mirror of
https://github.com/minio/minio.git
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382 lines
9.5 KiB
Go
382 lines
9.5 KiB
Go
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// Copyright (c) 2015-2023 MinIO, Inc.
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//
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// This file is part of MinIO Object Storage stack
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//
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// This program is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Affero General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// This program is distributed in the hope that it will be useful
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Affero General Public License for more details.
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//
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// You should have received a copy of the GNU Affero General Public License
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// along with this program. If not, see <http://www.gnu.org/licenses/>.
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package cmd
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import (
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"fmt"
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"sync"
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"sync/atomic"
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"time"
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"github.com/rcrowley/go-metrics"
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)
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//go:generate msgp -file $GOFILE
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const (
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// beta is the weight used to calculate exponential moving average
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beta = 0.1 // Number of averages considered = 1/(1-beta)
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)
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// rateMeasurement captures the transfer details for one bucket/target
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//msgp:ignore rateMeasurement
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type rateMeasurement struct {
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lock sync.Mutex
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bytesSinceLastWindow uint64 // Total bytes since last window was processed
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startTime time.Time // Start time for window
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expMovingAvg float64 // Previously calculated exponential moving average
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}
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// newRateMeasurement creates a new instance of the measurement with the initial start time.
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func newRateMeasurement(initTime time.Time) *rateMeasurement {
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return &rateMeasurement{
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startTime: initTime,
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}
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}
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// incrementBytes add bytes reported for a bucket/target.
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func (m *rateMeasurement) incrementBytes(bytes uint64) {
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atomic.AddUint64(&m.bytesSinceLastWindow, bytes)
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}
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// updateExponentialMovingAverage processes the measurements captured so far.
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func (m *rateMeasurement) updateExponentialMovingAverage(endTime time.Time) {
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// Calculate aggregate avg bandwidth and exp window avg
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m.lock.Lock()
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defer func() {
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m.startTime = endTime
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m.lock.Unlock()
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}()
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if m.startTime.IsZero() {
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return
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}
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if endTime.Before(m.startTime) {
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return
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}
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duration := endTime.Sub(m.startTime)
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bytesSinceLastWindow := atomic.SwapUint64(&m.bytesSinceLastWindow, 0)
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if m.expMovingAvg == 0 {
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// Should address initial calculation and should be fine for resuming from 0
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m.expMovingAvg = float64(bytesSinceLastWindow) / duration.Seconds()
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return
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}
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increment := float64(bytesSinceLastWindow) / duration.Seconds()
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m.expMovingAvg = exponentialMovingAverage(beta, m.expMovingAvg, increment)
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}
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// exponentialMovingAverage calculates the exponential moving average
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func exponentialMovingAverage(beta, previousAvg, incrementAvg float64) float64 {
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return (1-beta)*incrementAvg + beta*previousAvg
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}
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// getExpMovingAvgBytesPerSecond returns the exponential moving average for the bucket/target in bytes
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func (m *rateMeasurement) getExpMovingAvgBytesPerSecond() float64 {
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m.lock.Lock()
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defer m.lock.Unlock()
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return m.expMovingAvg
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}
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// ActiveWorkerStat is stat for active replication workers
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type ActiveWorkerStat struct {
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Curr int `json:"curr"`
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Avg float32 `json:"avg"`
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Max int `json:"max"`
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hist metrics.Histogram
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}
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func newActiveWorkerStat(r metrics.Registry) *ActiveWorkerStat {
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h := metrics.NewHistogram(metrics.NewUniformSample(100))
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r.Register("replication.active_workers", h)
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return &ActiveWorkerStat{
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hist: h,
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}
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}
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// update curr and max workers;
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func (a *ActiveWorkerStat) update() {
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if a == nil {
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return
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}
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a.Curr = globalReplicationPool.ActiveWorkers()
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a.hist.Update(int64(a.Curr))
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a.Avg = float32(a.hist.Mean())
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a.Max = int(a.hist.Max())
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}
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func (a *ActiveWorkerStat) get() ActiveWorkerStat {
