vendor/github.com/rcrowley/go-metrics/sample.go - voltctl - Gitiles

 package metrics

 import (
 	"math"
 	"math/rand"
 	"sort"
 	"sync"
 	"time"
 )

 const rescaleThreshold = time.Hour

 // Samples maintain a statistically-significant selection of values from
 // a stream.
 type Sample interface {
 	Clear()
 	Count() int64
 	Max() int64
 	Mean() float64
 	Min() int64
 	Percentile(float64) float64
 	Percentiles([]float64) []float64
 	Size() int
 	Snapshot() Sample
 	StdDev() float64
 	Sum() int64
 	Update(int64)
 	Values() []int64
 	Variance() float64
 }

 // ExpDecaySample is an exponentially-decaying sample using a forward-decaying
 // priority reservoir.  See Cormode et al's "Forward Decay: A Practical Time
 // Decay Model for Streaming Systems".
 //
 // <http://dimacs.rutgers.edu/~graham/pubs/papers/fwddecay.pdf>
 type ExpDecaySample struct {
 	alpha         float64
 	count         int64
 	mutex         sync.Mutex
 	reservoirSize int
 	t0, t1        time.Time
 	values        *expDecaySampleHeap
 }

 // NewExpDecaySample constructs a new exponentially-decaying sample with the
 // given reservoir size and alpha.
 func NewExpDecaySample(reservoirSize int, alpha float64) Sample {
 	if UseNilMetrics {
 		return NilSample{}
 	}
 	s := &ExpDecaySample{
 		alpha:         alpha,
 		reservoirSize: reservoirSize,
 		t0:            time.Now(),
 		values:        newExpDecaySampleHeap(reservoirSize),
 	}
 	s.t1 = s.t0.Add(rescaleThreshold)
 	return s
 }

 // Clear clears all samples.
 func (s *ExpDecaySample) Clear() {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	s.count = 0
 	s.t0 = time.Now()
 	s.t1 = s.t0.Add(rescaleThreshold)
 	s.values.Clear()
 }

 // Count returns the number of samples recorded, which may exceed the
 // reservoir size.
 func (s *ExpDecaySample) Count() int64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return s.count
 }

 // Max returns the maximum value in the sample, which may not be the maximum
 // value ever to be part of the sample.
 func (s *ExpDecaySample) Max() int64 {
 	return SampleMax(s.Values())
 }

 // Mean returns the mean of the values in the sample.
 func (s *ExpDecaySample) Mean() float64 {
 	return SampleMean(s.Values())
 }

 // Min returns the minimum value in the sample, which may not be the minimum
 // value ever to be part of the sample.
 func (s *ExpDecaySample) Min() int64 {
 	return SampleMin(s.Values())
 }

 // Percentile returns an arbitrary percentile of values in the sample.
 func (s *ExpDecaySample) Percentile(p float64) float64 {
 	return SamplePercentile(s.Values(), p)
 }

 // Percentiles returns a slice of arbitrary percentiles of values in the
 // sample.
 func (s *ExpDecaySample) Percentiles(ps []float64) []float64 {
 	return SamplePercentiles(s.Values(), ps)
 }

 // Size returns the size of the sample, which is at most the reservoir size.
 func (s *ExpDecaySample) Size() int {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return s.values.Size()
 }

 // Snapshot returns a read-only copy of the sample.
 func (s *ExpDecaySample) Snapshot() Sample {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	vals := s.values.Values()
 	values := make([]int64, len(vals))
 	for i, v := range vals {
 		values[i] = v.v
 	}
 	return &SampleSnapshot{
 		count:  s.count,
 		values: values,
 	}
 }

 // StdDev returns the standard deviation of the values in the sample.
 func (s *ExpDecaySample) StdDev() float64 {
 	return SampleStdDev(s.Values())
 }

 // Sum returns the sum of the values in the sample.
 func (s *ExpDecaySample) Sum() int64 {
 	return SampleSum(s.Values())
 }

 // Update samples a new value.
 func (s *ExpDecaySample) Update(v int64) {
 	s.update(time.Now(), v)
 }

 // Values returns a copy of the values in the sample.
 func (s *ExpDecaySample) Values() []int64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	vals := s.values.Values()
 	values := make([]int64, len(vals))
 	for i, v := range vals {
 		values[i] = v.v
 	}
 	return values
 }

