minio/cmd/metrics-resource.go
Anis Eleuch b7f319b62a
properly reload a fresh drive when found in a failed state during startup (#20145)
When a drive is in a failed state when a single node multiple drives
deployment is started, a replacement of a fresh disk will not be
properly healed unless the user restarts the node.

Fix this by always adding the new fresh disk to globalLocalDrivesMap. Also
remove globalLocalDrives for simplification, a map to store local node
drives can still be used since the order of local drives of a node is
not defined.
2024-07-24 16:30:33 -07:00

494 lines
17 KiB
Go

// 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 (
"context"
"fmt"
"math"
"net/http"
"sync"
"time"
"github.com/minio/madmin-go/v3"
"github.com/prometheus/client_golang/prometheus"
)
const (
resourceMetricsCollectionInterval = time.Minute
resourceMetricsCacheInterval = time.Minute
// drive stats
totalInodes MetricName = "total_inodes"
readsPerSec MetricName = "reads_per_sec"
writesPerSec MetricName = "writes_per_sec"
readsKBPerSec MetricName = "reads_kb_per_sec"
writesKBPerSec MetricName = "writes_kb_per_sec"
readsAwait MetricName = "reads_await"
writesAwait MetricName = "writes_await"
percUtil MetricName = "perc_util"
usedInodes MetricName = "used_inodes"
// network stats
interfaceRxBytes MetricName = "rx_bytes"
interfaceRxErrors MetricName = "rx_errors"
interfaceTxBytes MetricName = "tx_bytes"
interfaceTxErrors MetricName = "tx_errors"
// cpu stats
cpuUser MetricName = "user"
cpuSystem MetricName = "system"
cpuIOWait MetricName = "iowait"
cpuIdle MetricName = "idle"
cpuNice MetricName = "nice"
cpuSteal MetricName = "steal"
cpuLoad1 MetricName = "load1"
cpuLoad5 MetricName = "load5"
cpuLoad15 MetricName = "load15"
cpuLoad1Perc MetricName = "load1_perc"
cpuLoad5Perc MetricName = "load5_perc"
cpuLoad15Perc MetricName = "load15_perc"
)
var (
resourceCollector *minioResourceCollector
// resourceMetricsMap is a map of subsystem to its metrics
resourceMetricsMap map[MetricSubsystem]ResourceMetrics
resourceMetricsMapMu sync.RWMutex
// resourceMetricsHelpMap maps metric name to its help string
resourceMetricsHelpMap map[MetricName]string
resourceMetricsGroups []*MetricsGroupV2
// initial values for drives (at the time of server startup)
// used for calculating avg values for drive metrics
latestDriveStats map[string]madmin.DiskIOStats
latestDriveStatsMu sync.RWMutex
lastDriveStatsRefresh time.Time
)
// PeerResourceMetrics represents the resource metrics
// retrieved from a peer, along with errors if any
type PeerResourceMetrics struct {
Metrics map[MetricSubsystem]ResourceMetrics
Errors []string
}
// ResourceMetrics is a map of unique key identifying
// a resource metric (e.g. reads_per_sec_{node}_{drive})
// to its data
type ResourceMetrics map[string]ResourceMetric
// ResourceMetric represents a single resource metric
// The metrics are collected from all servers periodically
// and stored in the resource metrics map.
// It also maintains the count of number of times this metric
// was collected since the server started, and the sum,
// average and max values across the same.
