milvus/internal/datacoord/compaction_trigger.go

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// Licensed to the LF AI & Data foundation under one
// or more contributor license agreements. See the NOTICE file
// distributed with this work for additional information
// regarding copyright ownership. The ASF licenses this file
// to you under the Apache License, Version 2.0 (the
// "License"); you may not use this file except in compliance
// with the License. You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package datacoord
import (
"context"
"fmt"
"sort"
"sync"
"time"
"github.com/samber/lo"
"go.uber.org/zap"
"github.com/milvus-io/milvus-proto/go-api/v2/commonpb"
"github.com/milvus-io/milvus-proto/go-api/v2/msgpb"
"github.com/milvus-io/milvus-proto/go-api/v2/schemapb"
"github.com/milvus-io/milvus/internal/metastore/model"
"github.com/milvus-io/milvus/internal/proto/datapb"
"github.com/milvus-io/milvus/pkg/log"
"github.com/milvus-io/milvus/pkg/util/indexparamcheck"
"github.com/milvus-io/milvus/pkg/util/logutil"
"github.com/milvus-io/milvus/pkg/util/paramtable"
"github.com/milvus-io/milvus/pkg/util/tsoutil"
"github.com/milvus-io/milvus/pkg/util/typeutil"
)
type compactTime struct {
expireTime Timestamp
collectionTTL time.Duration
}
type trigger interface {
start()
stop()
// triggerCompaction triggers a compaction if any compaction condition satisfy.
triggerCompaction() error
// triggerSingleCompaction triggers a compaction bundled with collection-partition-channel-segment
triggerSingleCompaction(collectionID, partitionID, segmentID int64, channel string, blockToSendSignal bool) error
// forceTriggerCompaction force to start a compaction
forceTriggerCompaction(collectionID int64) (UniqueID, error)
}
type compactionSignal struct {
id UniqueID
isForce bool
isGlobal bool
collectionID UniqueID
partitionID UniqueID
channel string
segmentID UniqueID
pos *msgpb.MsgPosition
}
var _ trigger = (*compactionTrigger)(nil)
type compactionTrigger struct {
handler Handler
meta *meta
allocator allocator
signals chan *compactionSignal
compactionHandler compactionPlanContext
globalTrigger *time.Ticker
forceMu sync.Mutex
quit chan struct{}
wg sync.WaitGroup
indexEngineVersionManager IndexEngineVersionManager
estimateNonDiskSegmentPolicy calUpperLimitPolicy
estimateDiskSegmentPolicy calUpperLimitPolicy
// A sloopy hack, so we can test with different segment row count without worrying that
// they are re-calculated in every compaction.
testingOnly bool
}
func newCompactionTrigger(
meta *meta,
compactionHandler compactionPlanContext,
allocator allocator,
handler Handler,
indexVersionManager IndexEngineVersionManager,
) *compactionTrigger {
return &compactionTrigger{
meta: meta,
allocator: allocator,
signals: make(chan *compactionSignal, 100),
compactionHandler: compactionHandler,
indexEngineVersionManager: indexVersionManager,
estimateDiskSegmentPolicy: calBySchemaPolicyWithDiskIndex,
estimateNonDiskSegmentPolicy: calBySchemaPolicy,
handler: handler,
}
}
func (t *compactionTrigger) start() {
t.quit = make(chan struct{})
t.globalTrigger = time.NewTicker(Params.DataCoordCfg.GlobalCompactionInterval.GetAsDuration(time.Second))
t.wg.Add(2)
go func() {
defer logutil.LogPanic()
defer t.wg.Done()
for {
select {
case <-t.quit:
log.Info("compaction trigger quit")
return
case signal := <-t.signals:
switch {
case signal.isGlobal:
// ManualCompaction also use use handleGlobalSignal
// so throw err here
err := t.handleGlobalSignal(signal)
if err != nil {
log.Warn("unable to handleGlobalSignal", zap.Error(err))
}
default:
// no need to handle err in handleSignal
t.handleSignal(signal)
// shouldn't reset, otherwise a frequent flushed collection will affect other collections
