Merge pull request #901 from prometheus/beorn7/histogram

Implement strategy to limit the sparse bucket count
2021-09-01 13:46:42 +02:00 · 2021-09-01 13:46:42 +02:00 · dfbcc28fff
parent 84fcafffb1 263be8dab7
commit dfbcc28fff
2 changed files with 713 additions and 207 deletions
--- a/prometheus/histogram.go
+++ b/prometheus/histogram.go
@ -39,21 +39,21 @@ import (
 // https://github.com/open-telemetry/opentelemetry-specification/issues/1776#issuecomment-870164310
 var sparseBounds = [][]float64{
 	// Schema "0":
-	[]float64{0.5},
+	{0.5},
 	// Schema 1:
-	[]float64{0.5, 0.7071067811865475},
+	{0.5, 0.7071067811865475},
 	// Schema 2:
-	[]float64{0.5, 0.5946035575013605, 0.7071067811865475, 0.8408964152537144},
+	{0.5, 0.5946035575013605, 0.7071067811865475, 0.8408964152537144},
 	// Schema 3:
-	[]float64{0.5, 0.5452538663326288, 0.5946035575013605, 0.6484197773255048,
+	{0.5, 0.5452538663326288, 0.5946035575013605, 0.6484197773255048,
 		0.7071067811865475, 0.7711054127039704, 0.8408964152537144, 0.9170040432046711},
 	// Schema 4:
-	[]float64{0.5, 0.5221368912137069, 0.5452538663326288, 0.5693943173783458,
+	{0.5, 0.5221368912137069, 0.5452538663326288, 0.5693943173783458,
 		0.5946035575013605, 0.620928906036742, 0.6484197773255048, 0.6771277734684463,
 		0.7071067811865475, 0.7384130729697496, 0.7711054127039704, 0.805245165974627,
 		0.8408964152537144, 0.8781260801866495, 0.9170040432046711, 0.9576032806985735},
 	// Schema 5:
-	[]float64{0.5, 0.5109485743270583, 0.5221368912137069, 0.5335702003384117,
+	{0.5, 0.5109485743270583, 0.5221368912137069, 0.5335702003384117,
 		0.5452538663326288, 0.5571933712979462, 0.5693943173783458, 0.5818624293887887,
 		0.5946035575013605, 0.6076236799902344, 0.620928906036742, 0.6345254785958666,
 		0.6484197773255048, 0.6626183215798706, 0.6771277734684463, 0.6919549409819159,
@ -62,7 +62,7 @@ var sparseBounds = [][]float64{
 		0.8408964152537144, 0.8593096490612387, 0.8781260801866495, 0.8973545375015533,
 		0.9170040432046711, 0.9370838170551498, 0.9576032806985735, 0.9785720620876999},
 	// Schema 6:
-	[]float64{0.5, 0.5054446430258502, 0.5109485743270583, 0.5165124395106142,
+	{0.5, 0.5054446430258502, 0.5109485743270583, 0.5165124395106142,
 		0.5221368912137069, 0.5278225891802786, 0.5335702003384117, 0.5393803988785598,
 		0.5452538663326288, 0.5511912916539204, 0.5571933712979462, 0.5632608093041209,
 		0.5693943173783458, 0.5755946149764913, 0.5818624293887887, 0.5881984958251406,
@ -79,7 +79,7 @@ var sparseBounds = [][]float64{
 		0.9170040432046711, 0.9269895625416926, 0.9370838170551498, 0.9472879907934827,
 		0.9576032806985735, 0.9680308967461471, 0.9785720620876999, 0.9892280131939752},
 	// Schema 7:
-	[]float64{0.5, 0.5027149505564014, 0.5054446430258502, 0.5081891574554764,
+	{0.5, 0.5027149505564014, 0.5054446430258502, 0.5081891574554764,
 		0.5109485743270583, 0.5137229745593818, 0.5165124395106142, 0.5193170509806894,
 		0.5221368912137069, 0.5249720429003435, 0.5278225891802786, 0.5306886136446309,
 		0.5335702003384117, 0.5364674337629877, 0.5393803988785598, 0.5423091811066545,
@ -112,7 +112,7 @@ var sparseBounds = [][]float64{
 		0.9576032806985735, 0.9628029718180622, 0.9680308967461471, 0.9732872087896164,
 		0.9785720620876999, 0.9838856116165875, 0.9892280131939752, 0.9945994234836328},
 	// Schema 8:
-	[]float64{0.5, 0.5013556375251013, 0.5027149505564014, 0.5040779490592088,
+	{0.5, 0.5013556375251013, 0.5027149505564014, 0.5040779490592088,
 		0.5054446430258502, 0.5068150424757447, 0.5081891574554764, 0.509566998038869,
 		0.5109485743270583, 0.5123338964485679, 0.5137229745593818, 0.5151158188430205,
 		0.5165124395106142, 0.5179128468009786, 0.5193170509806894, 0.520725062344158,
@ -405,10 +405,27 @@ type HistogramOpts struct {
 	// of making the zero value of HistogramOpts meaningful. Has to be
 	// solved more elegantly in the final version.)
 	SparseBucketsZeroThreshold float64
-	// TODO(beorn7): Need a setting to limit total bucket count and to
+
-	// configure a strategy to enforce the limit, e.g. if minimum duration
+	// The remaining fields define a strategy to limit the number of
-	// after last reset, reset. If not, half the resolution and/or expand
+	// populated sparse buckets. If SparseBucketsMaxNumber is left at zero,
-	// the zero bucket.
+	// the number of buckets is not limited. Otherwise, once the provided
 	// number is exceeded, the following strategy is enacted: First, if the
 	// last reset (or the creation) of the histogram is at least
 	// SparseBucketsMinResetDuration ago, then the whole histogram is reset
 	// to its initial state (including regular buckets). If less time has
 	// passed, or if SparseBucketsMinResetDuration is zero, no reset is
 	// performed. Instead, the zero threshold is increased sufficiently to
 	// reduce the number of buckets to or below SparseBucketsMaxNumber, but
 	// not to more than SparseBucketsMaxZeroThreshold. Thus, if
 	// SparseBucketsMaxZeroThreshold is already at or below the current zero
 	// threshold, nothing happens at this step. After that, if the number of
 	// buckets still exceeds SparseBucketsMaxNumber, the resolution of the
 	// histogram is reduced by doubling the width of the sparse buckets (up
 	// to a growth factor between one bucket to the next of 2^(2^4) = 65536,
 	// see above).
