// Copyright 2014 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. // +build appengine package build import ( "fmt" "sort" "strconv" "strings" "appengine" "appengine/datastore" ) var knownTags = map[string]string{ "go1": "0051c7442fed9c888de6617fa9239a913904d96e", "go1.1": "d29da2ced72ba2cf48ed6a8f1ec4abc01e4c5bf1", "go1.2": "b1edf8faa5d6cbc50c6515785df9df9c19296564", "go1.3": "f153208c0a0e306bfca14f71ef11f09859ccabc8", } var lastRelease = "go1.3" func splitBench(benchProcs string) (string, int) { ss := strings.Split(benchProcs, "-") procs, _ := strconv.Atoi(ss[1]) return ss[0], procs } func dashPerfCommits(c appengine.Context, page int) ([]*Commit, error) { q := datastore.NewQuery("Commit"). Ancestor((&Package{}).Key(c)). Order("-Num"). Filter("NeedsBenchmarking =", true). Limit(commitsPerPage). Offset(page * commitsPerPage) var commits []*Commit _, err := q.GetAll(c, &commits) if err == nil && len(commits) == 0 { err = fmt.Errorf("no commits") } return commits, err } func perfChangeStyle(pc *PerfConfig, v float64, builder, benchmark, metric string) string { noise := pc.NoiseLevel(builder, benchmark, metric) if isNoise(v, noise) { return "noise" } if v > 0 { return "bad" } return "good" } func isNoise(diff, noise float64) bool { rnoise := -100 * noise / (noise + 100) return diff < noise && diff > rnoise } func perfDiff(old, new uint64) float64 { return 100*float64(new)/float64(old) - 100 } func isPerfFailed(res *PerfResult, builder string) bool { data := res.ParseData()[builder] return data != nil && data["meta-done"] != nil && !data["meta-done"].OK } // PerfResultCache caches a set of PerfResults so that it's easy to access them // without lots of duplicate accesses to datastore. // It allows to iterate over newer or older results for some base commit. type PerfResultCache struct { c appengine.Context newer bool iter *datastore.Iterator results map[int]*PerfResult } func MakePerfResultCache(c appengine.Context, com *Commit, newer bool) *PerfResultCache { p := &Package{} q := datastore.NewQuery("PerfResult").Ancestor(p.Key(c)).Limit(100) if newer { q = q.Filter("CommitNum >=", com.Num).Order("CommitNum") } else { q = q.Filter("CommitNum <=", com.Num).Order("-CommitNum") } rc := &PerfResultCache{c: c, newer: newer, iter: q.Run(c), results: make(map[int]*PerfResult)} return rc } func (rc *PerfResultCache) Get(commitNum int) *PerfResult { rc.Next(commitNum) // fetch the commit, if necessary return rc.results[commitNum] } // Next returns the next PerfResult for the commit commitNum. // It does not care whether the result has any data, failed or whatever. func (rc *PerfResultCache) Next(commitNum int) (*PerfResult, error) { // See if we have next result in the cache. next := -1 for ci := range rc.results { if rc.newer { if ci > commitNum && (next == -1 || ci < next) { next = ci } } else { if ci < commitNum && (next == -1 || ci > next) { next = ci } } } if next != -1 { return rc.results[next], nil } // Fetch next result from datastore. res := new(PerfResult) _, err := rc.iter.Next(res) if err == datastore.Done { return nil, nil } if err != nil { return nil, fmt.Errorf("fetching perf results: %v", err) } if (rc.newer && res.CommitNum < commitNum) || (!rc.newer && res.CommitNum > commitNum) { rc.c.Errorf("PerfResultCache.Next: bad commit num") } rc.results[res.CommitNum] = res return res, nil } // NextForComparison returns PerfResult which we need to use for performance comprison. // It skips failed results, but does not skip results with no data. func (rc *PerfResultCache) NextForComparison(commitNum int, builder string) (*PerfResult, error) { for { res, err := rc.Next(commitNum) if err != nil { return nil, err } if res == nil { return nil, nil } if res.CommitNum == commitNum { continue } parsed := res.ParseData() if builder != "" { // Comparing for a particular builder. // This is used in perf_changes and in email