VictoriaMetrics/lib/storage/block.go

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package storage
import (
"fmt"
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"sync"
"sync/atomic"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/decimal"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/encoding"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/logger"
)
const (
// The maximum number of rows per block.
maxRowsPerBlock = 8 * 1024
// The maximum size of values in the block.
maxBlockSize = 8 * maxRowsPerBlock
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)
// Block represents a block of time series values for a single TSID.
type Block struct {
bh blockHeader
// nextIdx is the next index for reading timestamps and values.
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nextIdx int
timestamps []int64
values []int64
// Marshaled representation of block header.
headerData []byte
// Marshaled representation of timestamps.
timestampsData []byte
// Marshaled representation of values.
valuesData []byte
}
// Reset resets b.
func (b *Block) Reset() {
b.bh = blockHeader{}
b.nextIdx = 0
b.timestamps = b.timestamps[:0]
b.values = b.values[:0]
b.headerData = b.headerData[:0]
b.timestampsData = b.timestampsData[:0]
b.valuesData = b.valuesData[:0]
}
// CopyFrom copies src to b.
func (b *Block) CopyFrom(src *Block) {
b.bh = src.bh
b.nextIdx = 0
b.timestamps = append(b.timestamps[:0], src.timestamps[src.nextIdx:]...)
b.values = append(b.values[:0], src.values[src.nextIdx:]...)
b.headerData = append(b.headerData[:0], src.headerData...)
b.timestampsData = append(b.timestampsData[:0], src.timestampsData...)
b.valuesData = append(b.valuesData[:0], src.valuesData...)
}
func getBlock() *Block {
v := blockPool.Get()
if v == nil {
return &Block{}
}
return v.(*Block)
}
func putBlock(b *Block) {
b.Reset()
blockPool.Put(b)
}
var blockPool sync.Pool
func (b *Block) fixupTimestamps() {
b.bh.MinTimestamp = b.timestamps[b.nextIdx]
b.bh.MaxTimestamp = b.timestamps[len(b.timestamps)-1]
}
// RowsCount returns the number of rows in the block.
func (b *Block) RowsCount() int {
return int(b.bh.RowsCount)
}
// Init initializes b with the given tsid, timestamps, values and scale.
func (b *Block) Init(tsid *TSID, timestamps, values []int64, scale int16, precisionBits uint8) {
b.Reset()
b.bh.TSID = *tsid
b.bh.Scale = scale
b.bh.PrecisionBits = precisionBits
b.timestamps = append(b.timestamps[:0], timestamps...)
b.values = append(b.values[:0], values...)
}
// nextRow advances to the next row.
//
// Returns false if there are no more rows in the block.
func (b *Block) nextRow() bool {
if b.nextIdx == len(b.values) {
return false
}
b.nextIdx++
return true
}
// assertUnmarshaled makes sure the block is unmarshaled.
func (b *Block) assertUnmarshaled() {
if len(b.valuesData) > 0 {
logger.Panicf("BUG: valuesData must be empty; got %d bytes", len(b.valuesData))
}
if len(b.timestampsData) > 0 {
logger.Panicf("BUG: timestampsData must be empty; got %d bytes", len(b.timestampsData))
}
if len(b.values) != len(b.timestamps) {
logger.Panicf("BUG: the number of values must match the number of timestamps; got %d vs %d", len(b.values), len(b.timestamps))
}
if b.nextIdx > len(b.values) {
logger.Panicf("BUG: nextIdx cannot exceed the number of values; got %d vs %d", b.nextIdx, len(b.values))
}
}
// assertMergeable makes sure b and ib are mergeable, i.e. they have the same
// tsid and scale.
func (b *Block) assertMergeable(ib *Block) {
if b.bh.TSID.MetricID != ib.bh.TSID.MetricID {
logger.Panicf("BUG: unequal TSID: %q vs %q", &b.bh.TSID, &ib.bh.TSID)
}
if b.bh.Scale != ib.bh.Scale {
logger.Panicf("BUG: unequal Scale: %d vs %d", b.bh.Scale, ib.bh.Scale)
}
}
// tooBig returns true if the block is too big to be extended.
func (b *Block) tooBig() bool {
if b.bh.RowsCount >= maxRowsPerBlock || len(b.values[b.nextIdx:]) >= maxRowsPerBlock {
return true
}
if len(b.valuesData) >= maxBlockSize {
return true
}
return false
}
func (b *Block) deduplicateSamplesDuringMerge() {
if !isDedupEnabled() {
// Deduplication is disabled
return
}
// Unmarshal block if it isn't unmarshaled yet in order to apply the de-duplication to unmarshaled samples.
if err := b.UnmarshalData(); err != nil {
logger.Panicf("FATAL: cannot unmarshal block: %s", err)
}
srcTimestamps := b.timestamps[b.nextIdx:]
if len(srcTimestamps) < 2 {
// Nothing to dedup.
