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// Copyright 2023 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.
// Runtime -> tracer API.
package runtime
import (
"internal/runtime/atomic"
_ "unsafe" // for go:linkname
)
// gTraceState is per-G state for the tracer.
type gTraceState struct {
traceSchedResourceState
}
// reset resets the gTraceState for a new goroutine.
func (s *gTraceState) reset() {
s.seq = [2]uint64{}
// N.B. s.statusTraced is managed and cleared separately.
}
// mTraceState is per-M state for the tracer.
type mTraceState struct {
seqlock atomic.Uintptr // seqlock indicating that this M is writing to a trace buffer.
buf [2]*traceBuf // Per-M traceBuf for writing. Indexed by trace.gen%2.
link *m // Snapshot of alllink or freelink.
}
// pTraceState is per-P state for the tracer.
type pTraceState struct {
traceSchedResourceState
// mSyscallID is the ID of the M this was bound to before entering a syscall.
mSyscallID int64
// maySweep indicates the sweep events should be traced.
// This is used to defer the sweep start event until a span
// has actually been swept.
maySweep bool
// inSweep indicates that at least one sweep event has been traced.
inSweep bool
// swept and reclaimed track the number of bytes swept and reclaimed
// by sweeping in the current sweep loop (while maySweep was true).
swept, reclaimed uintptr
}
// traceLockInit initializes global trace locks.
func traceLockInit() {
// Sharing a lock rank here is fine because they should never be accessed
// together. If they are, we want to find out immediately.
lockInit(&trace.stringTab[0].lock, lockRankTraceStrings)
lockInit(&trace.stringTab[0].tab.mem.lock, lockRankTraceStrings)
lockInit(&trace.stringTab[1].lock, lockRankTraceStrings)
lockInit(&trace.stringTab[1].tab.mem.lock, lockRankTraceStrings)
lockInit(&trace.stackTab[0].tab.mem.lock, lockRankTraceStackTab)
lockInit(&trace.stackTab[1].tab.mem.lock, lockRankTraceStackTab)
lockInit(&trace.typeTab[0].tab.mem.lock, lockRankTraceTypeTab)
lockInit(&trace.typeTab[1].tab.mem.lock, lockRankTraceTypeTab)
lockInit(&trace.lock, lockRankTrace)
}
// lockRankMayTraceFlush records the lock ranking effects of a
// potential call to traceFlush.
//
// nosplit because traceAcquire is nosplit.
//
//go:nosplit
func lockRankMayTraceFlush() {
lockWithRankMayAcquire(&trace.lock, getLockRank(&trace.lock))
}
// traceBlockReason is an enumeration of reasons a goroutine might block.
// This is the interface the rest of the runtime uses to tell the
// tracer why a goroutine blocked. The tracer then propagates this information
// into the trace however it sees fit.
//
// Note that traceBlockReasons should not be compared, since reasons that are
// distinct by name may *not* be distinct by value.
type traceBlockReason uint8
const (
traceBlockGeneric traceBlockReason = iota
traceBlockForever
traceBlockNet
traceBlockSelect
traceBlockCondWait
traceBlockSync
traceBlockChanSend
traceBlockChanRecv
traceBlockGCMarkAssist
traceBlockGCSweep
traceBlockSystemGoroutine
traceBlockPreempted
traceBlockDebugCall
traceBlockUntilGCEnds
traceBlockSleep
)
var traceBlockReasonStrings = [...]string{
traceBlockGeneric: "unspecified",
traceBlockForever: "forever",
traceBlockNet: "network",
traceBlockSelect: "select",
traceBlockCondWait: "sync.(*Cond).Wait",
traceBlockSync: "sync",
traceBlockChanSend: "chan send",
traceBlockChanRecv: "chan receive",
traceBlockGCMarkAssist: "GC mark assist wait for work",
traceBlockGCSweep: "GC background sweeper wait",
traceBlockSystemGoroutine: "system goroutine wait",
traceBlockPreempted: "preempted",
traceBlockDebugCall: "wait for debug call",
traceBlockUntilGCEnds: "wait until GC ends",
traceBlockSleep: "sleep",
}
// traceGoStopReason is an enumeration of reasons a goroutine might yield.