type ResourceMetric struct {
Name MetricName
Labels map[string]string
// value captured in current cycle
Current float64
// Used when system provides cumulative (since uptime) values
// helps in calculating the current value by comparing the new
// cumulative value with previous one
Cumulative float64
Max float64
Avg float64
Sum float64
Count uint64
}
func init() {
interval := fmt.Sprintf("%ds", int(resourceMetricsCollectionInterval.Seconds()))
resourceMetricsHelpMap = map[MetricName]string{
interfaceRxBytes: "Bytes received on the interface in " + interval,
interfaceRxErrors: "Receive errors in " + interval,
interfaceTxBytes: "Bytes transmitted in " + interval,
interfaceTxErrors: "Transmit errors in " + interval,
total: "Total memory on the node",
memUsed: "Used memory on the node",
memUsedPerc: "Used memory percentage on the node",
memFree: "Free memory on the node",
memShared: "Shared memory on the node",
memBuffers: "Buffers memory on the node",
memCache: "Cache memory on the node",
memAvailable: "Available memory on the node",
readsPerSec: "Reads per second on a drive",
writesPerSec: "Writes per second on a drive",
readsKBPerSec: "Kilobytes read per second on a drive",
writesKBPerSec: "Kilobytes written per second on a drive",
readsAwait: "Average time for read requests to be served on a drive",
writesAwait: "Average time for write requests to be served on a drive",
percUtil: "Percentage of time the disk was busy",
usedBytes: "Used bytes on a drive",
totalBytes: "Total bytes on a drive",
usedInodes: "Total inodes used on a drive",
totalInodes: "Total inodes on a drive",
cpuUser: "CPU user time",
cpuSystem: "CPU system time",
cpuIdle: "CPU idle time",
cpuIOWait: "CPU ioWait time",
cpuSteal: "CPU steal time",
cpuNice: "CPU nice time",
cpuLoad1: "CPU load average 1min",
cpuLoad5: "CPU load average 5min",
cpuLoad15: "CPU load average 15min",
cpuLoad1Perc: "CPU load average 1min (perentage)",
cpuLoad5Perc: "CPU load average 5min (percentage)",
cpuLoad15Perc: "CPU load average 15min (percentage)",
}
resourceMetricsGroups = []*MetricsGroupV2{
getResourceMetrics(),
}
resourceCollector = newMinioResourceCollector(resourceMetricsGroups)
}
func getResourceKey(name MetricName, labels map[string]string) string {
// labels are used to uniquely identify a metric
// e.g. reads_per_sec_{drive} inside the map
sfx := ""
for _, v := range labels {
if len(sfx) > 0 {
sfx += "_"
}
sfx += v
}
return string(name) + "_" + sfx
}
func updateResourceMetrics(subSys MetricSubsystem, name MetricName, val float64, labels map[string]string, isCumulative bool) {
resourceMetricsMapMu.Lock()
defer resourceMetricsMapMu.Unlock()
subsysMetrics, found := resourceMetricsMap[subSys]
if !found {
subsysMetrics = ResourceMetrics{}
}
key := getResourceKey(name, labels)
metric, found := subsysMetrics[key]
if !found {
metric = ResourceMetric{
Name: name,
Labels: labels,
}
}
if isCumulative {
metric.Current = val - metric.Cumulative
metric.Cumulative = val
} else {
metric.Current = val
}
if metric.Current > metric.Max {
metric.Max = val
}
metric.Sum += metric.Current
metric.Count++
metric.Avg = metric.Sum / float64(metric.Count)
subsysMetrics[key] = metric
resourceMetricsMap[subSys] = subsysMetrics
}
// updateDriveIOStats - Updates the drive IO stats by calculating the difference between the current and latest updated values.
