// Copyright (c) 2015-2023 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"
"net/url"
"runtime"
"sync"
"time"
"github.com/cespare/xxhash/v2"
"github.com/klauspost/compress/zip"
"github.com/minio/madmin-go/v3"
xioutil "github.com/minio/minio/internal/ioutil"
xnet "github.com/minio/pkg/v3/net"
"github.com/minio/pkg/v3/sync/errgroup"
"github.com/minio/pkg/v3/workers"
"github.com/minio/minio/internal/bucket/bandwidth"
"github.com/minio/minio/internal/logger"
)
// This file contains peer related notifications. For sending notifications to
// external systems, see event-notification.go
// NotificationSys - notification system.
type NotificationSys struct {
peerClients []*peerRESTClient // Excludes self
allPeerClients []*peerRESTClient // Includes nil client for self
}
// NotificationPeerErr returns error associated for a remote peer.
type NotificationPeerErr struct {
Host xnet.Host // Remote host on which the rpc call was initiated
Err error // Error returned by the remote peer for an rpc call
}
// A NotificationGroup is a collection of goroutines working on subtasks that are part of
// the same overall task.
//
// A zero NotificationGroup is valid and does not cancel on error.
type NotificationGroup struct {
workers *workers.Workers
errs []NotificationPeerErr
retryCount int
}
// WithNPeers returns a new NotificationGroup with length of errs slice upto nerrs,
// upon Wait() errors are returned collected from all tasks.
func WithNPeers(nerrs int) *NotificationGroup {
if nerrs <= 0 {
nerrs = 1
}
wk, _ := workers.New(nerrs)
return &NotificationGroup{errs: make([]NotificationPeerErr, nerrs), workers: wk, retryCount: 3}
}
// WithNPeersThrottled returns a new NotificationGroup with length of errs slice upto nerrs,
// upon Wait() errors are returned collected from all tasks, optionally allows for X workers
// only "per" parallel task.
func WithNPeersThrottled(nerrs, wks int) *NotificationGroup {
if nerrs <= 0 {
nerrs = 1
}
if wks > nerrs {
wks = nerrs
}
wk, _ := workers.New(wks)
return &NotificationGroup{errs: make([]NotificationPeerErr, nerrs), workers: wk, retryCount: 3}
}
// WithRetries sets the retry count for all function calls from the Go method.
func (g *NotificationGroup) WithRetries(retryCount int) *NotificationGroup {
if g != nil {
g.retryCount = retryCount
}
return g
}
// Wait blocks until all function calls from the Go method have returned, then
// returns the slice of errors from all function calls.
func (g *NotificationGroup) Wait() []NotificationPeerErr {
g.workers.Wait()
return g.errs
}
// Go calls the given function in a new goroutine.
//
// The first call to return a non-nil error will be
// collected in errs slice and returned by Wait().
func (g *NotificationGroup) Go(ctx context.Context, f func() error, index int, addr xnet.Host) {
r := rand.New(rand.NewSource(time.Now().UnixNano()))
g.workers.Take()
go func() {
defer g.workers.Give()
g.errs[index] = NotificationPeerErr{
Host: addr,
}
retryCount := g.retryCount
for i := 0; i < retryCount; i++ {
g.errs[index].Err = nil
if err := f(); err != nil {
g.errs[index].Err = err
if contextCanceled(ctx) {
// context already canceled no retries.
retryCount = 0
}
// Last iteration log the error.
if i == retryCount-1 {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", addr.String())
ctx := logger.SetReqInfo(ctx, reqInfo)
peersLogOnceIf(ctx, err, addr.String())
}
// Wait for a minimum of 100ms and dynamically increase this based on number of attempts.
if i < retryCount-1 {
time.Sleep(100*time.Millisecond + time.Duration(r.Float64()*float64(time.Second)))
continue
}
}
break
}
}()
}
// DeletePolicy - deletes policy across all peers.
func (sys *NotificationSys) DeletePolicy(ctx context.Context, policyName string) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
for idx, client := range sys.peerClients {
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
return client.DeletePolicy(ctx, policyName)
}, idx, *client.host)
}
return ng.Wait()
}
// LoadPolicy - reloads a specific modified policy across all peers
func (sys *NotificationSys) LoadPolicy(ctx context.Context, policyName string) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
for idx, client := range sys.peerClients {
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
return client.LoadPolicy(ctx, policyName)
}, idx, *client.host)
}
return ng.Wait()
}
// LoadPolicyMapping - reloads a policy mapping across all peers
func (sys *NotificationSys) LoadPolicyMapping(ctx context.Context, userOrGroup string, userType IAMUserType, isGroup bool) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
for idx, client := range sys.peerClients {
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
return client.LoadPolicyMapping(ctx, userOrGroup, userType, isGroup)
}, idx, *client.host)
}
return ng.Wait()
}
// DeleteUser - deletes a specific user across all peers
func (sys *NotificationSys) DeleteUser(ctx context.Context, accessKey string) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
for idx, client := range sys.peerClients {
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
return client.DeleteUser(ctx, accessKey)
}, idx, *client.host)
}
return ng.Wait()
}
// LoadUser - reloads a specific user across all peers
func (sys *NotificationSys) LoadUser(ctx context.Context, accessKey string, temp bool) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
for idx, client := range sys.peerClients {
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
return client.LoadUser(ctx, accessKey, temp)
}, idx, *client.host)
}
return ng.Wait()
}
// LoadGroup - loads a specific group on all peers.