//
// Note that traceGoStopReasons should not be compared, since reasons that are
// distinct by name may *not* be distinct by value.
type traceGoStopReason uint8
const (
traceGoStopGeneric traceGoStopReason = iota
traceGoStopGoSched
traceGoStopPreempted
)
var traceGoStopReasonStrings = [...]string{
traceGoStopGeneric: "unspecified",
traceGoStopGoSched: "runtime.Gosched",
traceGoStopPreempted: "preempted",
}
// traceEnabled returns true if the trace is currently enabled.
//
//go:nosplit
func traceEnabled() bool {
return trace.enabled
}
// traceAllocFreeEnabled returns true if the trace is currently enabled
// and alloc/free events are also enabled.
//
//go:nosplit
func traceAllocFreeEnabled() bool {
return trace.enabledWithAllocFree
}
// traceShuttingDown returns true if the trace is currently shutting down.
func traceShuttingDown() bool {
return trace.shutdown.Load()
}
// traceLocker represents an M writing trace events. While a traceLocker value
// is valid, the tracer observes all operations on the G/M/P or trace events being
// written as happening atomically.
type traceLocker struct {
mp *m
gen uintptr
}
// debugTraceReentrancy checks if the trace is reentrant.
//
// This is optional because throwing in a function makes it instantly
// not inlineable, and we want traceAcquire to be inlineable for
// low overhead when the trace is disabled.
const debugTraceReentrancy = false
// traceAcquire prepares this M for writing one or more trace events.
//
// nosplit because it's called on the syscall path when stack movement is forbidden.
//
//go:nosplit
func traceAcquire() traceLocker {
if !traceEnabled() {
return traceLocker{}
}
return traceAcquireEnabled()
}
// traceAcquireEnabled is the traceEnabled path for traceAcquire. It's explicitly
// broken out to make traceAcquire inlineable to keep the overhead of the tracer
// when it's disabled low.
//
// nosplit because it's called by traceAcquire, which is nosplit.
//
//go:nosplit
func traceAcquireEnabled() traceLocker {
// Any time we acquire a traceLocker, we may flush a trace buffer. But
// buffer flushes are rare. Record the lock edge even if it doesn't happen
// this time.
lockRankMayTraceFlush()
// Prevent preemption.
mp := acquirem()
// Acquire the trace seqlock. This prevents traceAdvance from moving forward
// until all Ms are observed to be outside of their seqlock critical section.
//
// Note: The seqlock is mutated here and also in traceCPUSample. If you update
// usage of the seqlock here, make sure to also look at what traceCPUSample is
// doing.
seq := mp.trace.seqlock.Add(1)
if debugTraceReentrancy && seq%2 != 1 {
throw("bad use of trace.seqlock or tracer is reentrant")
}
// N.B. This load of gen appears redundant with the one in traceEnabled.
// However, it's very important that the gen we use for writing to the trace
// is acquired under a traceLocker so traceAdvance can make sure no stale
// gen values are being used.
//
// Because we're doing this load again, it also means that the trace
// might end up being disabled when we load it. In that case we need to undo
// what we did and bail.
gen := trace.gen.Load()
if gen == 0 {
mp.trace.seqlock.Add(1)
releasem(mp)
return traceLocker{}
}
return traceLocker{mp, gen}
}
// ok returns true if the traceLocker is valid (i.e. tracing is enabled).
//
// nosplit because it's called on the syscall path when stack movement is forbidden.
//
//go:nosplit
func (tl traceLocker) ok() bool {
return tl.gen != 0
}
// traceRelease indicates that this M is done writing trace events.
//
// nosplit because it's called on the syscall path when stack movement is forbidden.
//
//go:nosplit
func traceRelease(tl traceLocker) {
seq := tl.mp.trace.seqlock.Add(1)
if debugTraceReentrancy && seq%2 != 0 {
print("runtime: seq=", seq, "\n")
throw("bad use of trace.seqlock")
}
releasem(tl.mp)
}
// traceExitingSyscall marks a goroutine as exiting the syscall slow path.
//
// Must be paired with a traceExitedSyscall call.
func traceExitingSyscall() {
trace.exitingSyscall.Add(1)
}
// traceExitedSyscall marks a goroutine as having exited the syscall slow path.
func traceExitedSyscall() {
trace.exitingSyscall.Add(-1)
}
// Gomaxprocs emits a ProcsChange event.
func (tl traceLocker) Gomaxprocs(procs int32) {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvProcsChange, traceArg(procs), tl.stack(1))
}
// ProcStart traces a ProcStart event.
