src/runtime/traceevent.go - go - Git at Google

 // 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.

 // Trace event writing API for trace2runtime.go.

 package runtime

 import (
 	"runtime/internal/sys"
 )

 // Event types in the trace, args are given in square brackets.
 //
 // Naming scheme:
 //   - Time range event pairs have suffixes "Begin" and "End".
 //   - "Start", "Stop", "Create", "Destroy", "Block", "Unblock"
 //     are suffixes reserved for scheduling resources.
 //
 // NOTE: If you add an event type, make sure you also update all
 // tables in this file!
 type traceEv uint8

 const (
 	traceEvNone traceEv = iota // unused

 	// Structural events.
 	traceEvEventBatch // start of per-M batch of events [generation, M ID, timestamp, batch length]
 	traceEvStacks     // start of a section of the stack table [...traceEvStack]
 	traceEvStack      // stack table entry [ID, ...{PC, func string ID, file string ID, line #}]
 	traceEvStrings    // start of a section of the string dictionary [...traceEvString]
 	traceEvString     // string dictionary entry [ID, length, string]
 	traceEvCPUSamples // start of a section of CPU samples [...traceEvCPUSample]
 	traceEvCPUSample  // CPU profiling sample [timestamp, M ID, P ID, goroutine ID, stack ID]
 	traceEvFrequency  // timestamp units per sec [freq]

 	// Procs.
 	traceEvProcsChange // current value of GOMAXPROCS [timestamp, GOMAXPROCS, stack ID]
 	traceEvProcStart   // start of P [timestamp, P ID, P seq]
 	traceEvProcStop    // stop of P [timestamp]
 	traceEvProcSteal   // P was stolen [timestamp, P ID, P seq, M ID]
 	traceEvProcStatus  // P status at the start of a generation [timestamp, P ID, status]

 	// Goroutines.
 	traceEvGoCreate            // goroutine creation [timestamp, new goroutine ID, new stack ID, stack ID]
 	traceEvGoCreateSyscall     // goroutine appears in syscall (cgo callback) [timestamp, new goroutine ID]
 	traceEvGoStart             // goroutine starts running [timestamp, goroutine ID, goroutine seq]
 	traceEvGoDestroy           // goroutine ends [timestamp]
 	traceEvGoDestroySyscall    // goroutine ends in syscall (cgo callback) [timestamp]
 	traceEvGoStop              // goroutine yields its time, but is runnable [timestamp, reason, stack ID]
 	traceEvGoBlock             // goroutine blocks [timestamp, reason, stack ID]
 	traceEvGoUnblock           // goroutine is unblocked [timestamp, goroutine ID, goroutine seq, stack ID]
 	traceEvGoSyscallBegin      // syscall enter [timestamp, P seq, stack ID]
 	traceEvGoSyscallEnd        // syscall exit [timestamp]
 	traceEvGoSyscallEndBlocked // syscall exit and it blocked at some point [timestamp]
 	traceEvGoStatus            // goroutine status at the start of a generation [timestamp, goroutine ID, M ID, status]

 	// STW.
 	traceEvSTWBegin // STW start [timestamp, kind]
 	traceEvSTWEnd   // STW done [timestamp]

 	// GC events.
 	traceEvGCActive           // GC active [timestamp, seq]
 	traceEvGCBegin            // GC start [timestamp, seq, stack ID]
 	traceEvGCEnd              // GC done [timestamp, seq]
 	traceEvGCSweepActive      // GC sweep active [timestamp, P ID]
 	traceEvGCSweepBegin       // GC sweep start [timestamp, stack ID]
 	traceEvGCSweepEnd         // GC sweep done [timestamp, swept bytes, reclaimed bytes]
 	traceEvGCMarkAssistActive // GC mark assist active [timestamp, goroutine ID]
 	traceEvGCMarkAssistBegin  // GC mark assist start [timestamp, stack ID]
 	traceEvGCMarkAssistEnd    // GC mark assist done [timestamp]
 	traceEvHeapAlloc          // gcController.heapLive change [timestamp, heap alloc in bytes]
 	traceEvHeapGoal           // gcController.heapGoal() change [timestamp, heap goal in bytes]