 	SparseBucketsMaxNumber        uint32
 	SparseBucketsMinResetDuration time.Duration
 	SparseBucketsMaxZeroThreshold float64
 }
 // NewHistogram creates a new Histogram based on the provided HistogramOpts. It
@ -449,7 +466,10 @@ func newHistogram(desc *Desc, opts HistogramOpts, labelValues ...string) Histogr
 		desc:                   desc,
 		upperBounds:            opts.Buckets,
 		labelPairs:             MakeLabelPairs(desc, labelValues),
-		counts:      [2]*histogramCounts{{}, {}},
+		sparseMaxBuckets:       opts.SparseBucketsMaxNumber,
 		sparseMaxZeroThreshold: opts.SparseBucketsMaxZeroThreshold,
 		sparseMinResetDuration: opts.SparseBucketsMinResetDuration,
 		lastResetTime:          time.Now(),
 		now:                    time.Now,
 	}
 	if len(h.upperBounds) == 0 && opts.SparseBucketsFactor <= 1 {
@ -460,9 +480,9 @@ func newHistogram(desc *Desc, opts HistogramOpts, labelValues ...string) Histogr
 	} else {
 		switch {
 		case opts.SparseBucketsZeroThreshold > 0:
-			h.sparseThreshold = opts.SparseBucketsZeroThreshold
+			h.sparseZeroThreshold = opts.SparseBucketsZeroThreshold
 		case opts.SparseBucketsZeroThreshold == 0:
-			h.sparseThreshold = DefSparseBucketsZeroThreshold
+			h.sparseZeroThreshold = DefSparseBucketsZeroThreshold
 		} // Leave h.sparseThreshold at 0 otherwise.
 		h.sparseSchema = pickSparseSchema(opts.SparseBucketsFactor)
 	}
@ -483,8 +503,16 @@ func newHistogram(desc *Desc, opts HistogramOpts, labelValues ...string) Histogr
 	}
 	// Finally we know the final length of h.upperBounds and can make buckets
 	// for both counts as well as exemplars:
-	h.counts[0].buckets = make([]uint64, len(h.upperBounds))
+	h.counts[0] = &histogramCounts{
-	h.counts[1].buckets = make([]uint64, len(h.upperBounds))
+		buckets:                 make([]uint64, len(h.upperBounds)),
 		sparseZeroThresholdBits: math.Float64bits(h.sparseZeroThreshold),
 		sparseSchema:            h.sparseSchema,
 	}
 	h.counts[1] = &histogramCounts{
 		buckets:                 make([]uint64, len(h.upperBounds)),
 		sparseZeroThresholdBits: math.Float64bits(h.sparseZeroThreshold),
 		sparseSchema:            h.sparseSchema,
 	}
 	h.exemplars = make([]atomic.Value, len(h.upperBounds)+1)
 	h.init(h) // Init self-collection.
@ -492,14 +520,32 @@ func newHistogram(desc *Desc, opts HistogramOpts, labelValues ...string) Histogr
 }
 type histogramCounts struct {
 	// Order in this struct matters for the alignment required by atomic
 	// operations, see http://golang.org/pkg/sync/atomic/#pkg-note-BUG
 	// sumBits contains the bits of the float64 representing the sum of all
-	// observations. sumBits and count have to go first in the struct to
+	// observations.
 	// guarantee alignment for atomic operations.
 	// http://golang.org/pkg/sync/atomic/#pkg-note-BUG
 	sumBits uint64
 	count   uint64
 	// sparseZeroBucket counts all (positive and negative) observations in
 	// the zero bucket (with an absolute value less or equal the current
 	// threshold, see next field.
 	sparseZeroBucket uint64
 	// sparseZeroThresholdBits is the bit pattern of the current threshold
 	// for the zero bucket. It's initially equal to sparseZeroThreshold but
 	// may change according to the bucket count limitation strategy.
 	sparseZeroThresholdBits uint64
 	// sparseSchema may change over time according to the bucket count
 	// limitation strategy and therefore has to be saved here.
 	sparseSchema int32
 	// Number of (positive and negative) sparse buckets.
 	sparseBucketsNumber uint32
 	// Regular buckets.
 	buckets []uint64
-	// sparse buckets are implemented with a sync.Map for now. A dedicated
+
 	// Sparse buckets are implemented with a sync.Map for now. A dedicated
 	// data structure will likely be more efficient. There are separate maps
 	// for negative and positive observations. The map's value is an *int64,
 	// counting observations in that bucket. (Note that we don't use uint64
@ -508,38 +554,47 @@ type histogramCounts struct {
 	// map's key is the index of the bucket according to the used
 	// sparseSchema. Index 0 is for an upper bound of 1.
 	sparseBucketsPositive, sparseBucketsNegative sync.Map
 	// sparseZeroBucket counts all (positive and negative) observations in
 	// the zero bucket (with an absolute value less or equal
 	// SparseBucketsZeroThreshold).
 	sparseZeroBucket uint64
 }
 // observe manages the parts of observe that only affects
 // histogramCounts. doSparse is true if spare buckets should be done,
-// too. whichSparse is 0 for the sparseZeroBucket and +1 or -1 for
+// too.
-// sparseBucketsPositive or sparseBucketsNegative, respectively. sparseKey is
+func (hc *histogramCounts) observe(v float64, bucket int, doSparse bool) {
 // the key of the sparse bucket to use.
 func (hc *histogramCounts) observe(v float64, bucket int, doSparse bool, whichSparse int, sparseKey int) {
 	if bucket < len(hc.buckets) {
 		atomic.AddUint64(&hc.buckets[bucket], 1)
 	}
-	for {
+	atomicAddFloat(&hc.sumBits, v)
 		oldBits := atomic.LoadUint64(&hc.sumBits)
 		newBits := math.Float64bits(math.Float64frombits(oldBits) + v)
 		if atomic.CompareAndSwapUint64(&hc.sumBits, oldBits, newBits) {
 			break
 		}
 	}
 	if doSparse {
-		switch whichSparse {
+		var (
-		case 0:
+			sparseKey           int
-			atomic.AddUint64(&hc.sparseZeroBucket, 1)
+			sparseSchema        = atomic.LoadInt32(&hc.sparseSchema)
-		case +1:
+			sparseZeroThreshold = math.Float64frombits(atomic.LoadUint64(&hc.sparseZeroThresholdBits))
-			addToSparseBucket(&hc.sparseBucketsPositive, sparseKey, 1)
+			frac, exp           = math.Frexp(math.Abs(v))
-		case -1:
+			bucketCreated       bool
-			addToSparseBucket(&hc.sparseBucketsNegative, sparseKey, 1)
+		)
 		switch {
 		case math.IsInf(v, 0):
 			sparseKey = math.MaxInt32 // Largest possible sparseKey.