func updateDriveIOStats(currentStats madmin.DiskIOStats, latestStats madmin.DiskIOStats, labels map[string]string) {
sectorSize := uint64(512)
kib := float64(1 << 10)
diffInSeconds := time.Now().UTC().Sub(lastDriveStatsRefresh).Seconds()
if diffInSeconds == 0 {
// too soon to update the stats
return
}
diffStats := getDiffStats(latestStats, currentStats)
updateResourceMetrics(driveSubsystem, readsPerSec, float64(diffStats.ReadIOs)/diffInSeconds, labels, false)
readKib := float64(diffStats.ReadSectors*sectorSize) / kib
updateResourceMetrics(driveSubsystem, readsKBPerSec, readKib/diffInSeconds, labels, false)
updateResourceMetrics(driveSubsystem, writesPerSec, float64(diffStats.WriteIOs)/diffInSeconds, labels, false)
writeKib := float64(diffStats.WriteSectors*sectorSize) / kib
updateResourceMetrics(driveSubsystem, writesKBPerSec, writeKib/diffInSeconds, labels, false)
rdAwait := 0.0
if diffStats.ReadIOs > 0 {
rdAwait = float64(diffStats.ReadTicks) / float64(diffStats.ReadIOs)
}
updateResourceMetrics(driveSubsystem, readsAwait, rdAwait, labels, false)
wrAwait := 0.0
if diffStats.WriteIOs > 0 {
wrAwait = float64(diffStats.WriteTicks) / float64(diffStats.WriteIOs)
}
updateResourceMetrics(driveSubsystem, writesAwait, wrAwait, labels, false)
updateResourceMetrics(driveSubsystem, percUtil, float64(diffStats.TotalTicks)/(diffInSeconds*10), labels, false)
}
func collectDriveMetrics(m madmin.RealtimeMetrics) {
latestDriveStatsMu.Lock()
for d, dm := range m.ByDisk {
labels := map[string]string{"drive": d}
latestStats, ok := latestDriveStats[d]
if !ok {
latestDriveStats[d] = dm.IOStats
continue
}
updateDriveIOStats(dm.IOStats, latestStats, labels)
latestDriveStats[d] = dm.IOStats
}
lastDriveStatsRefresh = time.Now().UTC()
latestDriveStatsMu.Unlock()
globalLocalDrivesMu.RLock()
localDrives := cloneDrives(globalLocalDrivesMap)
globalLocalDrivesMu.RUnlock()
for _, d := range localDrives {
di, err := d.DiskInfo(GlobalContext, DiskInfoOptions{})
labels := map[string]string{"drive": di.Endpoint}
if err == nil {
updateResourceMetrics(driveSubsystem, usedBytes, float64(di.Used), labels, false)
updateResourceMetrics(driveSubsystem, totalBytes, float64(di.Total), labels, false)
updateResourceMetrics(driveSubsystem, usedInodes, float64(di.UsedInodes), labels, false)
updateResourceMetrics(driveSubsystem, totalInodes, float64(di.FreeInodes+di.UsedInodes), labels, false)
}
}
}
func collectLocalResourceMetrics() {
var types madmin.MetricType = madmin.MetricsDisk | madmin.MetricNet | madmin.MetricsMem | madmin.MetricsCPU
m := collectLocalMetrics(types, collectMetricsOpts{})
for _, hm := range m.ByHost {
if hm.Net != nil && len(hm.Net.NetStats.Name) > 0 {
stats := hm.Net.NetStats
labels := map[string]string{"interface": stats.Name}
updateResourceMetrics(interfaceSubsystem, interfaceRxBytes, float64(stats.RxBytes), labels, true)
updateResourceMetrics(interfaceSubsystem, interfaceRxErrors, float64(stats.RxErrors), labels, true)
updateResourceMetrics(interfaceSubsystem, interfaceTxBytes, float64(stats.TxBytes), labels, true)
updateResourceMetrics(interfaceSubsystem, interfaceTxErrors, float64(stats.TxErrors), labels, true)
}
if hm.Mem != nil && len(hm.Mem.Info.Addr) > 0 {
labels := map[string]string{}
stats := hm.Mem.Info
