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asynq/server.go
Ken Hibino fb38086590 Clean up log messages
Moved development purpose log messages to DEBUG level.
2020-05-16 08:00:35 -07:00

428 lines
12 KiB
Go

// Copyright 2020 Kentaro Hibino. All rights reserved.
// Use of this source code is governed by a MIT license
// that can be found in the LICENSE file.
package asynq
import (
"context"
"errors"
"fmt"
"math"
"math/rand"
"os"
"runtime"
"strings"
"sync"
"time"
"github.com/hibiken/asynq/internal/base"
"github.com/hibiken/asynq/internal/log"
"github.com/hibiken/asynq/internal/rdb"
)
// Server is responsible for managing the background-task processing.
//
// Server pulls tasks off queues and processes them.
// If the processing of a task is unsuccessful, server will
// schedule it for a retry.
// A task will be retried until either the task gets processed successfully
// or until it reaches its max retry count.
//
// If a task exhausts its retries, it will be moved to the "dead" queue and
// will be kept in the queue for some time until a certain condition is met
// (e.g., queue size reaches a certain limit, or the task has been in the
// queue for a certain amount of time).
type Server struct {
ss *base.ServerState
logger *log.Logger
broker base.Broker
// wait group to wait for all goroutines to finish.
wg sync.WaitGroup
scheduler *scheduler
processor *processor
syncer *syncer
heartbeater *heartbeater
subscriber *subscriber
}
// Config specifies the server's background-task processing behavior.
type Config struct {
// Maximum number of concurrent processing of tasks.
//
// If set to a zero or negative value, NewServer will overwrite the value
// to the number of CPUs usable by the currennt process.
Concurrency int
// Function to calculate retry delay for a failed task.
//
// By default, it uses exponential backoff algorithm to calculate the delay.
//
// n is the number of times the task has been retried.
// e is the error returned by the task handler.
// t is the task in question.
RetryDelayFunc func(n int, e error, t *Task) time.Duration
// List of queues to process with given priority value. Keys are the names of the
// queues and values are associated priority value.
//
// If set to nil or not specified, the server will process only the "default" queue.
//
// Priority is treated as follows to avoid starving low priority queues.
//
// Example:
// Queues: map[string]int{
// "critical": 6,
// "default": 3,
// "low": 1,
// }
// With the above config and given that all queues are not empty, the tasks
// in "critical", "default", "low" should be processed 60%, 30%, 10% of
// the time respectively.
//
// If a queue has a zero or negative priority value, the queue will be ignored.
Queues map[string]int
// StrictPriority indicates whether the queue priority should be treated strictly.
//
// If set to true, tasks in the queue with the highest priority is processed first.
// The tasks in lower priority queues are processed only when those queues with
// higher priorities are empty.
StrictPriority bool
// ErrorHandler handles errors returned by the task handler.
//
// HandleError is invoked only if the task handler returns a non-nil error.
//
// Example:
// func reportError(task *asynq.Task, err error, retried, maxRetry int) {
// if retried >= maxRetry {
// err = fmt.Errorf("retry exhausted for task %s: %w", task.Type, err)
// }
// errorReportingService.Notify(err)
// })
//
// ErrorHandler: asynq.ErrorHandlerFunc(reportError)
ErrorHandler ErrorHandler
// Logger specifies the logger used by the server instance.
//
// If unset, default logger is used.
Logger Logger
// LogLevel specifies the minimum log level to enable.
//
// If unset, InfoLevel is used by default.
LogLevel LogLevel
// ShutdownTimeout specifies the duration to wait to let workers finish their tasks
// before forcing them to abort when stopping the server.
//
// If unset or zero, default timeout of 8 seconds is used.
ShutdownTimeout time.Duration
}
// An ErrorHandler handles errors returned by the task handler.
type ErrorHandler interface {
HandleError(task *Task, err error, retried, maxRetry int)
}
// The ErrorHandlerFunc type is an adapter to allow the use of ordinary functions as a ErrorHandler.