 // Variance returns the variance of the values in the sample.
 func (s *ExpDecaySample) Variance() float64 {
 	return SampleVariance(s.Values())
 }

 // update samples a new value at a particular timestamp.  This is a method all
 // its own to facilitate testing.
 func (s *ExpDecaySample) update(t time.Time, v int64) {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	s.count++
 	if s.values.Size() == s.reservoirSize {
 		s.values.Pop()
 	}
 	s.values.Push(expDecaySample{
 		k: math.Exp(t.Sub(s.t0).Seconds()*s.alpha) / rand.Float64(),
 		v: v,
 	})
 	if t.After(s.t1) {
 		values := s.values.Values()
 		t0 := s.t0
 		s.values.Clear()
 		s.t0 = t
 		s.t1 = s.t0.Add(rescaleThreshold)
 		for _, v := range values {
 			v.k = v.k * math.Exp(-s.alpha*s.t0.Sub(t0).Seconds())
 			s.values.Push(v)
 		}
 	}
 }

 // NilSample is a no-op Sample.
 type NilSample struct{}

 // Clear is a no-op.
 func (NilSample) Clear() {}

 // Count is a no-op.
 func (NilSample) Count() int64 { return 0 }

 // Max is a no-op.
 func (NilSample) Max() int64 { return 0 }

 // Mean is a no-op.
 func (NilSample) Mean() float64 { return 0.0 }

 // Min is a no-op.
 func (NilSample) Min() int64 { return 0 }

 // Percentile is a no-op.
 func (NilSample) Percentile(p float64) float64 { return 0.0 }

 // Percentiles is a no-op.
 func (NilSample) Percentiles(ps []float64) []float64 {
 	return make([]float64, len(ps))
 }

 // Size is a no-op.
 func (NilSample) Size() int { return 0 }

 // Sample is a no-op.
 func (NilSample) Snapshot() Sample { return NilSample{} }

 // StdDev is a no-op.
 func (NilSample) StdDev() float64 { return 0.0 }

 // Sum is a no-op.
 func (NilSample) Sum() int64 { return 0 }

 // Update is a no-op.
 func (NilSample) Update(v int64) {}

 // Values is a no-op.
 func (NilSample) Values() []int64 { return []int64{} }

 // Variance is a no-op.
 func (NilSample) Variance() float64 { return 0.0 }

 // SampleMax returns the maximum value of the slice of int64.
 func SampleMax(values []int64) int64 {
 	if 0 == len(values) {
 		return 0
 	}
 	var max int64 = math.MinInt64
 	for _, v := range values {
 		if max < v {
 			max = v
 		}
 	}
 	return max
 }

 // SampleMean returns the mean value of the slice of int64.
 func SampleMean(values []int64) float64 {
 	if 0 == len(values) {
 		return 0.0
 	}
 	return float64(SampleSum(values)) / float64(len(values))
 }

 // SampleMin returns the minimum value of the slice of int64.
 func SampleMin(values []int64) int64 {
 	if 0 == len(values) {
 		return 0
 	}
 	var min int64 = math.MaxInt64
 	for _, v := range values {
 		if min > v {
 			min = v
 		}
 	}
 	return min
 }

 // SamplePercentiles returns an arbitrary percentile of the slice of int64.
 func SamplePercentile(values int64Slice, p float64) float64 {
 	return SamplePercentiles(values, []float64{p})[0]
 }

 // SamplePercentiles returns a slice of arbitrary percentiles of the slice of
 // int64.
 func SamplePercentiles(values int64Slice, ps []float64) []float64 {
 	scores := make([]float64, len(ps))
 	size := len(values)
 	if size > 0 {
 		sort.Sort(values)
 		for i, p := range ps {
 			pos := p * float64(size+1)
 			if pos < 1.0 {
 				scores[i] = float64(values[0])
 			} else if pos >= float64(size) {
 				scores[i] = float64(values[size-1])
 			} else {
 				lower := float64(values[int(pos)-1])
 				upper := float64(values[int(pos)])
 				scores[i] = lower + (pos-math.Floor(pos))*(upper-lower)
 			}
 		}
 	}
 	return scores
 }

