libgo/go/runtime/histogram.go - gofrontend - Git at Google

 // Copyright 2020 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package runtime

 import (
 	"runtime/internal/atomic"
 	"runtime/internal/sys"
 	"unsafe"
 )

 const (
 	// For the time histogram type, we use an HDR histogram.
 	// Values are placed in super-buckets based solely on the most
 	// significant set bit. Thus, super-buckets are power-of-2 sized.
 	// Values are then placed into sub-buckets based on the value of
 	// the next timeHistSubBucketBits most significant bits. Thus,
 	// sub-buckets are linear within a super-bucket.
 	//
 	// Therefore, the number of sub-buckets (timeHistNumSubBuckets)
 	// defines the error. This error may be computed as
 	// 1/timeHistNumSubBuckets*100%. For example, for 16 sub-buckets
 	// per super-bucket the error is approximately 6%.
 	//
 	// The number of super-buckets (timeHistNumSuperBuckets), on the
 	// other hand, defines the range. To reserve room for sub-buckets,
 	// bit timeHistSubBucketBits is the first bit considered for
 	// super-buckets, so super-bucket indices are adjusted accordingly.
 	//
 	// As an example, consider 45 super-buckets with 16 sub-buckets.
 	//
 	//    00110
 	//    ^----
 	//    │  ^
 	//    │  └---- Lowest 4 bits -> sub-bucket 6
 	//    └------- Bit 4 unset -> super-bucket 0
 	//
 	//    10110
 	//    ^----
 	//    │  ^
 	//    │  └---- Next 4 bits -> sub-bucket 6
 	//    └------- Bit 4 set -> super-bucket 1
 	//    100010
 	//    ^----^
 	//    │  ^ └-- Lower bits ignored
 	//    │  └---- Next 4 bits -> sub-bucket 1
 	//    └------- Bit 5 set -> super-bucket 2
 	//
 	// Following this pattern, bucket 45 will have the bit 48 set. We don't
 	// have any buckets for higher values, so the highest sub-bucket will
 	// contain values of 2^48-1 nanoseconds or approx. 3 days. This range is
 	// more than enough to handle durations produced by the runtime.
 	timeHistSubBucketBits   = 4
 	timeHistNumSubBuckets   = 1 << timeHistSubBucketBits
 	timeHistNumSuperBuckets = 45
 	timeHistTotalBuckets    = timeHistNumSuperBuckets*timeHistNumSubBuckets + 1
 )

 // timeHistogram represents a distribution of durations in
 // nanoseconds.
 //
 // The accuracy and range of the histogram is defined by the
 // timeHistSubBucketBits and timeHistNumSuperBuckets constants.
 //
 // It is an HDR histogram with exponentially-distributed
 // buckets and linearly distributed sub-buckets.
 //
 // Counts in the histogram are updated atomically, so it is safe
 // for concurrent use. It is also safe to read all the values
 // atomically.
 type timeHistogram struct {
 	counts [timeHistNumSuperBuckets * timeHistNumSubBuckets]uint64

 	// underflow counts all the times we got a negative duration
 	// sample. Because of how time works on some platforms, it's
 	// possible to measure negative durations. We could ignore them,
 	// but we record them anyway because it's better to have some
 	// signal that it's happening than just missing samples.
 	underflow uint64
 }

 // record adds the given duration to the distribution.
 func (h *timeHistogram) record(duration int64) {
 	if duration < 0 {
 		atomic.Xadd64(&h.underflow, 1)
 		return
 	}
 	// The index of the exponential bucket is just the index
 	// of the highest set bit adjusted for how many bits we
 	// use for the subbucket. Note that it's timeHistSubBucketsBits-1
 	// because we use the 0th bucket to hold values < timeHistNumSubBuckets.
 	var superBucket, subBucket uint
 	if duration >= timeHistNumSubBuckets {
 		// At this point, we know the duration value will always be
 		// at least timeHistSubBucketsBits long.
 		superBucket = uint(sys.Len64(uint64(duration))) - timeHistSubBucketBits
 		if superBucket*timeHistNumSubBuckets >= uint(len(h.counts)) {
 			// The bucket index we got is larger than what we support, so
 			// include this count in the highest bucket, which extends to
 			// infinity.
 			superBucket = timeHistNumSuperBuckets - 1
 			subBucket = timeHistNumSubBuckets - 1
 		} else {
 			// The linear subbucket index is just the timeHistSubBucketsBits
 			// bits after the top bit. To extract that value, shift down
 			// the duration such that we leave the top bit and the next bits
 			// intact, then extract the index.
 			subBucket = uint((duration >> (superBucket - 1)) % timeHistNumSubBuckets)
 		}
 	} else {
 		subBucket = uint(duration)
 	}
 	atomic.Xadd64(&h.counts[superBucket*timeHistNumSubBuckets+subBucket], 1)
 }

 const (
 	fInf    = 0x7FF0000000000000
 	fNegInf = 0xFFF0000000000000
 )

 func float64Inf() float64 {
 	inf := uint64(fInf)
 	return *(*float64)(unsafe.Pointer(&inf))
 }

 func float64NegInf() float64 {
 	inf := uint64(fNegInf)
 	return *(*float64)(unsafe.Pointer(&inf))
 }

