// Copyright 2014 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 local import ( "encoding/binary" "fmt" "io" "math" "github.com/prometheus/common/model" ) // The 37-byte header of a delta-encoded chunk looks like: // // - used buf bytes: 2 bytes // - time double-delta bytes: 1 bytes // - value double-delta bytes: 1 bytes // - is integer: 1 byte // - base time: 8 bytes // - base value: 8 bytes // - base time delta: 8 bytes // - base value delta: 8 bytes const ( doubleDeltaHeaderBytes = 37 doubleDeltaHeaderMinBytes = 21 // header isn't full for chunk w/ one sample doubleDeltaHeaderBufLenOffset = 0 doubleDeltaHeaderTimeBytesOffset = 2 doubleDeltaHeaderValueBytesOffset = 3 doubleDeltaHeaderIsIntOffset = 4 doubleDeltaHeaderBaseTimeOffset = 5 doubleDeltaHeaderBaseValueOffset = 13 doubleDeltaHeaderBaseTimeDeltaOffset = 21 doubleDeltaHeaderBaseValueDeltaOffset = 29 ) // A doubleDeltaEncodedChunk adaptively stores sample timestamps and values with // a double-delta encoding of various types (int, float) and bit widths. A base // value and timestamp and a base delta for each is saved in the header. The // payload consists of double-deltas, i.e. deviations from the values and // timestamps calculated by applying the base value and time and the base deltas. // However, once 8 bytes would be needed to encode a double-delta value, a // fall-back to the absolute numbers happens (so that timestamps are saved // directly as int64 and values as float64). // doubleDeltaEncodedChunk implements the chunk interface. type doubleDeltaEncodedChunk []byte // newDoubleDeltaEncodedChunk returns a newly allocated doubleDeltaEncodedChunk. func newDoubleDeltaEncodedChunk(tb, vb deltaBytes, isInt bool, length int) *doubleDeltaEncodedChunk { if tb < 1 { panic("need at least 1 time delta byte") } if length < doubleDeltaHeaderBytes+16 { panic(fmt.Errorf( "chunk length %d bytes is insufficient, need at least %d", length, doubleDeltaHeaderBytes+16, )) } c := make(doubleDeltaEncodedChunk, doubleDeltaHeaderIsIntOffset+1, length) c[doubleDeltaHeaderTimeBytesOffset] = byte(tb) c[doubleDeltaHeaderValueBytesOffset] = byte(vb) if vb < d8 && isInt { // Only use int for fewer than 8 value double-delta bytes. c[doubleDeltaHeaderIsIntOffset] = 1 } else { c[doubleDeltaHeaderIsIntOffset] = 0 } return &c } // add implements chunk. func (c doubleDeltaEncodedChunk) Add(s model.SamplePair) ([]Chunk, error) { // TODO(beorn7): Since we return &c, this method might cause an unnecessary allocation. if c.len() == 0 { return c.addFirstSample(s), nil } tb := c.timeBytes() vb := c.valueBytes() if c.len() == 1 { return c.addSecondSample(s, tb, vb) } remainingBytes := cap(c) - len(c) sampleSize := c.sampleSize() // Do we generally have space for another sample in this chunk? If not, // overflow into a new one. if remainingBytes < sampleSize { return addToOverflowChunk(&c, s) } projectedTime := c.baseTime() + model.Time(c.len())*c.baseTimeDelta() ddt := s.Timestamp - projectedTime projectedValue := c.baseValue() + model.SampleValue(c.len())*c.baseValueDelta() ddv := s.Value - projectedValue ntb, nvb, nInt := tb, vb, c.isInt() // If the new sample is incompatible with the current encoding, reencode the // existing chunk data into new chunk(s). if c.isInt() && !isInt64(ddv) { // int->float. nvb = d4 nInt = false } else if !c.isInt() && vb == d4 && projectedValue+model.SampleValue(float32(ddv)) != s.Value { // float32->float64. nvb = d8 } else { if tb < d8 { // Maybe