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asynq/internal/rdb/inspect.go

892 lines
24 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 rdb
import (
"encoding/json"
"fmt"
"sort"
"strings"
"time"
"github.com/go-redis/redis/v7"
"github.com/google/uuid"
"github.com/hibiken/asynq/internal/base"
"github.com/spf13/cast"
)
// Stats represents a state of queues at a certain time.
type Stats struct {
Enqueued int
InProgress int
Scheduled int
Retry int
Dead int
Processed int
Failed int
Queues []*Queue
Timestamp time.Time
}
// Queue represents a task queue.
type Queue struct {
// Name of the queue (e.g. "default", "critical").
// Note: It doesn't include the prefix "asynq:queues:".
Name string
// Paused indicates whether the queue is paused.
// If true, tasks in the queue should not be processed.
Paused bool
// Size is the number of tasks in the queue.
Size int
}
// DailyStats holds aggregate data for a given day.
type DailyStats struct {
Processed int
Failed int
Time time.Time
}
// EnqueuedTask is a task in a queue and is ready to be processed.
type EnqueuedTask struct {
ID uuid.UUID
Type string
Payload map[string]interface{}
Queue string
}
// InProgressTask is a task that's currently being processed.
type InProgressTask struct {
ID uuid.UUID
Type string
Payload map[string]interface{}
}
// ScheduledTask is a task that's scheduled to be processed in the future.
type ScheduledTask struct {
ID uuid.UUID
Type string
Payload map[string]interface{}
ProcessAt time.Time
Score int64
Queue string
}
// RetryTask is a task that's in retry queue because worker failed to process the task.
type RetryTask struct {
ID uuid.UUID
Type string
Payload map[string]interface{}
// TODO(hibiken): add LastFailedAt time.Time
ProcessAt time.Time
ErrorMsg string
Retried int
Retry int
Score int64
Queue string
}
// DeadTask is a task in that has exhausted all retries.
type DeadTask struct {
ID uuid.UUID
Type string
Payload map[string]interface{}
LastFailedAt time.Time
ErrorMsg string
Score int64
Queue string
}
// KEYS[1] -> asynq:queues
// KEYS[2] -> asynq:in_progress
// KEYS[3] -> asynq:scheduled
// KEYS[4] -> asynq:retry
// KEYS[5] -> asynq:dead
// KEYS[6] -> asynq:processed:<yyyy-mm-dd>
// KEYS[7] -> asynq:failure:<yyyy-mm-dd>
var currentStatsCmd = redis.NewScript(`
local res = {}
local queues = redis.call("SMEMBERS", KEYS[1])
for _, qkey in ipairs(queues) do
table.insert(res, qkey)
table.insert(res, redis.call("LLEN", qkey))
end
table.insert(res, KEYS[2])
table.insert(res, redis.call("LLEN", KEYS[2]))
table.insert(res, KEYS[3])
table.insert(res, redis.call("ZCARD", KEYS[3]))
table.insert(res, KEYS[4])
table.insert(res, redis.call("ZCARD", KEYS[4]))
table.insert(res, KEYS[5])
table.insert(res, redis.call("ZCARD", KEYS[5]))
local pcount = 0
local p = redis.call("GET", KEYS[6])
if p then
pcount = tonumber(p)
end
table.insert(res, "processed")
table.insert(res, pcount)
local fcount = 0
local f = redis.call("GET", KEYS[7])
if f then
fcount = tonumber(f)
end
table.insert(res, "failed")
table.insert(res, fcount)
return res`)
// CurrentStats returns a current state of the queues.