//
// Must be called with a valid P.
func (tl traceLocker) ProcStart() {
pp := tl.mp.p.ptr()
// Procs are typically started within the scheduler when there is no user goroutine. If there is a user goroutine,
// it must be in _Gsyscall because the only time a goroutine is allowed to have its Proc moved around from under it
// is during a syscall.
tl.eventWriter(traceGoSyscall, traceProcIdle).commit(traceEvProcStart, traceArg(pp.id), pp.trace.nextSeq(tl.gen))
}
// ProcStop traces a ProcStop event.
func (tl traceLocker) ProcStop(pp *p) {
// The only time a goroutine is allowed to have its Proc moved around
// from under it is during a syscall.
tl.eventWriter(traceGoSyscall, traceProcRunning).commit(traceEvProcStop)
}
// GCActive traces a GCActive event.
//
// Must be emitted by an actively running goroutine on an active P. This restriction can be changed
// easily and only depends on where it's currently called.
func (tl traceLocker) GCActive() {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGCActive, traceArg(trace.seqGC))
// N.B. Only one GC can be running at a time, so this is naturally
// serialized by the caller.
trace.seqGC++
}
// GCStart traces a GCBegin event.
//
// Must be emitted by an actively running goroutine on an active P. This restriction can be changed
// easily and only depends on where it's currently called.
func (tl traceLocker) GCStart() {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGCBegin, traceArg(trace.seqGC), tl.stack(3))
// N.B. Only one GC can be running at a time, so this is naturally
// serialized by the caller.
trace.seqGC++
}
// GCDone traces a GCEnd event.
//
// Must be emitted by an actively running goroutine on an active P. This restriction can be changed
// easily and only depends on where it's currently called.
func (tl traceLocker) GCDone() {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGCEnd, traceArg(trace.seqGC))
// N.B. Only one GC can be running at a time, so this is naturally
// serialized by the caller.
trace.seqGC++
}
// STWStart traces a STWBegin event.
func (tl traceLocker) STWStart(reason stwReason) {
// Although the current P may be in _Pgcstop here, we model the P as running during the STW. This deviates from the
// runtime's state tracking, but it's more accurate and doesn't result in any loss of information.
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvSTWBegin, tl.string(reason.String()), tl.stack(2))
}
// STWDone traces a STWEnd event.
func (tl traceLocker) STWDone() {
// Although the current P may be in _Pgcstop here, we model the P as running during the STW. This deviates from the
// runtime's state tracking, but it's more accurate and doesn't result in any loss of information.
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvSTWEnd)
}
// GCSweepStart prepares to trace a sweep loop. This does not
// emit any events until traceGCSweepSpan is called.
//
// GCSweepStart must be paired with traceGCSweepDone and there
// must be no preemption points between these two calls.
//
// Must be called with a valid P.
func (tl traceLocker) GCSweepStart() {
// Delay the actual GCSweepBegin event until the first span
// sweep. If we don't sweep anything, don't emit any events.
pp := tl.mp.p.ptr()
if pp.trace.maySweep {
throw("double traceGCSweepStart")
}
pp.trace.maySweep, pp.trace.swept, pp.trace.reclaimed = true, 0, 0
}
// GCSweepSpan traces the sweep of a single span. If this is
// the first span swept since traceGCSweepStart was called, this
// will emit a GCSweepBegin event.
//
// This may be called outside a traceGCSweepStart/traceGCSweepDone
// pair; however, it will not emit any trace events in this case.
//
// Must be called with a valid P.
func (tl traceLocker) GCSweepSpan(bytesSwept uintptr) {
pp := tl.mp.p.ptr()
if pp.trace.maySweep {
if pp.trace.swept == 0 {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGCSweepBegin, tl.stack(1))
pp.trace.inSweep = true
}
pp.trace.swept += bytesSwept
}
}
// GCSweepDone finishes tracing a sweep loop. If any memory was
// swept (i.e. traceGCSweepSpan emitted an event) then this will emit
// a GCSweepEnd event.
