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388 lines
12 KiB
388 lines
12 KiB
// Copyright 2015 The Prometheus Authors |
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// Licensed under the Apache License, Version 2.0 (the "License"); |
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// you may not use this file except in compliance with the License. |
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// You may obtain a copy of the License at |
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// |
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// http://www.apache.org/licenses/LICENSE-2.0 |
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// |
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// Unless required by applicable law or agreed to in writing, software |
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// distributed under the License is distributed on an "AS IS" BASIS, |
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
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// See the License for the specific language governing permissions and |
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// limitations under the License. |
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package promql |
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import ( |
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"math" |
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"sort" |
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"github.com/prometheus/prometheus/model/histogram" |
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"github.com/prometheus/prometheus/model/labels" |
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) |
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// Helpers to calculate quantiles. |
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// excludedLabels are the labels to exclude from signature calculation for |
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// quantiles. |
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var excludedLabels = []string{ |
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labels.MetricName, |
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labels.BucketLabel, |
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} |
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type bucket struct { |
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upperBound float64 |
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count float64 |
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} |
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// buckets implements sort.Interface. |
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type buckets []bucket |
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func (b buckets) Len() int { return len(b) } |
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func (b buckets) Swap(i, j int) { b[i], b[j] = b[j], b[i] } |
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func (b buckets) Less(i, j int) bool { return b[i].upperBound < b[j].upperBound } |
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type metricWithBuckets struct { |
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metric labels.Labels |
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buckets buckets |
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} |
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// bucketQuantile calculates the quantile 'q' based on the given buckets. The |
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// buckets will be sorted by upperBound by this function (i.e. no sorting |
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// needed before calling this function). The quantile value is interpolated |
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// assuming a linear distribution within a bucket. However, if the quantile |
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// falls into the highest bucket, the upper bound of the 2nd highest bucket is |
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// returned. A natural lower bound of 0 is assumed if the upper bound of the |
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// lowest bucket is greater 0. In that case, interpolation in the lowest bucket |
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// happens linearly between 0 and the upper bound of the lowest bucket. |
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// However, if the lowest bucket has an upper bound less or equal 0, this upper |
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// bound is returned if the quantile falls into the lowest bucket. |
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// |
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// There are a number of special cases (once we have a way to report errors |
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// happening during evaluations of AST functions, we should report those |
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// explicitly): |
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// |
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// If 'buckets' has 0 observations, NaN is returned. |
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// |
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// If 'buckets' has fewer than 2 elements, NaN is returned. |
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// |
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// If the highest bucket is not +Inf, NaN is returned. |
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// |
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// If q==NaN, NaN is returned. |
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// |
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// If q<0, -Inf is returned. |
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// |
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// If q>1, +Inf is returned. |
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func bucketQuantile(q float64, buckets buckets) float64 { |
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if math.IsNaN(q) { |
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return math.NaN() |
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} |
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if q < 0 { |
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return math.Inf(-1) |
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} |
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if q > 1 { |
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return math.Inf(+1) |
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} |
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sort.Sort(buckets) |
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if !math.IsInf(buckets[len(buckets)-1].upperBound, +1) { |
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return math.NaN() |
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} |
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buckets = coalesceBuckets(buckets) |
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ensureMonotonic(buckets) |
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if len(buckets) < 2 { |
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return math.NaN() |
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} |
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observations := buckets[len(buckets)-1].count |
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if observations == 0 { |
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return math.NaN() |
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} |
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rank := q * observations |
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b := sort.Search(len(buckets)-1, func(i int) bool { return buckets[i].count >= rank }) |
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if b == len(buckets)-1 { |
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return buckets[len(buckets)-2].upperBound |
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} |
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if b == 0 && buckets[0].upperBound <= 0 { |
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return buckets[0].upperBound |
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} |
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var ( |
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bucketStart float64 |
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bucketEnd = buckets[b].upperBound |
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count = buckets[b].count |
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) |
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if b > 0 { |
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bucketStart = buckets[b-1].upperBound |
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count -= buckets[b-1].count |
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rank -= buckets[b-1].count |
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} |
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return bucketStart + (bucketEnd-bucketStart)*(rank/count) |
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} |
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// histogramQuantile calculates the quantile 'q' based on the given histogram. |
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// |
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// The quantile value is interpolated assuming a linear distribution within a |
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// bucket. |
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// TODO(beorn7): Find an interpolation method that is a better fit for |
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// exponential buckets (and think about configurable interpolation). |
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// |
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// A natural lower bound of 0 is assumed if the histogram has only positive |
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// buckets. Likewise, a natural upper bound of 0 is assumed if the histogram has |
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// only negative buckets. |
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// TODO(beorn7): Come to terms if we want that. |