func (r *RDB) CurrentStats() (*Stats, error) {
now := time.Now()
res, err := currentStatsCmd.Run(r.client, []string{
base.AllQueues,
base.InProgressQueue,
base.ScheduledQueue,
base.RetryQueue,
base.DeadQueue,
base.ProcessedKey(now),
base.FailureKey(now),
}).Result()
if err != nil {
return nil, err
}
data, err := cast.ToSliceE(res)
if err != nil {
return nil, err
}
paused, err := r.client.SMembersMap(base.PausedQueues).Result()
if err != nil {
return nil, err
}
stats := &Stats{
Queues: make([]*Queue, 0),
Timestamp: now,
}
for i := 0; i < len(data); i += 2 {
key := cast.ToString(data[i])
val := cast.ToInt(data[i+1])
switch {
case strings.HasPrefix(key, base.QueuePrefix):
stats.Enqueued += val
q := Queue{
Name: strings.TrimPrefix(key, base.QueuePrefix),
Size: val,
}
if _, exist := paused[key]; exist {
q.Paused = true
}
stats.Queues = append(stats.Queues, &q)
case key == base.InProgressQueue:
stats.InProgress = val
case key == base.ScheduledQueue:
stats.Scheduled = val
case key == base.RetryQueue:
stats.Retry = val
case key == base.DeadQueue:
stats.Dead = val
case key == "processed":
stats.Processed = val
case key == "failed":
stats.Failed = val
}
}
sort.Slice(stats.Queues, func(i, j int) bool {
return stats.Queues[i].Name < stats.Queues[j].Name
})
return stats, nil
}
var historicalStatsCmd = redis.NewScript(`
local res = {}
for _, key in ipairs(KEYS) do
local n = redis.call("GET", key)
if not n then
n = 0
end
table.insert(res, tonumber(n))
end
return res`)
// HistoricalStats returns a list of stats from the last n days.
func (r *RDB) HistoricalStats(n int) ([]*DailyStats, error) {
if n < 1 {
return []*DailyStats{}, nil
}
const day = 24 * time.Hour
now := time.Now().UTC()
var days []time.Time
var keys []string
for i := 0; i < n; i++ {
ts := now.Add(-time.Duration(i) * day)
days = append(days, ts)
keys = append(keys, base.ProcessedKey(ts))
keys = append(keys, base.FailureKey(ts))
}
res, err := historicalStatsCmd.Run(r.client, keys, len(keys)).Result()
if err != nil {
return nil, err
}
data, err := cast.ToIntSliceE(res)
if err != nil {
return nil, err
}
var stats []*DailyStats
for i := 0; i < len(data); i += 2 {
stats = append(stats, &DailyStats{
Processed: data[i],
Failed: data[i+1],
Time: days[i/2],
})
}
return stats, nil
}
// RedisInfo returns a map of redis info.
func (r *RDB) RedisInfo() (map[string]string, error) {
res, err := r.client.Info().Result()
if err != nil {
return nil, err
}
info := make(map[string]string)
lines := strings.Split(res, "\r\n")
for _, l := range lines {
kv := strings.Split(l, ":")
if len(kv) == 2 {
info[kv[0]] = kv[1]
}
}
return info, nil
}
func reverse(x []string) {
for i := len(x)/2 - 1; i >= 0; i-- {
opp := len(x) - 1 - i
x[i], x[opp] = x[opp], x[i]
}
}
// Pagination specifies the page size and page number
// for the list operation.
type Pagination struct {
// Number of items in the page.
Size int
// Page number starting from zero.
Page int
}
func (p Pagination) start() int64 {
return int64(p.Size * p.Page)
}
func (p Pagination) stop() int64 {
return int64(p.Size*p.Page + p.Size - 1)
}
// ListEnqueued returns enqueued tasks that are ready to be processed.
func (r *RDB) ListEnqueued(qname string, pgn Pagination) ([]*EnqueuedTask, error) {
qkey := base.QueueKey(qname)
if !r.client.SIsMember(base.AllQueues, qkey).Val() {
return nil, fmt.Errorf("queue %q does not exist", qname)
}
// Note: Because we use LPUSH to redis list, we need to calculate the
// correct range and reverse the list to get the tasks with pagination.
