func chunksEqual(c1, c2 chunk.Chunk) bool {
it1 := c1.NewIterator()
it2 := c2.NewIterator()
for it1.Scan() && it2.Scan() {
if !(it1.Value() == it2.Value()) {
return false
}
}
return it1.Err() == nil && it2.Err() == nil
}
func writeChunkHeader(header []byte, c chunk.Chunk) error {
header[chunkHeaderTypeOffset] = byte(c.Encoding())
binary.LittleEndian.PutUint64(
header[chunkHeaderFirstTimeOffset:],
uint64(c.FirstTime()),
)
lt, err := c.NewIterator().LastTimestamp()
if err != nil {
return err
}
binary.LittleEndian.PutUint64(
header[chunkHeaderLastTimeOffset:],
uint64(lt),
)
return nil
}
// scan works like bufio.Scanner.Scan.
func (hs *headsScanner) scan() bool {
if hs.seriesCurrent == hs.seriesTotal || hs.err != nil {
return false
}
var (
seriesFlags byte
fpAsInt uint64
metric codable.Metric
persistWatermark int64
modTimeNano int64
modTime time.Time
chunkDescsOffset int64
savedFirstTime int64
numChunkDescs int64
firstTime int64
lastTime int64
encoding byte
ch chunk.Chunk
lastTimeHead model.Time
)
if seriesFlags, hs.err = hs.r.ReadByte(); hs.err != nil {
return false
}
headChunkPersisted := seriesFlags&flagHeadChunkPersisted != 0
if fpAsInt, hs.err = codable.DecodeUint64(hs.r); hs.err != nil {
return false
}
hs.fp = model.Fingerprint(fpAsInt)
if hs.err = metric.UnmarshalFromReader(hs.r); hs.err != nil {
return false
}
if hs.version != headsFormatLegacyVersion {
// persistWatermark only present in v2.
persistWatermark, hs.err = binary.ReadVarint(hs.r)
if hs.err != nil {
return false
}
modTimeNano, hs.err = binary.ReadVarint(hs.r)
if hs.err != nil {
return false
}
if modTimeNano != -1 {
modTime = time.Unix(0, modTimeNano)
}
}
if chunkDescsOffset, hs.err = binary.ReadVarint(hs.r); hs.err != nil {
return false
}
if savedFirstTime, hs.err = binary.ReadVarint(hs.r); hs.err != nil {
return false
}
if numChunkDescs, hs.err = binary.ReadVarint(hs.r); hs.err != nil {
return false
}
chunkDescs := make([]*chunk.Desc, numChunkDescs)
if hs.version == headsFormatLegacyVersion {
if headChunkPersisted {
persistWatermark = numChunkDescs
} else {
persistWatermark = numChunkDescs - 1
}
}
headChunkClosed := true // Initial assumption.
for i := int64(0); i < numChunkDescs; i++ {
if i < persistWatermark {
if firstTime, hs.err = binary.ReadVarint(hs.r); hs.err != nil {
return false
}
if lastTime, hs.err = binary.ReadVarint(hs.r); hs.err != nil {
return false
}
chunkDescs[i] = &chunk.Desc{
ChunkFirstTime: model.Time(firstTime),
ChunkLastTime: model.Time(lastTime),
}
chunk.NumMemDescs.Inc()
} else {
// Non-persisted chunk.
// If there are non-persisted chunks at all, we consider
// the head chunk not to be closed yet.
headChunkClosed = false
if encoding, hs.err = hs.r.ReadByte(); hs.err != nil {
return false
}
if ch, hs.err = chunk.NewForEncoding(chunk.Encoding(encoding)); hs.err != nil {
return false
}
if hs.err = ch.Unmarshal(hs.r); hs.err != nil {
return false
}
cd := chunk.NewDesc(ch, ch.FirstTime())
if i < numChunkDescs-1 {
// This is NOT the head chunk. So it's a chunk
// to be persisted, and we need to populate lastTime.
hs.chunksToPersistTotal++
cd.MaybePopulateLastTime()
}
chunkDescs[i] = cd
}
}
if lastTimeHead, hs.err = chunkDescs[len(chunkDescs)-1].LastTime(); hs.err != nil {
return false
}
hs.series = &memorySeries{
metric: model.Metric(metric),
chunkDescs: chunkDescs,
persistWatermark: int(persistWatermark),
modTime: modTime,
chunkDescsOffset: int(chunkDescsOffset),
savedFirstTime: model.Time(savedFirstTime),
lastTime: lastTimeHead,
headChunkClosed: headChunkClosed,
}
hs.seriesCurrent++
return true
}