VictoriaMetrics/lib/logstorage/block_data.go
Aliaksandr Valialkin 7bb5f75a2a
lib/logstorage: follow-up for 94627113db
- Move uniqueFields from rows to blockStreamMerger struct.
  This allows localizing all the references to uniqueFields inside blockStreamMerger.mustWriteBlock(),
  which should improve readability and maintainability of the code.

- Remove logging of the event when blocks cannot be merged because they contain more than maxColumnsPerBlock,
  since the provided logging didn't provide the solution for the issue with too many columns.
  I couldn't figure out the proper solution, which could be helpful for end user,
  so decided to remove the logging until we find the solution.

This commit also contains the following additional changes:

- It truncates field names longer than 128 chars during logs ingestion.
  This should prevent from ingesting bogus field names.
  This also should prevent from too big columnsHeader blocks,
  which could negatively affect search query performance,
  since columnsHeader is read on every scan of the corresponding data block.

- It limits the maximum length of const column value to 256.
  Longer values are stored in an ordinary columns.
  This helps limiting the size of columnsHeader blocks
  and improving search query performance by avoiding
  reading too long const columns on every scan of the corresponding data block.

- It deduplicates columns with identical names during data ingestion
  and background merging. Previously it was possible to pass columns with duplicate names
  to block.mustInitFromRows(), and they were stored as is in the block.

Updates https://github.com/VictoriaMetrics/VictoriaMetrics/issues/4762
Updates https://github.com/VictoriaMetrics/VictoriaMetrics/pull/4969
2023-10-02 21:06:49 +02:00

