// Copyright 2017 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 trace import ( "container/heap" tracev2 "internal/trace/v2" "math" "sort" "strings" "time" ) // MutatorUtil is a change in mutator utilization at a particular // time. Mutator utilization functions are represented as a // time-ordered []MutatorUtil. type MutatorUtil struct { Time int64 // Util is the mean mutator utilization starting at Time. This // is in the range [0, 1]. Util float64 } // UtilFlags controls the behavior of MutatorUtilization. type UtilFlags int const ( // UtilSTW means utilization should account for STW events. // This includes non-GC STW events, which are typically user-requested. UtilSTW UtilFlags = 1 << iota // UtilBackground means utilization should account for // background mark workers. UtilBackground // UtilAssist means utilization should account for mark // assists. UtilAssist // UtilSweep means utilization should account for sweeping. UtilSweep // UtilPerProc means each P should be given a separate // utilization function. Otherwise, there is a single function // and each P is given a fraction of the utilization. UtilPerProc ) // MutatorUtilization returns a set of mutator utilization functions // for the given trace. Each function will always end with 0 // utilization. The bounds of each function are implicit in the first // and last event; outside of these bounds each function is undefined. // // If the UtilPerProc flag is not given, this always returns a single // utilization function. Otherwise, it returns one function per P. func MutatorUtilization(events []*Event, flags UtilFlags) [][]MutatorUtil { if len(events) == 0 { return nil } type perP struct { // gc > 0 indicates that GC is active on this P. gc int // series the logical series number for this P. This // is necessary because Ps may be removed and then // re-added, and then the new P needs a new series. series int } ps := []perP{} stw := 0 out := [][]MutatorUtil{} assists := map[uint64]bool{} block := map[uint64]*Event{} bgMark := map[uint64]bool{} for _, ev := range events { switch ev.Type { case EvGomaxprocs: gomaxprocs := int(ev.Args[0]) if len(ps) > gomaxprocs { if flags&UtilPerProc != 0 { // End each P's series. for _, p := range ps[gomaxprocs:] { out[p.series] = addUtil(out[p.series], MutatorUtil{ev.Ts, 0}) } } ps = ps[:gomaxprocs] } for len(ps) < gomaxprocs { // Start new P's series. series := 0 if flags&UtilPerProc != 0 || len(out) == 0 { series = len(out) out = append(out, []MutatorUtil{{ev.Ts, 1}}) } ps = append(ps, perP{series: series}) } case EvSTWStart: if flags&UtilSTW != 0 { stw++ } case EvSTWDone: if flags&UtilSTW != 0 { stw-- } case EvGCMarkAssistStart: if flags&UtilAssist != 0 { ps[ev.P].gc++ assists[ev.G] = true } case EvGCMarkAssistDone: if flags&UtilAssist != 0 { ps[ev.P].gc-- delete(assists, ev.G) } case EvGCSweepStart: if flags&UtilSweep != 0 { ps[ev.P].gc++ } case EvGCSweepDone: if flags&UtilSweep != 0 { ps[ev.P].gc-- } case EvGoStartLabel: if flags&UtilBackground != 0 && strings.HasPrefix(ev.SArgs[0], "GC ") && ev.SArgs[0] != "GC (idle)" { // Background mark worker. // // If we're in per-proc mode, we don't // count dedicated workers because // they kick all of the goroutines off // that P, so don't directly // contribute to goroutine latency. if !(flags&UtilPerProc != 0 && ev.SArgs[0] == "GC (dedicated)") { bgMark[ev.G] = true ps[ev.P].gc++ } } fallthrough case EvGoStart: if assists[ev.G] { // Unblocked during assist. ps[ev.P].gc++ } block[ev.G] = ev.Link default: if ev != block[ev.G] { continue } if assists[ev.G] { // Blocked during assist. ps[ev.P].gc-- } if bgMark[ev.G] { // Background mark worker done. ps[ev.P].gc-- delete(bgMark, ev.G) } delete(block, ev.G) } if flags&UtilPerProc == 0 { // Compute the current average utilization. if len(ps) == 0 { continue } gcPs := 0 if stw > 0 { gcPs = len(ps) } else { for i := range ps { if ps[i].gc > 0 { gcPs++ } } } mu := MutatorUtil{ev.Ts, 1 - float64(gcPs)/float64(len(ps))} // Record the utilization change. (Since // len(ps) == len(out), we know len(out) > 0.) out[0] = addUtil(out[0], mu) } else { // Check for per-P utilization changes. for i := range ps { p := &ps[i] util := 1.0 if stw > 0 || p.gc > 0 { util = 0.0 } out[p.series] = addUtil(out[p.series], MutatorUtil{ev.Ts, util}) } } } // Add final 0 utilization event to any remaining series. This // is important to mark the end of the trace. The exact value // shouldn't matter since no window should extend beyond this, // but using 0 is symmetric with the start of the trace. mu := MutatorUtil{events[len(events)-1].Ts, 0} for i := range ps { out[ps[i].series] = addUtil(out[ps[i].series], mu) } return out } // MutatorUtilizationV2 returns a set of mutator utilization functions // for the given v2 trace, passed as an io.Reader. Each function will // always end with 0 utilization. The bounds of each function are implicit // in the first and last event; outside of these bounds each function is // undefined. // // If the UtilPerProc flag is not given, this always returns a single // utilization function. Otherwise, it returns one function per P. func MutatorUtilizationV2(events []tracev2.Event, flags UtilFlags) [][]MutatorUtil { // Set up a bunch of analysis state. type perP struct { // gc > 0 indicates that GC is active on this P. gc int // series the logical series number for this P. This // is necessary because Ps may be removed and then // re-added, and then the new P needs a new series. series int } type procsCount struct { // time at which procs changed. time int64 // n is the number of procs at that point. n int } out := [][]MutatorUtil{} stw := 0 ps := []perP{} inGC := make(map[tracev2.GoID]bool) states := make(map[tracev2.GoID]tracev2.GoState) bgMark := make(map[tracev2.GoID]bool) procs := []procsCount{} seenSync := false // Helpers. handleSTW := func(r tracev2.Range) bool { return flags&UtilSTW != 0 && isGCSTW(r) } handleMarkAssist := func(r tracev2.Range) bool { return flags&UtilAssist != 0 && isGCMarkAssist(r) } handleSweep := func(r tracev2.Range) bool { return flags&UtilSweep != 0 && isGCSweep(r) } // Iterate through the trace, tracking mutator utilization. var lastEv *tracev2.Event for i := range events { ev := &events[i] lastEv = ev // Process the event. switch ev.Kind() { case tracev2.EventSync: seenSync = true case tracev2.EventMetric: m := ev.Metric() if m.Name != "/sched/gomaxprocs:threads" { break } gomaxprocs := int(m.Value.Uint64()) if len(ps) > gomaxprocs { if flags&UtilPerProc != 0 { // End each P's series. for _, p := range ps[gomaxprocs:] { out[p.series] = addUtil(out[p.series], MutatorUtil{int64(ev.Time()), 0}) } } ps = ps[:gomaxprocs] } for len(ps) < gomaxprocs { // Start new P's series. series := 0 if flags&UtilPerProc != 0 || len(out) == 0 { series = len(out) out = append(out, []MutatorUtil{{int64(ev.Time()), 1}}) } ps = append(ps, perP{series: series}) } if len(procs) == 0 || gomaxprocs != procs[len(procs)-1].n { procs = append(procs, procsCount{time: int64(ev.Time()), n: gomaxprocs}) } } if len(ps) == 0 { // We can't start doing any analysis until we see what GOMAXPROCS is. // It will show up very early in the trace, but we need to be robust to // something else being emitted beforehand. continue } switch ev.Kind() { case tracev2.EventRangeActive: if seenSync { // If we've seen a sync, then we can be sure we're not finding out about // something late; we have complete information after that point, and these // active events will just be redundant. break } // This range is active back to the start of the trace. We're failing to account // for this since we just found out about it now. Fix up the mutator utilization. // // N.B. A trace can't start during a STW, so we don't handle it here. r := ev.Range() switch { case handleMarkAssist(r): if !states[ev.Goroutine()].Executing() { // If the goroutine isn't executing, then the fact that it was in mark // assist doesn't actually count. break } // This G has been in a mark assist *and running on its P* since the start // of the trace. fallthrough case handleSweep(r): // This P has been in sweep (or mark assist, from above) in the start of the trace. // // We don't need to do anything if