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minio/cmd/erasure-server-pool.go

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// Copyright (c) 2015-2021 MinIO, Inc.
//
// This file is part of MinIO Object Storage stack
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU Affero General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Affero General Public License for more details.
//
// You should have received a copy of the GNU Affero General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
package cmd
import (
"bytes"
"context"
"errors"
"fmt"
"io"
"math/rand"
"net/http"
"sort"
"strconv"
"strings"
"sync"
"time"
"github.com/dustin/go-humanize"
"github.com/google/uuid"
"github.com/minio/madmin-go/v2"
"github.com/minio/minio-go/v7/pkg/s3utils"
"github.com/minio/minio-go/v7/pkg/set"
"github.com/minio/minio-go/v7/pkg/tags"
"github.com/minio/minio/internal/config/storageclass"
"github.com/minio/minio/internal/logger"
"github.com/minio/minio/internal/sync/errgroup"
"github.com/minio/pkg/wildcard"
)
type erasureServerPools struct {
poolMetaMutex sync.RWMutex
poolMeta poolMeta
rebalMu sync.RWMutex
rebalMeta *rebalanceMeta
deploymentID [16]byte
distributionAlgo string
serverPools []*erasureSets
// Active decommission canceler
decommissionCancelers []context.CancelFunc
s3Peer *S3PeerSys
}
func (z *erasureServerPools) SinglePool() bool {
return len(z.serverPools) == 1
}
// Initialize new pool of erasure sets.
func newErasureServerPools(ctx context.Context, endpointServerPools EndpointServerPools) (ObjectLayer, error) {
var (
deploymentID string
distributionAlgo string
commonParityDrives int
err error
formats = make([]*formatErasureV3, len(endpointServerPools))
storageDisks = make([][]StorageAPI, len(endpointServerPools))
z = &erasureServerPools{
serverPools: make([]*erasureSets, len(endpointServerPools)),
s3Peer: NewS3PeerSys(endpointServerPools),
}
)
var localDrives []StorageAPI
local := endpointServerPools.FirstLocal()
for i, ep := range endpointServerPools {
// If storage class is not set during startup, default values are used
// -- Default for Reduced Redundancy Storage class is, parity = 2
// -- Default for Standard Storage class is, parity = 2 - disks 4, 5
// -- Default for Standard Storage class is, parity = 3 - disks 6, 7
// -- Default for Standard Storage class is, parity = 4 - disks 8 to 16
if commonParityDrives == 0 {
commonParityDrives, err = ecDrivesNoConfig(ep.DrivesPerSet)
if err != nil {
return nil, err
}
}
if err = storageclass.ValidateParity(commonParityDrives, ep.DrivesPerSet); err != nil {
return nil, fmt.Errorf("parity validation returned an error: %w <- (%d, %d), for pool(%s)", err, commonParityDrives, ep.DrivesPerSet, humanize.Ordinal(i+1))
}
storageDisks[i], formats[i], err = waitForFormatErasure(local, ep.Endpoints, i+1,
ep.SetCount, ep.DrivesPerSet, deploymentID, distributionAlgo)
if err != nil {
return nil, err
}
for _, storageDisk := range storageDisks[i] {
if storageDisk != nil && storageDisk.IsLocal() {
localDrives = append(localDrives, storageDisk)
}
}
if deploymentID == "" {
// all pools should have same deployment ID
deploymentID = formats[i].ID
}
if distributionAlgo == "" {
distributionAlgo = formats[i].Erasure.DistributionAlgo
}
// Validate if users brought different DeploymentID pools.
if deploymentID != formats[i].ID {
return nil, fmt.Errorf("all pools must have same deployment ID - expected %s, got %s for pool(%s)", deploymentID, formats[i].ID, humanize.Ordinal(i+1))
}
z.serverPools[i], err = newErasureSets(ctx, ep, storageDisks[i], formats[i], commonParityDrives, i)
if err != nil {
return nil, err
}
if deploymentID != "" && bytes.Equal(z.deploymentID[:], []byte{}) {
z.deploymentID = uuid.MustParse(deploymentID)
}
if distributionAlgo != "" && z.distributionAlgo == "" {
z.distributionAlgo = distributionAlgo
}
}
z.decommissionCancelers = make([]context.CancelFunc, len(z.serverPools))
r := rand.New(rand.NewSource(time.Now().UnixNano()))
for {
err := z.Init(ctx) // Initializes all pools.
if err != nil {
if !configRetriableErrors(err) {
logger.Fatal(err, "Unable to initialize backend")
}
retry := time.Duration(r.Float64() * float64(5*time.Second))
logger.LogIf(ctx, fmt.Errorf("Unable to initialize backend: %w, retrying in %s", err, retry))
time.Sleep(retry)
continue
}
break
}
globalLocalDrivesMu.Lock()
globalLocalDrives = localDrives
defer globalLocalDrivesMu.Unlock()
return z, nil
}
func (z *erasureServerPools) NewNSLock(bucket string, objects ...string) RWLocker {
poolID := hashKey(z.distributionAlgo, "", len(z.serverPools), z.deploymentID)
if len(objects) >= 1 {
poolID = hashKey(z.distributionAlgo, objects[0], len(z.serverPools), z.deploymentID)
}
return z.serverPools[poolID].NewNSLock(bucket, objects...)
}
// GetDisksID will return disks by their ID.
func (z *erasureServerPools) GetDisksID(ids ...string) []StorageAPI {
idMap := make(map[string]struct{})
for _, id := range ids {
idMap[id] = struct{}{}
}
res := make([]StorageAPI, 0, len(idMap))
for _, s := range z.serverPools {
for _, set := range s.sets {
for _, disk := range set.getDisks() {
if disk == OfflineDisk {
continue
}
if id, _ := disk.GetDiskID(); id != "" {
if _, ok := idMap[id]; ok {
res = append(res, disk)
}
}
}
}
}
return res
}
// GetRawData will return all files with a given raw path to the callback.
// Errors are ignored, only errors from the callback are returned.
// For now only direct file paths are supported.
func (z *erasureServerPools) GetRawData(ctx context.Context, volume, file string, fn func(r io.Reader, host string, disk string, filename string, info StatInfo) error) error {
found := 0
for _, s := range z.serverPools {
for _, set := range s.sets {
for _, disk := range set.getDisks() {
if disk == OfflineDisk {
continue
}
stats, err := disk.StatInfoFile(ctx, volume, file, true)
if err != nil {
continue
}
for _, si := range stats {
found++
var r io.ReadCloser
if !si.Dir {
r, err = disk.ReadFileStream(ctx, volume, si.Name, 0, si.Size)
if err != nil {
continue
}
} else {
r = io.NopCloser(bytes.NewBuffer([]byte{}))
}
// Keep disk path instead of ID, to ensure that the downloaded zip file can be
// easily automated with `minio server hostname{1...n}/disk{1...m}`.
err = fn(r, disk.Hostname(), disk.Endpoint().Path, pathJoin(volume, si.Name), si)
r.Close()
if err != nil {
return err
}
}
}
}
}
if found == 0 {
return errFileNotFound
}
return nil
}
// Return the count of disks in each pool
func (z *erasureServerPools) SetDriveCounts() []int {
setDriveCounts := make([]int, len(z.serverPools))
for i := range z.serverPools {
setDriveCounts[i] = z.serverPools[i].SetDriveCount()
}
return setDriveCounts
}
type serverPoolsAvailableSpace []poolAvailableSpace
type poolAvailableSpace struct {
Index int
Available uint64
MaxUsedPct int // Used disk percentage of most filled disk, rounded down.
}
// TotalAvailable - total available space
func (p serverPoolsAvailableSpace) TotalAvailable() uint64 {
total := uint64(0)
for _, z := range p {
total += z.Available
}
return total
}
// FilterMaxUsed will filter out any pools that has used percent bigger than max,
// unless all have that, in which case all are preserved.
func (p serverPoolsAvailableSpace) FilterMaxUsed(max int) {
// We aren't modifying p, only entries in it, so we don't need to receive a pointer.
if len(p) <= 1 {
// Nothing to do.
return
}
var ok bool
for _, z := range p {
if z.MaxUsedPct < max {
ok = true
break
}
}
if !ok {
// All above limit.
// Do not modify
return
}
// Remove entries that are above.
for i, z := range p {
if z.MaxUsedPct < max {
continue
}
p[i].Available = 0
}
}
// getAvailablePoolIdx will return an index that can hold size bytes.
// -1 is returned if no serverPools have available space for the size given.
func (z *erasureServerPools) getAvailablePoolIdx(ctx context.Context, bucket, object string, size int64) int {
serverPools := z.getServerPoolsAvailableSpace(ctx, bucket, object, size)
serverPools.FilterMaxUsed(100 - (100 * diskReserveFraction))
total := serverPools.TotalAvailable()
if total == 0 {
return -1
}
// choose when we reach this many
choose := rand.Uint64() % total
atTotal := uint64(0)
for _, pool := range serverPools {
atTotal += pool.Available
if atTotal > choose && pool.Available > 0 {
return pool.Index
}
}
// Should not happen, but print values just in case.
logger.LogIf(ctx, fmt.Errorf("reached end of serverPools (total: %v, atTotal: %v, choose: %v)", total, atTotal, choose))
return -1
}
// getServerPoolsAvailableSpace will return the available space of each pool after storing the content.
// If there is not enough space the pool will return 0 bytes available.
// The size of each will be multiplied by the number of sets.
