Retro68/gcc/libgo/go/internal/trace/parser.go

787 lines
23 KiB
Go
Raw Normal View History

2017-04-10 11:32:00 +00:00
// 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.
package trace
import (
"bufio"
"bytes"
"fmt"
"io"
"os"
"os/exec"
"sort"
"strconv"
"strings"
)
// Event describes one event in the trace.
type Event struct {
Off int // offset in input file (for debugging and error reporting)
Type byte // one of Ev*
Seq int64 // sequence number
Ts int64 // timestamp in nanoseconds
P int // P on which the event happened (can be one of TimerP, NetpollP, SyscallP)
G uint64 // G on which the event happened
StkID uint64 // unique stack ID
Stk []*Frame // stack trace (can be empty)
Args [3]uint64 // event-type-specific arguments
// linked event (can be nil), depends on event type:
// for GCStart: the GCStop
// for GCScanStart: the GCScanDone
// for GCSweepStart: the GCSweepDone
// for GoCreate: first GoStart of the created goroutine
// for GoStart: the associated GoEnd, GoBlock or other blocking event
// for GoSched/GoPreempt: the next GoStart
// for GoBlock and other blocking events: the unblock event
// for GoUnblock: the associated GoStart
// for blocking GoSysCall: the associated GoSysExit
// for GoSysExit: the next GoStart
Link *Event
}
// Frame is a frame in stack traces.
type Frame struct {
PC uint64
Fn string
File string
Line int
}
const (
// Special P identifiers:
FakeP = 1000000 + iota
TimerP // depicts timer unblocks
NetpollP // depicts network unblocks
SyscallP // depicts returns from syscalls
)
// Parse parses, post-processes and verifies the trace.
func Parse(r io.Reader) ([]*Event, error) {
rawEvents, err := readTrace(r)
if err != nil {
return nil, err
}
events, err := parseEvents(rawEvents)
if err != nil {
return nil, err
}
events, err = removeFutile(events)
if err != nil {
return nil, err
}
err = postProcessTrace(events)
if err != nil {
return nil, err
}
return events, nil
}
// rawEvent is a helper type used during parsing.
type rawEvent struct {
off int
typ byte
args []uint64
}
// readTrace does wire-format parsing and verification.
// It does not care about specific event types and argument meaning.
func readTrace(r io.Reader) ([]rawEvent, error) {
// Read and validate trace header.
var buf [16]byte
off, err := r.Read(buf[:])
if off != 16 || err != nil {
return nil, fmt.Errorf("failed to read header: read %v, err %v", off, err)
}
if bytes.Compare(buf[:], []byte("go 1.5 trace\x00\x00\x00\x00")) != 0 {
return nil, fmt.Errorf("not a trace file")
}
// Read events.
var events []rawEvent
for {
// Read event type and number of arguments (1 byte).
off0 := off
n, err := r.Read(buf[:1])
if err == io.EOF {
break
}
if err != nil || n != 1 {
return nil, fmt.Errorf("failed to read trace at offset 0x%x: n=%v err=%v", off0, n, err)
}
off += n
typ := buf[0] << 2 >> 2
narg := buf[0] >> 6
ev := rawEvent{typ: typ, off: off0}
if narg < 3 {
for i := 0; i < int(narg)+2; i++ { // sequence number and time stamp are present but not counted in narg
var v uint64
v, off, err = readVal(r, off)
if err != nil {
return nil, err
}
ev.args = append(ev.args, v)
}
} else {
// If narg == 3, the first value is length of the event in bytes.
var v uint64
v, off, err = readVal(r, off)
if err != nil {
return nil, err
}
evLen := v
off1 := off
for evLen > uint64(off-off1) {
v, off, err = readVal(r, off)
if err != nil {
return nil, err
}
ev.args = append(ev.args, v)
}
if evLen != uint64(off-off1) {
return nil, fmt.Errorf("event has wrong length at offset 0x%x: want %v, got %v", off0, evLen, off-off1)
}
}
events = append(events, ev)
}
return events, nil
}
// Parse events transforms raw events into events.