 // SampleSnapshot is a read-only copy of another Sample.
 type SampleSnapshot struct {
 	count  int64
 	values []int64
 }

 func NewSampleSnapshot(count int64, values []int64) *SampleSnapshot {
 	return &SampleSnapshot{
 		count:  count,
 		values: values,
 	}
 }

 // Clear panics.
 func (*SampleSnapshot) Clear() {
 	panic("Clear called on a SampleSnapshot")
 }

 // Count returns the count of inputs at the time the snapshot was taken.
 func (s *SampleSnapshot) Count() int64 { return s.count }

 // Max returns the maximal value at the time the snapshot was taken.
 func (s *SampleSnapshot) Max() int64 { return SampleMax(s.values) }

 // Mean returns the mean value at the time the snapshot was taken.
 func (s *SampleSnapshot) Mean() float64 { return SampleMean(s.values) }

 // Min returns the minimal value at the time the snapshot was taken.
 func (s *SampleSnapshot) Min() int64 { return SampleMin(s.values) }

 // Percentile returns an arbitrary percentile of values at the time the
 // snapshot was taken.
 func (s *SampleSnapshot) Percentile(p float64) float64 {
 	return SamplePercentile(s.values, p)
 }

 // Percentiles returns a slice of arbitrary percentiles of values at the time
 // the snapshot was taken.
 func (s *SampleSnapshot) Percentiles(ps []float64) []float64 {
 	return SamplePercentiles(s.values, ps)
 }

 // Size returns the size of the sample at the time the snapshot was taken.
 func (s *SampleSnapshot) Size() int { return len(s.values) }

 // Snapshot returns the snapshot.
 func (s *SampleSnapshot) Snapshot() Sample { return s }

 // StdDev returns the standard deviation of values at the time the snapshot was
 // taken.
 func (s *SampleSnapshot) StdDev() float64 { return SampleStdDev(s.values) }

 // Sum returns the sum of values at the time the snapshot was taken.
 func (s *SampleSnapshot) Sum() int64 { return SampleSum(s.values) }

 // Update panics.
 func (*SampleSnapshot) Update(int64) {
 	panic("Update called on a SampleSnapshot")
 }

 // Values returns a copy of the values in the sample.
 func (s *SampleSnapshot) Values() []int64 {
 	values := make([]int64, len(s.values))
 	copy(values, s.values)
 	return values
 }

 // Variance returns the variance of values at the time the snapshot was taken.
 func (s *SampleSnapshot) Variance() float64 { return SampleVariance(s.values) }

 // SampleStdDev returns the standard deviation of the slice of int64.
 func SampleStdDev(values []int64) float64 {
 	return math.Sqrt(SampleVariance(values))
 }

 // SampleSum returns the sum of the slice of int64.
 func SampleSum(values []int64) int64 {
 	var sum int64
 	for _, v := range values {
 		sum += v
 	}
 	return sum
 }

 // SampleVariance returns the variance of the slice of int64.
 func SampleVariance(values []int64) float64 {
 	if 0 == len(values) {
 		return 0.0
 	}
 	m := SampleMean(values)
 	var sum float64
 	for _, v := range values {
 		d := float64(v) - m
 		sum += d * d
 	}
 	return sum / float64(len(values))
 }

 // A uniform sample using Vitter's Algorithm R.
 //
 // <http://www.cs.umd.edu/~samir/498/vitter.pdf>
 type UniformSample struct {
 	count         int64
 	mutex         sync.Mutex
 	reservoirSize int
 	values        []int64
 }

 // NewUniformSample constructs a new uniform sample with the given reservoir
 // size.
 func NewUniformSample(reservoirSize int) Sample {
 	if UseNilMetrics {
 		return NilSample{}
 	}
 	return &UniformSample{
 		reservoirSize: reservoirSize,
 		values:        make([]int64, 0, reservoirSize),
 	}
 }

 // Clear clears all samples.
 func (s *UniformSample) Clear() {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	s.count = 0
 	s.values = make([]int64, 0, s.reservoirSize)
 }

 // Count returns the number of samples recorded, which may exceed the
 // reservoir size.
 func (s *UniformSample) Count() int64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return s.count
 }

 // Max returns the maximum value in the sample, which may not be the maximum
 // value ever to be part of the sample.
 func (s *UniformSample) Max() int64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return SampleMax(s.values)
 }