// t.globalTrigger.Reset(Params.DataCoordCfg.GlobalCompactionInterval)
}
}
}
}()
go t.startGlobalCompactionLoop()
}
func (t *compactionTrigger) startGlobalCompactionLoop() {
defer logutil.LogPanic()
defer t.wg.Done()
// If AutoCompaction disabled, global loop will not start
if !Params.DataCoordCfg.EnableAutoCompaction.GetAsBool() {
return
}
for {
select {
case <-t.quit:
t.globalTrigger.Stop()
log.Info("global compaction loop exit")
return
case <-t.globalTrigger.C:
err := t.triggerCompaction()
if err != nil {
log.Warn("unable to triggerCompaction", zap.Error(err))
}
}
}
}
func (t *compactionTrigger) stop() {
close(t.quit)
t.wg.Wait()
}
func (t *compactionTrigger) allocTs() (Timestamp, error) {
cctx, cancel := context.WithTimeout(context.Background(), 5*time.Second)
defer cancel()
ts, err := t.allocator.allocTimestamp(cctx)
if err != nil {
return 0, err
}
return ts, nil
}
func (t *compactionTrigger) getCollection(collectionID UniqueID) (*collectionInfo, error) {
ctx, cancel := context.WithTimeout(context.Background(), time.Second)
defer cancel()
coll, err := t.handler.GetCollection(ctx, collectionID)
if err != nil {
return nil, fmt.Errorf("collection ID %d not found, err: %w", collectionID, err)
}
return coll, nil
}
func (t *compactionTrigger) isCollectionAutoCompactionEnabled(coll *collectionInfo) bool {
enabled, err := getCollectionAutoCompactionEnabled(coll.Properties)
if err != nil {
log.Warn("collection properties auto compaction not valid, returning false", zap.Error(err))
return false
}
return enabled
}
func (t *compactionTrigger) isChannelCheckpointHealthy(vchanName string) bool {
if paramtable.Get().DataCoordCfg.ChannelCheckpointMaxLag.GetAsInt64() <= 0 {
return true
}
checkpoint := t.meta.GetChannelCheckpoint(vchanName)
if checkpoint == nil {
log.Warn("channel checkpoint not found", zap.String("channel", vchanName))
return false
}
cpTime := tsoutil.PhysicalTime(checkpoint.GetTimestamp())
return time.Since(cpTime) < paramtable.Get().DataCoordCfg.ChannelCheckpointMaxLag.GetAsDuration(time.Second)
}
func (t *compactionTrigger) getCompactTime(ts Timestamp, coll *collectionInfo) (*compactTime, error) {
collectionTTL, err := getCollectionTTL(coll.Properties)
if err != nil {
return nil, err
}
pts, _ := tsoutil.ParseTS(ts)
if collectionTTL > 0 {
ttexpired := pts.Add(-collectionTTL)
ttexpiredLogic := tsoutil.ComposeTS(ttexpired.UnixNano()/int64(time.Millisecond), 0)
return &compactTime{ttexpiredLogic, collectionTTL}, nil
}
// no expiration time
return &compactTime{0, 0}, nil
}
// triggerCompaction trigger a compaction if any compaction condition satisfy.
func (t *compactionTrigger) triggerCompaction() error {
id, err := t.allocSignalID()
if err != nil {
return err
}
signal := &compactionSignal{
id: id,
isForce: false,
isGlobal: true,
}
t.signals <- signal
return nil
}
// triggerSingleCompaction triger a compaction bundled with collection-partition-channel-segment
func (t *compactionTrigger) triggerSingleCompaction(collectionID, partitionID, segmentID int64, channel string, blockToSendSignal bool) error {
// If AutoCompaction disabled, flush request will not trigger compaction
if !Params.DataCoordCfg.EnableAutoCompaction.GetAsBool() {
return nil
}
id, err := t.allocSignalID()
if err != nil {
return err
}
signal := &compactionSignal{
id: id,
isForce: false,
isGlobal: false,
collectionID: collectionID,
partitionID: partitionID,
segmentID: segmentID,
channel: channel,
}
if blockToSendSignal {
t.signals <- signal
return nil
}
select {
case t.signals <- signal:
default:
log.Info("no space to send compaction signal", zap.Int64("collectionID", collectionID), zap.Int64("segmentID", segmentID), zap.String("channel", channel))
}
return nil
}
// forceTriggerCompaction force to start a compaction
// invoked by user `ManualCompaction` operation
