// 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 ( "fmt" "strings" "internal/trace/event" "internal/trace/event/go122" "internal/trace/version" ) // ordering emulates Go scheduler state for both validation and // for putting events in the right order. // // The interface to ordering consists of two methods: Advance // and Next. Advance is called to try and advance an event and // add completed events to the ordering. Next is used to pick // off events in the ordering. type ordering struct { gStates map[GoID]*gState pStates map[ProcID]*pState // TODO: The keys are dense, so this can be a slice. mStates map[ThreadID]*mState activeTasks map[TaskID]taskState gcSeq uint64 gcState gcState initialGen uint64 queue queue[Event] } // Advance checks if it's valid to proceed with ev which came from thread m. // // It assumes the gen value passed to it is monotonically increasing across calls. // // If any error is returned, then the trace is broken and trace parsing must cease. // If it's not valid to advance with ev, but no error was encountered, the caller // should attempt to advance with other candidate events from other threads. If the // caller runs out of candidates, the trace is invalid. // // If this returns true, Next is guaranteed to return a complete event. However, // multiple events may be added to the ordering, so the caller should (but is not // required to) continue to call Next until it is exhausted. func (o *ordering) Advance(ev *baseEvent, evt *evTable, m ThreadID, gen uint64) (bool, error) { if o.initialGen == 0 { // Set the initial gen if necessary. o.initialGen = gen } var curCtx, newCtx schedCtx curCtx.M = m newCtx.M = m var ms *mState if m == NoThread { curCtx.P = NoProc curCtx.G = NoGoroutine newCtx = curCtx } else { // Pull out or create the mState for this event. var ok bool ms, ok = o.mStates[m] if !ok { ms = &mState{ g: NoGoroutine, p: NoProc, } o.mStates[m] = ms } curCtx.P = ms.p curCtx.G = ms.g newCtx = curCtx } f := orderingDispatch[ev.typ] if f == nil { return false, fmt.Errorf("bad event type found while ordering: %v", ev.typ) } newCtx, ok, err := f(o, ev, evt, m, gen, curCtx) if err == nil && ok && ms != nil { // Update the mState for this event. ms.p = newCtx.P ms.g = newCtx.G } return ok, err } type orderingHandleFunc func(o *ordering, ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) var orderingDispatch = [256]orderingHandleFunc{ // Procs. go122.EvProcsChange: (*ordering).advanceAnnotation, go122.EvProcStart: (*ordering).advanceProcStart, go122.EvProcStop: (*ordering).advanceProcStop, go122.EvProcSteal: (*ordering).advanceProcSteal, go122.EvProcStatus: (*ordering).advanceProcStatus, // Goroutines. go122.EvGoCreate: (*ordering).advanceGoCreate, go122.EvGoCreateSyscall: (*ordering).advanceGoCreateSyscall, go122.EvGoStart: (*ordering).advanceGoStart, go122.EvGoDestroy: (*ordering).advanceGoStopExec, go122.EvGoDestroySyscall: (*ordering).advanceGoDestroySyscall, go122.EvGoStop: (*ordering).advanceGoStopExec, go122.EvGoBlock: (*ordering).advanceGoStopExec, go122.EvGoUnblock: (*ordering).advanceGoUnblock, go122.EvGoSyscallBegin: (*ordering).advanceGoSyscallBegin, go122.EvGoSyscallEnd: (*ordering).advanceGoSyscallEnd, go122.EvGoSyscallEndBlocked: (*ordering).advanceGoSyscallEndBlocked, go122.EvGoStatus: (*ordering).advanceGoStatus, // STW. go122.EvSTWBegin: (*ordering).advanceGoRangeBegin, go122.EvSTWEnd: (*ordering).advanceGoRangeEnd, // GC events. go122.EvGCActive: (*ordering).advanceGCActive, go122.EvGCBegin: (*ordering).advanceGCBegin, go122.EvGCEnd: (*ordering).advanceGCEnd, go122.EvGCSweepActive: (*ordering).advanceGCSweepActive, go122.EvGCSweepBegin: (*ordering).advanceGCSweepBegin, go122.EvGCSweepEnd: (*ordering).advanceGCSweepEnd, go122.EvGCMarkAssistActive: (*ordering).advanceGoRangeActive, go122.EvGCMarkAssistBegin: (*ordering).advanceGoRangeBegin, go122.EvGCMarkAssistEnd: (*ordering).advanceGoRangeEnd, go122.EvHeapAlloc: (*ordering).advanceHeapMetric, go122.EvHeapGoal: (*ordering).advanceHeapMetric, // Annotations. go122.EvGoLabel: (*ordering).advanceAnnotation, go122.EvUserTaskBegin: (*ordering).advanceUserTaskBegin, go122.EvUserTaskEnd: (*ordering).advanceUserTaskEnd, go122.EvUserRegionBegin: (*ordering).advanceUserRegionBegin, go122.EvUserRegionEnd: (*ordering).advanceUserRegionEnd, go122.EvUserLog: (*ordering).advanceAnnotation, // Coroutines. Added in Go 1.23. go122.EvGoSwitch: (*ordering).advanceGoSwitch, go122.EvGoSwitchDestroy: (*ordering).advanceGoSwitch, go122.EvGoCreateBlocked: (*ordering).advanceGoCreate, // GoStatus event with a stack. Added in Go 1.23. go122.EvGoStatusStack: (*ordering).advanceGoStatus, // Experimental events. // Experimental heap span events. Added in Go 1.23. go122.EvSpan: (*ordering).advanceAllocFree, go122.EvSpanAlloc: (*ordering).advanceAllocFree, go122.EvSpanFree: (*ordering).advanceAllocFree, // Experimental heap object events. Added in Go 1.23. go122.EvHeapObject: (*ordering).advanceAllocFree, go122.EvHeapObjectAlloc: (*ordering).advanceAllocFree, go122.EvHeapObjectFree: (*ordering).advanceAllocFree, // Experimental goroutine stack events. Added in Go 1.23. go122.EvGoroutineStack: (*ordering).advanceAllocFree, go122.EvGoroutineStackAlloc: (*ordering).advanceAllocFree, go122.EvGoroutineStackFree: (*ordering).advanceAllocFree, } func (o *ordering) advanceProcStatus(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { pid := ProcID(ev.args[0]) status := go122.ProcStatus(ev.args[1]) if int(status) >= len(go122ProcStatus2ProcState) { return curCtx, false, fmt.Errorf("invalid status for proc %d: %d", pid, status) } oldState := go122ProcStatus2ProcState[status] if s, ok := o.pStates[pid]; ok { if status == go122.ProcSyscallAbandoned && s.status == go122.ProcSyscall { // ProcSyscallAbandoned is a special case of ProcSyscall. It indicates a // potential loss of information, but if we're already in ProcSyscall, // we haven't lost the