
// This way the base for subtraction is smaller and
// there is no chance that the set we subtract from
// contains postings of series that didn't exist when
// we constructed the set we subtract by.
slices.SortStableFunc(ms, func(i, j *labels.Matcher) int {
if !isSubtractingMatcher(i) && isSubtractingMatcher(j) {
return -1
}
return +1
})
for _, m := range ms {
if ctx.Err() != nil {
return nil, ctx.Err()
}
switch {
case m.Name == "" && m.Value == "": // Special-case for AllPostings, used in tests at least.
k, v := index.AllPostingsKey()
allPostings, err := ix.Postings(ctx, k, v)
if err != nil {
return nil, err
}
its = append(its, allPostings)
case labelMustBeSet[m.Name]:
// If this matcher must be non-empty, we can be smarter.
matchesEmpty := m.Matches("")
isNot := m.Type == labels.MatchNotEqual || m.Type == labels.MatchNotRegexp
switch {
case isNot && matchesEmpty: // l!="foo"
// If the label can't be empty and is a Not and the inner matcher
// doesn't match empty, then subtract it out at the end.
inverse, err := m.Inverse()
if err != nil {
return nil, err
}
it, err := postingsForMatcher(ctx, ix, inverse)
if err != nil {
return nil, err
}
notIts = append(notIts, it)
case isNot && !matchesEmpty: // l!=""
// If the label can't be empty and is a Not, but the inner matcher can
// be empty we need to use inversePostingsForMatcher.
inverse, err := m.Inverse()
if err != nil {
return nil, err
}
it, err := inversePostingsForMatcher(ctx, ix, inverse)
if err != nil {
return nil, err
}
if index.IsEmptyPostingsType(it) {
return index.EmptyPostings(), nil
}
its = append(its, it)
default: // l="a"
// Non-Not matcher, use normal postingsForMatcher.
it, err := postingsForMatcher(ctx, ix, m)
if err != nil {
return nil, err
}
if index.IsEmptyPostingsType(it) {
return index.EmptyPostings(), nil
}
its = append(its, it)
}
default: // l=""
// If the matchers for a labelname selects an empty value, it selects all
// the series which don't have the label name set too. See:
// https://github.com/prometheus/prometheus/issues/3575 and
// https://github.com/prometheus/prometheus/pull/3578#issuecomment-351653555
it, err := inversePostingsForMatcher(ctx, ix, m)
if err != nil {
return nil, err
}
notIts = append(notIts, it)
}
}
it := index.Intersect(its...)
for _, n := range notIts {
it = index.Without(it, n)
}
return it, nil
}
func postingsForMatcher(ctx context.Context, ix IndexReader, m *labels.Matcher) (index.Postings, error) {
// This method will not return postings for missing labels.
// Fast-path for equal matching.
if m.Type == labels.MatchEqual {
return ix.Postings(ctx, m.Name, m.Value)
}
// Fast-path for set matching.
if m.Type == labels.MatchRegexp {
setMatches := m.SetMatches()
if len(setMatches) > 0 {
return ix.Postings(ctx, m.Name, setMatches...)
}
}
it := ix.PostingsForLabelMatching(ctx, m.Name, m.Matches)
return it, it.Err()
}
// inversePostingsForMatcher returns the postings for the series with the label name set but not matching the matcher.
func inversePostingsForMatcher(ctx context.Context, ix IndexReader, m *labels.Matcher) (index.Postings, error) {
// Fast-path for MatchNotRegexp matching.
// Inverse of a MatchNotRegexp is MatchRegexp (double negation).
// Fast-path for set matching.
if m.Type == labels.MatchNotRegexp {
setMatches := m.SetMatches()
if len(setMatches) > 0 {
return ix.Postings(ctx, m.Name, setMatches...)
}
}
// Fast-path for MatchNotEqual matching.
