frostfs-node/pkg/local_object_storage/shard/gc.go

package shard

import (
	"context"
	"sync"
	"time"

	"github.com/nspcc-dev/neofs-api-go/pkg/object"
	meta "github.com/nspcc-dev/neofs-node/pkg/local_object_storage/metabase"
	"github.com/nspcc-dev/neofs-node/pkg/util"
	"github.com/nspcc-dev/neofs-node/pkg/util/logger"
	"go.uber.org/zap"
)

// Event represents class of external events.
type Event interface {
	typ() eventType
}

type eventType int

const (
	_ eventType = iota
	eventNewEpoch
)

type newEpoch struct {
	epoch uint64
}

func (e newEpoch) typ() eventType {
	return eventNewEpoch
}

// EventNewEpoch returns new epoch event.
func EventNewEpoch(e uint64) Event {
	return newEpoch{
		epoch: e,
	}
}

type eventHandler func(context.Context, Event)

type eventHandlers struct {
	prevGroup sync.WaitGroup

	cancelFunc context.CancelFunc

	handlers []eventHandler
}

type gc struct {
	*gcCfg

	workerPool util.WorkerPool

	remover func()

	mEventHandler map[eventType]*eventHandlers
}

type gcCfg struct {
	eventChanInit func() <-chan Event

	removerInterval time.Duration

	log *logger.Logger

	workerPoolInit func(int) util.WorkerPool
}

func defaultGCCfg() *gcCfg {
	ch := make(chan Event)
	close(ch)

	return &gcCfg{
		eventChanInit: func() <-chan Event {
			return ch
		},
		removerInterval: 10 * time.Second,
		log:             zap.L(),
		workerPoolInit: func(int) util.WorkerPool {
			return nil
		},
	}
}

func (gc *gc) init() {
	sz := 0

	for _, v := range gc.mEventHandler {
		sz += len(v.handlers)
	}

	if sz > 0 {
		gc.workerPool = gc.workerPoolInit(sz)
	}

	go gc.tickRemover()
	go gc.listenEvents()
}

func (gc *gc) listenEvents() {
	eventChan := gc.eventChanInit()

	for {
		event, ok := <-eventChan
		if !ok {
			gc.log.Warn("stop event listener by closed channel")
			return
		}

		v, ok := gc.mEventHandler[event.typ()]
		if !ok {
			continue
		}

		v.cancelFunc()
		v.prevGroup.Wait()

		var ctx context.Context
		ctx, v.cancelFunc = context.WithCancel(context.Background())

		v.prevGroup.Add(len(v.handlers))

		for _, h := range v.handlers {
			err := gc.workerPool.Submit(func() {
				h(ctx, event)
				v.prevGroup.Done()
			})
			if err != nil {
				gc.log.Warn("could not submit GC job to worker pool",
					zap.String("error", err.Error()),
				)

				v.prevGroup.Done()
			}
		}
	}
}

func (gc *gc) tickRemover() {
	timer := time.NewTimer(gc.removerInterval)
	defer timer.Stop()

	for {
		<-timer.C
		gc.remover()
		timer.Reset(gc.removerInterval)
	}
}

// iterates over metabase graveyard and deletes objects
// with GC-marked graves.
func (s *Shard) removeGarbage() {
	buf := make([]*object.Address, 0, s.rmBatchSize)

	// iterate over metabase graveyard and accumulate
	// objects with GC mark
	err := s.metaBase.IterateOverGraveyard(func(g *meta.Grave) error {
		if g.WithGCMark() {
			buf = append(buf, g.Address())
		}

		return nil
	})
	if err != nil {
		s.log.Warn("iterator over metabase graveyard failed",
			zap.String("error", err.Error()),
		)

		return
	} else if len(buf) == 0 {
		return
	}

	// delete accumulated objects
	_, err = s.Delete(new(DeletePrm).
		WithAddresses(buf...),
	)
	if err != nil {
		s.log.Warn("could not delete the objects",
			zap.String("error", err.Error()),
		)

		return
	}
}

func (s *Shard) collectExpiredObjects(ctx context.Context, e Event) {
	epoch := e.(newEpoch).epoch

	var expired []*object.Address

	// collect expired non-tombstone object
	err := s.metaBase.IterateExpired(epoch, func(expiredObject *meta.ExpiredObject) error {
		select {
		case <-ctx.Done():
			return meta.ErrInterruptIterator
		default:
		}

		if expiredObject.Type() != object.TypeTombstone {
			expired = append(expired, expiredObject.Address())
		}