func (sys *NotificationSys) LoadGroup(ctx context.Context, group string) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
for idx, client := range sys.peerClients {
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
return client.LoadGroup(ctx, group)
}, idx, *client.host)
}
return ng.Wait()
}
// DeleteServiceAccount - deletes a specific service account across all peers
func (sys *NotificationSys) DeleteServiceAccount(ctx context.Context, accessKey string) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
for idx, client := range sys.peerClients {
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
return client.DeleteServiceAccount(ctx, accessKey)
}, idx, *client.host)
}
return ng.Wait()
}
// LoadServiceAccount - reloads a specific service account across all peers
func (sys *NotificationSys) LoadServiceAccount(ctx context.Context, accessKey string) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
for idx, client := range sys.peerClients {
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
return client.LoadServiceAccount(ctx, accessKey)
}, idx, *client.host)
}
return ng.Wait()
}
// BackgroundHealStatus - returns background heal status of all peers
func (sys *NotificationSys) BackgroundHealStatus(ctx context.Context) ([]madmin.BgHealState, []NotificationPeerErr) {
ng := WithNPeers(len(sys.peerClients))
states := make([]madmin.BgHealState, len(sys.peerClients))
for idx, client := range sys.peerClients {
idx := idx
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
st, err := client.BackgroundHealStatus(ctx)
if err != nil {
return err
}
states[idx] = st
return nil
}, idx, *client.host)
}
return states, ng.Wait()
}
// StartProfiling - start profiling on remote peers, by initiating a remote RPC.
func (sys *NotificationSys) StartProfiling(ctx context.Context, profiler string) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.StartProfiling(ctx, profiler)
}, idx, *client.host)
}
return ng.Wait()
}
// DownloadProfilingData - download profiling data from all remote peers.
func (sys *NotificationSys) DownloadProfilingData(ctx context.Context, writer io.Writer) (profilingDataFound bool) {
// Initialize a zip writer which will provide a zipped content
// of profiling data of all nodes
zipWriter := zip.NewWriter(writer)
defer zipWriter.Close()
// Start by embedding cluster info.
if b := getClusterMetaInfo(ctx); len(b) > 0 {
internalLogIf(ctx, embedFileInZip(zipWriter, "cluster.info", b, 0o600))
}
// Profiles can be quite big, so we limit to max 16 concurrent downloads.
ng := WithNPeersThrottled(len(sys.peerClients), 16)
var writeMu sync.Mutex
for i, client := range sys.peerClients {
if client == nil {
continue
}
ng.Go(ctx, func() error {
// Give 15 seconds to each remote call.
// Errors are logged but not returned.
ctx, cancel := context.WithTimeout(ctx, 15*time.Second)
defer cancel()
data, err := client.DownloadProfileData(ctx)
if err != nil {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", client.host.String())
ctx := logger.SetReqInfo(ctx, reqInfo)
peersLogOnceIf(ctx, err, client.host.String())
return nil
}
for typ, data := range data {
// zip writer only handles one concurrent write
writeMu.Lock()
profilingDataFound = true
err := embedFileInZip(zipWriter, fmt.Sprintf("profile-%s-%s", client.host.String(), typ), data, 0o600)
writeMu.Unlock()
if err != nil {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", client.host.String())
ctx := logger.SetReqInfo(ctx, reqInfo)
peersLogOnceIf(ctx, err, client.host.String())
}
}
return nil
}, i, *client.host)
}
ng.Wait()
if ctx.Err() != nil {
return false
}
// Local host
thisAddr, err := xnet.ParseHost(globalLocalNodeName)
if err != nil {
bugLogIf(ctx, err)
return profilingDataFound
}
data, err := getProfileData()
if err != nil {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", thisAddr.String())
ctx := logger.SetReqInfo(ctx, reqInfo)
bugLogIf(ctx, err)
return profilingDataFound
}
profilingDataFound = true
// Send profiling data to zip as file
for typ, data := range data {
err := embedFileInZip(zipWriter, fmt.Sprintf("profile-%s-%s", thisAddr, typ), data, 0o600)
internalLogIf(ctx, err)
}
return
}
// VerifyBinary - asks remote peers to verify the checksum
func (sys *NotificationSys) VerifyBinary(ctx context.Context, u *url.URL, sha256Sum []byte, releaseInfo string, bin []byte) []NotificationPeerErr {
// FIXME: network calls made in this manner such as one goroutine per node,
// can easily eat into the internode bandwidth. This function would be mostly
// TX saturating, however there are situations where a RX might also saturate.