// It does analyze and verify per-event-type arguments.
func parseEvents(rawEvents []rawEvent) (events []*Event, err error) {
var ticksPerSec, lastSeq, lastTs int64
var lastG, timerGoid uint64
var lastP int
lastGs := make(map[int]uint64) // last goroutine running on P
stacks := make(map[uint64][]*Frame)
for _, raw := range rawEvents {
if raw.typ == EvNone || raw.typ >= EvCount {
err = fmt.Errorf("unknown event type %v at offset 0x%x", raw.typ, raw.off)
return
}
desc := EventDescriptions[raw.typ]
if desc.Name == "" {
err = fmt.Errorf("missing description for event type %v", raw.typ)
return
}
if raw.typ != EvStack {
narg := len(desc.Args)
if desc.Stack {
narg++
}
if raw.typ != EvBatch && raw.typ != EvFrequency && raw.typ != EvTimerGoroutine {
narg++ // sequence number
narg++ // timestamp
}
if len(raw.args) != narg {
err = fmt.Errorf("%v has wrong number of arguments at offset 0x%x: want %v, got %v",
desc.Name, raw.off, narg, len(raw.args))
return
}
}
switch raw.typ {
case EvBatch:
lastGs[lastP] = lastG
lastP = int(raw.args[0])
lastG = lastGs[lastP]
lastSeq = int64(raw.args[1])
lastTs = int64(raw.args[2])
case EvFrequency:
ticksPerSec = int64(raw.args[0])
if ticksPerSec <= 0 {
// The most likely cause for this is tick skew on different CPUs.
// For example, solaris/amd64 seems to have wildly different
// ticks on different CPUs.
err = ErrTimeOrder
return
}
case EvTimerGoroutine:
timerGoid = raw.args[0]
case EvStack:
if len(raw.args) < 2 {
err = fmt.Errorf("EvStack has wrong number of arguments at offset 0x%x: want at least 2, got %v",
raw.off, len(raw.args))
return
}
size := raw.args[1]
if size > 1000 {
err = fmt.Errorf("EvStack has bad number of frames at offset 0x%x: %v",
raw.off, size)
return
}
if uint64(len(raw.args)) != size+2 {
err = fmt.Errorf("EvStack has wrong number of arguments at offset 0x%x: want %v, got %v",
raw.off, size+2, len(raw.args))
return
}
id := raw.args[0]
if id != 0 && size > 0 {
stk := make([]*Frame, size)
for i := 0; i < int(size); i++ {
stk[i] = &Frame{PC: raw.args[i+2]}
}
stacks[id] = stk
}
default:
e := &Event{Off: raw.off, Type: raw.typ, P: lastP, G: lastG}
e.Seq = lastSeq + int64(raw.args[0])
e.Ts = lastTs + int64(raw.args[1])
lastSeq = e.Seq
lastTs = e.Ts
for i := range desc.Args {
e.Args[i] = raw.args[i+2]
}
if desc.Stack {
e.StkID = raw.args[len(desc.Args)+2]
}
switch raw.typ {
case EvGoStart:
lastG = e.Args[0]
e.G = lastG
case EvGCStart, EvGCDone, EvGCScanStart, EvGCScanDone:
e.G = 0
case EvGoEnd, EvGoStop, EvGoSched, EvGoPreempt,
EvGoSleep, EvGoBlock, EvGoBlockSend, EvGoBlockRecv,
EvGoBlockSelect, EvGoBlockSync, EvGoBlockCond, EvGoBlockNet,
EvGoSysBlock:
lastG = 0
case EvGoSysExit:
// EvGoSysExit emission is delayed until the thread has a P.