384 lines
12 KiB
Go

package logstorage
import (
"github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/encoding"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/logger"
)
// blockData contains packed data for a single block.
//
// The main purpose of this struct is to reduce the work needed during background merge of parts.
// If the block is full, then the blockData can be written to the destination part
// without the need to unpack it.
type blockData struct {
// streamID is id of the stream for the data
streamID streamID
// uncompressedSizeBytes is the original (uncompressed) size of log entries stored in the block
uncompressedSizeBytes uint64
// rowsCount is the number of log entries in the block
rowsCount uint64
// timestampsData contains the encoded timestamps data for the block
timestampsData timestampsData
// columnsData contains packed per-column data
columnsData []columnData
// constColumns contains data for const columns across the block
constColumns []Field
// a is used for storing byte slices for timestamps and columns.
//
// It reduces fragmentation for them.
a arena
}
// reset resets bd for subsequent re-use
func (bd *blockData) reset() {
bd.streamID.reset()
bd.uncompressedSizeBytes = 0
bd.rowsCount = 0
bd.timestampsData.reset()
cds := bd.columnsData
for i := range cds {
cds[i].reset()
}
bd.columnsData = cds[:0]
ccs := bd.constColumns
for i := range ccs {
ccs[i].Reset()
}
bd.constColumns = ccs[:0]
bd.a.reset()
}
func (bd *blockData) resizeColumnsData(columnsDataLen int) []columnData {
cds := bd.columnsData
if n := columnsDataLen - cap(cds); n > 0 {
cds = append(cds[:cap(cds)], make([]columnData, n)...)
}
cds = cds[:columnsDataLen]
bd.columnsData = cds
return cds
}
// copyFrom copies src to bd.
func (bd *blockData) copyFrom(src *blockData) {
bd.reset()
bd.streamID = src.streamID
bd.uncompressedSizeBytes = src.uncompressedSizeBytes
bd.rowsCount = src.rowsCount
bd.timestampsData.copyFrom(&src.timestampsData, &bd.a)
cdsSrc := src.columnsData
cds := bd.resizeColumnsData(len(cdsSrc))
for i := range cds {
cds[i].copyFrom(&cdsSrc[i], &bd.a)
}
bd.columnsData = cds
bd.constColumns = append(bd.constColumns[:0], src.constColumns...)
}
// unmarshalRows appends unmarshaled from bd log entries to dst.
//
// The returned log entries are valid until sbu and vd are valid.
func (bd *blockData) unmarshalRows(dst *rows, sbu *stringsBlockUnmarshaler, vd *valuesDecoder) error {
b := getBlock()
defer putBlock(b)
if err := b.InitFromBlockData(bd, sbu, vd); err != nil {
return err
}
b.appendRowsTo(dst)
return nil
}
// mustWriteTo writes bd with the given sid to sw and updates bh accordingly
func (bd *blockData) mustWriteTo(bh *blockHeader, sw *streamWriters) {
// Do not store the version used for encoding directly in the block data, since:
// - all the blocks in the same part use the same encoding
// - the block encoding version can be put in metadata file for the part (aka metadataFilename)
bh.reset()
bh.streamID = bd.streamID
bh.uncompressedSizeBytes = bd.uncompressedSizeBytes
bh.rowsCount = bd.rowsCount
// Marshal timestamps
bd.timestampsData.mustWriteTo(&bh.timestampsHeader, sw)
// Marshal columns
cds := bd.columnsData
csh := getColumnsHeader()
chs := csh.resizeColumnHeaders(len(cds))
for i := range cds {
cds[i].mustWriteTo(&chs[i], sw)
}
csh.constColumns = append(csh.constColumns[:0], bd.constColumns...)
bb := longTermBufPool.Get()
bb.B = csh.marshal(bb.B)
putColumnsHeader(csh)
bh.columnsHeaderOffset = sw.columnsHeaderWriter.bytesWritten
bh.columnsHeaderSize = uint64(len(bb.B))
if bh.columnsHeaderSize > maxColumnsHeaderSize {
logger.Panicf("BUG: too big columnsHeaderSize: %d bytes; mustn't exceed %d bytes", bh.columnsHeaderSize, maxColumnsHeaderSize)
}
sw.columnsHeaderWriter.MustWrite(bb.B)
longTermBufPool.Put(bb)
}
// mustReadFrom reads block data associated with bh from sr to bd.
func (bd *blockData) mustReadFrom(bh *blockHeader, sr *streamReaders) {
