// 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 ( "fmt" "sort" "strings" "unicode/utf8" "github.com/pkg/errors" "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/labels" ) // Querier provides querying access over time series data of a fixed // time range. type Querier interface { // Select returns a set of series that matches the given label matchers. Select(...labels.Matcher) (SeriesSet, error) // LabelValues returns all potential values for a label name. LabelValues(string) ([]string, error) // LabelValuesFor returns all potential values for a label name. // under the constraint of another label. LabelValuesFor(string, labels.Label) ([]string, error) // LabelNames returns all the unique label names present in the block in sorted order. LabelNames() ([]string, error) // Close releases the resources of the Querier. Close() error } // Series exposes a single time series. type Series interface { // Labels returns the complete set of labels identifying the series. Labels() labels.Labels // Iterator returns a new iterator of the data of the series. Iterator() SeriesIterator } // querier aggregates querying results from time blocks within // a single partition. type querier struct { blocks []Querier } func (q *querier) LabelValues(n string) ([]string, error) { return q.lvals(q.blocks, n) } // LabelNames returns all the unique label names present querier blocks. func (q *querier) LabelNames() ([]string, error) { labelNamesMap := make(map[string]struct{}) for _, b := range q.blocks { names, err := b.LabelNames() if err != nil { return nil, errors.Wrap(err, "LabelNames() from Querier") } for _, name := range names { labelNamesMap[name] = struct{}{} } } labelNames := make([]string, 0, len(labelNamesMap)) for name := range labelNamesMap { labelNames = append(labelNames, name) } sort.Strings(labelNames) return labelNames, nil } func (q *querier) lvals(qs []Querier, n string) ([]string, error) { if len(qs) == 0 { return nil, nil } if len(qs) == 1 { return qs[0].LabelValues(n) } l := len(qs) / 2 s1, err := q.lvals(qs[:l], n) if err != nil { return nil, err } s2, err := q.lvals(qs[l:], n) if err != nil { return nil, err } return mergeStrings(s1, s2), nil } func (q *querier) LabelValuesFor(string, labels.Label) ([]string, error) { return nil, fmt.Errorf("not implemented") } func (q *querier) Select(ms ...labels.Matcher) (SeriesSet, error) { return q.sel(q.blocks, ms) } func (q *querier) sel(qs []Querier, ms []labels.Matcher) (SeriesSet, error) { if len(qs) == 0 { return EmptySeriesSet(), nil } if len(qs) == 1 { return qs[0].Select(ms...) } l := len(qs) / 2 a, err := q.sel(qs[:l], ms) if err != nil { return nil, err } b, err := q.sel(qs[l:], ms) if err != nil { return nil, err } return newMergedSeriesSet(a, b), nil } func (q *querier) Close() error { var merr tsdb_errors.MultiError for _, bq := range q.blocks { merr.Add(bq.Close()) } return merr.Err() } // verticalQuerier aggregates querying results from time blocks within // a single partition. The block time ranges can be overlapping. type verticalQuerier struct { querier } func (q *verticalQuerier) Select(ms ...labels.Matcher) (SeriesSet, error) { return q.sel(q.blocks, ms) } func (q *verticalQuerier) sel(qs []Querier, ms []labels.Matcher) (SeriesSet, error) { if len(qs) == 0 { return EmptySeriesSet(), nil } if len(qs) == 1 { return qs[0].Select(ms...) } l := len(qs) / 2 a, err := q.sel(qs[:l], ms) if err != nil { return nil, err } b, err := q.sel(qs[l:], ms) if err != nil { return nil, err } return newMergedVerticalSeriesSet(a, b), nil } // NewBlockQuerier returns a querier against the reader. func NewBlockQuerier(b BlockReader, mint, maxt int64) (Querier, error) { indexr, err := b.Index() if err != nil { return nil, errors.Wrapf(err, "open index reader") } chunkr, err := b.Chunks() if err != nil { indexr.Close() return nil, errors.Wrapf(err, "open chunk reader") } tombsr, err := b.Tombstones() if err != nil { indexr.Close() chunkr.Close() return nil, errors.Wrapf(err, "open tombstone reader") } return &blockQuerier{ mint: mint, maxt: maxt, index: indexr, chunks: chunkr, tombstones: tombsr, }, nil } // blockQuerier provides querying access to a single block database. type blockQuerier struct { index IndexReader chunks ChunkReader tombstones TombstoneReader closed bool mint, maxt int64 } func (q *blockQuerier) Select(ms ...labels.Matcher) (SeriesSet, error) { base, err := LookupChunkSeries(q.index, q.tombstones, ms...) if err != nil { return nil, err } return &blockSeriesSet{ set: &populatedChunkSeries{ set: base, chunks: q.chunks, mint: q.mint, maxt: q.maxt, }, mint: q.mint, maxt: q.maxt, }, nil } func (q *blockQuerier) LabelValues(name string) ([]string, error) { tpls, err := q.index.LabelValues(name) if err != nil { return nil, err } res := make([]string, 0, tpls.Len()) for i := 0; i < tpls.Len(); i++ { vals, err := tpls.At(i) if err != nil { return nil, err } res = append(res, vals[0]) } return res, nil } func (q *blockQuerier) LabelNames() ([]string, error) { return q.index.LabelNames() } func (q *blockQuerier) LabelValuesFor(string, labels.Label) ([]string, error) { return nil, fmt.Errorf("not implemented") } func (q *blockQuerier) Close() error { if q.closed { return errors.New("block querier already closed") } var merr tsdb_errors.MultiError merr.Add(q.index.Close()) merr.Add(q.chunks.Close()) merr.Add(q.tombstones.Close()) q.closed = true return merr.Err() } // Bitmap used by func isRegexMetaCharacter to check whether a character needs to be escaped. var regexMetaCharacterBytes [16]byte // isRegexMetaCharacter reports whether byte b needs to be escaped. func isRegexMetaCharacter(b byte) bool { return b < utf8.RuneSelf && regexMetaCharacterBytes[b%16]&(1<<(b/16)) != 0 } func init() { for _, b := range []byte(`.+*?()|[]{}^$`) { regexMetaCharacterBytes[b%16] |= 1 << (b / 16) } } func findSetMatches(pattern string) []string { // Return empty matches if the wrapper from Prometheus is missing. if len(pattern) < 6 || pattern[:4] != "^(?:" || pattern[len(pattern)-2:] != ")$" { return nil } escaped := false sets := []*strings.Builder{{}} for i := 4; i < len(pattern)-2; i++ { if escaped { switch { case isRegexMetaCharacter(pattern[i]): sets[len(sets)-1].WriteByte(pattern[i]) case pattern[i] == '\\': sets[len(sets)-1].WriteByte('\\') default: return nil } escaped = false } else { switch { case isRegexMetaCharacter(pattern[i]): if pattern[i] == '|' { sets = append(sets, &strings.Builder{}) } else { return nil } case pattern[i] == '\\': escaped = true default: sets[len(sets)-1].WriteByte(pattern[i]) } } } matches := make([]string, 0, len(sets)) for _, s := range sets { if s.Len() > 0 { matches = append(matches, s.String()) } } return matches } // PostingsForMatchers assembles a single postings iterator against the index reader // based on the given matchers. func PostingsForMatchers(ix IndexReader, ms ...labels.Matcher) (index.Postings, error) { var its, notIts []index.Postings // See which label must be non-empty. labelMustBeSet := make(map[string]bool, len(ms)) for _, m := range ms { if !m.Matches("") { labelMustBeSet[m.Name()] = true } } for _, m := range ms { matchesEmpty := m.Matches("") if labelMustBeSet[m.Name()] || !matchesEmpty { // If this matcher must be non-empty, we can be smarter. nm, isNot := m.(*labels.NotMatcher) if 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. it, err := postingsForMatcher(ix, nm.Matcher) if err != nil { return nil, err } notIts = append(notIts, it) } else if 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. it, err := inversePostingsForMatcher(ix, nm.Matcher) if err != nil { return nil, err } its = append(its, it) } else { // l="a" // Non-Not matcher, use normal postingsForMatcher. it, err := postingsForMatcher(ix, m) if err != nil { return nil, err } its = append(its, it) } } else { // 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(ix, m) if err != nil { return nil, err } notIts = append(notIts, it) } } // If there's nothing to subtract from, add in everything and remove the notIts later. if len(its) == 0 && len(notIts) != 0 { allPostings, err := ix.Postings(index.AllPostingsKey()) if err != nil { return nil, err } its = append(its, allPostings) } it := index.Intersect(its...) for _, n := range notIts { it = index.Without(it, n) } return ix.SortedPostings(it), nil } func postingsForMatcher(ix IndexReader, m labels.Matcher) (index.Postings, error) { // This method will not return postings for missing labels. // Fast-path for equal matching. if em, ok := m.