stop := -pgn.start() - 1
start := -pgn.stop() - 1
data, err := r.client.LRange(qkey, start, stop).Result()
if err != nil {
return nil, err
}
reverse(data)
var tasks []*EnqueuedTask
for _, s := range data {
var msg base.TaskMessage
err := json.Unmarshal([]byte(s), &msg)
if err != nil {
continue // bad data, ignore and continue
}
tasks = append(tasks, &EnqueuedTask{
ID: msg.ID,
Type: msg.Type,
Payload: msg.Payload,
Queue: msg.Queue,
})
}
return tasks, nil
}
// ListInProgress returns all tasks that are currently being processed.
func (r *RDB) ListInProgress(pgn Pagination) ([]*InProgressTask, error) {
// Note: Because we use LPUSH to redis list, we need to calculate the
// correct range and reverse the list to get the tasks with pagination.
stop := -pgn.start() - 1
start := -pgn.stop() - 1
data, err := r.client.LRange(base.InProgressQueue, start, stop).Result()
if err != nil {
return nil, err
}
reverse(data)
var tasks []*InProgressTask
for _, s := range data {
var msg base.TaskMessage
err := json.Unmarshal([]byte(s), &msg)
if err != nil {
continue // bad data, ignore and continue
}
tasks = append(tasks, &InProgressTask{
ID: msg.ID,
Type: msg.Type,
Payload: msg.Payload,
})
}
return tasks, nil
}
// ListScheduled returns all tasks that are scheduled to be processed
// in the future.
func (r *RDB) ListScheduled(pgn Pagination) ([]*ScheduledTask, error) {
data, err := r.client.ZRangeWithScores(base.ScheduledQueue, pgn.start(), pgn.stop()).Result()
if err != nil {
return nil, err
}
var tasks []*ScheduledTask
for _, z := range data {
s, ok := z.Member.(string)
if !ok {
continue // bad data, ignore and continue
}
var msg base.TaskMessage
err := json.Unmarshal([]byte(s), &msg)
if err != nil {
continue // bad data, ignore and continue
}
processAt := time.Unix(int64(z.Score), 0)
tasks = append(tasks, &ScheduledTask{
ID: msg.ID,
Type: msg.Type,
Payload: msg.Payload,
Queue: msg.Queue,
ProcessAt: processAt,
Score: int64(z.Score),
})
}
return tasks, nil
}
// ListRetry returns all tasks that have failed before and willl be retried
// in the future.
func (r *RDB) ListRetry(pgn Pagination) ([]*RetryTask, error) {
data, err := r.client.ZRangeWithScores(base.RetryQueue, pgn.start(), pgn.stop()).Result()
if err != nil {
return nil, err
}
var tasks []*RetryTask
for _, z := range data {
s, ok := z.Member.(string)
if !ok {
continue // bad data, ignore and continue
}
var msg base.TaskMessage
err := json.Unmarshal([]byte(s), &msg)
if err != nil {
continue // bad data, ignore and continue
}
processAt := time.Unix(int64(z.Score), 0)
tasks = append(tasks, &RetryTask{
ID: msg.ID,
Type: msg.Type,
Payload: msg.Payload,
ErrorMsg: msg.ErrorMsg,
Retry: msg.Retry,
Retried: msg.Retried,
Queue: msg.Queue,
ProcessAt: processAt,
Score: int64(z.Score),
})
}
return tasks, nil
}
// ListDead returns all tasks that have exhausted its retry limit.
func (r *RDB) ListDead(pgn Pagination) ([]*DeadTask, error) {
data, err := r.client.ZRangeWithScores(base.DeadQueue, pgn.start(), pgn.stop()).Result()
if err != nil {
return nil, err
}
var tasks []*DeadTask
for _, z := range data {
s, ok := z.Member.(string)
if !ok {
continue // bad data, ignore and continue
}
var msg base.TaskMessage
err := json.Unmarshal([]byte(s), &msg)
if err != nil {
continue // bad data, ignore and continue
}
lastFailedAt := time.Unix(int64(z.Score), 0)
tasks = append(tasks, &DeadTask{
ID: msg.ID,
Type: msg.Type,
Payload: msg.Payload,
ErrorMsg: msg.ErrorMsg,
Queue: msg.Queue,
LastFailedAt: lastFailedAt,
Score: int64(z.Score),
})
}
return tasks, nil
}
// EnqueueDeadTask finds a task that matches the given id and score from dead queue
// and enqueues it for processing. If a task that matches the id and score
// does not exist, it returns ErrTaskNotFound.