more bytes for timestamp. ntb = max(tb, bytesNeededForSignedTimestampDelta(ddt)) } if c.isInt() && vb < d8 { // Maybe more bytes for sample value. nvb = max(vb, bytesNeededForIntegerSampleValueDelta(ddv)) } } if tb != ntb || vb != nvb || c.isInt() != nInt { if len(c)*2 < cap(c) { return transcodeAndAdd(newDoubleDeltaEncodedChunk(ntb, nvb, nInt, cap(c)), &c, s) } // Chunk is already half full. Better create a new one and save the transcoding efforts. return addToOverflowChunk(&c, s) } offset := len(c) c = c[:offset+sampleSize] switch tb { case d1: c[offset] = byte(ddt) case d2: binary.LittleEndian.PutUint16(c[offset:], uint16(ddt)) case d4: binary.LittleEndian.PutUint32(c[offset:], uint32(ddt)) case d8: // Store the absolute value (no delta) in case of d8. binary.LittleEndian.PutUint64(c[offset:], uint64(s.Timestamp)) default: return nil, fmt.Errorf("invalid number of bytes for time delta: %d", tb) } offset += int(tb) if c.isInt() { switch vb { case d0: // No-op. Constant delta is stored as base value. case d1: c[offset] = byte(int8(ddv)) case d2: binary.LittleEndian.PutUint16(c[offset:], uint16(int16(ddv))) case d4: binary.LittleEndian.PutUint32(c[offset:], uint32(int32(ddv))) // d8 must not happen. Those samples are encoded as float64. default: return nil, fmt.Errorf("invalid number of bytes for integer delta: %d", vb) } } else { switch vb { case d4: binary.LittleEndian.PutUint32(c[offset:], math.Float32bits(float32(ddv))) case d8: // Store the absolute value (no delta) in case of d8. binary.LittleEndian.PutUint64(c[offset:], math.Float64bits(float64(s.Value))) default: return nil, fmt.Errorf("invalid number of bytes for floating point delta: %d", vb) } } return []Chunk{&c}, nil } // clone implements chunk. func (c doubleDeltaEncodedChunk) Clone() Chunk { clone := make(doubleDeltaEncodedChunk, len(c), cap(c)) copy(clone, c) return &clone } // firstTime implements chunk. func (c doubleDeltaEncodedChunk) FirstTime() model.Time { return c.baseTime() } // NewIterator( implements chunk. func (c *doubleDeltaEncodedChunk) NewIterator() ChunkIterator { return newIndexAccessingChunkIterator(c.len(), &doubleDeltaEncodedIndexAccessor{ c: *c, baseT: c.baseTime(), baseΔT: c.baseTimeDelta(), baseV: c.baseValue(), baseΔV: c.baseValueDelta(), tBytes: c.timeBytes(), vBytes: c.valueBytes(), isInt: c.isInt(), }) } // marshal implements chunk. func (c doubleDeltaEncodedChunk) Marshal(w io.Writer) error { if len(c) > math.MaxUint16 { panic("chunk buffer length would overflow a 16 bit uint") } binary.LittleEndian.PutUint16(c[doubleDeltaHeaderBufLenOffset:], uint16(len(c))) n, err := w.Write(c[:cap(c)]) if err != nil { return err } if n != cap(c) { return fmt.Errorf("wanted to write %d bytes, wrote %d", cap(c), n) } return nil } // MarshalToBuf implements chunk. func (c doubleDeltaEncodedChunk) MarshalToBuf(buf []byte) error { if len(c) > math.MaxUint16 { panic("chunk buffer length would overflow a 16 bit uint") } binary.LittleEndian.PutUint16(c[doubleDeltaHeaderBufLenOffset:], uint16(len(c))) n := copy(buf, c) if n != len(c) { return fmt.Errorf("wanted to copy %d bytes to buffer, copied %d", len(c), n) } return nil } // unmarshal implements chunk. func (c *doubleDeltaEncodedChunk) Unmarshal(r io.Reader) error { *c = (*c)[:cap(*c)] if _, err := io.ReadFull(r, *c); err != nil { return err } l := binary.LittleEndian.Uint16((*c)[doubleDeltaHeaderBufLenOffset:]) if int(l) > cap(*c) { return fmt.Errorf("chunk length exceeded during