mirror of
https://github.com/prometheus/prometheus.git
synced 2024-12-30 07:59:40 -08:00
64a9abb8be
The only call we have to LabelValuesFor() has an index.Postings, and we expand it to pass to this method, which will iterate over the values. That's a waste of resources: we can iterate on the index.Postings directly. If there's any downstream implementation that has a slice of series, they can always do an index.ListPostings from them: doing that is cheaper than expanding an abstract index.Postings. Signed-off-by: Oleg Zaytsev <mail@olegzaytsev.com>
778 lines
24 KiB
Go
778 lines
24 KiB
Go
// Copyright 2021 The Prometheus Authors
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package tsdb
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import (
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"context"
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"errors"
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"fmt"
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"math"
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"slices"
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"sync"
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"github.com/go-kit/log/level"
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"github.com/prometheus/prometheus/model/labels"
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"github.com/prometheus/prometheus/storage"
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"github.com/prometheus/prometheus/tsdb/chunkenc"
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"github.com/prometheus/prometheus/tsdb/chunks"
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"github.com/prometheus/prometheus/tsdb/index"
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)
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func (h *Head) ExemplarQuerier(ctx context.Context) (storage.ExemplarQuerier, error) {
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return h.exemplars.ExemplarQuerier(ctx)
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}
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// Index returns an IndexReader against the block.
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func (h *Head) Index() (IndexReader, error) {
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return h.indexRange(math.MinInt64, math.MaxInt64), nil
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}
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func (h *Head) indexRange(mint, maxt int64) *headIndexReader {
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if hmin := h.MinTime(); hmin > mint {
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mint = hmin
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}
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return &headIndexReader{head: h, mint: mint, maxt: maxt}
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}
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type headIndexReader struct {
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head *Head
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mint, maxt int64
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}
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func (h *headIndexReader) Close() error {
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return nil
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}
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func (h *headIndexReader) Symbols() index.StringIter {
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return h.head.postings.Symbols()
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}
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// SortedLabelValues returns label values present in the head for the
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// specific label name that are within the time range mint to maxt.
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// If matchers are specified the returned result set is reduced
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// to label values of metrics matching the matchers.
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func (h *headIndexReader) SortedLabelValues(ctx context.Context, name string, matchers ...*labels.Matcher) ([]string, error) {
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values, err := h.LabelValues(ctx, name, matchers...)
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if err == nil {
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slices.Sort(values)
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}
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return values, err
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}
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// LabelValues returns label values present in the head for the
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// specific label name that are within the time range mint to maxt.
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// If matchers are specified the returned result set is reduced
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// to label values of metrics matching the matchers.
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func (h *headIndexReader) LabelValues(ctx context.Context, name string, matchers ...*labels.Matcher) ([]string, error) {
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if h.maxt < h.head.MinTime() || h.mint > h.head.MaxTime() {
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return []string{}, nil
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}
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if len(matchers) == 0 {
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return h.head.postings.LabelValues(ctx, name), nil
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}
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return labelValuesWithMatchers(ctx, h, name, matchers...)
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}
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// LabelNames returns all the unique label names present in the head
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// that are within the time range mint to maxt.
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func (h *headIndexReader) LabelNames(ctx context.Context, matchers ...*labels.Matcher) ([]string, error) {
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if h.maxt < h.head.MinTime() || h.mint > h.head.MaxTime() {
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return []string{}, nil
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}
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if len(matchers) == 0 {
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labelNames := h.head.postings.LabelNames()
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slices.Sort(labelNames)
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return labelNames, nil
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}
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return labelNamesWithMatchers(ctx, h, matchers...)
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}
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// Postings returns the postings list iterator for the label pairs.
