src/cmd/trace/v2/goroutinegen.go - toolchain/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.

 package trace

 import (
 	tracev2 "internal/trace/v2"
 )

 var _ generator = &goroutineGenerator{}

 type goroutineGenerator struct {
 	globalRangeGenerator
 	globalMetricGenerator
 	stackSampleGenerator[tracev2.GoID]
 	logEventGenerator[tracev2.GoID]

 	gStates map[tracev2.GoID]*gState[tracev2.GoID]
 	focus   tracev2.GoID
 	filter  map[tracev2.GoID]struct{}
 }

 func newGoroutineGenerator(ctx *traceContext, focus tracev2.GoID, filter map[tracev2.GoID]struct{}) *goroutineGenerator {
 	gg := new(goroutineGenerator)
 	rg := func(ev *tracev2.Event) tracev2.GoID {
 		return ev.Goroutine()
 	}
 	gg.stackSampleGenerator.getResource = rg
 	gg.logEventGenerator.getResource = rg
 	gg.gStates = make(map[tracev2.GoID]*gState[tracev2.GoID])
 	gg.focus = focus
 	gg.filter = filter

 	// Enable a filter on the emitter.
 	if filter != nil {
 		ctx.SetResourceFilter(func(resource uint64) bool {
 			_, ok := filter[tracev2.GoID(resource)]
 			return ok
 		})
 	}
 	return gg
 }

 func (g *goroutineGenerator) Sync() {
 	g.globalRangeGenerator.Sync()
 }

 func (g *goroutineGenerator) GoroutineLabel(ctx *traceContext, ev *tracev2.Event) {
 	l := ev.Label()
 	g.gStates[l.Resource.Goroutine()].setLabel(l.Label)
 }

 func (g *goroutineGenerator) GoroutineRange(ctx *traceContext, ev *tracev2.Event) {
 	r := ev.Range()
 	switch ev.Kind() {
 	case tracev2.EventRangeBegin:
 		g.gStates[r.Scope.Goroutine()].rangeBegin(ev.Time(), r.Name, ev.Stack())
 	case tracev2.EventRangeActive:
 		g.gStates[r.Scope.Goroutine()].rangeActive(r.Name)
 	case tracev2.EventRangeEnd:
 		gs := g.gStates[r.Scope.Goroutine()]
 		gs.rangeEnd(ev.Time(), r.Name, ev.Stack(), ctx)
 	}
 }

 func (g *goroutineGenerator) GoroutineTransition(ctx *traceContext, ev *tracev2.Event) {
 	st := ev.StateTransition()
 	goID := st.Resource.Goroutine()

 	// If we haven't seen this goroutine before, create a new
 	// gState for it.
 	gs, ok := g.gStates[goID]
 	if !ok {
 		gs = newGState[tracev2.GoID](goID)
 		g.gStates[goID] = gs
 	}

 	// Try to augment the name of the goroutine.
 	gs.augmentName(st.Stack)

 	// Handle the goroutine state transition.
 	from, to := st.Goroutine()
 	if from == to {
 		// Filter out no-op events.
 		return
 	}
 	if from.Executing() && !to.Executing() {
 		if to == tracev2.GoWaiting {
 			// Goroutine started blocking.
 			gs.block(ev.Time(), ev.Stack(), st.Reason, ctx)
 		} else {
 			gs.stop(ev.Time(), ev.Stack(), ctx)
 		}
 	}
 	if !from.Executing() && to.Executing() {
 		start := ev.Time()
 		if from == tracev2.GoUndetermined {
 			// Back-date the event to the start of the trace.
 			start = ctx.startTime
 		}
 		gs.start(start, goID, ctx)
 	}

 	if from == tracev2.GoWaiting {
 		// Goroutine unblocked.
 		gs.unblock(ev.Time(), ev.Stack(), ev.Goroutine(), ctx)
 	}
 	if from == tracev2.GoNotExist && to == tracev2.GoRunnable {
 		// Goroutine was created.
 		gs.created(ev.Time(), ev.Goroutine(), ev.Stack())
 	}
 	if from == tracev2.GoSyscall && to != tracev2.GoRunning {
 		// Exiting blocked syscall.
 		gs.syscallEnd(ev.Time(), true, ctx)
 		gs.blockedSyscallEnd(ev.Time(), ev.Stack(), ctx)
 	} else if from == tracev2.GoSyscall {
 		// Check if we're exiting a syscall in a non-blocking way.
 		gs.syscallEnd(ev.Time(), false, ctx)
 	}