// Give it the real sequence number and time stamp.
e.Seq = int64(e.Args[1])
if e.Args[2] != 0 {
e.Ts = int64(e.Args[2])
}
}
events = append(events, e)
}
}
if len(events) == 0 {
err = fmt.Errorf("trace is empty")
return
}
// Attach stack traces.
for _, ev := range events {
if ev.StkID != 0 {
ev.Stk = stacks[ev.StkID]
}
}
// Sort by sequence number and translate cpu ticks to real time.
sort.Sort(eventList(events))
if ticksPerSec == 0 {
err = fmt.Errorf("no EvFrequency event")
return
}
minTs := events[0].Ts
for _, ev := range events {
ev.Ts = (ev.Ts - minTs) * 1e9 / ticksPerSec
// Move timers and syscalls to separate fake Ps.
if timerGoid != 0 && ev.G == timerGoid && ev.Type == EvGoUnblock {
ev.P = TimerP
}
if ev.Type == EvGoSysExit {
ev.P = SyscallP
ev.G = ev.Args[0]
}
}
return
}
// removeFutile removes all constituents of futile wakeups (block, unblock, start).
// For example, a goroutine was unblocked on a mutex, but another goroutine got
// ahead and acquired the mutex before the first goroutine is scheduled,
// so the first goroutine has to block again. Such wakeups happen on buffered
// channels and sync.Mutex, but are generally not interesting for end user.
func removeFutile(events []*Event) ([]*Event, error) {
// Two non-trivial aspects:
// 1. A goroutine can be preempted during a futile wakeup and migrate to another P.
// We want to remove all of that.
// 2. Tracing can start in the middle of a futile wakeup.
// That is, we can see a futile wakeup event w/o the actual wakeup before it.
// postProcessTrace runs after us and ensures that we leave the trace in a consistent state.
// Phase 1: determine futile wakeup sequences.
type G struct {
futile bool
wakeup []*Event // wakeup sequence (subject for removal)
}
gs := make(map[uint64]G)
futile := make(map[*Event]bool)
for _, ev := range events {
switch ev.Type {
case EvGoUnblock:
g := gs[ev.Args[0]]
g.wakeup = []*Event{ev}
gs[ev.Args[0]] = g
case EvGoStart, EvGoPreempt, EvFutileWakeup:
g := gs[ev.G]
g.wakeup = append(g.wakeup, ev)
if ev.Type == EvFutileWakeup {
g.futile = true
}
gs[ev.G] = g
case EvGoBlock, EvGoBlockSend, EvGoBlockRecv, EvGoBlockSelect, EvGoBlockSync, EvGoBlockCond:
g := gs[ev.G]
if g.futile {
futile[ev] = true
for _, ev1 := range g.wakeup {
futile[ev1] = true
}
}
delete(gs, ev.G)
}
}
// Phase 2: remove futile wakeup sequences.
newEvents := events[:0] // overwrite the original slice
for _, ev := range events {
if !futile[ev] {
newEvents = append(newEvents, ev)
}
}
return newEvents, nil
}
// ErrTimeOrder is returned by Parse when the trace contains
// time stamps that do not respect actual event ordering.
var ErrTimeOrder = fmt.Errorf("time stamps out of order")
// postProcessTrace does inter-event verification and information restoration.
// The resulting trace is guaranteed to be consistent
// (for example, a P does not run two Gs at the same time, or a G is indeed
// blocked before an unblock event).