// Negative sizes are seen as 0 bytes.
func (z *erasureServerPools) getServerPoolsAvailableSpace(ctx context.Context, bucket, object string, size int64) serverPoolsAvailableSpace {
serverPools := make(serverPoolsAvailableSpace, len(z.serverPools))
storageInfos := make([][]*DiskInfo, len(z.serverPools))
nSets := make([]int, len(z.serverPools))
g := errgroup.WithNErrs(len(z.serverPools))
for index := range z.serverPools {
index := index
// Skip suspended pools or pools participating in rebalance for any new
// I/O.
if z.IsSuspended(index) || z.IsPoolRebalancing(index) {
continue
}
pool := z.serverPools[index]
nSets[index] = pool.setCount
g.Go(func() error {
// Get the set where it would be placed.
storageInfos[index] = getDiskInfos(ctx, pool.getHashedSet(object).getDisks()...)
return nil
}, index)
}
// Wait for the go routines.
g.Wait()
for i, zinfo := range storageInfos {
var available uint64
if !isMinioMetaBucketName(bucket) && !hasSpaceFor(zinfo, size) {
serverPools[i] = poolAvailableSpace{Index: i}
continue
}
var maxUsedPct int
for _, disk := range zinfo {
if disk == nil || disk.Total == 0 {
continue
}
available += disk.Total - disk.Used
// set maxUsedPct to the value from the disk with the least space percentage.
if pctUsed := int(disk.Used * 100 / disk.Total); pctUsed > maxUsedPct {
maxUsedPct = pctUsed
}
}
// Since we are comparing pools that may have a different number of sets
// we multiply by the number of sets in the pool.
// This will compensate for differences in set sizes
// when choosing destination pool.
// Different set sizes are already compensated by less disks.
available *= uint64(nSets[i])
serverPools[i] = poolAvailableSpace{
Index: i,
Available: available,
MaxUsedPct: maxUsedPct,
}
}
return serverPools
}
// PoolObjInfo represents the state of current object version per pool
type PoolObjInfo struct {
Index int
ObjInfo ObjectInfo
Err error
}
func (z *erasureServerPools) getPoolInfoExistingWithOpts(ctx context.Context, bucket, object string, opts ObjectOptions) (PoolObjInfo, error) {
poolObjInfos := make([]PoolObjInfo, len(z.serverPools))
poolOpts := make([]ObjectOptions, len(z.serverPools))
for i := range z.serverPools {
poolOpts[i] = opts
}
var wg sync.WaitGroup
for i, pool := range z.serverPools {
wg.Add(1)
go func(i int, pool *erasureSets, opts ObjectOptions) {
defer wg.Done()
// remember the pool index, we may sort the slice original index might be lost.
pinfo := PoolObjInfo{
Index: i,
}
// do not remove this check as it can lead to inconsistencies
// for all callers of bucket replication.
opts.VersionID = ""
pinfo.ObjInfo, pinfo.Err = pool.GetObjectInfo(ctx, bucket, object, opts)
poolObjInfos[i] = pinfo
}(i, pool, poolOpts[i])
}
wg.Wait()
// Sort the objInfos such that we always serve latest
// this is a defensive change to handle any duplicate
// content that may have been created, we always serve
// the latest object.
sort.Slice(poolObjInfos, func(i, j int) bool {
mtime1 := poolObjInfos[i].ObjInfo.ModTime
mtime2 := poolObjInfos[j].ObjInfo.ModTime
return mtime1.After(mtime2)
})
defPool := PoolObjInfo{Index: -1}
for _, pinfo := range poolObjInfos {
// skip all objects from suspended pools if asked by the
// caller.
if z.IsSuspended(pinfo.Index) && opts.SkipDecommissioned {
continue
}
// Skip object if it's from pools participating in a rebalance operation.
if opts.SkipRebalancing && z.IsPoolRebalancing(pinfo.Index) {
continue
}
if pinfo.Err != nil && !isErrObjectNotFound(pinfo.Err) {
return pinfo, pinfo.Err
}
defPool = pinfo
if isErrObjectNotFound(pinfo.Err) {
// No object exists or its a delete marker,
// check objInfo to confirm.
if pinfo.ObjInfo.DeleteMarker && pinfo.ObjInfo.Name != "" {
return pinfo, nil
}
// objInfo is not valid, truly the object doesn't
// exist proceed to next pool.
continue
}
return pinfo, nil
}
if opts.ReplicationRequest && opts.DeleteMarker && defPool.Index >= 0 {
// If the request is a delete marker replication request, return a default pool
// in cases where the object does not exist.
// This is to ensure that the delete marker is replicated to the destination.
return defPool, nil
}
return PoolObjInfo{}, toObjectErr(errFileNotFound, bucket, object)
}
func (z *erasureServerPools) getPoolIdxExistingWithOpts(ctx context.Context, bucket, object string, opts ObjectOptions) (idx int, err error) {
pinfo, err := z.getPoolInfoExistingWithOpts(ctx, bucket, object, opts)
if err != nil {
return -1, err
}
return pinfo.Index, nil
}
// getPoolIdxExistingNoLock returns the (first) found object pool index containing an object.
// If the object exists, but the latest version is a delete marker, the index with it is still returned.
// If the object does not exist ObjectNotFound error is returned.
// If any other error is found, it is returned.
// The check is skipped if there is only one pool, and 0, nil is always returned in that case.
func (z *erasureServerPools) getPoolIdxExistingNoLock(ctx context.Context, bucket, object string) (idx int, err error) {
return z.getPoolIdxExistingWithOpts(ctx, bucket, object, ObjectOptions{
NoLock: true,
SkipDecommissioned: true,
SkipRebalancing: true,
})
}
func (z *erasureServerPools) getPoolIdxNoLock(ctx context.Context, bucket, object string, size int64) (idx int, err error) {
idx, err = z.getPoolIdxExistingNoLock(ctx, bucket, object)
if err != nil && !isErrObjectNotFound(err) {
return idx, err
}
if isErrObjectNotFound(err) {
idx = z.getAvailablePoolIdx(ctx, bucket, object, size)
if idx < 0 {
return -1, toObjectErr(errDiskFull)
}
}
return idx, nil
}
// getPoolIdx returns the found previous object and its corresponding pool idx,
// if none are found falls back to most available space pool, this function is
// designed to be only used by PutObject, CopyObject (newObject creation) and NewMultipartUpload.
func (z *erasureServerPools) getPoolIdx(ctx context.Context, bucket, object string, size int64) (idx int, err error) {
idx, err = z.getPoolIdxExistingWithOpts(ctx, bucket, object, ObjectOptions{
SkipDecommissioned: true,
SkipRebalancing: true,
})
if err != nil && !isErrObjectNotFound(err) {
return idx, err
}
if isErrObjectNotFound(err) {
idx = z.getAvailablePoolIdx(ctx, bucket, object, size)
if idx < 0 {
return -1, toObjectErr(errDiskFull)
}
}
return idx, nil
}
func (z *erasureServerPools) Shutdown(ctx context.Context) error {
g := errgroup.WithNErrs(len(z.serverPools))
for index := range z.serverPools {
index := index
g.Go(func() error {
return z.serverPools[index].Shutdown(ctx)
}, index)
}
for _, err := range g.Wait() {
if err != nil {
logger.LogIf(ctx, err)
}
// let's the rest shutdown
}
return nil
}
func (z *erasureServerPools) BackendInfo() (b madmin.BackendInfo) {
b.Type = madmin.Erasure
scParity := globalStorageClass.GetParityForSC(storageclass.STANDARD)
if scParity < 0 {
scParity = z.serverPools[0].defaultParityCount
}
rrSCParity := globalStorageClass.GetParityForSC(storageclass.RRS)
// Data blocks can vary per pool, but parity is same.
for i, setDriveCount := range z.SetDriveCounts() {
b.StandardSCData = append(b.StandardSCData, setDriveCount-scParity)
b.RRSCData = append(b.RRSCData, setDriveCount-rrSCParity)
b.DrivesPerSet = append(b.DrivesPerSet, setDriveCount)
b.TotalSets = append(b.TotalSets, z.serverPools[i].setCount)
}
b.StandardSCParity = scParity
b.RRSCParity = rrSCParity
return
}
func (z *erasureServerPools) LocalStorageInfo(ctx context.Context) StorageInfo {
var storageInfo StorageInfo
storageInfos := make([]StorageInfo, len(z.serverPools))
g := errgroup.WithNErrs(len(z.serverPools))
for index := range z.serverPools {
index := index
g.Go(func() error {
storageInfos[index] = z.serverPools[index].LocalStorageInfo(ctx)
return nil
}, index)
}
// Wait for the go routines.
g.Wait()
storageInfo.Backend = z.BackendInfo()
for _, lstorageInfo := range storageInfos {
storageInfo.Disks = append(storageInfo.Disks, lstorageInfo.Disks...)