func (t *compactionTrigger) forceTriggerCompaction(collectionID int64) (UniqueID, error) {
id, err := t.allocSignalID()
if err != nil {
return -1, err
}
signal := &compactionSignal{
id: id,
isForce: true,
isGlobal: true,
collectionID: collectionID,
}
err = t.handleGlobalSignal(signal)
if err != nil {
log.Warn("unable to handleGlobalSignal", zap.Error(err))
return -1, err
}
return id, nil
}
func (t *compactionTrigger) allocSignalID() (UniqueID, error) {
ctx, cancel := context.WithTimeout(context.Background(), 5*time.Second)
defer cancel()
return t.allocator.allocID(ctx)
}
func (t *compactionTrigger) getExpectedSegmentSize(collectionID int64) int64 {
indexInfos := t.meta.indexMeta.GetIndexesForCollection(collectionID, "")
ctx, cancel := context.WithTimeout(context.Background(), time.Second)
defer cancel()
collMeta, err := t.handler.GetCollection(ctx, collectionID)
if err != nil {
log.Warn("failed to get collection", zap.Int64("collectionID", collectionID), zap.Error(err))
return Params.DataCoordCfg.SegmentMaxSize.GetAsInt64() * 1024 * 1024
}
vectorFields := typeutil.GetVectorFieldSchemas(collMeta.Schema)
fieldIndexTypes := lo.SliceToMap(indexInfos, func(t *model.Index) (int64, indexparamcheck.IndexType) {
return t.FieldID, GetIndexType(t.IndexParams)
})
vectorFieldsWithDiskIndex := lo.Filter(vectorFields, func(field *schemapb.FieldSchema, _ int) bool {
if indexType, ok := fieldIndexTypes[field.FieldID]; ok {
return indexparamcheck.IsDiskIndex(indexType)
}
return false
})
allDiskIndex := len(vectorFields) == len(vectorFieldsWithDiskIndex)
if allDiskIndex {
// Only if all vector fields index type are DiskANN, recalc segment max size here.
return Params.DataCoordCfg.DiskSegmentMaxSize.GetAsInt64() * 1024 * 1024
}
// If some vector fields index type are not DiskANN, recalc segment max size using default policy.
return Params.DataCoordCfg.SegmentMaxSize.GetAsInt64() * 1024 * 1024
}
func (t *compactionTrigger) handleGlobalSignal(signal *compactionSignal) error {
t.forceMu.Lock()
defer t.forceMu.Unlock()
log := log.With(zap.Int64("compactionID", signal.id),
zap.Int64("signal.collectionID", signal.collectionID),
zap.Int64("signal.partitionID", signal.partitionID),
zap.Int64("signal.segmentID", signal.segmentID))
m := t.meta.GetSegmentsChanPart(func(segment *SegmentInfo) bool {
return (signal.collectionID == 0 || segment.CollectionID == signal.collectionID) &&
isSegmentHealthy(segment) &&
isFlush(segment) &&
!segment.isCompacting && // not compacting now
!segment.GetIsImporting() && // not importing now
segment.GetLevel() != datapb.SegmentLevel_L0 // ignore level zero segments
}) // m is list of chanPartSegments, which is channel-partition organized segments
if len(m) == 0 {
log.Info("the length of SegmentsChanPart is 0, skip to handle compaction")
return nil
}
ts, err := t.allocTs()
if err != nil {
log.Warn("allocate ts failed, skip to handle compaction")
return err
}
channelCheckpointOK := make(map[string]bool)
isChannelCPOK := func(channelName string) bool {
cached, ok := channelCheckpointOK[channelName]
if ok {
return cached
}
return t.isChannelCheckpointHealthy(channelName)
}
for _, group := range m {
log := log.With(zap.Int64("collectionID", group.collectionID),
zap.Int64("partitionID", group.partitionID),
zap.String("channel", group.channelName))
if !signal.isForce && t.compactionHandler.isFull() {
log.Warn("compaction plan skipped due to handler full")
break
}
if !isChannelCPOK(group.channelName) && !signal.isForce {
log.Warn("compaction plan skipped due to channel checkpoint lag", zap.String("channel", signal.channel))
continue
}
if Params.DataCoordCfg.IndexBasedCompaction.GetAsBool() {
group.segments = FilterInIndexedSegments(t.handler, t.meta, group.segments...)