func postProcessTrace(events []*Event) error {
const (
gDead = iota
gRunnable
gRunning
gWaiting
)
type gdesc struct {
state int
ev *Event
evStart *Event
evCreate *Event
}
type pdesc struct {
running bool
g uint64
evScan *Event
evSweep *Event
}
gs := make(map[uint64]gdesc)
ps := make(map[int]pdesc)
gs[0] = gdesc{state: gRunning}
var evGC *Event
checkRunning := func(p pdesc, g gdesc, ev *Event, allowG0 bool) error {
name := EventDescriptions[ev.Type].Name
if g.state != gRunning {
return fmt.Errorf("g %v is not running while %v (offset %v, time %v)", ev.G, name, ev.Off, ev.Ts)
}
if p.g != ev.G {
return fmt.Errorf("p %v is not running g %v while %v (offset %v, time %v)", ev.P, ev.G, name, ev.Off, ev.Ts)
}
if !allowG0 && ev.G == 0 {
return fmt.Errorf("g 0 did %v (offset %v, time %v)", EventDescriptions[ev.Type].Name, ev.Off, ev.Ts)
}
return nil
}
for _, ev := range events {
g := gs[ev.G]
p := ps[ev.P]
switch ev.Type {
case EvProcStart:
if p.running {
return fmt.Errorf("p %v is running before start (offset %v, time %v)", ev.P, ev.Off, ev.Ts)
}
p.running = true
case EvProcStop:
if !p.running {
return fmt.Errorf("p %v is not running before stop (offset %v, time %v)", ev.P, ev.Off, ev.Ts)
}
if p.g != 0 {
return fmt.Errorf("p %v is running a goroutine %v during stop (offset %v, time %v)", ev.P, p.g, ev.Off, ev.Ts)
}
p.running = false
case EvGCStart:
if evGC != nil {
return fmt.Errorf("previous GC is not ended before a new one (offset %v, time %v)", ev.Off, ev.Ts)
}
evGC = ev
case EvGCDone:
if evGC == nil {
return fmt.Errorf("bogus GC end (offset %v, time %v)", ev.Off, ev.Ts)
}
evGC.Link = ev
evGC = nil
case EvGCScanStart:
if p.evScan != nil {
return fmt.Errorf("previous scanning is not ended before a new one (offset %v, time %v)", ev.Off, ev.Ts)
}
p.evScan = ev
case EvGCScanDone:
if p.evScan == nil {
return fmt.Errorf("bogus scanning end (offset %v, time %v)", ev.Off, ev.Ts)
}
p.evScan.Link = ev
p.evScan = nil
case EvGCSweepStart:
if p.evSweep != nil {
return fmt.Errorf("previous sweeping is not ended before a new one (offset %v, time %v)", ev.Off, ev.Ts)
}
p.evSweep = ev
case EvGCSweepDone:
if p.evSweep == nil {
return fmt.Errorf("bogus sweeping end (offset %v, time %v)", ev.Off, ev.Ts)
}
p.evSweep.Link = ev
p.evSweep = nil
case EvGoWaiting:
g1 := gs[ev.Args[0]]
if g1.state != gRunnable {
return fmt.Errorf("g %v is not runnable before EvGoWaiting (offset %v, time %v)", ev.Args[0], ev.Off, ev.Ts)
}
g1.state = gWaiting
gs[ev.Args[0]] = g1
case EvGoInSyscall:
g1 := gs[ev.Args[0]]
if g1.state != gRunnable {
return fmt.Errorf("g %v is not runnable before EvGoInSyscall (offset %v, time %v)", ev.Args[0], ev.Off, ev.Ts)
}
g1.state = gWaiting
gs[ev.Args[0]] = g1
case EvGoCreate:
if err := checkRunning(p, g, ev, true); err != nil {
return err
}
if _, ok := gs[ev.Args[0]]; ok {
return fmt.Errorf("g %v already exists (offset %v, time %v)", ev.Args[0], ev.Off, ev.Ts)
}
gs[ev.Args[0]] = gdesc{state: gRunnable, ev: ev, evCreate: ev}
case EvGoStart:
if g.state != gRunnable {
return fmt.Errorf("g %v is not runnable before start (offset %v, time %v)", ev.G, ev.Off, ev.Ts)
}
if p.g != 0 {
return fmt.Errorf("p %v is already running g %v while start g %v (offset %v, time %v)", ev.P, p.g, ev.G, ev.Off, ev.Ts)
}
g.state = gRunning
g.evStart = ev
p.g = ev.G
if g.evCreate != nil {
// +1 because symbolizer expects return pc.