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func (h *headIndexReader) Postings(ctx context.Context, name string, values ...string) (index.Postings, error) {
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switch len(values) {
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case 0:
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return index.EmptyPostings(), nil
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case 1:
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return h.head.postings.Get(name, values[0]), nil
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default:
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res := make([]index.Postings, 0, len(values))
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for _, value := range values {
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if p := h.head.postings.Get(name, value); !index.IsEmptyPostingsType(p) {
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res = append(res, p)
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}
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}
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return index.Merge(ctx, res...), nil
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}
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}
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func (h *headIndexReader) PostingsForLabelMatching(ctx context.Context, name string, match func(string) bool) index.Postings {
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return h.head.postings.PostingsForLabelMatching(ctx, name, match)
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}
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func (h *headIndexReader) SortedPostings(p index.Postings) index.Postings {
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series := make([]*memSeries, 0, 128)
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// Fetch all the series only once.
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for p.Next() {
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s := h.head.series.getByID(chunks.HeadSeriesRef(p.At()))
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if s == nil {
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level.Debug(h.head.logger).Log("msg", "Looked up series not found")
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} else {
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series = append(series, s)
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}
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}
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if err := p.Err(); err != nil {
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return index.ErrPostings(fmt.Errorf("expand postings: %w", err))
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}
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slices.SortFunc(series, func(a, b *memSeries) int {
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return labels.Compare(a.lset, b.lset)
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})
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// Convert back to list.
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ep := make([]storage.SeriesRef, 0, len(series))
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for _, p := range series {
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ep = append(ep, storage.SeriesRef(p.ref))
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}
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return index.NewListPostings(ep)
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}
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// ShardedPostings implements IndexReader. This function returns an failing postings list if sharding
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// has not been enabled in the Head.
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func (h *headIndexReader) ShardedPostings(p index.Postings, shardIndex, shardCount uint64) index.Postings {
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if !h.head.opts.EnableSharding {
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return index.ErrPostings(errors.New("sharding is disabled"))
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}
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out := make([]storage.SeriesRef, 0, 128)
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for p.Next() {
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s := h.head.series.getByID(chunks.HeadSeriesRef(p.At()))
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if s == nil {
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level.Debug(h.head.logger).Log("msg", "Looked up series not found")
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continue
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}
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// Check if the series belong to the shard.
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if s.shardHash%shardCount != shardIndex {
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continue
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}
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out = append(out, storage.SeriesRef(s.ref))
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}
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return index.NewListPostings(out)
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}
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// Series returns the series for the given reference.
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// Chunks are skipped if chks is nil.
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func (h *headIndexReader) Series(ref storage.SeriesRef, builder *labels.ScratchBuilder, chks *[]chunks.Meta) error {
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s := h.head.series.getByID(chunks.HeadSeriesRef(ref))
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if s == nil {
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h.head.metrics.seriesNotFound.Inc()
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return storage.ErrNotFound
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}
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builder.Assign(s.lset)
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if chks == nil {
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return nil
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}
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s.Lock()
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defer s.Unlock()
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*chks = (*chks)[:0]
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for i, c := range s.mmappedChunks {
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// Do not expose chunks that are outside of the specified range.
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if !c.OverlapsClosedInterval(h.mint, h.maxt) {
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continue
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}
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*chks = append(*chks, chunks.Meta{
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MinTime: c.minTime,
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MaxTime: c.maxTime,
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Ref: chunks.ChunkRef(chunks.NewHeadChunkRef(s.ref, s.headChunkID(i))),
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})
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}
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if s.headChunks != nil {
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var maxTime int64
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var i, j int
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for i = s.headChunks.len() - 1; i >= 0; i-- {
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chk := s.headChunks.atOffset(i)
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if i == 0 {
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// Set the head chunk as open (being appended to) for the first headChunk.
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maxTime = math.MaxInt64
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} else {
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maxTime = chk.maxTime
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}
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if chk.OverlapsClosedInterval(h.mint, h.maxt) {
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*chks = append(*chks, chunks.Meta{
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MinTime: chk.minTime,
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MaxTime: maxTime,
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Ref: chunks.ChunkRef(chunks.NewHeadChunkRef(s.ref, s.headChunkID(len(s.mmappedChunks)+j))),
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})
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}
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j++
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}
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}
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return nil
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}
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// headChunkID returns the HeadChunkID referred to by the given position.