 		case sparseSchema > 0:
 			bounds := sparseBounds[sparseSchema]
 			sparseKey = sort.SearchFloat64s(bounds, frac) + (exp-1)*len(bounds)
 		default:
-			panic(fmt.Errorf("invalid value for whichSparse: %d", whichSparse))
+			sparseKey = exp
 			if frac == 0.5 {
 				sparseKey--
 			}
 			sparseKey /= 1 << -sparseSchema
 		}
 		switch {
 		case v > sparseZeroThreshold:
 			bucketCreated = addToSparseBucket(&hc.sparseBucketsPositive, sparseKey, 1)
 		case v < -sparseZeroThreshold:
 			bucketCreated = addToSparseBucket(&hc.sparseBucketsNegative, sparseKey, 1)
 		default:
 			atomic.AddUint64(&hc.sparseZeroBucket, 1)
 		}
 		if bucketCreated {
 			atomic.AddUint32(&hc.sparseBucketsNumber, 1)
 		}
 	}
 	// Increment count last as we take it as a signal that the observation
@ -547,21 +602,6 @@ func (hc *histogramCounts) observe(v float64, bucket int, doSparse bool, whichSp
 	atomic.AddUint64(&hc.count, 1)
 }
 func addToSparseBucket(buckets *sync.Map, key int, increment int64) {
 	if existingBucket, ok := buckets.Load(key); ok {
 		// Fast path without allocation.
 		atomic.AddInt64(existingBucket.(*int64), increment)
 		return
 	}
 	// Bucket doesn't exist yet. Slow path allocating new counter.
 	newBucket := increment // TODO(beorn7): Check if this is sufficient to not let increment escape.
 	if actualBucket, loaded := buckets.LoadOrStore(key, &newBucket); loaded {
 		// The bucket was created concurrently in another goroutine.
 		// Have to increment after all.
 		atomic.AddInt64(actualBucket.(*int64), increment)
 	}
 }
 type histogram struct {
 	// countAndHotIdx enables lock-free writes with use of atomic updates.
 	// The most significant bit is the hot index [0 or 1] of the count field
@ -583,7 +623,9 @@ type histogram struct {
 	selfCollector
 	desc *Desc
-	writeMtx sync.Mutex // Only used in the Write method.
+
 	// Only used in the Write method and for sparse bucket management.
 	mtx sync.Mutex
 	// Two counts, one is "hot" for lock-free observations, the other is
 	// "cold" for writing out a dto.Metric. It has to be an array of
@ -594,8 +636,12 @@ type histogram struct {
 	upperBounds            []float64
 	labelPairs             []*dto.LabelPair
 	exemplars              []atomic.Value // One more than buckets (to include +Inf), each a *dto.Exemplar.
-	sparseSchema    int32          // Set to math.MinInt32 if no sparse buckets are used.
+	sparseSchema           int32          // The initial schema. Set to math.MinInt32 if no sparse buckets are used.
-	sparseThreshold float64
+	sparseZeroThreshold    float64        // The initial zero threshold.
 	sparseMaxZeroThreshold float64
 	sparseMaxBuckets       uint32
 	sparseMinResetDuration time.Duration
 	lastResetTime          time.Time // Protected by mtx.
 	now func() time.Time // To mock out time.Now() for testing.
 }
@ -619,8 +665,8 @@ func (h *histogram) Write(out *dto.Metric) error {
 	// the hot path, i.e. Observe is called much more often than Write. The
 	// complication of making Write lock-free isn't worth it, if possible at
 	// all.
-	h.writeMtx.Lock()
+	h.mtx.Lock()
-	defer h.writeMtx.Unlock()
+	defer h.mtx.Unlock()
 	// Adding 1<<63 switches the hot index (from 0 to 1 or from 1 to 0)
 	// without touching the count bits. See the struct comments for a full
@ -633,10 +679,7 @@ func (h *histogram) Write(out *dto.Metric) error {
 	hotCounts := h.counts[n>>63]
 	coldCounts := h.counts[(^n)>>63]
-	// Await cooldown.
+	waitForCooldown(count, coldCounts)
 	for count != atomic.LoadUint64(&coldCounts.count) {
 		runtime.Gosched() // Let observations get work done.
 	}
 	his := &dto.Histogram{
 		Bucket:      make([]*dto.Bucket, len(h.upperBounds)),
@ -666,106 +709,24 @@ func (h *histogram) Write(out *dto.Metric) error {
 		}
 		his.Bucket = append(his.Bucket, b)
 	}
 	// Add all the cold counts to the new hot counts and reset the cold counts.
 	atomic.AddUint64(&hotCounts.count, count)
 	atomic.StoreUint64(&coldCounts.count, 0)
 	for {
 		oldBits := atomic.LoadUint64(&hotCounts.sumBits)
 		newBits := math.Float64bits(math.Float64frombits(oldBits) + his.GetSampleSum())
 		if atomic.CompareAndSwapUint64(&hotCounts.sumBits, oldBits, newBits) {
 			atomic.StoreUint64(&coldCounts.sumBits, 0)
 			break
 		}
 	}
 	for i := range h.upperBounds {
 		atomic.AddUint64(&hotCounts.buckets[i], atomic.LoadUint64(&coldCounts.buckets[i]))
 		atomic.StoreUint64(&coldCounts.buckets[i], 0)
 	}
 	if h.sparseSchema > math.MinInt32 {
-		his.SbZeroThreshold = &h.sparseThreshold
+		his.SbZeroThreshold = proto.Float64(math.Float64frombits(atomic.LoadUint64(&coldCounts.sparseZeroThresholdBits)))
-		his.SbSchema = &h.sparseSchema
+		his.SbSchema = proto.Int32(atomic.LoadInt32(&coldCounts.sparseSchema))
 		zeroBucket := atomic.LoadUint64(&coldCounts.sparseZeroBucket)
 		defer func() {
-			atomic.AddUint64(&hotCounts.sparseZeroBucket, zeroBucket)
+			coldCounts.sparseBucketsPositive.Range(addAndReset(&hotCounts.sparseBucketsPositive, &hotCounts.sparseBucketsNumber))
-			atomic.StoreUint64(&coldCounts.sparseZeroBucket, 0)
+			coldCounts.sparseBucketsNegative.Range(addAndReset(&hotCounts.sparseBucketsNegative, &hotCounts.sparseBucketsNumber))
 			coldCounts.sparseBucketsPositive.Range(addAndReset(&hotCounts.sparseBucketsPositive))
 			coldCounts.sparseBucketsNegative.Range(addAndReset(&hotCounts.sparseBucketsNegative))
 		}()
 		his.SbZeroCount = proto.Uint64(zeroBucket)
 		his.SbNegative = makeSparseBuckets(&coldCounts.sparseBucketsNegative)
 		his.SbPositive = makeSparseBuckets(&coldCounts.sparseBucketsPositive)
 	}
 	addAndResetCounts(hotCounts, coldCounts)
 	return nil
 }
 func makeSparseBuckets(buckets *sync.Map) *dto.SparseBuckets {
 	var ii []int
 	buckets.Range(func(k, v interface{}) bool {
 		ii = append(ii, k.(int))
 		return true
 	})
 	sort.Ints(ii)
 	if len(ii) == 0 {
 		return nil
 	}
 	sbs := dto.SparseBuckets{}
 	var prevCount int64
 	var nextI int
 	appendDelta := func(count int64) {
 		*sbs.Span[len(sbs.Span)-1].Length++
 		sbs.Delta = append(sbs.Delta, count-prevCount)
 		prevCount = count
 	}
 	for n, i := range ii {
 		v, _ := buckets.Load(i)
 		count := atomic.LoadInt64(v.(*int64))
 		// Multiple spans with only small gaps in between are probably
 		// encoded more efficiently as one larger span with a few empty
 		// buckets. Needs some research to find the sweet spot. For now,
 		// we assume that gaps of one ore two buckets should not create
 		// a new span.
 		iDelta := int32(i - nextI)
 		if n == 0 || iDelta > 2 {
 			// We have to create a new span, either because we are
 			// at the very beginning, or because we have found a gap
 			// of more than two buckets.
 			sbs.Span = append(sbs.Span, &dto.SparseBuckets_Span{
 				Offset: proto.Int32(iDelta),
 				Length: proto.Uint32(0),
 			})
 		} else {
 			// We have found a small gap (or no gap at all).
