frostfs-node/pkg/local_object_storage/metabase/delete.go

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package meta
import (
"bytes"
"context"
"errors"
"fmt"
"time"
"git.frostfs.info/TrueCloudLab/frostfs-node/pkg/core/object"
storagelog "git.frostfs.info/TrueCloudLab/frostfs-node/pkg/local_object_storage/internal/log"
"git.frostfs.info/TrueCloudLab/frostfs-node/pkg/local_object_storage/internal/metaerr"
"git.frostfs.info/TrueCloudLab/frostfs-observability/tracing"
"git.frostfs.info/TrueCloudLab/frostfs-sdk-go/client"
cid "git.frostfs.info/TrueCloudLab/frostfs-sdk-go/container/id"
objectSDK "git.frostfs.info/TrueCloudLab/frostfs-sdk-go/object"
oid "git.frostfs.info/TrueCloudLab/frostfs-sdk-go/object/id"
"go.etcd.io/bbolt"
"go.opentelemetry.io/otel/attribute"
"go.opentelemetry.io/otel/trace"
)
var errFailedToRemoveUniqueIndexes = errors.New("can't remove unique indexes")
// DeletePrm groups the parameters of Delete operation.
type DeletePrm struct {
addrs []oid.Address
}
// DeleteRes groups the resulting values of Delete operation.
type DeleteRes struct {
phyCount uint64
logicCount uint64
userCount uint64
phySize uint64
logicSize uint64
removedByCnrID map[cid.ID]ObjectCounters
}
// LogicCount returns the number of removed logic
// objects.
func (d DeleteRes) LogicCount() uint64 {
return d.logicCount
}
func (d DeleteRes) UserCount() uint64 {
return d.userCount
}
// RemovedByCnrID returns the number of removed objects by container ID.
func (d DeleteRes) RemovedByCnrID() map[cid.ID]ObjectCounters {
return d.removedByCnrID
}
// PhyCount returns the number of removed physical objects.
func (d DeleteRes) PhyCount() uint64 {
return d.phyCount
}
// PhySize returns the size of removed physical objects.
func (d DeleteRes) PhySize() uint64 {
return d.phySize
}
// LogicSize returns the size of removed logical objects.
func (d DeleteRes) LogicSize() uint64 {
return d.logicSize
}
// SetAddresses is a Delete option to set the addresses of the objects to delete.
//
// Option is required.
func (p *DeletePrm) SetAddresses(addrs ...oid.Address) {
p.addrs = addrs
}
type referenceNumber struct {
all, cur int
obj *objectSDK.Object
}
type referenceCounter map[string]*referenceNumber
// Delete removed object records from metabase indexes.
func (db *DB) Delete(ctx context.Context, prm DeletePrm) (DeleteRes, error) {
var (
startedAt = time.Now()
deleted = false
)
defer func() {
db.metrics.AddMethodDuration("Delete", time.Since(startedAt), deleted)
}()
_, span := tracing.StartSpanFromContext(ctx, "metabase.Delete",
trace.WithAttributes(
attribute.Int("addr_count", len(prm.addrs)),
))
defer span.End()
db.modeMtx.RLock()
defer db.modeMtx.RUnlock()
if db.mode.NoMetabase() {
return DeleteRes{}, ErrDegradedMode
} else if db.mode.ReadOnly() {
return DeleteRes{}, ErrReadOnlyMode
}
var err error
var res DeleteRes
err = db.boltDB.Batch(func(tx *bbolt.Tx) error {
res, err = db.deleteGroup(tx, prm.addrs)
return err
})
if err == nil {
deleted = true
for i := range prm.addrs {
storagelog.Write(ctx, db.log,
storagelog.AddressField(prm.addrs[i]),
storagelog.OpField("metabase DELETE"))
}
}
return res, metaerr.Wrap(err)
}
// deleteGroup deletes object from the metabase. Handles removal of the
// references of the split objects.