// To avoid these problems we must split the work at scale. With 1000 node
// setup becoming a reality we must try to shard the work properly such as
// pick 10 nodes that precisely can send those 100 requests the first node
// in the 10 node shard would coordinate between other 9 shards to get the
// rest of the `99*9` requests.
//
// This essentially splits the workload properly and also allows for network
// utilization to be optimal, instead of blindly throttling the way we are
// doing below. However the changes that are needed here are a bit involved,
// further discussion advised. Remove this comment and remove the worker model
// for this function in future.
maxWorkers := runtime.GOMAXPROCS(0) / 2
ng := WithNPeersThrottled(len(sys.peerClients), maxWorkers)
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.VerifyBinary(ctx, u, sha256Sum, releaseInfo, bytes.NewReader(bin))
}, idx, *client.host)
}
return ng.Wait()
}
// CommitBinary - asks remote peers to overwrite the old binary with the new one
func (sys *NotificationSys) CommitBinary(ctx context.Context) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.CommitBinary(ctx)
}, idx, *client.host)
}
return ng.Wait()
}
// SignalConfigReload reloads requested sub-system on a remote peer dynamically.
func (sys *NotificationSys) SignalConfigReload(subSys string) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(GlobalContext, func() error {
return client.SignalService(serviceReloadDynamic, subSys, false, nil)
}, idx, *client.host)
}
return ng.Wait()
}
// SignalService - calls signal service RPC call on all peers.
func (sys *NotificationSys) SignalService(sig serviceSignal) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(GlobalContext, func() error {
// force == true preserves the current behavior
return client.SignalService(sig, "", false, nil)
}, idx, *client.host)
}
return ng.Wait()
}
// SignalServiceV2 - calls signal service RPC call on all peers with v2 API
func (sys *NotificationSys) SignalServiceV2(sig serviceSignal, dryRun bool, execAt *time.Time) []NotificationPeerErr {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(GlobalContext, func() error {
return client.SignalService(sig, "", dryRun, execAt)
}, idx, *client.host)
}
return ng.Wait()
}
var errPeerNotReachable = errors.New("peer is not reachable")
// GetLocks - makes GetLocks RPC call on all peers.
func (sys *NotificationSys) GetLocks(ctx context.Context, r *http.Request) []*PeerLocks {
locksResp := make([]*PeerLocks, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
index := index
client := client
g.Go(func() error {
if client == nil {
return errPeerNotReachable
}
serverLocksResp, err := sys.peerClients[index].GetLocks(ctx)
if err != nil {
return err
}
locksResp[index] = &PeerLocks{
Addr: sys.peerClients[index].host.String(),
Locks: serverLocksResp,
}
return nil
}, index)
}
for index, err := range g.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress",
sys.peerClients[index].host.String())
ctx := logger.SetReqInfo(ctx, reqInfo)
peersLogOnceIf(ctx, err, sys.peerClients[index].host.String())
}
locksResp = append(locksResp, &PeerLocks{
Addr: getHostName(r),
Locks: globalLockServer.DupLockMap(),
})
return locksResp
}
// LoadBucketMetadata - calls LoadBucketMetadata call on all peers
func (sys *NotificationSys) LoadBucketMetadata(ctx context.Context, bucketName string) {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.LoadBucketMetadata(ctx, bucketName)
}, idx, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
}
// DeleteBucketMetadata - calls DeleteBucketMetadata call on all peers
func (sys *NotificationSys) DeleteBucketMetadata(ctx context.Context, bucketName string) {
globalReplicationStats.Load().Delete(bucketName)
globalBucketMetadataSys.Remove(bucketName)
globalBucketTargetSys.Delete(bucketName)
globalEventNotifier.RemoveNotification(bucketName)
globalBucketConnStats.delete(bucketName)
globalBucketHTTPStats.delete(bucketName)
if localMetacacheMgr != nil {
localMetacacheMgr.deleteBucketCache(bucketName)
}
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.DeleteBucketMetadata(ctx, bucketName)
}, idx, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
}
// GetClusterAllBucketStats - returns bucket stats for all buckets from all remote peers.
func (sys *NotificationSys) GetClusterAllBucketStats(ctx context.Context) []BucketStatsMap {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
replicationStats := make([]BucketStatsMap, len(sys.peerClients))
for index, client := range sys.peerClients {
index := index
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
bsMap, err := client.GetAllBucketStats(ctx)
if err != nil {
return err
}
replicationStats[index] = bsMap
return nil
}, index, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
replicationStatsList := globalReplicationStats.Load().GetAll()
bucketStatsMap := BucketStatsMap{
Stats: make(map[string]BucketStats, len(replicationStatsList)),
Timestamp: UTCNow(),
}
for k, replicationStats := range replicationStatsList {
bucketStatsMap.Stats[k] = BucketStats{
ReplicationStats: replicationStats,
ProxyStats: globalReplicationStats.Load().getProxyStats(k),
}
}
replicationStats = append(replicationStats, bucketStatsMap)
return replicationStats
}
// GetClusterBucketStats - calls GetClusterBucketStats call on all peers for a cluster statistics view.