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// * 0 <= pos < len(s.mmappedChunks) refer to s.mmappedChunks[pos]
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// * pos >= len(s.mmappedChunks) refers to s.headChunks linked list.
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func (s *memSeries) headChunkID(pos int) chunks.HeadChunkID {
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return chunks.HeadChunkID(pos) + s.firstChunkID
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}
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// oooHeadChunkID returns the HeadChunkID referred to by the given position.
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// * 0 <= pos < len(s.oooMmappedChunks) refer to s.oooMmappedChunks[pos]
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// * pos == len(s.oooMmappedChunks) refers to s.oooHeadChunk
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// The caller must ensure that s.ooo is not nil.
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func (s *memSeries) oooHeadChunkID(pos int) chunks.HeadChunkID {
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return chunks.HeadChunkID(pos) + s.ooo.firstOOOChunkID
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}
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// LabelValueFor returns label value for the given label name in the series referred to by ID.
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func (h *headIndexReader) LabelValueFor(_ context.Context, id storage.SeriesRef, label string) (string, error) {
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memSeries := h.head.series.getByID(chunks.HeadSeriesRef(id))
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if memSeries == nil {
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return "", storage.ErrNotFound
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}
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value := memSeries.lset.Get(label)
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if value == "" {
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return "", storage.ErrNotFound
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}
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return value, nil
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}
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// LabelNamesFor returns all the label names for the series referred to by the postings.
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// The names returned are sorted.
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func (h *headIndexReader) LabelNamesFor(ctx context.Context, series index.Postings) ([]string, error) {
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namesMap := make(map[string]struct{})
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i := 0
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for series.Next() {
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i++
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if i%checkContextEveryNIterations == 0 && ctx.Err() != nil {
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return nil, ctx.Err()
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}
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memSeries := h.head.series.getByID(chunks.HeadSeriesRef(series.At()))
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if memSeries == nil {
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// Series not found, this happens during compaction,
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// when series was garbage collected after the caller got the series IDs.
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continue
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}
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memSeries.lset.Range(func(lbl labels.Label) {
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namesMap[lbl.Name] = struct{}{}
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})
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}
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if err := series.Err(); err != nil {
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return nil, err
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}
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names := make([]string, 0, len(namesMap))
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for name := range namesMap {
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names = append(names, name)
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}
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slices.Sort(names)
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return names, nil
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}
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// Chunks returns a ChunkReader against the block.
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func (h *Head) Chunks() (ChunkReader, error) {
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return h.chunksRange(math.MinInt64, math.MaxInt64, h.iso.State(math.MinInt64, math.MaxInt64))
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}
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func (h *Head) chunksRange(mint, maxt int64, is *isolationState) (*headChunkReader, error) {
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h.closedMtx.Lock()
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defer h.closedMtx.Unlock()
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if h.closed {
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return nil, errors.New("can't read from a closed head")
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}
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if hmin := h.MinTime(); hmin > mint {
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mint = hmin
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}
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return &headChunkReader{
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head: h,
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mint: mint,
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maxt: maxt,
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isoState: is,
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}, nil
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}
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type headChunkReader struct {
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head *Head
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mint, maxt int64
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isoState *isolationState
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}
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func (h *headChunkReader) Close() error {
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if h.isoState != nil {
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h.isoState.Close()
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}
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return nil
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}
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// ChunkOrIterable returns the chunk for the reference number.
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func (h *headChunkReader) ChunkOrIterable(meta chunks.Meta) (chunkenc.Chunk, chunkenc.Iterable, error) {
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chk, _, err := h.chunk(meta, false)
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return chk, nil, err
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}
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// ChunkWithCopy returns the chunk for the reference number.
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// If the chunk is the in-memory chunk, then it makes a copy and returns the copied chunk.
