mirror of
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526 lines
15 KiB
Go
526 lines
15 KiB
Go
// Copyright 2015 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Package timeseries implements a time series structure for stats collection.
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package timeseries // import "golang.org/x/net/internal/timeseries"
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import (
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"fmt"
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"log"
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"time"
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)
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const (
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timeSeriesNumBuckets = 64
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minuteHourSeriesNumBuckets = 60
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)
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var timeSeriesResolutions = []time.Duration{
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1 * time.Second,
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10 * time.Second,
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1 * time.Minute,
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10 * time.Minute,
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1 * time.Hour,
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6 * time.Hour,
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24 * time.Hour, // 1 day
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7 * 24 * time.Hour, // 1 week
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4 * 7 * 24 * time.Hour, // 4 weeks
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16 * 7 * 24 * time.Hour, // 16 weeks
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}
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var minuteHourSeriesResolutions = []time.Duration{
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1 * time.Second,
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1 * time.Minute,
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}
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// An Observable is a kind of data that can be aggregated in a time series.
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type Observable interface {
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Multiply(ratio float64) // Multiplies the data in self by a given ratio
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Add(other Observable) // Adds the data from a different observation to self
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Clear() // Clears the observation so it can be reused.
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CopyFrom(other Observable) // Copies the contents of a given observation to self
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}
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// Float attaches the methods of Observable to a float64.
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type Float float64
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// NewFloat returns a Float.
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func NewFloat() Observable {
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f := Float(0)
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return &f
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}
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// String returns the float as a string.
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func (f *Float) String() string { return fmt.Sprintf("%g", f.Value()) }
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// Value returns the float's value.
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func (f *Float) Value() float64 { return float64(*f) }
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func (f *Float) Multiply(ratio float64) { *f *= Float(ratio) }
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func (f *Float) Add(other Observable) {
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o := other.(*Float)
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*f += *o
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}
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func (f *Float) Clear() { *f = 0 }
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func (f *Float) CopyFrom(other Observable) {
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o := other.(*Float)
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*f = *o
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}
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// A Clock tells the current time.
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type Clock interface {
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Time() time.Time
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}
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type defaultClock int
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var defaultClockInstance defaultClock
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func (defaultClock) Time() time.Time { return time.Now() }
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// Information kept per level. Each level consists of a circular list of
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// observations. The start of the level may be derived from end and the
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// len(buckets) * sizeInMillis.
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type tsLevel struct {
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oldest int // index to oldest bucketed Observable
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newest int // index to newest bucketed Observable
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end time.Time // end timestamp for this level
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size time.Duration // duration of the bucketed Observable
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buckets []Observable // collections of observations
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provider func() Observable // used for creating new Observable
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}
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func (l *tsLevel) Clear() {
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l.oldest = 0
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l.newest = len(l.buckets) - 1
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l.end = time.Time{}
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for i := range l.buckets {
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if l.buckets[i] != nil {
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l.buckets[i].Clear()
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l.buckets[i] = nil
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}
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}
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}
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func (l *tsLevel) InitLevel(size time.Duration, numBuckets int, f func() Observable) {
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l.size = size
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l.provider = f
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l.buckets = make([]Observable, numBuckets)
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}
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// Keeps a sequence of levels. Each level is responsible for storing data at
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// a given resolution. For example, the first level stores data at a one
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// minute resolution while the second level stores data at a one hour
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// resolution.
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// Each level is represented by a sequence of buckets. Each bucket spans an
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// interval equal to the resolution of the level. New observations are added
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// to the last bucket.
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type timeSeries struct {
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provider func() Observable // make more Observable
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numBuckets int // number of buckets in each level
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levels []*tsLevel // levels of bucketed Observable
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lastAdd time.Time // time of last Observable tracked
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total Observable // convenient aggregation of all Observable
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clock Clock // Clock for getting current time
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pending Observable // observations not yet bucketed
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pendingTime time.Time // what time are we keeping in pending
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dirty bool // if there are pending observations
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}
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// init initializes a level according to the supplied criteria.