 // Mean returns the mean of the values in the sample.
 func (s *UniformSample) Mean() float64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return SampleMean(s.values)
 }

 // Min returns the minimum value in the sample, which may not be the minimum
 // value ever to be part of the sample.
 func (s *UniformSample) Min() int64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return SampleMin(s.values)
 }

 // Percentile returns an arbitrary percentile of values in the sample.
 func (s *UniformSample) Percentile(p float64) float64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return SamplePercentile(s.values, p)
 }

 // Percentiles returns a slice of arbitrary percentiles of values in the
 // sample.
 func (s *UniformSample) Percentiles(ps []float64) []float64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return SamplePercentiles(s.values, ps)
 }

 // Size returns the size of the sample, which is at most the reservoir size.
 func (s *UniformSample) Size() int {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return len(s.values)
 }

 // Snapshot returns a read-only copy of the sample.
 func (s *UniformSample) Snapshot() Sample {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	values := make([]int64, len(s.values))
 	copy(values, s.values)
 	return &SampleSnapshot{
 		count:  s.count,
 		values: values,
 	}
 }

 // StdDev returns the standard deviation of the values in the sample.
 func (s *UniformSample) StdDev() float64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return SampleStdDev(s.values)
 }

 // Sum returns the sum of the values in the sample.
 func (s *UniformSample) Sum() int64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return SampleSum(s.values)
 }

 // Update samples a new value.
 func (s *UniformSample) Update(v int64) {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	s.count++
 	if len(s.values) < s.reservoirSize {
 		s.values = append(s.values, v)
 	} else {
 		r := rand.Int63n(s.count)
 		if r < int64(len(s.values)) {
 			s.values[int(r)] = v
 		}
 	}
 }

 // Values returns a copy of the values in the sample.
 func (s *UniformSample) Values() []int64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	values := make([]int64, len(s.values))
 	copy(values, s.values)
 	return values
 }

 // Variance returns the variance of the values in the sample.
 func (s *UniformSample) Variance() float64 {
 	s.mutex.Lock()
 	defer s.mutex.Unlock()
 	return SampleVariance(s.values)
 }

 // expDecaySample represents an individual sample in a heap.
 type expDecaySample struct {
 	k float64
 	v int64
 }

 func newExpDecaySampleHeap(reservoirSize int) *expDecaySampleHeap {
 	return &expDecaySampleHeap{make([]expDecaySample, 0, reservoirSize)}
 }

 // expDecaySampleHeap is a min-heap of expDecaySamples.
 // The internal implementation is copied from the standard library's container/heap
 type expDecaySampleHeap struct {
 	s []expDecaySample
 }

 func (h *expDecaySampleHeap) Clear() {
 	h.s = h.s[:0]
 }

 func (h *expDecaySampleHeap) Push(s expDecaySample) {
 	n := len(h.s)
 	h.s = h.s[0 : n+1]
 	h.s[n] = s
 	h.up(n)
 }

 func (h *expDecaySampleHeap) Pop() expDecaySample {
 	n := len(h.s) - 1
 	h.s[0], h.s[n] = h.s[n], h.s[0]
 	h.down(0, n)

 	n = len(h.s)
 	s := h.s[n-1]
 	h.s = h.s[0 : n-1]
 	return s
 }

 func (h *expDecaySampleHeap) Size() int {
 	return len(h.s)
 }

 func (h *expDecaySampleHeap) Values() []expDecaySample {
 	return h.s
 }

 func (h *expDecaySampleHeap) up(j int) {
 	for {
 		i := (j - 1) / 2 // parent
 		if i == j || !(h.s[j].k < h.s[i].k) {
 			break
 		}
 		h.s[i], h.s[j] = h.s[j], h.s[i]
 		j = i
 	}
 }

 func (h *expDecaySampleHeap) down(i, n int) {
 	for {
 		j1 := 2*i + 1
 		if j1 >= n || j1 < 0 { // j1 < 0 after int overflow
 			break
 		}
 		j := j1 // left child
 		if j2 := j1 + 1; j2 < n && !(h.s[j1].k < h.s[j2].k) {
 			j = j2 // = 2*i + 2  // right child
 		}
 		if !(h.s[j].k < h.s[i].k) {
 			break
 		}
 		h.s[i], h.s[j] = h.s[j], h.s[i]
 		i = j
 	}
 }