// Inverse of a MatchNotEqual is MatchEqual (double negation).
if m.Type == labels.MatchNotEqual {
return ix.Postings(ctx, m.Name, m.Value)
}
vals, err := ix.LabelValues(ctx, m.Name)
if err != nil {
return nil, err
}
res := vals[:0]
// If the match before inversion was !="" or !~"", we just want all the values.
if m.Value == "" && (m.Type == labels.MatchRegexp || m.Type == labels.MatchEqual) {
res = vals
} else {
count := 1
for _, val := range vals {
if count%checkContextEveryNIterations == 0 && ctx.Err() != nil {
return nil, ctx.Err()
}
count++
if !m.Matches(val) {
res = append(res, val)
}
}
}
return ix.Postings(ctx, m.Name, res...)
}
func labelValuesWithMatchers(ctx context.Context, r IndexReader, name string, matchers ...*labels.Matcher) ([]string, error) {
allValues, err := r.LabelValues(ctx, name)
if err != nil {
return nil, fmt.Errorf("fetching values of label %s: %w", name, err)
}
// If we have a matcher for the label name, we can filter out values that don't match
// before we fetch postings. This is especially useful for labels with many values.
// e.g. __name__ with a selector like {__name__="xyz"}
hasMatchersForOtherLabels := false
for _, m := range matchers {
if m.Name != name {
hasMatchersForOtherLabels = true
continue
}
// re-use the allValues slice to avoid allocations
// this is safe because the iteration is always ahead of the append
filteredValues := allValues[:0]
count := 1
for _, v := range allValues {
if count%checkContextEveryNIterations == 0 && ctx.Err() != nil {
return nil, ctx.Err()
}
count++
if m.Matches(v) {
filteredValues = append(filteredValues, v)
}
}
allValues = filteredValues
}
if len(allValues) == 0 {
return nil, nil
}
// If we don't have any matchers for other labels, then we're done.
if !hasMatchersForOtherLabels {
return allValues, nil
}
p, err := PostingsForMatchers(ctx, r, matchers...)
if err != nil {
return nil, fmt.Errorf("fetching postings for matchers: %w", err)
}
valuesPostings := make([]index.Postings, len(allValues))
for i, value := range allValues {
valuesPostings[i], err = r.Postings(ctx, name, value)
if err != nil {
return nil, fmt.Errorf("fetching postings for %s=%q: %w", name, value, err)
}
}
indexes, err := index.FindIntersectingPostings(p, valuesPostings)
if err != nil {
return nil, fmt.Errorf("intersecting postings: %w", err)
}
values := make([]string, 0, len(indexes))
for _, idx := range indexes {
values = append(values, allValues[idx])
}
return values, nil
}
func labelNamesWithMatchers(ctx context.Context, r IndexReader, matchers ...*labels.Matcher) ([]string, error) {
p, err := PostingsForMatchers(ctx, r, matchers...)
if err != nil {
return nil, err
}
return r.LabelNamesFor(ctx, p)
}
// seriesData, used inside other iterators, are updated when we move from one series to another.
type seriesData struct {
chks []chunks.Meta
intervals tombstones.Intervals
labels labels.Labels
}
// Labels implements part of storage.Series and storage.ChunkSeries.
func (s *seriesData) Labels() labels.Labels { return s.labels }
// blockBaseSeriesSet allows to iterate over all series in the single block.
// Iterated series are trimmed with given min and max time as well as tombstones.
// See newBlockSeriesSet and NewBlockChunkSeriesSet to use it for either sample or chunk iterating.
type blockBaseSeriesSet struct {
blockID ulid.ULID
p index.Postings
index IndexReader
chunks ChunkReader
tombstones tombstones.Reader
mint, maxt int64
disableTrimming bool
curr seriesData
bufChks []chunks.Meta
builder labels.ScratchBuilder
err error
}
func (b *blockBaseSeriesSet) Next() bool {
for b.p.Next() {
if err := b.index.Series(b.p.At(), &b.builder, &b.bufChks); err != nil {
// Postings may be stale. Skip if no underlying series exists.
if errors.Is(err, storage.ErrNotFound) {
continue
}
b.err = fmt.Errorf("get series %d: %w", b.p.At(), err)
return false
}
if len(b.bufChks) == 0 {
continue
}
intervals, err := b.tombstones.Get(b.p.At())
if err != nil {
b.err = fmt.Errorf("get tombstones: %w", err)
return false
}
// NOTE:
// * block time range is half-open: [meta.MinTime, meta.MaxTime).