func (sys *NotificationSys) GetClusterBucketStats(ctx context.Context, bucketName string) []BucketStats {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
bucketStats := make([]BucketStats, len(sys.peerClients))
for index, client := range sys.peerClients {
index := index
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
bs, err := client.GetBucketStats(ctx, bucketName)
if err != nil {
return err
}
bucketStats[index] = bs
return nil
}, index, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
if st := globalReplicationStats.Load(); st != nil {
bucketStats = append(bucketStats, BucketStats{
ReplicationStats: st.Get(bucketName),
QueueStats: ReplicationQueueStats{Nodes: []ReplQNodeStats{st.getNodeQueueStats(bucketName)}},
ProxyStats: st.getProxyStats(bucketName),
})
}
return bucketStats
}
// GetClusterSiteMetrics - calls GetClusterSiteMetrics call on all peers for a cluster statistics view.
func (sys *NotificationSys) GetClusterSiteMetrics(ctx context.Context) []SRMetricsSummary {
ng := WithNPeers(len(sys.peerClients)).WithRetries(1)
siteStats := make([]SRMetricsSummary, len(sys.peerClients))
for index, client := range sys.peerClients {
index := index
client := client
ng.Go(ctx, func() error {
if client == nil {
return errPeerNotReachable
}
sm, err := client.GetSRMetrics(ctx)
if err != nil {
return err
}
siteStats[index] = sm
return nil
}, index, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
siteStats = append(siteStats, globalReplicationStats.Load().getSRMetricsForNode())
return siteStats
}
// ReloadPoolMeta reloads on disk updates on pool metadata
func (sys *NotificationSys) ReloadPoolMeta(ctx context.Context) {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.ReloadPoolMeta(ctx)
}, idx, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
}
// DeleteUploadID notifies all the MinIO nodes to remove the
// given uploadID from cache
func (sys *NotificationSys) DeleteUploadID(ctx context.Context, uploadID string) {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.DeleteUploadID(ctx, uploadID)
}, idx, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
}
// StopRebalance notifies all MinIO nodes to signal any ongoing rebalance
// goroutine to stop.
func (sys *NotificationSys) StopRebalance(ctx context.Context) {
objAPI := newObjectLayerFn()
if objAPI == nil {
internalLogIf(ctx, errServerNotInitialized)
return
}
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.StopRebalance(ctx)
}, idx, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
if pools, ok := objAPI.(*erasureServerPools); ok {
pools.StopRebalance()
}
}
// LoadRebalanceMeta notifies all peers to load rebalance.bin from object layer.
// Note: Only peers participating in rebalance operation, namely the first node
// in each pool will load rebalance.bin.
func (sys *NotificationSys) LoadRebalanceMeta(ctx context.Context, startRebalance bool) {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.LoadRebalanceMeta(ctx, startRebalance)
}, idx, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
}
// LoadTransitionTierConfig notifies remote peers to load their remote tier
// configs from config store.
func (sys *NotificationSys) LoadTransitionTierConfig(ctx context.Context) {
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(ctx, func() error {
return client.LoadTransitionTierConfig(ctx)
}, idx, *client.host)
}
for _, nErr := range ng.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress", nErr.Host.String())
if nErr.Err != nil {
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), nErr.Err, nErr.Host.String())
}
}
}
// GetCPUs - Get all CPU information.
func (sys *NotificationSys) GetCPUs(ctx context.Context) []madmin.CPUs {
reply := make([]madmin.CPUs, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetCPUs(ctx)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
sys.addNodeErr(&reply[index], sys.peerClients[index], err)
}
}
return reply
}
// GetNetInfo - Network information
func (sys *NotificationSys) GetNetInfo(ctx context.Context) []madmin.NetInfo {
reply := make([]madmin.NetInfo, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetNetInfo(ctx)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
sys.addNodeErr(&reply[index], sys.peerClients[index], err)
}
}
return reply
}
// GetPartitions - Disk partition information
func (sys *NotificationSys) GetPartitions(ctx context.Context) []madmin.Partitions {
reply := make([]madmin.Partitions, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetPartitions(ctx)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
sys.addNodeErr(&reply[index], sys.peerClients[index], err)
}
}
return reply
}
// GetOSInfo - Get operating system's information
func (sys *NotificationSys) GetOSInfo(ctx context.Context) []madmin.OSInfo {
reply := make([]madmin.OSInfo, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetOSInfo(ctx)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
sys.addNodeErr(&reply[index], sys.peerClients[index], err)
}
}
return reply
}
// GetMetrics - Get metrics from all peers.
