package taskrunner import ( "context" "fmt" "sync" "time" metrics "github.com/armon/go-metrics" log "github.com/hashicorp/go-hclog" "github.com/hashicorp/nomad/client/allocdir" "github.com/hashicorp/nomad/client/allocrunner/taskrunner/restarts" "github.com/hashicorp/nomad/client/allocrunnerv2/interfaces" "github.com/hashicorp/nomad/client/allocrunnerv2/taskrunner/state" "github.com/hashicorp/nomad/client/config" "github.com/hashicorp/nomad/client/consul" "github.com/hashicorp/nomad/client/driver" "github.com/hashicorp/nomad/client/driver/env" dstructs "github.com/hashicorp/nomad/client/driver/structs" cstate "github.com/hashicorp/nomad/client/state" cstructs "github.com/hashicorp/nomad/client/structs" "github.com/hashicorp/nomad/client/vaultclient" "github.com/hashicorp/nomad/nomad/structs" ) const ( // killBackoffBaseline is the baseline time for exponential backoff while // killing a task. killBackoffBaseline = 5 * time.Second // killBackoffLimit is the limit of the exponential backoff for killing // the task. killBackoffLimit = 2 * time.Minute // killFailureLimit is how many times we will attempt to kill a task before // giving up and potentially leaking resources. killFailureLimit = 5 // triggerUpdatechCap is the capacity for the triggerUpdateCh used for // triggering updates. It should be exactly 1 as even if multiple // updates have come in since the last one was handled, we only need to // handle the last one. triggerUpdateChCap = 1 ) type TaskRunner struct { // allocID and taskName are immutable so these fields may be accessed // without locks allocID string taskName string alloc *structs.Allocation allocLock sync.Mutex clientConfig *config.Config // stateUpdater is used to emit updated task state stateUpdater interfaces.TaskStateHandler // state captures the state of the task for updating the allocation state *structs.TaskState stateLock sync.Mutex // localState captures the node-local state of the task for when the // Nomad agent restarts localState *state.LocalState localStateLock sync.RWMutex // stateDB is for persisting localState and taskState stateDB cstate.StateDB // persistedHash is the hash of the last persisted state for skipping // unnecessary writes persistedHash []byte // ctx is the task runner's context representing the tasks's lifecycle. // Canceling the context will cause the task to be destroyed. ctx context.Context // ctxCancel is used to exit the task runner's Run loop without // stopping the task. Shutdown hooks are run. ctxCancel context.CancelFunc // Logger is the logger for the task runner. logger log.Logger // triggerUpdateCh is ticked whenever update hooks need to be run and // must be created with cap=1 to signal a pending update and prevent // callers from deadlocking if the receiver has exited. triggerUpdateCh chan struct{} // waitCh is closed when the task runner has transitioned to a terminal // state waitCh chan struct{} // driver is the driver for the task. driver driver.Driver handle driver.DriverHandle // the handle to the running driver handleResult *handleResult // proxy for handle results handleLock sync.Mutex // task is the task being run task *structs.Task taskLock sync.RWMutex // taskDir is the directory structure for this task. taskDir *allocdir.TaskDir // envBuilder is used to build the task's environment envBuilder *env.Builder // restartTracker is used to decide if the task should be restarted. restartTracker *restarts.RestartTracker // runnerHooks are task runner lifecycle hooks that should be run on state // transistions. runnerHooks []interfaces.TaskHook // consulClient is the client used by the consul service hook for // registering services and checks consulClient consul.ConsulServiceAPI // vaultClient is the client to use to derive and renew Vault tokens vaultClient vaultclient.VaultClient // vaultToken is the current Vault token. It should be accessed with the // getter. vaultToken string vaultTokenLock sync.Mutex // baseLabels are used when emitting tagged metrics. All task runner metrics // will have these tags, and optionally more. baseLabels []metrics.Label // logmonHookConfig is used to get the paths