func (r *RDB) EnqueueDeadTask(id uuid.UUID, score int64) error {
n, err := r.removeAndEnqueue(base.DeadQueue, id.String(), float64(score))
if err != nil {
return err
}
if n == 0 {
return ErrTaskNotFound
}
return nil
}
// EnqueueRetryTask finds a task that matches the given id and score from retry queue
// and enqueues it for processing. If a task that matches the id and score
// does not exist, it returns ErrTaskNotFound.
func (r *RDB) EnqueueRetryTask(id uuid.UUID, score int64) error {
n, err := r.removeAndEnqueue(base.RetryQueue, id.String(), float64(score))
if err != nil {
return err
}
if n == 0 {
return ErrTaskNotFound
}
return nil
}
// EnqueueScheduledTask finds a task that matches the given id and score from scheduled queue
// and enqueues it for processing. If a task that matches the id and score does not
// exist, it returns ErrTaskNotFound.
func (r *RDB) EnqueueScheduledTask(id uuid.UUID, score int64) error {
n, err := r.removeAndEnqueue(base.ScheduledQueue, id.String(), float64(score))
if err != nil {
return err
}
if n == 0 {
return ErrTaskNotFound
}
return nil
}
// EnqueueAllScheduledTasks enqueues all tasks from scheduled queue
// and returns the number of tasks enqueued.
func (r *RDB) EnqueueAllScheduledTasks() (int64, error) {
return r.removeAndEnqueueAll(base.ScheduledQueue)
}
// EnqueueAllRetryTasks enqueues all tasks from retry queue
// and returns the number of tasks enqueued.
func (r *RDB) EnqueueAllRetryTasks() (int64, error) {
return r.removeAndEnqueueAll(base.RetryQueue)
}
// EnqueueAllDeadTasks enqueues all tasks from dead queue
// and returns the number of tasks enqueued.
func (r *RDB) EnqueueAllDeadTasks() (int64, error) {
return r.removeAndEnqueueAll(base.DeadQueue)
}
var removeAndEnqueueCmd = redis.NewScript(`
local msgs = redis.call("ZRANGEBYSCORE", KEYS[1], ARGV[1], ARGV[1])
for _, msg in ipairs(msgs) do
local decoded = cjson.decode(msg)
if decoded["ID"] == ARGV[2] then
local qkey = ARGV[3] .. decoded["Queue"]
redis.call("LPUSH", qkey, msg)
redis.call("ZREM", KEYS[1], msg)
return 1
end
end
return 0`)
func (r *RDB) removeAndEnqueue(zset, id string, score float64) (int64, error) {
res, err := removeAndEnqueueCmd.Run(r.client, []string{zset}, score, id, base.QueuePrefix).Result()
if err != nil {
return 0, err
}
n, ok := res.(int64)
if !ok {
return 0, fmt.Errorf("could not cast %v to int64", res)
}
return n, nil
}
var removeAndEnqueueAllCmd = redis.NewScript(`
local msgs = redis.call("ZRANGE", KEYS[1], 0, -1)
for _, msg in ipairs(msgs) do
local decoded = cjson.decode(msg)
local qkey = ARGV[1] .. decoded["Queue"]
redis.call("LPUSH", qkey, msg)
redis.call("ZREM", KEYS[1], msg)
end
return table.getn(msgs)`)
func (r *RDB) removeAndEnqueueAll(zset string) (int64, error) {
res, err := removeAndEnqueueAllCmd.Run(r.client, []string{zset}, base.QueuePrefix).Result()
if err != nil {
return 0, err
}
n, ok := res.(int64)
if !ok {
return 0, fmt.Errorf("could not cast %v to int64", res)
}
return n, nil
}
// KillRetryTask finds a task that matches the given id and score from retry queue
// and moves it to dead queue. If a task that maches the id and score does not exist,
// it returns ErrTaskNotFound.
