reqless
This is a fork of seomoz/qless-py that
includes significant type improvements and support for throttles.
qless
is a powerful Redis
-based job queueing system inspired by
resque, but built on a collection
of Lua scripts, maintained in the
qless-core repo.
Philosophy and Nomenclature
A job
is a unit of work identified by a job id or jid
. A queue
can
contain several jobs that are scheduled to be run at a certain time, several
jobs that are waiting to run, and jobs that are currently running. A worker
is a process on a host, identified uniquely, that asks for jobs from the
queue, performs some process associated with that job, and then marks it as
complete. When it's completed, it can be put into another queue.
Jobs can only be in one queue at a time. That queue is whatever queue they
were last put in. So if a worker is working on a job, and you move it, the
worker's request to complete the job will be ignored.
A job can be canceled
, which means it disappears into the ether, and we'll
never pay it any mind every again. A job can be dropped
, which is when a
worker fails to heartbeat or complete the job in a timely fashion, or a job
can be failed
, which is when a host recognizes some systematically
problematic state about the job. A worker should only fail a job if the error
is likely not a transient one; otherwise, that worker should just drop it and
let the system reclaim it.
Features
- Jobs don't get dropped on the floor -- Sometimes workers drop jobs.
qless
automatically picks them back up and gives them to another worker - Tagging / Tracking -- Some jobs are more interesting than others. Track
those jobs to get updates on their progress. Tag jobs with meaningful
identifiers to find them quickly in the UI.
- Job Dependencies -- One job might need to wait for another job to
complete
- Stats --
qless
automatically keeps statistics about how long jobs wait
to be processed and how long they take to be processed. Currently, we keep
track of the count, mean, standard deviation, and a histogram of these
times. - Job data is stored temporarily -- Job info sticks around for a
configurable amount of time so you can still look back on a job's history,
data, etc.
- Priority -- Jobs with the same priority get popped in the order they
were inserted; a higher priority means that it gets popped faster
- Retry logic -- Every job has a number of retries associated with it,
which are renewed when it is put into a new queue or completed. If a job
is repeatedly dropped, then it is presumed to be problematic, and is
automatically failed.
- Web App -- With the advent of a Ruby client, there is a Sinatra-based
web app that gives you control over certain operational issues
- Scheduled Work -- Until a job waits for a specified delay (defaults to
0), jobs cannot be popped by workers
- Recurring Jobs -- Scheduling's all well and good, but we also support
jobs that need to recur periodically.
- Notifications -- Tracked jobs emit events on pubsub channels as they get
completed, failed, put, popped, etc. Use these events to get notified of
progress on jobs you're interested in.
Interest piqued? Then read on!
Installation
Install from pip:
pip install reqless
Alternatively, install reqless-py from source by checking it out from github,
and checking out the qless-core submodule:
git clone git://github.com/tdg5/reqless-py.git
cd reqless-py
git submodule init
git submodule update
pip install .
Business Time!
You've read this far -- you probably want to write some code now and turn them
into jobs. Jobs are described essentially by two pieces of information -- a
class
and data
. The class should have static methods that know how to
process this type of job depending on the queue it's in. For those thrown for
a loop by this example, it's in reference to a
South Park
episode where a group of enterprising gnomes set on world domination through
three steps: 1) collect underpants, 2) ? 3) profit!
class GnomesJob:
@staticmethod
def underpants(job):
...
job.complete("unknown")
@staticmethod
def unknown(job):
...
job.complete("profit")
@staticmethod
def profit(job):
...
job.complete()
This makes it easy to describe how a GnomesJob
might move through a pipeline,
first in the "underpants" step, then "unknown", and lastly "profit."
Alternatively, you can define a single method process
that knows how to
complete the job, no matter what queue it was popped from. The above is just
meant as a convenience for pipelines:
class GnomesJob:
@staticmethod
def process(job):
if job.queue == "underpants":
...
job.complete("underpants")
elif job.queue == "unknown":
...
job.complete("profit")
elif job.queue == "profit":
...
job.complete()
else:
job.fail("unknown-stage", "What what?")
