// Copyright 2013 Prometheus Team // 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 metric import ( "fmt" "github.com/prometheus/prometheus/coding" "github.com/prometheus/prometheus/coding/indexable" "github.com/prometheus/prometheus/model" dto "github.com/prometheus/prometheus/model/generated" "github.com/prometheus/prometheus/storage/raw/leveldb" "time" ) // diskFrontier describes an on-disk store of series to provide a // representation of the known keyspace and time series values available. // // This is used to reduce the burden associated with LevelDB iterator // management. type diskFrontier struct { firstFingerprint *model.Fingerprint firstSupertime time.Time lastFingerprint *model.Fingerprint lastSupertime time.Time } func (f diskFrontier) String() string { return fmt.Sprintf("diskFrontier from %s at %s to %s at %s", f.firstFingerprint.ToRowKey(), f.firstSupertime, f.lastFingerprint.ToRowKey(), f.lastSupertime) } func (f diskFrontier) ContainsFingerprint(fingerprint *model.Fingerprint) bool { return !(fingerprint.Less(f.firstFingerprint) || f.lastFingerprint.Less(fingerprint)) } func newDiskFrontier(i leveldb.Iterator) (d *diskFrontier, err error) { if !i.SeekToLast() || i.Key() == nil { return } lastKey, err := extractSampleKey(i) if err != nil { panic(fmt.Sprintln(err, i.Key(), i.Value())) } if !i.SeekToFirst() || i.Key() == nil { return } firstKey, err := extractSampleKey(i) if i.Key() == nil { return } if err != nil { panic(err) } d = &diskFrontier{} d.firstFingerprint = firstKey.Fingerprint d.firstSupertime = firstKey.FirstTimestamp d.lastFingerprint = lastKey.Fingerprint d.lastSupertime = lastKey.FirstTimestamp return } // seriesFrontier represents the valid seek frontier for a given series. type seriesFrontier struct { firstSupertime time.Time lastSupertime time.Time lastTime time.Time } func (f seriesFrontier) String() string { return fmt.Sprintf("seriesFrontier from %s to %s at %s", f.firstSupertime, f.lastSupertime, f.lastTime) } // newSeriesFrontier furnishes a populated diskFrontier for a given // fingerprint. A nil diskFrontier will be returned if the series cannot // be found in the store. func newSeriesFrontier(f *model.Fingerprint, d diskFrontier, i leveldb.Iterator) (s *seriesFrontier, err error) { lowerSeek := firstSupertime upperSeek := lastSupertime // If the diskFrontier for this iterator says that the candidate fingerprint // is outside of its seeking domain, there is no way that a seriesFrontier // could be materialized. Simply bail. if !d.ContainsFingerprint(f) { return } // If we are either the first or the last key in the database, we need to use // pessimistic boundary frontiers. if f.Equal(d.firstFingerprint) { lowerSeek = indexable.EncodeTime(d.firstSupertime) } if f.Equal(d.lastFingerprint) { upperSeek = indexable.EncodeTime(d.lastSupertime) } // TODO: Convert this to SampleKey.ToPartialDTO. key := &dto.SampleKey{ Fingerprint: f.ToDTO(), Timestamp: upperSeek, } raw := coding.NewPBEncoder(key).MustEncode() i.Seek(raw) if i.Key() == nil { return } retrievedKey, err := extractSampleKey(i) if err != nil { panic(err) } retrievedFingerprint := retrievedKey.Fingerprint // The returned fingerprint may not match if the original seek key lives // outside of a metric's frontier. This is probable, for we are seeking to // to the maximum allowed time, which could advance us to the next // fingerprint. // // if !retrievedFingerprint.Equal(f) { i.Previous() retrievedKey, err = extractSampleKey(i) if err != nil { panic(err) } retrievedFingerprint := retrievedKey.Fingerprint // If the previous key does not match, we know that the requested // fingerprint does not live in the database. if !retrievedFingerprint.Equal(f) { return } } s = &seriesFrontier{ lastSupertime: retrievedKey.FirstTimestamp, lastTime: retrievedKey.LastTimestamp, } key.Timestamp = lowerSeek raw = coding.NewPBEncoder(key).MustEncode() i.Seek(raw) retrievedKey, err = extractSampleKey(i) if err != nil { panic(err) } retrievedFingerprint = retrievedKey.Fingerprint s.firstSupertime = retrievedKey.FirstTimestamp return } // Contains indicates whether a given time value is within the recorded // interval. func (s seriesFrontier) Contains(t time.Time) bool { return !(t.Before(s.firstSupertime) || t.After(s.lastTime)) } // InSafeSeekRange indicates whether the time is within the recorded time range // and is safely seekable such that a seek does not result in an iterator point // after the last value of the series or outside of the entire store. func (s seriesFrontier) InSafeSeekRange(t time.Time) (safe bool) { if !s.Contains(t) { return } if s.lastSupertime.Before(t) { return } return true } func (s seriesFrontier) After(t time.Time) bool { return s.firstSupertime.After(t) } // optimalStartTime indicates what the best start time for a curation operation // should be given the curation remark. func (s seriesFrontier) optimalStartTime(remark *model.CurationRemark) (t time.Time) { switch { case remark == nil: t = s.firstSupertime case s.After(remark.LastCompletionTimestamp): t = s.firstSupertime case !s.InSafeSeekRange(remark.LastCompletionTimestamp): t = s.lastSupertime default: t = remark.LastCompletionTimestamp } return }