// 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. // Serving of pprof-like profiles. package main import ( "bufio" "fmt" "internal/trace" "io" "net/http" "os" "os/exec" "path/filepath" "runtime" "sort" "strconv" "time" "github.com/google/pprof/profile" ) func goCmd() string { var exeSuffix string if runtime.GOOS == "windows" { exeSuffix = ".exe" } path := filepath.Join(runtime.GOROOT(), "bin", "go"+exeSuffix) if _, err := os.Stat(path); err == nil { return path } return "go" } func init() { http.HandleFunc("/io", serveSVGProfile(pprofByGoroutine(computePprofIO))) http.HandleFunc("/block", serveSVGProfile(pprofByGoroutine(computePprofBlock))) http.HandleFunc("/syscall", serveSVGProfile(pprofByGoroutine(computePprofSyscall))) http.HandleFunc("/sched", serveSVGProfile(pprofByGoroutine(computePprofSched))) http.HandleFunc("/regionio", serveSVGProfile(pprofByRegion(computePprofIO))) http.HandleFunc("/regionblock", serveSVGProfile(pprofByRegion(computePprofBlock))) http.HandleFunc("/regionsyscall", serveSVGProfile(pprofByRegion(computePprofSyscall))) http.HandleFunc("/regionsched", serveSVGProfile(pprofByRegion(computePprofSched))) } // Record represents one entry in pprof-like profiles. type Record struct { stk []*trace.Frame n uint64 time int64 } // interval represents a time interval in the trace. type interval struct { begin, end int64 // nanoseconds. } func pprofByGoroutine(compute func(io.Writer, map[uint64][]interval, []*trace.Event) error) func(w io.Writer, r *http.Request) error { return func(w io.Writer, r *http.Request) error { id := r.FormValue("id") events, err := parseEvents() if err != nil { return err } gToIntervals, err := pprofMatchingGoroutines(id, events) if err != nil { return err } return compute(w, gToIntervals, events) } } func pprofByRegion(compute func(io.Writer, map[uint64][]interval, []*trace.Event) error) func(w io.Writer, r *http.Request) error { return func(w io.Writer, r *http.Request) error { filter, err := newRegionFilter(r) if err != nil { return err } gToIntervals, err := pprofMatchingRegions(filter) if err != nil { return err } events, _ := parseEvents() return compute(w, gToIntervals, events) } } // pprofMatchingGoroutines parses the goroutine type id string (i.e. pc) // and returns the ids of goroutines of the matching type and its interval. // If the id string is empty, returns nil without an error. func pprofMatchingGoroutines(id string, events []*trace.Event) (map[uint64][]interval, error) { if id == "" { return nil, nil } pc, err := strconv.ParseUint(id, 10, 64) // id is string if err != nil { return nil, fmt.Errorf("invalid goroutine type: %v", id) } analyzeGoroutines(events) var res map[uint64][]interval for _, g := range gs { if g.PC != pc { continue } if res == nil { res = make(map[uint64][]interval) } endTime := g.EndTime if g.EndTime == 0 { endTime = lastTimestamp() // the trace doesn't include the goroutine end event. Use the trace end time. } res[g.ID] = []interval{{begin: g.StartTime, end: endTime}} } if len(res) == 0 && id != "" { return nil, fmt.Errorf("failed to find matching goroutines for id: %s", id) } return res, nil } // pprofMatchingRegions returns the time intervals of matching regions // grouped by the goroutine id. If the filter is nil, returns nil without an error. func pprofMatchingRegions(filter *regionFilter) (map[uint64][]interval, error) { res, err := analyzeAnnotations() if err != nil { return nil, err } if filter == nil { return nil, nil } gToIntervals := make(map[uint64][]interval) for