func (sys *NotificationSys) GetMetrics(ctx context.Context, t madmin.MetricType, opts collectMetricsOpts) []madmin.RealtimeMetrics {
reply := make([]madmin.RealtimeMetrics, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
host := client.host.String()
if len(opts.hosts) > 0 {
if _, ok := opts.hosts[host]; !ok {
continue
}
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetMetrics(ctx, t, opts)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
reply[index].Errors = []string{fmt.Sprintf("%s: %s (rpc)", sys.peerClients[index].String(), err.Error())}
}
}
return reply
}
// GetResourceMetrics - gets the resource metrics from all nodes excluding self.
func (sys *NotificationSys) GetResourceMetrics(ctx context.Context) <-chan MetricV2 {
if sys == nil {
return nil
}
g := errgroup.WithNErrs(len(sys.peerClients))
peerChannels := make([]<-chan MetricV2, len(sys.peerClients))
for index := range sys.peerClients {
index := index
g.Go(func() error {
if sys.peerClients[index] == nil {
return errPeerNotReachable
}
var err error
peerChannels[index], err = sys.peerClients[index].GetResourceMetrics(ctx)
return err
}, index)
}
return sys.collectPeerMetrics(ctx, peerChannels, g)
}
// GetSysConfig - Get information about system config
// (only the config that are of concern to minio)
func (sys *NotificationSys) GetSysConfig(ctx context.Context) []madmin.SysConfig {
reply := make([]madmin.SysConfig, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetSysConfig(ctx)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
sys.addNodeErr(&reply[index], sys.peerClients[index], err)
}
}
return reply
}
// GetSysServices - Get information about system services
// (only the services that are of concern to minio)
func (sys *NotificationSys) GetSysServices(ctx context.Context) []madmin.SysServices {
reply := make([]madmin.SysServices, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetSELinuxInfo(ctx)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
sys.addNodeErr(&reply[index], sys.peerClients[index], err)
}
}
return reply
}
func (sys *NotificationSys) addNodeErr(nodeInfo madmin.NodeInfo, peerClient *peerRESTClient, err error) {
addr := peerClient.host.String()
reqInfo := (&logger.ReqInfo{}).AppendTags("remotePeer", addr)
ctx := logger.SetReqInfo(GlobalContext, reqInfo)
peersLogOnceIf(ctx, err, "add-node-err-"+addr)
nodeInfo.SetAddr(addr)
nodeInfo.SetError(err.Error())
}
// GetSysErrors - Memory information
func (sys *NotificationSys) GetSysErrors(ctx context.Context) []madmin.SysErrors {
reply := make([]madmin.SysErrors, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetSysErrors(ctx)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
sys.addNodeErr(&reply[index], sys.peerClients[index], err)
}
}
return reply
}
// GetMemInfo - Memory information
func (sys *NotificationSys) GetMemInfo(ctx context.Context) []madmin.MemInfo {
reply := make([]madmin.MemInfo, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetMemInfo(ctx)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
sys.addNodeErr(&reply[index], sys.peerClients[index], err)
}
}
return reply
}
// GetProcInfo - Process information
func (sys *NotificationSys) GetProcInfo(ctx context.Context) []madmin.ProcInfo {
reply := make([]madmin.ProcInfo, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
index := index
g.Go(func() error {
var err error
reply[index], err = sys.peerClients[index].GetProcInfo(ctx)
return err
}, index)
}
for index, err := range g.Wait() {
if err != nil {
sys.addNodeErr(&reply[index], sys.peerClients[index], err)
}
}
return reply
}
// Construct a list of offline disks information for a given node.
// If offlineHost is empty, do it for the local disks.
func getOfflineDisks(offlineHost string, endpoints EndpointServerPools) []madmin.Disk {
var offlineDisks []madmin.Disk
for _, pool := range endpoints {
for _, ep := range pool.Endpoints {
if offlineHost == "" && ep.IsLocal || offlineHost == ep.Host {
offlineDisks = append(offlineDisks, madmin.Disk{
Endpoint: ep.String(),
State: string(madmin.ItemOffline),
PoolIndex: ep.PoolIdx,
SetIndex: ep.SetIdx,
DiskIndex: ep.DiskIdx,
})
}
}
}
return offlineDisks
}
// StorageInfo returns disk information across all peers
func (sys *NotificationSys) StorageInfo(ctx context.Context, objLayer ObjectLayer, metrics bool) StorageInfo {
var storageInfo StorageInfo
replies := make([]StorageInfo, len(sys.peerClients))
var wg sync.WaitGroup
for i, client := range sys.peerClients {
if client == nil {
continue
}
wg.Add(1)
go func(client *peerRESTClient, idx int) {
defer wg.Done()
info, err := client.LocalStorageInfo(ctx, metrics)
if err != nil {
info.Disks = getOfflineDisks(client.host.String(), globalEndpoints)
}
replies[idx] = info
}(client, i)
}
wg.Wait()
// Add local to this server.
replies = append(replies, objLayer.LocalStorageInfo(ctx, metrics))
storageInfo.Backend = objLayer.BackendInfo()
for _, sinfo := range replies {
storageInfo.Disks = append(storageInfo.Disks, sinfo.Disks...)