unmarshaling: %d", l) } if int(l) < doubleDeltaHeaderMinBytes { return fmt.Errorf("chunk length less than header size: %d < %d", l, doubleDeltaHeaderMinBytes) } *c = (*c)[:l] return nil } // unmarshalFromBuf implements chunk. func (c *doubleDeltaEncodedChunk) UnmarshalFromBuf(buf []byte) error { *c = (*c)[:cap(*c)] copy(*c, buf) l := binary.LittleEndian.Uint16((*c)[doubleDeltaHeaderBufLenOffset:]) if int(l) > cap(*c) { return fmt.Errorf("chunk length exceeded during unmarshaling: %d", l) } if int(l) < doubleDeltaHeaderMinBytes { return fmt.Errorf("chunk length less than header size: %d < %d", l, doubleDeltaHeaderMinBytes) } *c = (*c)[:l] return nil } // encoding implements chunk. func (c doubleDeltaEncodedChunk) Encoding() ChunkEncoding { return DoubleDelta } func (c doubleDeltaEncodedChunk) baseTime() model.Time { return model.Time( binary.LittleEndian.Uint64( c[doubleDeltaHeaderBaseTimeOffset:], ), ) } func (c doubleDeltaEncodedChunk) baseValue() model.SampleValue { return model.SampleValue( math.Float64frombits( binary.LittleEndian.Uint64( c[doubleDeltaHeaderBaseValueOffset:], ), ), ) } func (c doubleDeltaEncodedChunk) baseTimeDelta() model.Time { if len(c) < doubleDeltaHeaderBaseTimeDeltaOffset+8 { return 0 } return model.Time( binary.LittleEndian.Uint64( c[doubleDeltaHeaderBaseTimeDeltaOffset:], ), ) } func (c doubleDeltaEncodedChunk) baseValueDelta() model.SampleValue { if len(c) < doubleDeltaHeaderBaseValueDeltaOffset+8 { return 0 } return model.SampleValue( math.Float64frombits( binary.LittleEndian.Uint64( c[doubleDeltaHeaderBaseValueDeltaOffset:], ), ), ) } func (c doubleDeltaEncodedChunk) timeBytes() deltaBytes { return deltaBytes(c[doubleDeltaHeaderTimeBytesOffset]) } func (c doubleDeltaEncodedChunk) valueBytes() deltaBytes { return deltaBytes(c[doubleDeltaHeaderValueBytesOffset]) } func (c doubleDeltaEncodedChunk) sampleSize() int { return int(c.timeBytes() + c.valueBytes()) } func (c doubleDeltaEncodedChunk) len() int { if len(c) <= doubleDeltaHeaderIsIntOffset+1 { return 0 } if len(c) <= doubleDeltaHeaderBaseValueOffset+8 { return 1 } return (len(c)-doubleDeltaHeaderBytes)/c.sampleSize() + 2 } func (c doubleDeltaEncodedChunk) isInt() bool { return c[doubleDeltaHeaderIsIntOffset] == 1 } // addFirstSample is a helper method only used by c.add(). It adds timestamp and // value as base time and value. func (c doubleDeltaEncodedChunk) addFirstSample(s model.SamplePair) []Chunk { c = c[:doubleDeltaHeaderBaseValueOffset+8] binary.LittleEndian.PutUint64( c[doubleDeltaHeaderBaseTimeOffset:], uint64(s.Timestamp), ) binary.LittleEndian.PutUint64( c[doubleDeltaHeaderBaseValueOffset:], math.Float64bits(float64(s.Value)), ) return []Chunk{&c} } // addSecondSample is a helper method only used by c.add(). It calculates the // base delta from the provided sample and adds it to the chunk. func (c doubleDeltaEncodedChunk) addSecondSample(s model.SamplePair, tb, vb deltaBytes) ([]Chunk, error) { baseTimeDelta := s.Timestamp - c.baseTime() if baseTimeDelta < 0 { return nil, fmt.Errorf("base time delta is less than zero: %v", baseTimeDelta) } c = c[:doubleDeltaHeaderBytes] if tb >= d8 || bytesNeededForUnsignedTimestampDelta(baseTimeDelta) >= d8 { // If already the base delta needs d8 (or we are at d8 // already, anyway), we better encode this timestamp // directly rather than as a delta and switch everything // to d8. c[doubleDeltaHeaderTimeBytesOffset] = byte(d8) binary.LittleEndian.PutUint64( c[doubleDeltaHeaderBaseTimeDeltaOffset:], uint64(s.Timestamp), ) } else { binary.LittleEndian.PutUint64( c[doubleDeltaHeaderBaseTimeDeltaOffset:], uint64(baseTimeDelta), ) } baseValue := c.baseValue() baseValueDelta := s.Value - baseValue if vb >= d8 || baseValue+baseValueDelta != s.Value { // If we can't reproduce the original sample value (or // if we are at d8 already, anyway), we better encode // this value directly rather than as a delta and switch // everything to d8. c[doubleDeltaHeaderValueBytesOffset] = byte(d8) c[doubleDeltaHeaderIsIntOffset] = 0 binary.LittleEndian.PutUint64( c[doubleDeltaHeaderBaseValueDeltaOffset:], math.Float64bits(float64(s.Value)), ) } else { binary.LittleEndian.PutUint64( c[doubleDeltaHeaderBaseValueDeltaOffset:], math.Float64bits(float64(baseValueDelta)), ) } return []Chunk{&c}, nil } // doubleDeltaEncodedIndexAccessor implements indexAccessor. type doubleDeltaEncodedIndexAccessor struct { c doubleDeltaEncodedChunk baseT, baseΔT model.Time baseV, baseΔV model.SampleValue tBytes, vBytes deltaBytes isInt bool lastErr error } func (acc *doubleDeltaEncodedIndexAccessor) err() error { return acc.lastErr } func (acc *doubleDeltaEncodedIndexAccessor) timestampAtIndex(idx int) model.Time { if idx == 0 { return acc.baseT } if idx == 1 { // If time bytes are at d8, the time is saved directly rather // than as a difference. if acc.tBytes == d8 { return acc.baseΔT } return acc.baseT + acc.baseΔT } offset := doubleDeltaHeaderBytes + (idx-2)*int(acc.tBytes+acc.vBytes) switch acc.tBytes { case d1: return acc.baseT + model.Time(idx)*acc.baseΔT + model.Time(int8(acc.c[offset])) case d2: return acc.baseT + model.Time(idx)*acc.baseΔT + model.Time(int16(binary.LittleEndian.Uint16(acc.c[offset:]))) case d4: return acc.baseT + model.Time(idx)*acc.baseΔT + model.Time(int32(binary.LittleEndian.Uint32(acc.c[offset:]))) case d8: // Take absolute value for d8. return model.Time(binary.LittleEndian.Uint64(acc.c[offset:])) default: acc.lastErr = fmt.Errorf("invalid number of bytes for time delta: %d", acc.tBytes) return model.Earliest } } func (acc *doubleDeltaEncodedIndexAccessor) sampleValueAtIndex(idx int) model.SampleValue { if idx == 0 { return acc.baseV } if idx == 1 { // If value bytes are at d8, the value is saved directly rather // than as a difference. if acc.vBytes == d8 { return acc.baseΔV } return acc.baseV + acc.baseΔV } offset := doubleDeltaHeaderBytes + (idx-2)*int(acc.tBytes+acc.vBytes) + int(acc.tBytes) if acc.isInt { switch acc.vBytes { case d0: return acc.baseV + model.SampleValue(idx)*acc.baseΔV case d1: return acc.baseV + model.SampleValue(idx)*acc.baseΔV + model.SampleValue(int8(acc.c[offset])) case d2: return acc.baseV + model.SampleValue(idx)*acc.baseΔV + model.SampleValue(int16(binary.LittleEndian.Uint16(acc.c[offset:]))) case d4: return acc.baseV + model.SampleValue(idx)*acc.baseΔV + model.SampleValue(int32(binary.LittleEndian.Uint32(acc.c[offset:]))) // No d8 for ints. default: acc.lastErr = fmt.Errorf("invalid number of bytes for integer delta: %d", acc.vBytes) return 0 } } else { switch acc.vBytes { case d4: return acc.baseV + model.SampleValue(idx)*acc.baseΔV + model.SampleValue(math.Float32frombits(binary.LittleEndian.Uint32(acc.c[offset:]))) case d8: // Take absolute value for d8. return model.SampleValue(math.Float64frombits(binary.LittleEndian.Uint64(acc.c[offset:]))) default: acc.lastErr = fmt.Errorf("invalid number of bytes for floating point delta: %d", acc.vBytes) return 0 } } }