}
return storageInfo
}
func (z *erasureServerPools) StorageInfo(ctx context.Context) StorageInfo {
return globalNotificationSys.StorageInfo(z)
}
func (z *erasureServerPools) NSScanner(ctx context.Context, updates chan<- DataUsageInfo, wantCycle uint32, healScanMode madmin.HealScanMode) error {
// Updates must be closed before we return.
defer close(updates)
ctx, cancel := context.WithCancel(ctx)
defer cancel()
var wg sync.WaitGroup
var mu sync.Mutex
var results []dataUsageCache
var firstErr error
allBuckets, err := z.ListBuckets(ctx, BucketOptions{})
if err != nil {
return err
}
if len(allBuckets) == 0 {
updates <- DataUsageInfo{} // no buckets found update data usage to reflect latest state
return nil
}
// Scanner latest allBuckets first.
sort.Slice(allBuckets, func(i, j int) bool {
return allBuckets[i].Created.After(allBuckets[j].Created)
})
// Collect for each set in serverPools.
for _, z := range z.serverPools {
for _, erObj := range z.sets {
wg.Add(1)
results = append(results, dataUsageCache{})
go func(i int, erObj *erasureObjects) {
updates := make(chan dataUsageCache, 1)
defer close(updates)
// Start update collector.
go func() {
defer wg.Done()
for info := range updates {
mu.Lock()
results[i] = info
mu.Unlock()
}
}()
// Start scanner. Blocks until done.
err := erObj.nsScanner(ctx, allBuckets, wantCycle, updates, healScanMode)
if err != nil {
logger.LogIf(ctx, err)
mu.Lock()
if firstErr == nil {
firstErr = err
}
// Cancel remaining...
cancel()
mu.Unlock()
return
}
}(len(results)-1, erObj)
}
}
updateCloser := make(chan chan struct{})
go func() {
updateTicker := time.NewTicker(30 * time.Second)
defer updateTicker.Stop()
var lastUpdate time.Time
// We need to merge since we will get the same buckets from each pool.
// Therefore to get the exact bucket sizes we must merge before we can convert.
var allMerged dataUsageCache
update := func() {
mu.Lock()
defer mu.Unlock()
allMerged = dataUsageCache{Info: dataUsageCacheInfo{Name: dataUsageRoot}}
for _, info := range results {
if info.Info.LastUpdate.IsZero() {
// Not filled yet.
return
}
allMerged.merge(info)
}
if allMerged.root() != nil && allMerged.Info.LastUpdate.After(lastUpdate) {
updates <- allMerged.dui(allMerged.Info.Name, allBuckets)
lastUpdate = allMerged.Info.LastUpdate
}
}
for {
select {
case <-ctx.Done():
return
case v := <-updateCloser:
update()
close(v)
return
case <-updateTicker.C:
update()
}
}
}()
wg.Wait()
ch := make(chan struct{})
select {
case updateCloser <- ch:
<-ch
case <-ctx.Done():
mu.Lock()
if firstErr == nil {
firstErr = ctx.Err()
}
defer mu.Unlock()
}
return firstErr
}
// MakeBucket - creates a new bucket across all serverPools simultaneously
// even if one of the sets fail to create buckets, we proceed all the successful
// operations.
func (z *erasureServerPools) MakeBucket(ctx context.Context, bucket string, opts MakeBucketOptions) error {
// Verify if bucket is valid.
if !isMinioMetaBucketName(bucket) {
if err := s3utils.CheckValidBucketNameStrict(bucket); err != nil {
return BucketNameInvalid{Bucket: bucket}
}
if !opts.NoLock {
// Lock the bucket name before creating.
lk := z.NewNSLock(minioMetaTmpBucket, bucket+".lck")
lkctx, err := lk.GetLock(ctx, globalOperationTimeout)
if err != nil {
return err
}
ctx = lkctx.Context()
defer lk.Unlock(lkctx)
}
}
if err := z.s3Peer.MakeBucket(ctx, bucket, opts); err != nil {
if _, ok := err.(BucketExists); !ok {
// Delete created buckets, ignoring errors.
z.DeleteBucket(context.Background(), bucket, DeleteBucketOptions{
NoLock: true,
NoRecreate: true,
})
}
return err
}
// If it doesn't exist we get a new, so ignore errors
meta := newBucketMetadata(bucket)
meta.SetCreatedAt(opts.CreatedAt)
if opts.LockEnabled {
meta.VersioningConfigXML = enabledBucketVersioningConfig
meta.ObjectLockConfigXML = enabledBucketObjectLockConfig
}
if opts.VersioningEnabled {
meta.VersioningConfigXML = enabledBucketVersioningConfig
}
if err := meta.Save(context.Background(), z); err != nil {
return toObjectErr(err, bucket)
}
globalBucketMetadataSys.Set(bucket, meta)
// Success.
return nil
}
func (z *erasureServerPools) GetObjectNInfo(ctx context.Context, bucket, object string, rs *HTTPRangeSpec, h http.Header, lockType LockType, opts ObjectOptions) (gr *GetObjectReader, err error) {
if err = checkGetObjArgs(ctx, bucket, object); err != nil {
return nil, err
}
object = encodeDirObject(object)
if z.SinglePool() {
return z.serverPools[0].GetObjectNInfo(ctx, bucket, object, rs, h, lockType, opts)
}
var unlockOnDefer bool
nsUnlocker := func() {}
defer func() {
if unlockOnDefer {
nsUnlocker()
}
}()
// Acquire lock
if lockType != noLock {
lock := z.NewNSLock(bucket, object)
switch lockType {
case writeLock:
lkctx, err := lock.GetLock(ctx, globalOperationTimeout)
if err != nil {
return nil, err
}
ctx = lkctx.Context()
nsUnlocker = func() { lock.Unlock(lkctx) }
case readLock:
lkctx, err := lock.GetRLock(ctx, globalOperationTimeout)
if err != nil {
return nil, err
}
ctx = lkctx.Context()
nsUnlocker = func() { lock.RUnlock(lkctx) }
}
unlockOnDefer = true
}
checkPrecondFn := opts.CheckPrecondFn
opts.CheckPrecondFn = nil // do not need to apply pre-conditions at lower layer.
opts.NoLock = true // no locks needed at lower levels for getObjectInfo()
objInfo, zIdx, err := z.getLatestObjectInfoWithIdx(ctx, bucket, object, opts)
if err != nil {
if objInfo.DeleteMarker {
if opts.VersionID == "" {
return &GetObjectReader{
ObjInfo: objInfo,
}, toObjectErr(errFileNotFound, bucket, object)
}
// Make sure to return object info to provide extra information.
return &GetObjectReader{
ObjInfo: objInfo,
}, toObjectErr(errMethodNotAllowed, bucket, object)
}
return nil, err
}
// check preconditions before reading the stream.
if checkPrecondFn != nil && checkPrecondFn(objInfo) {
return nil, PreConditionFailed{}
}
lockType = noLock // do not take locks at lower levels for GetObjectNInfo()
gr, err = z.serverPools[zIdx].GetObjectNInfo(ctx, bucket, object, rs, h, lockType, opts)
if err != nil {
return nil, err
}
if unlockOnDefer {
unlockOnDefer = false
return gr.WithCleanupFuncs(nsUnlocker), nil
}
return gr, nil
}
// getLatestObjectInfoWithIdx returns the objectInfo of the latest object from multiple pools (this function
// is present in-case there were duplicate writes to both pools, this function also returns the
// additional index where the latest object exists, that is used to start the GetObject stream.
func (z *erasureServerPools) getLatestObjectInfoWithIdx(ctx context.Context, bucket, object string, opts ObjectOptions) (ObjectInfo, int, error) {
object = encodeDirObject(object)
results := make([]struct {
zIdx int
oi ObjectInfo
err error
}, len(z.serverPools))
var wg sync.WaitGroup
for i, pool := range z.serverPools {
wg.Add(1)
go func(i int, pool *erasureSets) {
defer wg.Done()
results[i].zIdx = i
results[i].oi, results[i].err = pool.GetObjectInfo(ctx, bucket, object, opts)
}(i, pool)
}
wg.Wait()
// Sort the objInfos such that we always serve latest
// this is a defensive change to handle any duplicate
// content that may have been created, we always serve
// the latest object.
sort.Slice(results, func(i, j int) bool {
a, b := results[i], results[j]
if a.oi.ModTime.Equal(b.oi.ModTime) {
// On tiebreak, select the lowest pool index.
return a.zIdx < b.zIdx
}
return a.oi.ModTime.After(b.oi.ModTime)
})
for _, res := range results {
err := res.err
if err == nil {
return res.oi, res.zIdx, nil
}
if !isErrObjectNotFound(err) && !isErrVersionNotFound(err) {
// some errors such as MethodNotAllowed for delete marker
// should be returned upwards.
return res.oi, res.zIdx, err
}
// When its a delete marker and versionID is empty
// we should simply return the error right away.
if res.oi.DeleteMarker && opts.VersionID == "" {
return res.oi, res.zIdx, err
}
}
object = decodeDirObject(object)
if opts.VersionID != "" {
return ObjectInfo{}, -1, VersionNotFound{Bucket: bucket, Object: object, VersionID: opts.VersionID}
}
return ObjectInfo{}, -1, ObjectNotFound{Bucket: bucket, Object: object}
}
func (z *erasureServerPools) GetObjectInfo(ctx context.Context, bucket, object string, opts ObjectOptions) (objInfo ObjectInfo, err error) {
if err = checkGetObjArgs(ctx, bucket, object); err != nil {
return objInfo, err
}
object = encodeDirObject(object)
if z.SinglePool() {
return z.serverPools[0].GetObjectInfo(ctx, bucket, object, opts)
}
if !opts.NoLock {
opts.NoLock = true // avoid taking locks at lower levels for multi-pool setups.