 	// Handle syscalls.
 	if to == tracev2.GoSyscall {
 		start := ev.Time()
 		if from == tracev2.GoUndetermined {
 			// Back-date the event to the start of the trace.
 			start = ctx.startTime
 		}
 		// Write down that we've entered a syscall. Note: we might have no G or P here
 		// if we're in a cgo callback or this is a transition from GoUndetermined
 		// (i.e. the G has been blocked in a syscall).
 		gs.syscallBegin(start, goID, ev.Stack())
 	}

 	// Note down the goroutine transition.
 	_, inMarkAssist := gs.activeRanges["GC mark assist"]
 	ctx.GoroutineTransition(ctx.elapsed(ev.Time()), viewerGState(from, inMarkAssist), viewerGState(to, inMarkAssist))
 }

 func (g *goroutineGenerator) ProcRange(ctx *traceContext, ev *tracev2.Event) {
 	// TODO(mknyszek): Extend procRangeGenerator to support rendering proc ranges
 	// that overlap with a goroutine's execution.
 }

 func (g *goroutineGenerator) ProcTransition(ctx *traceContext, ev *tracev2.Event) {
 	// Not needed. All relevant information for goroutines can be derived from goroutine transitions.
 }

 func (g *goroutineGenerator) Finish(ctx *traceContext) {
 	ctx.SetResourceType("G")

 	// Finish off global ranges.
 	g.globalRangeGenerator.Finish(ctx)

 	// Finish off all the goroutine slices.
 	for id, gs := range g.gStates {
 		gs.finish(ctx)

 		// Tell the emitter about the goroutines we want to render.
 		ctx.Resource(uint64(id), gs.name())
 	}

 	// Set the goroutine to focus on.
 	if g.focus != tracev2.NoGoroutine {
 		ctx.Focus(uint64(g.focus))
 	}
 }
	// 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.

	package trace

	import (
	tracev2 "internal/trace/v2"
	)

	var _ generator = &goroutineGenerator{}

	type goroutineGenerator struct {
	globalRangeGenerator
	globalMetricGenerator
	stackSampleGenerator[tracev2.GoID]
	logEventGenerator[tracev2.GoID]

	gStates map[tracev2.GoID]*gState[tracev2.GoID]
	focus tracev2.GoID
	filter map[tracev2.GoID]struct{}
	}

	func newGoroutineGenerator(ctx traceContext, focus tracev2.GoID, filter map[tracev2.GoID]struct{}) goroutineGenerator {
	gg := new(goroutineGenerator)
	rg := func(ev *tracev2.Event) tracev2.GoID {
	return ev.Goroutine()
	}
	gg.stackSampleGenerator.getResource = rg
	gg.logEventGenerator.getResource = rg
	gg.gStates = make(map[tracev2.GoID]*gState[tracev2.GoID])
	gg.focus = focus
	gg.filter = filter

	// Enable a filter on the emitter.
	if filter != nil {
	ctx.SetResourceFilter(func(resource uint64) bool {
	_, ok := filter[tracev2.GoID(resource)]
	return ok
	})
	}
	return gg
	}

	func (g *goroutineGenerator) Sync() {
	g.globalRangeGenerator.Sync()
	}

	func (g goroutineGenerator) GoroutineLabel(ctx traceContext, ev *tracev2.Event) {
	l := ev.Label()
	g.gStates[l.Resource.Goroutine()].setLabel(l.Label)
	}

	func (g goroutineGenerator) GoroutineRange(ctx traceContext, ev *tracev2.Event) {
	r := ev.Range()
	switch ev.Kind() {
	case tracev2.EventRangeBegin:
	g.gStates[r.Scope.Goroutine()].rangeBegin(ev.Time(), r.Name, ev.Stack())
	case tracev2.EventRangeActive:
	g.gStates[r.Scope.Goroutine()].rangeActive(r.Name)
	case tracev2.EventRangeEnd:
	gs := g.gStates[r.Scope.Goroutine()]
	gs.rangeEnd(ev.Time(), r.Name, ev.Stack(), ctx)
	}
	}

	func (g goroutineGenerator) GoroutineTransition(ctx traceContext, ev *tracev2.Event) {
	st := ev.StateTransition()
	goID := st.Resource.Goroutine()