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w := ActiveWorkerStat{
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Curr: a.Curr,
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Avg: a.Avg,
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Max: a.Max,
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}
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return w
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}
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// QStat holds queue stats for replication
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type QStat struct {
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Count float64 `json:"count"`
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Bytes float64 `json:"bytes"`
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}
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func (q *QStat) add(o QStat) QStat {
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return QStat{Bytes: q.Bytes + o.Bytes, Count: q.Count + o.Count}
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}
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// InQueueMetric holds queue stats for replication
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type InQueueMetric struct {
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Curr QStat `json:"curr" msg:"cq"`
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Avg QStat `json:"avg" msg:"aq"`
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Max QStat `json:"max" msg:"pq"`
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}
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func (qm InQueueMetric) merge(o InQueueMetric) InQueueMetric {
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return InQueueMetric{
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Curr: qm.Curr.add(o.Curr),
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Avg: qm.Avg.add(o.Avg),
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Max: qm.Max.add(o.Max),
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}
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}
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type queueCache struct {
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srQueueStats InQueueStats
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bucketStats map[string]InQueueStats
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sync.RWMutex // mutex for queue stats
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}
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func newQueueCache(r metrics.Registry) queueCache {
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return queueCache{
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bucketStats: make(map[string]InQueueStats),
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srQueueStats: newInQueueStats(r, "site"),
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}
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}
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func (q *queueCache) update() {
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q.Lock()
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defer q.Unlock()
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q.srQueueStats.update()
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for _, s := range q.bucketStats {
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s.update()
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}
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}
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func (q *queueCache) getBucketStats(bucket string) InQueueMetric {
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q.RLock()
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defer q.RUnlock()
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v, ok := q.bucketStats[bucket]
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if !ok {
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return InQueueMetric{}
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}
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return InQueueMetric{
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Curr: QStat{Bytes: float64(v.nowBytes), Count: float64(v.nowCount)},
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Max: QStat{Bytes: float64(v.histBytes.Max()), Count: float64(v.histCounts.Max())},
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Avg: QStat{Bytes: v.histBytes.Mean(), Count: v.histCounts.Mean()},
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}
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}
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func (q *queueCache) getSiteStats() InQueueMetric {
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q.RLock()
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defer q.RUnlock()
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v := q.srQueueStats
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return InQueueMetric{
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Curr: QStat{Bytes: float64(v.nowBytes), Count: float64(v.nowCount)},
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Max: QStat{Bytes: float64(v.histBytes.Max()), Count: float64(v.histCounts.Max())},
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Avg: QStat{Bytes: v.histBytes.Mean(), Count: v.histCounts.Mean()},
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}
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}
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// InQueueStats holds queue stats for replication
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type InQueueStats struct {
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nowBytes int64 `json:"-"`
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nowCount int64 `json:"-"`
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histCounts metrics.Histogram
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histBytes metrics.Histogram
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}
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func newInQueueStats(r metrics.Registry, lbl string) InQueueStats {
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histCounts := metrics.NewHistogram(metrics.NewUniformSample(100))
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histBytes := metrics.NewHistogram(metrics.NewUniformSample(100))
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r.Register("replication.queue.counts."+lbl, histCounts)
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r.Register("replication.queue.bytes."+lbl, histBytes)
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return InQueueStats{
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histCounts: histCounts,
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histBytes: histBytes,
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}
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}
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func (q *InQueueStats) update() {
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q.histBytes.Update(atomic.LoadInt64(&q.nowBytes))
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q.histCounts.Update(atomic.LoadInt64(&q.nowCount))
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}
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// XferStats has transfer stats for replication
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type XferStats struct {
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Curr float64 `json:"currRate" msg:"cr"`
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Avg float64 `json:"avgRate" msg:"av"`
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Peak float64 `json:"peakRate" msg:"p"`
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N int64 `json:"n" msg:"n"`
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measure *rateMeasurement `json:"-"`
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sma *SMA `json:"-"`
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}
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// Clone returns a copy of XferStats
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func (rx *XferStats) Clone() *XferStats {
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curr := rx.curr()
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peak := rx.Peak
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if curr > peak {
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peak = curr
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}
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return &XferStats{
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Curr: curr,
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Avg: rx.Avg,