}
return storageInfo
}
// ServerInfo - calls ServerInfo RPC call on all peers.
func (sys *NotificationSys) ServerInfo(ctx context.Context, metrics bool) []madmin.ServerProperties {
reply := make([]madmin.ServerProperties, len(sys.peerClients))
var wg sync.WaitGroup
for i, client := range sys.peerClients {
if client == nil {
continue
}
wg.Add(1)
go func(client *peerRESTClient, idx int) {
defer wg.Done()
ctx, cancel := context.WithTimeout(ctx, 10*time.Second)
defer cancel()
info, err := client.ServerInfo(ctx, metrics)
if err != nil {
info.Endpoint = client.host.String()
info.State = string(madmin.ItemOffline)
info.Disks = getOfflineDisks(info.Endpoint, globalEndpoints)
}
reply[idx] = info
}(client, i)
}
wg.Wait()
return reply
}
// restClientFromHash will return a deterministic peerRESTClient based on s.
// Will return nil if client is local.
func (sys *NotificationSys) restClientFromHash(s string) (client *peerRESTClient) {
if len(sys.peerClients) == 0 {
return nil
}
peerClients := sys.allPeerClients
if len(peerClients) == 0 {
return nil
}
idx := xxhash.Sum64String(s) % uint64(len(peerClients))
return peerClients[idx]
}
// GetPeerOnlineCount gets the count of online and offline nodes.
func (sys *NotificationSys) GetPeerOnlineCount() (nodesOnline, nodesOffline int) {
nodesOnline = 1 // Self is always online.
nodesOffline = 0
nodesOnlineIndex := make([]bool, len(sys.peerClients))
var wg sync.WaitGroup
for idx, client := range sys.peerClients {
if client == nil {
continue
}
wg.Add(1)
go func(idx int, client *peerRESTClient) {
defer wg.Done()
nodesOnlineIndex[idx] = client.restClient.HealthCheckFn()
}(idx, client)
}
wg.Wait()
for _, online := range nodesOnlineIndex {
if online {
nodesOnline++
} else {
nodesOffline++
}
}
return
}
// NewNotificationSys - creates new notification system object.
func NewNotificationSys(endpoints EndpointServerPools) *NotificationSys {
remote, all := newPeerRestClients(endpoints)
return &NotificationSys{
peerClients: remote,
allPeerClients: all,
}
}
// GetBandwidthReports - gets the bandwidth report from all nodes including self.
func (sys *NotificationSys) GetBandwidthReports(ctx context.Context, buckets ...string) bandwidth.BucketBandwidthReport {
reports := make([]*bandwidth.BucketBandwidthReport, len(sys.peerClients))
g := errgroup.WithNErrs(len(sys.peerClients))
for index := range sys.peerClients {
if sys.peerClients[index] == nil {
continue
}
index := index
g.Go(func() error {
var err error
reports[index], err = sys.peerClients[index].MonitorBandwidth(ctx, buckets)
return err
}, index)
}
for index, err := range g.Wait() {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress",
sys.peerClients[index].host.String())
ctx := logger.SetReqInfo(ctx, reqInfo)
peersLogOnceIf(ctx, err, sys.peerClients[index].host.String())
}
reports = append(reports, globalBucketMonitor.GetReport(bandwidth.SelectBuckets(buckets...)))
consolidatedReport := bandwidth.BucketBandwidthReport{
BucketStats: make(map[bandwidth.BucketOptions]bandwidth.Details),
}
for _, report := range reports {
if report == nil || report.BucketStats == nil {
continue
}
for opts := range report.BucketStats {
d, ok := consolidatedReport.BucketStats[opts]
if !ok {
d = bandwidth.Details{
LimitInBytesPerSecond: report.BucketStats[opts].LimitInBytesPerSecond,
}
}
dt, ok := report.BucketStats[opts]
if ok {
d.CurrentBandwidthInBytesPerSecond += dt.CurrentBandwidthInBytesPerSecond
}
consolidatedReport.BucketStats[opts] = d
}
}
return consolidatedReport
}
func (sys *NotificationSys) collectPeerMetrics(ctx context.Context, peerChannels []<-chan MetricV2, g *errgroup.Group) <-chan MetricV2 {
ch := make(chan MetricV2)
var wg sync.WaitGroup
for index, err := range g.Wait() {
if err != nil {
if sys.peerClients[index] != nil {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress",
sys.peerClients[index].host.String())
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), err, sys.peerClients[index].host.String())
} else {
peersLogOnceIf(ctx, err, "peer-offline")
}
continue
}
wg.Add(1)
go func(ctx context.Context, peerChannel <-chan MetricV2, wg *sync.WaitGroup) {
defer wg.Done()
for {
select {
case m, ok := <-peerChannel:
if !ok {
return
}
select {
case ch <- m:
case <-ctx.Done():
return
}
case <-ctx.Done():
return
}
}
}(ctx, peerChannels[index], &wg)
}
go func(wg *sync.WaitGroup, ch chan MetricV2) {
wg.Wait()
xioutil.SafeClose(ch)
}(&wg, ch)
return ch
}
// GetBucketMetrics - gets the cluster level bucket metrics from all nodes excluding self.