func (r *RDB) KillRetryTask(id uuid.UUID, score int64) error {
n, err := r.removeAndKill(base.RetryQueue, id.String(), float64(score))
if err != nil {
return err
}
if n == 0 {
return ErrTaskNotFound
}
return nil
}
// KillScheduledTask finds a task that matches the given id and score from scheduled queue
// and moves it to dead queue. If a task that maches the id and score does not exist,
// it returns ErrTaskNotFound.
func (r *RDB) KillScheduledTask(id uuid.UUID, score int64) error {
n, err := r.removeAndKill(base.ScheduledQueue, id.String(), float64(score))
if err != nil {
return err
}
if n == 0 {
return ErrTaskNotFound
}
return nil
}
// KillAllRetryTasks moves all tasks from retry queue to dead queue and
// returns the number of tasks that were moved.
func (r *RDB) KillAllRetryTasks() (int64, error) {
return r.removeAndKillAll(base.RetryQueue)
}
// KillAllScheduledTasks moves all tasks from scheduled queue to dead queue and
// returns the number of tasks that were moved.
func (r *RDB) KillAllScheduledTasks() (int64, error) {
return r.removeAndKillAll(base.ScheduledQueue)
}
// KEYS[1] -> ZSET to move task from (e.g., retry queue)
// KEYS[2] -> asynq:dead
// ARGV[1] -> score of the task to kill
// ARGV[2] -> id of the task to kill
// ARGV[3] -> current timestamp
// ARGV[4] -> cutoff timestamp (e.g., 90 days ago)
// ARGV[5] -> max number of tasks in dead queue (e.g., 100)
var removeAndKillCmd = redis.NewScript(`
local msgs = redis.call("ZRANGEBYSCORE", KEYS[1], ARGV[1], ARGV[1])
for _, msg in ipairs(msgs) do
local decoded = cjson.decode(msg)
if decoded["ID"] == ARGV[2] then
redis.call("ZREM", KEYS[1], msg)
redis.call("ZADD", KEYS[2], ARGV[3], msg)
redis.call("ZREMRANGEBYSCORE", KEYS[2], "-inf", ARGV[4])
redis.call("ZREMRANGEBYRANK", KEYS[2], 0, -ARGV[5])
return 1
end
end
return 0`)
func (r *RDB) removeAndKill(zset, id string, score float64) (int64, error) {
now := time.Now()
limit := now.AddDate(0, 0, -deadExpirationInDays).Unix() // 90 days ago
res, err := removeAndKillCmd.Run(r.client,
[]string{zset, base.DeadQueue},
score, id, now.Unix(), limit, maxDeadTasks).Result()
if err != nil {
return 0, err
}
n, ok := res.(int64)
if !ok {
return 0, fmt.Errorf("could not cast %v to int64", res)
}
return n, nil
}
// KEYS[1] -> ZSET to move task from (e.g., retry queue)
// KEYS[2] -> asynq:dead
// ARGV[1] -> current timestamp
// ARGV[2] -> cutoff timestamp (e.g., 90 days ago)
// ARGV[3] -> max number of tasks in dead queue (e.g., 100)
var removeAndKillAllCmd = redis.NewScript(`
local msgs = redis.call("ZRANGE", KEYS[1], 0, -1)
for _, msg in ipairs(msgs) do
redis.call("ZADD", KEYS[2], ARGV[1], msg)
redis.call("ZREM", KEYS[1], msg)
redis.call("ZREMRANGEBYSCORE", KEYS[2], "-inf", ARGV[2])
redis.call("ZREMRANGEBYRANK", KEYS[2], 0, -ARGV[3])
end
return table.getn(msgs)`)
func (r *RDB) removeAndKillAll(zset string) (int64, error) {
now := time.Now()
limit := now.AddDate(0, 0, -deadExpirationInDays).Unix() // 90 days ago
res, err := removeAndKillAllCmd.Run(r.client, []string{zset, base.DeadQueue},
now.Unix(), limit, maxDeadTasks).Result()
if err != nil {
return 0, err
}
n, ok := res.(int64)
if !ok {
return 0, fmt.Errorf("could not cast %v to int64", res)
}
return n, nil
}
// DeleteDeadTask finds a task that matches the given id and score from dead queue
// and deletes it. If a task that matches the id and score does not exist,
// it returns ErrTaskNotFound.