// Lock the object before reading.
lk := z.NewNSLock(bucket, object)
lkctx, err := lk.GetRLock(ctx, globalOperationTimeout)
if err != nil {
return ObjectInfo{}, err
}
ctx = lkctx.Context()
defer lk.RUnlock(lkctx)
}
objInfo, _, err = z.getLatestObjectInfoWithIdx(ctx, bucket, object, opts)
return objInfo, err
}
// PutObject - writes an object to least used erasure pool.
func (z *erasureServerPools) PutObject(ctx context.Context, bucket string, object string, data *PutObjReader, opts ObjectOptions) (ObjectInfo, error) {
// Validate put object input args.
if err := checkPutObjectArgs(ctx, bucket, object, z); err != nil {
return ObjectInfo{}, err
}
object = encodeDirObject(object)
if z.SinglePool() {
if !isMinioMetaBucketName(bucket) && !hasSpaceFor(getDiskInfos(ctx, z.serverPools[0].getHashedSet(object).getDisks()...), data.Size()) {
return ObjectInfo{}, toObjectErr(errDiskFull)
}
return z.serverPools[0].PutObject(ctx, bucket, object, data, opts)
}
if !opts.NoLock {
ns := z.NewNSLock(bucket, object)
lkctx, err := ns.GetLock(ctx, globalOperationTimeout)
if err != nil {
return ObjectInfo{}, err
}
ctx = lkctx.Context()
defer ns.Unlock(lkctx)
opts.NoLock = true
}
idx, err := z.getPoolIdxNoLock(ctx, bucket, object, data.Size())
if err != nil {
return ObjectInfo{}, err
}
// Overwrite the object at the right pool
return z.serverPools[idx].PutObject(ctx, bucket, object, data, opts)
}
func (z *erasureServerPools) deletePrefix(ctx context.Context, bucket string, prefix string) error {
for _, pool := range z.serverPools {
if _, err := pool.DeleteObject(ctx, bucket, prefix, ObjectOptions{DeletePrefix: true}); err != nil {
return err
}
}
return nil
}
func (z *erasureServerPools) DeleteObject(ctx context.Context, bucket string, object string, opts ObjectOptions) (objInfo ObjectInfo, err error) {
if err = checkDelObjArgs(ctx, bucket, object); err != nil {
return objInfo, err
}
if opts.DeletePrefix {
err := z.deletePrefix(ctx, bucket, object)
return ObjectInfo{}, err
}
object = encodeDirObject(object)
// Acquire a write lock before deleting the object.
lk := z.NewNSLock(bucket, object)
lkctx, err := lk.GetLock(ctx, globalDeleteOperationTimeout)
if err != nil {
return ObjectInfo{}, err
}
ctx = lkctx.Context()
defer lk.Unlock(lkctx)
gopts := opts
gopts.NoLock = true
pinfo, err := z.getPoolInfoExistingWithOpts(ctx, bucket, object, gopts)
if err != nil {
if _, ok := err.(InsufficientReadQuorum); ok {
return objInfo, InsufficientWriteQuorum{}
}
return objInfo, err
}
// Delete marker already present we are not going to create new delete markers.
if pinfo.ObjInfo.DeleteMarker && opts.VersionID == "" {
pinfo.ObjInfo.Name = decodeDirObject(object)
return pinfo.ObjInfo, nil
}
objInfo, err = z.serverPools[pinfo.Index].DeleteObject(ctx, bucket, object, opts)
objInfo.Name = decodeDirObject(object)
return objInfo, err
}
func (z *erasureServerPools) DeleteObjects(ctx context.Context, bucket string, objects []ObjectToDelete, opts ObjectOptions) ([]DeletedObject, []error) {
derrs := make([]error, len(objects))
dobjects := make([]DeletedObject, len(objects))
objSets := set.NewStringSet()
for i := range derrs {
objects[i].ObjectName = encodeDirObject(objects[i].ObjectName)
derrs[i] = checkDelObjArgs(ctx, bucket, objects[i].ObjectName)
objSets.Add(objects[i].ObjectName)
}
// Acquire a bulk write lock across 'objects'
multiDeleteLock := z.NewNSLock(bucket, objSets.ToSlice()...)
lkctx, err := multiDeleteLock.GetLock(ctx, globalOperationTimeout)
if err != nil {
for i := range derrs {
derrs[i] = err
}
return dobjects, derrs
}
ctx = lkctx.Context()
defer multiDeleteLock.Unlock(lkctx)
// Fetch location of up to 10 objects concurrently.
poolObjIdxMap := map[int][]ObjectToDelete{}
origIndexMap := map[int][]int{}
// Always perform 1/10th of the number of objects per delete
concurrent := len(objects) / 10
if concurrent <= 10 {
// if we cannot get 1/10th then choose the number of
// objects as concurrent.
concurrent = len(objects)
}
var mu sync.Mutex
eg := errgroup.WithNErrs(len(objects)).WithConcurrency(concurrent)
for j, obj := range objects {
j := j
obj := obj
eg.Go(func() error {
pinfo, err := z.getPoolInfoExistingWithOpts(ctx, bucket, obj.ObjectName, ObjectOptions{
NoLock: true,
})
if err != nil {
if !isErrObjectNotFound(err) && !isErrVersionNotFound(err) {
derrs[j] = err
}
dobjects[j] = DeletedObject{
ObjectName: decodeDirObject(obj.ObjectName),
VersionID: obj.VersionID,
}
return nil
}
// Delete marker already present we are not going to create new delete markers.
if pinfo.ObjInfo.DeleteMarker && obj.VersionID == "" {
dobjects[j] = DeletedObject{
DeleteMarker: pinfo.ObjInfo.DeleteMarker,
DeleteMarkerVersionID: pinfo.ObjInfo.VersionID,
DeleteMarkerMTime: DeleteMarkerMTime{pinfo.ObjInfo.ModTime},
ObjectName: decodeDirObject(pinfo.ObjInfo.Name),
}
return nil
}
idx := pinfo.Index
mu.Lock()
defer mu.Unlock()
poolObjIdxMap[idx] = append(poolObjIdxMap[idx], obj)
origIndexMap[idx] = append(origIndexMap[idx], j)
return nil
}, j)
}
eg.Wait() // wait to check all the pools.
if len(poolObjIdxMap) > 0 {
// Delete concurrently in all server pools.
var wg sync.WaitGroup
wg.Add(len(z.serverPools))
for idx, pool := range z.serverPools {
go func(idx int, pool *erasureSets) {
defer wg.Done()
objs := poolObjIdxMap[idx]
if len(objs) > 0 {
orgIndexes := origIndexMap[idx]
deletedObjects, errs := pool.DeleteObjects(ctx, bucket, objs, opts)
mu.Lock()
for i, derr := range errs {
if derr != nil {
derrs[orgIndexes[i]] = derr
}
deletedObjects[i].ObjectName = decodeDirObject(deletedObjects[i].ObjectName)
dobjects[orgIndexes[i]] = deletedObjects[i]
}
mu.Unlock()
}
}(idx, pool)
}
wg.Wait()
}
return dobjects, derrs
}
func (z *erasureServerPools) CopyObject(ctx context.Context, srcBucket, srcObject, dstBucket, dstObject string, srcInfo ObjectInfo, srcOpts, dstOpts ObjectOptions) (objInfo ObjectInfo, err error) {
srcObject = encodeDirObject(srcObject)
dstObject = encodeDirObject(dstObject)
cpSrcDstSame := isStringEqual(pathJoin(srcBucket, srcObject), pathJoin(dstBucket, dstObject))
if !dstOpts.NoLock {
ns := z.NewNSLock(dstBucket, dstObject)
lkctx, err := ns.GetLock(ctx, globalOperationTimeout)
if err != nil {
return ObjectInfo{}, err
}
ctx = lkctx.Context()
defer ns.Unlock(lkctx)
dstOpts.NoLock = true
}
poolIdx, err := z.getPoolIdxNoLock(ctx, dstBucket, dstObject, srcInfo.Size)
if err != nil {
return objInfo, err
}
if cpSrcDstSame && srcInfo.metadataOnly {
// Version ID is set for the destination and source == destination version ID.
if dstOpts.VersionID != "" && srcOpts.VersionID == dstOpts.VersionID {
return z.serverPools[poolIdx].CopyObject(ctx, srcBucket, srcObject, dstBucket, dstObject, srcInfo, srcOpts, dstOpts)
}
// Destination is not versioned and source version ID is empty
// perform an in-place update.
if !dstOpts.Versioned && srcOpts.VersionID == "" {
return z.serverPools[poolIdx].CopyObject(ctx, srcBucket, srcObject, dstBucket, dstObject, srcInfo, srcOpts, dstOpts)
}
// Destination is versioned, source is not destination version,
// as a special case look for if the source object is not legacy
// from older format, for older format we will rewrite them as
// newer using PutObject() - this is an optimization to save space
if dstOpts.Versioned && srcOpts.VersionID != dstOpts.VersionID && !srcInfo.Legacy {
// CopyObject optimization where we don't create an entire copy
// of the content, instead we add a reference.
srcInfo.versionOnly = true
return z.serverPools[poolIdx].CopyObject(ctx, srcBucket, srcObject, dstBucket, dstObject, srcInfo, srcOpts, dstOpts)
}
}
putOpts := ObjectOptions{
ServerSideEncryption: dstOpts.ServerSideEncryption,
UserDefined: srcInfo.UserDefined,
Versioned: dstOpts.Versioned,
VersionID: dstOpts.VersionID,
MTime: dstOpts.MTime,
NoLock: true,
}
return z.serverPools[poolIdx].PutObject(ctx, dstBucket, dstObject, srcInfo.PutObjReader, putOpts)
}
func (z *erasureServerPools) ListObjectsV2(ctx context.Context, bucket, prefix, continuationToken, delimiter string, maxKeys int, fetchOwner bool, startAfter string) (ListObjectsV2Info, error) {
marker := continuationToken
if marker == "" {
marker = startAfter
}
loi, err := z.ListObjects(ctx, bucket, prefix, marker, delimiter, maxKeys)
if err != nil {
return ListObjectsV2Info{}, err
}
listObjectsV2Info := ListObjectsV2Info{
IsTruncated: loi.IsTruncated,
ContinuationToken: continuationToken,
NextContinuationToken: loi.NextMarker,
Objects: loi.Objects,
Prefixes: loi.Prefixes,
}
return listObjectsV2Info, err
}
func (z *erasureServerPools) ListObjectVersions(ctx context.Context, bucket, prefix, marker, versionMarker, delimiter string, maxKeys int) (ListObjectVersionsInfo, error) {
loi := ListObjectVersionsInfo{}
if marker == "" && versionMarker != "" {
return loi, NotImplemented{}
}
opts := listPathOptions{
Bucket: bucket,
Prefix: prefix,
Separator: delimiter,
Limit: maxKeysPlusOne(maxKeys, marker != ""),
Marker: marker,
InclDeleted: true,
AskDisks: globalAPIConfig.getListQuorum(),
Versioned: true,
}
// Shortcut for APN/1.0 Veeam/1.0 Backup/10.0
// It requests unique blocks with a specific prefix.