updateResourceMetrics(memSubsystem, total, float64(stats.Total), labels, false)
updateResourceMetrics(memSubsystem, memUsed, float64(stats.Used), labels, false)
perc := math.Round(float64(stats.Used*100*100)/float64(stats.Total)) / 100
updateResourceMetrics(memSubsystem, memUsedPerc, perc, labels, false)
updateResourceMetrics(memSubsystem, memFree, float64(stats.Free), labels, false)
updateResourceMetrics(memSubsystem, memShared, float64(stats.Shared), labels, false)
updateResourceMetrics(memSubsystem, memBuffers, float64(stats.Buffers), labels, false)
updateResourceMetrics(memSubsystem, memAvailable, float64(stats.Available), labels, false)
updateResourceMetrics(memSubsystem, memCache, float64(stats.Cache), labels, false)
}
if hm.CPU != nil {
labels := map[string]string{}
ts := hm.CPU.TimesStat
if ts != nil {
tot := ts.User + ts.System + ts.Idle + ts.Iowait + ts.Nice + ts.Steal
cpuUserVal := math.Round(ts.User/tot*100*100) / 100
updateResourceMetrics(cpuSubsystem, cpuUser, cpuUserVal, labels, false)
cpuSystemVal := math.Round(ts.System/tot*100*100) / 100
updateResourceMetrics(cpuSubsystem, cpuSystem, cpuSystemVal, labels, false)
cpuIdleVal := math.Round(ts.Idle/tot*100*100) / 100
updateResourceMetrics(cpuSubsystem, cpuIdle, cpuIdleVal, labels, false)
cpuIOWaitVal := math.Round(ts.Iowait/tot*100*100) / 100
updateResourceMetrics(cpuSubsystem, cpuIOWait, cpuIOWaitVal, labels, false)
cpuNiceVal := math.Round(ts.Nice/tot*100*100) / 100
updateResourceMetrics(cpuSubsystem, cpuNice, cpuNiceVal, labels, false)
cpuStealVal := math.Round(ts.Steal/tot*100*100) / 100
updateResourceMetrics(cpuSubsystem, cpuSteal, cpuStealVal, labels, false)
}
ls := hm.CPU.LoadStat
if ls != nil {
updateResourceMetrics(cpuSubsystem, cpuLoad1, ls.Load1, labels, false)
updateResourceMetrics(cpuSubsystem, cpuLoad5, ls.Load5, labels, false)
updateResourceMetrics(cpuSubsystem, cpuLoad15, ls.Load15, labels, false)
if hm.CPU.CPUCount > 0 {
perc := math.Round(ls.Load1*100*100/float64(hm.CPU.CPUCount)) / 100
updateResourceMetrics(cpuSubsystem, cpuLoad1Perc, perc, labels, false)
perc = math.Round(ls.Load5*100*100/float64(hm.CPU.CPUCount)) / 100
updateResourceMetrics(cpuSubsystem, cpuLoad5Perc, perc, labels, false)
perc = math.Round(ls.Load15*100*100/float64(hm.CPU.CPUCount)) / 100
updateResourceMetrics(cpuSubsystem, cpuLoad15Perc, perc, labels, false)
}
}
}
break // only one host expected
}
collectDriveMetrics(m)
}
func initLatestValues() {
m := collectLocalMetrics(madmin.MetricsDisk, collectMetricsOpts{})
latestDriveStatsMu.Lock()
latestDriveStats = map[string]madmin.DiskIOStats{}
for d, dm := range m.ByDisk {
latestDriveStats[d] = dm.IOStats
}
lastDriveStatsRefresh = time.Now().UTC()
latestDriveStatsMu.Unlock()
}
// startResourceMetricsCollection - starts the job for collecting resource metrics
func startResourceMetricsCollection() {
initLatestValues()
resourceMetricsMapMu.Lock()
resourceMetricsMap = map[MetricSubsystem]ResourceMetrics{}
resourceMetricsMapMu.Unlock()
metricsTimer := time.NewTimer(resourceMetricsCollectionInterval)
defer metricsTimer.Stop()
collectLocalResourceMetrics()
for {
select {
case <-GlobalContext.Done():
return
case <-metricsTimer.C:
collectLocalResourceMetrics()
// Reset the timer for next cycle.