 type int64Slice []int64

 func (p int64Slice) Len() int           { return len(p) }
 func (p int64Slice) Less(i, j int) bool { return p[i] < p[j] }
 func (p int64Slice) Swap(i, j int)      { p[i], p[j] = p[j], p[i] }
	package metrics

	import (
	"math"
	"math/rand"
	"sort"
	"sync"
	"time"
	)

	const rescaleThreshold = time.Hour

	// Samples maintain a statistically-significant selection of values from
	// a stream.
	type Sample interface {
	Clear()
	Count() int64
	Max() int64
	Mean() float64
	Min() int64
	Percentile(float64) float64
	Percentiles([]float64) []float64
	Size() int
	Snapshot() Sample
	StdDev() float64
	Sum() int64
	Update(int64)
	Values() []int64
	Variance() float64
	}

	// ExpDecaySample is an exponentially-decaying sample using a forward-decaying
	// priority reservoir. See Cormode et al's "Forward Decay: A Practical Time
	// Decay Model for Streaming Systems".
	//
	// <http://dimacs.rutgers.edu/~graham/pubs/papers/fwddecay.pdf>
	type ExpDecaySample struct {
	alpha float64
	count int64
	mutex sync.Mutex
	reservoirSize int
	t0, t1 time.Time
	values *expDecaySampleHeap
	}

	// NewExpDecaySample constructs a new exponentially-decaying sample with the
	// given reservoir size and alpha.
	func NewExpDecaySample(reservoirSize int, alpha float64) Sample {
	if UseNilMetrics {
	return NilSample{}
	}
	s := &ExpDecaySample{
	alpha: alpha,
	reservoirSize: reservoirSize,
	t0: time.Now(),
	values: newExpDecaySampleHeap(reservoirSize),
	}
	s.t1 = s.t0.Add(rescaleThreshold)
	return s
	}

	// Clear clears all samples.
	func (s *ExpDecaySample) Clear() {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	s.count = 0
	s.t0 = time.Now()
	s.t1 = s.t0.Add(rescaleThreshold)
	s.values.Clear()
	}

	// Count returns the number of samples recorded, which may exceed the
	// reservoir size.
	func (s *ExpDecaySample) Count() int64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return s.count
	}

	// Max returns the maximum value in the sample, which may not be the maximum
	// value ever to be part of the sample.
	func (s *ExpDecaySample) Max() int64 {
	return SampleMax(s.Values())
	}

	// Mean returns the mean of the values in the sample.
	func (s *ExpDecaySample) Mean() float64 {
	return SampleMean(s.Values())
	}

	// Min returns the minimum value in the sample, which may not be the minimum
	// value ever to be part of the sample.
	func (s *ExpDecaySample) Min() int64 {
	return SampleMin(s.Values())
	}

	// Percentile returns an arbitrary percentile of values in the sample.
	func (s *ExpDecaySample) Percentile(p float64) float64 {
	return SamplePercentile(s.Values(), p)
	}

	// Percentiles returns a slice of arbitrary percentiles of values in the
	// sample.
	func (s *ExpDecaySample) Percentiles(ps []float64) []float64 {
	return SamplePercentiles(s.Values(), ps)
	}

	// Size returns the size of the sample, which is at most the reservoir size.
	func (s *ExpDecaySample) Size() int {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return s.values.Size()
	}

	// Snapshot returns a read-only copy of the sample.
	func (s *ExpDecaySample) Snapshot() Sample {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	vals := s.values.Values()
	values := make([]int64, len(vals))
	for i, v := range vals {
	values[i] = v.v
	}
	return &SampleSnapshot{
	count: s.count,
	values: values,
	}
	}

	// StdDev returns the standard deviation of the values in the sample.
	func (s *ExpDecaySample) StdDev() float64 {
	return SampleStdDev(s.Values())
	}

	// Sum returns the sum of the values in the sample.
	func (s *ExpDecaySample) Sum() int64 {
	return SampleSum(s.Values())
	}

	// Update samples a new value.
	func (s *ExpDecaySample) Update(v int64) {
	s.update(time.Now(), v)
	}