// We skip scanning the parent directory for
// more objects matching the prefix.
ri := logger.GetReqInfo(ctx)
if ri != nil && strings.Contains(ri.UserAgent, `1.0 Veeam/1.0 Backup`) && strings.HasSuffix(prefix, ".blk") {
opts.BaseDir = prefix
opts.Transient = true
}
// set bucket metadata in opts
opts.setBucketMeta(ctx)
merged, err := z.listPath(ctx, &opts)
if err != nil && err != io.EOF {
return loi, err
}
defer merged.truncate(0) // Release when returning
if versionMarker == "" {
o := listPathOptions{Marker: marker}
// If we are not looking for a specific version skip it.
o.parseMarker()
merged.forwardPast(o.Marker)
}
objects := merged.fileInfoVersions(bucket, prefix, delimiter, versionMarker)
loi.IsTruncated = err == nil && len(objects) > 0
if maxKeys > 0 && len(objects) > maxKeys {
objects = objects[:maxKeys]
loi.IsTruncated = true
}
for _, obj := range objects {
if obj.IsDir && obj.ModTime.IsZero() && delimiter != "" {
// Only add each once.
// With slash delimiter we only get the directory once.
found := false
if delimiter != slashSeparator {
for _, p := range loi.Prefixes {
if found {
break
}
found = p == obj.Name
}
}
if !found {
loi.Prefixes = append(loi.Prefixes, obj.Name)
}
} else {
loi.Objects = append(loi.Objects, obj)
}
}
if loi.IsTruncated {
last := objects[len(objects)-1]
loi.NextMarker = opts.encodeMarker(last.Name)
loi.NextVersionIDMarker = last.VersionID
}
return loi, nil
}
func maxKeysPlusOne(maxKeys int, addOne bool) int {
if maxKeys < 0 || maxKeys > maxObjectList {
maxKeys = maxObjectList
}
if addOne {
maxKeys++
}
return maxKeys
}
func (z *erasureServerPools) ListObjects(ctx context.Context, bucket, prefix, marker, delimiter string, maxKeys int) (ListObjectsInfo, error) {
var loi ListObjectsInfo
opts := listPathOptions{
Bucket: bucket,
Prefix: prefix,
Separator: delimiter,
Limit: maxKeysPlusOne(maxKeys, marker != ""),
Marker: marker,
InclDeleted: false,
AskDisks: globalAPIConfig.getListQuorum(),
}
opts.setBucketMeta(ctx)
if len(prefix) > 0 && maxKeys == 1 && delimiter == "" && marker == "" {
// Optimization for certain applications like
// - Cohesity
// - Actifio, Splunk etc.
// which send ListObjects requests where the actual object
// itself is the prefix and max-keys=1 in such scenarios
// we can simply verify locally if such an object exists
// to avoid the need for ListObjects().
objInfo, err := z.GetObjectInfo(ctx, bucket, prefix, ObjectOptions{NoLock: true})
if err == nil {
if opts.Lifecycle != nil {
evt := evalActionFromLifecycle(ctx, *opts.Lifecycle, opts.Retention, objInfo)
if evt.Action.Delete() {
globalExpiryState.enqueueByDays(objInfo, evt.Action.DeleteRestored(), evt.Action.DeleteVersioned())
if !evt.Action.DeleteRestored() {
// Skip entry if ILM action was DeleteVersionAction or DeleteAction
return loi, nil
}
}
}
loi.Objects = append(loi.Objects, objInfo)
return loi, nil
}
}
merged, err := z.listPath(ctx, &opts)
if err != nil && err != io.EOF {
if !isErrBucketNotFound(err) {
logger.LogIf(ctx, err)
}
return loi, err
}
merged.forwardPast(opts.Marker)
defer merged.truncate(0) // Release when returning
// Default is recursive, if delimiter is set then list non recursive.
objects := merged.fileInfos(bucket, prefix, delimiter)
loi.IsTruncated = err == nil && len(objects) > 0
if maxKeys > 0 && len(objects) > maxKeys {
objects = objects[:maxKeys]
loi.IsTruncated = true
}
for _, obj := range objects {
if obj.IsDir && obj.ModTime.IsZero() && delimiter != "" {
// Only add each once.
// With slash delimiter we only get the directory once.
found := false
if delimiter != slashSeparator {
for _, p := range loi.Prefixes {
if found {
break
}
found = p == obj.Name
}
}
if !found {
loi.Prefixes = append(loi.Prefixes, obj.Name)
}
} else {
loi.Objects = append(loi.Objects, obj)
}
}
if loi.IsTruncated {
last := objects[len(objects)-1]
loi.NextMarker = opts.encodeMarker(last.Name)
}
return loi, nil
}
func (z *erasureServerPools) ListMultipartUploads(ctx context.Context, bucket, prefix, keyMarker, uploadIDMarker, delimiter string, maxUploads int) (ListMultipartsInfo, error) {
if err := checkListMultipartArgs(ctx, bucket, prefix, keyMarker, uploadIDMarker, delimiter, z); err != nil {
return ListMultipartsInfo{}, err
}
if z.SinglePool() {
return z.serverPools[0].ListMultipartUploads(ctx, bucket, prefix, keyMarker, uploadIDMarker, delimiter, maxUploads)
}
poolResult := ListMultipartsInfo{}
poolResult.MaxUploads = maxUploads
poolResult.KeyMarker = keyMarker
poolResult.Prefix = prefix
poolResult.Delimiter = delimiter
for idx, pool := range z.serverPools {
if z.IsSuspended(idx) {
continue
}
result, err := pool.ListMultipartUploads(ctx, bucket, prefix, keyMarker, uploadIDMarker,
delimiter, maxUploads)
if err != nil {
return result, err
}
poolResult.Uploads = append(poolResult.Uploads, result.Uploads...)
}
return poolResult, nil
}
// Initiate a new multipart upload on a hashedSet based on object name.
func (z *erasureServerPools) NewMultipartUpload(ctx context.Context, bucket, object string, opts ObjectOptions) (*NewMultipartUploadResult, error) {
if err := checkNewMultipartArgs(ctx, bucket, object, z); err != nil {
return nil, err
}
if z.SinglePool() {
if !isMinioMetaBucketName(bucket) && !hasSpaceFor(getDiskInfos(ctx, z.serverPools[0].getHashedSet(object).getDisks()...), -1) {
return nil, toObjectErr(errDiskFull)
}
return z.serverPools[0].NewMultipartUpload(ctx, bucket, object, opts)
}
for idx, pool := range z.serverPools {
if z.IsSuspended(idx) || z.IsPoolRebalancing(idx) {
continue
}
result, err := pool.ListMultipartUploads(ctx, bucket, object, "", "", "", maxUploadsList)
if err != nil {
return nil, err
}
// If there is a multipart upload with the same bucket/object name,
// create the new multipart in the same pool, this will avoid
// creating two multiparts uploads in two different pools
if len(result.Uploads) != 0 {
return z.serverPools[idx].NewMultipartUpload(ctx, bucket, object, opts)
}
}
// any parallel writes on the object will block for this poolIdx
// to return since this holds a read lock on the namespace.
idx, err := z.getPoolIdx(ctx, bucket, object, -1)
if err != nil {
return nil, err
}
return z.serverPools[idx].NewMultipartUpload(ctx, bucket, object, opts)
}
// Copies a part of an object from source hashedSet to destination hashedSet.
func (z *erasureServerPools) CopyObjectPart(ctx context.Context, srcBucket, srcObject, destBucket, destObject string, uploadID string, partID int, startOffset int64, length int64, srcInfo ObjectInfo, srcOpts, dstOpts ObjectOptions) (PartInfo, error) {
if err := checkNewMultipartArgs(ctx, srcBucket, srcObject, z); err != nil {
return PartInfo{}, err
}
return z.PutObjectPart(ctx, destBucket, destObject, uploadID, partID,
NewPutObjReader(srcInfo.Reader), dstOpts)
}
// PutObjectPart - writes part of an object to hashedSet based on the object name.
func (z *erasureServerPools) PutObjectPart(ctx context.Context, bucket, object, uploadID string, partID int, data *PutObjReader, opts ObjectOptions) (PartInfo, error) {
if err := checkPutObjectPartArgs(ctx, bucket, object, z); err != nil {
return PartInfo{}, err
}
if z.SinglePool() {
return z.serverPools[0].PutObjectPart(ctx, bucket, object, uploadID, partID, data, opts)
}
for idx, pool := range z.serverPools {
if z.IsSuspended(idx) {
continue
}
pi, err := pool.PutObjectPart(ctx, bucket, object, uploadID, partID, data, opts)
if err == nil {
return pi, nil
}
if _, ok := err.(InvalidUploadID); ok {
// Look for information on the next pool
continue
}
// Any other unhandled errors such as quorum return.
