open-nomad/client/task_runner.go
2015-11-24 17:26:30 -08:00

347 lines
9.3 KiB
Go

package client
import (
"crypto/md5"
"encoding/hex"
"fmt"
"log"
"os"
"path/filepath"
"sync"
"time"
"github.com/hashicorp/nomad/client/config"
"github.com/hashicorp/nomad/client/driver"
"github.com/hashicorp/nomad/nomad/structs"
cstructs "github.com/hashicorp/nomad/client/driver/structs"
)
// TaskRunner is used to wrap a task within an allocation and provide the execution context.
type TaskRunner struct {
config *config.Config
updater TaskStateUpdater
logger *log.Logger
ctx *driver.ExecContext
allocID string
restartTracker restartTracker
consulService *ConsulService
task *structs.Task
state *structs.TaskState
updateCh chan *structs.Task
handle driver.DriverHandle
destroy bool
destroyCh chan struct{}
destroyLock sync.Mutex
waitCh chan struct{}
snapshotLock sync.Mutex
}
// taskRunnerState is used to snapshot the state of the task runner
type taskRunnerState struct {
Task *structs.Task
HandleID string
}
// TaskStateUpdater is used to signal that tasks state has changed.
type TaskStateUpdater func(taskName string)
// NewTaskRunner is used to create a new task context
func NewTaskRunner(logger *log.Logger, config *config.Config,
updater TaskStateUpdater, ctx *driver.ExecContext,
allocID string, task *structs.Task, state *structs.TaskState,
restartTracker restartTracker, consulService *ConsulService) *TaskRunner {
tc := &TaskRunner{
config: config,
updater: updater,
logger: logger,
restartTracker: restartTracker,
consulService: consulService,
ctx: ctx,
allocID: allocID,
task: task,
state: state,
updateCh: make(chan *structs.Task, 8),
destroyCh: make(chan struct{}),
waitCh: make(chan struct{}),
}
return tc
}
// WaitCh returns a channel to wait for termination
func (r *TaskRunner) WaitCh() <-chan struct{} {
return r.waitCh
}
// stateFilePath returns the path to our state file
func (r *TaskRunner) stateFilePath() string {
// Get the MD5 of the task name
hashVal := md5.Sum([]byte(r.task.Name))
hashHex := hex.EncodeToString(hashVal[:])
dirName := fmt.Sprintf("task-%s", hashHex)
// Generate the path
path := filepath.Join(r.config.StateDir, "alloc", r.allocID,
dirName, "state.json")
return path
}
// RestoreState is used to restore our state
func (r *TaskRunner) RestoreState() error {
// Load the snapshot
var snap taskRunnerState
if err := restoreState(r.stateFilePath(), &snap); err != nil {
return err
}
// Restore fields
r.task = snap.Task
// Restore the driver
if snap.HandleID != "" {
driver, err := r.createDriver()
if err != nil {
return err
}
handle, err := driver.Open(r.ctx, snap.HandleID)
// In the case it fails, we relaunch the task in the Run() method.
if err != nil {
r.logger.Printf("[ERR] client: failed to open handle to task '%s' for alloc '%s': %v",
r.task.Name, r.allocID, err)
return nil
}
r.handle = handle
}
return nil
}
// SaveState is used to snapshot our state
func (r *TaskRunner) SaveState() error {
r.snapshotLock.Lock()
defer r.snapshotLock.Unlock()
snap := taskRunnerState{
Task: r.task,
}
if r.handle != nil {
snap.HandleID = r.handle.ID()
}
return persistState(r.stateFilePath(), &snap)
}
// DestroyState is used to cleanup after ourselves
func (r *TaskRunner) DestroyState() error {
return os.RemoveAll(r.stateFilePath())
}
func (r *TaskRunner) appendEvent(event *structs.TaskEvent) {
capacity := 10
if r.state.Events == nil {
r.state.Events = make([]*structs.TaskEvent, 0, capacity)
}
// If we hit capacity, then shift it.
if len(r.state.Events) == capacity {
old := r.state.Events
r.state.Events = make([]*structs.TaskEvent, 0, capacity)
r.state.Events = append(r.state.Events, old[1:]...)
}
r.state.Events = append(r.state.Events, event)
}
// setState is used to update the state of the task runner
func (r *TaskRunner) setState(state string, event *structs.TaskEvent) {
// Update the task.
r.state.State = state
r.appendEvent(event)
// Persist our state to disk.
if err := r.SaveState(); err != nil {
r.logger.Printf("[ERR] client: failed to save state of Task Runner: %v", r.task.Name)
}
// Indicate the task has been updated.
r.updater(r.task.Name)
}
// createDriver makes a driver for the task
func (r *TaskRunner) createDriver() (driver.Driver, error) {
driverCtx := driver.NewDriverContext(r.task.Name, r.config, r.config.Node, r.logger)
driver, err := driver.NewDriver(r.task.Driver, driverCtx)
if err != nil {
err = fmt.Errorf("failed to create driver '%s' for alloc %s: %v",
r.task.Driver, r.allocID, err)
r.logger.Printf("[ERR] client: %s", err)
}
return driver, err
}
// startTask is used to start the task if there is no handle
func (r *TaskRunner) startTask() error {
// Create a driver
driver, err := r.createDriver()
if err != nil {
e := structs.NewTaskEvent(structs.TaskDriverFailure).SetDriverError(err)
r.setState(structs.TaskStateDead, e)
return err
}
// Start the job
handle, err := driver.Start(r.ctx, r.task)
if err != nil {
r.logger.Printf("[ERR] client: failed to start task '%s' for alloc '%s': %v",
r.task.Name, r.allocID, err)
e := structs.NewTaskEvent(structs.TaskDriverFailure).