	// Values returns a copy of the values in the sample.
	func (s *ExpDecaySample) Values() []int64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	vals := s.values.Values()
	values := make([]int64, len(vals))
	for i, v := range vals {
	values[i] = v.v
	}
	return values
	}

	// Variance returns the variance of the values in the sample.
	func (s *ExpDecaySample) Variance() float64 {
	return SampleVariance(s.Values())
	}

	// update samples a new value at a particular timestamp. This is a method all
	// its own to facilitate testing.
	func (s *ExpDecaySample) update(t time.Time, v int64) {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	s.count++
	if s.values.Size() == s.reservoirSize {
	s.values.Pop()
	}
	s.values.Push(expDecaySample{
	k: math.Exp(t.Sub(s.t0).Seconds()*s.alpha) / rand.Float64(),
	v: v,
	})
	if t.After(s.t1) {
	values := s.values.Values()
	t0 := s.t0
	s.values.Clear()
	s.t0 = t
	s.t1 = s.t0.Add(rescaleThreshold)
	for _, v := range values {
	v.k = v.k * math.Exp(-s.alpha*s.t0.Sub(t0).Seconds())
	s.values.Push(v)
	}
	}
	}

	// NilSample is a no-op Sample.
	type NilSample struct{}

	// Clear is a no-op.
	func (NilSample) Clear() {}

	// Count is a no-op.
	func (NilSample) Count() int64 { return 0 }

	// Max is a no-op.
	func (NilSample) Max() int64 { return 0 }

	// Mean is a no-op.
	func (NilSample) Mean() float64 { return 0.0 }

	// Min is a no-op.
	func (NilSample) Min() int64 { return 0 }

	// Percentile is a no-op.
	func (NilSample) Percentile(p float64) float64 { return 0.0 }

	// Percentiles is a no-op.
	func (NilSample) Percentiles(ps []float64) []float64 {
	return make([]float64, len(ps))
	}

	// Size is a no-op.
	func (NilSample) Size() int { return 0 }

	// Sample is a no-op.
	func (NilSample) Snapshot() Sample { return NilSample{} }

	// StdDev is a no-op.
	func (NilSample) StdDev() float64 { return 0.0 }

	// Sum is a no-op.
	func (NilSample) Sum() int64 { return 0 }

	// Update is a no-op.
	func (NilSample) Update(v int64) {}

	// Values is a no-op.
	func (NilSample) Values() []int64 { return []int64{} }

	// Variance is a no-op.
	func (NilSample) Variance() float64 { return 0.0 }

	// SampleMax returns the maximum value of the slice of int64.
	func SampleMax(values []int64) int64 {
	if 0 == len(values) {
	return 0
	}
	var max int64 = math.MinInt64
	for _, v := range values {
	if max < v {
	max = v
	}
	}
	return max
	}

	// SampleMean returns the mean value of the slice of int64.
	func SampleMean(values []int64) float64 {
	if 0 == len(values) {
	return 0.0
	}
	return float64(SampleSum(values)) / float64(len(values))
	}

	// SampleMin returns the minimum value of the slice of int64.
	func SampleMin(values []int64) int64 {
	if 0 == len(values) {
	return 0
	}
	var min int64 = math.MaxInt64
	for _, v := range values {
	if min > v {
	min = v
	}
	}
	return min
	}

	// SamplePercentiles returns an arbitrary percentile of the slice of int64.
	func SamplePercentile(values int64Slice, p float64) float64 {
	return SamplePercentiles(values, []float64{p})[0]
	}

	// SamplePercentiles returns a slice of arbitrary percentiles of the slice of
	// int64.
	func SamplePercentiles(values int64Slice, ps []float64) []float64 {
	scores := make([]float64, len(ps))
	size := len(values)
	if size > 0 {
	sort.Sort(values)
	for i, p := range ps {
	pos := p * float64(size+1)
	if pos < 1.0 {
	scores[i] = float64(values[0])
	} else if pos >= float64(size) {
	scores[i] = float64(values[size-1])
	} else {
	lower := float64(values[int(pos)-1])
	upper := float64(values[int(pos)])
	scores[i] = lower + (pos-math.Floor(pos))*(upper-lower)
	}
	}
	}
	return scores
	}

	// SampleSnapshot is a read-only copy of another Sample.
	type SampleSnapshot struct {
	count int64
	values []int64
	}

	func NewSampleSnapshot(count int64, values []int64) *SampleSnapshot {
	return &SampleSnapshot{
	count: count,
	values: values,
	}
	}