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func (h *headChunkReader) ChunkWithCopy(meta chunks.Meta) (chunkenc.Chunk, int64, error) {
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return h.chunk(meta, true)
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}
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// chunk returns the chunk for the reference number.
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// If copyLastChunk is true, then it makes a copy of the head chunk if asked for it.
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// Also returns max time of the chunk.
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func (h *headChunkReader) chunk(meta chunks.Meta, copyLastChunk bool) (chunkenc.Chunk, int64, error) {
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sid, cid := chunks.HeadChunkRef(meta.Ref).Unpack()
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s := h.head.series.getByID(sid)
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// This means that the series has been garbage collected.
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if s == nil {
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return nil, 0, storage.ErrNotFound
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}
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s.Lock()
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c, headChunk, isOpen, err := s.chunk(cid, h.head.chunkDiskMapper, &h.head.memChunkPool)
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if err != nil {
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s.Unlock()
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return nil, 0, err
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}
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defer func() {
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if !headChunk {
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// Set this to nil so that Go GC can collect it after it has been used.
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c.chunk = nil
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c.prev = nil
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h.head.memChunkPool.Put(c)
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}
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}()
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// This means that the chunk is outside the specified range.
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if !c.OverlapsClosedInterval(h.mint, h.maxt) {
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s.Unlock()
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return nil, 0, storage.ErrNotFound
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}
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chk, maxTime := c.chunk, c.maxTime
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if headChunk && isOpen && copyLastChunk {
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// The caller may ask to copy the head chunk in order to take the
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// bytes of the chunk without causing the race between read and append.
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b := s.headChunks.chunk.Bytes()
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newB := make([]byte, len(b))
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copy(newB, b) // TODO(codesome): Use bytes.Clone() when we upgrade to Go 1.20.
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// TODO(codesome): Put back in the pool (non-trivial).
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chk, err = h.head.opts.ChunkPool.Get(s.headChunks.chunk.Encoding(), newB)
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if err != nil {
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return nil, 0, err
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}
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}
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s.Unlock()
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return &safeHeadChunk{
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Chunk: chk,
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s: s,
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cid: cid,
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isoState: h.isoState,
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}, maxTime, nil
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}
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// chunk returns the chunk for the HeadChunkID from memory or by m-mapping it from the disk.
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// If headChunk is false, it means that the returned *memChunk
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// (and not the chunkenc.Chunk inside it) can be garbage collected after its usage.
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// if isOpen is true, it means that the returned *memChunk is used for appends.
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func (s *memSeries) chunk(id chunks.HeadChunkID, chunkDiskMapper *chunks.ChunkDiskMapper, memChunkPool *sync.Pool) (chunk *memChunk, headChunk, isOpen bool, err error) {
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// ix represents the index of chunk in the s.mmappedChunks slice. The chunk id's are
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// incremented by 1 when new chunk is created, hence (id - firstChunkID) gives the slice index.
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// The max index for the s.mmappedChunks slice can be len(s.mmappedChunks)-1, hence if the ix
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// is >= len(s.mmappedChunks), it represents one of the chunks on s.headChunks linked list.
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// The order of elemens is different for slice and linked list.
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// For s.mmappedChunks slice newer chunks are appended to it.
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// For s.headChunks list newer chunks are prepended to it.
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//
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// memSeries {
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// mmappedChunks: [t0, t1, t2]
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// headChunk: {t5}->{t4}->{t3}
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// }
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ix := int(id) - int(s.firstChunkID)
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var headChunksLen int
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if s.headChunks != nil {
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headChunksLen = s.headChunks.len()
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}
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if ix < 0 || ix > len(s.mmappedChunks)+headChunksLen-1 {
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return nil, false, false, storage.ErrNotFound
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}
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if ix < len(s.mmappedChunks) {
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chk, err := chunkDiskMapper.Chunk(s.mmappedChunks[ix].ref)
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if err != nil {
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var cerr *chunks.CorruptionErr
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if errors.As(err, &cerr) {
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panic(err)
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}
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return nil, false, false, err
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}
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mc := memChunkPool.Get().(*memChunk)
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mc.chunk = chk
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mc.minTime = s.mmappedChunks[ix].minTime
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mc.maxTime = s.mmappedChunks[ix].maxTime
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return mc, false, false, nil
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}
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ix -= len(s.mmappedChunks)
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offset := headChunksLen - ix - 1
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// headChunks is a linked list where first element is the most recent one and the last one is the oldest.