 // timeHistogramMetricsBuckets generates a slice of boundaries for
 // the timeHistogram. These boundaries are represented in seconds,
 // not nanoseconds like the timeHistogram represents durations.
 func timeHistogramMetricsBuckets() []float64 {
 	b := make([]float64, timeHistTotalBuckets+1)
 	b[0] = float64NegInf()
 	for i := 0; i < timeHistNumSuperBuckets; i++ {
 		superBucketMin := uint64(0)
 		// The (inclusive) minimum for the first non-negative bucket is 0.
 		if i > 0 {
 			// The minimum for the second bucket will be
 			// 1 << timeHistSubBucketBits, indicating that all
 			// sub-buckets are represented by the next timeHistSubBucketBits
 			// bits.
 			// Thereafter, we shift up by 1 each time, so we can represent
 			// this pattern as (i-1)+timeHistSubBucketBits.
 			superBucketMin = uint64(1) << uint(i-1+timeHistSubBucketBits)
 		}
 		// subBucketShift is the amount that we need to shift the sub-bucket
 		// index to combine it with the bucketMin.
 		subBucketShift := uint(0)
 		if i > 1 {
 			// The first two super buckets are exact with respect to integers,
 			// so we'll never have to shift the sub-bucket index. Thereafter,
 			// we shift up by 1 with each subsequent bucket.
 			subBucketShift = uint(i - 2)
 		}
 		for j := 0; j < timeHistNumSubBuckets; j++ {
 			// j is the sub-bucket index. By shifting the index into position to
 			// combine with the bucket minimum, we obtain the minimum value for that
 			// sub-bucket.
 			subBucketMin := superBucketMin + (uint64(j) << subBucketShift)

 			// Convert the subBucketMin which is in nanoseconds to a float64 seconds value.
 			// These values will all be exactly representable by a float64.
 			b[i*timeHistNumSubBuckets+j+1] = float64(subBucketMin) / 1e9
 		}
 	}
 	b[len(b)-1] = float64Inf()
 	return b
 }
	// Copyright 2020 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package runtime

	import (
	"runtime/internal/atomic"
	"runtime/internal/sys"
	"unsafe"
	)

	const (
	// For the time histogram type, we use an HDR histogram.
	// Values are placed in super-buckets based solely on the most
	// significant set bit. Thus, super-buckets are power-of-2 sized.
	// Values are then placed into sub-buckets based on the value of
	// the next timeHistSubBucketBits most significant bits. Thus,
	// sub-buckets are linear within a super-bucket.
	//
	// Therefore, the number of sub-buckets (timeHistNumSubBuckets)
	// defines the error. This error may be computed as
	// 1/timeHistNumSubBuckets*100%. For example, for 16 sub-buckets
	// per super-bucket the error is approximately 6%.
	//
	// The number of super-buckets (timeHistNumSuperBuckets), on the
	// other hand, defines the range. To reserve room for sub-buckets,
	// bit timeHistSubBucketBits is the first bit considered for
	// super-buckets, so super-bucket indices are adjusted accordingly.
	//
	// As an example, consider 45 super-buckets with 16 sub-buckets.
	//
	// 00110
	// ^----
	// │ ^
	// │ └---- Lowest 4 bits -> sub-bucket 6
	// └------- Bit 4 unset -> super-bucket 0
	//
	// 10110
	// ^----
	// │ ^
	// │ └---- Next 4 bits -> sub-bucket 6
	// └------- Bit 4 set -> super-bucket 1
	// 100010
	// ^----^
	// │ ^ └-- Lower bits ignored
	// │ └---- Next 4 bits -> sub-bucket 1
	// └------- Bit 5 set -> super-bucket 2
	//
	// Following this pattern, bucket 45 will have the bit 48 set. We don't
	// have any buckets for higher values, so the highest sub-bucket will
	// contain values of 2^48-1 nanoseconds or approx. 3 days. This range is
	// more than enough to handle durations produced by the runtime.
	timeHistSubBucketBits = 4
	timeHistNumSubBuckets = 1 << timeHistSubBucketBits
	timeHistNumSuperBuckets = 45
	timeHistTotalBuckets = timeHistNumSuperBuckets*timeHistNumSubBuckets + 1
	)