// * chunks are both closed: [chk.MinTime, chk.MaxTime].
// * requested time ranges are closed: [req.Start, req.End].
var trimFront, trimBack bool
// Copy chunks as iterables are reusable.
// Count those in range to size allocation (roughly - ignoring tombstones).
nChks := 0
for _, chk := range b.bufChks {
if !(chk.MaxTime < b.mint || chk.MinTime > b.maxt) {
nChks++
}
}
chks := make([]chunks.Meta, 0, nChks)
// Prefilter chunks and pick those which are not entirely deleted or totally outside of the requested range.
for _, chk := range b.bufChks {
if chk.MaxTime < b.mint {
continue
}
if chk.MinTime > b.maxt {
continue
}
if (tombstones.Interval{Mint: chk.MinTime, Maxt: chk.MaxTime}.IsSubrange(intervals)) {
continue
}
chks = append(chks, chk)
// If still not entirely deleted, check if trim is needed based on requested time range.
if !b.disableTrimming {
if chk.MinTime < b.mint {
trimFront = true
}
if chk.MaxTime > b.maxt {
trimBack = true
}
}
}
if len(chks) == 0 {
continue
}
if trimFront {
intervals = intervals.Add(tombstones.Interval{Mint: math.MinInt64, Maxt: b.mint - 1})
}
if trimBack {
intervals = intervals.Add(tombstones.Interval{Mint: b.maxt + 1, Maxt: math.MaxInt64})
}
b.curr.labels = b.builder.Labels()
b.curr.chks = chks
b.curr.intervals = intervals
return true
}
return false
}
func (b *blockBaseSeriesSet) Err() error {
if b.err != nil {
return b.err
}
return b.p.Err()
}
func (b *blockBaseSeriesSet) Warnings() annotations.Annotations { return nil }
// populateWithDelGenericSeriesIterator allows to iterate over given chunk
// metas. In each iteration it ensures that chunks are trimmed based on given
// tombstones interval if any.
//
// populateWithDelGenericSeriesIterator assumes that chunks that would be fully
// removed by intervals are filtered out in previous phase.
//
// On each iteration currMeta is available. If currDelIter is not nil, it
// means that the chunk in currMeta is invalid and a chunk rewrite is needed,
// for which currDelIter should be used.
type populateWithDelGenericSeriesIterator struct {
blockID ulid.ULID
cr ChunkReader
// metas are expected to be sorted by minTime and should be related to
// the same, single series.
// It's possible for a single chunks.Meta to refer to multiple chunks.
// cr.ChunkOrIterator() would return an iterable and a nil chunk in this
// case.
metas []chunks.Meta
i int // Index into metas; -1 if not started yet.
err error
bufIter DeletedIterator // Retained for memory re-use. currDelIter may point here.
intervals tombstones.Intervals
currDelIter chunkenc.Iterator
// currMeta is the current chunks.Meta from metas. currMeta.Chunk is set to
// the chunk returned from cr.ChunkOrIterable(). As that can return a nil
// chunk, currMeta.Chunk is not always guaranteed to be set.
currMeta chunks.Meta
}
func (p *populateWithDelGenericSeriesIterator) reset(blockID ulid.ULID, cr ChunkReader, chks []chunks.Meta, intervals tombstones.Intervals) {
p.blockID = blockID
p.cr = cr
p.metas = chks
p.i = -1
p.err = nil
// Note we don't touch p.bufIter.Iter; it is holding on to an iterator we might reuse in next().
p.bufIter.Intervals = p.bufIter.Intervals[:0]
p.intervals = intervals
p.currDelIter = nil
p.currMeta = chunks.Meta{}
}
// If copyHeadChunk is true, then the head chunk (i.e. the in-memory chunk of the TSDB)
// is deep copied to avoid races between reads and copying chunk bytes.