relevant information. Promote the status and advance. oldState = ProcRunning ev.args[1] = uint64(go122.ProcSyscall) } else if status == go122.ProcSyscallAbandoned && s.status == go122.ProcSyscallAbandoned { // If we're passing through ProcSyscallAbandoned, then there's no promotion // to do. We've lost the M that this P is associated with. However it got there, // it's going to appear as idle in the API, so pass through as idle. oldState = ProcIdle ev.args[1] = uint64(go122.ProcSyscallAbandoned) } else if s.status != status { return curCtx, false, fmt.Errorf("inconsistent status for proc %d: old %v vs. new %v", pid, s.status, status) } s.seq = makeSeq(gen, 0) // Reset seq. } else { o.pStates[pid] = &pState{id: pid, status: status, seq: makeSeq(gen, 0)} if gen == o.initialGen { oldState = ProcUndetermined } else { oldState = ProcNotExist } } ev.extra(version.Go122)[0] = uint64(oldState) // Smuggle in the old state for StateTransition. // Bind the proc to the new context, if it's running. newCtx := curCtx if status == go122.ProcRunning || status == go122.ProcSyscall { newCtx.P = pid } // If we're advancing through ProcSyscallAbandoned *but* oldState is running then we've // promoted it to ProcSyscall. However, because it's ProcSyscallAbandoned, we know this // P is about to get stolen and its status very likely isn't being emitted by the same // thread it was bound to. Since this status is Running -> Running and Running is binding, // we need to make sure we emit it in the right context: the context to which it is bound. // Find it, and set our current context to it. if status == go122.ProcSyscallAbandoned && oldState == ProcRunning { // N.B. This is slow but it should be fairly rare. found := false for mid, ms := range o.mStates { if ms.p == pid { curCtx.M = mid curCtx.P = pid curCtx.G = ms.g found = true } } if !found { return curCtx, false, fmt.Errorf("failed to find sched context for proc %d that's about to be stolen", pid) } } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceProcStart(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { pid := ProcID(ev.args[0]) seq := makeSeq(gen, ev.args[1]) // Try to advance. We might fail here due to sequencing, because the P hasn't // had a status emitted, or because we already have a P and we're in a syscall, // and we haven't observed that it was stolen from us yet. state, ok := o.pStates[pid] if !ok || state.status != go122.ProcIdle || !seq.succeeds(state.seq) || curCtx.P != NoProc { // We can't make an inference as to whether this is bad. We could just be seeing // a ProcStart on a different M before the proc's state was emitted, or before we // got to the right point in the trace. // // Note that we also don't advance here if we have a P and we're in a syscall. return curCtx, false, nil } // We can advance this P. Check some invariants. // // We might have a goroutine if a goroutine is exiting a syscall. reqs := event.SchedReqs{Thread: event.MustHave, Proc: event.MustNotHave, Goroutine: event.MayHave} if err := validateCtx(curCtx, reqs); err != nil { return curCtx, false, err } state.status = go122.ProcRunning state.seq = seq newCtx := curCtx newCtx.P = pid o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceProcStop(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // We must be able to advance this P. // // There are 2 ways a P can stop: ProcStop and ProcSteal. ProcStop is used when the P // is stopped by the same M that started it, while ProcSteal is used when another M // steals the P by stopping it from a distance. // // Since a P is bound to an M, and we're stopping on the same M we started, it must // always be possible to advance the current M's P from a ProcStop. This is also why // ProcStop doesn't need a sequence number. state, ok := o.pStates[curCtx.P] if !ok { return curCtx, false, fmt.Errorf("event %s for proc (%v) that doesn't exist", go122.EventString(ev.typ), curCtx.P) } if state.status != go122.ProcRunning && state.status != go122.ProcSyscall { return curCtx, false, fmt.Errorf("%s event for proc that's not %s or %s", go122.EventString(ev.typ), go122.ProcRunning, go122.ProcSyscall) } reqs := event.SchedReqs{Thread: event.MustHave, Proc: event.MustHave, Goroutine: event.MayHave} if err := validateCtx(curCtx, reqs); err != nil { return curCtx, false, err } state.status = go122.ProcIdle newCtx := curCtx newCtx.P = NoProc o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceProcSteal(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { pid := ProcID(ev.args[0]) seq := makeSeq(gen, ev.args[1]) state, ok := o.pStates[pid] if !ok || (state.status != go122.ProcSyscall && state.status != go122.ProcSyscallAbandoned) || !seq.succeeds(state.seq) { // We can't make an inference as to whether this is bad. We could just be seeing // a ProcStart on a different M before the proc's state was emitted, or before we // got to the right point in the trace. return curCtx, false, nil } // We can advance this P. Check some invariants. reqs := event.SchedReqs{Thread: event.MustHave, Proc: event.MayHave, Goroutine: event.MayHave} if err := validateCtx(curCtx, reqs); err != nil { return curCtx, false, err } // Smuggle in the P state that let us advance so we can surface information to the event. // Specifically, we need to make sure that the event is interpreted not as a transition of // ProcRunning -> ProcIdle but ProcIdle -> ProcIdle instead. // // ProcRunning is binding, but we may be running with a P on the current M and we can't // bind another P. This P is about to go ProcIdle anyway. oldStatus := state.status ev.extra(version.Go122)[0] = uint64(oldStatus) // Update the P's status and sequence number. state.status = go122.ProcIdle state.seq = seq // If we've lost information then don't try to do anything with the M. // It may have moved on and we can't be sure. if oldStatus == go122.ProcSyscallAbandoned { o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } // Validate