		return nil
	})
	if err != nil {
		s.log.Warn("iterator over expired objects failed",
			zap.String("error", err.Error()),
		)

		return
	} else if len(expired) == 0 {
		return
	}

	// check if context canceled
	select {
	case <-ctx.Done():
		return
	default:
	}

	// inhume the collected objects
	_, err = s.metaBase.Inhume(new(meta.InhumePrm).
		WithAddresses(expired...).
		WithGCMark(),
	)
	if err != nil {
		s.log.Warn("could not inhume the objects",
			zap.String("error", err.Error()),
		)

		return
	}
}
[#378] shard: Implement skeleton of internal GC Shard's GC component consists of: * asynchronous remover that periodically wake up and removes all garbage objects from the shard, and goes to sleep for particular time interval; * external event listener that distributes jobs between workers; * group of workers that can handle a single job related to particular external event. Remover and event listener represents go-routines which are started by `init` method (calls from `Shard.Init`). In initial version all event handlers are interrupted: this means that next event of the same type will interrupt previous handling and start the new one. GC is fully encapsulated in Shard. All GC configurations are reflected in Shard's configuration. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 11:34:48 +00:00			`package shard`

			`import (`
			`"context"`
[#378] shard: Control the completion of all handlers of the previous event Group handlers of the particular event to a WaitGroup and wait for it before the next event handling. This will ensure that all handlers complete and prevent potential conflicts between past and present jobs. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 12:17:37 +00:00			`"sync"`
[#378] shard: Implement skeleton of internal GC Shard's GC component consists of: * asynchronous remover that periodically wake up and removes all garbage objects from the shard, and goes to sleep for particular time interval; * external event listener that distributes jobs between workers; * group of workers that can handle a single job related to particular external event. Remover and event listener represents go-routines which are started by `init` method (calls from `Shard.Init`). In initial version all event handlers are interrupted: this means that next event of the same type will interrupt previous handling and start the new one. GC is fully encapsulated in Shard. All GC configurations are reflected in Shard's configuration. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 11:34:48 +00:00			`"time"`

			`"github.com/nspcc-dev/neofs-api-go/pkg/object"`
			`meta "github.com/nspcc-dev/neofs-node/pkg/local_object_storage/metabase"`
			`"github.com/nspcc-dev/neofs-node/pkg/util"`
			`"github.com/nspcc-dev/neofs-node/pkg/util/logger"`
			`"go.uber.org/zap"`
			`)`

			`// Event represents class of external events.`
			`type Event interface {`
			`typ() eventType`
			`}`

			`type eventType int`

			`const (`
			`_ eventType = iota`
[#378] shard: Define new epoch event Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 17:32:46 +00:00			`eventNewEpoch`
[#378] shard: Implement skeleton of internal GC Shard's GC component consists of: * asynchronous remover that periodically wake up and removes all garbage objects from the shard, and goes to sleep for particular time interval; * external event listener that distributes jobs between workers; * group of workers that can handle a single job related to particular external event. Remover and event listener represents go-routines which are started by `init` method (calls from `Shard.Init`). In initial version all event handlers are interrupted: this means that next event of the same type will interrupt previous handling and start the new one. GC is fully encapsulated in Shard. All GC configurations are reflected in Shard's configuration. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 11:34:48 +00:00			`)`

[#378] shard: Define new epoch event Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 17:32:46 +00:00			`type newEpoch struct {`
			`epoch uint64`
			`}`

			`func (e newEpoch) typ() eventType {`
			`return eventNewEpoch`
			`}`

			`// EventNewEpoch returns new epoch event.`
			`func EventNewEpoch(e uint64) Event {`
			`return newEpoch{`
			`epoch: e,`
			`}`
			`}`

[#378] shard: Implement skeleton of internal GC Shard's GC component consists of: * asynchronous remover that periodically wake up and removes all garbage objects from the shard, and goes to sleep for particular time interval; * external event listener that distributes jobs between workers; * group of workers that can handle a single job related to particular external event. Remover and event listener represents go-routines which are started by `init` method (calls from `Shard.Init`). In initial version all event handlers are interrupted: this means that next event of the same type will interrupt previous handling and start the new one. GC is fully encapsulated in Shard. All GC configurations are reflected in Shard's configuration. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 11:34:48 +00:00			`type eventHandler func(context.Context, Event)`

			`type eventHandlers struct {`
[#378] shard: Control the completion of all handlers of the previous event Group handlers of the particular event to a WaitGroup and wait for it before the next event handling. This will ensure that all handlers complete and prevent potential conflicts between past and present jobs. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 12:17:37 +00:00			`prevGroup sync.WaitGroup`