// However, if the deletion intervals overlaps with the head chunk, then the head chunk is
// not copied irrespective of copyHeadChunk because it will be re-encoded later anyway.
func (p *populateWithDelGenericSeriesIterator) next(copyHeadChunk bool) bool {
if p.err != nil || p.i >= len(p.metas)-1 {
return false
}
p.i++
p.currMeta = p.metas[p.i]
p.bufIter.Intervals = p.bufIter.Intervals[:0]
for _, interval := range p.intervals {
if p.currMeta.OverlapsClosedInterval(interval.Mint, interval.Maxt) {
p.bufIter.Intervals = p.bufIter.Intervals.Add(interval)
}
}
hcr, ok := p.cr.(*headChunkReader)
var iterable chunkenc.Iterable
if ok && copyHeadChunk && len(p.bufIter.Intervals) == 0 {
// ChunkWithCopy will copy the head chunk.
var maxt int64
p.currMeta.Chunk, maxt, p.err = hcr.ChunkWithCopy(p.currMeta)
// For the in-memory head chunk the index reader sets maxt as MaxInt64. We fix it here.
p.currMeta.MaxTime = maxt
} else {
p.currMeta.Chunk, iterable, p.err = p.cr.ChunkOrIterable(p.currMeta)
}
if p.err != nil {
p.err = fmt.Errorf("cannot populate chunk %d from block %s: %w", p.currMeta.Ref, p.blockID.String(), p.err)
return false
}
// Use the single chunk if possible.
if p.currMeta.Chunk != nil {
if len(p.bufIter.Intervals) == 0 {
// If there is no overlap with deletion intervals and a single chunk is
// returned, we can take chunk as it is.
p.currDelIter = nil
return true
}
// Otherwise we need to iterate over the samples in the single chunk
// and create new chunks.
p.bufIter.Iter = p.currMeta.Chunk.Iterator(p.bufIter.Iter)
p.currDelIter = &p.bufIter
return true
}
// Otherwise, use the iterable to create an iterator.
p.bufIter.Iter = iterable.Iterator(p.bufIter.Iter)
p.currDelIter = &p.bufIter
return true
}
func (p *populateWithDelGenericSeriesIterator) Err() error { return p.err }
type blockSeriesEntry struct {
chunks ChunkReader
blockID ulid.ULID
seriesData
}
func (s *blockSeriesEntry) Iterator(it chunkenc.Iterator) chunkenc.Iterator {
pi, ok := it.(*populateWithDelSeriesIterator)
if !ok {
pi = &populateWithDelSeriesIterator{}
}
pi.reset(s.blockID, s.chunks, s.chks, s.intervals)
return pi
}
type chunkSeriesEntry struct {
chunks ChunkReader
blockID ulid.ULID
seriesData
}
func (s *chunkSeriesEntry) Iterator(it chunks.Iterator) chunks.Iterator {
pi, ok := it.(*populateWithDelChunkSeriesIterator)
if !ok {
pi = &populateWithDelChunkSeriesIterator{}
}
pi.reset(s.blockID, s.chunks, s.chks, s.intervals)
return pi
}
// populateWithDelSeriesIterator allows to iterate over samples for the single series.
