minio/cmd/erasure-server-pool.go
Harshavardhana c3d70e0795
cache usage, prefix-usage, and buckets for AccountInfo up to 10 secs (#18051)
AccountInfo is quite frequently called by the Console UI 
login attempts, when many users are logging in it is important
that we provide them with better responsiveness.

- ListBuckets information is cached every second
- Bucket usage info is cached for up to 10 seconds
- Prefix usage (optional) info is cached for up to 10 secs

Failure to update after cache expiration, would still
allow login which would end up providing information
previously cached.

This allows for seamless responsiveness for the Console UI
logins, and overall responsiveness on a heavily loaded
system.
2023-09-18 22:13:03 -07:00

2466 lines
72 KiB
Go

// 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/v3"
"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/pkg/v2/sync/errgroup"
"github.com/minio/pkg/v2/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))
// initialize the object layer.
setObjectLayer(z)
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 disks belonging to the poolIdx, and setIdx.
func (z *erasureServerPools) GetDisks(poolIdx, setIdx int) ([]StorageAPI, error) {
if poolIdx < len(z.serverPools) && setIdx < len(z.serverPools[poolIdx].sets) {
return z.serverPools[poolIdx].sets[setIdx].getDisks(), nil
}
return nil, fmt.Errorf("Matching pool %s, set %s not found", humanize.Ordinal(poolIdx+1), humanize.Ordinal(setIdx+1))
}
// 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 // in bytes
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.Available > 0 && 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.Available > 0 && 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 {
if zinfo == nil {
serverPools[i] = poolAvailableSpace{Index: i}
continue
}
var available uint64
if !isMinioMetaBucketName(bucket) {
if avail, err := hasSpaceFor(zinfo, size); err != nil || !avail {
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.
if !opts.MetadataChg {
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 opts.SkipDecommissioned && z.IsSuspended(pinfo.Index) {
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 {
// found a pool
return pinfo, nil
}
if isErrReadQuorum(pinfo.Err) && !opts.MetadataChg {
// read quorum is returned when the object is visibly
// present but its unreadable, we simply ask the writes to
// schedule to this pool instead. If there is no quorum
// it will fail anyways, however if there is quorum available
// with enough disks online but sufficiently inconsistent to
// break parity threshold, allow them to be overwritten
// or allow new versions to be added.
return pinfo, nil
}
defPool = pinfo
if !isErrObjectNotFound(pinfo.Err) {
return pinfo, pinfo.Err
}
// No object exists or its a delete marker,
// check objInfo to confirm.
if pinfo.ObjInfo.DeleteMarker && pinfo.ObjInfo.Name != "" {
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
}
// 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, 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, opts)
}
var unlockOnDefer bool
nsUnlocker := func() {}
defer func() {
if unlockOnDefer {
nsUnlocker()
}
}()
// Acquire lock
if !opts.NoLock {
lock := z.NewNSLock(bucket, object)
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{}
}
opts.NoLock = true
gr, err = z.serverPools[zIdx].GetObjectNInfo(ctx, bucket, object, rs, h, opts)
if err != nil {
return nil, err
}
if unlockOnDefer {
unlockOnDefer = gr.ObjInfo.Inlined
}
if !unlockOnDefer {
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) {
avail, err := hasSpaceFor(getDiskInfos(ctx, z.serverPools[0].getHashedSet(object).getDisks()...), data.Size())
if err != nil {
logger.LogOnceIf(ctx, err, "erasure-write-quorum")
return ObjectInfo{}, toObjectErr(errErasureWriteQuorum)
}
if !avail {
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 { // DeletePrefix handles dir object encoding differently.
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)
if opts.DeletePrefix {
return ObjectInfo{}, z.deletePrefix(ctx, bucket, object)
}
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 contextCanceled(ctx) {
return ListObjectVersionsInfo{}, ctx.Err()
}
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 && 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, lcEventSrc_s3ListObjects)
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
}
if contextCanceled(ctx) {
return ListObjectsInfo{}, ctx.Err()
}
}
merged, err := z.listPath(ctx, &opts)
if err != nil && err != io.EOF {
if !isErrBucketNotFound(err) {
logger.LogOnceIf(ctx, err, "erasure-list-objects-path-"+bucket)
}
return loi, err
}
merged.forwardPast(opts.Marker)
defer merged.truncate(0) // Release when returning
if contextCanceled(ctx) {
return ListObjectsInfo{}, ctx.Err()
}
// 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) {
avail, err := hasSpaceFor(getDiskInfos(ctx, z.serverPools[0].getHashedSet(object).getDisks()...), -1)
if err != nil {
logger.LogIf(ctx, err)
return nil, toObjectErr(errErasureWriteQuorum)
}
if !avail {
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,
srcInfo.PutObjReader, 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, uploadID, 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, uploadID, 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, uploadID, 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, uploadID, 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, uploadID, 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.Versioning()
