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, }, } } 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 }