ev.Stk = []*Frame{{PC: g.evCreate.Args[1] + 1}}
g.evCreate = nil
}
if g.ev != nil {
g.ev.Link = ev
g.ev = nil
}
case EvGoEnd, EvGoStop:
if err := checkRunning(p, g, ev, false); err != nil {
return err
}
g.evStart.Link = ev
g.evStart = nil
g.state = gDead
p.g = 0
case EvGoSched, EvGoPreempt:
if err := checkRunning(p, g, ev, false); err != nil {
return err
}
g.state = gRunnable
g.evStart.Link = ev
g.evStart = nil
p.g = 0
g.ev = ev
case EvGoUnblock:
if g.state != gRunning {
return fmt.Errorf("g %v is not running while unpark (offset %v, time %v)", ev.G, ev.Off, ev.Ts)
}
if ev.P != TimerP && p.g != ev.G {
return fmt.Errorf("p %v is not running g %v while unpark (offset %v, time %v)", ev.P, ev.G, ev.Off, ev.Ts)
}
g1 := gs[ev.Args[0]]
if g1.state != gWaiting {
return fmt.Errorf("g %v is not waiting before unpark (offset %v, time %v)", ev.Args[0], ev.Off, ev.Ts)
}
if g1.ev != nil && g1.ev.Type == EvGoBlockNet && ev.P != TimerP {
ev.P = NetpollP
}
if g1.ev != nil {
g1.ev.Link = ev
}
g1.state = gRunnable
g1.ev = ev
gs[ev.Args[0]] = g1
case EvGoSysCall:
if err := checkRunning(p, g, ev, false); err != nil {
return err
}
g.ev = ev
case EvGoSysBlock:
if err := checkRunning(p, g, ev, false); err != nil {
return err
}
g.state = gWaiting
g.evStart.Link = ev
g.evStart = nil
p.g = 0
case EvGoSysExit:
if g.state != gWaiting {
return fmt.Errorf("g %v is not waiting during syscall exit (offset %v, time %v)", ev.G, ev.Off, ev.Ts)
}
if g.ev != nil && g.ev.Type == EvGoSysCall {
g.ev.Link = ev
}
g.state = gRunnable
g.ev = ev
case EvGoSleep, EvGoBlock, EvGoBlockSend, EvGoBlockRecv,
EvGoBlockSelect, EvGoBlockSync, EvGoBlockCond, EvGoBlockNet:
if err := checkRunning(p, g, ev, false); err != nil {
return err
}
g.state = gWaiting
g.ev = ev
g.evStart.Link = ev
g.evStart = nil
p.g = 0
}
gs[ev.G] = g
ps[ev.P] = p
}
// TODO(dvyukov): restore stacks for EvGoStart events.
// TODO(dvyukov): test that all EvGoStart events has non-nil Link.
// Last, after all the other consistency checks,
// make sure time stamps respect sequence numbers.
// The tests will skip (not fail) the test case if they see this error,
// so check everything else that could possibly be wrong first.
lastTs := int64(0)
for _, ev := range events {
if ev.Ts < lastTs {
return ErrTimeOrder
}
lastTs = ev.Ts
}
return nil
}
// symbolizeTrace attaches func/file/line info to stack traces.
func Symbolize(events []*Event, bin string) error {
// First, collect and dedup all pcs.
pcs := make(map[uint64]*Frame)
for _, ev := range events {
for _, f := range ev.Stk {
pcs[f.PC] = nil
}
}
// Start addr2line.
cmd := exec.Command("go", "tool", "addr2line", bin)
in, err := cmd.StdinPipe()
if err != nil {
return fmt.Errorf("failed to pipe addr2line stdin: %v", err)
}
cmd.Stderr = os.Stderr
out, err := cmd.StdoutPipe()
if err != nil {
return fmt.Errorf("failed to pipe addr2line stdout: %v", err)
}
err = cmd.Start()
if err != nil {
return fmt.Errorf("failed to start addr2line: %v", err)
}
outb := bufio.NewReader(out)
// Write all pcs to addr2line.