func (r *RDB) DeleteDeadTask(id uuid.UUID, score int64) error {
return r.deleteTask(base.DeadQueue, id.String(), float64(score))
}
// DeleteRetryTask finds a task that matches the given id and score from retry queue
// and deletes it. If a task that matches the id and score does not exist,
// it returns ErrTaskNotFound.
func (r *RDB) DeleteRetryTask(id uuid.UUID, score int64) error {
return r.deleteTask(base.RetryQueue, id.String(), float64(score))
}
// DeleteScheduledTask finds a task that matches the given id and score from
// scheduled queue and deletes it. If a task that matches the id and score
//does not exist, it returns ErrTaskNotFound.
func (r *RDB) DeleteScheduledTask(id uuid.UUID, score int64) error {
return r.deleteTask(base.ScheduledQueue, id.String(), float64(score))
}
var deleteTaskCmd = redis.NewScript(`
local msgs = redis.call("ZRANGEBYSCORE", KEYS[1], ARGV[1], ARGV[1])
for _, msg in ipairs(msgs) do
local decoded = cjson.decode(msg)
if decoded["ID"] == ARGV[2] then
redis.call("ZREM", KEYS[1], msg)
return 1
end
end
return 0`)
func (r *RDB) deleteTask(zset, id string, score float64) error {
res, err := deleteTaskCmd.Run(r.client, []string{zset}, score, id).Result()
if err != nil {
return err
}
n, ok := res.(int64)
if !ok {
return fmt.Errorf("could not cast %v to int64", res)
}
if n == 0 {
return ErrTaskNotFound
}
return nil
}
// DeleteAllDeadTasks deletes all tasks from the dead queue.
func (r *RDB) DeleteAllDeadTasks() error {
return r.client.Del(base.DeadQueue).Err()
}
// DeleteAllRetryTasks deletes all tasks from the dead queue.
func (r *RDB) DeleteAllRetryTasks() error {
return r.client.Del(base.RetryQueue).Err()
}
// DeleteAllScheduledTasks deletes all tasks from the dead queue.
func (r *RDB) DeleteAllScheduledTasks() error {
return r.client.Del(base.ScheduledQueue).Err()
}
// ErrQueueNotFound indicates specified queue does not exist.
type ErrQueueNotFound struct {
qname string
}
func (e *ErrQueueNotFound) Error() string {
return fmt.Sprintf("queue %q does not exist", e.qname)
}
// ErrQueueNotEmpty indicates specified queue is not empty.
type ErrQueueNotEmpty struct {
qname string
}
func (e *ErrQueueNotEmpty) Error() string {
return fmt.Sprintf("queue %q is not empty", e.qname)
}
// Skip checking whether queue is empty before removing.
var removeQueueForceCmd = redis.NewScript(`
local n = redis.call("SREM", KEYS[1], KEYS[2])
if n == 0 then
return redis.error_reply("LIST NOT FOUND")
end
redis.call("DEL", KEYS[2])
return redis.status_reply("OK")`)
// Checks whether queue is empty before removing.
var removeQueueCmd = redis.NewScript(`
local l = redis.call("LLEN", KEYS[2]) if l > 0 then
return redis.error_reply("LIST NOT EMPTY")
end
local n = redis.call("SREM", KEYS[1], KEYS[2])
if n == 0 then
return redis.error_reply("LIST NOT FOUND")
end
redis.call("DEL", KEYS[2])
return redis.status_reply("OK")`)
// RemoveQueue removes the specified queue.
//
// If force is set to true, it will remove the queue regardless
// of whether the queue is empty.