to the stdout and stderr fifos // to be passed to the driver for task logging logmonHookConfig *logmonHookConfig // resourceUsage is written via UpdateStats and read via // LatestResourceUsage. May be nil at all times. resourceUsage *cstructs.TaskResourceUsage resourceUsageLock sync.Mutex } type Config struct { Alloc *structs.Allocation ClientConfig *config.Config Consul consul.ConsulServiceAPI Task *structs.Task TaskDir *allocdir.TaskDir Logger log.Logger // VaultClient is the client to use to derive and renew Vault tokens VaultClient vaultclient.VaultClient // LocalState is optionally restored task state LocalState *state.LocalState // StateDB is used to store and restore state. StateDB cstate.StateDB // StateUpdater is used to emit updated task state StateUpdater interfaces.TaskStateHandler } func NewTaskRunner(config *Config) (*TaskRunner, error) { // Create a context for the runner trCtx, trCancel := context.WithCancel(context.Background()) // Initialize the environment builder envBuilder := env.NewBuilder( config.ClientConfig.Node, config.Alloc, config.Task, config.ClientConfig.Region, ) tr := &TaskRunner{ alloc: config.Alloc, allocID: config.Alloc.ID, clientConfig: config.ClientConfig, task: config.Task, taskDir: config.TaskDir, taskName: config.Task.Name, envBuilder: envBuilder, consulClient: config.Consul, vaultClient: config.VaultClient, state: config.Alloc.TaskStates[config.Task.Name].Copy(), localState: config.LocalState, stateDB: config.StateDB, stateUpdater: config.StateUpdater, ctx: trCtx, ctxCancel: trCancel, triggerUpdateCh: make(chan struct{}, triggerUpdateChCap), waitCh: make(chan struct{}), } // Create the logger based on the allocation ID tr.logger = config.Logger.Named("task_runner").With("task", config.Task.Name) // Build the restart tracker. tg := tr.alloc.Job.LookupTaskGroup(tr.alloc.TaskGroup) if tg == nil { tr.logger.Error("alloc missing task group") return nil, fmt.Errorf("alloc missing task group") } tr.restartTracker = restarts.NewRestartTracker(tg.RestartPolicy, tr.alloc.Job.Type) // Initialize the task state tr.initState() // Get the driver if err := tr.initDriver(); err != nil { tr.logger.Error("failed to create driver", "error", err) return nil, err } // Initialize the runners hooks. tr.initHooks() // Initialize base labels tr.initLabels() return tr, nil } func (tr *TaskRunner) initState() { if tr.state == nil { tr.state = &structs.TaskState{ State: structs.TaskStatePending, } } if tr.localState == nil { tr.localState = state.NewLocalState() } } func (tr *TaskRunner) initLabels() { alloc := tr.Alloc() tr.baseLabels = []metrics.Label{ { Name: "job", Value: alloc.Job.Name, }, { Name: "task_group", Value: alloc.TaskGroup, }, { Name: "alloc_id", Value: tr.allocID, }, { Name: "task", Value: tr.taskName, }, } } func (tr *TaskRunner) Run() { defer close(tr.waitCh) var waitRes *dstructs.WaitResult // Updates are handled asynchronously with the other hooks but each // triggered update - whether due to alloc updates or a new vault token // - should be handled serially. go tr.handleUpdates() MAIN: for tr.ctx.Err() == nil { // Run the prestart hooks if err := tr.prestart(); err != nil { tr.logger.Error("prestart failed", "error", err) tr.restartTracker.SetStartError(err) goto RESTART } if tr.ctx.Err() != nil { break MAIN } // Run the task if err := tr.runDriver(); err != nil { tr.logger.Error("running driver failed", "error", err) tr.restartTracker.SetStartError(err) goto RESTART } // Run the poststart hooks if err := tr.poststart(); err != nil { tr.logger.Error("poststart failed", "error", err) } // Grab the result proxy and wait for task to exit { _, result := tr.getDriverHandle() // Do *not* use tr.ctx here as it would cause Wait() to // unblock before the task exits when Kill() is called. waitRes = result.Wait(context.Background()) } // Clear the handle tr.clearDriverHandle() // Store the wait result on the restart tracker tr.restartTracker.SetWaitResult(waitRes) if err := tr.exited(); err != nil { tr.logger.Error("exited hooks failed", "error", err) } RESTART: restart, restartDelay := tr.shouldRestart() if !restart { break MAIN } // Actually