//
// Must be called with a valid P.
func (tl traceLocker) GCSweepDone() {
pp := tl.mp.p.ptr()
if !pp.trace.maySweep {
throw("missing traceGCSweepStart")
}
if pp.trace.inSweep {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGCSweepEnd, traceArg(pp.trace.swept), traceArg(pp.trace.reclaimed))
pp.trace.inSweep = false
}
pp.trace.maySweep = false
}
// GCMarkAssistStart emits a MarkAssistBegin event.
func (tl traceLocker) GCMarkAssistStart() {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGCMarkAssistBegin, tl.stack(1))
}
// GCMarkAssistDone emits a MarkAssistEnd event.
func (tl traceLocker) GCMarkAssistDone() {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGCMarkAssistEnd)
}
// GoCreate emits a GoCreate event.
func (tl traceLocker) GoCreate(newg *g, pc uintptr, blocked bool) {
newg.trace.setStatusTraced(tl.gen)
ev := traceEvGoCreate
if blocked {
ev = traceEvGoCreateBlocked
}
tl.eventWriter(traceGoRunning, traceProcRunning).commit(ev, traceArg(newg.goid), tl.startPC(pc), tl.stack(2))
}
// GoStart emits a GoStart event.
//
// Must be called with a valid P.
func (tl traceLocker) GoStart() {
gp := getg().m.curg
pp := gp.m.p
w := tl.eventWriter(traceGoRunnable, traceProcRunning)
w = w.write(traceEvGoStart, traceArg(gp.goid), gp.trace.nextSeq(tl.gen))
if pp.ptr().gcMarkWorkerMode != gcMarkWorkerNotWorker {
w = w.write(traceEvGoLabel, trace.markWorkerLabels[tl.gen%2][pp.ptr().gcMarkWorkerMode])
}
w.end()
}
// GoEnd emits a GoDestroy event.
//
// TODO(mknyszek): Rename this to GoDestroy.
func (tl traceLocker) GoEnd() {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGoDestroy)
}
// GoSched emits a GoStop event with a GoSched reason.
func (tl traceLocker) GoSched() {
tl.GoStop(traceGoStopGoSched)
}
// GoPreempt emits a GoStop event with a GoPreempted reason.
func (tl traceLocker) GoPreempt() {
tl.GoStop(traceGoStopPreempted)
}
// GoStop emits a GoStop event with the provided reason.
func (tl traceLocker) GoStop(reason traceGoStopReason) {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGoStop, traceArg(trace.goStopReasons[tl.gen%2][reason]), tl.stack(1))
}
// GoPark emits a GoBlock event with the provided reason.
//
// TODO(mknyszek): Replace traceBlockReason with waitReason. It's silly
// that we have both, and waitReason is way more descriptive.
func (tl traceLocker) GoPark(reason traceBlockReason, skip int) {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGoBlock, traceArg(trace.goBlockReasons[tl.gen%2][reason]), tl.stack(skip))
}
// GoUnpark emits a GoUnblock event.
func (tl traceLocker) GoUnpark(gp *g, skip int) {
// Emit a GoWaiting status if necessary for the unblocked goroutine.
w := tl.eventWriter(traceGoRunning, traceProcRunning)
// Careful: don't use the event writer. We never want status or in-progress events
// to trigger more in-progress events.
w.w = emitUnblockStatus(w.w, gp, tl.gen)
w.commit(traceEvGoUnblock, traceArg(gp.goid), gp.trace.nextSeq(tl.gen), tl.stack(skip))
}
// GoCoroswitch emits a GoSwitch event. If destroy is true, the calling goroutine
// is simultaneously being destroyed.
func (tl traceLocker) GoSwitch(nextg *g, destroy bool) {
// Emit a GoWaiting status if necessary for the unblocked goroutine.
w := tl.eventWriter(traceGoRunning, traceProcRunning)
// Careful: don't use the event writer. We never want status or in-progress events
// to trigger more in-progress events.
w.w = emitUnblockStatus(w.w, nextg, tl.gen)
ev := traceEvGoSwitch
if destroy {
ev = traceEvGoSwitchDestroy
}
w.commit(ev, traceArg(nextg.goid), nextg.trace.nextSeq(tl.gen))
}
// emitUnblockStatus emits a GoStatus GoWaiting event for a goroutine about to be
// unblocked to the trace writer.
func emitUnblockStatus(w traceWriter, gp *g, gen uintptr) traceWriter {
if !gp.trace.statusWasTraced(gen) && gp.trace.acquireStatus(gen) {
// TODO(go.dev/issue/65634): Although it would be nice to add a stack trace here of gp,
// we cannot safely do so. gp is in _Gwaiting and so we don't have ownership of its stack.