return PartInfo{}, err
}
return PartInfo{}, InvalidUploadID{
Bucket: bucket,
Object: object,
UploadID: uploadID,
}
}
func (z *erasureServerPools) GetMultipartInfo(ctx context.Context, bucket, object, uploadID string, opts ObjectOptions) (MultipartInfo, error) {
if err := checkListPartsArgs(ctx, bucket, object, z); err != nil {
return MultipartInfo{}, err
}
if z.SinglePool() {
return z.serverPools[0].GetMultipartInfo(ctx, bucket, object, uploadID, opts)
}
for idx, pool := range z.serverPools {
if z.IsSuspended(idx) {
continue
}
mi, err := pool.GetMultipartInfo(ctx, bucket, object, uploadID, opts)
if err == nil {
return mi, nil
}
if _, ok := err.(InvalidUploadID); ok {
// upload id not found, continue to the next pool.
continue
}
// any other unhandled error return right here.
return MultipartInfo{}, err
}
return MultipartInfo{}, InvalidUploadID{
Bucket: bucket,
Object: object,
UploadID: uploadID,
}
}
// ListObjectParts - lists all uploaded parts to an object in hashedSet.
func (z *erasureServerPools) ListObjectParts(ctx context.Context, bucket, object, uploadID string, partNumberMarker int, maxParts int, opts ObjectOptions) (ListPartsInfo, error) {
if err := checkListPartsArgs(ctx, bucket, object, z); err != nil {
return ListPartsInfo{}, err
}
if z.SinglePool() {
return z.serverPools[0].ListObjectParts(ctx, bucket, object, uploadID, partNumberMarker, maxParts, opts)
}
for idx, pool := range z.serverPools {
if z.IsSuspended(idx) {
continue
}
result, err := pool.ListObjectParts(ctx, bucket, object, uploadID, partNumberMarker, maxParts, opts)
if err == nil {
return result, nil
}
if _, ok := err.(InvalidUploadID); ok {
continue
}
return ListPartsInfo{}, err
}
return ListPartsInfo{}, InvalidUploadID{
Bucket: bucket,
Object: object,
UploadID: uploadID,
}
}
// Aborts an in-progress multipart operation on hashedSet based on the object name.
func (z *erasureServerPools) AbortMultipartUpload(ctx context.Context, bucket, object, uploadID string, opts ObjectOptions) error {
if err := checkAbortMultipartArgs(ctx, bucket, object, z); err != nil {
return err
}
if z.SinglePool() {
return z.serverPools[0].AbortMultipartUpload(ctx, bucket, object, uploadID, opts)
}
for idx, pool := range z.serverPools {
if z.IsSuspended(idx) {
continue
}
err := pool.AbortMultipartUpload(ctx, bucket, object, uploadID, opts)
if err == nil {
return nil
}
if _, ok := err.(InvalidUploadID); ok {
// upload id not found move to next pool
continue
}
return err
}
return InvalidUploadID{
Bucket: bucket,
Object: object,
UploadID: uploadID,
}
}
// CompleteMultipartUpload - completes a pending multipart transaction, on hashedSet based on object name.
func (z *erasureServerPools) CompleteMultipartUpload(ctx context.Context, bucket, object, uploadID string, uploadedParts []CompletePart, opts ObjectOptions) (objInfo ObjectInfo, err error) {
if err = checkCompleteMultipartArgs(ctx, bucket, object, z); err != nil {
return objInfo, err
}
if z.SinglePool() {
return z.serverPools[0].CompleteMultipartUpload(ctx, bucket, object, uploadID, uploadedParts, opts)
}
for idx, pool := range z.serverPools {
if z.IsSuspended(idx) {
continue
}
objInfo, err = pool.CompleteMultipartUpload(ctx, bucket, object, uploadID, uploadedParts, opts)
if err == nil {
return objInfo, nil
}
if _, ok := err.(InvalidUploadID); ok {
// upload id not found move to next pool
continue
}
return objInfo, err
}
return objInfo, InvalidUploadID{
Bucket: bucket,
Object: object,
UploadID: uploadID,
}
}
// GetBucketInfo - returns bucket info from one of the erasure coded serverPools.
func (z *erasureServerPools) GetBucketInfo(ctx context.Context, bucket string, opts BucketOptions) (bucketInfo BucketInfo, err error) {
bucketInfo, err = z.s3Peer.GetBucketInfo(ctx, bucket, opts)
if err != nil {
return bucketInfo, toObjectErr(err, bucket)
}
meta, err := globalBucketMetadataSys.Get(bucket)
if err == nil {
bucketInfo.Created = meta.Created
bucketInfo.Versioning = meta.LockEnabled || globalBucketVersioningSys.Enabled(bucket)
bucketInfo.ObjectLocking = meta.LockEnabled
}
return bucketInfo, nil
}
// DeleteBucket - deletes a bucket on all serverPools simultaneously,
// even if one of the serverPools fail to delete buckets, we proceed to
// undo a successful operation.
func (z *erasureServerPools) DeleteBucket(ctx context.Context, bucket string, opts DeleteBucketOptions) error {
if isMinioMetaBucketName(bucket) {
return BucketNameInvalid{Bucket: bucket}
}
// Verify if bucket is valid.
if err := s3utils.CheckValidBucketName(bucket); err != nil {
return BucketNameInvalid{Bucket: bucket}
}
if !opts.NoLock {
// Lock the bucket name before creating.
lk := z.NewNSLock(minioMetaTmpBucket, bucket+".lck")
lkctx, err := lk.GetLock(ctx, globalOperationTimeout)
if err != nil {
return err
}
ctx = lkctx.Context()
defer lk.Unlock(lkctx)
}
err := z.s3Peer.DeleteBucket(ctx, bucket, opts)
if err == nil || errors.Is(err, errVolumeNotFound) {
// If site replication is configured, hold on to deleted bucket state until sites sync
if opts.SRDeleteOp == MarkDelete {
z.s3Peer.MakeBucket(context.Background(), pathJoin(minioMetaBucket, bucketMetaPrefix, deletedBucketsPrefix, bucket), MakeBucketOptions{})
}
}
if err != nil && !errors.Is(err, errVolumeNotFound) {
if !opts.NoRecreate {
z.s3Peer.MakeBucket(ctx, bucket, MakeBucketOptions{})
}
}
if err == nil {
// Purge the entire bucket metadata entirely.
z.deleteAll(context.Background(), minioMetaBucket, pathJoin(bucketMetaPrefix, bucket))
}
return toObjectErr(err, bucket)
}
// deleteAll will rename bucket+prefix unconditionally across all disks to
// minioMetaTmpDeletedBucket + unique uuid,
// Note that set distribution is ignored so it should only be used in cases where
// data is not distributed across sets. Errors are logged but individual
// disk failures are not returned.
func (z *erasureServerPools) deleteAll(ctx context.Context, bucket, prefix string) {
for _, servers := range z.serverPools {
for _, set := range servers.sets {
set.deleteAll(ctx, bucket, prefix)
}
}
}
// List all buckets from one of the serverPools, we are not doing merge
// sort here just for simplification. As per design it is assumed
// that all buckets are present on all serverPools.
func (z *erasureServerPools) ListBuckets(ctx context.Context, opts BucketOptions) (buckets []BucketInfo, err error) {
buckets, err = z.s3Peer.ListBuckets(ctx, opts)
if err != nil {
return nil, err
}
for i := range buckets {
createdAt, err := globalBucketMetadataSys.CreatedAt(buckets[i].Name)
if err == nil {
buckets[i].Created = createdAt
}
}
return buckets, nil
}
func (z *erasureServerPools) HealFormat(ctx context.Context, dryRun bool) (madmin.HealResultItem, error) {
// Acquire lock on format.json
formatLock := z.NewNSLock(minioMetaBucket, formatConfigFile)
lkctx, err := formatLock.GetLock(ctx, globalOperationTimeout)
if err != nil {
return madmin.HealResultItem{}, err
}
ctx = lkctx.Context()
defer formatLock.Unlock(lkctx)
r := madmin.HealResultItem{
Type: madmin.HealItemMetadata,
Detail: "disk-format",
}
var countNoHeal int
for _, pool := range z.serverPools {
result, err := pool.HealFormat(ctx, dryRun)
if err != nil && !errors.Is(err, errNoHealRequired) {
logger.LogIf(ctx, err)
continue
}
// Count errNoHealRequired across all serverPools,
// to return appropriate error to the caller
if errors.Is(err, errNoHealRequired) {
countNoHeal++
}
r.DiskCount += result.DiskCount
r.SetCount += result.SetCount
r.Before.Drives = append(r.Before.Drives, result.Before.Drives...)
r.After.Drives = append(r.After.Drives, result.After.Drives...)
}
// No heal returned by all serverPools, return errNoHealRequired
if countNoHeal == len(z.serverPools) {
return r, errNoHealRequired
}
return r, nil
}
func (z *erasureServerPools) HealBucket(ctx context.Context, bucket string, opts madmin.HealOpts) (madmin.HealResultItem, error) {
r := madmin.HealResultItem{
Type: madmin.HealItemBucket,
Bucket: bucket,
}
// Attempt heal on the bucket metadata, ignore any failures
hopts := opts
hopts.Recreate = false
defer z.HealObject(ctx, minioMetaBucket, pathJoin(bucketMetaPrefix, bucket, bucketMetadataFile), "", hopts)
for _, pool := range z.serverPools {
result, err := pool.HealBucket(ctx, bucket, opts)
if err != nil {
if _, ok := err.(BucketNotFound); ok {
continue
}
return result, err
}
r.DiskCount += result.DiskCount
r.SetCount += result.SetCount
r.Before.Drives = append(r.Before.Drives, result.Before.Drives...)
r.After.Drives = append(r.After.Drives, result.After.Drives...)