func (sys *NotificationSys) GetBucketMetrics(ctx context.Context) <-chan MetricV2 {
if sys == nil {
return nil
}
g := errgroup.WithNErrs(len(sys.peerClients))
peerChannels := make([]<-chan MetricV2, len(sys.peerClients))
for index := range sys.peerClients {
index := index
g.Go(func() error {
if sys.peerClients[index] == nil {
return errPeerNotReachable
}
var err error
peerChannels[index], err = sys.peerClients[index].GetPeerBucketMetrics(ctx)
return err
}, index)
}
return sys.collectPeerMetrics(ctx, peerChannels, g)
}
// GetClusterMetrics - gets the cluster metrics from all nodes excluding self.
func (sys *NotificationSys) GetClusterMetrics(ctx context.Context) <-chan MetricV2 {
if sys == nil {
return nil
}
g := errgroup.WithNErrs(len(sys.peerClients))
peerChannels := make([]<-chan MetricV2, len(sys.peerClients))
for index := range sys.peerClients {
index := index
g.Go(func() error {
if sys.peerClients[index] == nil {
return errPeerNotReachable
}
var err error
peerChannels[index], err = sys.peerClients[index].GetPeerMetrics(ctx)
return err
}, index)
}
return sys.collectPeerMetrics(ctx, peerChannels, g)
}
// ServiceFreeze freezes all S3 API calls when 'freeze' is true,
// 'freeze' is 'false' would resume all S3 API calls again.
// NOTE: once a tenant is frozen either two things needs to
// happen before resuming normal operations.
// - Server needs to be restarted 'mc admin service restart'
// - 'freeze' should be set to 'false' for this call
// to resume normal operations.
func (sys *NotificationSys) ServiceFreeze(ctx context.Context, freeze bool) []NotificationPeerErr {
serviceSig := serviceUnFreeze
if freeze {
serviceSig = serviceFreeze
}
ng := WithNPeers(len(sys.peerClients))
for idx, client := range sys.peerClients {
if client == nil {
continue
}
client := client
ng.Go(GlobalContext, func() error {
return client.SignalService(serviceSig, "", false, nil)
}, idx, *client.host)
}
nerrs := ng.Wait()
if freeze {
freezeServices()
} else {
unfreezeServices()
}
return nerrs
}
// Netperf - perform mesh style network throughput test
func (sys *NotificationSys) Netperf(ctx context.Context, duration time.Duration) []madmin.NetperfNodeResult {
length := len(sys.allPeerClients)
if length == 0 {
// For single node erasure setup.
return nil
}
results := make([]madmin.NetperfNodeResult, length)
scheme := "http"
if globalIsTLS {
scheme = "https"
}
var wg sync.WaitGroup
for index := range sys.peerClients {
if sys.peerClients[index] == nil {
continue
}
wg.Add(1)
go func(index int) {
defer wg.Done()
r, err := sys.peerClients[index].Netperf(ctx, duration)
u := &url.URL{
Scheme: scheme,
Host: sys.peerClients[index].host.String(),
}
if err != nil {
results[index].Error = err.Error()
} else {
results[index] = r
}
results[index].Endpoint = u.String()
}(index)
}
wg.Add(1)
go func() {
defer wg.Done()
r := netperf(ctx, duration)
u := &url.URL{
Scheme: scheme,
Host: globalLocalNodeName,
}
results[len(results)-1] = r
results[len(results)-1].Endpoint = u.String()
}()
wg.Wait()
return results
}
// SpeedTest run GET/PUT tests at input concurrency for requested object size,
// optionally you can extend the tests longer with time.Duration.
func (sys *NotificationSys) SpeedTest(ctx context.Context, sopts speedTestOpts) []SpeedTestResult {
length := len(sys.allPeerClients)
if length == 0 {
// For single node erasure setup.