Jobs have user data associated with them that can be modified as it goes
through a pipeline. In general, user data is accessible through job.data
. It
is generally handled as a JSON string so that each job class may parse and
handle the user data in whatever way is appropriate for that job class. For
example, you might update the data like so...
@staticmethod
def underpants(job):
data = json.loads(job.data)
data["collected"] = ...
job.data = json.dumps(job.data)
@staticmethod
def unknown(job):
data = json.loads(job.data)
if data["collected"] ...:
...
Great! With all this in place, let's put them in the queue so that they can
get run
import reqless
client = reqless.Client()
client = reqless.Client("redis://foo.bar.com:1234")
Now, reference a queue, and start putting your gnomes to work:
queue = client.queues["underpants"]
import gnomes
for i in range(1000):
queue.put(gnomes.GnomesJob, "{"})
Alternatively, if the job class is not importable from where you're adding
jobs, you can use the full path of the job class as a string:
...
for i in range(1000):
queue.put("gnomes.GnomesJob", {})
By way of a quick note, it's important that your job class can be imported
-- you can't create a job class in an interactive prompt, for example. You can
add jobs in an interactive prompt, but just can't define new job types.
Running
All that remains is to have workers actually run these jobs. This distribution
comes with a script to help with this:
reqless-py-worker -q underpants -q unknown -q profit
This script actually forks off several subprocesses that perform the work, and
the original process keeps tabs on them to ensure that they are all up and
running. In the future, the parent process might also perform other sanity
checks, but for the time being, it's just that the process is still alive. You
can specify the host
and port
you want to use for the qless server as well:
reqless-py-worker --host foo.bar --port 1234 ...
In the absence of the --workers
argument, reqless-py-worker
will spawn as
many workers as there are cores on the machine. The interval specifies how
often to poll in seconds) for work items. Future versions may have a mechanism
to support blocking pop.
reqless-py-worker --workers 4 --interval 10
Because this works on a forked process model, it can be convenient to import
large modules before subprocesses are forked. Specify these with --import
:
reqless-py-worker --import my.really.bigModule
Filesystem
Each child process runs in its own sandboxed directory and each job is given a
sandbox
attribute which is the name of a directory for the sole use of that
job. It's guaranteed to be clean by the time the job is performed, and it
cleaned up afterwards.
For example, if you invoke:
reqless-py-worker --workers 4 --greenlets 5 --workdir foo
Then four child processes will be spawned using the directories:
foo/reqless-py-workers/sandbox-{0,1,2,3}
The jobs run by the greenlets in the first process are given their own sandboxes
of the form:
foo/reqless-py-workers/sandbox-0/greenlet-{0,1,2,3,4}
Gevent
Some jobs are I/O-bound, and might want to, say, make use of a greenlet pool.
If you have a class where you've, say, monkey-patched socket
, you can ask
reqless to create a pool of greenlets to run you job inside each process. To run
5 processes with 50 greenlets each:
reqless-py-worker --workers 5 --greenlets 50
Signals
With a worker running, you can send signals to child processes to:
USR1
- Get the current stack trace in that workerUSR2
- Enter a debugger in that worker
So, for example, if one of the worker child processes is PID 1234
, then you
can invoke kill -USR1 1234
to get the backtrace in the logs (and console
output).
Resuming Jobs
This is an experimental feature, but you can start workers --resume
flag
to have the worker begin its processing with the jobs it left off with. For
instance, during deployments, it's common to restart the worker processes, and
the --resume
flag has the worker first perform a check with qless
server to
see which jobs it had last been running (and still has locks for).
This flag should be used with some caution. In particular, if two workers are
running with the same worker name, then this should not be used. The reason is
that through the qless
interface, it's impossible to differentiate the two,
and currently-running jobs may be confused with jobs that were simply dropped
when the worker was stopped.