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// This order is reversed when compared with mmappedChunks, since mmappedChunks[0] is the oldest chunk,
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// while headChunk.atOffset(0) would give us the most recent chunk.
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// So when calling headChunk.atOffset() we need to reverse the value of ix.
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elem := s.headChunks.atOffset(offset)
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if elem == nil {
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// This should never really happen and would mean that headChunksLen value is NOT equal
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// to the length of the headChunks list.
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return nil, false, false, storage.ErrNotFound
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}
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return elem, true, offset == 0, nil
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}
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// oooMergedChunks return an iterable over one or more OOO chunks for the given
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// chunks.Meta reference from memory or by m-mapping it from the disk. The
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// returned iterable will be a merge of all the overlapping chunks, if any,
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// amongst all the chunks in the OOOHead.
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// This function is not thread safe unless the caller holds a lock.
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// The caller must ensure that s.ooo is not nil.
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func (s *memSeries) oooMergedChunks(meta chunks.Meta, cdm *chunks.ChunkDiskMapper, mint, maxt int64) (*mergedOOOChunks, error) {
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_, cid := chunks.HeadChunkRef(meta.Ref).Unpack()
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// ix represents the index of chunk in the s.mmappedChunks slice. The chunk meta's are
|
|
// incremented by 1 when new chunk is created, hence (meta - firstChunkID) gives the slice index.
|
|
// The max index for the s.mmappedChunks slice can be len(s.mmappedChunks)-1, hence if the ix
|
|
// is len(s.mmappedChunks), it represents the next chunk, which is the head chunk.
|
|
ix := int(cid) - int(s.ooo.firstOOOChunkID)
|
|
if ix < 0 || ix > len(s.ooo.oooMmappedChunks) {
|
|
return nil, storage.ErrNotFound
|
|
}
|
|
|
|
if ix == len(s.ooo.oooMmappedChunks) {
|
|
if s.ooo.oooHeadChunk == nil {
|
|
return nil, errors.New("invalid ooo head chunk")
|
|
}
|
|
}
|
|
|
|
// We create a temporary slice of chunk metas to hold the information of all
|
|
// possible chunks that may overlap with the requested chunk.
|
|
tmpChks := make([]chunkMetaAndChunkDiskMapperRef, 0, len(s.ooo.oooMmappedChunks))
|
|
|
|
oooHeadRef := chunks.ChunkRef(chunks.NewHeadChunkRef(s.ref, s.oooHeadChunkID(len(s.ooo.oooMmappedChunks))))
|
|
if s.ooo.oooHeadChunk != nil && s.ooo.oooHeadChunk.OverlapsClosedInterval(mint, maxt) {
|
|
// We only want to append the head chunk if this chunk existed when
|
|
// Series() was called. This brings consistency in case new data
|
|
// is added in between Series() and Chunk() calls.
|
|
if oooHeadRef == meta.OOOLastRef {
|
|
tmpChks = append(tmpChks, chunkMetaAndChunkDiskMapperRef{
|
|
meta: chunks.Meta{
|
|
// Ignoring samples added before and after the last known min and max time for this chunk.
|
|
MinTime: meta.OOOLastMinTime,
|
|
MaxTime: meta.OOOLastMaxTime,
|
|
Ref: oooHeadRef,
|
|
},
|
|
})
|
|
}
|
|
}
|
|
|
|
for i, c := range s.ooo.oooMmappedChunks {
|
|
chunkRef := chunks.ChunkRef(chunks.NewHeadChunkRef(s.ref, s.oooHeadChunkID(i)))
|
|
// We can skip chunks that came in later than the last known OOOLastRef.