type populateWithDelSeriesIterator struct {
populateWithDelGenericSeriesIterator
curr chunkenc.Iterator
}
func (p *populateWithDelSeriesIterator) reset(blockID ulid.ULID, cr ChunkReader, chks []chunks.Meta, intervals tombstones.Intervals) {
p.populateWithDelGenericSeriesIterator.reset(blockID, cr, chks, intervals)
p.curr = nil
}
func (p *populateWithDelSeriesIterator) Next() chunkenc.ValueType {
if p.curr != nil {
if valueType := p.curr.Next(); valueType != chunkenc.ValNone {
return valueType
}
}
for p.next(false) {
if p.currDelIter != nil {
p.curr = p.currDelIter
} else {
p.curr = p.currMeta.Chunk.Iterator(p.curr)
}
if valueType := p.curr.Next(); valueType != chunkenc.ValNone {
return valueType
}
}
return chunkenc.ValNone
}
func (p *populateWithDelSeriesIterator) Seek(t int64) chunkenc.ValueType {
if p.curr != nil {
if valueType := p.curr.Seek(t); valueType != chunkenc.ValNone {
return valueType
}
}
for p.Next() != chunkenc.ValNone {
if valueType := p.curr.Seek(t); valueType != chunkenc.ValNone {
return valueType
}
}
return chunkenc.ValNone
}
func (p *populateWithDelSeriesIterator) At() (int64, float64) {
return p.curr.At()
}
func (p *populateWithDelSeriesIterator) AtHistogram(h *histogram.Histogram) (int64, *histogram.Histogram) {
return p.curr.AtHistogram(h)
}
func (p *populateWithDelSeriesIterator) AtFloatHistogram(fh *histogram.FloatHistogram) (int64, *histogram.FloatHistogram) {
return p.curr.AtFloatHistogram(fh)
}
func (p *populateWithDelSeriesIterator) AtT() int64 {
return p.curr.AtT()
}
func (p *populateWithDelSeriesIterator) Err() error {
if err := p.populateWithDelGenericSeriesIterator.Err(); err != nil {
return err
}
if p.curr != nil {
return p.curr.Err()
}
return nil
}
type populateWithDelChunkSeriesIterator struct {
populateWithDelGenericSeriesIterator
// currMetaWithChunk is current meta with its chunk field set. This meta
// is guaranteed to map to a single chunk. This differs from
// populateWithDelGenericSeriesIterator.currMeta as that
// could refer to multiple chunks.
currMetaWithChunk chunks.Meta
// chunksFromIterable stores the chunks created from iterating through
// the iterable returned by cr.ChunkOrIterable() (with deleted samples
// removed).
chunksFromIterable []chunks.Meta
chunksFromIterableIdx int
}
func (p *populateWithDelChunkSeriesIterator) reset(blockID ulid.ULID, cr ChunkReader, chks []chunks.Meta, intervals tombstones.Intervals) {
p.populateWithDelGenericSeriesIterator.reset(blockID, cr, chks, intervals)
p.currMetaWithChunk = chunks.Meta{}
p.chunksFromIterable = p.chunksFromIterable[:0]
p.chunksFromIterableIdx = -1
}
func (p *populateWithDelChunkSeriesIterator) Next() bool {
if p.currMeta.Chunk == nil {
// If we've been creating chunks from the iterable, check if there are
// any more chunks to iterate through.
if p.chunksFromIterableIdx < len(p.chunksFromIterable)-1 {
p.chunksFromIterableIdx++
p.currMetaWithChunk = p.chunksFromIterable[p.chunksFromIterableIdx]
return true
}
}
// Move to the next chunk/deletion iterator.
// This is a for loop as if the current p.currDelIter returns no samples
// (which means a chunk won't be created), there still might be more
// samples/chunks from the rest of p.metas.
for p.next(true) {
if p.currDelIter == nil {
p.currMetaWithChunk = p.currMeta
return true
}
if p.currMeta.Chunk != nil {
// If ChunkOrIterable() returned a non-nil chunk, the samples in
// p.currDelIter will only form one chunk, as the only change
// p.currDelIter might make is deleting some samples.
if p.populateCurrForSingleChunk() {
return true
}
} else {
// If ChunkOrIterable() returned an iterable, multiple chunks may be
// created from the samples in p.currDelIter.
if p.populateChunksFromIterable() {
return true
}
}
}
return false
}
// populateCurrForSingleChunk sets the fields within p.currMetaWithChunk. This
// should be called if the samples in p.currDelIter only form one chunk.