return
}
dedupInterval := GetDedupInterval()
if dedupInterval <= 0 {
// Deduplication is disabled.
return
}
srcValues := b.values[b.nextIdx:]
timestamps, values := deduplicateSamplesDuringMerge(srcTimestamps, srcValues, dedupInterval)
dedups := len(srcTimestamps) - len(timestamps)
atomic.AddUint64(&dedupsDuringMerge, uint64(dedups))
b.timestamps = b.timestamps[:b.nextIdx+len(timestamps)]
b.values = b.values[:b.nextIdx+len(values)]
}
var dedupsDuringMerge uint64
func (b *Block) rowsCount() int {
if len(b.values) == 0 {
return int(b.bh.RowsCount)
}
return len(b.values[b.nextIdx:])
}
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// MarshalData marshals the block into binary representation.
func (b *Block) MarshalData(timestampsBlockOffset, valuesBlockOffset uint64) ([]byte, []byte, []byte) {
if len(b.values) == 0 {
// The data has been already marshaled.
// b.valuesData and b.timestampsData may be empty for certain
// b.bh.*MarshalType values, so don't check them.
if b.nextIdx != 0 {
logger.Panicf("BUG: nextIdx must be zero; got %d", b.nextIdx)
}
if int(b.bh.TimestampsBlockSize) != len(b.timestampsData) {
logger.Panicf("BUG: invalid TimestampsBlockSize; got %d; expecting %d", b.bh.TimestampsBlockSize, len(b.timestampsData))
}
if int(b.bh.ValuesBlockSize) != len(b.valuesData) {
logger.Panicf("BUG: invalid ValuesBlockSize; got %d; expecting %d", b.bh.ValuesBlockSize, len(b.valuesData))
}
if b.bh.RowsCount <= 0 {
logger.Panicf("BUG: RowsCount must be greater than 0; got %d", b.bh.RowsCount)
}
// headerData must be always recreated, since it contains timestampsBlockOffset and valuesBlockOffset.
b.bh.TimestampsBlockOffset = timestampsBlockOffset
b.bh.ValuesBlockOffset = valuesBlockOffset
b.headerData = b.bh.Marshal(b.headerData[:0])
return b.headerData, b.timestampsData, b.valuesData
}
if b.nextIdx > len(b.values) {
logger.Panicf("BUG: nextIdx cannot exceed values size; got %d vs %d", b.nextIdx, len(b.values))
}
timestamps := b.timestamps[b.nextIdx:]
values := b.values[b.nextIdx:]
if len(values) == 0 {
logger.Panicf("BUG: values cannot be empty; nextIdx=%d, timestampsBlockOffset=%d, valuesBlockOffset=%d", b.nextIdx, timestampsBlockOffset, valuesBlockOffset)
}
if len(values) != len(timestamps) {
logger.Panicf("BUG: the number of values must match the number of timestamps; got %d vs %d", len(values), len(timestamps))
}
b.valuesData, b.bh.ValuesMarshalType, b.bh.FirstValue = encoding.MarshalValues(b.valuesData[:0], values, b.bh.PrecisionBits)
b.bh.ValuesBlockOffset = valuesBlockOffset
b.bh.ValuesBlockSize = uint32(len(b.valuesData))
b.values = b.values[:0]
b.timestampsData, b.bh.TimestampsMarshalType, b.bh.MinTimestamp = encoding.MarshalTimestamps(b.timestampsData[:0], timestamps, b.bh.PrecisionBits)
b.bh.TimestampsBlockOffset = timestampsBlockOffset
b.bh.TimestampsBlockSize = uint32(len(b.timestampsData))
b.bh.MaxTimestamp = timestamps[len(timestamps)-1]
b.timestamps = b.timestamps[:0]
b.bh.RowsCount = uint32(len(values))
b.headerData = b.bh.Marshal(b.headerData[:0])
b.nextIdx = 0
return b.headerData, b.timestampsData, b.valuesData
}
// UnmarshalData unmarshals block data.
func (b *Block) UnmarshalData() error {
// blockHeader (b.bh) must be already unmarshaled.
if len(b.values) > 0 {
// The data has been already unmarshaled.
if len(b.valuesData) > 0 {
logger.Panicf("BUG: valuesData must be empty; contains %d bytes", len(b.valuesData))
}
if len(b.timestampsData) > 0 {
logger.Panicf("BUG: timestampsData must be empty; contains %d bytes", len(b.timestampsData))
}
return nil
}
if b.bh.RowsCount <= 0 {
return fmt.Errorf("RowsCount must be greater than 0; got %d", b.bh.RowsCount)
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}
var err error
b.timestamps, err = encoding.UnmarshalTimestamps(b.timestamps[:0], b.timestampsData, b.bh.TimestampsMarshalType, b.bh.MinTimestamp, int(b.bh.RowsCount))
if err != nil {
return err
}
if b.bh.PrecisionBits < 64 {
// Recover timestamps order after lossy compression.