that the M we're stealing from is what we expect. mid := ThreadID(ev.args[2]) // The M we're stealing from. newCtx := curCtx if mid == curCtx.M { // We're stealing from ourselves. This behaves like a ProcStop. if curCtx.P != pid { return curCtx, false, fmt.Errorf("tried to self-steal proc %d (thread %d), but got proc %d instead", pid, mid, curCtx.P) } newCtx.P = NoProc o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } // We're stealing from some other M. mState, ok := o.mStates[mid] if !ok { return curCtx, false, fmt.Errorf("stole proc from non-existent thread %d", mid) } // Make sure we're actually stealing the right P. if mState.p != pid { return curCtx, false, fmt.Errorf("tried to steal proc %d from thread %d, but got proc %d instead", pid, mid, mState.p) } // Tell the M it has no P so it can proceed. // // This is safe because we know the P was in a syscall and // the other M must be trying to get out of the syscall. // GoSyscallEndBlocked cannot advance until the corresponding // M loses its P. mState.p = NoProc o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceGoStatus(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { gid := GoID(ev.args[0]) mid := ThreadID(ev.args[1]) status := go122.GoStatus(ev.args[2]) if int(status) >= len(go122GoStatus2GoState) { return curCtx, false, fmt.Errorf("invalid status for goroutine %d: %d", gid, status) } oldState := go122GoStatus2GoState[status] if s, ok := o.gStates[gid]; ok { if s.status != status { return curCtx, false, fmt.Errorf("inconsistent status for goroutine %d: old %v vs. new %v", gid, s.status, status) } s.seq = makeSeq(gen, 0) // Reset seq. } else if gen == o.initialGen { // Set the state. o.gStates[gid] = &gState{id: gid, status: status, seq: makeSeq(gen, 0)} oldState = GoUndetermined } else { return curCtx, false, fmt.Errorf("found goroutine status for new goroutine after the first generation: id=%v status=%v", gid, status) } ev.args[2] = uint64(oldState)<<32 | uint64(status) // Smuggle in the old state for StateTransition. newCtx := curCtx switch status { case go122.GoRunning: // Bind the goroutine to the new context, since it's running. newCtx.G = gid case go122.GoSyscall: if mid == NoThread { return curCtx, false, fmt.Errorf("found goroutine %d in syscall without a thread", gid) } // Is the syscall on this thread? If so, bind it to the context. // Otherwise, we're talking about a G sitting in a syscall on an M. // Validate the named M. if mid == curCtx.M { if gen != o.initialGen && curCtx.G != gid { // If this isn't the first generation, we *must* have seen this // binding occur already. Even if the G was blocked in a syscall // for multiple generations since trace start, we would have seen // a previous GoStatus event that bound the goroutine to an M. return curCtx, false, fmt.Errorf("inconsistent thread for syscalling goroutine %d: thread has goroutine %d", gid, curCtx.G) } newCtx.G = gid break } // Now we're talking about a thread and goroutine that have been // blocked on a syscall for the entire generation. This case must // not have a P; the runtime makes sure that all Ps are traced at // the beginning of a generation, which involves taking a P back // from every thread. ms, ok := o.mStates[mid] if ok { // This M has been seen. That means we must have seen this // goroutine go into a syscall on this thread at some point. if ms.g != gid { // But the G on the M doesn't match. Something's wrong. return curCtx, false, fmt.Errorf("inconsistent thread for syscalling goroutine %d: thread has goroutine %d", gid, ms.g) } // This case is just a Syscall->Syscall event, which needs to // appear as having the G currently bound to this M. curCtx.G = ms.g } else if !ok { // The M hasn't been seen yet. That means this goroutine // has just been sitting in a syscall on this M. Create // a state for it. o.mStates[mid] = &mState{g: gid, p: NoProc} // Don't set curCtx.G in this case because this event is the // binding event (and curCtx represents the "before" state). } // Update the current context to the M we're talking about. curCtx.M = mid } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceGoCreate(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // Goroutines must be created on a running P, but may or may not be created // by a running goroutine. reqs := event.SchedReqs{Thread: event.MustHave, Proc: event.MustHave, Goroutine: event.MayHave} if err := validateCtx(curCtx, reqs); err != nil { return curCtx, false, err } // If we have a goroutine, it must be running. if state, ok := o.gStates[curCtx.G]; ok && state.status != go122.GoRunning { return curCtx, false, fmt.Errorf("%s event for goroutine that's not %s", go122.EventString(ev.typ), GoRunning) } // This goroutine created another. Add a state for it. newgid := GoID(ev.args[0]) if _, ok := o.gStates[newgid]; ok { return curCtx, false, fmt.Errorf("tried to create goroutine (%v) that already exists", newgid) } status := go122.GoRunnable if ev.typ == go122.EvGoCreateBlocked { status = go122.GoWaiting } o.gStates[newgid] = &gState{id: newgid, status: status, seq: makeSeq(gen, 0)} o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGoStopExec(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // These are goroutine events that all require an active running // goroutine on some thread. They must *always* be advance-able, // since running goroutines are bound to their M. if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } state, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("event %s for goroutine (%v) that doesn't exist", go122.EventString(ev.typ), curCtx.G) } if state.status != go122.GoRunning { return curCtx, false, fmt.Errorf("%s event for goroutine that's not %s", go122.EventString(ev.typ), GoRunning) } // Handle each case slightly differently; we just group them together // because they have shared preconditions. newCtx := curCtx switch ev.typ { case