 			// Insert empty buckets as needed.
 			for j := int32(0); j < iDelta; j++ {
 				appendDelta(0)
 			}
 		}
 		appendDelta(count)
 		nextI = i + 1
 	}
 	return &sbs
 }
 // addAndReset returns a function to be used with sync.Map.Range of spare
 // buckets in coldCounts. It increments the buckets in the provided hotBuckets
 // according to the buckets ranged through. It then resets all buckets ranged
 // through to 0 (but leaves them in place so that they don't need to get
 // recreated on the next scrape).
 func addAndReset(hotBuckets *sync.Map) func(k, v interface{}) bool {
 	return func(k, v interface{}) bool {
 		bucket := v.(*int64)
 		addToSparseBucket(hotBuckets, k.(int), atomic.LoadInt64(bucket))
 		atomic.StoreInt64(bucket, 0)
 		return true
 	}
 }
 // findBucket returns the index of the bucket for the provided value, or
 // len(h.upperBounds) for the +Inf bucket.
 func (h *histogram) findBucket(v float64) int {
@ -785,34 +746,213 @@ func (h *histogram) findBucket(v float64) int {
 func (h *histogram) observe(v float64, bucket int) {
 	// Do not add to sparse buckets for NaN observations.
 	doSparse := h.sparseSchema > math.MinInt32 && !math.IsNaN(v)
 	var whichSparse, sparseKey int
 	if doSparse {
 		switch {
 		case v > h.sparseThreshold:
 			whichSparse = +1
 		case v < -h.sparseThreshold:
 			whichSparse = -1
 		}
 		frac, exp := math.Frexp(math.Abs(v))
 		switch {
 		case math.IsInf(v, 0):
 			sparseKey = math.MaxInt32 // Largest possible sparseKey.
 		case h.sparseSchema > 0:
 			bounds := sparseBounds[h.sparseSchema]
 			sparseKey = sort.SearchFloat64s(bounds, frac) + (exp-1)*len(bounds)
 		default:
 			sparseKey = exp
 			if frac == 0.5 {
 				sparseKey--
 			}
 			sparseKey /= 1 << -h.sparseSchema
 		}
 	}
 	// We increment h.countAndHotIdx so that the counter in the lower
 	// 63 bits gets incremented. At the same time, we get the new value
 	// back, which we can use to find the currently-hot counts.
 	n := atomic.AddUint64(&h.countAndHotIdx, 1)
-	h.counts[n>>63].observe(v, bucket, doSparse, whichSparse, sparseKey)
+	hotCounts := h.counts[n>>63]
 	hotCounts.observe(v, bucket, doSparse)
 	if doSparse {
 		h.limitSparseBuckets(hotCounts, v, bucket)
 	}
 }
 // limitSparsebuckets applies a strategy to limit the number of populated sparse
 // buckets. It's generally best effort, and there are situations where the
 // number can go higher (if even the lowest resolution isn't enough to reduce
 // the number sufficiently, or if the provided counts aren't fully updated yet
 // by a concurrently happening Write call).
 func (h *histogram) limitSparseBuckets(counts *histogramCounts, value float64, bucket int) {
 	if h.sparseMaxBuckets == 0 {
 		return // No limit configured.
 	}
 	if h.sparseMaxBuckets >= atomic.LoadUint32(&counts.sparseBucketsNumber) {
 		return // Bucket limit not exceeded yet.
 	}
 	h.mtx.Lock()
 	defer h.mtx.Unlock()
 	// The hot counts might have been swapped just before we acquired the
 	// lock. Re-fetch the hot counts first...
 	n := atomic.LoadUint64(&h.countAndHotIdx)
 	hotIdx := n >> 63
 	coldIdx := (^n) >> 63
 	hotCounts := h.counts[hotIdx]
 	coldCounts := h.counts[coldIdx]
 	// ...and then check again if we really have to reduce the bucket count.
 	if h.sparseMaxBuckets >= atomic.LoadUint32(&hotCounts.sparseBucketsNumber) {
 		return // Bucket limit not exceeded after all.
 	}
 	// Try the various strategies in order.
 	if h.maybeReset(hotCounts, coldCounts, coldIdx, value, bucket) {
 		return
 	}
 	if h.maybeWidenZeroBucket(hotCounts, coldCounts) {
 		return
 	}
 	h.doubleBucketWidth(hotCounts, coldCounts)
 }
 // maybyReset resests the whole histogram if at least h.sparseMinResetDuration
 // has been passed. It returns true if the histogram has been reset. The caller
 // must have locked h.mtx.
 func (h *histogram) maybeReset(hot, cold *histogramCounts, coldIdx uint64, value float64, bucket int) bool {
 	// We are using the possibly mocked h.now() rather than
 	// time.Since(h.lastResetTime) to enable testing.
 	if h.sparseMinResetDuration == 0 || h.now().Sub(h.lastResetTime) < h.sparseMinResetDuration {
 		return false
 	}
 	// Completely reset coldCounts.
 	h.resetCounts(cold)
 	// Repeat the latest observation to not lose it completely.
 	cold.observe(value, bucket, true)
 	// Make coldCounts the new hot counts while ressetting countAndHotIdx.
 	n := atomic.SwapUint64(&h.countAndHotIdx, (coldIdx<<63)+1)
 	count := n & ((1 << 63) - 1)
 	waitForCooldown(count, hot)
 	// Finally, reset the formerly hot counts, too.
 	h.resetCounts(hot)
 	h.lastResetTime = h.now()
 	return true
 }
 // maybeWidenZeroBucket widens the zero bucket until it includes the existing
 // buckets closest to the zero bucket (which could be two, if an equidistant
 // negative and a positive bucket exists, but usually it's only one bucket to be
 // merged into the new wider zero bucket). h.sparseMaxZeroThreshold limits how
 // far the zero bucket can be extended, and if that's not enough to include an
 // existing bucket, the method returns false. The caller must have locked h.mtx.
 func (h *histogram) maybeWidenZeroBucket(hot, cold *histogramCounts) bool {
 	currentZeroThreshold := math.Float64frombits(atomic.LoadUint64(&hot.sparseZeroThresholdBits))
 	if currentZeroThreshold >= h.sparseMaxZeroThreshold {
 		return false
 	}
 	// Find the key of the bucket closest to zero.
 	smallestKey := findSmallestKey(&hot.sparseBucketsPositive)
 	smallestNegativeKey := findSmallestKey(&hot.sparseBucketsNegative)
 	if smallestNegativeKey < smallestKey {
 		smallestKey = smallestNegativeKey
 	}
 	if smallestKey == math.MaxInt32 {
 		return false
 	}
 	newZeroThreshold := getLe(smallestKey, atomic.LoadInt32(&hot.sparseSchema))
 	if newZeroThreshold > h.sparseMaxZeroThreshold {
 		return false // New threshold would exceed the max threshold.