bd.reset()
bd.streamID = bh.streamID
bd.uncompressedSizeBytes = bh.uncompressedSizeBytes
bd.rowsCount = bh.rowsCount
// Read timestamps
bd.timestampsData.mustReadFrom(&bh.timestampsHeader, sr, &bd.a)
// Read columns
if bh.columnsHeaderOffset != sr.columnsHeaderReader.bytesRead {
logger.Panicf("FATAL: %s: unexpected columnsHeaderOffset=%d; must equal to the number of bytes read: %d",
sr.columnsHeaderReader.Path(), bh.columnsHeaderOffset, sr.columnsHeaderReader.bytesRead)
}
columnsHeaderSize := bh.columnsHeaderSize
if columnsHeaderSize > maxColumnsHeaderSize {
logger.Panicf("BUG: %s: too big columnsHeaderSize: %d bytes; mustn't exceed %d bytes", sr.columnsHeaderReader.Path(), columnsHeaderSize, maxColumnsHeaderSize)
}
bb := longTermBufPool.Get()
bb.B = bytesutil.ResizeNoCopyMayOverallocate(bb.B, int(columnsHeaderSize))
sr.columnsHeaderReader.MustReadFull(bb.B)
csh := getColumnsHeader()
if err := csh.unmarshal(bb.B); err != nil {
logger.Panicf("FATAL: %s: cannot unmarshal columnsHeader: %s", sr.columnsHeaderReader.Path(), err)
}
longTermBufPool.Put(bb)
chs := csh.columnHeaders
cds := bd.resizeColumnsData(len(chs))
for i := range chs {
cds[i].mustReadFrom(&chs[i], sr, &bd.a)
}
bd.constColumns = append(bd.constColumns[:0], csh.constColumns...)
putColumnsHeader(csh)
}
// timestampsData contains the encoded timestamps data.
type timestampsData struct {
// data contains packed timestamps data.
data []byte
// marshalType is the marshal type for timestamps
marshalType encoding.MarshalType
// minTimestamp is the minimum timestamp in the timestamps data
minTimestamp int64
// maxTimestamp is the maximum timestamp in the timestamps data
maxTimestamp int64
}
// reset resets td for subsequent re-use
func (td *timestampsData) reset() {
td.data = nil
td.marshalType = 0
td.minTimestamp = 0
td.maxTimestamp = 0
}
// copyFrom copies src to td.
func (td *timestampsData) copyFrom(src *timestampsData, a *arena) {
td.reset()
td.data = a.copyBytes(src.data)
td.marshalType = src.marshalType
td.minTimestamp = src.minTimestamp
td.maxTimestamp = src.maxTimestamp
}
// mustWriteTo writes td to sw and updates th accordingly
func (td *timestampsData) mustWriteTo(th *timestampsHeader, sw *streamWriters) {
th.reset()
th.marshalType = td.marshalType
th.minTimestamp = td.minTimestamp
th.maxTimestamp = td.maxTimestamp
th.blockOffset = sw.timestampsWriter.bytesWritten
th.blockSize = uint64(len(td.data))
if th.blockSize > maxTimestampsBlockSize {
logger.Panicf("BUG: too big timestampsHeader.blockSize: %d bytes; mustn't exceed %d bytes", th.blockSize, maxTimestampsBlockSize)
}
sw.timestampsWriter.MustWrite(td.data)
}
// mustReadFrom reads timestamps data associated with th from sr to td.
func (td *timestampsData) mustReadFrom(th *timestampsHeader, sr *streamReaders, a *arena) {
td.reset()
td.marshalType = th.marshalType
td.minTimestamp = th.minTimestamp
td.maxTimestamp = th.maxTimestamp
timestampsReader := &sr.timestampsReader
if th.blockOffset != timestampsReader.bytesRead {
logger.Panicf("FATAL: %s: unexpected timestampsHeader.blockOffset=%d; must equal to the number of bytes read: %d",
timestampsReader.Path(), th.blockOffset, timestampsReader.bytesRead)
}
timestampsBlockSize := th.blockSize
if timestampsBlockSize > maxTimestampsBlockSize {
logger.Panicf("FATAL: %s: too big timestamps block with %d bytes; the maximum supported block size is %d bytes",
timestampsReader.Path(), timestampsBlockSize, maxTimestampsBlockSize)
}
td.data = a.newBytes(int(timestampsBlockSize))
timestampsReader.MustReadFull(td.data)
}
// columnData contains packed data for a single column.
type columnData struct {
// name is the column name
name string
// valueType is the type of values stored in valuesData
valueType valueType
// minValue is the minimum encoded uint* or float64 value in the columnHeader
//
// It is used for fast detection of whether the given columnHeader contains values in the given range