restart by sleeping and also watching for destroy events select { case <-time.After(restartDelay): case <-tr.ctx.Done(): tr.logger.Trace("task killed between restarts", "delay", restartDelay) break MAIN } } // If task terminated, update server. All other exit conditions (eg // killed or out of restarts) will perform their own server updates. if waitRes != nil { event := structs.NewTaskEvent(structs.TaskTerminated). SetExitCode(waitRes.ExitCode). SetSignal(waitRes.Signal). SetExitMessage(waitRes.Err) tr.UpdateState(structs.TaskStateDead, event) } // Run the stop hooks if err := tr.stop(); err != nil { tr.logger.Error("stop failed", "error", err) } tr.logger.Debug("task run loop exiting") } // handleUpdates runs update hooks when triggerUpdateCh is ticked and exits // when Run has returned. Should only be run in a goroutine from Run. func (tr *TaskRunner) handleUpdates() { for { select { case <-tr.triggerUpdateCh: case <-tr.waitCh: return } if tr.Alloc().TerminalStatus() { // Terminal update: kill TaskRunner and let Run execute postrun hooks err := tr.Kill(context.TODO(), structs.NewTaskEvent(structs.TaskKilled)) if err != nil { tr.logger.Warn("error stopping task", "error", err) } continue } // Non-terminal update; run hooks tr.updateHooks() } } // shouldRestart determines whether the task should be restarted and updates // the task state unless the task is killed or terminated. func (tr *TaskRunner) shouldRestart() (bool, time.Duration) { // Determine if we should restart state, when := tr.restartTracker.GetState() reason := tr.restartTracker.GetReason() switch state { case structs.TaskKilled: // Never restart an explicitly killed task. Kill method handles // updating the server. return false, 0 case structs.TaskNotRestarting, structs.TaskTerminated: tr.logger.Info("not restarting task", "reason", reason) if state == structs.TaskNotRestarting { tr.UpdateState(structs.TaskStateDead, structs.NewTaskEvent(structs.TaskNotRestarting).SetRestartReason(reason).SetFailsTask()) } return false, 0 case structs.TaskRestarting: tr.logger.Info("restarting task", "reason", reason, "delay", when) tr.UpdateState(structs.TaskStatePending, structs.NewTaskEvent(structs.TaskRestarting).SetRestartDelay(when).SetRestartReason(reason)) return true, 0 default: tr.logger.Error("restart tracker returned unknown state", "state", state) return true, when } } // runDriver runs the driver and waits for it to exit func (tr *TaskRunner) runDriver() error { // Run prestart ctx := driver.NewExecContext(tr.taskDir, tr.envBuilder.Build()) _, err := tr.driver.Prestart(ctx, tr.task) if err != nil { tr.logger.Error("driver pre-start failed", "error", err) return err } // Create a new context for Start since the environment may have been updated. ctx = driver.NewExecContext(tr.taskDir, tr.envBuilder.Build()) ctx.StdoutFifo = tr.logmonHookConfig.stdoutFifo ctx.StderrFifo = tr.logmonHookConfig.stderrFifo // Start the job sresp, err := tr.driver.Start(ctx, tr.task) if err != nil { tr.logger.Warn("driver start failed", "error", err) return err } // Store the driver handle and associated metadata tr.setDriverHandle(sresp.Handle) // Emit an event that we started tr.UpdateState(structs.TaskStateRunning, structs.NewTaskEvent(structs.TaskStarted)) return nil } // initDriver creates the driver for the task func (tr *TaskRunner) initDriver() error { // Create a task-specific event emitter callback to expose minimal // state to drivers //XXX Replace with EmitEvent -- no need for a shim eventEmitter := func(m string, args ...interface{}) { msg := fmt.Sprintf(m, args...) tr.logger.Debug("driver event", "event", msg) tr.EmitEvent(structs.NewTaskEvent(structs.TaskDriverMessage).SetDriverMessage(msg)) } alloc := tr.Alloc() driverCtx := driver.NewDriverContext( alloc.Job.Name, alloc.TaskGroup, tr.taskName, tr.allocID, tr.clientConfig, // XXX Why does it need this tr.clientConfig.Node, // XXX THIS I NEED TO FIX tr.logger.StandardLogger(nil), // XXX Should pass this through eventEmitter) driver, err := driver.NewDriver(tr.task.Driver, driverCtx) if err != nil { return err } tr.driver = driver return nil } // handleDestroy