// We can fix this by acquiring the goroutine's scan bit.
w = w.writeGoStatus(gp.goid, -1, traceGoWaiting, gp.inMarkAssist, 0)
}
return w
}
// GoSysCall emits a GoSyscallBegin event.
//
// Must be called with a valid P.
func (tl traceLocker) GoSysCall() {
// Scribble down the M that the P is currently attached to.
pp := tl.mp.p.ptr()
pp.trace.mSyscallID = int64(tl.mp.procid)
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvGoSyscallBegin, pp.trace.nextSeq(tl.gen), tl.stack(1))
}
// GoSysExit emits a GoSyscallEnd event, possibly along with a GoSyscallBlocked event
// if lostP is true.
//
// lostP must be true in all cases that a goroutine loses its P during a syscall.
// This means it's not sufficient to check if it has no P. In particular, it needs to be
// true in the following cases:
// - The goroutine lost its P, it ran some other code, and then got it back. It's now running with that P.
// - The goroutine lost its P and was unable to reacquire it, and is now running without a P.
// - The goroutine lost its P and acquired a different one, and is now running with that P.
func (tl traceLocker) GoSysExit(lostP bool) {
ev := traceEvGoSyscallEnd
procStatus := traceProcSyscall // Procs implicitly enter traceProcSyscall on GoSyscallBegin.
if lostP {
ev = traceEvGoSyscallEndBlocked
procStatus = traceProcRunning // If a G has a P when emitting this event, it reacquired a P and is indeed running.
} else {
tl.mp.p.ptr().trace.mSyscallID = -1
}
tl.eventWriter(traceGoSyscall, procStatus).commit(ev)
}
// ProcSteal indicates that our current M stole a P from another M.
//
// inSyscall indicates that we're stealing the P from a syscall context.
//
// The caller must have ownership of pp.
func (tl traceLocker) ProcSteal(pp *p, inSyscall bool) {
// Grab the M ID we stole from.
mStolenFrom := pp.trace.mSyscallID
pp.trace.mSyscallID = -1
// The status of the proc and goroutine, if we need to emit one here, is not evident from the
// context of just emitting this event alone. There are two cases. Either we're trying to steal
// the P just to get its attention (e.g. STW or sysmon retake) or we're trying to steal a P for
// ourselves specifically to keep running. The two contexts look different, but can be summarized
// fairly succinctly. In the former, we're a regular running goroutine and proc, if we have either.
// In the latter, we're a goroutine in a syscall.
goStatus := traceGoRunning
procStatus := traceProcRunning
if inSyscall {
goStatus = traceGoSyscall
procStatus = traceProcSyscallAbandoned
}
w := tl.eventWriter(goStatus, procStatus)
// Emit the status of the P we're stealing. We may have *just* done this when creating the event
// writer but it's not guaranteed, even if inSyscall is true. Although it might seem like from a
// syscall context we're always stealing a P for ourselves, we may have not wired it up yet (so
// it wouldn't be visible to eventWriter) or we may not even intend to wire it up to ourselves
// at all (e.g. entersyscall_gcwait).
if !pp.trace.statusWasTraced(tl.gen) && pp.trace.acquireStatus(tl.gen) {
// Careful: don't use the event writer. We never want status or in-progress events
// to trigger more in-progress events.
w.w = w.w.writeProcStatus(uint64(pp.id), traceProcSyscallAbandoned, pp.trace.inSweep)
}
w.commit(traceEvProcSteal, traceArg(pp.id), pp.trace.nextSeq(tl.gen), traceArg(mStolenFrom))
}
// HeapAlloc emits a HeapAlloc event.
func (tl traceLocker) HeapAlloc(live uint64) {
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvHeapAlloc, traceArg(live))
}
// HeapGoal reads the current heap goal and emits a HeapGoal event.
func (tl traceLocker) HeapGoal() {
heapGoal := gcController.heapGoal()
if heapGoal == ^uint64(0) {
// Heap-based triggering is disabled.
heapGoal = 0
}
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvHeapGoal, traceArg(heapGoal))
}
// GoCreateSyscall indicates that a goroutine has transitioned from dead to GoSyscall.
//
// Unlike GoCreate, the caller must be running on gp.