notifications. b := parsed[builder] if b == nil || b["meta-done"] == nil { // No results yet, must not do the comparison. return nil, nil } if b["meta-done"].OK { // Have complete results, compare. return res, nil } } else { // Comparing for all builders, find a result with at least // one successful meta-done. // This is used in perf_detail. for _, benchs := range parsed { if data := benchs["meta-done"]; data != nil && data.OK { return res, nil } } } // Failed, try next result. commitNum = res.CommitNum } } type PerfChange struct { Builder string Bench string Metric string Old uint64 New uint64 Diff float64 } func significantPerfChanges(pc *PerfConfig, builder string, prevRes, res *PerfResult) (changes []*PerfChange) { // First, collect all significant changes. for builder1, benchmarks1 := range res.ParseData() { if builder != "" && builder != builder1 { // This is not the builder you're looking for, Luke. continue } benchmarks0 := prevRes.ParseData()[builder1] if benchmarks0 == nil { continue } for benchmark, data1 := range benchmarks1 { data0 := benchmarks0[benchmark] if data0 == nil { continue } for metric, val := range data1.Metrics { val0 := data0.Metrics[metric] if val0 == 0 { continue } diff := perfDiff(val0, val) noise := pc.NoiseLevel(builder, benchmark, metric) if isNoise(diff, noise) { continue } ch := &PerfChange{Builder: builder, Bench: benchmark, Metric: metric, Old: val0, New: val, Diff: diff} changes = append(changes, ch) } } } // Then, strip non-repeatable changes (flakes). // The hypothesis is that a real change must show up with the majority of GOMAXPROCS values. majority := len(pc.ProcList(builder))/2 + 1 cnt := make(map[string]int) for _, ch := range changes { b, _ := splitBench(ch.Bench) name := b + "|" + ch.Metric if ch.Diff < 0 { name += "--" } cnt[name] = cnt[name] + 1 } for i := 0; i < len(changes); i++ { ch := changes[i] b, _ := splitBench(ch.Bench) name := b + "|" + ch.Metric if cnt[name] >= majority { continue } if cnt[name+"--"] >= majority { continue } // Remove flake. last := len(changes) - 1 changes[i] = changes[last] changes = changes[:last] i-- } return changes } // orderPrefTodo reorders commit nums for benchmarking todo. // The resulting order is somewhat tricky. We want 2 things: // 1. benchmark sequentially backwards (this provides information about most // recent changes, and allows to estimate noise levels) // 2. benchmark old commits in "scatter" order (this allows to quickly gather // brief information about thousands of old commits) // So this function interleaves the two orders. func orderPrefTodo(nums []int) []int { sort.Ints(nums) n := len(nums) pow2 := uint32(0) // next power-of-two that is >= n npow2 := 0 for npow2 <= n { pow2++ npow2 = 1 << pow2 } res := make([]int, n) resPos := n - 1 // result array is filled backwards present := make([]bool, n) // denotes values that already present in result array for i0, i1 := n-1, 0; i0 >= 0 || i1 < npow2; { // i0 represents "benchmark sequentially backwards" sequence // find the next commit that is not yet present and add it for cnt := 0; cnt < 2; cnt++ { for ; i0 >= 0; i0-- { if !present[i0] { present[i0] = true res[resPos] = nums[i0] resPos-- i0-- break } } } // i1 represents "scatter order" sequence // find the next commit that is not yet present and add it for ; i1 < npow2; i1++ { // do the "recursive split-ordering" trick idx := 0 // bitwise reverse of i1 for j := uint32(0); j <= pow2; j++ { if (i1 & (1 << j)) != 0 { idx = idx | (1 << (pow2 - j - 1)) } } if idx < n && !present[idx] { present[idx] = true res[resPos] = nums[idx] resPos-- i1++ break } } } // The above can't possibly be correct. Do dump check. res2 := make([]int, n) copy(res2, res) sort.Ints(res2) for i := range res2 { if res2[i] != nums[i] { panic(fmt.Sprintf("diff at %v: expect %v, want %v\nwas: %v\n become: %v", i, nums[i], res2[i], nums, res2)) } } return res }