 	}
 	atomic.StoreUint64(&cold.sparseZeroThresholdBits, math.Float64bits(newZeroThreshold))
 	// Remove applicable buckets.
 	if _, loaded := cold.sparseBucketsNegative.LoadAndDelete(smallestKey); loaded {
 		atomicDecUint32(&cold.sparseBucketsNumber)
 	}
 	if _, loaded := cold.sparseBucketsPositive.LoadAndDelete(smallestKey); loaded {
 		atomicDecUint32(&cold.sparseBucketsNumber)
 	}
 	// Make cold counts the new hot counts.
 	n := atomic.AddUint64(&h.countAndHotIdx, 1<<63)
 	count := n & ((1 << 63) - 1)
 	// Swap the pointer names to represent the new roles and make
 	// the rest less confusing.
 	hot, cold = cold, hot
 	waitForCooldown(count, cold)
 	// Add all the now cold counts to the new hot counts...
 	addAndResetCounts(hot, cold)
 	// ...adjust the new zero threshold in the cold counts, too...
 	atomic.StoreUint64(&cold.sparseZeroThresholdBits, math.Float64bits(newZeroThreshold))
 	// ...and then merge the newly deleted buckets into the wider zero
 	// bucket.
 	mergeAndDeleteOrAddAndReset := func(hotBuckets, coldBuckets *sync.Map) func(k, v interface{}) bool {
 		return func(k, v interface{}) bool {
 			key := k.(int)
 			bucket := v.(*int64)
 			if key == smallestKey {
 				// Merge into hot zero bucket...
 				atomic.AddUint64(&hot.sparseZeroBucket, uint64(atomic.LoadInt64(bucket)))
 				// ...and delete from cold counts.
 				coldBuckets.Delete(key)
 				atomicDecUint32(&cold.sparseBucketsNumber)
 			} else {
 				// Add to corresponding hot bucket...
 				if addToSparseBucket(hotBuckets, key, atomic.LoadInt64(bucket)) {
 					atomic.AddUint32(&hot.sparseBucketsNumber, 1)
 				}
 				// ...and reset cold bucket.
 				atomic.StoreInt64(bucket, 0)
 			}
 			return true
 		}
 	}
 	cold.sparseBucketsPositive.Range(mergeAndDeleteOrAddAndReset(&hot.sparseBucketsPositive, &cold.sparseBucketsPositive))
 	cold.sparseBucketsNegative.Range(mergeAndDeleteOrAddAndReset(&hot.sparseBucketsNegative, &cold.sparseBucketsNegative))
 	return true
 }
 // doubleBucketWidth doubles the bucket width (by decrementing the schema
 // number). Note that very sparse buckets could lead to a low reduction of the
 // bucket count (or even no reduction at all). The method does nothing if the
 // schema is already -4.
 func (h *histogram) doubleBucketWidth(hot, cold *histogramCounts) {
 	coldSchema := atomic.LoadInt32(&cold.sparseSchema)
 	if coldSchema == -4 {
 		return // Already at lowest resolution.
 	}
 	coldSchema--
 	atomic.StoreInt32(&cold.sparseSchema, coldSchema)
 	// Play it simple and just delete all cold buckets.
 	atomic.StoreUint32(&cold.sparseBucketsNumber, 0)
 	deleteSyncMap(&cold.sparseBucketsNegative)
 	deleteSyncMap(&cold.sparseBucketsPositive)
 	// Make coldCounts the new hot counts.
 	n := atomic.AddUint64(&h.countAndHotIdx, 1<<63)
 	count := n & ((1 << 63) - 1)
 	// Swap the pointer names to represent the new roles and make
 	// the rest less confusing.
 	hot, cold = cold, hot
 	waitForCooldown(count, cold)
 	// Add all the now cold counts to the new hot counts...
 	addAndResetCounts(hot, cold)
 	// ...adjust the schema in the cold counts, too...
 	atomic.StoreInt32(&cold.sparseSchema, coldSchema)
 	// ...and then merge the cold buckets into the wider hot buckets.
 	merge := func(hotBuckets *sync.Map) func(k, v interface{}) bool {
 		return func(k, v interface{}) bool {
 			key := k.(int)
 			bucket := v.(*int64)
 			// Adjust key to match the bucket to merge into.
 			if key > 0 {
 				key++
 			}
 			key /= 2
 			// Add to corresponding hot bucket.
 			if addToSparseBucket(hotBuckets, key, atomic.LoadInt64(bucket)) {
 				atomic.AddUint32(&hot.sparseBucketsNumber, 1)
 			}
 			return true
 		}
 	}
 	cold.sparseBucketsPositive.Range(merge(&hot.sparseBucketsPositive))
 	cold.sparseBucketsNegative.Range(merge(&hot.sparseBucketsNegative))
 	// Play it simple again and just delete all cold buckets.
 	atomic.StoreUint32(&cold.sparseBucketsNumber, 0)
 	deleteSyncMap(&cold.sparseBucketsNegative)
 	deleteSyncMap(&cold.sparseBucketsPositive)
 }
 func (h *histogram) resetCounts(counts *histogramCounts) {
 	atomic.StoreUint64(&counts.sumBits, 0)
 	atomic.StoreUint64(&counts.count, 0)
 	atomic.StoreUint64(&counts.sparseZeroBucket, 0)
 	atomic.StoreUint64(&counts.sparseZeroThresholdBits, math.Float64bits(h.sparseZeroThreshold))
 	atomic.StoreInt32(&counts.sparseSchema, h.sparseSchema)
 	atomic.StoreUint32(&counts.sparseBucketsNumber, 0)
 	for i := range h.upperBounds {
 		atomic.StoreUint64(&counts.buckets[i], 0)
 	}
 	deleteSyncMap(&counts.sparseBucketsNegative)
 	deleteSyncMap(&counts.sparseBucketsPositive)
 }
 // updateExemplar replaces the exemplar for the provided bucket. With empty
@ -1081,3 +1221,163 @@ func pickSparseSchema(bucketFactor float64) int32 {
 		return -int32(floor)
 	}
 }
 func makeSparseBuckets(buckets *sync.Map) *dto.SparseBuckets {
 	var ii []int
 	buckets.Range(func(k, v interface{}) bool {
 		ii = append(ii, k.(int))
 		return true
 	})
 	sort.Ints(ii)
 	if len(ii) == 0 {
 		return nil
 	}
 	sbs := dto.SparseBuckets{}
 	var prevCount int64
 	var nextI int
 	appendDelta := func(count int64) {
 		*sbs.Span[len(sbs.Span)-1].Length++
 		sbs.Delta = append(sbs.Delta, count-prevCount)
 		prevCount = count
 	}
 	for n, i := range ii {
 		v, _ := buckets.Load(i)
 		count := atomic.LoadInt64(v.(*int64))
 		// Multiple spans with only small gaps in between are probably
 		// encoded more efficiently as one larger span with a few empty
 		// buckets. Needs some research to find the sweet spot. For now,
 		// we assume that gaps of one ore two buckets should not create
 		// a new span.