UtilPerProc is set. If we get an event like // this for a running P, it must show up the first time a P is mentioned. Therefore, // this P won't actually have any MutatorUtils on its list yet. // // However, if UtilPerProc isn't set, then we probably have data from other procs // and from previous events. We need to fix that up. if flags&UtilPerProc != 0 { break } // Subtract out 1/gomaxprocs mutator utilization for all time periods // from the beginning of the trace until now. mi, pi := 0, 0 for mi < len(out[0]) { if pi < len(procs)-1 && procs[pi+1].time < out[0][mi].Time { pi++ continue } out[0][mi].Util -= float64(1) / float64(procs[pi].n) if out[0][mi].Util < 0 { out[0][mi].Util = 0 } mi++ } } // After accounting for the portion we missed, this just acts like the // beginning of a new range. fallthrough case tracev2.EventRangeBegin: r := ev.Range() if handleSTW(r) { stw++ } else if handleSweep(r) { ps[ev.Proc()].gc++ } else if handleMarkAssist(r) { ps[ev.Proc()].gc++ if g := r.Scope.Goroutine(); g != tracev2.NoGoroutine { inGC[g] = true } } case tracev2.EventRangeEnd: r := ev.Range() if handleSTW(r) { stw-- } else if handleSweep(r) { ps[ev.Proc()].gc-- } else if handleMarkAssist(r) { ps[ev.Proc()].gc-- if g := r.Scope.Goroutine(); g != tracev2.NoGoroutine { delete(inGC, g) } } case tracev2.EventStateTransition: st := ev.StateTransition() if st.Resource.Kind != tracev2.ResourceGoroutine { break } old, new := st.Goroutine() g := st.Resource.Goroutine() if inGC[g] || bgMark[g] { if !old.Executing() && new.Executing() { // Started running while doing GC things. ps[ev.Proc()].gc++ } else if old.Executing() && !new.Executing() { // Stopped running while doing GC things. ps[ev.Proc()].gc-- } } states[g] = new case tracev2.EventLabel: l := ev.Label() if flags&UtilBackground != 0 && strings.HasPrefix(l.Label, "GC ") && l.Label != "GC (idle)" { // Background mark worker. // // If we're in per-proc mode, we don't // count dedicated workers because // they kick all of the goroutines off // that P, so don't directly // contribute to goroutine latency. if !(flags&UtilPerProc != 0 && l.Label == "GC (dedicated)") { bgMark[ev.Goroutine()] = true ps[ev.Proc()].gc++ } } } if flags&UtilPerProc == 0 { // Compute the current average utilization. if len(ps) == 0 { continue } gcPs := 0 if stw > 0 { gcPs = len(ps) } else { for i := range ps { if ps[i].gc > 0 { gcPs++ } } } mu := MutatorUtil{int64(ev.Time()), 1 - float64(gcPs)/float64(len(ps))} // Record the utilization change. (Since // len(ps) == len(out), we know len(out) > 0.) out[0] = addUtil(out[0], mu) } else { // Check for per-P utilization changes. for i := range ps { p := &ps[i] util := 1.0 if stw > 0 || p.gc > 0 { util = 0.0 } out[p.series] = addUtil(out[p.series], MutatorUtil{int64(ev.Time()), util}) } } } // No events in the stream. if lastEv == nil { return nil } // Add final 0 utilization event to any remaining series. This // is important to mark the end of the trace. The exact value // shouldn't matter since no window should extend beyond this, // but using 0 is symmetric with the start of the trace. mu := MutatorUtil{int64(lastEv.Time()), 0} for i := range ps { out[ps[i].series] = addUtil(out[ps[i].series], mu) } return out } func addUtil(util []MutatorUtil, mu MutatorUtil) []MutatorUtil { if len(util) > 0 { if mu.Util == util[len(util)-1].Util { // No change. return util } if mu.Time == util[len(util)-1].Time { // Take the lowest utilization at a time stamp. if mu.Util < util[len(util)-1].Util { util[len(util)-1] = mu } return util } } return append(util, mu) } // totalUtil is total utilization, measured in nanoseconds. This is a // separate type primarily to distinguish it from mean utilization, // which is also a float64. type totalUtil float64 func totalUtilOf(meanUtil float64, dur int64) totalUtil { return totalUtil(meanUtil * float64(dur)) } // mean returns the mean utilization over dur. func (u totalUtil) mean(dur time.Duration) float64 { return float64(u) / float64(dur) } // An MMUCurve is the minimum mutator utilization curve across // multiple window sizes. type MMUCurve