// Need to copy pcs to an array, because map iteration order is non-deterministic.
var pcArray []uint64
for pc := range pcs {
pcArray = append(pcArray, pc)
_, err := fmt.Fprintf(in, "0x%x\n", pc-1)
if err != nil {
return fmt.Errorf("failed to write to addr2line: %v", err)
}
}
in.Close()
// Read in answers.
for _, pc := range pcArray {
fn, err := outb.ReadString('\n')
if err != nil {
return fmt.Errorf("failed to read from addr2line: %v", err)
}
file, err := outb.ReadString('\n')
if err != nil {
return fmt.Errorf("failed to read from addr2line: %v", err)
}
f := &Frame{PC: pc}
f.Fn = fn[:len(fn)-1]
f.File = file[:len(file)-1]
if colon := strings.LastIndex(f.File, ":"); colon != -1 {
ln, err := strconv.Atoi(f.File[colon+1:])
if err == nil {
f.File = f.File[:colon]
f.Line = ln
}
}
pcs[pc] = f
}
cmd.Wait()
// Replace frames in events array.
for _, ev := range events {
for i, f := range ev.Stk {
ev.Stk[i] = pcs[f.PC]
}
}
return nil
}
// readVal reads unsigned base-128 value from r.
func readVal(r io.Reader, off0 int) (v uint64, off int, err error) {
off = off0
for i := 0; i < 10; i++ {
var buf [1]byte
var n int
n, err = r.Read(buf[:])
if err != nil || n != 1 {
return 0, 0, fmt.Errorf("failed to read trace at offset %d: read %v, error %v", off0, n, err)
}
off++
v |= uint64(buf[0]&0x7f) << (uint(i) * 7)
if buf[0]&0x80 == 0 {
return
}
}
return 0, 0, fmt.Errorf("bad value at offset 0x%x", off0)
}
type eventList []*Event
func (l eventList) Len() int {
return len(l)
}
func (l eventList) Less(i, j int) bool {
return l[i].Seq < l[j].Seq
}
func (l eventList) Swap(i, j int) {
l[i], l[j] = l[j], l[i]
}
// Print dumps events to stdout. For debugging.
func Print(events []*Event) {
for _, ev := range events {
desc := EventDescriptions[ev.Type]
fmt.Printf("%v %v p=%v g=%v off=%v", ev.Ts, desc.Name, ev.P, ev.G, ev.Off)
for i, a := range desc.Args {
fmt.Printf(" %v=%v", a, ev.Args[i])
}
fmt.Printf("\n")
}
}
// Event types in the trace.
// Verbatim copy from src/runtime/trace.go.
const (
EvNone = 0 // unused
EvBatch = 1 // start of per-P batch of events [pid, timestamp]
EvFrequency = 2 // contains tracer timer frequency [frequency (ticks per second)]
EvStack = 3 // stack [stack id, number of PCs, array of PCs]
EvGomaxprocs = 4 // current value of GOMAXPROCS [timestamp, GOMAXPROCS, stack id]
EvProcStart = 5 // start of P [timestamp, thread id]
EvProcStop = 6 // stop of P [timestamp]
EvGCStart = 7 // GC start [timestamp, stack id]
EvGCDone = 8 // GC done [timestamp]
EvGCScanStart = 9 // GC scan start [timestamp]
EvGCScanDone = 10 // GC scan done [timestamp]
EvGCSweepStart = 11 // GC sweep start [timestamp, stack id]
EvGCSweepDone = 12 // GC sweep done [timestamp]
EvGoCreate = 13 // goroutine creation [timestamp, new goroutine id, start PC, stack id]
EvGoStart = 14 // goroutine starts running [timestamp, goroutine id]
EvGoEnd = 15 // goroutine ends [timestamp]
EvGoStop = 16 // goroutine stops (like in select{}) [timestamp, stack]
EvGoSched = 17 // goroutine calls Gosched [timestamp, stack]
EvGoPreempt = 18 // goroutine is preempted [timestamp, stack]
EvGoSleep = 19 // goroutine calls Sleep [timestamp, stack]