func (db *DB) deleteGroup(tx *bbolt.Tx, addrs []oid.Address) (DeleteRes, error) {
res := DeleteRes{
removedByCnrID: make(map[cid.ID]ObjectCounters),
}
refCounter := make(referenceCounter, len(addrs))
currEpoch := db.epochState.CurrentEpoch()
for i := range addrs {
r, err := db.delete(tx, addrs[i], refCounter, currEpoch)
if err != nil {
return DeleteRes{}, err
}
applyDeleteSingleResult(r, &res, addrs, i)
}
if err := db.updateCountersDelete(tx, res); err != nil {
return DeleteRes{}, err
}
for _, refNum := range refCounter {
if refNum.cur == refNum.all {
err := db.deleteObject(tx, refNum.obj, true)
if err != nil {
return DeleteRes{}, err
}
}
}
return res, nil
}
func (db *DB) updateCountersDelete(tx *bbolt.Tx, res DeleteRes) error {
if res.phyCount > 0 {
err := db.updateShardObjectCounter(tx, phy, res.phyCount, false)
if err != nil {
return fmt.Errorf("could not decrease phy object counter: %w", err)
}
}
if res.logicCount > 0 {
err := db.updateShardObjectCounter(tx, logical, res.logicCount, false)
if err != nil {
return fmt.Errorf("could not decrease logical object counter: %w", err)
}
}
if res.userCount > 0 {
err := db.updateShardObjectCounter(tx, user, res.userCount, false)
if err != nil {
return fmt.Errorf("could not decrease user object counter: %w", err)
}
}
if err := db.updateContainerCounter(tx, res.removedByCnrID, false); err != nil {
return fmt.Errorf("could not decrease container object counter: %w", err)
}
return nil
}
func applyDeleteSingleResult(r deleteSingleResult, res *DeleteRes, addrs []oid.Address, i int) {
if r.Phy {
if v, ok := res.removedByCnrID[addrs[i].Container()]; ok {
v.Phy++
res.removedByCnrID[addrs[i].Container()] = v
} else {
res.removedByCnrID[addrs[i].Container()] = ObjectCounters{
Phy: 1,
}
}
res.phyCount++
res.phySize += r.Size
}
if r.Logic {
if v, ok := res.removedByCnrID[addrs[i].Container()]; ok {
v.Logic++
res.removedByCnrID[addrs[i].Container()] = v
} else {
res.removedByCnrID[addrs[i].Container()] = ObjectCounters{
Logic: 1,
}
}
res.logicCount++
res.logicSize += r.Size
}
if r.User {
if v, ok := res.removedByCnrID[addrs[i].Container()]; ok {
v.User++
res.removedByCnrID[addrs[i].Container()] = v
} else {
res.removedByCnrID[addrs[i].Container()] = ObjectCounters{
User: 1,
}
}
res.userCount++
}
}
type deleteSingleResult struct {
Phy bool
Logic bool
User bool
Size uint64
}
// delete removes object indexes from the metabase. Counts the references
// of the object that is being removed.
// The first return value indicates if an object has been removed. (removing a
// non-exist object is error-free). The second return value indicates if an
// object was available before the removal (for calculating the logical object
// counter). The third return value The fourth return value is removed object payload size.
func (db *DB) delete(tx *bbolt.Tx, addr oid.Address, refCounter referenceCounter, currEpoch uint64) (deleteSingleResult, error) {
key := make([]byte, addressKeySize)
addrKey := addressKey(addr, key)
garbageBKT := tx.Bucket(garbageBucketName)
graveyardBKT := tx.Bucket(graveyardBucketName)
removeAvailableObject := inGraveyardWithKey(addrKey, graveyardBKT, garbageBKT) == 0
// unmarshal object, work only with physically stored (raw == true) objects
obj, err := db.get(tx, addr, key, false, true, currEpoch)
if err != nil {
if client.IsErrObjectNotFound(err) {
addrKey = addressKey(addr, key)
if garbageBKT != nil {
err := garbageBKT.Delete(addrKey)
if err != nil {
return deleteSingleResult{}, fmt.Errorf("could not remove from garbage bucket: %w", err)
}
}
return deleteSingleResult{}, nil
}
var siErr *objectSDK.SplitInfoError
var ecErr *objectSDK.ECInfoError
if errors.As(err, &siErr) || errors.As(err, &ecErr) {
// if object is virtual (parent) then do nothing, it will be deleted with last child