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func (ts *timeSeries) init(resolutions []time.Duration, f func() Observable, numBuckets int, clock Clock) {
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ts.provider = f
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ts.numBuckets = numBuckets
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ts.clock = clock
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ts.levels = make([]*tsLevel, len(resolutions))
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for i := range resolutions {
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if i > 0 && resolutions[i-1] >= resolutions[i] {
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log.Print("timeseries: resolutions must be monotonically increasing")
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break
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}
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newLevel := new(tsLevel)
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newLevel.InitLevel(resolutions[i], ts.numBuckets, ts.provider)
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ts.levels[i] = newLevel
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}
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ts.Clear()
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}
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// Clear removes all observations from the time series.
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func (ts *timeSeries) Clear() {
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ts.lastAdd = time.Time{}
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ts.total = ts.resetObservation(ts.total)
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ts.pending = ts.resetObservation(ts.pending)
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ts.pendingTime = time.Time{}
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ts.dirty = false
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for i := range ts.levels {
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ts.levels[i].Clear()
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}
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}
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// Add records an observation at the current time.
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func (ts *timeSeries) Add(observation Observable) {
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ts.AddWithTime(observation, ts.clock.Time())
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}
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// AddWithTime records an observation at the specified time.
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func (ts *timeSeries) AddWithTime(observation Observable, t time.Time) {
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smallBucketDuration := ts.levels[0].size
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if t.After(ts.lastAdd) {
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ts.lastAdd = t
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}
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if t.After(ts.pendingTime) {
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ts.advance(t)
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ts.mergePendingUpdates()
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ts.pendingTime = ts.levels[0].end
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ts.pending.CopyFrom(observation)
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ts.dirty = true
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} else if t.After(ts.pendingTime.Add(-1 * smallBucketDuration)) {
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// The observation is close enough to go into the pending bucket.
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// This compensates for clock skewing and small scheduling delays
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// by letting the update stay in the fast path.
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ts.pending.Add(observation)
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ts.dirty = true
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} else {
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ts.mergeValue(observation, t)
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}
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}
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// mergeValue inserts the observation at the specified time in the past into all levels.
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func (ts *timeSeries) mergeValue(observation Observable, t time.Time) {
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for _, level := range ts.levels {
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index := (ts.numBuckets - 1) - int(level.end.Sub(t)/level.size)
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if 0 <= index && index < ts.numBuckets {
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bucketNumber := (level.oldest + index) % ts.numBuckets
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if level.buckets[bucketNumber] == nil {
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level.buckets[bucketNumber] = level.provider()
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}
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level.buckets[bucketNumber].Add(observation)
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}
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}
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ts.total.Add(observation)
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}
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// mergePendingUpdates applies the pending updates into all levels.
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func (ts *timeSeries) mergePendingUpdates() {
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if ts.dirty {
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ts.mergeValue(ts.pending, ts.pendingTime)
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ts.pending = ts.resetObservation(ts.pending)
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ts.dirty = false
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}
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}
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// advance cycles the buckets at each level until the latest bucket in
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// each level can hold the time specified.
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func (ts *timeSeries) advance(t time.Time) {
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if !t.After(ts.levels[0].end) {
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return
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}
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for i := 0; i < len(ts.levels); i++ {
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level := ts.levels[i]
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if !level.end.Before(t) {
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break
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}
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// If the time is sufficiently far, just clear the level and advance
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// directly.
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if !t.Before(level.end.Add(level.size * time.Duration(ts.numBuckets))) {
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for _, b := range level.buckets {
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ts.resetObservation(b)
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}
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level.end = time.Unix(0, (t.UnixNano()/level.size.Nanoseconds())*level.size.Nanoseconds())
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}
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for t.After(level.end) {
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level.end = level.end.Add(level.size)
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level.newest = level.oldest
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level.oldest = (level.oldest + 1) % ts.numBuckets
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ts.resetObservation(level.buckets[level.newest])
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}
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t = level.end
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}
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}
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// Latest returns the sum of the num latest buckets from the level.