 	// Annotations.
 	traceEvGoLabel         // apply string label to current running goroutine [timestamp, label string ID]
 	traceEvUserTaskBegin   // trace.NewTask [timestamp, internal task ID, internal parent task ID, name string ID, stack ID]
 	traceEvUserTaskEnd     // end of a task [timestamp, internal task ID, stack ID]
 	traceEvUserRegionBegin // trace.{Start,With}Region [timestamp, internal task ID, name string ID, stack ID]
 	traceEvUserRegionEnd   // trace.{End,With}Region [timestamp, internal task ID, name string ID, stack ID]
 	traceEvUserLog         // trace.Log [timestamp, internal task ID, key string ID, stack, value string ID]

 	// Coroutines.
 	traceEvGoSwitch        // goroutine switch (coroswitch) [timestamp, goroutine ID, goroutine seq]
 	traceEvGoSwitchDestroy // goroutine switch and destroy [timestamp, goroutine ID, goroutine seq]
 	traceEvGoCreateBlocked // goroutine creation (starts blocked) [timestamp, new goroutine ID, new stack ID, stack ID]

 	// GoStatus with stack.
 	traceEvGoStatusStack // goroutine status at the start of a generation, with a stack [timestamp, goroutine ID, M ID, status, stack ID]
 )

 // traceArg is a simple wrapper type to help ensure that arguments passed
 // to traces are well-formed.
 type traceArg uint64

 // traceEventWriter is the high-level API for writing trace events.
 //
 // See the comment on traceWriter about style for more details as to why
 // this type and its methods are structured the way they are.
 type traceEventWriter struct {
 	w traceWriter
 }

 // eventWriter creates a new traceEventWriter. It is the main entrypoint for writing trace events.
 //
 // Before creating the event writer, this method will emit a status for the current goroutine
 // or proc if it exists, and if it hasn't had its status emitted yet. goStatus and procStatus indicate
 // what the status of goroutine or P should be immediately *before* the events that are about to
 // be written using the eventWriter (if they exist). No status will be written if there's no active
 // goroutine or P.
 //
 // Callers can elect to pass a constant value here if the status is clear (e.g. a goroutine must have
 // been Runnable before a GoStart). Otherwise, callers can query the status of either the goroutine
 // or P and pass the appropriate status.
 //
 // In this case, the default status should be traceGoBad or traceProcBad to help identify bugs sooner.
 func (tl traceLocker) eventWriter(goStatus traceGoStatus, procStatus traceProcStatus) traceEventWriter {
 	w := tl.writer()
 	if pp := tl.mp.p.ptr(); pp != nil && !pp.trace.statusWasTraced(tl.gen) && pp.trace.acquireStatus(tl.gen) {
 		w = w.writeProcStatus(uint64(pp.id), procStatus, pp.trace.inSweep)
 	}
 	if gp := tl.mp.curg; gp != nil && !gp.trace.statusWasTraced(tl.gen) && gp.trace.acquireStatus(tl.gen) {
 		w = w.writeGoStatus(uint64(gp.goid), int64(tl.mp.procid), goStatus, gp.inMarkAssist, 0 /* no stack */)
 	}
 	return traceEventWriter{w}
 }

 // commit writes out a trace event and calls end. It's a helper to make the
 // common case of writing out a single event less error-prone.
 func (e traceEventWriter) commit(ev traceEv, args ...traceArg) {
 	e = e.write(ev, args...)
 	e.end()
 }

 // write writes an event into the trace.
 func (e traceEventWriter) write(ev traceEv, args ...traceArg) traceEventWriter {
 	e.w = e.w.event(ev, args...)
 	return e
 }

 // end finishes writing to the trace. The traceEventWriter must not be used after this call.
 func (e traceEventWriter) end() {
 	e.w.end()
 }