metricsTimer.Reset(resourceMetricsCollectionInterval)
}
}
}
// minioResourceCollector is the Collector for resource metrics
type minioResourceCollector struct {
metricsGroups []*MetricsGroupV2
desc *prometheus.Desc
}
// Describe sends the super-set of all possible descriptors of metrics
func (c *minioResourceCollector) Describe(ch chan<- *prometheus.Desc) {
ch <- c.desc
}
// Collect is called by the Prometheus registry when collecting metrics.
func (c *minioResourceCollector) Collect(out chan<- prometheus.Metric) {
var wg sync.WaitGroup
publish := func(in <-chan MetricV2) {
defer wg.Done()
for metric := range in {
labels, values := getOrderedLabelValueArrays(metric.VariableLabels)
collectMetric(metric, labels, values, "resource", out)
}
}
// Call peer api to fetch metrics
wg.Add(2)
go publish(ReportMetrics(GlobalContext, c.metricsGroups))
go publish(globalNotificationSys.GetResourceMetrics(GlobalContext))
wg.Wait()
}
// newMinioResourceCollector describes the collector
// and returns reference of minio resource Collector
// It creates the Prometheus Description which is used
// to define Metric and help string
func newMinioResourceCollector(metricsGroups []*MetricsGroupV2) *minioResourceCollector {
return &minioResourceCollector{
metricsGroups: metricsGroups,
desc: prometheus.NewDesc("minio_resource_stats", "Resource statistics exposed by MinIO server", nil, nil),
}
}
func prepareResourceMetrics(rm ResourceMetric, subSys MetricSubsystem, requireAvgMax bool) []MetricV2 {
help := resourceMetricsHelpMap[rm.Name]
name := rm.Name
metrics := make([]MetricV2, 0, 3)
metrics = append(metrics, MetricV2{
Description: getResourceMetricDescription(subSys, name, help),
Value: rm.Current,
VariableLabels: cloneMSS(rm.Labels),
})
if requireAvgMax {
avgName := MetricName(fmt.Sprintf("%s_avg", name))
avgHelp := fmt.Sprintf("%s (avg)", help)
metrics = append(metrics, MetricV2{
Description: getResourceMetricDescription(subSys, avgName, avgHelp),
Value: math.Round(rm.Avg*100) / 100,
VariableLabels: cloneMSS(rm.Labels),
})
maxName := MetricName(fmt.Sprintf("%s_max", name))
maxHelp := fmt.Sprintf("%s (max)", help)
metrics = append(metrics, MetricV2{
Description: getResourceMetricDescription(subSys, maxName, maxHelp),
Value: rm.Max,
VariableLabels: cloneMSS(rm.Labels),
})
}
return metrics
}
func getResourceMetricDescription(subSys MetricSubsystem, name MetricName, help string) MetricDescription {
return MetricDescription{
Namespace: nodeMetricNamespace,
Subsystem: subSys,
Name: name,
Help: help,
Type: gaugeMetric,
}
}
func getResourceMetrics() *MetricsGroupV2 {
mg := &MetricsGroupV2{
cacheInterval: resourceMetricsCacheInterval,
}
mg.RegisterRead(func(ctx context.Context) []MetricV2 {
metrics := []MetricV2{}
subSystems := []MetricSubsystem{interfaceSubsystem, memSubsystem, driveSubsystem, cpuSubsystem}
resourceMetricsMapMu.RLock()
defer resourceMetricsMapMu.RUnlock()
for _, subSys := range subSystems {
stats, found := resourceMetricsMap[subSys]
if found {
requireAvgMax := true
if subSys == driveSubsystem {
requireAvgMax = false
}
for _, m := range stats {
metrics = append(metrics, prepareResourceMetrics(m, subSys, requireAvgMax)...)
}
}
}
return metrics
})
return mg
}
// metricsResourceHandler is the prometheus handler for resource metrics
func metricsResourceHandler() http.Handler {
return metricsHTTPHandler(resourceCollector, "handler.MetricsResource")
}