struct { series []mmuSeries } type mmuSeries struct { util []MutatorUtil // sums[j] is the cumulative sum of util[:j]. sums []totalUtil // bands summarizes util in non-overlapping bands of duration // bandDur. bands []mmuBand // bandDur is the duration of each band. bandDur int64 } type mmuBand struct { // minUtil is the minimum instantaneous mutator utilization in // this band. minUtil float64 // cumUtil is the cumulative total mutator utilization between // time 0 and the left edge of this band. cumUtil totalUtil // integrator is the integrator for the left edge of this // band. integrator integrator } // NewMMUCurve returns an MMU curve for the given mutator utilization // function. func NewMMUCurve(utils [][]MutatorUtil) *MMUCurve { series := make([]mmuSeries, len(utils)) for i, util := range utils { series[i] = newMMUSeries(util) } return &MMUCurve{series} } // bandsPerSeries is the number of bands to divide each series into. // This is only changed by tests. var bandsPerSeries = 1000 func newMMUSeries(util []MutatorUtil) mmuSeries { // Compute cumulative sum. sums := make([]totalUtil, len(util)) var prev MutatorUtil var sum totalUtil for j, u := range util { sum += totalUtilOf(prev.Util, u.Time-prev.Time) sums[j] = sum prev = u } // Divide the utilization curve up into equal size // non-overlapping "bands" and compute a summary for each of // these bands. // // Compute the duration of each band. numBands := bandsPerSeries if numBands > len(util) { // There's no point in having lots of bands if there // aren't many events. numBands = len(util) } dur := util[len(util)-1].Time - util[0].Time bandDur := (dur + int64(numBands) - 1) / int64(numBands) if bandDur < 1 { bandDur = 1 } // Compute the bands. There are numBands+1 bands in order to // record the final cumulative sum. bands := make([]mmuBand, numBands+1) s := mmuSeries{util, sums, bands, bandDur} leftSum := integrator{&s, 0} for i := range bands { startTime, endTime := s.bandTime(i) cumUtil := leftSum.advance(startTime) predIdx := leftSum.pos minUtil := 1.0 for i := predIdx; i < len(util) && util[i].Time < endTime; i++ { minUtil = math.Min(minUtil, util[i].Util) } bands[i] = mmuBand{minUtil, cumUtil, leftSum} } return s } func (s *mmuSeries) bandTime(i int) (start, end int64) { start = int64(i)*s.bandDur + s.util[0].Time end = start + s.bandDur return } type bandUtil struct { // Utilization series index series int // Band index i int // Lower bound of mutator utilization for all windows // with a left edge in this band. utilBound float64 } type bandUtilHeap []bandUtil func (h bandUtilHeap) Len() int { return len(h) } func (h bandUtilHeap) Less(i, j int) bool { return h[i].utilBound < h[j].utilBound } func (h bandUtilHeap) Swap(i, j int) { h[i], h[j] = h[j], h[i] } func (h *bandUtilHeap) Push(x any) { *h = append(*h, x.(bandUtil)) } func (h *bandUtilHeap) Pop() any { x := (*h)[len(*h)-1] *h = (*h)[:len(*h)-1] return x } // UtilWindow is a specific window at Time. type UtilWindow struct { Time int64 // MutatorUtil is the mean mutator utilization in this window. MutatorUtil float64 } type utilHeap []UtilWindow func (h utilHeap) Len() int { return len(h) } func (h utilHeap) Less(i, j int) bool { if h[i].MutatorUtil != h[j].MutatorUtil { return h[i].MutatorUtil > h[j].MutatorUtil } return h[i].Time > h[j].Time } func (h utilHeap) Swap(i, j int) { h[i], h[j] = h[j], h[i] } func (h *utilHeap) Push(x any) { *h = append(*h, x.(UtilWindow)) } func (h *utilHeap) Pop() any { x := (*h)[len(*h)-1] *h = (*h)[:len(*h)-1] return x } // An accumulator takes a windowed mutator utilization function and // tracks various statistics for that function. type accumulator struct { mmu float64 // bound is the mutator utilization bound where adding any // mutator utilization above this bound cannot affect the // accumulated statistics. bound float64 // Worst N window tracking nWorst int wHeap utilHeap // Mutator utilization distribution tracking mud *mud // preciseMass is the distribution mass that must be precise // before accumulation is stopped. preciseMass float64 // lastTime and lastMU are