VictoriaMetrics/lib/logstorage/pipe_top.go
Aliaksandr Valialkin 246c339e3d
lib/logstorage: read timestamps column when it is really needed during query execution
Previously timestamps column was read unconditionally on every query.
This could significantly slow down queries, which do not need reading this column
like in https://github.com/VictoriaMetrics/VictoriaMetrics/issues/7070 .
2024-09-25 19:18:37 +02:00

504 lines
11 KiB
Go

package logstorage
import (
"fmt"
"slices"
"sort"
"strings"
"sync/atomic"
"unsafe"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/encoding"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/logger"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/memory"
)
// pipeTopDefaultLimit is the default number of entries pipeTop returns.
const pipeTopDefaultLimit = 10
// pipeTop processes '| top ...' queries.
//
// See https://docs.victoriametrics.com/victorialogs/logsql/#top-pipe
type pipeTop struct {
// fields contains field names for returning top values for.
byFields []string
// limit is the number of top (byFields) sets to return.
limit uint64
// limitStr is string representation of the limit.
limitStr string
// if hitsFieldName isn't empty, then the number of hits per each unique value is returned in this field.
hitsFieldName string
}
func (pt *pipeTop) String() string {
s := "top"
if pt.limit != pipeTopDefaultLimit {
s += " " + pt.limitStr
}
if len(pt.byFields) > 0 {
s += " by (" + fieldNamesString(pt.byFields) + ")"
}
return s
}
func (pt *pipeTop) canLiveTail() bool {
return false
}
func (pt *pipeTop) updateNeededFields(neededFields, unneededFields fieldsSet) {
neededFields.reset()
unneededFields.reset()
if len(pt.byFields) == 0 {
neededFields.add("*")
} else {
neededFields.addFields(pt.byFields)
}
}
func (pt *pipeTop) optimize() {
// nothing to do
}
func (pt *pipeTop) hasFilterInWithQuery() bool {
return false
}
func (pt *pipeTop) initFilterInValues(_ map[string][]string, _ getFieldValuesFunc) (pipe, error) {
return pt, nil
}
func (pt *pipeTop) newPipeProcessor(workersCount int, stopCh <-chan struct{}, cancel func(), ppNext pipeProcessor) pipeProcessor {
maxStateSize := int64(float64(memory.Allowed()) * 0.2)
shards := make([]pipeTopProcessorShard, workersCount)
for i := range shards {
shards[i] = pipeTopProcessorShard{
pipeTopProcessorShardNopad: pipeTopProcessorShardNopad{
pt: pt,
stateSizeBudget: stateSizeBudgetChunk,
},
}
maxStateSize -= stateSizeBudgetChunk
}
ptp := &pipeTopProcessor{
pt: pt,
stopCh: stopCh,
cancel: cancel,
ppNext: ppNext,
shards: shards,
maxStateSize: maxStateSize,
}
ptp.stateSizeBudget.Store(maxStateSize)
return ptp
}
type pipeTopProcessor struct {
pt *pipeTop
stopCh <-chan struct{}
cancel func()
ppNext pipeProcessor
shards []pipeTopProcessorShard
maxStateSize int64
stateSizeBudget atomic.Int64
}
type pipeTopProcessorShard struct {
pipeTopProcessorShardNopad
// The padding prevents false sharing on widespread platforms with 128 mod (cache line size) = 0 .
_ [128 - unsafe.Sizeof(pipeTopProcessorShardNopad{})%128]byte
}
type pipeTopProcessorShardNopad struct {
// pt points to the parent pipeTop.
pt *pipeTop
// m holds per-row hits.
m map[string]*uint64
// keyBuf is a temporary buffer for building keys for m.
keyBuf []byte
// columnValues is a temporary buffer for the processed column values.
columnValues [][]string
// stateSizeBudget is the remaining budget for the whole state size for the shard.
// The per-shard budget is provided in chunks from the parent pipeTopProcessor.
stateSizeBudget int
}
// writeBlock writes br to shard.
func (shard *pipeTopProcessorShard) writeBlock(br *blockResult) {
byFields := shard.pt.byFields
if len(byFields) == 0 {
// Take into account all the columns in br.
keyBuf := shard.keyBuf
cs := br.getColumns()
for i := 0; i < br.rowsLen; i++ {
keyBuf = keyBuf[:0]
for _, c := range cs {
v := c.getValueAtRow(br, i)
keyBuf = encoding.MarshalBytes(keyBuf, bytesutil.ToUnsafeBytes(c.name))
keyBuf = encoding.MarshalBytes(keyBuf, bytesutil.ToUnsafeBytes(v))
}
shard.updateState(bytesutil.ToUnsafeString(keyBuf), 1)
}
shard.keyBuf = keyBuf
return
}
if len(byFields) == 1 {
// Fast path for a single field.