kills the task handle. In the case that killing fails, // handleDestroy will retry with an exponential backoff and will give up at a // given limit. It returns whether the task was destroyed and the error // associated with the last kill attempt. func (tr *TaskRunner) handleDestroy(handle driver.DriverHandle) (destroyed bool, err error) { // Cap the number of times we attempt to kill the task. for i := 0; i < killFailureLimit; i++ { if err = handle.Kill(); err != nil { // Calculate the new backoff backoff := (1 << (2 * uint64(i))) * killBackoffBaseline if backoff > killBackoffLimit { backoff = killBackoffLimit } tr.logger.Error("failed to kill task", "backoff", backoff, "error", err) time.Sleep(backoff) } else { // Kill was successful return true, nil } } return } // persistLocalState persists local state to disk synchronously. func (tr *TaskRunner) persistLocalState() error { tr.localStateLock.Lock() defer tr.localStateLock.Unlock() return tr.stateDB.PutTaskRunnerLocalState(tr.allocID, tr.taskName, tr.localState) } // XXX If the objects don't exists since the client shutdown before the task // runner ever saved state, then we should treat it as a new task runner and not // return an error // // Restore task runner state. Called by AllocRunner.Restore after NewTaskRunner // but before Run so no locks need to be acquired. func (tr *TaskRunner) Restore() error { ls, ts, err := tr.stateDB.GetTaskRunnerState(tr.allocID, tr.taskName) if err != nil { return err } tr.localState = ls tr.state = ts return nil } // UpdateState sets the task runners allocation state and triggers a server // update. func (tr *TaskRunner) UpdateState(state string, event *structs.TaskEvent) { tr.logger.Debug("setting task state", "state", state, "event", event.Type) // Update the local state stateCopy := tr.setStateLocal(state, event) // Notify the alloc runner of the transition tr.stateUpdater.TaskStateUpdated(tr.taskName, stateCopy) } // setStateLocal updates the local in-memory state, persists a copy to disk and returns a // copy of the task's state. func (tr *TaskRunner) setStateLocal(state string, event *structs.TaskEvent) *structs.TaskState { tr.stateLock.Lock() defer tr.stateLock.Unlock() //XXX REMOVE ME AFTER TESTING if state == "" { panic("UpdateState must not be called with an empty state") } // Update the task state oldState := tr.state.State taskState := tr.state taskState.State = state // Append the event tr.appendEvent(event) // Handle the state transition. switch state { case structs.TaskStateRunning: // Capture the start time if it is just starting if oldState != structs.TaskStateRunning { taskState.StartedAt = time.Now().UTC() if !tr.clientConfig.DisableTaggedMetrics { metrics.IncrCounterWithLabels([]string{"client", "allocs", "running"}, 1, tr.baseLabels) } //if r.config.BackwardsCompatibleMetrics { //metrics.IncrCounter([]string{"client", "allocs", r.alloc.Job.Name, r.alloc.TaskGroup, taskName, "running"}, 1) //} } case structs.TaskStateDead: // Capture the finished time if not already set if taskState.FinishedAt.IsZero() { taskState.FinishedAt = time.Now().UTC() } // Emitting metrics to indicate task complete and failures if taskState.Failed { if !tr.clientConfig.DisableTaggedMetrics { metrics.IncrCounterWithLabels([]string{"client", "allocs", "failed"}, 1, tr.baseLabels) } //if r.config.BackwardsCompatibleMetrics { //metrics.IncrCounter([]string{"client", "allocs", r.alloc.Job.Name, r.alloc.TaskGroup, taskName, "failed"}, 1) //} } else { if !tr.clientConfig.DisableTaggedMetrics { metrics.IncrCounterWithLabels([]string{"client", "allocs", "complete"}, 1, tr.baseLabels) } //if r.config.BackwardsCompatibleMetrics { //metrics.IncrCounter([]string{"client", "allocs", r.alloc.Job.Name, r.alloc.TaskGroup, taskName, "complete"}, 1) //} } } // Persist the state and event if err := tr.stateDB.PutTaskState(tr.allocID, tr.taskName, taskState); err != nil { // Only a warning because the next event/state-transition will // try to persist it again. tr.logger.Error("error persisting task state", "error", err, "event", event, "state", state) } return tr.state.Copy() } // EmitEvent appends a new