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// |
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// There are a number of special cases (once we have a way to report errors |
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// happening during evaluations of AST functions, we should report those |
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// explicitly): |
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// |
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// If the histogram has 0 observations, NaN is returned. |
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// |
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// If q<0, -Inf is returned. |
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// |
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// If q>1, +Inf is returned. |
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// |
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// If q is NaN, NaN is returned. |
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func histogramQuantile(q float64, h *histogram.FloatHistogram) float64 { |
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if q < 0 { |
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return math.Inf(-1) |
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} |
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if q > 1 { |
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return math.Inf(+1) |
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} |
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if h.Count == 0 || math.IsNaN(q) { |
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return math.NaN() |
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} |
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var ( |
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bucket histogram.Bucket[float64] |
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count float64 |
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it = h.AllBucketIterator() |
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rank = q * h.Count |
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) |
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for it.Next() { |
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bucket = it.At() |
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count += bucket.Count |
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if count >= rank { |
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break |
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} |
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} |
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if bucket.Lower < 0 && bucket.Upper > 0 { |
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switch { |
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case len(h.NegativeBuckets) == 0 && len(h.PositiveBuckets) > 0: |
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// The result is in the zero bucket and the histogram has only |
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// positive buckets. So we consider 0 to be the lower bound. |
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bucket.Lower = 0 |
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case len(h.PositiveBuckets) == 0 && len(h.NegativeBuckets) > 0: |
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// The result is in the zero bucket and the histogram has only |
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// negative buckets. So we consider 0 to be the upper bound. |
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bucket.Upper = 0 |
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} |
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} |
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// Due to numerical inaccuracies, we could end up with a higher count |
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// than h.Count. Thus, make sure count is never higher than h.Count. |
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if count > h.Count { |
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count = h.Count |
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} |
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// We could have hit the highest bucket without even reaching the rank |
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// (this should only happen if the histogram contains observations of |
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// the value NaN), in which case we simply return the upper limit of the |
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// highest explicit bucket. |
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if count < rank { |
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return bucket.Upper |
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} |
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rank -= count - bucket.Count |
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// TODO(codesome): Use a better estimation than linear. |
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return bucket.Lower + (bucket.Upper-bucket.Lower)*(rank/bucket.Count) |
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} |
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// histogramFraction calculates the fraction of observations between the |
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// provided lower and upper bounds, based on the provided histogram. |
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// |
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// histogramFraction is in a certain way the inverse of histogramQuantile. If |
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// histogramQuantile(0.9, h) returns 123.4, then histogramFraction(-Inf, 123.4, h) |
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// returns 0.9. |
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// |
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// The same notes (and TODOs) with regard to interpolation and assumptions about |
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// the zero bucket boundaries apply as for histogramQuantile. |
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// |
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// Whether either boundary is inclusive or exclusive doesn’t actually matter as |
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// long as interpolation has to be performed anyway. In the case of a boundary |
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// coinciding with a bucket boundary, the inclusive or exclusive nature of the |
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// boundary determines the exact behavior of the threshold. With the current |
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// implementation, that means that lower is exclusive for positive values and |
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// inclusive for negative values, while upper is inclusive for positive values |
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// and exclusive for negative values. |
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// |
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// Special cases: |
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// |
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// If the histogram has 0 observations, NaN is returned. |
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// |
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// Use a lower bound of -Inf to get the fraction of all observations below the |
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// upper bound. |
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// |
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// Use an upper bound of +Inf to get the fraction of all observations above the |
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// lower bound. |
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// |
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// If lower or upper is NaN, NaN is returned. |
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// |
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// If lower >= upper and the histogram has at least 1 observation, zero is returned. |
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func histogramFraction(lower, upper float64, h *histogram.FloatHistogram) float64 { |
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if h.Count == 0 || math.IsNaN(lower) || math.IsNaN(upper) { |
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return math.NaN() |
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} |
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if lower >= upper { |
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return 0 |
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} |
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var ( |
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rank, lowerRank, upperRank float64 |
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lowerSet, upperSet bool |
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it = h.AllBucketIterator() |
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) |
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for it.Next() { |
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b := it.At() |
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if b.Lower < 0 && b.Upper > 0 { |
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switch { |
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case len(h.NegativeBuckets) == 0 && len(h.PositiveBuckets) > 0: |
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// This is the zero bucket and the histogram has only |
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// positive buckets. So we consider 0 to be the lower |
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// bound. |
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b.Lower = 0 |
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case len(h.PositiveBuckets) == 0 && len(h.NegativeBuckets) > 0: |
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// This is in the zero bucket and the histogram has only |
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// negative buckets. So we consider 0 to be the upper |
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// bound. |
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b.Upper = 0 |