// If force is set to false, it will only remove the queue if
// it is empty.
func (r *RDB) RemoveQueue(qname string, force bool) error {
var script *redis.Script
if force {
script = removeQueueForceCmd
} else {
script = removeQueueCmd
}
err := script.Run(r.client,
[]string{base.AllQueues, base.QueueKey(qname)},
force).Err()
if err != nil {
switch err.Error() {
case "LIST NOT FOUND":
return &ErrQueueNotFound{qname}
case "LIST NOT EMPTY":
return &ErrQueueNotEmpty{qname}
default:
return err
}
}
return nil
}
// Note: Script also removes stale keys.
var listServersCmd = redis.NewScript(`
local res = {}
local now = tonumber(ARGV[1])
local keys = redis.call("ZRANGEBYSCORE", KEYS[1], now, "+inf")
for _, key in ipairs(keys) do
local s = redis.call("GET", key)
if s then
table.insert(res, s)
end
end
redis.call("ZREMRANGEBYSCORE", KEYS[1], "-inf", now-1)
return res`)
// ListServers returns the list of server info.
func (r *RDB) ListServers() ([]*base.ServerInfo, error) {
res, err := listServersCmd.Run(r.client,
[]string{base.AllServers}, time.Now().UTC().Unix()).Result()
if err != nil {
return nil, err
}
data, err := cast.ToStringSliceE(res)
if err != nil {
return nil, err
}
var servers []*base.ServerInfo
for _, s := range data {
var info base.ServerInfo
err := json.Unmarshal([]byte(s), &info)
if err != nil {
continue // skip bad data
}
servers = append(servers, &info)
}
return servers, nil
}
// Note: Script also removes stale keys.
var listWorkersCmd = redis.NewScript(`
local res = {}
local now = tonumber(ARGV[1])
local keys = redis.call("ZRANGEBYSCORE", KEYS[1], now, "+inf")
for _, key in ipairs(keys) do
local workers = redis.call("HVALS", key)
for _, w in ipairs(workers) do
table.insert(res, w)
end
end
redis.call("ZREMRANGEBYSCORE", KEYS[1], "-inf", now-1)
return res`)
// ListWorkers returns the list of worker stats.
func (r *RDB) ListWorkers() ([]*base.WorkerInfo, error) {
res, err := listWorkersCmd.Run(r.client, []string{base.AllWorkers}, time.Now().UTC().Unix()).Result()
if err != nil {
return nil, err
}
data, err := cast.ToStringSliceE(res)
if err != nil {
return nil, err
}
var workers []*base.WorkerInfo
for _, s := range data {
var w base.WorkerInfo
err := json.Unmarshal([]byte(s), &w)
if err != nil {
continue // skip bad data
}
workers = append(workers, &w)
}
return workers, nil
}
// KEYS[1] -> asynq:paused
// ARGV[1] -> asynq:queues:<qname> - queue to pause
var pauseCmd = redis.NewScript(`
local ismem = redis.call("SISMEMBER", KEYS[1], ARGV[1])
if ismem == 1 then
return redis.error_reply("queue is already paused")
end
return redis.call("SADD", KEYS[1], ARGV[1])`)
// Pause pauses processing of tasks from the given queue.
func (r *RDB) Pause(qname string) error {
qkey := base.QueueKey(qname)
return pauseCmd.Run(r.client, []string{base.PausedQueues}, qkey).Err()
}
// KEYS[1] -> asynq:paused
// ARGV[1] -> asynq:queues:<qname> - queue to unpause
var unpauseCmd = redis.NewScript(`
local ismem = redis.call("SISMEMBER", KEYS[1], ARGV[1])
if ismem == 0 then
return redis.error_reply("queue is not paused")
end
return redis.call("SREM", KEYS[1], ARGV[1])`)
// Unpause resumes processing of tasks from the given queue.
func (r *RDB) Unpause(qname string) error {
qkey := base.QueueKey(qname)
return unpauseCmd.Run(r.client, []string{base.PausedQueues}, qkey).Err()
}