// If f is a function with the appropriate signature, ErrorHandlerFunc(f) is a ErrorHandler that calls f.
type ErrorHandlerFunc func(task *Task, err error, retried, maxRetry int)
// HandleError calls fn(task, err, retried, maxRetry)
func (fn ErrorHandlerFunc) HandleError(task *Task, err error, retried, maxRetry int) {
fn(task, err, retried, maxRetry)
}
// Logger supports logging at various log levels.
type Logger interface {
// Debug logs a message at Debug level.
Debug(args ...interface{})
// Info logs a message at Info level.
Info(args ...interface{})
// Warn logs a message at Warning level.
Warn(args ...interface{})
// Error logs a message at Error level.
Error(args ...interface{})
// Fatal logs a message at Fatal level
// and process will exit with status set to 1.
Fatal(args ...interface{})
}
// LogLevel represents logging level.
//
// It satisfies flag.Value interface.
type LogLevel int32
const (
// Note: reserving value zero to differentiate unspecified case.
level_unspecified LogLevel = iota
// DebugLevel is the lowest level of logging.
// Debug logs are intended for debugging and development purposes.
DebugLevel
// InfoLevel is used for general informational log messages.
InfoLevel
// WarnLevel is used for undesired but relatively expected events,
// which may indicate a problem.
WarnLevel
// ErrorLevel is used for undesired and unexpected events that
// the program can recover from.
ErrorLevel
// FatalLevel is used for undesired and unexpected events that
// the program cannot recover from.
FatalLevel
)
// String is part of the flag.Value interface.
func (l *LogLevel) String() string {
switch *l {
case DebugLevel:
return "debug"
case InfoLevel:
return "info"
case WarnLevel:
return "warn"
case ErrorLevel:
return "error"
case FatalLevel:
return "fatal"
}
panic(fmt.Sprintf("asynq: unexpected log level: %v", *l))
}
// Set is part of the flag.Value interface.
func (l *LogLevel) Set(val string) error {
switch strings.ToLower(val) {
case "debug":
*l = DebugLevel
case "info":
*l = InfoLevel
case "warn", "warning":
*l = WarnLevel
case "error":
*l = ErrorLevel
case "fatal":
*l = FatalLevel
default:
return fmt.Errorf("asynq: unsupported log level %q", val)
}
return nil
}
func toInternalLogLevel(l LogLevel) log.Level {
switch l {
case DebugLevel:
return log.DebugLevel
case InfoLevel:
return log.InfoLevel
case WarnLevel:
return log.WarnLevel
case ErrorLevel:
return log.ErrorLevel
case FatalLevel:
return log.FatalLevel
}
panic(fmt.Sprintf("asynq: unexpected log level: %v", l))
}
// Formula taken from https://github.com/mperham/sidekiq.
func defaultDelayFunc(n int, e error, t *Task) time.Duration {
r := rand.New(rand.NewSource(time.Now().UnixNano()))
s := int(math.Pow(float64(n), 4)) + 15 + (r.Intn(30) * (n + 1))
return time.Duration(s) * time.Second
}
var defaultQueueConfig = map[string]int{
base.DefaultQueueName: 1,
}
const defaultShutdownTimeout = 8 * time.Second
// NewServer returns a new Server given a redis connection option
// and background processing configuration.
func NewServer(r RedisConnOpt, cfg Config) *Server {
n := cfg.Concurrency
if n < 1 {
n = runtime.NumCPU()
}
delayFunc := cfg.RetryDelayFunc
if delayFunc == nil {
delayFunc = defaultDelayFunc
}
queues := make(map[string]int)
for qname, p := range cfg.Queues {
if p > 0 {
queues[qname] = p
}
}
if len(queues) == 0 {
queues = defaultQueueConfig
}
shutdownTimeout := cfg.ShutdownTimeout
if shutdownTimeout == 0 {
shutdownTimeout = defaultShutdownTimeout
}
logger := log.NewLogger(cfg.Logger)
loglevel := cfg.LogLevel
if loglevel == level_unspecified {
loglevel = InfoLevel
}
logger.SetLevel(toInternalLogLevel(loglevel))
host, err := os.Hostname()
if err != nil {
host = "unknown-host"
}
pid := os.Getpid()
rdb := rdb.NewRDB(createRedisClient(r))
ss := base.NewServerState(host, pid, n, queues, cfg.StrictPriority)
syncCh := make(chan *syncRequest)
cancels := base.NewCancelations()
syncer := newSyncer(logger, syncCh, 5*time.Second)
heartbeater := newHeartbeater(logger, rdb, ss, 5*time.Second)
scheduler := newScheduler(logger, rdb, 5*time.Second, queues)
subscriber := newSubscriber(logger, rdb, cancels)
processor := newProcessor(newProcessorParams{
logger: logger,
broker: rdb,
ss: ss,
retryDelayFunc: delayFunc,
syncCh: syncCh,
cancelations: cancels,
errHandler: cfg.ErrorHandler,
shutdownTimeout: shutdownTimeout,
})
return &Server{
ss: ss,
logger: logger,
broker: rdb,
scheduler: scheduler,
processor: processor,
syncer: syncer,
heartbeater: heartbeater,
subscriber: subscriber,
}
}
// A Handler processes tasks.