 		iDelta := int32(i - nextI)
 		if n == 0 || iDelta > 2 {
 			// We have to create a new span, either because we are
 			// at the very beginning, or because we have found a gap
 			// of more than two buckets.
 			sbs.Span = append(sbs.Span, &dto.SparseBuckets_Span{
 				Offset: proto.Int32(iDelta),
 				Length: proto.Uint32(0),
 			})
 		} else {
 			// We have found a small gap (or no gap at all).
 			// Insert empty buckets as needed.
 			for j := int32(0); j < iDelta; j++ {
 				appendDelta(0)
 			}
 		}
 		appendDelta(count)
 		nextI = i + 1
 	}
 	return &sbs
 }
 // addToSparseBucket increments the sparse bucket at key by the provided
 // amount. It returns true if a new sparse bucket had to be created for that.
 func addToSparseBucket(buckets *sync.Map, key int, increment int64) bool {
 	if existingBucket, ok := buckets.Load(key); ok {
 		// Fast path without allocation.
 		atomic.AddInt64(existingBucket.(*int64), increment)
 		return false
 	}
 	// Bucket doesn't exist yet. Slow path allocating new counter.
 	newBucket := increment // TODO(beorn7): Check if this is sufficient to not let increment escape.
 	if actualBucket, loaded := buckets.LoadOrStore(key, &newBucket); loaded {
 		// The bucket was created concurrently in another goroutine.
 		// Have to increment after all.
 		atomic.AddInt64(actualBucket.(*int64), increment)
 		return false
 	}
 	return true
 }
 // addAndReset returns a function to be used with sync.Map.Range of spare
 // buckets in coldCounts. It increments the buckets in the provided hotBuckets
 // according to the buckets ranged through. It then resets all buckets ranged
 // through to 0 (but leaves them in place so that they don't need to get
 // recreated on the next scrape).
 func addAndReset(hotBuckets *sync.Map, bucketNumber *uint32) func(k, v interface{}) bool {
 	return func(k, v interface{}) bool {
 		bucket := v.(*int64)
 		if addToSparseBucket(hotBuckets, k.(int), atomic.LoadInt64(bucket)) {
 			atomic.AddUint32(bucketNumber, 1)
 		}
 		atomic.StoreInt64(bucket, 0)
 		return true
 	}
 }
 func deleteSyncMap(m *sync.Map) {
 	m.Range(func(k, v interface{}) bool {
 		m.Delete(k)
 		return true
 	})
 }
 func findSmallestKey(m *sync.Map) int {
 	result := math.MaxInt32
 	m.Range(func(k, v interface{}) bool {
 		key := k.(int)
 		if key < result {
 			result = key
 		}
 		return true
 	})
 	return result
 }
 func getLe(key int, schema int32) float64 {
 	if schema < 0 {
 		return math.Ldexp(1, key<<(-schema))
 	}
 	fracIdx := key & ((1 << schema) - 1)
 	frac := sparseBounds[schema][fracIdx]
 	exp := (key >> schema) + 1
 	return math.Ldexp(frac, exp)
 }
 // waitForCooldown returns after the count field in the provided histogramCounts
 // has reached the provided count value.
 func waitForCooldown(count uint64, counts *histogramCounts) {
 	for count != atomic.LoadUint64(&counts.count) {
 		runtime.Gosched() // Let observations get work done.
 	}
 }
 // atomicAddFloat adds the provided float atomically to another float
 // represented by the bit pattern the bits pointer is pointing to.
 func atomicAddFloat(bits *uint64, v float64) {
 	for {
 		loadedBits := atomic.LoadUint64(bits)
 		newBits := math.Float64bits(math.Float64frombits(loadedBits) + v)
 		if atomic.CompareAndSwapUint64(bits, loadedBits, newBits) {
 			break
 		}
 	}
 }
 // atomicDecUint32 atomically decrements the uint32 p points to.  See
 // https://pkg.go.dev/sync/atomic#AddUint32 to understand how this is done.
 func atomicDecUint32(p *uint32) {
 	atomic.AddUint32(p, ^uint32(0))
 }
 // addAndResetCounts adds certain fields (count, sum, conventional buckets,
 // sparse zero bucket) from the cold counts to the corresponding fields in the
 // hot counts. Those fields are then reset to 0 in the cold counts.