}
coll, err := t.getCollection(group.collectionID)
if err != nil {
log.Warn("get collection info failed, skip handling compaction", zap.Error(err))
return err
}
if !signal.isForce && !t.isCollectionAutoCompactionEnabled(coll) {
log.RatedInfo(20, "collection auto compaction disabled",
zap.Int64("collectionID", group.collectionID),
)
return nil
}
ct, err := t.getCompactTime(ts, coll)
if err != nil {
log.Warn("get compact time failed, skip to handle compaction",
zap.Int64("collectionID", group.collectionID),
zap.Int64("partitionID", group.partitionID),
zap.String("channel", group.channelName))
return err
}
plans := t.generatePlans(group.segments, signal.isForce, ct)
for _, plan := range plans {
segIDs := fetchSegIDs(plan.GetSegmentBinlogs())
if !signal.isForce && t.compactionHandler.isFull() {
log.Warn("compaction plan skipped due to handler full",
zap.Int64("collectionID", signal.collectionID),
zap.Int64s("segmentIDs", segIDs))
break
}
start := time.Now()
if err := fillOriginPlan(t.allocator, plan); err != nil {
log.Warn("failed to fill plan",
zap.Int64("collectionID", signal.collectionID),
zap.Int64s("segmentIDs", segIDs),
zap.Error(err))
continue
}
err := t.compactionHandler.execCompactionPlan(signal, plan)
if err != nil {
log.Warn("failed to execute compaction plan",
zap.Int64("collectionID", signal.collectionID),
zap.Int64("planID", plan.PlanID),
zap.Int64s("segmentIDs", segIDs),
zap.Error(err))
continue
}
log.Info("time cost of generating global compaction",
zap.Int64("planID", plan.PlanID),
zap.Int64("time cost", time.Since(start).Milliseconds()),
zap.Int64("collectionID", signal.collectionID),
zap.String("channel", group.channelName),
zap.Int64("partitionID", group.partitionID),
zap.Int64s("segmentIDs", segIDs))
}
}
return nil
}
// handleSignal processes segment flush caused partition-chan level compaction signal
func (t *compactionTrigger) handleSignal(signal *compactionSignal) {
t.forceMu.Lock()
defer t.forceMu.Unlock()
// 1. check whether segment's binlogs should be compacted or not
if t.compactionHandler.isFull() {
log.Warn("compaction plan skipped due to handler full")
return
}
if !t.isChannelCheckpointHealthy(signal.channel) {
log.Warn("compaction plan skipped due to channel checkpoint lag", zap.String("channel", signal.channel))
return
}
segment := t.meta.GetHealthySegment(signal.segmentID)
if segment == nil {
log.Warn("segment in compaction signal not found in meta", zap.Int64("segmentID", signal.segmentID))
return
}
channel := segment.GetInsertChannel()
partitionID := segment.GetPartitionID()
collectionID := segment.GetCollectionID()
segments := t.getCandidateSegments(channel, partitionID)
if len(segments) == 0 {
log.Info("the number of candidate segments is 0, skip to handle compaction")
return
}
ts, err := t.allocTs()
if err != nil {
log.Warn("allocate ts failed, skip to handle compaction", zap.Int64("collectionID", signal.collectionID),
zap.Int64("partitionID", signal.partitionID), zap.Int64("segmentID", signal.segmentID))
return
}
coll, err := t.getCollection(collectionID)
if err != nil {
log.Warn("get collection info failed, skip handling compaction",
zap.Int64("collectionID", collectionID),
zap.Int64("partitionID", partitionID),
zap.String("channel", channel),
zap.Error(err),
)
return
}
if !signal.isForce && !t.isCollectionAutoCompactionEnabled(coll) {
log.RatedInfo(20, "collection auto compaction disabled",
zap.Int64("collectionID", collectionID),
)
return
}
ct, err := t.getCompactTime(ts, coll)
if err != nil {
log.Warn("get compact time failed, skip to handle compaction", zap.Int64("collectionID", segment.GetCollectionID()),
zap.Int64("partitionID", partitionID), zap.String("channel", channel))
return
}
plans := t.generatePlans(segments, signal.isForce, ct)
for _, plan := range plans {
if t.compactionHandler.isFull() {
log.Warn("compaction plan skipped due to handler full", zap.Int64("collection", signal.collectionID), zap.Int64("planID", plan.PlanID))
break
}
start := time.Now()
if err := fillOriginPlan(t.allocator, plan); err != nil {