minValue uint64
// maxValue is the maximum encoded uint* or float64 value in the columnHeader
//
// It is used for fast detection of whether the given columnHeader contains values in the given range
maxValue uint64
// valuesDict contains unique values for valueType = valueTypeDict
valuesDict valuesDict
// valuesData contains packed values data for the given column
valuesData []byte
// bloomFilterData contains packed bloomFilter data for the given column
bloomFilterData []byte
}
// reset rests cd for subsequent re-use
func (cd *columnData) reset() {
cd.name = ""
cd.valueType = 0
cd.minValue = 0
cd.maxValue = 0
cd.valuesDict.reset()
cd.valuesData = nil
cd.bloomFilterData = nil
}
// copyFrom copies src to cd.
func (cd *columnData) copyFrom(src *columnData, a *arena) {
cd.reset()
cd.name = src.name
cd.valueType = src.valueType
cd.minValue = src.minValue
cd.maxValue = src.maxValue
cd.valuesDict.copyFrom(&src.valuesDict)
cd.valuesData = a.copyBytes(src.valuesData)
cd.bloomFilterData = a.copyBytes(src.bloomFilterData)
}
// mustWriteTo writes cd to sw and updates ch accordingly.
func (cd *columnData) mustWriteTo(ch *columnHeader, sw *streamWriters) {
ch.reset()
valuesWriter := &sw.fieldValuesWriter
bloomFilterWriter := &sw.fieldBloomFilterWriter
if cd.name == "" {
valuesWriter = &sw.messageValuesWriter
bloomFilterWriter = &sw.messageBloomFilterWriter
}
ch.name = cd.name
ch.valueType = cd.valueType
ch.minValue = cd.minValue
ch.maxValue = cd.maxValue
ch.valuesDict.copyFrom(&cd.valuesDict)
// marshal values
ch.valuesSize = uint64(len(cd.valuesData))
if ch.valuesSize > maxValuesBlockSize {
logger.Panicf("BUG: too big valuesSize: %d bytes; mustn't exceed %d bytes", ch.valuesSize, maxValuesBlockSize)
}
ch.valuesOffset = valuesWriter.bytesWritten
valuesWriter.MustWrite(cd.valuesData)
// marshal bloom filter
ch.bloomFilterSize = uint64(len(cd.bloomFilterData))
if ch.bloomFilterSize > maxBloomFilterBlockSize {
logger.Panicf("BUG: too big bloomFilterSize: %d bytes; mustn't exceed %d bytes", ch.bloomFilterSize, maxBloomFilterBlockSize)
}
ch.bloomFilterOffset = bloomFilterWriter.bytesWritten
bloomFilterWriter.MustWrite(cd.bloomFilterData)
}
// mustReadFrom reads columns data associated with ch from sr to cd.
func (cd *columnData) mustReadFrom(ch *columnHeader, sr *streamReaders, a *arena) {
cd.reset()
valuesReader := &sr.fieldValuesReader
bloomFilterReader := &sr.fieldBloomFilterReader
if ch.name == "" {
valuesReader = &sr.messageValuesReader
bloomFilterReader = &sr.messageBloomFilterReader
}
cd.name = ch.name
cd.valueType = ch.valueType
cd.minValue = ch.minValue
cd.maxValue = ch.maxValue
cd.valuesDict.copyFrom(&ch.valuesDict)
// read values
if ch.valuesOffset != valuesReader.bytesRead {
logger.Panicf("FATAL: %s: unexpected columnHeader.valuesOffset=%d; must equal to the number of bytes read: %d",
valuesReader.Path(), ch.valuesOffset, valuesReader.bytesRead)
}
valuesSize := ch.valuesSize
if valuesSize > maxValuesBlockSize {
logger.Panicf("FATAL: %s: values block size cannot exceed %d bytes; got %d bytes", valuesReader.Path(), maxValuesBlockSize, valuesSize)
}
cd.valuesData = a.newBytes(int(valuesSize))
valuesReader.MustReadFull(cd.valuesData)
// read bloom filter
// bloom filter is missing in valueTypeDict.
if ch.valueType != valueTypeDict {
if ch.bloomFilterOffset != bloomFilterReader.bytesRead {
logger.Panicf("FATAL: %s: unexpected columnHeader.bloomFilterOffset=%d; must equal to the number of bytes read: %d",
bloomFilterReader.Path(), ch.bloomFilterOffset, bloomFilterReader.bytesRead)
}
bloomFilterSize := ch.bloomFilterSize
if bloomFilterSize > maxBloomFilterBlockSize {
logger.Panicf("FATAL: %s: bloom filter block size cannot exceed %d bytes; got %d bytes", bloomFilterReader.Path(), maxBloomFilterBlockSize, bloomFilterSize)
}
cd.bloomFilterData = a.newBytes(int(bloomFilterSize))
bloomFilterReader.MustReadFull(cd.bloomFilterData)
}
}