Debugging / Developing
Whenever a job is processed, it checks to see if the file in which your job is
defined has been updated since its last import. If it has, it automatically
reimports it. We think of this as a feature.
With this in mind, when I start a new project and want to make use of
reqless
, I first start up the web app locally (see
qless
for more), take a first pass, and
enqueue a single job while the worker is running:
# Supposing that I have /my/awesome/project/awesomeproject.py
# In one terminal...
reqless-py-worker --path /my/awesome/project --queue foo --workers 1 --interval 10 --verbose
# In another terminal...
>>> import reqless
>>> import awesomeproject
>>> reqless.Client().queues["foo"].put(awesomeproject.Job, '{"key": "value"}')
From there, I watch the output on the worker, adjust my job class, save it,
watch again, etc., but without restarting the worker -- in general it
shouldn't be necessary to restart the worker.
Internals and Additional Features
While in many cases the above is sufficient, there are also many cases where
you may need something more. Hopefully after this section many of your
questions will be answered.
Priority
Jobs can optionally have priority associated with them. Jobs of equal priority
are popped in the order in which they were put in a queue. The higher the
priority, the sooner it will be processed. If, for example, you get a new job
to collect some really valuable underpants:
queue.put(reqless.gnomes.GnomesJob, '{"address": "123 Brief St."}', priority = 10)
You can also adjust a job's priority while it's waiting:
job = client.jobs["83da4d32a0a811e1933012313b062cf1"]
job.priority = 25
Scheduled Jobs
Jobs can also be scheduled for the future with a delay (in seconds). If for
example, you just learned of an underpants heist opportunity, but you have to
wait until later:
queue.put(reqless.gnomes.GnomesJob, {}, delay=3600)
It's worth noting that it's not guaranteed that this job will run at that time.
It merely means that this job will only be considered valid after the delay
has passed, at which point it will be subject to the normal constraints. If
you want it to be processed very soon after the delay expires, you could also
boost its priority:
queue.put(reqless.gnomes.GnomesJob, {}, delay=3600, priority=100)
Recurring Jobs
Whether it's nightly maintenance, or weekly customer updates, you can have a
job of a certain configuration set to recur. Recurring jobs still support
priority, and tagging, and are attached to a queue. Let's say, for example, I
need some global maintenance to run, and I don't care what machine runs it, so
long as someone does:
client.queues["maintenance"].recur(myJob, '{"tasks": ["sweep", "mop", "scrub"]}', interval=60 * 60 * 24)
That will spawn a job right now, but it's possible you'd like to have it recur,
but maybe the first job should wait a little bit:
client.queues["maintenance"].recur(..., interval=86400, offset=3600)
You can always update the tags, priority and even the interval of a recurring job:
job = client.jobs["83da4d32a0a811e1933012313b062cf1"]
job.priority = 20
job.tag("foo", "bar")
job.untag("hello")
job.interval = 7200
These attributes aren't attached to the recurring jobs, per se, but it's used
as the template for the job that it creates. In the case where more than one
interval passes before a worker tries to pop the job, more than one job is
created. The thinking is that while it's
completely client-managed, the state should not be dependent on how often
workers are trying to pop jobs.
queue.recur(..., '{"lots": "of jobs"}', 60)
len(queue.pop(10))
Configuration Options
You can get and set global (read: in the context of the same Redis instance)
configuration to change the behavior for heartbeating, and so forth. There
aren't a tremendous number of configuration options, but an important one is
how long job data is kept around. Job data is expired after it has been
completed for jobs-history
seconds, but is limited to the last
jobs-history-count
completed jobs. These default to 50k jobs, and 30 days,
but depending on volume, your needs may change. To only keep the last 500 jobs
for up to 7 days:
client.config["jobs-history"] = 7 * 86400
client.config["jobs-history-count"] = 500
Tagging / Tracking
In qless
, "tracking" means flagging a job as important. Tracked jobs have a
tab reserved for them in the web interface, and they also emit events that can
be subscribed to as they make progress (more on that below). You can flag a job
from the web interface, or the corresponding code:
client.jobs["b1882e009a3d11e192d0b174d751779d"].track()
Jobs can be tagged with strings which are indexed for quick searches. For
example, jobs might be associated with customer accounts, or some other key
that makes sense for your project.