// if object is erasure-coded it will be deleted with the last chunk presented on the shard
return deleteSingleResult{}, nil
}
return deleteSingleResult{}, err
}
addrKey = addressKey(addr, key)
// remove record from the garbage bucket
if garbageBKT != nil {
err := garbageBKT.Delete(addrKey)
if err != nil {
return deleteSingleResult{}, fmt.Errorf("could not remove from garbage bucket: %w", err)
}
}
// if object is an only link to a parent, then remove parent
if parent := obj.Parent(); parent != nil {
parAddr := object.AddressOf(parent)
sParAddr := addressKey(parAddr, key)
k := string(sParAddr)
nRef, ok := refCounter[k]
if !ok {
nRef = &referenceNumber{
all: parentLength(tx, parAddr),
obj: parent,
}
refCounter[k] = nRef
}
nRef.cur++
}
isUserObject := IsUserObject(obj)
// remove object
err = db.deleteObject(tx, obj, false)
if err != nil {
return deleteSingleResult{}, fmt.Errorf("could not remove object: %w", err)
}
if err := deleteECRelatedInfo(tx, garbageBKT, obj, addr.Container(), refCounter); err != nil {
return deleteSingleResult{}, err
}
return deleteSingleResult{
Phy: true,
Logic: removeAvailableObject,
User: isUserObject && removeAvailableObject,
Size: obj.PayloadSize(),
}, nil
}
func (db *DB) deleteObject(
tx *bbolt.Tx,
obj *objectSDK.Object,
isParent bool,
) error {
err := delUniqueIndexes(tx, obj, isParent)
if err != nil {
return errFailedToRemoveUniqueIndexes
}
err = updateListIndexes(tx, obj, delListIndexItem)
if err != nil {
return fmt.Errorf("can't remove list indexes: %w", err)
}
err = updateFKBTIndexes(tx, obj, delFKBTIndexItem)
if err != nil {
return fmt.Errorf("can't remove fake bucket tree indexes: %w", err)
}
if isParent {
// remove record from the garbage bucket, because regular object deletion does nothing for virtual object
garbageBKT := tx.Bucket(garbageBucketName)
if garbageBKT != nil {
key := make([]byte, addressKeySize)
addrKey := addressKey(object.AddressOf(obj), key)
err := garbageBKT.Delete(addrKey)
if err != nil {
return fmt.Errorf("could not remove from garbage bucket: %w", err)
}
}
}
return nil
}
// parentLength returns amount of available children from parentid index.
func parentLength(tx *bbolt.Tx, addr oid.Address) int {
bucketName := make([]byte, bucketKeySize)
bkt := tx.Bucket(parentBucketName(addr.Container(), bucketName[:]))
if bkt == nil {
return 0
}
lst, err := decodeList(bkt.Get(objectKey(addr.Object(), bucketName[:])))
if err != nil {
return 0
}
return len(lst)
}
func delUniqueIndexItem(tx *bbolt.Tx, item namedBucketItem) {
bkt := tx.Bucket(item.name)
if bkt != nil {
_ = bkt.Delete(item.key) // ignore error, best effort there
}
}
func delListIndexItem(tx *bbolt.Tx, item namedBucketItem) error {
bkt := tx.Bucket(item.name)
if bkt == nil {
return nil
}
lst, err := decodeList(bkt.Get(item.key))
if err != nil || len(lst) == 0 {
return nil
}
// remove element from the list
for i := range lst {
if bytes.Equal(item.val, lst[i]) {
copy(lst[i:], lst[i+1:])
lst = lst[:len(lst)-1]
break
}
}
// if list empty, remove the key from <list> bucket
if len(lst) == 0 {
_ = bkt.Delete(item.key) // ignore error, best effort there
return nil
}
// if list is not empty, then update it
encodedLst, err := encodeList(lst)
if err != nil {
return nil // ignore error, best effort there
}
_ = bkt.Put(item.key, encodedLst) // ignore error, best effort there
return nil
}
func delFKBTIndexItem(tx *bbolt.Tx, item namedBucketItem) error {
bkt := tx.Bucket(item.name)
if bkt == nil {
return nil
}
fkbtRoot := bkt.Bucket(item.key)
if fkbtRoot == nil {
return nil
}
if err := fkbtRoot.Delete(item.val); err != nil {
return err
}
if hasAnyItem(fkbtRoot) {
return nil
}
if err := bkt.DeleteBucket(item.key); err != nil {
return err
}
if hasAnyItem(bkt) {