|
|
if chunkRef > meta.OOOLastRef {
|
|
break
|
|
}
|
|
|
|
switch {
|
|
case chunkRef == meta.OOOLastRef:
|
|
tmpChks = append(tmpChks, chunkMetaAndChunkDiskMapperRef{
|
|
meta: chunks.Meta{
|
|
MinTime: meta.OOOLastMinTime,
|
|
MaxTime: meta.OOOLastMaxTime,
|
|
Ref: chunkRef,
|
|
},
|
|
ref: c.ref,
|
|
origMinT: c.minTime,
|
|
origMaxT: c.maxTime,
|
|
})
|
|
case c.OverlapsClosedInterval(mint, maxt):
|
|
tmpChks = append(tmpChks, chunkMetaAndChunkDiskMapperRef{
|
|
meta: chunks.Meta{
|
|
MinTime: c.minTime,
|
|
MaxTime: c.maxTime,
|
|
Ref: chunkRef,
|
|
},
|
|
ref: c.ref,
|
|
})
|
|
}
|
|
}
|
|
|
|
// Next we want to sort all the collected chunks by min time so we can find
|
|
// those that overlap and stop when we know the rest don't.
|
|
slices.SortFunc(tmpChks, refLessByMinTimeAndMinRef)
|
|
|
|
mc := &mergedOOOChunks{}
|
|
absoluteMax := int64(math.MinInt64)
|
|
for _, c := range tmpChks {
|
|
if c.meta.Ref != meta.Ref && (len(mc.chunkIterables) == 0 || c.meta.MinTime > absoluteMax) {
|
|
continue
|
|
}
|
|
var iterable chunkenc.Iterable
|
|
if c.meta.Ref == oooHeadRef {
|
|
var xor *chunkenc.XORChunk
|
|
var err error
|
|
// If head chunk min and max time match the meta OOO markers
|
|
// that means that the chunk has not expanded so we can append
|
|
// it as it is.
|
|
if s.ooo.oooHeadChunk.minTime == meta.OOOLastMinTime && s.ooo.oooHeadChunk.maxTime == meta.OOOLastMaxTime {
|
|
xor, err = s.ooo.oooHeadChunk.chunk.ToXOR() // TODO(jesus.vazquez) (This is an optimization idea that has no priority and might not be that useful) See if we could use a copy of the underlying slice. That would leave the more expensive ToXOR() function only for the usecase where Bytes() is called.
|
|
} else {
|
|
// We need to remove samples that are outside of the markers
|
|
xor, err = s.ooo.oooHeadChunk.chunk.ToXORBetweenTimestamps(meta.OOOLastMinTime, meta.OOOLastMaxTime)
|
|
}
|
|
if err != nil {
|
|
return nil, fmt.Errorf("failed to convert ooo head chunk to xor chunk: %w", err)
|
|
}
|
|
iterable = xor
|
|
} else {
|
|
chk, err := cdm.Chunk(c.ref)
|
|
if err != nil {
|
|
var cerr *chunks.CorruptionErr
|
|
if errors.As(err, &cerr) {
|
|
return nil, fmt.Errorf("invalid ooo mmapped chunk: %w", err)
|
|
}
|
|
return nil, err
|
|
}
|
|
if c.meta.Ref == meta.OOOLastRef &&
|
|
(c.origMinT != meta.OOOLastMinTime || c.origMaxT != meta.OOOLastMaxTime) {
|
|
// The head expanded and was memory mapped so now we need to
|
|
// wrap the chunk within a chunk that doesnt allows us to iterate
|
|
// through samples out of the OOOLastMinT and OOOLastMaxT
|
|
// markers.