}
return r, nil
}
// Walk a bucket, optionally prefix recursively, until we have returned
// all the content to objectInfo channel, it is callers responsibility
// to allocate a receive channel for ObjectInfo, upon any unhandled
// error walker returns error. Optionally if context.Done() is received
// then Walk() stops the walker.
func (z *erasureServerPools) Walk(ctx context.Context, bucket, prefix string, results chan<- ObjectInfo, opts ObjectOptions) error {
if err := checkListObjsArgs(ctx, bucket, prefix, "", z); err != nil {
// Upon error close the channel.
close(results)
return err
}
vcfg, _ := globalBucketVersioningSys.Get(bucket)
ctx, cancel := context.WithCancel(ctx)
go func() {
defer cancel()
defer close(results)
for _, erasureSet := range z.serverPools {
var wg sync.WaitGroup
for _, set := range erasureSet.sets {
set := set
wg.Add(1)
go func() {
defer wg.Done()
disks, _ := set.getOnlineDisksWithHealing()
if len(disks) == 0 {
cancel()
return
}
loadEntry := func(entry metaCacheEntry) {
if entry.isDir() {
return
}
fivs, err := entry.fileInfoVersions(bucket)
if err != nil {
cancel()
return
}
versionsSorter(fivs.Versions).reverse()
for _, version := range fivs.Versions {
send := true
if opts.WalkFilter != nil && !opts.WalkFilter(version) {
send = false
}
if !send {
continue
}
versioned := vcfg != nil && vcfg.Versioned(version.Name)
objInfo := version.ToObjectInfo(bucket, version.Name, versioned)
select {
case <-ctx.Done():
return
case results <- objInfo:
}
}
}
// How to resolve partial results.
resolver := metadataResolutionParams{
dirQuorum: 1,
objQuorum: 1,
bucket: bucket,
}
path := baseDirFromPrefix(prefix)
filterPrefix := strings.Trim(strings.TrimPrefix(prefix, path), slashSeparator)
if path == prefix {
filterPrefix = ""
}
lopts := listPathRawOptions{
disks: disks,
bucket: bucket,
path: path,
filterPrefix: filterPrefix,
recursive: true,
forwardTo: opts.WalkMarker,
minDisks: 1,
reportNotFound: false,
agreed: loadEntry,
partial: func(entries metaCacheEntries, _ []error) {
entry, ok := entries.resolve(&resolver)
if !ok {
// check if we can get one entry atleast
// proceed to heal nonetheless.
entry, _ = entries.firstFound()
}
loadEntry(*entry)
},
finished: nil,
}
if err := listPathRaw(ctx, lopts); err != nil {
logger.LogIf(ctx, fmt.Errorf("listPathRaw returned %w: opts(%#v)", err, lopts))
cancel()
return
}
}()
}
wg.Wait()
}
}()
return nil
}
// HealObjectFn closure function heals the object.
type HealObjectFn func(bucket, object, versionID string) error
func listAndHeal(ctx context.Context, bucket, prefix string, set *erasureObjects, healEntry func(string, metaCacheEntry) error) error {
ctx, cancel := context.WithCancel(ctx)
defer cancel()
disks, _ := set.getOnlineDisksWithHealing()
if len(disks) == 0 {
return errors.New("listAndHeal: No non-healing drives found")
}
// How to resolve partial results.
resolver := metadataResolutionParams{
dirQuorum: 1,
objQuorum: 1,
bucket: bucket,
strict: false, // Allow less strict matching.
}
path := baseDirFromPrefix(prefix)
filterPrefix := strings.Trim(strings.TrimPrefix(prefix, path), slashSeparator)
if path == prefix {
filterPrefix = ""
}
lopts := listPathRawOptions{
disks: disks,
bucket: bucket,
path: path,
filterPrefix: filterPrefix,
recursive: true,
forwardTo: "",
minDisks: 1,
reportNotFound: false,
agreed: func(entry metaCacheEntry) {
if err := healEntry(bucket, entry); err != nil {
logger.LogIf(ctx, err)
cancel()
}
},
partial: func(entries metaCacheEntries, _ []error) {
entry, ok := entries.resolve(&resolver)
if !ok {
// check if we can get one entry atleast
// proceed to heal nonetheless.
entry, _ = entries.firstFound()
}
if err := healEntry(bucket, *entry); err != nil {
logger.LogIf(ctx, err)
cancel()
return
}
},
finished: nil,
}
if err := listPathRaw(ctx, lopts); err != nil {
return fmt.Errorf("listPathRaw returned %w: opts(%#v)", err, lopts)
}
return nil
}
func (z *erasureServerPools) HealObjects(ctx context.Context, bucket, prefix string, opts madmin.HealOpts, healObjectFn HealObjectFn) error {
healEntry := func(bucket string, entry metaCacheEntry) error {
if entry.isDir() {
return nil
}
// We might land at .metacache, .trash, .multipart
// no need to heal them skip, only when bucket
// is '.minio.sys'
if bucket == minioMetaBucket {
if wildcard.Match("buckets/*/.metacache/*", entry.name) {
return nil
}
if wildcard.Match("tmp/*", entry.name) {
return nil
}
if wildcard.Match("multipart/*", entry.name) {
return nil
}
if wildcard.Match("tmp-old/*", entry.name) {
return nil
}
}
fivs, err := entry.fileInfoVersions(bucket)
if err != nil {
return healObjectFn(bucket, entry.name, "")
}
if opts.Remove && !opts.DryRun {
err := z.CheckAbandonedParts(ctx, bucket, entry.name, opts)
if err != nil {
logger.LogIf(ctx, fmt.Errorf("unable to check object %s/%s for abandoned data: %w", bucket, entry.name, err))
}
}
for _, version := range fivs.Versions {
err := healObjectFn(bucket, version.Name, version.VersionID)
if err != nil && !isErrObjectNotFound(err) && !isErrVersionNotFound(err) {
return err
}
}
return nil
}
ctx, cancel := context.WithCancel(ctx)
defer cancel()
var poolErrs [][]error
for idx, erasureSet := range z.serverPools {
if z.IsSuspended(idx) {
continue
}
errs := make([]error, len(erasureSet.sets))
var wg sync.WaitGroup
for idx, set := range erasureSet.sets {
wg.Add(1)
go func(idx int, set *erasureObjects) {
defer wg.Done()
errs[idx] = listAndHeal(ctx, bucket, prefix, set, healEntry)
}(idx, set)
}
wg.Wait()
poolErrs = append(poolErrs, errs)
}
for _, errs := range poolErrs {
for _, err := range errs {
if err == nil {
continue
}
return err
}
}
return nil
}
func (z *erasureServerPools) HealObject(ctx context.Context, bucket, object, versionID string, opts madmin.HealOpts) (madmin.HealResultItem, error) {
object = encodeDirObject(object)
errs := make([]error, len(z.serverPools))
results := make([]madmin.HealResultItem, len(z.serverPools))
var wg sync.WaitGroup
for idx, pool := range z.serverPools {
if z.IsSuspended(idx) {
continue
}
wg.Add(1)
go func(idx int, pool *erasureSets) {
defer wg.Done()
result, err := pool.HealObject(ctx, bucket, object, versionID, opts)
result.Object = decodeDirObject(result.Object)
errs[idx] = err
results[idx] = result
}(idx, pool)
}
wg.Wait()
// Return the first nil error
for idx, err := range errs {
if err == nil {
return results[idx], nil
}
}
// No pool returned a nil error, return the first non 'not found' error
for idx, err := range errs {
if !isErrObjectNotFound(err) && !isErrVersionNotFound(err) {
return results[idx], err
}
}
// At this stage, all errors are 'not found'
if versionID != "" {
return madmin.HealResultItem{}, VersionNotFound{
Bucket: bucket,
Object: object,
VersionID: versionID,
}
}
return madmin.HealResultItem{}, ObjectNotFound{
Bucket: bucket,
Object: object,
}
}
func (z *erasureServerPools) getPoolAndSet(id string) (poolIdx, setIdx, diskIdx int, err error) {
for poolIdx := range z.serverPools {
format := z.serverPools[poolIdx].format
for setIdx, set := range format.Erasure.Sets {
for i, diskID := range set {
if diskID == id {
return poolIdx, setIdx, i, nil
}
}
}
}
return -1, -1, -1, fmt.Errorf("DriveID(%s) %w", id, errDiskNotFound)
}
// HealthOptions takes input options to return sepcific information
type HealthOptions struct {
Maintenance bool
}
// HealthResult returns the current state of the system, also
// additionally with any specific heuristic information which
// was queried
type HealthResult struct {
Healthy bool
HealingDrives int
PoolID, SetID int
WriteQuorum int
}
// ReadHealth returns if the cluster can serve read requests
func (z *erasureServerPools) ReadHealth(ctx context.Context) bool {
erasureSetUpCount := make([][]int, len(z.serverPools))
for i := range z.serverPools {
erasureSetUpCount[i] = make([]int, len(z.serverPools[i].sets))
}
diskIDs := globalNotificationSys.GetLocalDiskIDs(ctx)
diskIDs = append(diskIDs, getLocalDiskIDs(z))
for _, localDiskIDs := range diskIDs {
for _, id := range localDiskIDs {
poolIdx, setIdx, _, err := z.getPoolAndSet(id)
if err != nil {
logger.LogIf(ctx, err)
continue
}
erasureSetUpCount[poolIdx][setIdx]++
}
}
b := z.BackendInfo()
poolReadQuorums := make([]int, len(b.StandardSCData))
copy(poolReadQuorums, b.StandardSCData)
for poolIdx := range erasureSetUpCount {
for setIdx := range erasureSetUpCount[poolIdx] {
if erasureSetUpCount[poolIdx][setIdx] < poolReadQuorums[poolIdx] {
return false
}
}
}
return true
}
// Health - returns current status of the object layer health,
// provides if write access exists across sets, additionally
// can be used to query scenarios if health may be lost
// if this node is taken down by an external orchestrator.