//
// ProcessTask should return nil if the processing of a task
// is successful.
//
// If ProcessTask return a non-nil error or panics, the task
// will be retried after delay.
type Handler interface {
ProcessTask(context.Context, *Task) error
}
// The HandlerFunc type is an adapter to allow the use of
// ordinary functions as a Handler. If f is a function
// with the appropriate signature, HandlerFunc(f) is a
// Handler that calls f.
type HandlerFunc func(context.Context, *Task) error
// ProcessTask calls fn(ctx, task)
func (fn HandlerFunc) ProcessTask(ctx context.Context, task *Task) error {
return fn(ctx, task)
}
// ErrServerStopped indicates that the operation is now illegal because of the server being stopped.
var ErrServerStopped = errors.New("asynq: the server has been stopped")
// Run starts the background-task processing and blocks until
// an os signal to exit the program is received. Once it receives
// a signal, it gracefully shuts down all active workers and other
// goroutines to process the tasks.
//
// Run returns any error encountered during server startup time.
// If the server has already been stopped, ErrServerStopped is returned.
func (srv *Server) Run(handler Handler) error {
if err := srv.Start(handler); err != nil {
return err
}
srv.waitForSignals()
srv.Stop()
return nil
}
// Start starts the worker server. Once the server has started,
// it pulls tasks off queues and starts a worker goroutine for each task.
// Tasks are processed concurrently by the workers up to the number of
// concurrency specified at the initialization time.
//
// Start returns any error encountered during server startup time.
// If the server has already been stopped, ErrServerStopped is returned.
func (srv *Server) Start(handler Handler) error {
if handler == nil {
return fmt.Errorf("asynq: server cannot run with nil handler")
}
switch srv.ss.Status() {
case base.StatusRunning:
return fmt.Errorf("asynq: the server is already running")
case base.StatusStopped:
return ErrServerStopped
}
srv.ss.SetStatus(base.StatusRunning)
srv.processor.handler = handler
srv.logger.Info("Starting processing")
srv.heartbeater.start(&srv.wg)
srv.subscriber.start(&srv.wg)
srv.syncer.start(&srv.wg)
srv.scheduler.start(&srv.wg)
srv.processor.start(&srv.wg)
return nil
}
// Stop stops the worker server.
// It gracefully closes all active workers. The server will wait for
// active workers to finish processing tasks for duration specified in Config.ShutdownTimeout.
// If worker didn't finish processing a task during the timeout, the task will be pushed back to Redis.
func (srv *Server) Stop() {
switch srv.ss.Status() {
case base.StatusIdle, base.StatusStopped:
// server is not running, do nothing and return.
return
}
srv.logger.Info("Starting graceful shutdown")
// Note: The order of termination is important.
// Sender goroutines should be terminated before the receiver goroutines.
// processor -> syncer (via syncCh)
srv.scheduler.terminate()
srv.processor.terminate()
srv.syncer.terminate()
srv.subscriber.terminate()
srv.heartbeater.terminate()
srv.wg.Wait()
srv.broker.Close()
srv.ss.SetStatus(base.StatusStopped)
srv.logger.Info("Exiting")
}
// Quiet signals the server to stop pulling new tasks off queues.
// Quiet should be used before stopping the server.
func (srv *Server) Quiet() {
srv.processor.stop()
srv.ss.SetStatus(base.StatusQuiet)
}