return nil
}
return tx.DeleteBucket(item.name)
}
func hasAnyItem(b *bbolt.Bucket) bool {
var hasAnyItem bool
c := b.Cursor()
for k, _ := c.First(); k != nil; {
hasAnyItem = true
break
}
return hasAnyItem
}
func delUniqueIndexes(tx *bbolt.Tx, obj *objectSDK.Object, isParent bool) error {
addr := object.AddressOf(obj)
objKey := objectKey(addr.Object(), make([]byte, objectKeySize))
cnr := addr.Container()
bucketName := make([]byte, bucketKeySize)
// add value to primary unique bucket
if !isParent {
switch obj.Type() {
case objectSDK.TypeRegular:
bucketName = primaryBucketName(cnr, bucketName)
case objectSDK.TypeTombstone:
bucketName = tombstoneBucketName(cnr, bucketName)
case objectSDK.TypeLock:
bucketName = bucketNameLockers(cnr, bucketName)
default:
return ErrUnknownObjectType
}
delUniqueIndexItem(tx, namedBucketItem{
name: bucketName,
key: objKey,
})
} else {
delUniqueIndexItem(tx, namedBucketItem{
name: parentBucketName(cnr, bucketName),
key: objKey,
})
}
delUniqueIndexItem(tx, namedBucketItem{ // remove from storage id index
name: smallBucketName(cnr, bucketName),
key: objKey,
})
delUniqueIndexItem(tx, namedBucketItem{ // remove from root index
name: rootBucketName(cnr, bucketName),
key: objKey,
})
if expEpoch, ok := hasExpirationEpoch(obj); ok {
delUniqueIndexItem(tx, namedBucketItem{
name: expEpochToObjectBucketName,
key: expirationEpochKey(expEpoch, cnr, addr.Object()),
})
delUniqueIndexItem(tx, namedBucketItem{
name: objectToExpirationEpochBucketName(cnr, make([]byte, bucketKeySize)),
key: objKey,
})
}
return nil
}
func deleteECRelatedInfo(tx *bbolt.Tx, garbageBKT *bbolt.Bucket, obj *objectSDK.Object, cnr cid.ID, refCounter referenceCounter) error {
ech := obj.ECHeader()
if ech == nil {
return nil
}
hasAnyChunks := hasAnyECChunks(tx, ech, cnr)
// drop EC parent GC mark if current EC chunk is the last one
if !hasAnyChunks && garbageBKT != nil {
var ecParentAddress oid.Address
ecParentAddress.SetContainer(cnr)
ecParentAddress.SetObject(ech.Parent())
addrKey := addressKey(ecParentAddress, make([]byte, addressKeySize))
err := garbageBKT.Delete(addrKey)
if err != nil {
return fmt.Errorf("could not remove EC parent from garbage bucket: %w", err)
}
}
// also drop EC parent root info if current EC chunk is the last one
if !hasAnyChunks {
delUniqueIndexItem(tx, namedBucketItem{
name: rootBucketName(cnr, make([]byte, bucketKeySize)),
key: objectKey(ech.Parent(), make([]byte, objectKeySize)),
})
}
if ech.ParentSplitParentID() == nil {
return nil
}
var splitParentAddress oid.Address
splitParentAddress.SetContainer(cnr)
splitParentAddress.SetObject(*ech.ParentSplitParentID())
if ref, ok := refCounter[string(addressKey(splitParentAddress, make([]byte, addressKeySize)))]; ok {
// linking object is already processing
// so just inform that one more reference was deleted
// split info and gc marks will be deleted after linking object delete
ref.cur++
return nil
}
if parentLength(tx, splitParentAddress) > 0 {
// linking object still exists, so leave split info and gc mark deletion for linking object processing
return nil
}
// drop split parent gc mark
if garbageBKT != nil {
addrKey := addressKey(splitParentAddress, make([]byte, addressKeySize))
err := garbageBKT.Delete(addrKey)
if err != nil {
return fmt.Errorf("could not remove EC parent from garbage bucket: %w", err)
}
}
// drop split info
delUniqueIndexItem(tx, namedBucketItem{
name: rootBucketName(cnr, make([]byte, bucketKeySize)),
key: objectKey(*ech.ParentSplitParentID(), make([]byte, objectKeySize)),
})
return nil
}
func hasAnyECChunks(tx *bbolt.Tx, ech *objectSDK.ECHeader, cnr cid.ID) bool {
data := getFromBucket(tx, ecInfoBucketName(cnr, make([]byte, bucketKeySize)),
objectKey(ech.Parent(), make([]byte, objectKeySize)))
return len(data) > 0
}