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Peak: peak,
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N: rx.N,
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measure: rx.measure,
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}
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}
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func newXferStats() *XferStats {
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return &XferStats{
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measure: newRateMeasurement(time.Now()),
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sma: newSMA(50),
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}
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}
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func (rx *XferStats) String() string {
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return fmt.Sprintf("curr=%f avg=%f, peak=%f", rx.curr(), rx.Avg, rx.Peak)
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}
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func (rx *XferStats) curr() float64 {
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if rx.measure == nil {
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return 0.0
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}
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return rx.measure.getExpMovingAvgBytesPerSecond()
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}
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func (rx *XferStats) merge(o XferStats) XferStats {
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curr := calcAvg(rx.curr(), o.curr(), rx.N, o.N)
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peak := rx.Peak
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if o.Peak > peak {
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peak = o.Peak
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}
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if curr > peak {
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peak = curr
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}
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return XferStats{
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Avg: calcAvg(rx.Avg, o.Avg, rx.N, o.N),
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Peak: peak,
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Curr: curr,
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measure: rx.measure,
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N: rx.N + o.N,
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}
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}
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func calcAvg(x, y float64, n1, n2 int64) float64 {
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if n1+n2 == 0 {
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return 0
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}
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avg := (x*float64(n1) + y*float64(n2)) / float64(n1+n2)
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return avg
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}
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// Add a new transfer
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func (rx *XferStats) addSize(sz int64, t time.Duration) {
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if rx.measure == nil {
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rx.measure = newRateMeasurement(time.Now())
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}
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rx.measure.incrementBytes(uint64(sz))
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rx.Curr = rx.measure.getExpMovingAvgBytesPerSecond()
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rx.sma.addSample(rx.Curr)
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rx.Avg = rx.sma.simpleMovingAvg()
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if rx.Curr > rx.Peak {
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rx.Peak = rx.Curr
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}
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rx.N++
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}
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// ReplicationMRFStats holds stats of MRF backlog saved to disk in the last 5 minutes
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// and number of entries that failed replication after 3 retries
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type ReplicationMRFStats struct {
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LastFailedCount uint64 `json:"failedCount_last5min"`
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// Count of unreplicated entries that were dropped after MRF retry limit reached since cluster start.
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TotalDroppedCount uint64 `json:"droppedCount_since_uptime"`
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// Bytes of unreplicated entries that were dropped after MRF retry limit reached since cluster start.
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TotalDroppedBytes uint64 `json:"droppedBytes_since_uptime"`
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}
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// SMA struct for calculating simple moving average
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type SMA struct {
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buf []float64
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window int // len of buf
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idx int // current index in buf
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CAvg float64 // cumulative average
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prevSMA float64
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filledBuf bool
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}
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func newSMA(len int) *SMA {
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if len <= 0 {
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len = defaultWindowSize
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}
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return &SMA{
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buf: make([]float64, len),
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window: len,
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idx: 0,
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}
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}
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func (s *SMA) addSample(next float64) {
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prev := s.buf[s.idx]
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s.buf[s.idx] = next
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if s.filledBuf {
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s.prevSMA += (next - prev) / float64(s.window)
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s.CAvg += (next - s.CAvg) / float64(s.window)
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} else {
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s.CAvg = s.simpleMovingAvg()
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s.prevSMA = s.CAvg
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}
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if s.idx == s.window-1 {
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s.filledBuf = true
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}
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s.idx = (s.idx + 1) % s.window
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}
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func (s *SMA) simpleMovingAvg() float64 {
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if s.filledBuf {
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return s.prevSMA
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}
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var tot float64
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for _, r := range s.buf {
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tot += r
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}
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return tot / float64(s.idx+1)
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}
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const (
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defaultWindowSize = 10
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)
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