the previous point added to the // windowed mutator utilization function. lastTime int64 lastMU float64 } // resetTime declares a discontinuity in the windowed mutator // utilization function by resetting the current time. func (acc *accumulator) resetTime() { // This only matters for distribution collection, since that's // the only thing that depends on the progression of the // windowed mutator utilization function. acc.lastTime = math.MaxInt64 } // addMU adds a point to the windowed mutator utilization function at // (time, mu). This must be called for monotonically increasing values // of time. // // It returns true if further calls to addMU would be pointless. func (acc *accumulator) addMU(time int64, mu float64, window time.Duration) bool { if mu < acc.mmu { acc.mmu = mu } acc.bound = acc.mmu if acc.nWorst == 0 { // If the minimum has reached zero, it can't go any // lower, so we can stop early. return mu == 0 } // Consider adding this window to the n worst. if len(acc.wHeap) < acc.nWorst || mu < acc.wHeap[0].MutatorUtil { // This window is lower than the K'th worst window. // // Check if there's any overlapping window // already in the heap and keep whichever is // worse. for i, ui := range acc.wHeap { if time+int64(window) > ui.Time && ui.Time+int64(window) > time { if ui.MutatorUtil <= mu { // Keep the first window. goto keep } else { // Replace it with this window. heap.Remove(&acc.wHeap, i) break } } } heap.Push(&acc.wHeap, UtilWindow{time, mu}) if len(acc.wHeap) > acc.nWorst { heap.Pop(&acc.wHeap) } keep: } if len(acc.wHeap) < acc.nWorst { // We don't have N windows yet, so keep accumulating. acc.bound = 1.0 } else { // Anything above the least worst window has no effect. acc.bound = math.Max(acc.bound, acc.wHeap[0].MutatorUtil) } if acc.mud != nil { if acc.lastTime != math.MaxInt64 { // Update distribution. acc.mud.add(acc.lastMU, mu, float64(time-acc.lastTime)) } acc.lastTime, acc.lastMU = time, mu if _, mudBound, ok := acc.mud.approxInvCumulativeSum(); ok { acc.bound = math.Max(acc.bound, mudBound) } else { // We haven't accumulated enough total precise // mass yet to even reach our goal, so keep // accumulating. acc.bound = 1 } // It's not worth checking percentiles every time, so // just keep accumulating this band. return false } // If we've found enough 0 utilizations, we can stop immediately. return len(acc.wHeap) == acc.nWorst && acc.wHeap[0].MutatorUtil == 0 } // MMU returns the minimum mutator utilization for the given time // window. This is the minimum utilization for all windows of this // duration across the execution. The returned value is in the range // [0, 1]. func (c *MMUCurve) MMU(window time.Duration) (mmu float64) { acc := accumulator{mmu: 1.0, bound: 1.0} c.mmu(window, &acc) return acc.mmu } // Examples returns n specific examples of the lowest mutator // utilization for the given window size. The returned windows will be // disjoint (otherwise there would be a huge number of // mostly-overlapping windows at the single lowest point). There are // no guarantees on which set of disjoint windows this returns. func (c *MMUCurve) Examples(window time.Duration, n int) (worst []UtilWindow) { acc := accumulator{mmu: 1.0, bound: 1.0, nWorst: n} c.mmu(window, &acc) sort.Sort(sort.Reverse(acc.wHeap)) return ([]UtilWindow)(acc.wHeap) } // MUD returns mutator utilization distribution quantiles for the // given window size. // // The mutator utilization distribution is the distribution of mean // mutator utilization across all windows of the given window size in // the trace. // // The minimum mutator utilization is the minimum (0th percentile) of // this distribution. (However, if only the minimum is desired, it's // more efficient to use the MMU method.) func (c *MMUCurve) MUD(window time.Duration, quantiles []float64) []float64 { if len(quantiles) == 0 { return []float64{} } // Each unrefined band contributes a known total mass to the // distribution (bandDur except at the end), but in an unknown // way. However, we know that all the mass it contributes must // be at or above its worst-case mean