log.Warn("failed to fill plan", zap.Error(err))
continue
}
if err := t.compactionHandler.execCompactionPlan(signal, plan); err != nil {
log.Warn("failed to execute compaction plan",
zap.Int64("collection", signal.collectionID),
zap.Int64("planID", plan.PlanID),
zap.Int64s("segmentIDs", fetchSegIDs(plan.GetSegmentBinlogs())),
zap.Error(err))
continue
}
log.Info("time cost of generating compaction",
zap.Int64("planID", plan.PlanID),
zap.Int64("time cost", time.Since(start).Milliseconds()),
zap.Int64("collectionID", signal.collectionID),
zap.String("channel", channel),
zap.Int64("partitionID", partitionID),
zap.Int64s("segmentIDs", fetchSegIDs(plan.GetSegmentBinlogs())))
}
}
func (t *compactionTrigger) generatePlans(segments []*SegmentInfo, force bool, compactTime *compactTime) []*datapb.CompactionPlan {
if len(segments) == 0 {
log.Warn("the number of candidate segments is 0, skip to generate compaction plan")
return []*datapb.CompactionPlan{}
}
// find segments need internal compaction
// TODO add low priority candidates, for example if the segment is smaller than full 0.9 * max segment size but larger than small segment boundary, we only execute compaction when there are no compaction running actively
var prioritizedCandidates []*SegmentInfo
var smallCandidates []*SegmentInfo
var nonPlannedSegments []*SegmentInfo
expectedSize := t.getExpectedSegmentSize(segments[0].CollectionID)
// TODO, currently we lack of the measurement of data distribution, there should be another compaction help on redistributing segment based on scalar/vector field distribution
for _, segment := range segments {
segment := segment.ShadowClone()
// TODO should we trigger compaction periodically even if the segment has no obvious reason to be compacted?
if force || t.ShouldDoSingleCompaction(segment, compactTime) {
prioritizedCandidates = append(prioritizedCandidates, segment)
} else if t.isSmallSegment(segment, expectedSize) {
smallCandidates = append(smallCandidates, segment)
} else {
nonPlannedSegments = append(nonPlannedSegments, segment)
}
}
buckets := [][]*SegmentInfo{}
// sort segment from large to small
sort.Slice(prioritizedCandidates, func(i, j int) bool {
if prioritizedCandidates[i].getSegmentSize() != prioritizedCandidates[j].getSegmentSize() {
return prioritizedCandidates[i].getSegmentSize() > prioritizedCandidates[j].getSegmentSize()
}
return prioritizedCandidates[i].GetID() < prioritizedCandidates[j].GetID()
})
sort.Slice(smallCandidates, func(i, j int) bool {
if smallCandidates[i].getSegmentSize() != smallCandidates[j].getSegmentSize() {
return smallCandidates[i].getSegmentSize() > smallCandidates[j].getSegmentSize()
}
return smallCandidates[i].GetID() < smallCandidates[j].GetID()
})
// Sort non-planned from small to large.
sort.Slice(nonPlannedSegments, func(i, j int) bool {
if nonPlannedSegments[i].getSegmentSize() != nonPlannedSegments[j].getSegmentSize() {
return nonPlannedSegments[i].getSegmentSize() < nonPlannedSegments[j].getSegmentSize()
}
return nonPlannedSegments[i].GetID() > nonPlannedSegments[j].GetID()
})
// greedy pick from large segment to small, the goal is to fill each segment to reach 512M
// we must ensure all prioritized candidates is in a plan
// TODO the compaction selection policy should consider if compaction workload is high
for len(prioritizedCandidates) > 0 {
var bucket []*SegmentInfo
// pop out the first element
segment := prioritizedCandidates[0]
bucket = append(bucket, segment)
prioritizedCandidates = prioritizedCandidates[1:]
// only do single file compaction if segment is already large enough
if segment.getSegmentSize() < expectedSize {
var result []*SegmentInfo
free := expectedSize - segment.getSegmentSize()
maxNum := Params.DataCoordCfg.MaxSegmentToMerge.GetAsInt() - 1
prioritizedCandidates, result, free = greedySelect(prioritizedCandidates, free, maxNum)
bucket = append(bucket, result...)
maxNum -= len(result)
if maxNum > 0 {
smallCandidates, result, _ = greedySelect(smallCandidates, free, maxNum)
bucket = append(bucket, result...)