go122.EvGoDestroy: // This goroutine is exiting itself. delete(o.gStates, curCtx.G) newCtx.G = NoGoroutine case go122.EvGoStop: // Goroutine stopped (yielded). It's runnable but not running on this M. state.status = go122.GoRunnable newCtx.G = NoGoroutine case go122.EvGoBlock: // Goroutine blocked. It's waiting now and not running on this M. state.status = go122.GoWaiting newCtx.G = NoGoroutine } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceGoStart(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { gid := GoID(ev.args[0]) seq := makeSeq(gen, ev.args[1]) state, ok := o.gStates[gid] if !ok || state.status != go122.GoRunnable || !seq.succeeds(state.seq) { // We can't make an inference as to whether this is bad. We could just be seeing // a GoStart on a different M before the goroutine was created, before it had its // state emitted, or before we got to the right point in the trace yet. return curCtx, false, nil } // We can advance this goroutine. Check some invariants. reqs := event.SchedReqs{Thread: event.MustHave, Proc: event.MustHave, Goroutine: event.MustNotHave} if err := validateCtx(curCtx, reqs); err != nil { return curCtx, false, err } state.status = go122.GoRunning state.seq = seq newCtx := curCtx newCtx.G = gid o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceGoUnblock(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // N.B. These both reference the goroutine to unblock, not the current goroutine. gid := GoID(ev.args[0]) seq := makeSeq(gen, ev.args[1]) state, ok := o.gStates[gid] if !ok || state.status != go122.GoWaiting || !seq.succeeds(state.seq) { // We can't make an inference as to whether this is bad. We could just be seeing // a GoUnblock on a different M before the goroutine was created and blocked itself, // before it had its state emitted, or before we got to the right point in the trace yet. return curCtx, false, nil } state.status = go122.GoRunnable state.seq = seq // N.B. No context to validate. Basically anything can unblock // a goroutine (e.g. sysmon). o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGoSwitch(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // GoSwitch and GoSwitchDestroy represent a trio of events: // - Unblock of the goroutine to switch to. // - Block or destroy of the current goroutine. // - Start executing the next goroutine. // // Because it acts like a GoStart for the next goroutine, we can // only advance it if the sequence numbers line up. // // The current goroutine on the thread must be actively running. if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } curGState, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("event %s for goroutine (%v) that doesn't exist", go122.EventString(ev.typ), curCtx.G) } if curGState.status != go122.GoRunning { return curCtx, false, fmt.Errorf("%s event for goroutine that's not %s", go122.EventString(ev.typ), GoRunning) } nextg := GoID(ev.args[0]) seq := makeSeq(gen, ev.args[1]) // seq is for nextg, not curCtx.G. nextGState, ok := o.gStates[nextg] if !ok || nextGState.status != go122.GoWaiting || !seq.succeeds(nextGState.seq) { // We can't make an inference as to whether this is bad. We could just be seeing // a GoSwitch on a different M before the goroutine was created, before it had its // state emitted, or before we got to the right point in the trace yet. return curCtx, false, nil } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) // Update the state of the executing goroutine and emit an event for it // (GoSwitch and GoSwitchDestroy will be interpreted as GoUnblock events // for nextg). switch ev.typ { case go122.EvGoSwitch: // Goroutine blocked. It's waiting now and not running on this M. curGState.status = go122.GoWaiting // Emit a GoBlock event. // TODO(mknyszek): Emit a reason. o.queue.push(makeEvent(evt, curCtx, go122.EvGoBlock, ev.time, 0 /* no reason */, 0 /* no stack */)) case go122.EvGoSwitchDestroy: // This goroutine is exiting itself. delete(o.gStates, curCtx.G) // Emit a GoDestroy event. o.queue.push(makeEvent(evt, curCtx, go122.EvGoDestroy, ev.time)) } // Update the state of the next goroutine. nextGState.status = go122.GoRunning nextGState.seq = seq newCtx := curCtx newCtx.G = nextg // Queue an event for the next goroutine starting to run. startCtx := curCtx startCtx.G = NoGoroutine o.queue.push(makeEvent(evt, startCtx, go122.EvGoStart, ev.time, uint64(nextg), ev.args[1])) return newCtx, true, nil } func (o *ordering) advanceGoSyscallBegin(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // Entering a syscall requires an active running goroutine with a // proc on some thread. It is always advancable. if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } state, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("event %s for goroutine (%v) that doesn't exist", go122.EventString(ev.typ), curCtx.G) } if state.status != go122.GoRunning { return curCtx, false, fmt.Errorf("%s event for goroutine that's not %s", go122.EventString(ev.typ), GoRunning) } // Goroutine entered a syscall. It's still running on this P and M. state.status = go122.GoSyscall pState, ok := o.pStates[curCtx.P] if !ok { return curCtx, false, fmt.Errorf("uninitialized proc %d found during %s", curCtx.P, go122.EventString(ev.typ)) } pState.status = go122.ProcSyscall // Validate the P sequence number on the event and advance it. // // We have a P sequence number for what is supposed to be a goroutine event // so that we can correctly model P stealing. Without this sequence number here, // the syscall from which a ProcSteal event is stealing can be ambiguous in the // face of broken timestamps. See the go122-syscall-steal-proc-ambiguous test for // more details. // // Note that because this sequence number only exists as a tool for disambiguation, // we can enforce that we have the right sequence number at this point; we don't need // to back off and see if any other events will advance. This is a running