func (z *erasureServerPools) Health(ctx context.Context, opts HealthOptions) HealthResult {
erasureSetUpCount := make([][]int, len(z.serverPools))
for i := range z.serverPools {
erasureSetUpCount[i] = make([]int, len(z.serverPools[i].sets))
}
diskIDs := globalNotificationSys.GetLocalDiskIDs(ctx)
if !opts.Maintenance {
diskIDs = append(diskIDs, getLocalDiskIDs(z))
}
for _, localDiskIDs := range diskIDs {
for _, id := range localDiskIDs {
poolIdx, setIdx, _, err := z.getPoolAndSet(id)
if err != nil {
logger.LogIf(ctx, err)
continue
}
erasureSetUpCount[poolIdx][setIdx]++
}
}
reqInfo := (&logger.ReqInfo{}).AppendTags("maintenance", strconv.FormatBool(opts.Maintenance))
b := z.BackendInfo()
poolWriteQuorums := make([]int, len(b.StandardSCData))
for i, data := range b.StandardSCData {
poolWriteQuorums[i] = data
if data == b.StandardSCParity {
poolWriteQuorums[i] = data + 1
}
}
var aggHealStateResult madmin.BgHealState
if opts.Maintenance {
// check if local disks are being healed, if they are being healed
// we need to tell healthy status as 'false' so that this server
// is not taken down for maintenance
var err error
aggHealStateResult, err = getAggregatedBackgroundHealState(ctx, nil)
if err != nil {
logger.LogIf(logger.SetReqInfo(ctx, reqInfo), fmt.Errorf("Unable to verify global heal status: %w", err))
return HealthResult{
Healthy: false,
}
}
if len(aggHealStateResult.HealDisks) > 0 {
logger.LogIf(logger.SetReqInfo(ctx, reqInfo), fmt.Errorf("Total drives to be healed %d", len(aggHealStateResult.HealDisks)))
}
}
for poolIdx := range erasureSetUpCount {
for setIdx := range erasureSetUpCount[poolIdx] {
if erasureSetUpCount[poolIdx][setIdx] < poolWriteQuorums[poolIdx] {
logger.LogIf(logger.SetReqInfo(ctx, reqInfo),
fmt.Errorf("Write quorum may be lost on pool: %d, set: %d, expected write quorum: %d",
poolIdx, setIdx, poolWriteQuorums[poolIdx]))
return HealthResult{
Healthy: false,
HealingDrives: len(aggHealStateResult.HealDisks),
PoolID: poolIdx,
SetID: setIdx,
WriteQuorum: poolWriteQuorums[poolIdx],
}
}
}
}
var maximumWriteQuorum int
for _, writeQuorum := range poolWriteQuorums {
if maximumWriteQuorum == 0 {
maximumWriteQuorum = writeQuorum
}
if writeQuorum > maximumWriteQuorum {
maximumWriteQuorum = writeQuorum
}
}
// when maintenance is not specified we don't have
// to look at the healing side of the code.
if !opts.Maintenance {
return HealthResult{
Healthy: true,
WriteQuorum: maximumWriteQuorum,
}
}
return HealthResult{
Healthy: len(aggHealStateResult.HealDisks) == 0,
HealingDrives: len(aggHealStateResult.HealDisks),
WriteQuorum: maximumWriteQuorum,
}
}
// PutObjectMetadata - replace or add tags to an existing object
func (z *erasureServerPools) PutObjectMetadata(ctx context.Context, bucket, object string, opts ObjectOptions) (ObjectInfo, error) {
object = encodeDirObject(object)
if z.SinglePool() {
return z.serverPools[0].PutObjectMetadata(ctx, bucket, object, opts)
}
// We don't know the size here set 1GiB atleast.
idx, err := z.getPoolIdxExistingWithOpts(ctx, bucket, object, opts)
if err != nil {
return ObjectInfo{}, err
}
return z.serverPools[idx].PutObjectMetadata(ctx, bucket, object, opts)
}
// PutObjectTags - replace or add tags to an existing object
func (z *erasureServerPools) PutObjectTags(ctx context.Context, bucket, object string, tags string, opts ObjectOptions) (ObjectInfo, error) {
object = encodeDirObject(object)
if z.SinglePool() {
return z.serverPools[0].PutObjectTags(ctx, bucket, object, tags, opts)
}
// We don't know the size here set 1GiB atleast.
idx, err := z.getPoolIdxExistingWithOpts(ctx, bucket, object, opts)
if err != nil {
return ObjectInfo{}, err
}
return z.serverPools[idx].PutObjectTags(ctx, bucket, object, tags, opts)
}
// DeleteObjectTags - delete object tags from an existing object
func (z *erasureServerPools) DeleteObjectTags(ctx context.Context, bucket, object string, opts ObjectOptions) (ObjectInfo, error) {
object = encodeDirObject(object)
if z.SinglePool() {
return z.serverPools[0].DeleteObjectTags(ctx, bucket, object, opts)
}
idx, err := z.getPoolIdxExistingWithOpts(ctx, bucket, object, opts)
if err != nil {
return ObjectInfo{}, err
}
return z.serverPools[idx].DeleteObjectTags(ctx, bucket, object, opts)
}
// GetObjectTags - get object tags from an existing object
func (z *erasureServerPools) GetObjectTags(ctx context.Context, bucket, object string, opts ObjectOptions) (*tags.Tags, error) {
object = encodeDirObject(object)
if z.SinglePool() {
return z.serverPools[0].GetObjectTags(ctx, bucket, object, opts)
}
idx, err := z.getPoolIdxExistingWithOpts(ctx, bucket, object, opts)
if err != nil {
return nil, err
}
return z.serverPools[idx].GetObjectTags(ctx, bucket, object, opts)
}
// TransitionObject - transition object content to target tier.
func (z *erasureServerPools) TransitionObject(ctx context.Context, bucket, object string, opts ObjectOptions) error {
object = encodeDirObject(object)
if z.SinglePool() {
return z.serverPools[0].TransitionObject(ctx, bucket, object, opts)
}
// Avoid transitioning an object from a pool being decommissioned.
opts.SkipDecommissioned = true
idx, err := z.getPoolIdxExistingWithOpts(ctx, bucket, object, opts)
if err != nil {
return err
}
return z.serverPools[idx].TransitionObject(ctx, bucket, object, opts)
}
// RestoreTransitionedObject - restore transitioned object content locally on this cluster.
func (z *erasureServerPools) RestoreTransitionedObject(ctx context.Context, bucket, object string, opts ObjectOptions) error {
object = encodeDirObject(object)
if z.SinglePool() {
return z.serverPools[0].RestoreTransitionedObject(ctx, bucket, object, opts)
}
// Avoid restoring object from a pool being decommissioned.
opts.SkipDecommissioned = true
idx, err := z.getPoolIdxExistingWithOpts(ctx, bucket, object, opts)
if err != nil {
return err
}
return z.serverPools[idx].RestoreTransitionedObject(ctx, bucket, object, opts)
}
func (z *erasureServerPools) CheckAbandonedParts(ctx context.Context, bucket, object string, opts madmin.HealOpts) error {
object = encodeDirObject(object)
if z.SinglePool() {
return z.serverPools[0].CheckAbandonedParts(ctx, bucket, object, opts)
}
errs := make([]error, len(z.serverPools))
var wg sync.WaitGroup
for idx, pool := range z.serverPools {
if z.IsSuspended(idx) {
continue
}
wg.Add(1)
go func(idx int, pool *erasureSets) {
defer wg.Done()
err := pool.CheckAbandonedParts(ctx, bucket, object, opts)
if err != nil && !isErrObjectNotFound(err) && !isErrVersionNotFound(err) {
errs[idx] = err
}
}(idx, pool)
}
wg.Wait()
for _, err := range errs {
return err
}
return nil
}
// DecomTieredObject - moves tiered object to another pool during decommissioning.
func (z *erasureServerPools) DecomTieredObject(ctx context.Context, bucket, object string, fi FileInfo, opts ObjectOptions) error {
object = encodeDirObject(object)
if z.SinglePool() {
return fmt.Errorf("error decommissioning %s/%s", bucket, object)
}
if !opts.NoLock {
ns := z.NewNSLock(bucket, object)
lkctx, err := ns.GetLock(ctx, globalOperationTimeout)
if err != nil {
return err
}
ctx = lkctx.Context()
defer ns.Unlock(lkctx)
opts.NoLock = true
}
idx, err := z.getPoolIdxNoLock(ctx, bucket, object, fi.Size)
if err != nil {
return err
}
return z.serverPools[idx].DecomTieredObject(ctx, bucket, object, fi, opts)
}
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