(*labels.EqualMatcher); ok { return ix.Postings(em.Name(), em.Value()) } // Fast-path for set matching. if em, ok := m.(*labels.RegexpMatcher); ok { setMatches := findSetMatches(em.Value()) if len(setMatches) > 0 { return postingsForSetMatcher(ix, em.Name(), setMatches) } } tpls, err := ix.LabelValues(m.Name()) if err != nil { return nil, err } var res []string for i := 0; i < tpls.Len(); i++ { vals, err := tpls.At(i) if err != nil { return nil, err } if m.Matches(vals[0]) { res = append(res, vals[0]) } } if len(res) == 0 { return index.EmptyPostings(), nil } var rit []index.Postings for _, v := range res { it, err := ix.Postings(m.Name(), v) if err != nil { return nil, err } rit = append(rit, it) } return index.Merge(rit...), nil } // inversePostingsForMatcher eeturns the postings for the series with the label name set but not matching the matcher. func inversePostingsForMatcher(ix IndexReader, m labels.Matcher) (index.Postings, error) { tpls, err := ix.LabelValues(m.Name()) if err != nil { return nil, err } var res []string for i := 0; i < tpls.Len(); i++ { vals, err := tpls.At(i) if err != nil { return nil, err } if !m.Matches(vals[0]) { res = append(res, vals[0]) } } var rit []index.Postings for _, v := range res { it, err := ix.Postings(m.Name(), v) if err != nil { return nil, err } rit = append(rit, it) } return index.Merge(rit...), nil } func postingsForSetMatcher(ix IndexReader, name string, matches []string) (index.Postings, error) { var its []index.Postings for _, match := range matches { if it, err := ix.Postings(name, match); err == nil { its = append(its, it) } else { return nil, err } } return index.Merge(its...), nil } func mergeStrings(a, b []string) []string { maxl := len(a) if len(b) > len(a) { maxl = len(b) } res := make([]string, 0, maxl*10/9) for len(a) > 0 && len(b) > 0 { d := strings.Compare(a[0], b[0]) if d == 0 { res = append(res, a[0]) a, b = a[1:], b[1:] } else if d < 0 { res = append(res, a[0]) a = a[1:] } else if d > 0 { res = append(res, b[0]) b = b[1:] } } // Append all remaining elements. res = append(res, a...) res = append(res, b...) return res } // SeriesSet contains a set of series. type SeriesSet interface { Next() bool At() Series Err() error } var emptySeriesSet = errSeriesSet{} // EmptySeriesSet returns a series set that's always empty. func EmptySeriesSet() SeriesSet { return emptySeriesSet } // mergedSeriesSet takes two series sets as a single series set. The input series sets // must be sorted and sequential in time, i.e. if they have the same label set, // the datapoints of a must be before the datapoints of b. type mergedSeriesSet struct { a, b SeriesSet cur Series adone, bdone bool } // NewMergedSeriesSet takes two series sets as a single series set. The input series sets // must be sorted and sequential in time, i.e. if they have the same label set, // the datapoints of a must be before the datapoints of b. func NewMergedSeriesSet(a, b SeriesSet) SeriesSet { return newMergedSeriesSet(a, b) } func newMergedSeriesSet(a, b SeriesSet) *mergedSeriesSet { s := &mergedSeriesSet{a: a, b: b} // Initialize first elements of both sets as Next() needs // one element look-ahead. s.adone = !s.a.Next() s.bdone = !s.b.Next() return s } func (s *mergedSeriesSet) At() Series { return s.cur } func (s *mergedSeriesSet) Err() error { if s.a.Err() != nil { return s.a.Err() } return s.b.Err() } func (s *mergedSeriesSet) compare() int { if s.adone { return 1 } if s.bdone { return -1 } return labels.Compare(s.a.At().Labels(), s.b.At().Labels()) } func (s *mergedSeriesSet) Next() bool { if s.adone && s.bdone || s.Err() != nil { return false } d := s.compare() // Both sets contain the