SetDriverError(fmt.Errorf("failed to start: %v", err))
r.setState(structs.TaskStateDead, e)
return err
}
r.handle = handle
r.setState(structs.TaskStateRunning, structs.NewTaskEvent(structs.TaskStarted))
return nil
}
// Run is a long running routine used to manage the task
func (r *TaskRunner) Run() {
defer close(r.waitCh)
r.logger.Printf("[DEBUG] client: starting task context for '%s' (alloc '%s')",
r.task.Name, r.allocID)
r.run()
return
}
func (r *TaskRunner) run() {
var forceStart bool
for {
// Start the task if not yet started or it is being forced.
if r.handle == nil || forceStart {
forceStart = false
if err := r.startTask(); err != nil {
return
}
}
// Store the errors that caused use to stop waiting for updates.
var waitRes *cstructs.WaitResult
var destroyErr error
destroyed := false
// Register the services defined by the task with Consil
r.consulService.Register(r.task, r.allocID)
// De-Register the services belonging to the task from consul
defer r.consulService.Deregister(r.task, r.allocID)
OUTER:
// Wait for updates
for {
select {
case waitRes = <-r.handle.WaitCh():
break OUTER
case update := <-r.updateCh:
// Update
r.task = update
if err := r.handle.Update(update); err != nil {
r.logger.Printf("[ERR] client: failed to update task '%s' for alloc '%s': %v", r.task.Name, r.allocID, err)
}
case <-r.destroyCh:
// Avoid destroying twice
if destroyed {
continue
}
// Send the kill signal, and use the WaitCh to block until complete
if err := r.handle.Kill(); err != nil {
r.logger.Printf("[ERR] client: failed to kill task '%s' for alloc '%s': %v", r.task.Name, r.allocID, err)
destroyErr = err
}
destroyed = true
}
}
// If the user destroyed the task, we do not attempt to do any restarts.
if destroyed {
r.setState(structs.TaskStateDead, structs.NewTaskEvent(structs.TaskKilled).SetKillError(destroyErr))
return
}
// Log whether the task was successful or not.
if !waitRes.Successful() {
r.logger.Printf("[ERR] client: failed to complete task '%s' for alloc '%s': %v", r.task.Name, r.allocID, waitRes)
} else {
r.logger.Printf("[INFO] client: completed task '%s' for alloc '%s'", r.task.Name, r.allocID)
}
// Check if we should restart. If not mark task as dead and exit.
shouldRestart, when := r.restartTracker.nextRestart(waitRes.ExitCode)
waitEvent := r.waitErrorToEvent(waitRes)
if !shouldRestart {
r.logger.Printf("[INFO] client: Not restarting task: %v for alloc: %v ", r.task.Name, r.allocID)
r.setState(structs.TaskStateDead, waitEvent)
return
}
r.logger.Printf("[INFO] client: Restarting Task: %v", r.task.Name)
r.logger.Printf("[DEBUG] client: Sleeping for %v before restarting Task %v", when, r.task.Name)
r.setState(structs.TaskStatePending, waitEvent)
// Sleep but watch for destroy events.
select {
case <-time.After(when):
case <-r.destroyCh:
}
// Destroyed while we were waiting to restart, so abort.
r.destroyLock.Lock()
destroyed = r.destroy
r.destroyLock.Unlock()
if destroyed {
r.logger.Printf("[DEBUG] client: Not restarting task: %v because it's destroyed by user", r.task.Name)
r.setState(structs.TaskStateDead, structs.NewTaskEvent(structs.TaskKilled))
return
}
// Set force start because we are restarting the task.
forceStart = true
}
return
}
// Helper function for converting a WaitResult into a TaskTerminated event.
func (r *TaskRunner) waitErrorToEvent(res *cstructs.WaitResult) *structs.TaskEvent {
return structs.NewTaskEvent(structs.TaskTerminated).
SetExitCode(res.ExitCode).
SetSignal(res.Signal).
SetExitMessage(res.Err)
}
// Update is used to update the task of the context
func (r *TaskRunner) Update(update *structs.Task) {
select {
case r.updateCh <- update:
default:
r.logger.Printf("[ERR] client: dropping task update '%s' (alloc '%s')",
update.Name, r.allocID)
}
}
// Destroy is used to indicate that the task context should be destroyed
func (r *TaskRunner) Destroy() {
r.destroyLock.Lock()
defer r.destroyLock.Unlock()
if r.destroy {
return
}
r.destroy = true
close(r.destroyCh)
}