|
|
iterable = boundedIterable{chk, meta.OOOLastMinTime, meta.OOOLastMaxTime}
|
|
} else {
|
|
iterable = chk
|
|
}
|
|
}
|
|
mc.chunkIterables = append(mc.chunkIterables, iterable)
|
|
if c.meta.MaxTime > absoluteMax {
|
|
absoluteMax = c.meta.MaxTime
|
|
}
|
|
}
|
|
|
|
return mc, nil
|
|
}
|
|
|
|
var _ chunkenc.Iterable = &boundedIterable{}
|
|
|
|
// boundedIterable is an implementation of chunkenc.Iterable that uses a
|
|
// boundedIterator that only iterates through samples which timestamps are
|
|
// >= minT and <= maxT.
|
|
type boundedIterable struct {
|
|
chunk chunkenc.Chunk
|
|
minT int64
|
|
maxT int64
|
|
}
|
|
|
|
func (b boundedIterable) Iterator(iterator chunkenc.Iterator) chunkenc.Iterator {
|
|
it := b.chunk.Iterator(iterator)
|
|
if it == nil {
|
|
panic("iterator shouldn't be nil")
|
|
}
|
|
return boundedIterator{it, b.minT, b.maxT}
|
|
}
|
|
|
|
var _ chunkenc.Iterator = &boundedIterator{}
|
|
|
|
// boundedIterator is an implementation of Iterator that only iterates through
|
|
// samples which timestamps are >= minT and <= maxT.
|
|
type boundedIterator struct {
|
|
chunkenc.Iterator
|
|
minT int64
|
|
maxT int64
|
|
}
|
|
|
|
// Next the first time its called it will advance as many positions as necessary
|
|
// until its able to find a sample within the bounds minT and maxT.
|
|
// If there are samples within bounds it will advance one by one amongst them.
|
|
// If there are no samples within bounds it will return false.
|
|
func (b boundedIterator) Next() chunkenc.ValueType {
|
|
for b.Iterator.Next() == chunkenc.ValFloat {
|
|
t, _ := b.Iterator.At()
|
|
switch {
|
|
case t < b.minT:
|
|
continue
|
|
case t > b.maxT:
|
|
return chunkenc.ValNone
|
|
default:
|
|
return chunkenc.ValFloat
|
|
}
|
|
}
|
|
return chunkenc.ValNone
|
|
}
|
|
|
|
func (b boundedIterator) Seek(t int64) chunkenc.ValueType {
|
|
if t < b.minT {
|
|
// We must seek at least up to b.minT if it is asked for something before that.
|
|
val := b.Iterator.Seek(b.minT)
|
|
if !(val == chunkenc.ValFloat) {
|
|
return chunkenc.ValNone
|
|
}
|
|
t, _ := b.Iterator.At()
|
|
if t <= b.maxT {
|
|
return chunkenc.ValFloat
|
|
}
|
|
}
|
|
if t > b.maxT {
|
|
// We seek anyway so that the subsequent Next() calls will also return false.
|
|
b.Iterator.Seek(t)
|
|
return chunkenc.ValNone
|
|
}
|
|
return b.Iterator.Seek(t)
|
|
}
|
|
|
|
// safeHeadChunk makes sure that the chunk can be accessed without a race condition.
|
|
type safeHeadChunk struct {
|
|
chunkenc.Chunk
|
|
s *memSeries
|
|
cid chunks.HeadChunkID
|
|
isoState *isolationState
|
|
}
|
|
|
|
func (c *safeHeadChunk) Iterator(reuseIter chunkenc.Iterator) chunkenc.Iterator {
|
|
c.s.Lock()
|
|
it := c.s.iterator(c.cid, c.Chunk, c.isoState, reuseIter)
|
|
c.s.Unlock()
|
|
return it
|
|
}
|
|
|
|
// iterator returns a chunk iterator for the requested chunkID, or a NopIterator if the requested ID is out of range.
|
|
// It is unsafe to call this concurrently with s.append(...) without holding the series lock.