 // traceEventWrite is the part of traceEvent that actually writes the event.
 func (w traceWriter) event(ev traceEv, args ...traceArg) traceWriter {
 	// Make sure we have room.
 	w, _ = w.ensure(1 + (len(args)+1)*traceBytesPerNumber)

 	// Compute the timestamp diff that we'll put in the trace.
 	ts := traceClockNow()
 	if ts <= w.traceBuf.lastTime {
 		ts = w.traceBuf.lastTime + 1
 	}
 	tsDiff := uint64(ts - w.traceBuf.lastTime)
 	w.traceBuf.lastTime = ts

 	// Write out event.
 	w.byte(byte(ev))
 	w.varint(tsDiff)
 	for _, arg := range args {
 		w.varint(uint64(arg))
 	}
 	return w
 }

 // stack takes a stack trace skipping the provided number of frames.
 // It then returns a traceArg representing that stack which may be
 // passed to write.
 func (tl traceLocker) stack(skip int) traceArg {
 	return traceArg(traceStack(skip, nil, tl.gen))
 }

 // startPC takes a start PC for a goroutine and produces a unique
 // stack ID for it.
 //
 // It then returns a traceArg representing that stack which may be
 // passed to write.
 func (tl traceLocker) startPC(pc uintptr) traceArg {
 	// +PCQuantum because makeTraceFrame expects return PCs and subtracts PCQuantum.
 	return traceArg(trace.stackTab[tl.gen%2].put([]uintptr{
 		logicalStackSentinel,
 		startPCForTrace(pc) + sys.PCQuantum,
 	}))
 }

 // string returns a traceArg representing s which may be passed to write.
 // The string is assumed to be relatively short and popular, so it may be
 // stored for a while in the string dictionary.
 func (tl traceLocker) string(s string) traceArg {
 	return traceArg(trace.stringTab[tl.gen%2].put(tl.gen, s))
 }

 // uniqueString returns a traceArg representing s which may be passed to write.
 // The string is assumed to be unique or long, so it will be written out to
 // the trace eagerly.
 func (tl traceLocker) uniqueString(s string) traceArg {
 	return traceArg(trace.stringTab[tl.gen%2].emit(tl.gen, s))
 }
	// 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.

	// Trace event writing API for trace2runtime.go.

	package runtime

	import (
	"runtime/internal/sys"
	)

	// Event types in the trace, args are given in square brackets.
	//
	// Naming scheme:
	// - Time range event pairs have suffixes "Begin" and "End".
	// - "Start", "Stop", "Create", "Destroy", "Block", "Unblock"
	// are suffixes reserved for scheduling resources.
	//
	// NOTE: If you add an event type, make sure you also update all
	// tables in this file!
	type traceEv uint8

	const (
	traceEvNone traceEv = iota // unused

	// Structural events.
	traceEvEventBatch // start of per-M batch of events [generation, M ID, timestamp, batch length]
	traceEvStacks // start of a section of the stack table [...traceEvStack]
	traceEvStack // stack table entry [ID, ...{PC, func string ID, file string ID, line #}]
	traceEvStrings // start of a section of the string dictionary [...traceEvString]
	traceEvString // string dictionary entry [ID, length, string]
	traceEvCPUSamples // start of a section of CPU samples [...traceEvCPUSample]
	traceEvCPUSample // CPU profiling sample [timestamp, M ID, P ID, goroutine ID, stack ID]
	traceEvFrequency // timestamp units per sec [freq]

	// Procs.
	traceEvProcsChange // current value of GOMAXPROCS [timestamp, GOMAXPROCS, stack ID]
	traceEvProcStart // start of P [timestamp, P ID, P seq]
	traceEvProcStop // stop of P [timestamp]
	traceEvProcSteal // P was stolen [timestamp, P ID, P seq, M ID]
	traceEvProcStatus // P status at the start of a generation [timestamp, P ID, status]