 func addAndResetCounts(hot, cold *histogramCounts) {
 	atomic.AddUint64(&hot.count, atomic.LoadUint64(&cold.count))
 	atomic.StoreUint64(&cold.count, 0)
 	coldSum := math.Float64frombits(atomic.LoadUint64(&cold.sumBits))
 	atomicAddFloat(&hot.sumBits, coldSum)
 	atomic.StoreUint64(&cold.sumBits, 0)
 	for i := range hot.buckets {
 		atomic.AddUint64(&hot.buckets[i], atomic.LoadUint64(&cold.buckets[i]))
 		atomic.StoreUint64(&cold.buckets[i], 0)
 	}
 	atomic.AddUint64(&hot.sparseZeroBucket, atomic.LoadUint64(&cold.sparseZeroBucket))
 	atomic.StoreUint64(&cold.sparseZeroBucket, 0)
 }
--- a/prometheus/histogram_test.go
+++ b/prometheus/histogram_test.go
@ -20,6 +20,7 @@ import (
 	"runtime"
 	"sort"
 	"sync"
 	"sync/atomic"
 	"testing"
 	"testing/quick"
 	"time"
@ -167,7 +168,7 @@ func TestHistogramConcurrency(t *testing.T) {
 		start.Add(1)
 		end.Add(concLevel)
-		sum := NewHistogram(HistogramOpts{
+		his := NewHistogram(HistogramOpts{
 			Name:    "test_histogram",
 			Help:    "helpless",
 			Buckets: testBuckets,
@ -188,9 +189,9 @@ func TestHistogramConcurrency(t *testing.T) {
 				start.Wait()
 				for _, v := range vals {
 					if n%2 == 0 {
-						sum.Observe(v)
+						his.Observe(v)
 					} else {
-						sum.(ExemplarObserver).ObserveWithExemplar(v, Labels{"foo": "bar"})
+						his.(ExemplarObserver).ObserveWithExemplar(v, Labels{"foo": "bar"})
 					}
 				}
 				end.Done()
@ -201,7 +202,7 @@ func TestHistogramConcurrency(t *testing.T) {
 		end.Wait()
 		m := &dto.Metric{}
-		sum.Write(m)
+		his.Write(m)
 		if got, want := int(*m.Histogram.SampleCount), total; got != want {
 			t.Errorf("got sample count %d, want %d", got, want)
 		}
@ -424,24 +425,24 @@ func TestHistogramExemplar(t *testing.T) {
 	}
 	expectedExemplars := []*dto.Exemplar{
 		nil,
-		&dto.Exemplar{
+		{
 			Label: []*dto.LabelPair{
-				&dto.LabelPair{Name: proto.String("id"), Value: proto.String("2")},
+				{Name: proto.String("id"), Value: proto.String("2")},
 			},
 			Value:     proto.Float64(1.6),
 			Timestamp: ts,
 		},
 		nil,
-		&dto.Exemplar{
+		{
 			Label: []*dto.LabelPair{
-				&dto.LabelPair{Name: proto.String("id"), Value: proto.String("3")},
+				{Name: proto.String("id"), Value: proto.String("3")},
 			},
 			Value:     proto.Float64(4),
 			Timestamp: ts,
 		},
-		&dto.Exemplar{
+		{
 			Label: []*dto.LabelPair{
-				&dto.LabelPair{Name: proto.String("id"), Value: proto.String("4")},
+				{Name: proto.String("id"), Value: proto.String("4")},
 			},
 			Value:     proto.Float64(4.5),
 			Timestamp: ts,
@ -471,9 +472,12 @@ func TestSparseHistogram(t *testing.T) {
 	scenarios := []struct {
 		name             string
-		observations  []float64
+		observations     []float64 // With simulated interval of 1m.
 		factor           float64
 		zeroThreshold    float64
 		maxBuckets       uint32
 		minResetDuration time.Duration
 		maxZeroThreshold float64
 		want             string // String representation of protobuf.
 	}{
 		{
@ -531,6 +535,101 @@ func TestSparseHistogram(t *testing.T) {
 			factor:       1.2,
 			want:         `sample_count:7 sample_sum:-inf sb_schema:2 sb_zero_threshold:2.938735877055719e-39 sb_zero_count:1 sb_negative:<span:<offset:2147483647 length:1 > delta:1 > sb_positive:<span:<offset:0 length:5 > delta:1 delta:-1 delta:2 delta:-2 delta:2 > `,
 		},
 		{
 			name:         "limited buckets but nothing triggered",
 			observations: []float64{0, 1, 1.2, 1.4, 1.8, 2},
 			factor:       1.2,
 			maxBuckets:   4,
 			want:         `sample_count:6 sample_sum:7.4 sb_schema:2 sb_zero_threshold:2.938735877055719e-39 sb_zero_count:1 sb_positive:<span:<offset:0 length:5 > delta:1 delta:-1 delta:2 delta:-2 delta:2 > `,
 		},
 		{
 			name:         "buckets limited by halving resolution",
 			observations: []float64{0, 1, 1.1, 1.2, 1.4, 1.8, 2, 3},
 			factor:       1.2,
 			maxBuckets:   4,
 			want:         `sample_count:8 sample_sum:11.5 sb_schema:1 sb_zero_threshold:2.938735877055719e-39 sb_zero_count:1 sb_positive:<span:<offset:0 length:5 > delta:1 delta:2 delta:-1 delta:-2 delta:1 > `,
 		},
 		{
 			name:             "buckets limited by widening the zero bucket",
 			observations:     []float64{0, 1, 1.1, 1.2, 1.4, 1.8, 2, 3},
 			factor:           1.2,
 			maxBuckets:       4,
 			maxZeroThreshold: 1.2,
 			want:             `sample_count:8 sample_sum:11.5 sb_schema:2 sb_zero_threshold:1 sb_zero_count:2 sb_positive:<span:<offset:1 length:7 > delta:1 delta:1 delta:-2 delta:2 delta:-2 delta:0 delta:1 > `,
 		},
 		{
 			name:             "buckets limited by widening the zero bucket twice",
 			observations:     []float64{0, 1, 1.1, 1.2, 1.4, 1.8, 2, 3, 4},
 			factor:           1.2,
 			maxBuckets:       4,
 			maxZeroThreshold: 1.2,
 			want:             `sample_count:9 sample_sum:15.5 sb_schema:2 sb_zero_threshold:1.189207115002721 sb_zero_count:3 sb_positive:<span:<offset:2 length:7 > delta:2 delta:-2 delta:2 delta:-2 delta:0 delta:1 delta:0 > `,
 		},
 		{
 			name:             "buckets limited by reset",
 			observations:     []float64{0, 1, 1.1, 1.2, 1.4, 1.8, 2, 3, 4},
 			factor:           1.2,
 			maxBuckets:       4,
 			maxZeroThreshold: 1.2,
 			minResetDuration: 5 * time.Minute,
 			want:             `sample_count:2 sample_sum:7 sb_schema:2 sb_zero_threshold:2.938735877055719e-39 sb_zero_count:0 sb_positive:<span:<offset:7 length:2 > delta:1 delta:0 > `,
 		},
 		{
 			name:         "limited buckets but nothing triggered, negative observations",
 			observations: []float64{0, -1, -1.2, -1.4, -1.8, -2},
 			factor:       1.2,
 			maxBuckets:   4,
 			want:         `sample_count:6 sample_sum:-7.4 sb_schema:2 sb_zero_threshold:2.938735877055719e-39 sb_zero_count:1 sb_negative:<span:<offset:0 length:5 > delta:1 delta:-1 delta:2 delta:-2 delta:2 > `,
 		},
 		{
 			name:         "buckets limited by halving resolution, negative observations",
 			observations: []float64{0, -1, -1.1, -1.2, -1.4, -1.8, -2, -3},
 			factor:       1.2,