P. pSeq := makeSeq(gen, ev.args[0]) if !pSeq.succeeds(pState.seq) { return curCtx, false, fmt.Errorf("failed to advance %s: can't make sequence: %s -> %s", go122.EventString(ev.typ), pState.seq, pSeq) } pState.seq = pSeq o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGoSyscallEnd(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // This event is always advance-able because it happens on the same // thread that EvGoSyscallStart happened, and the goroutine can't leave // that thread until its done. if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } state, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("event %s for goroutine (%v) that doesn't exist", go122.EventString(ev.typ), curCtx.G) } if state.status != go122.GoSyscall { return curCtx, false, fmt.Errorf("%s event for goroutine that's not %s", go122.EventString(ev.typ), GoRunning) } state.status = go122.GoRunning // Transfer the P back to running from syscall. pState, ok := o.pStates[curCtx.P] if !ok { return curCtx, false, fmt.Errorf("uninitialized proc %d found during %s", curCtx.P, go122.EventString(ev.typ)) } if pState.status != go122.ProcSyscall { return curCtx, false, fmt.Errorf("expected proc %d in state %v, but got %v instead", curCtx.P, go122.ProcSyscall, pState.status) } pState.status = go122.ProcRunning o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGoSyscallEndBlocked(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // This event becomes advanceable when its P is not in a syscall state // (lack of a P altogether is also acceptable for advancing). // The transfer out of ProcSyscall can happen either voluntarily via // ProcStop or involuntarily via ProcSteal. We may also acquire a new P // before we get here (after the transfer out) but that's OK: that new // P won't be in the ProcSyscall state anymore. // // Basically: while we have a preemptible P, don't advance, because we // *know* from the event that we're going to lose it at some point during // the syscall. We shouldn't advance until that happens. if curCtx.P != NoProc { pState, ok := o.pStates[curCtx.P] if !ok { return curCtx, false, fmt.Errorf("uninitialized proc %d found during %s", curCtx.P, go122.EventString(ev.typ)) } if pState.status == go122.ProcSyscall { return curCtx, false, nil } } // As mentioned above, we may have a P here if we ProcStart // before this event. if err := validateCtx(curCtx, event.SchedReqs{Thread: event.MustHave, Proc: event.MayHave, Goroutine: event.MustHave}); err != nil { return curCtx, false, err } state, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("event %s for goroutine (%v) that doesn't exist", go122.EventString(ev.typ), curCtx.G) } if state.status != go122.GoSyscall { return curCtx, false, fmt.Errorf("%s event for goroutine that's not %s", go122.EventString(ev.typ), GoRunning) } newCtx := curCtx newCtx.G = NoGoroutine state.status = go122.GoRunnable o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceGoCreateSyscall(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // This event indicates that a goroutine is effectively // being created out of a cgo callback. Such a goroutine // is 'created' in the syscall state. if err := validateCtx(curCtx, event.SchedReqs{Thread: event.MustHave, Proc: event.MayHave, Goroutine: event.MustNotHave}); err != nil { return curCtx, false, err } // This goroutine is effectively being created. Add a state for it. newgid := GoID(ev.args[0]) if _, ok := o.gStates[newgid]; ok { return curCtx, false, fmt.Errorf("tried to create goroutine (%v) in syscall that already exists", newgid) } o.gStates[newgid] = &gState{id: newgid, status: go122.GoSyscall, seq: makeSeq(gen, 0)} // Goroutine is executing. Bind it to the context. newCtx := curCtx newCtx.G = newgid o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceGoDestroySyscall(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // This event indicates that a goroutine created for a // cgo callback is disappearing, either because the callback // ending or the C thread that called it is being destroyed. // // Also, treat this as if we lost our P too. // The thread ID may be reused by the platform and we'll get // really confused if we try to steal the P is this is running // with later. The new M with the same ID could even try to // steal back this P from itself! // // The runtime is careful to make sure that any GoCreateSyscall // event will enter the runtime emitting events for reacquiring a P. // // Note: we might have a P here. The P might not be released // eagerly by the runtime, and it might get stolen back later // (or never again, if the program is going to exit). if err := validateCtx(curCtx, event.SchedReqs{Thread: event.MustHave, Proc: event.MayHave, Goroutine: event.MustHave}); err != nil { return curCtx, false, err } // Check to make sure the goroutine exists in the right state. state, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("event %s for goroutine (%v) that doesn't exist", go122.EventString(ev.typ), curCtx.G) } if state.status != go122.GoSyscall { return curCtx, false, fmt.Errorf("%s event for goroutine that's not %v", go122.EventString(ev.typ), GoSyscall) } // This goroutine is exiting itself. delete(o.gStates, curCtx.G) newCtx := curCtx newCtx.G = NoGoroutine // If we have a proc, then we're dissociating from it now. See the comment at the top of the case. if curCtx.P != NoProc { pState, ok := o.pStates[curCtx.P] if !ok { return curCtx, false, fmt.Errorf("found invalid proc %d during %s", curCtx.P, go122.EventString(ev.typ)) } if pState.status != go122.ProcSyscall { return curCtx, false, fmt.Errorf("proc %d in unexpected state %s during %s", curCtx.P, pState.status, go122.EventString(ev.typ)) } // See the go122-create-syscall-reuse-thread-id test case for more details. pState.status = go122.ProcSyscallAbandoned newCtx.P = NoProc // Queue an extra self-ProcSteal event. extra := makeEvent(evt, curCtx, go122.EvProcSteal, ev.time, uint64(curCtx.P)) extra.base.extra(version.Go122)[0] = uint64(go122.ProcSyscall) o.queue.push(extra) } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return newCtx, true, nil } func (o *ordering) advanceUserTaskBegin(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // Handle tasks. Tasks are interesting because: // - There's no Begin event required to reference a task. // - End for a particular task ID can appear multiple times. // As a result, there's very little to validate. The only // thing we have to be sure of is that a task didn't begin // after it had already begun. Task IDs are allowed to be // reused, so we don't care about a Begin after an End. id := TaskID(ev.args[0]) if _, ok := o.activeTasks[id]; ok { return curCtx, false, fmt.Errorf("task ID conflict: %d", id) } // Get the parent ID, but don't validate it. There's no guarantee // we actually have information on whether it's active. parentID := TaskID(ev.args[1]) if parentID == BackgroundTask { // Note: a value of 0 here actually means no parent, *not* the // background task. Automatic background task attachment only // applies to regions. parentID = NoTask ev.args[1] = uint64(NoTask) } // Validate the name and record it. We'll need to pass it through to // EvUserTaskEnd. nameID := stringID(ev.args[2]) name, ok := evt.strings.get(nameID) if !ok { return curCtx, false, fmt.Errorf("invalid string ID %v for %v event", nameID, ev.typ) } o.activeTasks[id] = taskState{name: name, parentID: parentID} if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceUserTaskEnd(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { id := TaskID(ev.args[0]) if ts, ok := o.activeTasks[id]; ok { // Smuggle the task info. This may happen in a different generation, // which may not have the name in its string table. Add it to the extra // strings table so we can look it up later. ev.extra(version.Go122)[0] = uint64(ts.parentID) ev.extra(version.Go122)[1] = uint64(evt.addExtraString(ts.name)) delete(o.activeTasks, id) } else { // Explicitly clear the task info. ev.extra(version.Go122)[0] = uint64(NoTask) ev.extra(version.Go122)[1] = uint64(evt.addExtraString("")) } if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceUserRegionBegin(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } tid := TaskID(ev.args[0]) nameID := stringID(ev.args[1]) name, ok := evt.strings.get(nameID) if !ok { return curCtx, false, fmt.Errorf("invalid string ID %v for %v event", nameID, ev.typ) } gState, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("encountered EvUserRegionBegin without known state for current goroutine %d", curCtx.G) } if err := gState.beginRegion(userRegion{tid, name}); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceUserRegionEnd(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } tid := TaskID(ev.args[0]) nameID := stringID(ev.args[1]) name, ok := evt.strings.get(nameID) if !ok { return curCtx, false, fmt.Errorf("invalid string ID %v for %v event", nameID, ev.typ) } gState, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("encountered EvUserRegionEnd without known state for current goroutine %d", curCtx.G) } if err := gState.endRegion(userRegion{tid, name}); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } // Handle the GC mark phase. // // We have sequence numbers for both start and end because they // can happen on completely different threads. We want an explicit // partial order edge between start and end here, otherwise we're // relying entirely on timestamps to make sure we don't advance a // GCEnd for a _different_ GC cycle if timestamps are wildly broken. func (o *ordering) advanceGCActive(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { seq := ev.args[0] if gen == o.initialGen { if o.gcState != gcUndetermined { return curCtx, false, fmt.Errorf("GCActive in the first generation isn't first GC event") } o.gcSeq = seq o.gcState = gcRunning o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } if seq != o.gcSeq+1 { // This is not the right GC cycle. return curCtx, false, nil } if o.gcState != gcRunning { return curCtx, false, fmt.Errorf("encountered GCActive while GC was not in progress") } o.gcSeq = seq if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGCBegin(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { seq := ev.args[0] if o.gcState == gcUndetermined { o.gcSeq = seq o.gcState = gcRunning o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } if seq != o.gcSeq+1 { // This is not the right GC cycle. return curCtx, false, nil } if o.gcState == gcRunning { return curCtx, false, fmt.Errorf("encountered GCBegin while GC was already in progress") } o.gcSeq = seq o.gcState = gcRunning if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGCEnd(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { seq := ev.args[0] if seq != o.gcSeq+1 { // This is not the right GC cycle. return curCtx, false, nil } if o.gcState == gcNotRunning { return curCtx, false, fmt.Errorf("encountered GCEnd when GC was not in progress") } if o.gcState == gcUndetermined { return curCtx, false, fmt.Errorf("encountered GCEnd when GC was in an undetermined state") } o.gcSeq = seq o.gcState = gcNotRunning if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceAnnotation(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // Handle simple instantaneous events that require a G. if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceHeapMetric(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // Handle allocation metrics, which don't require a G. if err := validateCtx(curCtx, event.SchedReqs{Thread: event.MustHave, Proc: event.MustHave, Goroutine: event.MayHave}); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGCSweepBegin(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // Handle sweep, which is bound to a P and doesn't require a G. if err := validateCtx(curCtx, event.SchedReqs{Thread: event.MustHave, Proc: event.MustHave, Goroutine: event.MayHave}); err != nil { return curCtx, false, err } if err := o.pStates[curCtx.P].beginRange(makeRangeType(ev.typ, 0)); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGCSweepActive(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { pid := ProcID(ev.args[0]) // N.B. In practice Ps can't block while they're sweeping, so this can only // ever reference curCtx.P. However, be lenient about this like we are with // GCMarkAssistActive; there's no reason the runtime couldn't change to block // in the middle of a sweep. pState, ok := o.pStates[pid] if !ok { return curCtx, false, fmt.Errorf("encountered GCSweepActive for unknown proc %d", pid) } if err := pState.activeRange(makeRangeType(ev.typ, 0), gen == o.initialGen); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGCSweepEnd(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { if err := validateCtx(curCtx, event.SchedReqs{Thread: event.MustHave, Proc: event.MustHave, Goroutine: event.MayHave}); err != nil { return curCtx, false, err } _, err := o.pStates[curCtx.P].endRange(ev.typ) if err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGoRangeBegin(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // Handle special goroutine-bound event ranges. if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } desc := stringID(0) if ev.typ == go122.EvSTWBegin { desc = stringID(ev.args[0]) } gState, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("encountered event of type %d without known state for current goroutine %d", ev.typ, curCtx.G) } if err := gState.beginRange(makeRangeType(ev.typ, desc)); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGoRangeActive(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { gid := GoID(ev.args[0]) // N.B. Like GoStatus, this can happen at any time, because it can // reference a non-running goroutine. Don't check anything about the // current scheduler context. gState, ok := o.gStates[gid] if !ok { return curCtx, false, fmt.Errorf("uninitialized goroutine %d found during %s", gid, go122.EventString(ev.typ)) } if err := gState.activeRange(makeRangeType(ev.typ, 0), gen == o.initialGen); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceGoRangeEnd(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { if err := validateCtx(curCtx, event.UserGoReqs); err != nil { return curCtx, false, err } gState, ok := o.gStates[curCtx.G] if !ok { return curCtx, false, fmt.Errorf("encountered event of type %d without known state for current goroutine %d", ev.typ, curCtx.G) } desc, err := gState.endRange(ev.typ) if err != nil { return curCtx, false, err } if ev.typ == go122.EvSTWEnd { // Smuggle the kind into the event. // Don't use ev.extra here so we have symmetry with STWBegin. ev.args[0] = uint64(desc) } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } func (o *ordering) advanceAllocFree(ev *baseEvent, evt *evTable, m ThreadID, gen uint64, curCtx schedCtx) (schedCtx, bool, error) { // Handle simple instantaneous events that may or may not have a P. if err := validateCtx(curCtx, event.SchedReqs{Thread: event.MustHave, Proc: event.MayHave, Goroutine: event.MayHave}); err != nil { return curCtx, false, err } o.queue.push(Event{table: evt, ctx: curCtx, base: *ev}) return curCtx, true, nil } // Next returns the next event in the ordering. func (o *ordering) Next() (Event, bool) { return o.queue.pop() } // schedCtx represents the scheduling resources associated with an event. type schedCtx struct { G GoID P ProcID M ThreadID } // validateCtx ensures that ctx conforms to some reqs, returning an error if // it doesn't. func validateCtx(ctx schedCtx, reqs event.SchedReqs) error { // Check thread requirements. if reqs.Thread == event.MustHave && ctx.M == NoThread { return fmt.Errorf("expected a thread but didn't have one") } else if reqs.Thread == event.MustNotHave && ctx.M != NoThread { return fmt.Errorf("expected no thread but had one") } // Check proc requirements. if reqs.Proc == event.MustHave && ctx.P == NoProc { return fmt.Errorf("expected a proc but didn't have one") } else if reqs.Proc == event.MustNotHave && ctx.P != NoProc { return fmt.Errorf("expected no proc but had one") } // Check goroutine requirements. if reqs.Goroutine == event.MustHave && ctx.G == NoGoroutine { return fmt.Errorf("expected a goroutine but didn't have one") } else if reqs.Goroutine == event.MustNotHave && ctx.G != NoGoroutine { return fmt.Errorf("expected no goroutine but had one") } return nil } // gcState is a trinary variable for the current state of the GC. // // The third state besides "enabled" and "disabled" is "undetermined." type gcState uint8 const ( gcUndetermined gcState = iota gcNotRunning gcRunning ) // String returns a human-readable string for the GC state. func (s gcState) String() string { switch s { case gcUndetermined: return "Undetermined" case gcNotRunning: return "NotRunning" case gcRunning: return "Running" } return "Bad" } // userRegion represents a unique user region when attached to some gState. type userRegion struct { // name must be a resolved string because the string ID for the same // string may change across generations, but we care about checking // the value itself. taskID TaskID name string } // rangeType is a way to classify special ranges of time. // // These typically correspond 1:1 with "Begin" events, but // they may have an optional subtype that describes the range // in more detail. type rangeType struct { typ event.Type // "Begin" event. desc stringID // Optional subtype. } // makeRangeType constructs a new rangeType. func makeRangeType(typ event.Type, desc stringID) rangeType { if styp := go122.Specs()[typ].StartEv; styp != go122.EvNone { typ = styp } return rangeType{typ, desc} } // gState is the state of a goroutine at a point in the trace. type gState struct { id GoID status go122.GoStatus seq seqCounter // regions are the active user regions for this goroutine. regions []userRegion // rangeState is the state of special time ranges bound to this goroutine. rangeState } // beginRegion starts a user region on the goroutine. func (s *gState) beginRegion(r userRegion) error { s.regions = append(s.regions, r) return nil } // endRegion ends a user region on the goroutine. func (s *gState) endRegion(r userRegion) error { if len(s.regions) == 0 { // We do not know about regions that began before tracing started. return nil } if next := s.regions[len(s.regions)-1]; next != r { return fmt.Errorf("misuse of region in goroutine %v: region end %v when the inner-most active region start event is %v", s.id, r, next) } s.regions = s.regions[:len(s.regions)-1] return nil } // pState is the state of a proc at a point in the trace. type pState struct { id ProcID status go122.ProcStatus seq seqCounter // rangeState is the state of special time ranges bound to this proc. rangeState } // mState is the state of a thread at a point in the trace. type mState struct { g GoID // Goroutine bound to this M. (The goroutine's state is Executing.) p ProcID // Proc bound to this M. (The proc's state is Executing.) } // rangeState represents the state of special time ranges. type rangeState struct { // inFlight contains the rangeTypes of any ranges bound to a resource. inFlight []rangeType } // beginRange begins a special range in time on the goroutine. // // Returns an error if the range is already in progress. func (s *rangeState) beginRange(typ rangeType) error { if s.hasRange(typ) { return fmt.Errorf("discovered event already in-flight for when starting event %v", go122.Specs()[typ.typ].Name) } s.inFlight = append(s.inFlight, typ) return nil } // activeRange marks special range in time on the goroutine as active in the // initial generation, or confirms that it is indeed active in later generations. func (s *rangeState) activeRange(typ rangeType, isInitialGen bool) error { if isInitialGen { if s.hasRange(typ) { return fmt.Errorf("found named active range already in first gen: %v", typ) } s.inFlight = append(s.inFlight, typ) } else if !s.hasRange(typ) { return fmt.Errorf("resource is missing active range: %v %v", go122.Specs()[typ.typ].Name, s.inFlight) } return nil } // hasRange returns true if a special time range on the goroutine as in progress. func (s *rangeState) hasRange(typ rangeType) bool { for _, ftyp := range s.inFlight { if ftyp == typ { return true } } return false } // endRange ends a special range in time on the goroutine. // // This must line up with the start event type of the range the goroutine is currently in. func (s *rangeState) endRange(typ event.Type) (stringID, error) { st := go122.Specs()[typ].StartEv idx := -1 for i, r := range s.inFlight { if r.typ == st { idx = i break } } if idx < 0 { return 0, fmt.Errorf("tried to end event %v, but not in-flight", go122.Specs()[st].Name) } // Swap remove. desc := s.inFlight[idx].desc s.inFlight[idx], s.inFlight[len(s.inFlight)-1] = s.inFlight[len(s.inFlight)-1], s.inFlight[idx] s.inFlight = s.inFlight[:len(s.inFlight)-1] return desc, nil } // seqCounter represents a global sequence counter for a resource. type seqCounter struct { gen uint64 // The generation for the local sequence counter seq. seq uint64 // The sequence number local to the generation. } // makeSeq creates a new seqCounter. func makeSeq(gen, seq uint64) seqCounter { return seqCounter{gen: gen, seq: seq} } // succeeds returns true if a is the immediate successor of b. func (a seqCounter) succeeds(b seqCounter) bool { return a.gen == b.gen && a.seq == b.seq+1 } // String returns a debug string representation of the seqCounter. func (c seqCounter) String() string { return fmt.Sprintf("%d (gen=%d)", c.seq, c.gen) } func dumpOrdering(order *ordering) string { var sb strings.Builder for id, state := range order.gStates { fmt.Fprintf(&sb, "G %d [status=%s seq=%s]\n", id, state.status, state.seq) } fmt.Fprintln(&sb) for id, state := range order.pStates { fmt.Fprintf(&sb, "P %d [status=%s seq=%s]\n", id, state.status, state.seq) } fmt.Fprintln(&sb) for id, state := range order.mStates { fmt.Fprintf(&sb, "M %d [g=%d p=%d]\n", id, state.g, state.p) } fmt.Fprintln(&sb) fmt.Fprintf(&sb, "GC %d %s\n", order.gcSeq, order.gcState) return sb.String() } // taskState represents an active task. type taskState struct { // name is the type of the active task. name string // parentID is the parent ID of the active task. parentID TaskID } // queue implements a growable ring buffer with a queue API. type queue[T any] struct { start, end int buf []T } // push adds a new event to the back of the queue. func (q *queue[T]) push(value T) { if q.end-q.start == len(q.buf) { q.grow() } q.buf[q.end%len(q.buf)] = value q.end++ } // grow increases the size of the queue. func (q *queue[T]) grow() { if len(q.buf) == 0 { q.buf = make([]T, 2) return } // Create new buf and copy data over. newBuf := make([]T, len(q.buf)*2) pivot := q.start % len(q.buf) first, last := q.buf[pivot:], q.buf[:pivot] copy(newBuf[:len(first)], first) copy(newBuf[len(first):], last) // Update the queue state. q.start = 0 q.end = len(q.buf) q.buf = newBuf } // pop removes an event from the front of the queue. If the // queue is empty, it returns an EventBad event. func (q *queue[T]) pop() (T, bool) { if q.end-q.start == 0 { return *new(T), false } elem := &q.buf[q.start%len(q.buf)] value := *elem *elem = *new(T) // Clear the entry before returning, so we don't hold onto old tables. q.start++ return value, true } // makeEvent creates an Event from the provided information. // // It's just a convenience function; it's always OK to construct // an Event manually if this isn't quite the right way to express // the contents of the event. func makeEvent(table *evTable, ctx schedCtx, typ event.Type, time Time, args ...uint64) Event { ev := Event{ table: table, ctx: ctx, base: baseEvent{ typ: typ, time: time, }, } copy(ev.base.args[:], args) return ev }