current series. Chain them into a single one. if d > 0 { s.cur = s.b.At() s.bdone = !s.b.Next() } else if d < 0 { s.cur = s.a.At() s.adone = !s.a.Next() } else { s.cur = &chainedSeries{series: []Series{s.a.At(), s.b.At()}} s.adone = !s.a.Next() s.bdone = !s.b.Next() } return true } type mergedVerticalSeriesSet struct { a, b SeriesSet cur Series adone, bdone bool } // NewMergedVerticalSeriesSet takes two series sets as a single series set. // The input series sets must be sorted and // the time ranges of the series can be overlapping. func NewMergedVerticalSeriesSet(a, b SeriesSet) SeriesSet { return newMergedVerticalSeriesSet(a, b) } func newMergedVerticalSeriesSet(a, b SeriesSet) *mergedVerticalSeriesSet { s := &mergedVerticalSeriesSet{a: a, b: b} // Initialize first elements of both sets as Next() needs // one element look-ahead. s.adone = !s.a.Next() s.bdone = !s.b.Next() return s } func (s *mergedVerticalSeriesSet) At() Series { return s.cur } func (s *mergedVerticalSeriesSet) Err() error { if s.a.Err() != nil { return s.a.Err() } return s.b.Err() } func (s *mergedVerticalSeriesSet) compare() int { if s.adone { return 1 } if s.bdone { return -1 } return labels.Compare(s.a.At().Labels(), s.b.At().Labels()) } func (s *mergedVerticalSeriesSet) Next() bool { if s.adone && s.bdone || s.Err() != nil { return false } d := s.compare() // Both sets contain the current series. Chain them into a single one. if d > 0 { s.cur = s.b.At() s.bdone = !s.b.Next() } else if d < 0 { s.cur = s.a.At() s.adone = !s.a.Next() } else { s.cur = &verticalChainedSeries{series: []Series{s.a.At(), s.b.At()}} s.adone = !s.a.Next() s.bdone = !s.b.Next() } return true } // ChunkSeriesSet exposes the chunks and intervals of a series instead of the // actual series itself. type ChunkSeriesSet interface { Next() bool At() (labels.Labels, []chunks.Meta, Intervals) Err() error } // baseChunkSeries loads the label set and chunk references for a postings // list from an index. It filters out series that have labels set that should be unset. type baseChunkSeries struct { p index.Postings index IndexReader tombstones TombstoneReader lset labels.Labels chks []chunks.Meta intervals Intervals err error } // LookupChunkSeries retrieves all series for the given matchers and returns a ChunkSeriesSet // over them. It drops chunks based on tombstones in the given reader. func LookupChunkSeries(ir IndexReader, tr TombstoneReader, ms ...labels.Matcher) (ChunkSeriesSet, error) { if tr == nil { tr = newMemTombstones() } p, err := PostingsForMatchers(ir, ms...) if err != nil { return nil, err } return &baseChunkSeries{ p: p, index: ir, tombstones: tr, }, nil } func (s *baseChunkSeries) At() (labels.Labels, []chunks.Meta, Intervals) { return s.lset, s.chks, s.intervals } func (s *baseChunkSeries) Err() error { return s.err } func (s *baseChunkSeries) Next() bool { var ( lset = make(labels.Labels, len(s.lset)) chkMetas = make([]chunks.Meta, len(s.chks)) err error ) for s.p.Next() { ref := s.p.At() if err := s.index.Series(ref, &lset, &chkMetas); err != nil { // Postings may be stale. Skip if no underlying series exists. if errors.Cause(err) == ErrNotFound { continue } s.err = err return false } s.lset = lset s.chks = chkMetas s.intervals, err = s.tombstones.Get(s.p.At()) if err != nil { s.err = errors.Wrap(err, "get tombstones") return false } if len(s.intervals) > 0 { // Only those chunks that are not entirely deleted. chks := make([]chunks.Meta, 0, len(s.chks)) for _, chk := range s.chks { if !