EvGoBlock = 20 // goroutine blocks [timestamp, stack]
EvGoUnblock = 21 // goroutine is unblocked [timestamp, goroutine id, stack]
EvGoBlockSend = 22 // goroutine blocks on chan send [timestamp, stack]
EvGoBlockRecv = 23 // goroutine blocks on chan recv [timestamp, stack]
EvGoBlockSelect = 24 // goroutine blocks on select [timestamp, stack]
EvGoBlockSync = 25 // goroutine blocks on Mutex/RWMutex [timestamp, stack]
EvGoBlockCond = 26 // goroutine blocks on Cond [timestamp, stack]
EvGoBlockNet = 27 // goroutine blocks on network [timestamp, stack]
EvGoSysCall = 28 // syscall enter [timestamp, stack]
EvGoSysExit = 29 // syscall exit [timestamp, goroutine id, real timestamp]
EvGoSysBlock = 30 // syscall blocks [timestamp]
EvGoWaiting = 31 // denotes that goroutine is blocked when tracing starts [goroutine id]
EvGoInSyscall = 32 // denotes that goroutine is in syscall when tracing starts [goroutine id]
EvHeapAlloc = 33 // memstats.heap_alloc change [timestamp, heap_alloc]
EvNextGC = 34 // memstats.next_gc change [timestamp, next_gc]
EvTimerGoroutine = 35 // denotes timer goroutine [timer goroutine id]
EvFutileWakeup = 36 // denotes that the previous wakeup of this goroutine was futile [timestamp]
EvCount = 37
)
var EventDescriptions = [EvCount]struct {
Name string
Stack bool
Args []string
}{
EvNone: {"None", false, []string{}},
EvBatch: {"Batch", false, []string{"p", "seq", "ticks"}},
EvFrequency: {"Frequency", false, []string{"freq", "unused"}},
EvStack: {"Stack", false, []string{"id", "siz"}},
EvGomaxprocs: {"Gomaxprocs", true, []string{"procs"}},
EvProcStart: {"ProcStart", false, []string{"thread"}},
EvProcStop: {"ProcStop", false, []string{}},
EvGCStart: {"GCStart", true, []string{}},
EvGCDone: {"GCDone", false, []string{}},
EvGCScanStart: {"GCScanStart", false, []string{}},
EvGCScanDone: {"GCScanDone", false, []string{}},
EvGCSweepStart: {"GCSweepStart", true, []string{}},
EvGCSweepDone: {"GCSweepDone", false, []string{}},
EvGoCreate: {"GoCreate", true, []string{"g", "pc"}},
EvGoStart: {"GoStart", false, []string{"g"}},
EvGoEnd: {"GoEnd", false, []string{}},
EvGoStop: {"GoStop", true, []string{}},
EvGoSched: {"GoSched", true, []string{}},
EvGoPreempt: {"GoPreempt", true, []string{}},
EvGoSleep: {"GoSleep", true, []string{}},
EvGoBlock: {"GoBlock", true, []string{}},
EvGoUnblock: {"GoUnblock", true, []string{"g"}},
EvGoBlockSend: {"GoBlockSend", true, []string{}},
EvGoBlockRecv: {"GoBlockRecv", true, []string{}},
EvGoBlockSelect: {"GoBlockSelect", true, []string{}},
EvGoBlockSync: {"GoBlockSync", true, []string{}},
EvGoBlockCond: {"GoBlockCond", true, []string{}},
EvGoBlockNet: {"GoBlockNet", true, []string{}},
EvGoSysCall: {"GoSysCall", true, []string{}},
EvGoSysExit: {"GoSysExit", false, []string{"g", "seq", "ts"}},
EvGoSysBlock: {"GoSysBlock", false, []string{}},
EvGoWaiting: {"GoWaiting", false, []string{"g"}},
EvGoInSyscall: {"GoInSyscall", false, []string{"g"}},
EvHeapAlloc: {"HeapAlloc", false, []string{"mem"}},
EvNextGC: {"NextGC", false, []string{"mem"}},
EvTimerGoroutine: {"TimerGoroutine", false, []string{"g", "unused"}},
EvFutileWakeup: {"FutileWakeup", false, []string{}},
}