	// Clear panics.
	func (*SampleSnapshot) Clear() {
	panic("Clear called on a SampleSnapshot")
	}

	// Count returns the count of inputs at the time the snapshot was taken.
	func (s *SampleSnapshot) Count() int64 { return s.count }

	// Max returns the maximal value at the time the snapshot was taken.
	func (s *SampleSnapshot) Max() int64 { return SampleMax(s.values) }

	// Mean returns the mean value at the time the snapshot was taken.
	func (s *SampleSnapshot) Mean() float64 { return SampleMean(s.values) }

	// Min returns the minimal value at the time the snapshot was taken.
	func (s *SampleSnapshot) Min() int64 { return SampleMin(s.values) }

	// Percentile returns an arbitrary percentile of values at the time the
	// snapshot was taken.
	func (s *SampleSnapshot) Percentile(p float64) float64 {
	return SamplePercentile(s.values, p)
	}

	// Percentiles returns a slice of arbitrary percentiles of values at the time
	// the snapshot was taken.
	func (s *SampleSnapshot) Percentiles(ps []float64) []float64 {
	return SamplePercentiles(s.values, ps)
	}

	// Size returns the size of the sample at the time the snapshot was taken.
	func (s *SampleSnapshot) Size() int { return len(s.values) }

	// Snapshot returns the snapshot.
	func (s *SampleSnapshot) Snapshot() Sample { return s }

	// StdDev returns the standard deviation of values at the time the snapshot was
	// taken.
	func (s *SampleSnapshot) StdDev() float64 { return SampleStdDev(s.values) }

	// Sum returns the sum of values at the time the snapshot was taken.
	func (s *SampleSnapshot) Sum() int64 { return SampleSum(s.values) }

	// Update panics.
	func (*SampleSnapshot) Update(int64) {
	panic("Update called on a SampleSnapshot")
	}

	// Values returns a copy of the values in the sample.
	func (s *SampleSnapshot) Values() []int64 {
	values := make([]int64, len(s.values))
	copy(values, s.values)
	return values
	}

	// Variance returns the variance of values at the time the snapshot was taken.
	func (s *SampleSnapshot) Variance() float64 { return SampleVariance(s.values) }

	// SampleStdDev returns the standard deviation of the slice of int64.
	func SampleStdDev(values []int64) float64 {
	return math.Sqrt(SampleVariance(values))
	}

	// SampleSum returns the sum of the slice of int64.
	func SampleSum(values []int64) int64 {
	var sum int64
	for _, v := range values {
	sum += v
	}
	return sum
	}

	// SampleVariance returns the variance of the slice of int64.
	func SampleVariance(values []int64) float64 {
	if 0 == len(values) {
	return 0.0
	}
	m := SampleMean(values)
	var sum float64
	for _, v := range values {
	d := float64(v) - m
	sum += d * d
	}
	return sum / float64(len(values))
	}

	// A uniform sample using Vitter's Algorithm R.
	//
	// <http://www.cs.umd.edu/~samir/498/vitter.pdf>
	type UniformSample struct {
	count int64
	mutex sync.Mutex
	reservoirSize int
	values []int64
	}

	// NewUniformSample constructs a new uniform sample with the given reservoir
	// size.
	func NewUniformSample(reservoirSize int) Sample {
	if UseNilMetrics {
	return NilSample{}
	}
	return &UniformSample{
	reservoirSize: reservoirSize,
	values: make([]int64, 0, reservoirSize),
	}
	}

	// Clear clears all samples.
	func (s *UniformSample) Clear() {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	s.count = 0
	s.values = make([]int64, 0, s.reservoirSize)
	}

	// Count returns the number of samples recorded, which may exceed the
	// reservoir size.
	func (s *UniformSample) Count() int64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return s.count
	}

	// Max returns the maximum value in the sample, which may not be the maximum
	// value ever to be part of the sample.
	func (s *UniformSample) Max() int64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return SampleMax(s.values)
	}

	// Mean returns the mean of the values in the sample.
	func (s *UniformSample) Mean() float64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return SampleMean(s.values)
	}