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func (ts *timeSeries) Latest(level, num int) Observable {
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now := ts.clock.Time()
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if ts.levels[0].end.Before(now) {
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ts.advance(now)
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}
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ts.mergePendingUpdates()
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result := ts.provider()
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l := ts.levels[level]
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index := l.newest
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for i := 0; i < num; i++ {
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if l.buckets[index] != nil {
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result.Add(l.buckets[index])
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}
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if index == 0 {
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index = ts.numBuckets
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}
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index--
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}
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return result
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}
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// LatestBuckets returns a copy of the num latest buckets from level.
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func (ts *timeSeries) LatestBuckets(level, num int) []Observable {
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if level < 0 || level > len(ts.levels) {
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log.Print("timeseries: bad level argument: ", level)
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return nil
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}
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if num < 0 || num >= ts.numBuckets {
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log.Print("timeseries: bad num argument: ", num)
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return nil
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}
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results := make([]Observable, num)
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now := ts.clock.Time()
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if ts.levels[0].end.Before(now) {
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ts.advance(now)
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}
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ts.mergePendingUpdates()
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l := ts.levels[level]
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index := l.newest
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for i := 0; i < num; i++ {
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result := ts.provider()
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results[i] = result
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if l.buckets[index] != nil {
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result.CopyFrom(l.buckets[index])
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}
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if index == 0 {
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index = ts.numBuckets
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}
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index -= 1
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}
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return results
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}
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// ScaleBy updates observations by scaling by factor.
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func (ts *timeSeries) ScaleBy(factor float64) {
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for _, l := range ts.levels {
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for i := 0; i < ts.numBuckets; i++ {
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l.buckets[i].Multiply(factor)
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}
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}
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ts.total.Multiply(factor)
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ts.pending.Multiply(factor)
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}
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// Range returns the sum of observations added over the specified time range.
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// If start or finish times don't fall on bucket boundaries of the same
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// level, then return values are approximate answers.
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func (ts *timeSeries) Range(start, finish time.Time) Observable {
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return ts.ComputeRange(start, finish, 1)[0]
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}
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// Recent returns the sum of observations from the last delta.
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func (ts *timeSeries) Recent(delta time.Duration) Observable {
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now := ts.clock.Time()
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return ts.Range(now.Add(-delta), now)
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}
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// Total returns the total of all observations.
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func (ts *timeSeries) Total() Observable {
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ts.mergePendingUpdates()
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return ts.total
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}
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// ComputeRange computes a specified number of values into a slice using
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// the observations recorded over the specified time period. The return
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// values are approximate if the start or finish times don't fall on the
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// bucket boundaries at the same level or if the number of buckets spanning
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// the range is not an integral multiple of num.
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func (ts *timeSeries) ComputeRange(start, finish time.Time, num int) []Observable {
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if start.After(finish) {
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log.Printf("timeseries: start > finish, %v>%v", start, finish)
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return nil
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}
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if num < 0 {
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log.Printf("timeseries: num < 0, %v", num)
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return nil
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}
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results := make([]Observable, num)
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for _, l := range ts.levels {
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if !start.Before(l.end.Add(-l.size * time.Duration(ts.numBuckets))) {
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ts.extract(l, start, finish, num, results)
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return results
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}
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}
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// Failed to find a level that covers the desired range. So just
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// extract from the last level, even if it doesn't cover the entire
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// desired range.
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ts.extract(ts.levels[len(ts.levels)-1], start, finish, num, results)
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return results
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}
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// RecentList returns the specified number of values in slice over the most
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// recent time period of the specified range.
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func (ts *timeSeries) RecentList(delta time.Duration, num int) []Observable {
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if delta < 0 {
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return nil
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}
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now := ts.clock.Time()
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return ts.ComputeRange(now.Add(-delta), now, num)
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}
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// extract returns a slice of specified number of observations from a given
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// level over a given range.
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func (ts *timeSeries) extract(l *tsLevel, start, finish time.Time, num int, results []Observable) {
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ts.mergePendingUpdates()
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srcInterval := l.size
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dstInterval := finish.Sub(start) / time.Duration(num)
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dstStart := start
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srcStart := l.end.Add(-srcInterval * time.Duration(ts.numBuckets))
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srcIndex := 0
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// Where should scanning start?