(Interval{chk.MinTime, chk.MaxTime}.isSubrange(s.intervals)) { chks = append(chks, chk) } } s.chks = chks } return true } if err := s.p.Err(); err != nil { s.err = err } return false } // populatedChunkSeries loads chunk data from a store for a set of series // with known chunk references. It filters out chunks that do not fit the // given time range. type populatedChunkSeries struct { set ChunkSeriesSet chunks ChunkReader mint, maxt int64 err error chks []chunks.Meta lset labels.Labels intervals Intervals } func (s *populatedChunkSeries) At() (labels.Labels, []chunks.Meta, Intervals) { return s.lset, s.chks, s.intervals } func (s *populatedChunkSeries) Err() error { return s.err } func (s *populatedChunkSeries) Next() bool { for s.set.Next() { lset, chks, dranges := s.set.At() for len(chks) > 0 { if chks[0].MaxTime >= s.mint { break } chks = chks[1:] } // This is to delete in place while iterating. for i, rlen := 0, len(chks); i < rlen; i++ { j := i - (rlen - len(chks)) c := &chks[j] // Break out at the first chunk that has no overlap with mint, maxt. if c.MinTime > s.maxt { chks = chks[:j] break } c.Chunk, s.err = s.chunks.Chunk(c.Ref) if s.err != nil { // This means that the chunk has be garbage collected. Remove it from the list. if s.err == ErrNotFound { s.err = nil // Delete in-place. s.chks = append(chks[:j], chks[j+1:]...) } return false } } if len(chks) == 0 { continue } s.lset = lset s.chks = chks s.intervals = dranges return true } if err := s.set.Err(); err != nil { s.err = err } return false } // blockSeriesSet is a set of series from an inverted index query. type blockSeriesSet struct { set ChunkSeriesSet err error cur Series mint, maxt int64 } func (s *blockSeriesSet) Next() bool { for s.set.Next() { lset, chunks, dranges := s.set.At() s.cur = &chunkSeries{ labels: lset, chunks: chunks, mint: s.mint, maxt: s.maxt, intervals: dranges, } return true } if s.set.Err() != nil { s.err = s.set.Err() } return false } func (s *blockSeriesSet) At() Series { return s.cur } func (s *blockSeriesSet) Err() error { return s.err } // chunkSeries is a series that is backed by a sequence of chunks holding // time series data. type chunkSeries struct { labels labels.Labels chunks []chunks.Meta // in-order chunk refs mint, maxt int64 intervals Intervals } func (s *chunkSeries) Labels() labels.Labels { return s.labels } func (s *chunkSeries) Iterator() SeriesIterator { return newChunkSeriesIterator(s.chunks, s.intervals, s.mint, s.maxt) } // SeriesIterator iterates over the data of a time series. type SeriesIterator interface { // Seek advances the iterator forward to the given timestamp. // If there's no value exactly at t, it advances to the first value // after t. Seek(t int64) bool // At returns the current timestamp/value pair. At() (t int64, v float64) // Next advances the iterator by one. Next() bool // Err returns the current error. Err() error } // chainedSeries implements a series for a list of time-sorted series. // They all must have the same labels. type chainedSeries struct { series []Series } func (s *chainedSeries) Labels() labels.Labels { return s.series[0].Labels() } func (s *chainedSeries) Iterator() SeriesIterator { return newChainedSeriesIterator(s.series...) } // chainedSeriesIterator implements a series iterater over a list // of time-sorted, non-overlapping iterators. type chainedSeriesIterator struct { series []Series // series in time order i int cur SeriesIterator } func newChainedSeriesIterator(s ...Series) *chainedSeriesIterator { return &chainedSeriesIterator{ series: s, i: 0, cur: s[0].Iterator(), } } func (it *chainedSeriesIterator) Seek(t int64) bool { // We just scan the chained series sequentially as they are already // pre-selected by relevant time and should be accessed sequentially anyway. for i, s := range it.series[it.i:] { cur := s.Iterator() if !cur.Seek(t) { continue } it.cur = cur it.i += i return true } return false } func (it *chainedSeriesIterator) Next() bool { if it.cur.Next() { return true } if err := it.cur.Err(); err != nil { return false } if it.i == len(it.series)-1 { return false } it.i++ it.cur = it.series[it.i].Iterator() return it.Next() } func (it *chainedSeriesIterator) At() (t int64, v float64) { return it.cur.At() } func (it *chainedSeriesIterator) Err() error { return it.cur.Err() } // verticalChainedSeries implements a series for a list of time-sorted, time-overlapping series. // They all must have the same labels. type verticalChainedSeries struct { series []Series } func (s *verticalChainedSeries) Labels() labels.Labels { return s.series[0].Labels() } func (s *verticalChainedSeries) Iterator() SeriesIterator { return newVerticalMergeSeriesIterator(s.series...) } // verticalMergeSeriesIterator implements a series iterater over a list // of time-sorted, time-overlapping iterators. type verticalMergeSeriesIterator struct { a, b SeriesIterator aok, bok, initialized bool curT int64 curV float64 } func newVerticalMergeSeriesIterator(s ...Series) SeriesIterator { if len(s) == 1 { return s[0].Iterator() } else if len(s) == 2 { return &verticalMergeSeriesIterator{ a: s[0].Iterator(), b: s[1].Iterator(), } } return &verticalMergeSeriesIterator{ a: s[0].Iterator(), b: newVerticalMergeSeriesIterator(s[1:]...), } } func (it *verticalMergeSeriesIterator) Seek(t int64) bool { it.aok, it.bok = it.a.Seek(t), it.b.Seek(t) it.initialized = true return it.Next() } func (it *verticalMergeSeriesIterator) Next() bool { if !it.initialized { it.aok = it.a.Next() it.bok = it.b.Next() it.initialized = true } if !it.aok && !it.bok { return false } if !it.aok { it.curT, it.curV = it.b.At() it.bok = it.b.Next() return true } if !it.bok { it.curT, it.curV = it.a.At() it.aok = it.a.Next() return true } acurT, acurV := it.a.At() bcurT, bcurV := it.b.At() if acurT < bcurT { it.curT, it.curV = acurT, acurV it.aok = it.a.Next() } else if acurT > bcurT { it.curT, it.curV = bcurT, bcurV it.bok = it.b.Next() } else { it.curT, it.curV = bcurT, bcurV it.aok = it.a.Next() it.bok = it.b.Next() } return true } func (it *verticalMergeSeriesIterator) At() (t int64, v float64) { return it.curT, it.curV } func (it *verticalMergeSeriesIterator) Err() error { if it.a.Err() != nil { return it.a.Err() } return it.b.Err() } // chunkSeriesIterator implements a series iterator on top // of a list of time-sorted, non-overlapping chunks. type chunkSeriesIterator struct { chunks []chunks.Meta i int cur chunkenc.Iterator bufDelIter *deletedIterator maxt, mint int64 intervals Intervals } func newChunkSeriesIterator(cs []chunks.Meta, dranges Intervals, mint, maxt int64) *chunkSeriesIterator { csi := &chunkSeriesIterator{ chunks: cs, i: 0, mint: mint, maxt: maxt, intervals: dranges, } csi.resetCurIterator() return csi } func (it *chunkSeriesIterator) resetCurIterator() { if len(it.intervals) == 0 { it.cur = it.chunks[it.i].Chunk.Iterator(it.cur) return } if it.bufDelIter == nil { it.bufDelIter = &deletedIterator{ intervals: it.intervals, } } it.bufDelIter.it = it.chunks[it.i].Chunk.Iterator(it.bufDelIter.it) it.cur = it.bufDelIter } func (it *chunkSeriesIterator) Seek(t int64) (ok bool) { if t > it.maxt { return false } // Seek to the first valid value after t. if t < it.mint { t = it.mint } for ; it.chunks[it.i].MaxTime < t; it.i++ { if it.i == len(it.chunks)-1 { return false } } it.resetCurIterator() for it.cur.Next() { t0, _ := it.cur.At() if t0 >= t { return true } } return false } func (it *chunkSeriesIterator) At() (t int64, v float64) { return it.cur.At() } func (it *chunkSeriesIterator) Next() bool { if it.cur.Next() { t, _ := it.cur.At() if t < it.mint { if !it.Seek(it.mint) { return false } t, _ = it.At() return t <= it.maxt } if t > it.maxt { return false } return true } if err := it.cur.Err(); err != nil { return false } if it.i == len(it.chunks)-1 { return false } it.i++ it.resetCurIterator() return it.Next() } func (it *chunkSeriesIterator) Err() error { return it.cur.Err() } // deletedIterator wraps an Iterator and makes sure any deleted metrics are not // returned. type deletedIterator struct { it chunkenc.Iterator intervals Intervals } func (it *deletedIterator) At() (int64, float64) { return it.it.At() } func (it *deletedIterator) Next() bool { Outer: for it.it.Next() { ts, _ := it.it.At() for _, tr := range it.intervals { if tr.inBounds(ts) { continue Outer } if ts > tr.Maxt { it.intervals = it.intervals[1:] continue } return true } return true } return false } func (it *deletedIterator) Err() error { return it.it.Err() } type errSeriesSet struct { err error } func (s errSeriesSet) Next() bool { return false } func (s errSeriesSet) At() Series { return nil } func (s errSeriesSet) Err() error { return s.err }