}
}
// since this is priority compaction, we will execute even if there is only segment
log.Info("pick priority candidate for compaction",
zap.Int64("prioritized segmentID", segment.GetID()),
zap.Int64s("picked segmentIDs", lo.Map(bucket, func(s *SegmentInfo, _ int) int64 { return s.GetID() })),
zap.Int64("target size", lo.SumBy(bucket, func(s *SegmentInfo) int64 { return s.getSegmentSize() })),
zap.Int64("target count", lo.SumBy(bucket, func(s *SegmentInfo) int64 { return s.GetNumOfRows() })),
)
buckets = append(buckets, bucket)
}
var remainingSmallSegs []*SegmentInfo
// check if there are small candidates left can be merged into large segments
for len(smallCandidates) > 0 {
var bucket []*SegmentInfo
// pop out the first element
segment := smallCandidates[0]
bucket = append(bucket, segment)
smallCandidates = smallCandidates[1:]
var result []*SegmentInfo
free := expectedSize - segment.getSegmentSize()
// for small segment merge, we pick one largest segment and merge as much as small segment together with it
// Why reverse? try to merge as many segments as expected.
// for instance, if a 255M and 255M is the largest small candidates, they will never be merged because of the MinSegmentToMerge limit.
smallCandidates, result, _ = reverseGreedySelect(smallCandidates, free, Params.DataCoordCfg.MaxSegmentToMerge.GetAsInt()-1)
bucket = append(bucket, result...)
// only merge if candidate number is large than MinSegmentToMerge or if target size is large enough
targetSize := lo.SumBy(bucket, func(s *SegmentInfo) int64 { return s.getSegmentSize() })
if len(bucket) >= Params.DataCoordCfg.MinSegmentToMerge.GetAsInt() ||
len(bucket) > 1 && t.isCompactableSegment(targetSize, expectedSize) {
buckets = append(buckets, bucket)
} else {
remainingSmallSegs = append(remainingSmallSegs, bucket...)
}
}
remainingSmallSegs = t.squeezeSmallSegmentsToBuckets(remainingSmallSegs, buckets, expectedSize)
// If there are still remaining small segments, try adding them to non-planned segments.
for _, npSeg := range nonPlannedSegments {
bucket := []*SegmentInfo{npSeg}
targetSize := npSeg.getSegmentSize()
for i := len(remainingSmallSegs) - 1; i >= 0; i-- {
// Note: could also simply use MaxRowNum as limit.
if targetSize+remainingSmallSegs[i].getSegmentSize() <=
int64(Params.DataCoordCfg.SegmentExpansionRate.GetAsFloat()*float64(expectedSize)) {
bucket = append(bucket, remainingSmallSegs[i])
targetSize += remainingSmallSegs[i].getSegmentSize()
remainingSmallSegs = append(remainingSmallSegs[:i], remainingSmallSegs[i+1:]...)
}
}
if len(bucket) > 1 {
buckets = append(buckets, bucket)
}
}
plans := make([]*datapb.CompactionPlan, len(buckets))
for i, b := range buckets {
plans[i] = segmentsToPlan(b, compactTime)
}
return plans
}
func segmentsToPlan(segments []*SegmentInfo, compactTime *compactTime) *datapb.CompactionPlan {
plan := &datapb.CompactionPlan{
Type: datapb.CompactionType_MixCompaction,
Channel: segments[0].GetInsertChannel(),
CollectionTtl: compactTime.collectionTTL.Nanoseconds(),
}
var size int64
for _, s := range segments {
segmentBinlogs := &datapb.CompactionSegmentBinlogs{
SegmentID: s.GetID(),
FieldBinlogs: s.GetBinlogs(),
Field2StatslogPaths: s.GetStatslogs(),
Deltalogs: s.GetDeltalogs(),
CollectionID: s.GetCollectionID(),
PartitionID: s.GetPartitionID(),
}
plan.TotalRows += s.GetNumOfRows()
size += s.getSegmentSize()
plan.SegmentBinlogs = append(plan.SegmentBinlogs, segmentBinlogs)
}
log.Info("generate a plan for priority candidates", zap.Any("plan", plan),
zap.Int64("target segment row", plan.TotalRows), zap.Int64("target segment size", size))
return plan
}
func greedySelect(candidates []*SegmentInfo, free int64, maxSegment int) ([]*SegmentInfo, []*SegmentInfo, int64) {
var result []*SegmentInfo
for i := 0; i < len(candidates); {
candidate := candidates[i]
if len(result) < maxSegment && candidate.getSegmentSize() < free {
result = append(result, candidate)
free -= candidate.getSegmentSize()
candidates = append(candidates[:i], candidates[i+1:]...)