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} |
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} |
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if !lowerSet && b.Lower >= lower { |
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lowerRank = rank |
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lowerSet = true |
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} |
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if !upperSet && b.Lower >= upper { |
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upperRank = rank |
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upperSet = true |
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} |
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if lowerSet && upperSet { |
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break |
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} |
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if !lowerSet && b.Lower < lower && b.Upper > lower { |
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lowerRank = rank + b.Count*(lower-b.Lower)/(b.Upper-b.Lower) |
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lowerSet = true |
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} |
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if !upperSet && b.Lower < upper && b.Upper > upper { |
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upperRank = rank + b.Count*(upper-b.Lower)/(b.Upper-b.Lower) |
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upperSet = true |
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} |
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if lowerSet && upperSet { |
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break |
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} |
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rank += b.Count |
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} |
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if !lowerSet || lowerRank > h.Count { |
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lowerRank = h.Count |
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} |
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if !upperSet || upperRank > h.Count { |
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upperRank = h.Count |
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} |
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return (upperRank - lowerRank) / h.Count |
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} |
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// coalesceBuckets merges buckets with the same upper bound. |
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// |
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// The input buckets must be sorted. |
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func coalesceBuckets(buckets buckets) buckets { |
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last := buckets[0] |
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i := 0 |
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for _, b := range buckets[1:] { |
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if b.upperBound == last.upperBound { |
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last.count += b.count |
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} else { |
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buckets[i] = last |
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last = b |
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i++ |
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} |
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} |
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buckets[i] = last |
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return buckets[:i+1] |
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} |
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// The assumption that bucket counts increase monotonically with increasing |
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// upperBound may be violated during: |
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// |
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// * Recording rule evaluation of histogram_quantile, especially when rate() |
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// has been applied to the underlying bucket timeseries. |
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// * Evaluation of histogram_quantile computed over federated bucket |
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// timeseries, especially when rate() has been applied. |
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// |
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// This is because scraped data is not made available to rule evaluation or |
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// federation atomically, so some buckets are computed with data from the |
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// most recent scrapes, but the other buckets are missing data from the most |
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// recent scrape. |
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// |
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// Monotonicity is usually guaranteed because if a bucket with upper bound |
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// u1 has count c1, then any bucket with a higher upper bound u > u1 must |
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// have counted all c1 observations and perhaps more, so that c >= c1. |
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// |
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// Randomly interspersed partial sampling breaks that guarantee, and rate() |
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// exacerbates it. Specifically, suppose bucket le=1000 has a count of 10 from |
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// 4 samples but the bucket with le=2000 has a count of 7 from 3 samples. The |
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// monotonicity is broken. It is exacerbated by rate() because under normal |
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// operation, cumulative counting of buckets will cause the bucket counts to |
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// diverge such that small differences from missing samples are not a problem. |
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// rate() removes this divergence.) |
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// |
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// bucketQuantile depends on that monotonicity to do a binary search for the |
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// bucket with the φ-quantile count, so breaking the monotonicity |
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// guarantee causes bucketQuantile() to return undefined (nonsense) results. |
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// |
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// As a somewhat hacky solution until ingestion is atomic per scrape, we |
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// calculate the "envelope" of the histogram buckets, essentially removing |
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// any decreases in the count between successive buckets. |
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func ensureMonotonic(buckets buckets) { |
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max := buckets[0].count |
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for i := 1; i < len(buckets); i++ { |
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switch { |
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case buckets[i].count > max: |
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max = buckets[i].count |
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case buckets[i].count < max: |
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buckets[i].count = max |
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} |
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} |
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} |
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// quantile calculates the given quantile of a vector of samples. |
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// |
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// The Vector will be sorted. |
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// If 'values' has zero elements, NaN is returned. |
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// If q==NaN, NaN is returned. |
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// If q<0, -Inf is returned. |
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// If q>1, +Inf is returned. |
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func quantile(q float64, values vectorByValueHeap) float64 { |
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if len(values) == 0 || math.IsNaN(q) { |
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return math.NaN() |
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} |
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if q < 0 { |
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return math.Inf(-1) |
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} |
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if q > 1 { |
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return math.Inf(+1) |
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} |
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sort.Sort(values) |
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n := float64(len(values)) |
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// When the quantile lies between two samples, |
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// we use a weighted average of the two samples. |
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rank := q * (n - 1) |
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lowerIndex := math.Max(0, math.Floor(rank)) |
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upperIndex := math.Min(n-1, lowerIndex+1) |
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weight := rank - math.Floor(rank) |
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return values[int(lowerIndex)].F*(1-weight) + values[int(upperIndex)].F*weight |
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}
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