id, regions := range res.regions { for _, s := range regions { if filter.match(id, s) { gToIntervals[s.G] = append(gToIntervals[s.G], interval{begin: s.firstTimestamp(), end: s.lastTimestamp()}) } } } for g, intervals := range gToIntervals { // in order to remove nested regions and // consider only the outermost regions, // first, we sort based on the start time // and then scan through to select only the outermost regions. sort.Slice(intervals, func(i, j int) bool { x := intervals[i].begin y := intervals[j].begin if x == y { return intervals[i].end < intervals[j].end } return x < y }) var lastTimestamp int64 var n int // select only the outermost regions. for _, i := range intervals { if lastTimestamp <= i.begin { intervals[n] = i // new non-overlapping region starts. lastTimestamp = i.end n++ } // otherwise, skip because this region overlaps with a previous region. } gToIntervals[g] = intervals[:n] } return gToIntervals, nil } // computePprofIO generates IO pprof-like profile (time spent in IO wait, currently only network blocking event). func computePprofIO(w io.Writer, gToIntervals map[uint64][]interval, events []*trace.Event) error { prof := make(map[uint64]Record) for _, ev := range events { if ev.Type != trace.EvGoBlockNet || ev.Link == nil || ev.StkID == 0 || len(ev.Stk) == 0 { continue } overlapping := pprofOverlappingDuration(gToIntervals, ev) if overlapping > 0 { rec := prof[ev.StkID] rec.stk = ev.Stk rec.n++ rec.time += overlapping.Nanoseconds() prof[ev.StkID] = rec } } return buildProfile(prof).Write(w) } // computePprofBlock generates blocking pprof-like profile (time spent blocked on synchronization primitives). func computePprofBlock(w io.Writer, gToIntervals map[uint64][]interval, events []*trace.Event) error { prof := make(map[uint64]Record) for _, ev := range events { switch ev.Type { case trace.EvGoBlockSend, trace.EvGoBlockRecv, trace.EvGoBlockSelect, trace.EvGoBlockSync, trace.EvGoBlockCond, trace.EvGoBlockGC: // TODO(hyangah): figure out why EvGoBlockGC should be here. // EvGoBlockGC indicates the goroutine blocks on GC assist, not // on synchronization primitives. default: continue } if ev.Link == nil || ev.StkID == 0 || len(ev.Stk) == 0 { continue } overlapping := pprofOverlappingDuration(gToIntervals, ev) if overlapping > 0 { rec := prof[ev.StkID] rec.stk = ev.Stk rec.n++ rec.time += overlapping.Nanoseconds() prof[ev.StkID] = rec } } return buildProfile(prof).Write(w) } // computePprofSyscall generates syscall pprof-like profile (time spent blocked in syscalls). func computePprofSyscall(w io.Writer, gToIntervals map[uint64][]interval, events []*trace.Event) error { prof := make(map[uint64]Record) for _, ev := range events { if ev.Type != trace.EvGoSysCall || ev.Link == nil || ev.StkID == 0 || len(ev.Stk) == 0 { continue } overlapping := pprofOverlappingDuration(gToIntervals, ev) if overlapping > 0 { rec := prof[ev.StkID] rec.stk = ev.Stk rec.n++ rec.time += overlapping.Nanoseconds() prof[ev.StkID] = rec } } return buildProfile(prof).Write(w) } // computePprofSched generates scheduler latency pprof-like profile // (time between a goroutine become runnable and actually scheduled for execution). func computePprofSched(w io.Writer, gToIntervals map[uint64][]interval, events []*trace.Event) error { prof := make(map[uint64]Record) for _, ev := range events { if (ev.Type != trace.EvGoUnblock && ev.Type != trace.EvGoCreate) || ev.Link == nil || ev.StkID == 0 || len(ev.Stk) == 0 { continue } overlapping := pprofOverlappingDuration(gToIntervals, ev) if