func (p *populateWithDelChunkSeriesIterator) populateCurrForSingleChunk() bool {
valueType := p.currDelIter.Next()
if valueType == chunkenc.ValNone {
if err := p.currDelIter.Err(); err != nil {
p.err = fmt.Errorf("iterate chunk while re-encoding: %w", err)
}
return false
}
p.currMetaWithChunk.MinTime = p.currDelIter.AtT()
// Re-encode the chunk if iterator is provided. This means that it has
// some samples to be deleted or chunk is opened.
var (
newChunk chunkenc.Chunk
app chunkenc.Appender
t int64
err error
)
switch valueType {
case chunkenc.ValHistogram:
newChunk = chunkenc.NewHistogramChunk()
if app, err = newChunk.Appender(); err != nil {
break
}
for vt := valueType; vt != chunkenc.ValNone; vt = p.currDelIter.Next() {
if vt != chunkenc.ValHistogram {
err = fmt.Errorf("found value type %v in histogram chunk", vt)
break
}
var h *histogram.Histogram
t, h = p.currDelIter.AtHistogram(nil)
_, _, app, err = app.AppendHistogram(nil, t, h, true)
if err != nil {
break
}
}
case chunkenc.ValFloat:
newChunk = chunkenc.NewXORChunk()
if app, err = newChunk.Appender(); err != nil {
break
}
for vt := valueType; vt != chunkenc.ValNone; vt = p.currDelIter.Next() {
if vt != chunkenc.ValFloat {
err = fmt.Errorf("found value type %v in float chunk", vt)
break
}
var v float64
t, v = p.currDelIter.At()
app.Append(t, v)
}
case chunkenc.ValFloatHistogram:
newChunk = chunkenc.NewFloatHistogramChunk()
if app, err = newChunk.Appender(); err != nil {
break
}
for vt := valueType; vt != chunkenc.ValNone; vt = p.currDelIter.Next() {
if vt != chunkenc.ValFloatHistogram {
err = fmt.Errorf("found value type %v in histogram chunk", vt)
break
}
var h *histogram.FloatHistogram
t, h = p.currDelIter.AtFloatHistogram(nil)
_, _, app, err = app.AppendFloatHistogram(nil, t, h, true)
if err != nil {
break
}
}
default:
err = fmt.Errorf("populateCurrForSingleChunk: value type %v unsupported", valueType)
}
if err != nil {
p.err = fmt.Errorf("iterate chunk while re-encoding: %w", err)
return false
}
if err := p.currDelIter.Err(); err != nil {
p.err = fmt.Errorf("iterate chunk while re-encoding: %w", err)
return false
}
p.currMetaWithChunk.Chunk = newChunk
p.currMetaWithChunk.MaxTime = t
return true
}
// populateChunksFromIterable reads the samples from currDelIter to create
// chunks for chunksFromIterable. It also sets p.currMetaWithChunk to the first
// chunk.
func (p *populateWithDelChunkSeriesIterator) populateChunksFromIterable() bool {
p.chunksFromIterable = p.chunksFromIterable[:0]
p.chunksFromIterableIdx = -1
firstValueType := p.currDelIter.Next()
if firstValueType == chunkenc.ValNone {
if err := p.currDelIter.Err(); err != nil {
p.err = fmt.Errorf("populateChunksFromIterable: no samples could be read: %w", err)
return false
}
return false
}
var (
// t is the timestamp for the current sample.
t int64
cmint int64
cmaxt int64
currentChunk chunkenc.Chunk
app chunkenc.Appender
newChunk chunkenc.Chunk
recoded bool
err error
)
prevValueType := chunkenc.ValNone
for currentValueType := firstValueType; currentValueType != chunkenc.ValNone; currentValueType = p.currDelIter.Next() {
// Check if the encoding has changed (i.e. we need to create a new
// chunk as chunks can't have multiple encoding types).