length = 1
}
results := make([]SpeedTestResult, length)
scheme := "http"
if globalIsTLS {
scheme = "https"
}
var wg sync.WaitGroup
for index := range sys.peerClients {
if sys.peerClients[index] == nil {
continue
}
wg.Add(1)
go func(index int) {
defer wg.Done()
r, err := sys.peerClients[index].SpeedTest(ctx, sopts)
u := &url.URL{
Scheme: scheme,
Host: sys.peerClients[index].host.String(),
}
if err != nil {
results[index].Error = err.Error()
} else {
results[index] = r
}
results[index].Endpoint = u.String()
}(index)
}
wg.Add(1)
go func() {
defer wg.Done()
r, err := selfSpeedTest(ctx, sopts)
u := &url.URL{
Scheme: scheme,
Host: globalLocalNodeName,
}
if err != nil {
results[len(results)-1].Error = err.Error()
} else {
results[len(results)-1] = r
}
results[len(results)-1].Endpoint = u.String()
}()
wg.Wait()
return results
}
// DriveSpeedTest - Drive performance information
func (sys *NotificationSys) DriveSpeedTest(ctx context.Context, opts madmin.DriveSpeedTestOpts) chan madmin.DriveSpeedTestResult {
ch := make(chan madmin.DriveSpeedTestResult)
var wg sync.WaitGroup
for _, client := range sys.peerClients {
if client == nil {
continue
}
wg.Add(1)
go func(client *peerRESTClient) {
defer wg.Done()
resp, err := client.DriveSpeedTest(ctx, opts)
if err != nil {
resp.Error = err.Error()
}
select {
case <-ctx.Done():
case ch <- resp:
}
reqInfo := (&logger.ReqInfo{}).AppendTags("remotePeer", client.host.String())
ctx := logger.SetReqInfo(GlobalContext, reqInfo)
peersLogOnceIf(ctx, err, client.host.String())
}(client)
}
wg.Add(1)
go func() {
defer wg.Done()
select {
case <-ctx.Done():
case ch <- driveSpeedTest(ctx, opts):
}
}()
go func(wg *sync.WaitGroup, ch chan madmin.DriveSpeedTestResult) {
wg.Wait()
xioutil.SafeClose(ch)
}(&wg, ch)
return ch
}
// ReloadSiteReplicationConfig - tells all peer minio nodes to reload the
// site-replication configuration.
func (sys *NotificationSys) ReloadSiteReplicationConfig(ctx context.Context) []error {
errs := make([]error, len(sys.allPeerClients))
var wg sync.WaitGroup
for index := range sys.peerClients {
if sys.peerClients[index] == nil {
continue
}
wg.Add(1)
go func(index int) {
defer wg.Done()
errs[index] = sys.peerClients[index].ReloadSiteReplicationConfig(ctx)
}(index)
}
wg.Wait()
return errs
}
// GetLastDayTierStats fetches per-tier stats of the last 24hrs from all peers
func (sys *NotificationSys) GetLastDayTierStats(ctx context.Context) DailyAllTierStats {
errs := make([]error, len(sys.allPeerClients))
lastDayStats := make([]DailyAllTierStats, len(sys.allPeerClients))
var wg sync.WaitGroup
for index := range sys.peerClients {
if sys.peerClients[index] == nil {
continue
}
wg.Add(1)
go func(index int) {
defer wg.Done()
lastDayStats[index], errs[index] = sys.peerClients[index].GetLastDayTierStats(ctx)
}(index)
}
wg.Wait()
merged := globalTransitionState.getDailyAllTierStats()
for i, stat := range lastDayStats {
if errs[i] != nil {
peersLogOnceIf(ctx, fmt.Errorf("failed to fetch last day tier stats: %w", errs[i]), sys.peerClients[i].host.String())
continue
}
merged.merge(stat)
}
return merged
}
// GetReplicationMRF - Get replication MRF from all peers.
func (sys *NotificationSys) GetReplicationMRF(ctx context.Context, bucket, node string) (mrfCh chan madmin.ReplicationMRF, err error) {
g := errgroup.WithNErrs(len(sys.peerClients))
peerChannels := make([]<-chan madmin.ReplicationMRF, len(sys.peerClients))
for index, client := range sys.peerClients {
if client == nil {
continue
}
host := client.host.String()
if host != node && node != "all" {
continue
}
index := index
g.Go(func() error {
var err error
peerChannels[index], err = sys.peerClients[index].GetReplicationMRF(ctx, bucket)
return err
}, index)
}
mrfCh = make(chan madmin.ReplicationMRF, 4000)
var wg sync.WaitGroup
for index, err := range g.Wait() {
if err != nil {
if sys.peerClients[index] != nil {
reqInfo := (&logger.ReqInfo{}).AppendTags("peerAddress",
sys.peerClients[index].host.String())
peersLogOnceIf(logger.SetReqInfo(ctx, reqInfo), err, sys.peerClients[index].host.String())
} else {
peersLogOnceIf(ctx, err, "peer-offline")
}
continue
}
wg.Add(1)
go func(ctx context.Context, peerChannel <-chan madmin.ReplicationMRF, wg *sync.WaitGroup) {
defer wg.Done()
for {
select {
case m, ok := <-peerChannel:
if !ok {
return
}
select {
case <-ctx.Done():
return
case mrfCh <- m:
}
case <-ctx.Done():
return
}
}
}(ctx, peerChannels[index], &wg)
}
wg.Add(1)
go func(ch chan madmin.ReplicationMRF) error {
defer wg.Done()
if node != "all" && node != globalLocalNodeName {
return nil
}
mCh, err := globalReplicationPool.Get().getMRF(ctx, bucket)
if err != nil {
return err
}
for e := range mCh {
select {
case <-ctx.Done():
return err
case mrfCh <- e:
}
}
return nil
}(mrfCh)
go func(wg *sync.WaitGroup) {
wg.Wait()
xioutil.SafeClose(mrfCh)
}(&wg)
return mrfCh, nil
}