} else {
i++
}
}
return candidates, result, free
}
func reverseGreedySelect(candidates []*SegmentInfo, free int64, maxSegment int) ([]*SegmentInfo, []*SegmentInfo, int64) {
var result []*SegmentInfo
for i := len(candidates) - 1; i >= 0; i-- {
candidate := candidates[i]
if (len(result) < maxSegment) && (candidate.getSegmentSize() < free) {
result = append(result, candidate)
free -= candidate.getSegmentSize()
candidates = append(candidates[:i], candidates[i+1:]...)
}
}
return candidates, result, free
}
func (t *compactionTrigger) getCandidateSegments(channel string, partitionID UniqueID) []*SegmentInfo {
segments := t.meta.GetSegmentsByChannel(channel)
if Params.DataCoordCfg.IndexBasedCompaction.GetAsBool() {
segments = FilterInIndexedSegments(t.handler, t.meta, segments...)
}
var res []*SegmentInfo
for _, s := range segments {
if !isSegmentHealthy(s) ||
!isFlush(s) ||
s.GetInsertChannel() != channel ||
s.GetPartitionID() != partitionID ||
s.isCompacting ||
s.GetIsImporting() ||
s.GetLevel() == datapb.SegmentLevel_L0 {
continue
}
res = append(res, s)
}
return res
}
func (t *compactionTrigger) isSmallSegment(segment *SegmentInfo, expectedSize int64) bool {
return segment.getSegmentSize() < int64(float64(expectedSize)*Params.DataCoordCfg.SegmentSmallProportion.GetAsFloat())
}
func (t *compactionTrigger) isCompactableSegment(targetSize, expectedSize int64) bool {
smallProportion := Params.DataCoordCfg.SegmentSmallProportion.GetAsFloat()
compactableProportion := Params.DataCoordCfg.SegmentCompactableProportion.GetAsFloat()
// avoid invalid single segment compaction
if compactableProportion < smallProportion {
compactableProportion = smallProportion
}
return targetSize > int64(float64(expectedSize)*compactableProportion)
}
func isExpandableSmallSegment(segment *SegmentInfo, expectedSize int64) bool {
return segment.getSegmentSize() < int64(float64(expectedSize)*(Params.DataCoordCfg.SegmentExpansionRate.GetAsFloat()-1))
}
func (t *compactionTrigger) ShouldDoSingleCompaction(segment *SegmentInfo, compactTime *compactTime) bool {
// no longer restricted binlog numbers because this is now related to field numbers
binlogCount := GetBinlogCount(segment.GetBinlogs())
deltaLogCount := GetBinlogCount(segment.GetDeltalogs())
if deltaLogCount > Params.DataCoordCfg.SingleCompactionDeltalogMaxNum.GetAsInt() {
log.Info("total delta number is too much, trigger compaction", zap.Int64("segmentID", segment.ID), zap.Int("Bin logs", binlogCount), zap.Int("Delta logs", deltaLogCount))
return true
}
// if expire time is enabled, put segment into compaction candidate
totalExpiredSize := int64(0)
totalExpiredRows := 0
for _, binlogs := range segment.GetBinlogs() {
for _, l := range binlogs.GetBinlogs() {
// TODO, we should probably estimate expired log entries by total rows in binlog and the ralationship of timeTo, timeFrom and expire time
if l.TimestampTo < compactTime.expireTime {
log.RatedDebug(10, "mark binlog as expired",
zap.Int64("segmentID", segment.ID),
zap.Int64("binlogID", l.GetLogID()),
zap.Uint64("binlogTimestampTo", l.TimestampTo),
zap.Uint64("compactExpireTime", compactTime.expireTime))
totalExpiredRows += int(l.GetEntriesNum())
totalExpiredSize += l.GetMemorySize()
}
}
}