// For the first sample, the following condition will always be true as
// ValNoneNone != ValFloat | ValHistogram | ValFloatHistogram.
if currentValueType != prevValueType {
if prevValueType != chunkenc.ValNone {
p.chunksFromIterable = append(p.chunksFromIterable, chunks.Meta{Chunk: currentChunk, MinTime: cmint, MaxTime: cmaxt})
}
cmint = p.currDelIter.AtT()
if currentChunk, err = currentValueType.NewChunk(); err != nil {
break
}
if app, err = currentChunk.Appender(); err != nil {
break
}
}
switch currentValueType {
case chunkenc.ValFloat:
{
var v float64
t, v = p.currDelIter.At()
app.Append(t, v)
}
case chunkenc.ValHistogram:
{
var v *histogram.Histogram
t, v = p.currDelIter.AtHistogram(nil)
// No need to set prevApp as AppendHistogram will set the
// counter reset header for the appender that's returned.
newChunk, recoded, app, err = app.AppendHistogram(nil, t, v, false)
}
case chunkenc.ValFloatHistogram:
{
var v *histogram.FloatHistogram
t, v = p.currDelIter.AtFloatHistogram(nil)
// No need to set prevApp as AppendHistogram will set the
// counter reset header for the appender that's returned.
newChunk, recoded, app, err = app.AppendFloatHistogram(nil, t, v, false)
}
}
if err != nil {
break
}
if newChunk != nil {
if !recoded {
p.chunksFromIterable = append(p.chunksFromIterable, chunks.Meta{Chunk: currentChunk, MinTime: cmint, MaxTime: cmaxt})
}
currentChunk = newChunk
cmint = t
}
cmaxt = t
prevValueType = currentValueType
}
if err != nil {
p.err = fmt.Errorf("populateChunksFromIterable: error when writing new chunks: %w", err)
return false
}
if err = p.currDelIter.Err(); err != nil {
p.err = fmt.Errorf("populateChunksFromIterable: currDelIter error when writing new chunks: %w", err)
return false
}
if prevValueType != chunkenc.ValNone {
p.chunksFromIterable = append(p.chunksFromIterable, chunks.Meta{Chunk: currentChunk, MinTime: cmint, MaxTime: cmaxt})
}
if len(p.chunksFromIterable) == 0 {
return false
}
p.currMetaWithChunk = p.chunksFromIterable[0]
p.chunksFromIterableIdx = 0
return true
}
func (p *populateWithDelChunkSeriesIterator) At() chunks.Meta { return p.currMetaWithChunk }
// blockSeriesSet allows to iterate over sorted, populated series with applied tombstones.
// Series with all deleted chunks are still present as Series with no samples.
// Samples from chunks are also trimmed to requested min and max time.
type blockSeriesSet struct {
blockBaseSeriesSet
}
func newBlockSeriesSet(i IndexReader, c ChunkReader, t tombstones.Reader, p index.Postings, mint, maxt int64, disableTrimming bool) storage.SeriesSet {
return &blockSeriesSet{
blockBaseSeriesSet{
index: i,
chunks: c,
tombstones: t,
p: p,
mint: mint,
maxt: maxt,
disableTrimming: disableTrimming,
},
}
}
func (b *blockSeriesSet) At() storage.Series {
// At can be looped over before iterating, so save the current values locally.
return &blockSeriesEntry{
chunks: b.chunks,
blockID: b.blockID,
seriesData: b.curr,
}
}
// blockChunkSeriesSet allows to iterate over sorted, populated series with applied tombstones.
// Series with all deleted chunks are still present as Labelled iterator with no chunks.