queue.put(reqless.gnomes.GnomesJob, '{"tags": "aplenty"}', tags=["12345", "foo", "bar"])
This makes them searchable in the web interface, or from code:
jids = client.jobs.tagged("foo")
You can add or remove tags at will, too:
job = client.jobs["b1882e009a3d11e192d0b174d751779d"]
job.tag("howdy", "hello")
job.untag("foo", "bar")
Job Dependencies
Jobs can be made dependent on the completion of another job. For example, if
you need to buy eggs, and buy a pan before making an omelet, you could say:
eggs_jid = client.queues["buy_eggs"].put(myJob, '{"count": 12}')
pan_jid = client.queues["buy_pan" ].put(myJob, '{"coating": "non-stick"}')
client.queues["omelete"].put(myJob, '{"toppings": ["onions", "ham"]}', depends=[eggs_jid, pan_jid])
That way, the job to make the omelet can't be performed until the pan and eggs
purchases have been completed.
Notifications
Tracked jobs emit events on specific pubsub channels as things happen to them.
Whether it's getting popped off of a queue, completed by a worker, etc. The
jist of it goes like this, though:
def callback(evt, jid):
print('%s => %s' % (jid, evt))
from functools import partial
for evt in ["canceled", "completed", "failed", "popped", "put", "stalled", "track", "untrack"]:
client.events.on(evt, partial(callback, evt))
client.events.listen()
If you're interested in, say, getting growl or campfire notifications, you
should check out the qless-growl
and qless-campfire
ruby gems.
Retries
Workers sometimes die. That's an unfortunate reality of life. We try to
mitigate the effects of this by insisting that workers heartbeat their jobs to
ensure that they do not get dropped. That said, qless
server will
automatically requeue jobs that do get "stalled" up to the provided number of
retries (default is 5). Since underpants profit can sometimes go awry, maybe
you want to retry a particular heist several times:
queue.put(reqless.gnomes.GnomesJob, "{}", retries=10)
Pop
A client pops one or more jobs from a queue:
job = queue.pop()
jobs = queue.pop(20)
Heartbeating
Each job object has a notion of when you must either check in with a heartbeat
or turn it in as completed. You can get the absolute time until it expires, or
how long you have left:
job.expires_at
job.ttl
If your lease on the job will expire before you have a chance to complete it,
then you should heartbeat it to make sure that no other worker gets access to
it. Or, if you are done, you should complete it so that the job can move on:
job.heartbeat()
job.complete()
job.complete("anotherQueue")
Stats
One of the selling points of qless
is that it keeps stats for you about your
underpants hijinks. It tracks the average wait time, number of jobs that have
waited in a queue, failures, retries, and average running time. It also keeps
histograms for the number of jobs that have waited x time, and the number
that took x time to run.
Frankly, these are best viewed using the web app.
Lua
qless
is a set of client language bindings, but the majority of the work is
done in a collection of Lua scripts that comprise the
core functionality. These scripts run
on the Redis 2.6+ server atomically and allow for portability with the same
functionality guarantees. Consult the documentation for qless-core
to learn
more about its internals.
Web App
qless
also comes with a web app for administrative tasks, like keeping tabs
on the progress of jobs, tracking specific jobs, retrying failed jobs, etc.
It's available in the qless
library as a
mountable Sinatra
app. The web app is language
agnostic and was one of the major desires out of this project, so you should
consider using it even if you're not planning on using the Ruby client.