	// If we haven't seen this goroutine before, create a new
	// gState for it.
	gs, ok := g.gStates[goID]
	if !ok {
	gs = newGState[tracev2.GoID](goID)
	g.gStates[goID] = gs
	}

	// Try to augment the name of the goroutine.
	gs.augmentName(st.Stack)

	// Handle the goroutine state transition.
	from, to := st.Goroutine()
	if from == to {
	// Filter out no-op events.
	return
	}
	if from.Executing() && !to.Executing() {
	if to == tracev2.GoWaiting {
	// Goroutine started blocking.
	gs.block(ev.Time(), ev.Stack(), st.Reason, ctx)
	} else {
	gs.stop(ev.Time(), ev.Stack(), ctx)
	}
	}
	if !from.Executing() && to.Executing() {
	start := ev.Time()
	if from == tracev2.GoUndetermined {
	// Back-date the event to the start of the trace.
	start = ctx.startTime
	}
	gs.start(start, goID, ctx)
	}

	if from == tracev2.GoWaiting {
	// Goroutine unblocked.
	gs.unblock(ev.Time(), ev.Stack(), ev.Goroutine(), ctx)
	}
	if from == tracev2.GoNotExist && to == tracev2.GoRunnable {
	// Goroutine was created.
	gs.created(ev.Time(), ev.Goroutine(), ev.Stack())
	}
	if from == tracev2.GoSyscall && to != tracev2.GoRunning {
	// Exiting blocked syscall.
	gs.syscallEnd(ev.Time(), true, ctx)
	gs.blockedSyscallEnd(ev.Time(), ev.Stack(), ctx)
	} else if from == tracev2.GoSyscall {
	// Check if we're exiting a syscall in a non-blocking way.
	gs.syscallEnd(ev.Time(), false, ctx)
	}

	// Handle syscalls.
	if to == tracev2.GoSyscall {
	start := ev.Time()
	if from == tracev2.GoUndetermined {
	// Back-date the event to the start of the trace.
	start = ctx.startTime
	}
	// Write down that we've entered a syscall. Note: we might have no G or P here
	// if we're in a cgo callback or this is a transition from GoUndetermined
	// (i.e. the G has been blocked in a syscall).
	gs.syscallBegin(start, goID, ev.Stack())
	}

	// Note down the goroutine transition.
	_, inMarkAssist := gs.activeRanges["GC mark assist"]
	ctx.GoroutineTransition(ctx.elapsed(ev.Time()), viewerGState(from, inMarkAssist), viewerGState(to, inMarkAssist))
	}

	func (g goroutineGenerator) ProcRange(ctx traceContext, ev *tracev2.Event) {
	// TODO(mknyszek): Extend procRangeGenerator to support rendering proc ranges
	// that overlap with a goroutine's execution.
	}

	func (g goroutineGenerator) ProcTransition(ctx traceContext, ev *tracev2.Event) {
	// Not needed. All relevant information for goroutines can be derived from goroutine transitions.
	}

	func (g goroutineGenerator) Finish(ctx traceContext) {
	ctx.SetResourceType("G")

	// Finish off global ranges.
	g.globalRangeGenerator.Finish(ctx)

	// Finish off all the goroutine slices.
	for id, gs := range g.gStates {
	gs.finish(ctx)

	// Tell the emitter about the goroutines we want to render.
	ctx.Resource(uint64(id), gs.name())
	}

	// Set the goroutine to focus on.
	if g.focus != tracev2.NoGoroutine {
	ctx.Focus(uint64(g.focus))
	}
	}