	// Goroutines.
	traceEvGoCreate // goroutine creation [timestamp, new goroutine ID, new stack ID, stack ID]
	traceEvGoCreateSyscall // goroutine appears in syscall (cgo callback) [timestamp, new goroutine ID]
	traceEvGoStart // goroutine starts running [timestamp, goroutine ID, goroutine seq]
	traceEvGoDestroy // goroutine ends [timestamp]
	traceEvGoDestroySyscall // goroutine ends in syscall (cgo callback) [timestamp]
	traceEvGoStop // goroutine yields its time, but is runnable [timestamp, reason, stack ID]
	traceEvGoBlock // goroutine blocks [timestamp, reason, stack ID]
	traceEvGoUnblock // goroutine is unblocked [timestamp, goroutine ID, goroutine seq, stack ID]
	traceEvGoSyscallBegin // syscall enter [timestamp, P seq, stack ID]
	traceEvGoSyscallEnd // syscall exit [timestamp]
	traceEvGoSyscallEndBlocked // syscall exit and it blocked at some point [timestamp]
	traceEvGoStatus // goroutine status at the start of a generation [timestamp, goroutine ID, M ID, status]

	// STW.
	traceEvSTWBegin // STW start [timestamp, kind]
	traceEvSTWEnd // STW done [timestamp]

	// GC events.
	traceEvGCActive // GC active [timestamp, seq]
	traceEvGCBegin // GC start [timestamp, seq, stack ID]
	traceEvGCEnd // GC done [timestamp, seq]
	traceEvGCSweepActive // GC sweep active [timestamp, P ID]
	traceEvGCSweepBegin // GC sweep start [timestamp, stack ID]
	traceEvGCSweepEnd // GC sweep done [timestamp, swept bytes, reclaimed bytes]
	traceEvGCMarkAssistActive // GC mark assist active [timestamp, goroutine ID]
	traceEvGCMarkAssistBegin // GC mark assist start [timestamp, stack ID]
	traceEvGCMarkAssistEnd // GC mark assist done [timestamp]
	traceEvHeapAlloc // gcController.heapLive change [timestamp, heap alloc in bytes]
	traceEvHeapGoal // gcController.heapGoal() change [timestamp, heap goal in bytes]

	// Annotations.
	traceEvGoLabel // apply string label to current running goroutine [timestamp, label string ID]
	traceEvUserTaskBegin // trace.NewTask [timestamp, internal task ID, internal parent task ID, name string ID, stack ID]
	traceEvUserTaskEnd // end of a task [timestamp, internal task ID, stack ID]
	traceEvUserRegionBegin // trace.{Start,With}Region [timestamp, internal task ID, name string ID, stack ID]
	traceEvUserRegionEnd // trace.{End,With}Region [timestamp, internal task ID, name string ID, stack ID]
	traceEvUserLog // trace.Log [timestamp, internal task ID, key string ID, stack, value string ID]

	// Coroutines.
	traceEvGoSwitch // goroutine switch (coroswitch) [timestamp, goroutine ID, goroutine seq]
	traceEvGoSwitchDestroy // goroutine switch and destroy [timestamp, goroutine ID, goroutine seq]
	traceEvGoCreateBlocked // goroutine creation (starts blocked) [timestamp, new goroutine ID, new stack ID, stack ID]

	// GoStatus with stack.
	traceEvGoStatusStack // goroutine status at the start of a generation, with a stack [timestamp, goroutine ID, M ID, status, stack ID]
	)

	// traceArg is a simple wrapper type to help ensure that arguments passed
	// to traces are well-formed.
	type traceArg uint64

	// traceEventWriter is the high-level API for writing trace events.
	//
	// See the comment on traceWriter about style for more details as to why
	// this type and its methods are structured the way they are.
	type traceEventWriter struct {
	w traceWriter
	}