c := br.getColumnByName(byFields[0])
if c.isConst {
v := c.valuesEncoded[0]
shard.updateState(v, uint64(br.rowsLen))
return
}
if c.valueType == valueTypeDict {
a := encoding.GetUint64s(len(c.dictValues))
hits := a.A
valuesEncoded := c.getValuesEncoded(br)
for _, v := range valuesEncoded {
idx := unmarshalUint8(v)
hits[idx]++
}
for i, v := range c.dictValues {
shard.updateState(v, hits[i])
}
encoding.PutUint64s(a)
return
}
values := c.getValues(br)
for _, v := range values {
shard.updateState(v, 1)
}
return
}
// Take into account only the selected columns.
columnValues := shard.columnValues[:0]
for _, f := range byFields {
c := br.getColumnByName(f)
values := c.getValues(br)
columnValues = append(columnValues, values)
}
shard.columnValues = columnValues
keyBuf := shard.keyBuf
for i := 0; i < br.rowsLen; i++ {
keyBuf = keyBuf[:0]
for _, values := range columnValues {
keyBuf = encoding.MarshalBytes(keyBuf, bytesutil.ToUnsafeBytes(values[i]))
}
shard.updateState(bytesutil.ToUnsafeString(keyBuf), 1)
}
shard.keyBuf = keyBuf
}
func (shard *pipeTopProcessorShard) updateState(v string, hits uint64) {
m := shard.getM()
pHits, ok := m[v]
if !ok {
vCopy := strings.Clone(v)
hits := uint64(0)
pHits = &hits
m[vCopy] = pHits
shard.stateSizeBudget -= len(vCopy) + int(unsafe.Sizeof(vCopy)+unsafe.Sizeof(hits)+unsafe.Sizeof(pHits))
}
*pHits += hits
}
func (shard *pipeTopProcessorShard) getM() map[string]*uint64 {
if shard.m == nil {
shard.m = make(map[string]*uint64)
}
return shard.m
}
func (ptp *pipeTopProcessor) writeBlock(workerID uint, br *blockResult) {
if br.rowsLen == 0 {
return
}
shard := &ptp.shards[workerID]
for shard.stateSizeBudget < 0 {
// steal some budget for the state size from the global budget.
remaining := ptp.stateSizeBudget.Add(-stateSizeBudgetChunk)
if remaining < 0 {
// The state size is too big. Stop processing data in order to avoid OOM crash.
if remaining+stateSizeBudgetChunk >= 0 {
// Notify worker goroutines to stop calling writeBlock() in order to save CPU time.
ptp.cancel()
}
return
}
shard.stateSizeBudget += stateSizeBudgetChunk
}
shard.writeBlock(br)
}
func (ptp *pipeTopProcessor) flush() error {
if n := ptp.stateSizeBudget.Load(); n <= 0 {
return fmt.Errorf("cannot calculate [%s], since it requires more than %dMB of memory", ptp.pt.String(), ptp.maxStateSize/(1<<20))
}
// merge state across shards
shards := ptp.shards
m := shards[0].getM()
shards = shards[1:]
for i := range shards {
if needStop(ptp.stopCh) {
return nil
}
for k, pHitsSrc := range shards[i].getM() {
pHits, ok := m[k]
if !ok {
m[k] = pHitsSrc
} else {
*pHits += *pHitsSrc
}
}
}
// select top entries with the biggest number of hits
entries := make([]pipeTopEntry, 0, len(m))
for k, pHits := range m {
entries = append(entries, pipeTopEntry{
k: k,
hits: *pHits,
})
}
sort.Slice(entries, func(i, j int) bool {
a, b := &entries[i], &entries[j]
if a.hits == b.hits {
return a.k < b.k
}
return a.hits > b.hits
})
if uint64(len(entries)) > ptp.pt.limit {
entries = entries[:ptp.pt.limit]
}
// write result
wctx := &pipeTopWriteContext{
ptp: ptp,
}
byFields := ptp.pt.byFields
var rowFields []Field
addHitsField := func(dst []Field, hits uint64) []Field {
hitsStr := string(marshalUint64String(nil, hits))
dst = append(dst, Field{
Name: ptp.pt.hitsFieldName,
Value: hitsStr,
})
return dst
}
if len(byFields) == 0 {
for _, e := range entries {
if needStop(ptp.stopCh) {
return nil
}
rowFields = rowFields[:0]
keyBuf := bytesutil.ToUnsafeBytes(e.k)