 			maxBuckets:   4,
 			want:         `sample_count:8 sample_sum:-11.5 sb_schema:1 sb_zero_threshold:2.938735877055719e-39 sb_zero_count:1 sb_negative:<span:<offset:0 length:5 > delta:1 delta:2 delta:-1 delta:-2 delta:1 > `,
 		},
 		{
 			name:             "buckets limited by widening the zero bucket, negative observations",
 			observations:     []float64{0, -1, -1.1, -1.2, -1.4, -1.8, -2, -3},
 			factor:           1.2,
 			maxBuckets:       4,
 			maxZeroThreshold: 1.2,
 			want:             `sample_count:8 sample_sum:-11.5 sb_schema:2 sb_zero_threshold:1 sb_zero_count:2 sb_negative:<span:<offset:1 length:7 > delta:1 delta:1 delta:-2 delta:2 delta:-2 delta:0 delta:1 > `,
 		},
 		{
 			name:             "buckets limited by widening the zero bucket twice, negative observations",
 			observations:     []float64{0, -1, -1.1, -1.2, -1.4, -1.8, -2, -3, -4},
 			factor:           1.2,
 			maxBuckets:       4,
 			maxZeroThreshold: 1.2,
 			want:             `sample_count:9 sample_sum:-15.5 sb_schema:2 sb_zero_threshold:1.189207115002721 sb_zero_count:3 sb_negative:<span:<offset:2 length:7 > delta:2 delta:-2 delta:2 delta:-2 delta:0 delta:1 delta:0 > `,
 		},
 		{
 			name:             "buckets limited by reset, negative observations",
 			observations:     []float64{0, -1, -1.1, -1.2, -1.4, -1.8, -2, -3, -4},
 			factor:           1.2,
 			maxBuckets:       4,
 			maxZeroThreshold: 1.2,
 			minResetDuration: 5 * time.Minute,
 			want:             `sample_count:2 sample_sum:-7 sb_schema:2 sb_zero_threshold:2.938735877055719e-39 sb_zero_count:0 sb_negative:<span:<offset:7 length:2 > delta:1 delta:0 > `,
 		},
 		{
 			name:             "buckets limited by halving resolution, then reset",
 			observations:     []float64{0, 1, 1.1, 1.2, 1.4, 1.8, 2, 5, 5.1, 3, 4},
 			factor:           1.2,
 			maxBuckets:       4,
 			minResetDuration: 9 * time.Minute,
 			want:             `sample_count:2 sample_sum:7 sb_schema:2 sb_zero_threshold:2.938735877055719e-39 sb_zero_count:0 sb_positive:<span:<offset:7 length:2 > delta:1 delta:0 > `,
 		},
 		{
 			name:             "buckets limited by widening the zero bucket, then reset",
 			observations:     []float64{0, 1, 1.1, 1.2, 1.4, 1.8, 2, 5, 5.1, 3, 4},
 			factor:           1.2,
 			maxBuckets:       4,
 			maxZeroThreshold: 1.2,
 			minResetDuration: 9 * time.Minute,
 			want:             `sample_count:2 sample_sum:7 sb_schema:2 sb_zero_threshold:2.938735877055719e-39 sb_zero_count:0 sb_positive:<span:<offset:7 length:2 > delta:1 delta:0 > `,
 		},
 	}
 	for _, s := range scenarios {
@ -540,9 +639,18 @@ func TestSparseHistogram(t *testing.T) {
 				Help:                          "help",
 				SparseBucketsFactor:           s.factor,
 				SparseBucketsZeroThreshold:    s.zeroThreshold,
 				SparseBucketsMaxNumber:        s.maxBuckets,
 				SparseBucketsMinResetDuration: s.minResetDuration,
 				SparseBucketsMaxZeroThreshold: s.maxZeroThreshold,
 			})
 			ts := time.Now().Add(30 * time.Second)
 			now := func() time.Time {
 				return ts
 			}
 			his.(*histogram).now = now
 			for _, o := range s.observations {
 				his.Observe(o)
 				ts = ts.Add(time.Minute)
 			}
 			m := &dto.Metric{}
 			if err := his.Write(m); err != nil {
@ -556,3 +664,101 @@ func TestSparseHistogram(t *testing.T) {
 	}
 }
 func TestSparseHistogramConcurrency(t *testing.T) {
 	if testing.Short() {
 		t.Skip("Skipping test in short mode.")
 	}
 	rand.Seed(42)
 	it := func(n uint32) bool {
 		mutations := int(n%1e4 + 1e4)
 		concLevel := int(n%5 + 1)
 		total := mutations * concLevel
 		var start, end sync.WaitGroup
 		start.Add(1)
 		end.Add(concLevel)
 		his := NewHistogram(HistogramOpts{
 			Name:                          "test_sparse_histogram",
 			Help:                          "This help is sparse.",
 			SparseBucketsFactor:           1.05,
 			SparseBucketsZeroThreshold:    0.0000001,
 			SparseBucketsMaxNumber:        50,
 			SparseBucketsMinResetDuration: time.Hour, // Comment out to test for totals below.
 			SparseBucketsMaxZeroThreshold: 0.001,
 		})
 		ts := time.Now().Add(30 * time.Second).Unix()
 		now := func() time.Time {
 			return time.Unix(atomic.LoadInt64(&ts), 0)
 		}
 		his.(*histogram).now = now
 		allVars := make([]float64, total)
 		var sampleSum float64
 		for i := 0; i < concLevel; i++ {
 			vals := make([]float64, mutations)
 			for j := 0; j < mutations; j++ {
 				v := rand.NormFloat64()
 				vals[j] = v
 				allVars[i*mutations+j] = v
 				sampleSum += v
 			}
 			go func(vals []float64) {
 				start.Wait()
 				for _, v := range vals {
 					// An observation every 1 to 10 seconds.
 					atomic.AddInt64(&ts, rand.Int63n(10)+1)
 					his.Observe(v)
 				}
 				end.Done()
 			}(vals)
 		}
 		sort.Float64s(allVars)
 		start.Done()
 		end.Wait()
 		m := &dto.Metric{}
 		his.Write(m)
 		// Uncomment these tests for totals only if you have disabled histogram resets above.
 		//
 		// if got, want := int(*m.Histogram.SampleCount), total; got != want {
 		// 	t.Errorf("got sample count %d, want %d", got, want)
 		// }
 		// if got, want := *m.Histogram.SampleSum, sampleSum; math.Abs((got-want)/want) > 0.001 {
 		// 	t.Errorf("got sample sum %f, want %f", got, want)
 		// }
 		sumBuckets := int(m.Histogram.GetSbZeroCount())
 		current := 0
 		for _, delta := range m.Histogram.GetSbNegative().GetDelta() {
 			current += int(delta)
 			if current < 0 {
 				t.Fatalf("negative bucket population negative: %d", current)
 			}
 			sumBuckets += current
 		}
 		current = 0
 		for _, delta := range m.Histogram.GetSbPositive().GetDelta() {
 			current += int(delta)
 			if current < 0 {
 				t.Fatalf("positive bucket population negative: %d", current)
 			}
 			sumBuckets += current
 		}
 		if got, want := sumBuckets, int(*m.Histogram.SampleCount); got != want {
 			t.Errorf("got bucket population sum %d, want %d", got, want)
 		}
 		return true
 	}
 	if err := quick.Check(it, nil); err != nil {
 		t.Error(err)
 	}
 }