TaskEvent to this task's TaskState. The actual // TaskState.State (pending, running, dead) is not changed. Use UpdateState to // transition states. // Events are persisted locally and sent to the server, but errors are simply // logged. Use AppendEvent to simply add a new event. func (tr *TaskRunner) EmitEvent(event *structs.TaskEvent) { tr.stateLock.Lock() defer tr.stateLock.Unlock() tr.appendEvent(event) if err := tr.stateDB.PutTaskState(tr.allocID, tr.taskName, tr.state); err != nil { // Only a warning because the next event/state-transition will // try to persist it again. tr.logger.Warn("error persisting event", "error", err, "event", event) } // Notify the alloc runner of the event tr.stateUpdater.TaskStateUpdated(tr.taskName, tr.state.Copy()) } // AppendEvent appends a new TaskEvent to this task's TaskState. The actual // TaskState.State (pending, running, dead) is not changed. Use UpdateState to // transition states. // Events are persisted locally and errors are simply logged. Use EmitEvent // also update AllocRunner. func (tr *TaskRunner) AppendEvent(event *structs.TaskEvent) { tr.stateLock.Lock() defer tr.stateLock.Unlock() tr.appendEvent(event) if err := tr.stateDB.PutTaskState(tr.allocID, tr.taskName, tr.state); err != nil { // Only a warning because the next event/state-transition will // try to persist it again. tr.logger.Warn("error persisting event", "error", err, "event", event) } } // appendEvent to task's event slice. Caller must acquire stateLock. func (tr *TaskRunner) appendEvent(event *structs.TaskEvent) error { // Ensure the event is populated with human readable strings event.PopulateEventDisplayMessage() // Propogate failure from event to task state if event.FailsTask { tr.state.Failed = true } // XXX This seems like a super awkward spot for this? Why not shouldRestart? // Update restart metrics if event.Type == structs.TaskRestarting { if !tr.clientConfig.DisableTaggedMetrics { metrics.IncrCounterWithLabels([]string{"client", "allocs", "restart"}, 1, tr.baseLabels) } //if r.config.BackwardsCompatibleMetrics { //metrics.IncrCounter([]string{"client", "allocs", r.alloc.Job.Name, r.alloc.TaskGroup, taskName, "restart"}, 1) //} tr.state.Restarts++ tr.state.LastRestart = time.Unix(0, event.Time) } // Append event to slice appendTaskEvent(tr.state, event) return nil } // WaitCh is closed when TaskRunner.Run exits. func (tr *TaskRunner) WaitCh() <-chan struct{} { return tr.waitCh } // Update the running allocation with a new version received from the server. // Calls Update hooks asynchronously with Run(). // // This method is safe for calling concurrently with Run() and does not modify // the passed in allocation. func (tr *TaskRunner) Update(update *structs.Allocation) { // Update tr.alloc tr.setAlloc(update) // Trigger update hooks tr.triggerUpdateHooks() } // triggerUpdate if there isn't already an update pending. Should be called // instead of calling updateHooks directly to serialize runs of update hooks. // TaskRunner state should be updated prior to triggering update hooks. // // Does not block. func (tr *TaskRunner) triggerUpdateHooks() { select { case tr.triggerUpdateCh <- struct{}{}: default: // already an update hook pending } } // LatestResourceUsage returns the last resource utilization datapoint // collected. May return nil if the task is not running or no resource // utilization has been collected yet. func (tr *TaskRunner) LatestResourceUsage() *cstructs.TaskResourceUsage { tr.resourceUsageLock.Lock() ru := tr.resourceUsage tr.resourceUsageLock.Unlock() return ru } // UpdateStats updates and emits the latest stats from the driver. func (tr *TaskRunner) UpdateStats(ru *cstructs.TaskResourceUsage) { tr.resourceUsageLock.Lock() tr.resourceUsage = ru tr.resourceUsageLock.Unlock() if ru != nil { tr.emitStats(ru) } } //TODO Remove Backwardscompat or use tr.Alloc()? func (tr *TaskRunner) setGaugeForMemory(ru *cstructs.TaskResourceUsage) { if !tr.clientConfig.DisableTaggedMetrics { metrics.SetGaugeWithLabels([]string{"client", "allocs", "memory", "rss"}, float32(ru.ResourceUsage.MemoryStats.RSS), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "memory", "rss"}, float32(ru.ResourceUsage.MemoryStats.RSS), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "memory", "cache"}, float32(ru.ResourceUsage.MemoryStats.Cache), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "memory", "swap"}, float32(ru.ResourceUsage.MemoryStats.Swap), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "memory", "max_usage"}, float32(ru.ResourceUsage.MemoryStats.MaxUsage), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "memory", "kernel_usage"}, float32(ru.ResourceUsage.MemoryStats.KernelUsage), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "memory", "kernel_max_usage"}, float32(ru.ResourceUsage.MemoryStats.KernelMaxUsage), tr.baseLabels) } if tr.clientConfig.BackwardsCompatibleMetrics { metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "memory", "rss"}, float32(ru.ResourceUsage.MemoryStats.RSS)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "memory", "cache"}, float32(ru.ResourceUsage.MemoryStats.Cache)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "memory", "swap"}, float32(ru.ResourceUsage.MemoryStats.Swap)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "memory", "max_usage"}, float32(ru.ResourceUsage.MemoryStats.MaxUsage)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "memory", "kernel_usage"}, float32(ru.ResourceUsage.MemoryStats.KernelUsage)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "memory", "kernel_max_usage"}, float32(ru.ResourceUsage.MemoryStats.KernelMaxUsage)) } } //TODO Remove Backwardscompat or use tr.Alloc()? func (tr *TaskRunner) setGaugeForCPU(ru *cstructs.TaskResourceUsage) { if !tr.clientConfig.DisableTaggedMetrics { metrics.SetGaugeWithLabels([]string{"client", "allocs", "cpu", "total_percent"}, float32(ru.ResourceUsage.CpuStats.Percent), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "cpu", "system"}, float32(ru.ResourceUsage.CpuStats.SystemMode), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "cpu", "user"}, float32(ru.ResourceUsage.CpuStats.UserMode), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "cpu", "throttled_time"}, float32(ru.ResourceUsage.CpuStats.ThrottledTime), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "cpu", "throttled_periods"}, float32(ru.ResourceUsage.CpuStats.ThrottledPeriods), tr.baseLabels) metrics.SetGaugeWithLabels([]string{"client", "allocs", "cpu", "total_ticks"}, float32(ru.ResourceUsage.CpuStats.TotalTicks), tr.baseLabels) } if tr.clientConfig.BackwardsCompatibleMetrics { metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "cpu", "total_percent"}, float32(ru.ResourceUsage.CpuStats.Percent)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "cpu", "system"}, float32(ru.ResourceUsage.CpuStats.SystemMode)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "cpu", "user"}, float32(ru.ResourceUsage.CpuStats.UserMode)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "cpu", "throttled_time"}, float32(ru.ResourceUsage.CpuStats.ThrottledTime)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "cpu", "throttled_periods"}, float32(ru.ResourceUsage.CpuStats.ThrottledPeriods)) metrics.SetGauge([]string{"client", "allocs", tr.alloc.Job.Name, tr.alloc.TaskGroup, tr.allocID, tr.taskName, "cpu", "total_ticks"}, float32(ru.ResourceUsage.CpuStats.TotalTicks)) } } // emitStats emits resource usage stats of tasks to remote metrics collector // sinks func (tr *TaskRunner) emitStats(ru *cstructs.TaskResourceUsage) { if !tr.clientConfig.PublishAllocationMetrics { return } if ru.ResourceUsage.MemoryStats != nil { tr.setGaugeForMemory(ru) } if ru.ResourceUsage.CpuStats != nil { tr.setGaugeForCPU(ru) } } // appendTaskEvent updates the task status by appending the new event. func appendTaskEvent(state *structs.TaskState, event *structs.TaskEvent) { const capacity = 10 if state.Events == nil { state.Events = make([]*structs.TaskEvent, 1, capacity) state.Events[0] = event return } // If we hit capacity, then shift it. if len(state.Events) == capacity { old := state.Events state.Events = make([]*structs.TaskEvent, 0, capacity) state.Events = append(state.Events, old[1:]...) } state.Events = append(state.Events, event) }