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if dstStart.After(srcStart) {
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advance := int(dstStart.Sub(srcStart) / srcInterval)
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srcIndex += advance
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srcStart = srcStart.Add(time.Duration(advance) * srcInterval)
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}
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// The i'th value is computed as show below.
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// interval = (finish/start)/num
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// i'th value = sum of observation in range
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// [ start + i * interval,
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// start + (i + 1) * interval )
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for i := 0; i < num; i++ {
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results[i] = ts.resetObservation(results[i])
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dstEnd := dstStart.Add(dstInterval)
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for srcIndex < ts.numBuckets && srcStart.Before(dstEnd) {
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srcEnd := srcStart.Add(srcInterval)
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if srcEnd.After(ts.lastAdd) {
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srcEnd = ts.lastAdd
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}
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if !srcEnd.Before(dstStart) {
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srcValue := l.buckets[(srcIndex+l.oldest)%ts.numBuckets]
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if !srcStart.Before(dstStart) && !srcEnd.After(dstEnd) {
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// dst completely contains src.
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if srcValue != nil {
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results[i].Add(srcValue)
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}
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} else {
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// dst partially overlaps src.
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overlapStart := maxTime(srcStart, dstStart)
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overlapEnd := minTime(srcEnd, dstEnd)
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base := srcEnd.Sub(srcStart)
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fraction := overlapEnd.Sub(overlapStart).Seconds() / base.Seconds()
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used := ts.provider()
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if srcValue != nil {
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used.CopyFrom(srcValue)
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}
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used.Multiply(fraction)
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results[i].Add(used)
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}
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if srcEnd.After(dstEnd) {
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break
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}
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}
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srcIndex++
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srcStart = srcStart.Add(srcInterval)
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}
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dstStart = dstStart.Add(dstInterval)
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}
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}
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// resetObservation clears the content so the struct may be reused.
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func (ts *timeSeries) resetObservation(observation Observable) Observable {
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if observation == nil {
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observation = ts.provider()
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} else {
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observation.Clear()
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}
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return observation
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}
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// TimeSeries tracks data at granularities from 1 second to 16 weeks.
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type TimeSeries struct {
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timeSeries
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}
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// NewTimeSeries creates a new TimeSeries using the function provided for creating new Observable.
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func NewTimeSeries(f func() Observable) *TimeSeries {
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return NewTimeSeriesWithClock(f, defaultClockInstance)
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}
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// NewTimeSeriesWithClock creates a new TimeSeries using the function provided for creating new Observable and the clock for
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// assigning timestamps.
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func NewTimeSeriesWithClock(f func() Observable, clock Clock) *TimeSeries {
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ts := new(TimeSeries)
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ts.timeSeries.init(timeSeriesResolutions, f, timeSeriesNumBuckets, clock)
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return ts
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}
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// MinuteHourSeries tracks data at granularities of 1 minute and 1 hour.
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type MinuteHourSeries struct {
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timeSeries
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}
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// NewMinuteHourSeries creates a new MinuteHourSeries using the function provided for creating new Observable.
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func NewMinuteHourSeries(f func() Observable) *MinuteHourSeries {
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return NewMinuteHourSeriesWithClock(f, defaultClockInstance)
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}
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// NewMinuteHourSeriesWithClock creates a new MinuteHourSeries using the function provided for creating new Observable and the clock for
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// assigning timestamps.
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func NewMinuteHourSeriesWithClock(f func() Observable, clock Clock) *MinuteHourSeries {
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ts := new(MinuteHourSeries)
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ts.timeSeries.init(minuteHourSeriesResolutions, f,
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minuteHourSeriesNumBuckets, clock)
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return ts
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}
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func (ts *MinuteHourSeries) Minute() Observable {
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return ts.timeSeries.Latest(0, 60)
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}
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func (ts *MinuteHourSeries) Hour() Observable {
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return ts.timeSeries.Latest(1, 60)
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}
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func minTime(a, b time.Time) time.Time {
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if a.Before(b) {
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return a
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}
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return b
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}
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func maxTime(a, b time.Time) time.Time {
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if a.After(b) {
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return a
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}
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return b
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}
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