[#378] shard: Implement skeleton of internal GC Shard's GC component consists of: * asynchronous remover that periodically wake up and removes all garbage objects from the shard, and goes to sleep for particular time interval; * external event listener that distributes jobs between workers; * group of workers that can handle a single job related to particular external event. Remover and event listener represents go-routines which are started by `init` method (calls from `Shard.Init`). In initial version all event handlers are interrupted: this means that next event of the same type will interrupt previous handling and start the new one. GC is fully encapsulated in Shard. All GC configurations are reflected in Shard's configuration. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 11:34:48 +00:00			`cancelFunc context.CancelFunc`

			`handlers []eventHandler`
			`}`

			`type gc struct {`
			`*gcCfg`

			`workerPool util.WorkerPool`

			`remover func()`

			`mEventHandler map[eventType]*eventHandlers`
			`}`

			`type gcCfg struct {`
			`eventChanInit func() <-chan Event`

			`removerInterval time.Duration`

			`log *logger.Logger`

			`workerPoolInit func(int) util.WorkerPool`
			`}`

			`func defaultGCCfg() *gcCfg {`
			`ch := make(chan Event)`
			`close(ch)`

			`return &gcCfg{`
			`eventChanInit: func() <-chan Event {`
			`return ch`
			`},`
			`removerInterval: 10 * time.Second,`
			`log: zap.L(),`
			`workerPoolInit: func(int) util.WorkerPool {`
			`return nil`
			`},`
			`}`
			`}`

			`func (gc *gc) init() {`
			`sz := 0`

			`for _, v := range gc.mEventHandler {`
			`sz += len(v.handlers)`
			`}`

			`if sz > 0 {`
			`gc.workerPool = gc.workerPoolInit(sz)`
			`}`

			`go gc.tickRemover()`
			`go gc.listenEvents()`
			`}`

			`func (gc *gc) listenEvents() {`
			`eventChan := gc.eventChanInit()`

			`for {`
			`event, ok := <-eventChan`
			`if !ok {`
			`gc.log.Warn("stop event listener by closed channel")`
			`return`
			`}`

			`v, ok := gc.mEventHandler[event.typ()]`
			`if !ok {`
			`continue`
			`}`

			`v.cancelFunc()`
[#378] shard: Control the completion of all handlers of the previous event Group handlers of the particular event to a WaitGroup and wait for it before the next event handling. This will ensure that all handlers complete and prevent potential conflicts between past and present jobs. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 12:17:37 +00:00			`v.prevGroup.Wait()`
[#378] shard: Implement skeleton of internal GC Shard's GC component consists of: * asynchronous remover that periodically wake up and removes all garbage objects from the shard, and goes to sleep for particular time interval; * external event listener that distributes jobs between workers; * group of workers that can handle a single job related to particular external event. Remover and event listener represents go-routines which are started by `init` method (calls from `Shard.Init`). In initial version all event handlers are interrupted: this means that next event of the same type will interrupt previous handling and start the new one. GC is fully encapsulated in Shard. All GC configurations are reflected in Shard's configuration. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 11:34:48 +00:00
			`var ctx context.Context`
			`ctx, v.cancelFunc = context.WithCancel(context.Background())`

[#378] shard: Control the completion of all handlers of the previous event Group handlers of the particular event to a WaitGroup and wait for it before the next event handling. This will ensure that all handlers complete and prevent potential conflicts between past and present jobs. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 12:17:37 +00:00			`v.prevGroup.Add(len(v.handlers))`