//
// This occurs when C code calls into Go. On pthread platforms it occurs only when
// a C thread calls into Go code for the first time.
func (tl traceLocker) GoCreateSyscall(gp *g) {
// N.B. We should never trace a status for this goroutine (which we're currently running on),
// since we want this to appear like goroutine creation.
gp.trace.setStatusTraced(tl.gen)
tl.eventWriter(traceGoBad, traceProcBad).commit(traceEvGoCreateSyscall, traceArg(gp.goid))
}
// GoDestroySyscall indicates that a goroutine has transitioned from GoSyscall to dead.
//
// Must not have a P.
//
// This occurs when Go code returns back to C. On pthread platforms it occurs only when
// the C thread is destroyed.
func (tl traceLocker) GoDestroySyscall() {
// N.B. If we trace a status here, we must never have a P, and we must be on a goroutine
// that is in the syscall state.
tl.eventWriter(traceGoSyscall, traceProcBad).commit(traceEvGoDestroySyscall)
}
// To access runtime functions from runtime/trace.
// See runtime/trace/annotation.go
// trace_userTaskCreate emits a UserTaskCreate event.
//
//go:linkname trace_userTaskCreate runtime/trace.userTaskCreate
func trace_userTaskCreate(id, parentID uint64, taskType string) {
tl := traceAcquire()
if !tl.ok() {
// Need to do this check because the caller won't have it.
return
}
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvUserTaskBegin, traceArg(id), traceArg(parentID), tl.string(taskType), tl.stack(3))
traceRelease(tl)
}
// trace_userTaskEnd emits a UserTaskEnd event.
//
//go:linkname trace_userTaskEnd runtime/trace.userTaskEnd
func trace_userTaskEnd(id uint64) {
tl := traceAcquire()
if !tl.ok() {
// Need to do this check because the caller won't have it.
return
}
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvUserTaskEnd, traceArg(id), tl.stack(2))
traceRelease(tl)
}
// trace_userTaskEnd emits a UserRegionBegin or UserRegionEnd event,
// depending on mode (0 == Begin, 1 == End).
//
// TODO(mknyszek): Just make this two functions.
//
//go:linkname trace_userRegion runtime/trace.userRegion
func trace_userRegion(id, mode uint64, name string) {
tl := traceAcquire()
if !tl.ok() {
// Need to do this check because the caller won't have it.
return
}
var ev traceEv
switch mode {
case 0:
ev = traceEvUserRegionBegin
case 1:
ev = traceEvUserRegionEnd
default:
return
}
tl.eventWriter(traceGoRunning, traceProcRunning).commit(ev, traceArg(id), tl.string(name), tl.stack(3))
traceRelease(tl)
}
// trace_userTaskEnd emits a UserRegionBegin or UserRegionEnd event.
//
//go:linkname trace_userLog runtime/trace.userLog
func trace_userLog(id uint64, category, message string) {
tl := traceAcquire()
if !tl.ok() {
// Need to do this check because the caller won't have it.
return
}
tl.eventWriter(traceGoRunning, traceProcRunning).commit(traceEvUserLog, traceArg(id), tl.string(category), tl.uniqueString(message), tl.stack(3))
traceRelease(tl)
}
// traceThreadDestroy is called when a thread is removed from
// sched.freem.
//
// mp must not be able to emit trace events anymore.
//
// sched.lock must be held to synchronize with traceAdvance.
func traceThreadDestroy(mp *m) {
assertLockHeld(&sched.lock)
// Flush all outstanding buffers to maintain the invariant
// that an M only has active buffers while on sched.freem
// or allm.
//
// Perform a traceAcquire/traceRelease on behalf of mp to
// synchronize with the tracer trying to flush our buffer
// as well.
seq := mp.trace.seqlock.Add(1)
if debugTraceReentrancy && seq%2 != 1 {
throw("bad use of trace.seqlock or tracer is reentrant")
}
systemstack(func() {
lock(&trace.lock)
for i := range mp.trace.buf {
if mp.trace.buf[i] != nil {
// N.B. traceBufFlush accepts a generation, but it
// really just cares about gen%2.
traceBufFlush(mp.trace.buf[i], uintptr(i))
mp.trace.buf[i] = nil
}
}
unlock(&trace.lock)
})
seq1 := mp.trace.seqlock.Add(1)
if seq1 != seq+1 {
print("runtime: seq1=", seq1, "\n")
throw("bad use of trace.seqlock")
}
}