	// Min returns the minimum value in the sample, which may not be the minimum
	// value ever to be part of the sample.
	func (s *UniformSample) Min() int64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return SampleMin(s.values)
	}

	// Percentile returns an arbitrary percentile of values in the sample.
	func (s *UniformSample) Percentile(p float64) float64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return SamplePercentile(s.values, p)
	}

	// Percentiles returns a slice of arbitrary percentiles of values in the
	// sample.
	func (s *UniformSample) Percentiles(ps []float64) []float64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return SamplePercentiles(s.values, ps)
	}

	// Size returns the size of the sample, which is at most the reservoir size.
	func (s *UniformSample) Size() int {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return len(s.values)
	}

	// Snapshot returns a read-only copy of the sample.
	func (s *UniformSample) Snapshot() Sample {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	values := make([]int64, len(s.values))
	copy(values, s.values)
	return &SampleSnapshot{
	count: s.count,
	values: values,
	}
	}

	// StdDev returns the standard deviation of the values in the sample.
	func (s *UniformSample) StdDev() float64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return SampleStdDev(s.values)
	}

	// Sum returns the sum of the values in the sample.
	func (s *UniformSample) Sum() int64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return SampleSum(s.values)
	}

	// Update samples a new value.
	func (s *UniformSample) Update(v int64) {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	s.count++
	if len(s.values) < s.reservoirSize {
	s.values = append(s.values, v)
	} else {
	r := rand.Int63n(s.count)
	if r < int64(len(s.values)) {
	s.values[int(r)] = v
	}
	}
	}

	// Values returns a copy of the values in the sample.
	func (s *UniformSample) Values() []int64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	values := make([]int64, len(s.values))
	copy(values, s.values)
	return values
	}

	// Variance returns the variance of the values in the sample.
	func (s *UniformSample) Variance() float64 {
	s.mutex.Lock()
	defer s.mutex.Unlock()
	return SampleVariance(s.values)
	}

	// expDecaySample represents an individual sample in a heap.
	type expDecaySample struct {
	k float64
	v int64
	}

	func newExpDecaySampleHeap(reservoirSize int) *expDecaySampleHeap {
	return &expDecaySampleHeap{make([]expDecaySample, 0, reservoirSize)}
	}

	// expDecaySampleHeap is a min-heap of expDecaySamples.
	// The internal implementation is copied from the standard library's container/heap
	type expDecaySampleHeap struct {
	s []expDecaySample
	}

	func (h *expDecaySampleHeap) Clear() {
	h.s = h.s[:0]
	}

	func (h *expDecaySampleHeap) Push(s expDecaySample) {
	n := len(h.s)
	h.s = h.s[0 : n+1]
	h.s[n] = s
	h.up(n)
	}

	func (h *expDecaySampleHeap) Pop() expDecaySample {
	n := len(h.s) - 1
	h.s[0], h.s[n] = h.s[n], h.s[0]
	h.down(0, n)

	n = len(h.s)
	s := h.s[n-1]
	h.s = h.s[0 : n-1]
	return s
	}

	func (h *expDecaySampleHeap) Size() int {
	return len(h.s)
	}

	func (h *expDecaySampleHeap) Values() []expDecaySample {
	return h.s
	}

	func (h *expDecaySampleHeap) up(j int) {
	for {
	i := (j - 1) / 2 // parent
	if i == j \|\| !(h.s[j].k < h.s[i].k) {
	break
	}
	h.s[i], h.s[j] = h.s[j], h.s[i]
	j = i
	}
	}

	func (h *expDecaySampleHeap) down(i, n int) {
	for {
	j1 := 2*i + 1
	if j1 >= n \|\| j1 < 0 { // j1 < 0 after int overflow
	break
	}
	j := j1 // left child
	if j2 := j1 + 1; j2 < n && !(h.s[j1].k < h.s[j2].k) {
	j = j2 // = 2*i + 2 // right child
	}
	if !(h.s[j].k < h.s[i].k) {
	break
	}
	h.s[i], h.s[j] = h.s[j], h.s[i]
	i = j
	}
	}

	type int64Slice []int64

	func (p int64Slice) Len() int { return len(p) }
	func (p int64Slice) Less(i, j int) bool { return p[i] < p[j] }
	func (p int64Slice) Swap(i, j int) { p[i], p[j] = p[j], p[i] }