encoding.EnsureNonDecreasingSequence(b.timestamps, b.bh.MinTimestamp, b.bh.MaxTimestamp)
} else if b.bh.TimestampsMarshalType.NeedsValidation() {
// Ensure timestamps are in the range [MinTimestamp ... MaxTimestamps] and are ordered.
if err := checkTimestampsBounds(b.timestamps, b.bh.MinTimestamp, b.bh.MaxTimestamp); err != nil {
return err
}
}
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b.timestampsData = b.timestampsData[:0]
b.values, err = encoding.UnmarshalValues(b.values[:0], b.valuesData, b.bh.ValuesMarshalType, b.bh.FirstValue, int(b.bh.RowsCount))
if err != nil {
return err
}
b.valuesData = b.valuesData[:0]
if len(b.timestamps) != len(b.values) {
return fmt.Errorf("timestamps and values count mismatch; got %d vs %d", len(b.timestamps), len(b.values))
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}
b.nextIdx = 0
return nil
}
func checkTimestampsBounds(timestamps []int64, minTimestamp, maxTimestamp int64) error {
if len(timestamps) == 0 {
return nil
}
tsPrev := timestamps[0]
if tsPrev < minTimestamp {
return fmt.Errorf("timestamp for the row 0 out of %d rows cannot be smaller than %d; got %d", len(timestamps), minTimestamp, tsPrev)
}
for i, ts := range timestamps[1:] {
if ts < tsPrev {
return fmt.Errorf("timestamp for the row %d cannot be smaller than the timestamp for the row %d (total %d rows); got %d vs %d",
i+1, i, len(timestamps), ts, tsPrev)
}
tsPrev = ts
}
if tsPrev > maxTimestamp {
return fmt.Errorf("timestamp for the row %d (the last one) cannot be bigger than %d; got %d", len(timestamps)-1, maxTimestamp, tsPrev)
}
return nil
}
// AppendRowsWithTimeRangeFilter filters samples from b according to tr and appends them to dst*.
//
// It is expected that UnmarshalData has been already called on b.
func (b *Block) AppendRowsWithTimeRangeFilter(dstTimestamps []int64, dstValues []float64, tr TimeRange) ([]int64, []float64) {
timestamps, values := b.filterTimestamps(tr)
dstTimestamps = append(dstTimestamps, timestamps...)
dstValues = decimal.AppendDecimalToFloat(dstValues, values, b.bh.Scale)
return dstTimestamps, dstValues
}
func (b *Block) filterTimestamps(tr TimeRange) ([]int64, []int64) {
timestamps := b.timestamps
// Skip timestamps smaller than tr.MinTimestamp.
i := 0
for i < len(timestamps) && timestamps[i] < tr.MinTimestamp {
i++
}
// Skip timestamps bigger than tr.MaxTimestamp.
j := len(timestamps)
for j > i && timestamps[j-1] > tr.MaxTimestamp {
j--
}
if i == j {
return nil, nil
}
return timestamps[i:j], b.values[i:j]
}
// MarshalPortable marshals b to dst, so it could be portably migrated to other VictoriaMetrics instance.
//
// The marshaled value must be unmarshaled with UnmarshalPortable function.
func (b *Block) MarshalPortable(dst []byte) []byte {
b.MarshalData(0, 0)
dst = b.bh.marshalPortable(dst)
dst = encoding.MarshalBytes(dst, b.timestampsData)
dst = encoding.MarshalBytes(dst, b.valuesData)
return dst
}
// UnmarshalPortable unmarshals block from src to b and returns the remaining tail.
//
// It is assumed that the block has been marshaled with MarshalPortable.
func (b *Block) UnmarshalPortable(src []byte) ([]byte, error) {
b.Reset()
src, err := b.bh.unmarshalPortable(src)
if err != nil {
return src, err
}
src, timestampsData, err := encoding.UnmarshalBytes(src)
if err != nil {
return src, fmt.Errorf("cannot read timestampsData: %w", err)
}
b.timestampsData = append(b.timestampsData[:0], timestampsData...)
src, valuesData, err := encoding.UnmarshalBytes(src)
if err != nil {
return src, fmt.Errorf("cannot read valuesData: %w", err)
}
b.valuesData = append(b.valuesData[:0], valuesData...)
if err := b.bh.validate(); err != nil {
return src, fmt.Errorf("invalid blockHeader: %w", err)
}
if err := b.UnmarshalData(); err != nil {
return src, fmt.Errorf("invalid data: %w", err)
}
return src, nil
}