if float64(totalExpiredRows)/float64(segment.GetNumOfRows()) >= Params.DataCoordCfg.SingleCompactionRatioThreshold.GetAsFloat() ||
totalExpiredSize > Params.DataCoordCfg.SingleCompactionExpiredLogMaxSize.GetAsInt64() {
log.Info("total expired entities is too much, trigger compaction", zap.Int64("segmentID", segment.ID),
zap.Int("expiredRows", totalExpiredRows), zap.Int64("expiredLogSize", totalExpiredSize),
zap.Bool("createdByCompaction", segment.CreatedByCompaction), zap.Int64s("compactionFrom", segment.CompactionFrom))
return true
}
totalDeletedRows := 0
totalDeleteLogSize := int64(0)
for _, deltaLogs := range segment.GetDeltalogs() {
for _, l := range deltaLogs.GetBinlogs() {
totalDeletedRows += int(l.GetEntriesNum())
totalDeleteLogSize += l.GetMemorySize()
}
}
// currently delta log size and delete ratio policy is applied
if float64(totalDeletedRows)/float64(segment.GetNumOfRows()) >= Params.DataCoordCfg.SingleCompactionRatioThreshold.GetAsFloat() || totalDeleteLogSize > Params.DataCoordCfg.SingleCompactionDeltaLogMaxSize.GetAsInt64() {
log.Info("total delete entities is too much, trigger compaction",
zap.Int64("segmentID", segment.ID),
zap.Int64("numRows", segment.GetNumOfRows()),
zap.Int("deleted rows", totalDeletedRows),
zap.Int64("delete log size", totalDeleteLogSize))
return true
}
if Params.DataCoordCfg.AutoUpgradeSegmentIndex.GetAsBool() {
// index version of segment lower than current version and IndexFileKeys should have value, trigger compaction
indexIDToSegIdxes := t.meta.indexMeta.GetSegmentIndexes(segment.CollectionID, segment.ID)
for _, index := range indexIDToSegIdxes {
if index.CurrentIndexVersion < t.indexEngineVersionManager.GetCurrentIndexEngineVersion() &&
len(index.IndexFileKeys) > 0 {
log.Info("index version is too old, trigger compaction",
zap.Int64("segmentID", segment.ID),
zap.Int64("indexID", index.IndexID),
zap.Strings("indexFileKeys", index.IndexFileKeys),
zap.Int32("currentIndexVersion", index.CurrentIndexVersion),
zap.Int32("currentEngineVersion", t.indexEngineVersionManager.GetCurrentIndexEngineVersion()))
return true
}
}
}
return false
}
func isFlush(segment *SegmentInfo) bool {
return segment.GetState() == commonpb.SegmentState_Flushed || segment.GetState() == commonpb.SegmentState_Flushing
}
func fetchSegIDs(segBinLogs []*datapb.CompactionSegmentBinlogs) []int64 {
var segIDs []int64
for _, segBinLog := range segBinLogs {
segIDs = append(segIDs, segBinLog.GetSegmentID())
}
return segIDs
}
// buckets will be updated inplace
func (t *compactionTrigger) squeezeSmallSegmentsToBuckets(small []*SegmentInfo, buckets [][]*SegmentInfo, expectedSize int64) (remaining []*SegmentInfo) {
for i := len(small) - 1; i >= 0; i-- {
s := small[i]
if !isExpandableSmallSegment(s, expectedSize) {
continue
}
// Try squeeze this segment into existing plans. This could cause segment size to exceed maxSize.
for bidx, b := range buckets {
totalSize := lo.SumBy(b, func(s *SegmentInfo) int64 { return s.getSegmentSize() })
if totalSize+s.getSegmentSize() > int64(Params.DataCoordCfg.SegmentExpansionRate.GetAsFloat()*float64(expectedSize)) {
continue
}
buckets[bidx] = append(buckets[bidx], s)
small = append(small[:i], small[i+1:]...)
break
}
}
return small
}