	// timeHistogram represents a distribution of durations in
	// nanoseconds.
	//
	// The accuracy and range of the histogram is defined by the
	// timeHistSubBucketBits and timeHistNumSuperBuckets constants.
	//
	// It is an HDR histogram with exponentially-distributed
	// buckets and linearly distributed sub-buckets.
	//
	// Counts in the histogram are updated atomically, so it is safe
	// for concurrent use. It is also safe to read all the values
	// atomically.
	type timeHistogram struct {
	counts [timeHistNumSuperBuckets * timeHistNumSubBuckets]uint64

	// underflow counts all the times we got a negative duration
	// sample. Because of how time works on some platforms, it's
	// possible to measure negative durations. We could ignore them,
	// but we record them anyway because it's better to have some
	// signal that it's happening than just missing samples.
	underflow uint64
	}

	// record adds the given duration to the distribution.
	func (h *timeHistogram) record(duration int64) {
	if duration < 0 {
	atomic.Xadd64(&h.underflow, 1)
	return
	}
	// The index of the exponential bucket is just the index
	// of the highest set bit adjusted for how many bits we
	// use for the subbucket. Note that it's timeHistSubBucketsBits-1
	// because we use the 0th bucket to hold values < timeHistNumSubBuckets.
	var superBucket, subBucket uint
	if duration >= timeHistNumSubBuckets {
	// At this point, we know the duration value will always be
	// at least timeHistSubBucketsBits long.
	superBucket = uint(sys.Len64(uint64(duration))) - timeHistSubBucketBits
	if superBucket*timeHistNumSubBuckets >= uint(len(h.counts)) {
	// The bucket index we got is larger than what we support, so
	// include this count in the highest bucket, which extends to
	// infinity.
	superBucket = timeHistNumSuperBuckets - 1
	subBucket = timeHistNumSubBuckets - 1
	} else {
	// The linear subbucket index is just the timeHistSubBucketsBits
	// bits after the top bit. To extract that value, shift down
	// the duration such that we leave the top bit and the next bits
	// intact, then extract the index.
	subBucket = uint((duration >> (superBucket - 1)) % timeHistNumSubBuckets)
	}
	} else {
	subBucket = uint(duration)
	}
	atomic.Xadd64(&h.counts[superBucket*timeHistNumSubBuckets+subBucket], 1)
	}

	const (
	fInf = 0x7FF0000000000000
	fNegInf = 0xFFF0000000000000
	)

	func float64Inf() float64 {
	inf := uint64(fInf)
	return (float64)(unsafe.Pointer(&inf))
	}

	func float64NegInf() float64 {
	inf := uint64(fNegInf)
	return (float64)(unsafe.Pointer(&inf))
	}

	// timeHistogramMetricsBuckets generates a slice of boundaries for
	// the timeHistogram. These boundaries are represented in seconds,
	// not nanoseconds like the timeHistogram represents durations.
	func timeHistogramMetricsBuckets() []float64 {
	b := make([]float64, timeHistTotalBuckets+1)
	b[0] = float64NegInf()
	for i := 0; i < timeHistNumSuperBuckets; i++ {
	superBucketMin := uint64(0)
	// The (inclusive) minimum for the first non-negative bucket is 0.
	if i > 0 {
	// The minimum for the second bucket will be
	// 1 << timeHistSubBucketBits, indicating that all
	// sub-buckets are represented by the next timeHistSubBucketBits
	// bits.
	// Thereafter, we shift up by 1 each time, so we can represent
	// this pattern as (i-1)+timeHistSubBucketBits.
	superBucketMin = uint64(1) << uint(i-1+timeHistSubBucketBits)
	}
	// subBucketShift is the amount that we need to shift the sub-bucket
	// index to combine it with the bucketMin.
	subBucketShift := uint(0)
	if i > 1 {
	// The first two super buckets are exact with respect to integers,
	// so we'll never have to shift the sub-bucket index. Thereafter,
	// we shift up by 1 with each subsequent bucket.
	subBucketShift = uint(i - 2)
	}
	for j := 0; j < timeHistNumSubBuckets; j++ {
	// j is the sub-bucket index. By shifting the index into position to
	// combine with the bucket minimum, we obtain the minimum value for that
	// sub-bucket.
	subBucketMin := superBucketMin + (uint64(j) << subBucketShift)

	// Convert the subBucketMin which is in nanoseconds to a float64 seconds value.
	// These values will all be exactly representable by a float64.
	b[i*timeHistNumSubBuckets+j+1] = float64(subBucketMin) / 1e9
	}
	}
	b[len(b)-1] = float64Inf()
	return b
	}