bucketInfo.ObjectLocking = meta.ObjectLocking()
}
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 || isErrBucketNotFound(err) {
// 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 && !isErrBucketNotFound(err) {
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)
}
}
}
var listBucketsCache timedValue
// 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) {
if opts.Cached {
listBucketsCache.Once.Do(func() {
listBucketsCache.TTL = time.Second
listBucketsCache.Relax = true
listBucketsCache.Update = func() (interface{}, error) {
ctx, cancel := context.WithTimeout(context.Background(), 5*time.Second)
buckets, err = z.s3Peer.ListBuckets(ctx, opts)
cancel()
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
}
})
v, _ := listBucketsCache.Get()
if v != nil {
return v.([]BucketInfo), nil
}
return buckets, nil
}
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.LogOnceIf(ctx, err, "erasure-heal-format")
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
}
send := func(objInfo ObjectInfo) bool {
select {
case <-ctx.Done():
return false
case results <- objInfo:
return true
}
}
askDisks := getListQuorum(opts.WalkAskDisks, set.setDriveCount)
var fallbackDisks []StorageAPI
// Special case: ask all disks if the drive count is 4
if set.setDriveCount == 4 || askDisks > len(disks) {
askDisks = len(disks) // use all available drives
}
if askDisks > 0 && len(disks) > askDisks {
fallbackDisks = disks[askDisks:]
disks = disks[:askDisks]
}
requestedVersions := 0
if opts.WalkLatestOnly {
requestedVersions = 1
}
loadEntry := func(entry metaCacheEntry) {
if entry.isDir() {
return
}
if opts.WalkLatestOnly {
fi, err := entry.fileInfo(bucket)
if err != nil {
cancel()
return
}
if opts.WalkFilter != nil {
if opts.WalkFilter(fi) {
if !send(fi.ToObjectInfo(bucket, fi.Name, vcfg != nil && vcfg.Versioned(fi.Name))) {
return
}
}
} else {
if !send(fi.ToObjectInfo(bucket, fi.Name, vcfg != nil && vcfg.Versioned(fi.Name))) {
return
}
}
} else {
fivs, err := entry.fileInfoVersions(bucket)
if err != nil {
cancel()
return
}
versionsSorter(fivs.Versions).reverse()
for _, version := range fivs.Versions {
if opts.WalkFilter != nil {
if opts.WalkFilter(version) {
if !send(version.ToObjectInfo(bucket, version.Name, vcfg != nil && vcfg.Versioned(version.Name))) {
return
}
}
} else {
if !send(version.ToObjectInfo(bucket, version.Name, vcfg != nil && vcfg.Versioned(version.Name))) {
return
}
}
}
}
}
// How to resolve partial results.
resolver := metadataResolutionParams{
dirQuorum: 1,
objQuorum: 1,
bucket: bucket,
requestedVersions: requestedVersions,
}
path := baseDirFromPrefix(prefix)
filterPrefix := strings.Trim(strings.TrimPrefix(prefix, path), slashSeparator)
if path == prefix {
filterPrefix = ""
}
lopts := listPathRawOptions{
disks: disks,
fallbackDisks: fallbackDisks,
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 (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] = set.listAndHeal(bucket, prefix, 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)
}
const (
vmware = "VMWare"
)
// HealthOptions takes input options to return sepcific information
type HealthOptions struct {
Maintenance bool
DeploymentType string
}
// 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
UnhealthyPools []struct {
Maintenance bool
PoolID, SetID int
WriteQuorum int
}
WriteQuorum int
UsingDefaults bool
}
// 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
// Check if disks are healing on in-case of VMware vsphere deployments.
if opts.Maintenance && opts.DeploymentType == vmware {
// 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)))
}
}
var usingDefaults bool
if globalStorageClass.GetParityForSC(storageclass.STANDARD) < 0 {
usingDefaults = true
}
var maximumWriteQuorum int
for _, writeQuorum := range poolWriteQuorums {
if maximumWriteQuorum == 0 {
maximumWriteQuorum = writeQuorum
}
if writeQuorum > maximumWriteQuorum {
maximumWriteQuorum = writeQuorum
}
}
result := HealthResult{
HealingDrives: len(aggHealStateResult.HealDisks),
WriteQuorum: maximumWriteQuorum,
UsingDefaults: usingDefaults, // indicates if config was not initialized and we are using defaults on this node.
}
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]))
result.UnhealthyPools = append(result.UnhealthyPools, struct {
Maintenance bool
PoolID, SetID, WriteQuorum int
}{
Maintenance: opts.Maintenance,
SetID: setIdx,
PoolID: poolIdx,
WriteQuorum: poolWriteQuorums[poolIdx],
})
}
}
if len(result.UnhealthyPools) > 0 {
// We have unhealthy pools return error.
return result
}
}
// 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,
UsingDefaults: usingDefaults, // indicates if config was not initialized and we are using defaults on this node.
}
}
return HealthResult{
Healthy: len(aggHealStateResult.HealDisks) == 0,
HealingDrives: len(aggHealStateResult.HealDisks),
WriteQuorum: maximumWriteQuorum,
UsingDefaults: usingDefaults, // indicates if config was not initialized and we are using defaults on this node.
}
}
// 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)
}
opts.MetadataChg = true
// 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)
}
opts.MetadataChg = true
// 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)
}
opts.MetadataChg = true
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)
}