[#378] shard: Implement skeleton of internal GC Shard's GC component consists of: * asynchronous remover that periodically wake up and removes all garbage objects from the shard, and goes to sleep for particular time interval; * external event listener that distributes jobs between workers; * group of workers that can handle a single job related to particular external event. Remover and event listener represents go-routines which are started by `init` method (calls from `Shard.Init`). In initial version all event handlers are interrupted: this means that next event of the same type will interrupt previous handling and start the new one. GC is fully encapsulated in Shard. All GC configurations are reflected in Shard's configuration. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 11:34:48 +00:00			`for _, h := range v.handlers {`
			`err := gc.workerPool.Submit(func() {`
			`h(ctx, event)`
[#378] shard: Control the completion of all handlers of the previous event Group handlers of the particular event to a WaitGroup and wait for it before the next event handling. This will ensure that all handlers complete and prevent potential conflicts between past and present jobs. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 12:17:37 +00:00			`v.prevGroup.Done()`
[#378] shard: Implement skeleton of internal GC Shard's GC component consists of: * asynchronous remover that periodically wake up and removes all garbage objects from the shard, and goes to sleep for particular time interval; * external event listener that distributes jobs between workers; * group of workers that can handle a single job related to particular external event. Remover and event listener represents go-routines which are started by `init` method (calls from `Shard.Init`). In initial version all event handlers are interrupted: this means that next event of the same type will interrupt previous handling and start the new one. GC is fully encapsulated in Shard. All GC configurations are reflected in Shard's configuration. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 11:34:48 +00:00			`})`
			`if err != nil {`
			`gc.log.Warn("could not submit GC job to worker pool",`
			`zap.String("error", err.Error()),`
			`)`
[#378] shard: Control the completion of all handlers of the previous event Group handlers of the particular event to a WaitGroup and wait for it before the next event handling. This will ensure that all handlers complete and prevent potential conflicts between past and present jobs. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 12:17:37 +00:00
			`v.prevGroup.Done()`
[#378] shard: Implement skeleton of internal GC Shard's GC component consists of: * asynchronous remover that periodically wake up and removes all garbage objects from the shard, and goes to sleep for particular time interval; * external event listener that distributes jobs between workers; * group of workers that can handle a single job related to particular external event. Remover and event listener represents go-routines which are started by `init` method (calls from `Shard.Init`). In initial version all event handlers are interrupted: this means that next event of the same type will interrupt previous handling and start the new one. GC is fully encapsulated in Shard. All GC configurations are reflected in Shard's configuration. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 11:34:48 +00:00			`}`
			`}`
			`}`
			`}`

			`func (gc *gc) tickRemover() {`
			`timer := time.NewTimer(gc.removerInterval)`
			`defer timer.Stop()`

			`for {`
			`<-timer.C`
			`gc.remover()`
			`timer.Reset(gc.removerInterval)`
			`}`
			`}`

			`// iterates over metabase graveyard and deletes objects`
			`// with GC-marked graves.`
			`func (s *Shard) removeGarbage() {`
			`buf := make([]*object.Address, 0, s.rmBatchSize)`

			`// iterate over metabase graveyard and accumulate`
			`// objects with GC mark`
			`err := s.metaBase.IterateOverGraveyard(func(g *meta.Grave) error {`
			`if g.WithGCMark() {`
			`buf = append(buf, g.Address())`
			`}`

			`return nil`
			`})`
			`if err != nil {`
			`s.log.Warn("iterator over metabase graveyard failed",`
			`zap.String("error", err.Error()),`
			`)`

			`return`
			`} else if len(buf) == 0 {`
			`return`
			`}`

			`// delete accumulated objects`
			`_, err = s.Delete(new(DeletePrm).`
			`WithAddresses(buf...),`
			`)`
			`if err != nil {`
			`s.log.Warn("could not delete the objects",`
			`zap.String("error", err.Error()),`
			`)`

			`return`
			`}`
			`}`
[#378] shard: Collect expired non-tombstone objects in GC every epoch Add new epoch event handler to GC that finds all expired non-tombstone objects and marks them to be removed. Signed-off-by: Leonard Lyubich <leonard@nspcc.ru> 2021-02-16 17:34:45 +00:00
			`func (s *Shard) collectExpiredObjects(ctx context.Context, e Event) {`
			`epoch := e.(newEpoch).epoch`

			`var expired []*object.Address`

			`// collect expired non-tombstone object`
			`err := s.metaBase.IterateExpired(epoch, func(expiredObject *meta.ExpiredObject) error {`
			`select {`
			`case <-ctx.Done():`
			`return meta.ErrInterruptIterator`
			`default:`
			`}`

			`if expiredObject.Type() != object.TypeTombstone {`
			`expired = append(expired, expiredObject.Address())`
			`}`

			`return nil`
			`})`
			`if err != nil {`
			`s.log.Warn("iterator over expired objects failed",`
			`zap.String("error", err.Error()),`
			`)`

			`return`
			`} else if len(expired) == 0 {`
			`return`
			`}`

			`// check if context canceled`
			`select {`
			`case <-ctx.Done():`
			`return`
			`default:`
			`}`

			`// inhume the collected objects`
			`_, err = s.metaBase.Inhume(new(meta.InhumePrm).`
			`WithAddresses(expired...).`
			`WithGCMark(),`
			`)`
			`if err != nil {`
			`s.log.Warn("could not inhume the objects",`
			`zap.String("error", err.Error()),`
			`)`

			`return`
			`}`
			`}`