for len(keyBuf) > 0 {
name, nSize := encoding.UnmarshalBytes(keyBuf)
if nSize <= 0 {
logger.Panicf("BUG: cannot unmarshal field name")
}
keyBuf = keyBuf[nSize:]
value, nSize := encoding.UnmarshalBytes(keyBuf)
if nSize <= 0 {
logger.Panicf("BUG: cannot unmarshal field value")
}
keyBuf = keyBuf[nSize:]
rowFields = append(rowFields, Field{
Name: bytesutil.ToUnsafeString(name),
Value: bytesutil.ToUnsafeString(value),
})
}
rowFields = addHitsField(rowFields, e.hits)
wctx.writeRow(rowFields)
}
} else if len(byFields) == 1 {
fieldName := byFields[0]
for _, e := range entries {
if needStop(ptp.stopCh) {
return nil
}
rowFields = append(rowFields[:0], Field{
Name: fieldName,
Value: e.k,
})
rowFields = addHitsField(rowFields, e.hits)
wctx.writeRow(rowFields)
}
} else {
for _, e := range entries {
if needStop(ptp.stopCh) {
return nil
}
rowFields = rowFields[:0]
keyBuf := bytesutil.ToUnsafeBytes(e.k)
fieldIdx := 0
for len(keyBuf) > 0 {
value, nSize := encoding.UnmarshalBytes(keyBuf)
if nSize <= 0 {
logger.Panicf("BUG: cannot unmarshal field value")
}
keyBuf = keyBuf[nSize:]
rowFields = append(rowFields, Field{
Name: byFields[fieldIdx],
Value: bytesutil.ToUnsafeString(value),
})
fieldIdx++
}
rowFields = addHitsField(rowFields, e.hits)
wctx.writeRow(rowFields)
}
}
wctx.flush()
return nil
}
type pipeTopEntry struct {
k string
hits uint64
}
type pipeTopWriteContext struct {
ptp *pipeTopProcessor
rcs []resultColumn
br blockResult
// rowsCount is the number of rows in the current block
rowsCount int
// valuesLen is the total length of values in the current block
valuesLen int
}
func (wctx *pipeTopWriteContext) writeRow(rowFields []Field) {
rcs := wctx.rcs
areEqualColumns := len(rcs) == len(rowFields)
if areEqualColumns {
for i, f := range rowFields {
if rcs[i].name != f.Name {
areEqualColumns = false
break
}
}
}
if !areEqualColumns {
// send the current block to ppNext and construct a block with new set of columns
wctx.flush()
rcs = wctx.rcs[:0]
for _, f := range rowFields {
rcs = appendResultColumnWithName(rcs, f.Name)
}
wctx.rcs = rcs
}
for i, f := range rowFields {
v := f.Value
rcs[i].addValue(v)
wctx.valuesLen += len(v)
}
wctx.rowsCount++
if wctx.valuesLen >= 1_000_000 {
wctx.flush()
}
}
func (wctx *pipeTopWriteContext) flush() {
rcs := wctx.rcs
br := &wctx.br
wctx.valuesLen = 0
// Flush rcs to ppNext
br.setResultColumns(rcs, wctx.rowsCount)
wctx.rowsCount = 0
wctx.ptp.ppNext.writeBlock(0, br)
br.reset()
for i := range rcs {
rcs[i].resetValues()
}
}
func parsePipeTop(lex *lexer) (*pipeTop, error) {
if !lex.isKeyword("top") {
return nil, fmt.Errorf("expecting 'top'; got %q", lex.token)
}
lex.nextToken()
limit := uint64(pipeTopDefaultLimit)
limitStr := ""
if isNumberPrefix(lex.token) {
limitF, s, err := parseNumber(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse N in 'top': %w", err)
}
if limitF < 1 {
return nil, fmt.Errorf("N in 'top %s' must be integer bigger than 0", s)
}
limit = uint64(limitF)
limitStr = s
}
var byFields []string
if lex.isKeyword("by", "(") {
if lex.isKeyword("by") {
lex.nextToken()
}
bfs, err := parseFieldNamesInParens(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse 'by' clause in 'top': %w", err)
}
if slices.Contains(bfs, "*") {
bfs = nil
}
byFields = bfs
}
hitsFieldName := "hits"
for slices.Contains(byFields, hitsFieldName) {
hitsFieldName += "s"
}
pt := &pipeTop{
byFields: byFields,
limit: limit,
limitStr: limitStr,
hitsFieldName: hitsFieldName,
}
return pt, nil
}