mutator utilization. // // Hence, we refine bands until the highest desired // distribution quantile is less than the next worst-case mean // mutator utilization. At this point, all further // contributions to the distribution must be beyond the // desired quantile and hence cannot affect it. // // First, find the highest desired distribution quantile. maxQ := quantiles[0] for _, q := range quantiles { if q > maxQ { maxQ = q } } // The distribution's mass is in units of time (it's not // normalized because this would make it more annoying to // account for future contributions of unrefined bands). The // total final mass will be the duration of the trace itself // minus the window size. Using this, we can compute the mass // corresponding to quantile maxQ. var duration int64 for _, s := range c.series { duration1 := s.util[len(s.util)-1].Time - s.util[0].Time if duration1 >= int64(window) { duration += duration1 - int64(window) } } qMass := float64(duration) * maxQ // Accumulate the MUD until we have precise information for // everything to the left of qMass. acc := accumulator{mmu: 1.0, bound: 1.0, preciseMass: qMass, mud: new(mud)} acc.mud.setTrackMass(qMass) c.mmu(window, &acc) // Evaluate the quantiles on the accumulated MUD. out := make([]float64, len(quantiles)) for i := range out { mu, _ := acc.mud.invCumulativeSum(float64(duration) * quantiles[i]) if math.IsNaN(mu) { // There are a few legitimate ways this can // happen: // // 1. If the window is the full trace // duration, then the windowed MU function is // only defined at a single point, so the MU // distribution is not well-defined. // // 2. If there are no events, then the MU // distribution has no mass. // // Either way, all of the quantiles will have // converged toward the MMU at this point. mu = acc.mmu } out[i] = mu } return out } func (c *MMUCurve) mmu(window time.Duration, acc *accumulator) { if window <= 0 { acc.mmu = 0 return } var bandU bandUtilHeap windows := make([]time.Duration, len(c.series)) for i, s := range c.series { windows[i] = window if max := time.Duration(s.util[len(s.util)-1].Time - s.util[0].Time); window > max { windows[i] = max } bandU1 := bandUtilHeap(s.mkBandUtil(i, windows[i])) if bandU == nil { bandU = bandU1 } else { bandU = append(bandU, bandU1...) } } // Process bands from lowest utilization bound to highest. heap.Init(&bandU) // Refine each band into a precise window and MMU until // refining the next lowest band can no longer affect the MMU // or windows. for len(bandU) > 0 && bandU[0].utilBound < acc.bound { i := bandU[0].series c.series[i].bandMMU(bandU[0].i, windows[i], acc) heap.Pop(&bandU) } } func (c *mmuSeries) mkBandUtil(series int, window time.Duration) []bandUtil { // For each band, compute the worst-possible total mutator // utilization for all windows that start in that band. // minBands is the minimum number of bands a window can span // and maxBands is the maximum number of bands a window can // span in any alignment. minBands := int((int64(window) + c.bandDur - 1) / c.bandDur) maxBands := int((int64(window) + 2*(c.bandDur-1)) / c.bandDur) if window > 1 && maxBands < 2 { panic("maxBands < 2") } tailDur := int64(window) % c.bandDur nUtil := len(c.bands) - maxBands + 1 if nUtil < 0 { nUtil = 0 } bandU := make([]bandUtil, nUtil) for i := range bandU { // To compute the worst-case MU, we assume the minimum // for any bands that are only partially overlapped by // some window and the mean for any bands that are // completely covered by all windows. var util totalUtil // Find the lowest and second lowest of the partial // bands. l := c.bands[i].minUtil r1 := c.bands[i+minBands-1].minUtil r2 := c.bands[i+maxBands-1].minUtil minBand := math.Min(l, math.Min(r1, r2)) // Assume the worst window maximally overlaps the // worst minimum and then the rest overlaps the second // worst minimum. if minBands == 1 { util += totalUtilOf(minBand, int64(window)) } else { util += totalUtilOf(minBand, c.bandDur) midBand := 0.0 switch { case minBand == l: midBand = math.Min(r1, r2) case minBand == r1: midBand = math.Min(l, r2) case minBand == r2: midBand = math.Min(l, r1) } util += totalUtilOf(midBand, tailDur) } // Add the total mean MU of bands that are completely // overlapped by all windows. if minBands > 2 { util += c.bands[i+minBands-1].cumUtil - c.bands[i+1].cumUtil } bandU[i] = bandUtil{series, i, util.mean(window)} } return bandU } // bandMMU computes the precise minimum mutator utilization for // windows with a left edge in band bandIdx. func (c *mmuSeries) bandMMU(bandIdx int, window time.Duration, acc *accumulator) { util := c.util // We think of the mutator utilization over time as the // box-filtered utilization function, which we call the // "windowed mutator utilization function". The resulting // function is continuous and piecewise linear (unless // window==0, which we handle elsewhere), where the boundaries // between segments occur when either edge of the window // encounters a change in the instantaneous mutator // utilization function. Hence, the minimum of this function // will always occur when one of the edges of the window // aligns with a utilization change, so these are the only // points we need to consider. // // We compute the mutator utilization function incrementally // by tracking the integral from t=0 to the left edge of the // window and to the right edge of the window. left := c.bands[bandIdx].integrator right := left time, endTime := c.bandTime(bandIdx) if utilEnd := util[len(util)-1].Time - int64(window); utilEnd < endTime { endTime = utilEnd } acc.resetTime() for { // Advance edges to time and time+window. mu := (right.advance(time+int64(window)) - left.advance(time)).mean(window) if acc.addMU(time, mu, window) { break } if time == endTime { break } // The maximum slope of the windowed mutator // utilization function is 1/window, so we can always // advance the time by at least (mu - mmu) * window // without dropping below mmu. minTime := time + int64((mu-acc.bound)*float64(window)) // Advance the window to the next time where either // the left or right edge of the window encounters a // change in the utilization curve. if t1, t2 := left.next(time), right.next(time+int64(window))-int64(window); t1 < t2 { time = t1 } else { time = t2 } if time < minTime { time = minTime } if time >= endTime { // For MMUs we could stop here, but for MUDs // it's important that we span the entire // band. time = endTime } } } // An integrator tracks a position in a utilization function and // integrates it. type integrator struct { u *mmuSeries // pos is the index in u.util of the current time's non-strict // predecessor. pos int } // advance returns the integral of the utilization function from 0 to // time. advance must be called on monotonically increasing values of // times. func (in *integrator) advance(time int64) totalUtil { util, pos := in.u.util, in.pos // Advance pos until pos+1 is time's strict successor (making // pos time's non-strict predecessor). // // Very often, this will be nearby, so we optimize that case, // but it may be arbitrarily far away, so we handled that // efficiently, too. const maxSeq = 8 if pos+maxSeq < len(util) && util[pos+maxSeq].Time > time { // Nearby. Use a linear scan. for pos+1 < len(util) && util[pos+1].Time <= time { pos++ } } else { // Far. Binary search for time's strict successor. l, r := pos, len(util) for l < r { h := int(uint(l+r) >> 1) if util[h].Time <= time { l = h + 1 } else { r = h } } pos = l - 1 // Non-strict predecessor. } in.pos = pos var partial totalUtil if time != util[pos].Time { partial = totalUtilOf(util[pos].Util, time-util[pos].Time) } return in.u.sums[pos] + partial } // next returns the smallest time t' > time of a change in the // utilization function. func (in *integrator) next(time int64) int64 { for _, u := range in.u.util[in.pos:] { if u.Time > time { return u.Time } } return 1<<63 - 1 } func isGCSTW(r tracev2.Range) bool { return strings.HasPrefix(r.Name, "stop-the-world") && strings.Contains(r.Name, "GC") } func isGCMarkAssist(r tracev2.Range) bool { return r.Name == "GC mark assist" } func isGCSweep(r tracev2.Range) bool { return r.Name == "GC incremental sweep" }