// Chunks are also trimmed to requested [min and max] (keeping samples with min and max timestamps).
type blockChunkSeriesSet struct {
blockBaseSeriesSet
}
func NewBlockChunkSeriesSet(id ulid.ULID, i IndexReader, c ChunkReader, t tombstones.Reader, p index.Postings, mint, maxt int64, disableTrimming bool) storage.ChunkSeriesSet {
return &blockChunkSeriesSet{
blockBaseSeriesSet{
blockID: id,
index: i,
chunks: c,
tombstones: t,
p: p,
mint: mint,
maxt: maxt,
disableTrimming: disableTrimming,
},
}
}
func (b *blockChunkSeriesSet) At() storage.ChunkSeries {
// At can be looped over before iterating, so save the current values locally.
return &chunkSeriesEntry{
chunks: b.chunks,
blockID: b.blockID,
seriesData: b.curr,
}
}
// NewMergedStringIter returns string iterator that allows to merge symbols on demand and stream result.
func NewMergedStringIter(a, 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
err error
}
func (m *mergedStringIter) Next() bool {
if (!m.aok && !m.bok) || (m.Err() != nil) {
return false
}
switch {
case !m.aok:
m.cur = m.b.At()
m.bok = m.b.Next()
m.err = m.b.Err()
case !m.bok:
m.cur = m.a.At()
m.aok = m.a.Next()
m.err = m.a.Err()
case m.b.At() > m.a.At():
m.cur = m.a.At()
m.aok = m.a.Next()
m.err = m.a.Err()
case m.a.At() > m.b.At():
m.cur = m.b.At()
m.bok = m.b.Next()
m.err = m.b.Err()
default: // Equal.
m.cur = m.b.At()
m.aok = m.a.Next()
m.err = m.a.Err()
m.bok = m.b.Next()
if m.err == nil {
m.err = m.b.Err()
}
}
return true
}
func (m mergedStringIter) At() string { return m.cur }
func (m mergedStringIter) Err() error {
return m.err
}
// DeletedIterator wraps chunk Iterator and makes sure any deleted metrics are not returned.
type DeletedIterator struct {
// Iter is an Iterator to be wrapped.
Iter chunkenc.Iterator
// Intervals are the deletion intervals.
Intervals tombstones.Intervals
}
func (it *DeletedIterator) At() (int64, float64) {
return it.Iter.At()
}
func (it *DeletedIterator) AtHistogram(h *histogram.Histogram) (int64, *histogram.Histogram) {
t, h := it.Iter.AtHistogram(h)
return t, h
}
func (it *DeletedIterator) AtFloatHistogram(fh *histogram.FloatHistogram) (int64, *histogram.FloatHistogram) {
t, h := it.Iter.AtFloatHistogram(fh)
return t, h
}
func (it *DeletedIterator) AtT() int64 {
return it.Iter.AtT()
}
func (it *DeletedIterator) Seek(t int64) chunkenc.ValueType {
if it.Iter.Err() != nil {
return chunkenc.ValNone
}
valueType := it.Iter.Seek(t)
if valueType == chunkenc.ValNone {
return chunkenc.ValNone
}
// Now double check if the entry falls into a deleted interval.
ts := it.AtT()
for _, itv := range it.Intervals {
if ts < itv.Mint {
return valueType
}
if ts > itv.Maxt {
it.Intervals = it.Intervals[1:]
continue
}
// We're in the middle of an interval, we can now call Next().
return it.Next()
}
// The timestamp is greater than all the deleted intervals.
return valueType
}
func (it *DeletedIterator) Next() chunkenc.ValueType {
Outer:
for valueType := it.Iter.Next(); valueType != chunkenc.ValNone; valueType = it.Iter.Next() {
ts := it.AtT()
for _, tr := range it.Intervals {
if tr.InBounds(ts) {
continue Outer
}
if ts <= tr.Maxt {
return valueType
}
it.Intervals = it.Intervals[1:]
}
return valueType
}
return chunkenc.ValNone
}
func (it *DeletedIterator) Err() error { return it.Iter.Err() }
type nopChunkReader struct {
emptyChunk chunkenc.Chunk
}
func newNopChunkReader() ChunkReader {
return nopChunkReader{
emptyChunk: chunkenc.NewXORChunk(),
}
}
func (cr nopChunkReader) ChunkOrIterable(chunks.Meta) (chunkenc.Chunk, chunkenc.Iterable, error) {
return cr.emptyChunk, nil, nil
}
func (cr nopChunkReader) Close() error { return nil }