	// eventWriter creates a new traceEventWriter. It is the main entrypoint for writing trace events.
	//
	// Before creating the event writer, this method will emit a status for the current goroutine
	// or proc if it exists, and if it hasn't had its status emitted yet. goStatus and procStatus indicate
	// what the status of goroutine or P should be immediately before the events that are about to
	// be written using the eventWriter (if they exist). No status will be written if there's no active
	// goroutine or P.
	//
	// Callers can elect to pass a constant value here if the status is clear (e.g. a goroutine must have
	// been Runnable before a GoStart). Otherwise, callers can query the status of either the goroutine
	// or P and pass the appropriate status.
	//
	// In this case, the default status should be traceGoBad or traceProcBad to help identify bugs sooner.
	func (tl traceLocker) eventWriter(goStatus traceGoStatus, procStatus traceProcStatus) traceEventWriter {
	w := tl.writer()
	if pp := tl.mp.p.ptr(); pp != nil && !pp.trace.statusWasTraced(tl.gen) && pp.trace.acquireStatus(tl.gen) {
	w = w.writeProcStatus(uint64(pp.id), procStatus, pp.trace.inSweep)
	}
	if gp := tl.mp.curg; gp != nil && !gp.trace.statusWasTraced(tl.gen) && gp.trace.acquireStatus(tl.gen) {
	w = w.writeGoStatus(uint64(gp.goid), int64(tl.mp.procid), goStatus, gp.inMarkAssist, 0 /* no stack */)
	}
	return traceEventWriter{w}
	}

	// commit writes out a trace event and calls end. It's a helper to make the
	// common case of writing out a single event less error-prone.
	func (e traceEventWriter) commit(ev traceEv, args ...traceArg) {
	e = e.write(ev, args...)
	e.end()
	}

	// write writes an event into the trace.
	func (e traceEventWriter) write(ev traceEv, args ...traceArg) traceEventWriter {
	e.w = e.w.event(ev, args...)
	return e
	}

	// end finishes writing to the trace. The traceEventWriter must not be used after this call.
	func (e traceEventWriter) end() {
	e.w.end()
	}

	// traceEventWrite is the part of traceEvent that actually writes the event.
	func (w traceWriter) event(ev traceEv, args ...traceArg) traceWriter {
	// Make sure we have room.
	w, _ = w.ensure(1 + (len(args)+1)*traceBytesPerNumber)

	// Compute the timestamp diff that we'll put in the trace.
	ts := traceClockNow()
	if ts <= w.traceBuf.lastTime {
	ts = w.traceBuf.lastTime + 1
	}
	tsDiff := uint64(ts - w.traceBuf.lastTime)
	w.traceBuf.lastTime = ts

	// Write out event.
	w.byte(byte(ev))
	w.varint(tsDiff)
	for _, arg := range args {
	w.varint(uint64(arg))
	}
	return w
	}

	// stack takes a stack trace skipping the provided number of frames.
	// It then returns a traceArg representing that stack which may be
	// passed to write.
	func (tl traceLocker) stack(skip int) traceArg {
	return traceArg(traceStack(skip, nil, tl.gen))
	}

	// startPC takes a start PC for a goroutine and produces a unique
	// stack ID for it.
	//
	// It then returns a traceArg representing that stack which may be
	// passed to write.
	func (tl traceLocker) startPC(pc uintptr) traceArg {
	// +PCQuantum because makeTraceFrame expects return PCs and subtracts PCQuantum.
	return traceArg(trace.stackTab[tl.gen%2].put([]uintptr{
	logicalStackSentinel,
	startPCForTrace(pc) + sys.PCQuantum,
	}))
	}

	// string returns a traceArg representing s which may be passed to write.
	// The string is assumed to be relatively short and popular, so it may be
	// stored for a while in the string dictionary.
	func (tl traceLocker) string(s string) traceArg {
	return traceArg(trace.stringTab[tl.gen%2].put(tl.gen, s))
	}

	// uniqueString returns a traceArg representing s which may be passed to write.
	// The string is assumed to be unique or long, so it will be written out to
	// the trace eagerly.
	func (tl traceLocker) uniqueString(s string) traceArg {
	return traceArg(trace.stringTab[tl.gen%2].emit(tl.gen, s))
	}