|
|
func (s *memSeries) iterator(id chunks.HeadChunkID, c chunkenc.Chunk, isoState *isolationState, it chunkenc.Iterator) chunkenc.Iterator {
|
|
ix := int(id) - int(s.firstChunkID)
|
|
|
|
numSamples := c.NumSamples()
|
|
stopAfter := numSamples
|
|
|
|
if isoState != nil && !isoState.IsolationDisabled() {
|
|
totalSamples := 0 // Total samples in this series.
|
|
previousSamples := 0 // Samples before this chunk.
|
|
|
|
for j, d := range s.mmappedChunks {
|
|
totalSamples += int(d.numSamples)
|
|
if j < ix {
|
|
previousSamples += int(d.numSamples)
|
|
}
|
|
}
|
|
|
|
ix -= len(s.mmappedChunks)
|
|
if s.headChunks != nil {
|
|
// Iterate all head chunks from the oldest to the newest.
|
|
headChunksLen := s.headChunks.len()
|
|
for j := headChunksLen - 1; j >= 0; j-- {
|
|
chk := s.headChunks.atOffset(j)
|
|
chkSamples := chk.chunk.NumSamples()
|
|
totalSamples += chkSamples
|
|
// Chunk ID is len(s.mmappedChunks) + $(headChunks list position).
|
|
// Where $(headChunks list position) is zero for the oldest chunk and $(s.headChunks.len() - 1)
|
|
// for the newest (open) chunk.
|
|
if headChunksLen-1-j < ix {
|
|
previousSamples += chkSamples
|
|
}
|
|
}
|
|
}
|
|
|
|
// Removing the extra transactionIDs that are relevant for samples that
|
|
// come after this chunk, from the total transactionIDs.
|
|
appendIDsToConsider := int(s.txs.txIDCount) - (totalSamples - (previousSamples + numSamples))
|
|
|
|
// Iterate over the appendIDs, find the first one that the isolation state says not
|
|
// to return.
|
|
it := s.txs.iterator()
|
|
for index := 0; index < appendIDsToConsider; index++ {
|
|
appendID := it.At()
|
|
if appendID <= isoState.maxAppendID { // Easy check first.
|
|
if _, ok := isoState.incompleteAppends[appendID]; !ok {
|
|
it.Next()
|
|
continue
|
|
}
|
|
}
|
|
stopAfter = numSamples - (appendIDsToConsider - index)
|
|
if stopAfter < 0 {
|
|
stopAfter = 0 // Stopped in a previous chunk.
|
|
}
|
|
break
|
|
}
|
|
}
|
|
|
|
if stopAfter == 0 {
|
|
return chunkenc.NewNopIterator()
|
|
}
|
|
if stopAfter == numSamples {
|
|
return c.Iterator(it)
|
|
}
|
|
return makeStopIterator(c, it, stopAfter)
|
|
}
|
|
|
|
// stopIterator wraps an Iterator, but only returns the first
|
|
// stopAfter values, if initialized with i=-1.
|
|
type stopIterator struct {
|
|
chunkenc.Iterator
|
|
|
|
i, stopAfter int
|
|
}
|
|
|
|
func (it *stopIterator) Next() chunkenc.ValueType {
|
|
if it.i+1 >= it.stopAfter {
|
|
return chunkenc.ValNone
|
|
}
|
|
it.i++
|
|
return it.Iterator.Next()
|
|
}
|
|
|
|
func makeStopIterator(c chunkenc.Chunk, it chunkenc.Iterator, stopAfter int) chunkenc.Iterator {
|
|
// Re-use the Iterator object if it is a stopIterator.
|
|
if stopIter, ok := it.(*stopIterator); ok {
|
|
stopIter.Iterator = c.Iterator(stopIter.Iterator)
|
|
stopIter.i = -1
|
|
stopIter.stopAfter = stopAfter
|
|
return stopIter
|
|
}
|
|
|
|
return &stopIterator{
|
|
Iterator: c.Iterator(it),
|
|
i: -1,
|
|
stopAfter: stopAfter,
|
|
}
|
|
}
|