overlapping > 0 { rec := prof[ev.StkID] rec.stk = ev.Stk rec.n++ rec.time += overlapping.Nanoseconds() prof[ev.StkID] = rec } } return buildProfile(prof).Write(w) } // pprofOverlappingDuration returns the overlapping duration between // the time intervals in gToIntervals and the specified event. // If gToIntervals is nil, this simply returns the event's duration. func pprofOverlappingDuration(gToIntervals map[uint64][]interval, ev *trace.Event) time.Duration { if gToIntervals == nil { // No filtering. return time.Duration(ev.Link.Ts-ev.Ts) * time.Nanosecond } intervals := gToIntervals[ev.G] if len(intervals) == 0 { return 0 } var overlapping time.Duration for _, i := range intervals { if o := overlappingDuration(i.begin, i.end, ev.Ts, ev.Link.Ts); o > 0 { overlapping += o } } return overlapping } // serveSVGProfile serves pprof-like profile generated by prof as svg. func serveSVGProfile(prof func(w io.Writer, r *http.Request) error) http.HandlerFunc { return func(w http.ResponseWriter, r *http.Request) { if r.FormValue("raw") != "" { w.Header().Set("Content-Type", "application/octet-stream") if err := prof(w, r); err != nil { w.Header().Set("Content-Type", "text/plain; charset=utf-8") w.Header().Set("X-Go-Pprof", "1") http.Error(w, fmt.Sprintf("failed to get profile: %v", err), http.StatusInternalServerError) return } return } blockf, err := os.CreateTemp("", "block") if err != nil { http.Error(w, fmt.Sprintf("failed to create temp file: %v", err), http.StatusInternalServerError) return } defer func() { blockf.Close() os.Remove(blockf.Name()) }() blockb := bufio.NewWriter(blockf) if err := prof(blockb, r); err != nil { http.Error(w, fmt.Sprintf("failed to generate profile: %v", err), http.StatusInternalServerError) return } if err := blockb.Flush(); err != nil { http.Error(w, fmt.Sprintf("failed to flush temp file: %v", err), http.StatusInternalServerError) return } if err := blockf.Close(); err != nil { http.Error(w, fmt.Sprintf("failed to close temp file: %v", err), http.StatusInternalServerError) return } svgFilename := blockf.Name() + ".svg" if output, err := exec.Command(goCmd(), "tool", "pprof", "-svg", "-output", svgFilename, blockf.Name()).CombinedOutput(); err != nil { http.Error(w, fmt.Sprintf("failed to execute go tool pprof: %v\n%s", err, output), http.StatusInternalServerError) return } defer os.Remove(svgFilename) w.Header().Set("Content-Type", "image/svg+xml") http.ServeFile(w, r, svgFilename) } } func buildProfile(prof map[uint64]Record) *profile.Profile { p := &profile.Profile{ PeriodType: &profile.ValueType{Type: "trace", Unit: "count"}, Period: 1, SampleType: []*profile.ValueType{ {Type: "contentions", Unit: "count"}, {Type: "delay", Unit: "nanoseconds"}, }, } locs := make(map[uint64]*profile.Location) funcs := make(map[string]*profile.Function) for _, rec := range prof { var sloc []*profile.Location for _, frame := range rec.stk { loc := locs[frame.PC] if loc == nil { fn := funcs[frame.File+frame.Fn] if fn == nil { fn = &profile.Function{ ID: uint64(len(p.Function) + 1), Name: frame.Fn, SystemName: frame.Fn, Filename: frame.File, } p.Function = append(p.Function, fn) funcs[frame.File+frame.Fn] = fn } loc = &profile.Location{ ID: uint64(len(p.Location) + 1), Address: frame.PC, Line: []profile.Line{ { Function: fn, Line: int64(frame.Line), }, }, } p.Location = append(p.Location, loc) locs[frame.PC] = loc } sloc = append(sloc, loc) } p.Sample = append(p.Sample, &profile.Sample{ Value: []int64{int64(rec.n), rec.time}, Location: sloc, }) } return p }