# What's a good rate limiting algorithm?

I could use some pseudo-code, or better, Python. I am trying to implement a rate-limiting queue for a Python IRC bot, and it partially works, but if someone triggers less messages than the limit (e.g., rate limit is 5 messages per 8 seconds, and the person triggers only 4), and the next trigger is over the 8 seconds (e.g., 16 seconds later), the bot sends the message, but the queue becomes full and the bot waits 8 seconds, even though it's not needed since the 8 second period has lapsed.

## 10 Answers

Here the simplest algorithm, if you want just to drop messages when they arrive too quickly (instead of queuing them, which makes sense because the queue might get arbitrarily large):

``````rate = 5.0; // unit: messages
per  = 8.0; // unit: seconds
allowance = rate; // unit: messages
last_check = now(); // floating-point, e.g. usec accuracy. Unit: seconds

when (message_received):
current = now();
time_passed = current - last_check;
last_check = current;
allowance += time_passed * (rate / per);
if (allowance > rate):
allowance = rate; // throttle
if (allowance < 1.0):
discard_message();
else:
forward_message();
allowance -= 1.0;
``````

There are no datastructures, timers etc. in this solution and it works cleanly :) To see this, 'allowance' grows at speed 5/8 units per seconds at most, i.e. at most five units per eight seconds. Every message that is forwarded deducts one unit, so you can't send more than five messages per every eight seconds.

Note that `rate` should be an integer, i.e. without non-zero decimal part, or the algorithm won't work correctly (actual rate will not be `rate/per`). E.g. `rate=0.5; per=1.0;` does not work because `allowance` will never grow to 1.0. But `rate=1.0; per=2.0;` works fine.

• It's also worth pointing out that the dimension and scale of 'time_passed' must be the same as 'per', e.g. seconds. – skaffman Jun 17 '09 at 13:13
• Hi skaffman, thanks for the compliments---I threw it out of my sleeve but with 99.9% probability someone has earlier came up with a similar solution :) – Antti Huima Jun 19 '09 at 5:02
• That is a standard algorithm—it's a token bucket, without queue. The bucket is `allowance`. The bucket size is `rate`. The `allowance += …` line is an optimization of adding a token every rate ÷ per seconds. – derobert Jan 26 '12 at 19:32
• @zwirbeltier What you write above is not true. 'Allowance' is always capped by 'rate' (look at the "// throttle" line) so it will only allow a burst of exactly 'rate' messages at any particular time, i.e. 5. – Antti Huima Mar 18 '13 at 8:20
• This is good, but can exceed the rate. Let's say at time 0 you forward 5 messages, then at time N * (8/5) for N = 1, 2, ... you can send another message, resulting in more than 5 messages in an 8 second period – mindvirus Aug 30 '13 at 16:17

Use this decorator @RateLimited(ratepersec) before your function that enqueues.

Basically, this checks if 1/rate secs have passed since the last time and if not, waits the remainder of the time, otherwise it doesn't wait. This effectively limits you to rate/sec. The decorator can be applied to any function you want rate-limited.

In your case, if you want a maximum of 5 messages per 8 seconds, use @RateLimited(0.625) before your sendToQueue function.

``````import time

def RateLimited(maxPerSecond):
minInterval = 1.0 / float(maxPerSecond)
def decorate(func):
lastTimeCalled = [0.0]
def rateLimitedFunction(*args,**kargs):
elapsed = time.clock() - lastTimeCalled
leftToWait = minInterval - elapsed
if leftToWait>0:
time.sleep(leftToWait)
ret = func(*args,**kargs)
lastTimeCalled = time.clock()
return ret
return rateLimitedFunction
return decorate

@RateLimited(2)  # 2 per second at most
def PrintNumber(num):
print num

if __name__ == "__main__":
print "This should print 1,2,3... at about 2 per second."
for i in range(1,100):
PrintNumber(i)
``````
• I like the idea of using a decorator for this purpose. Why do is lastTimeCalled a list? Also, I doubt this'll work when multiple threads are calling the same RateLimited function... – Stephan202 Mar 20 '09 at 20:09
• It's a list because simple types like float are constant when captured by a closure. By making it a list, the list is constant, but its contents are not. Yes, it's not thread-safe but that can be easily fixed with locks. – Carlos A. Ibarra Mar 20 '09 at 21:08
• `time.clock()` doesn't have enough resolution on my system, so I adapted the code and changed to use `time.time()` – mtrbean Jun 5 '14 at 19:20
• For rate limiting, you definitely do not want to use `time.clock()`, which measures elapsed CPU time. CPU time can run much faster or much slower than "actual" time. You want to use `time.time()` instead, which measures wall time ("actual" time). – John Wiseman Dec 21 '15 at 23:42
• BTW for real production systems: implementing a rate limiting with a sleep() call might not be a good idea as it is going to block the thread and therefore preventing another client from using it. – Maresh Feb 7 '16 at 20:56

A Token Bucket is fairly simple to implement.

Start with a bucket with 5 tokens.

Every 5/8 seconds: If the bucket has less than 5 tokens, add one.

Each time you want to send a message: If the bucket has ≥1 token, take one token out and send the message. Otherwise, wait/drop the message/whatever.

(obviously, in actual code, you'd use an integer counter instead of real tokens and you can optimize out the every 5/8s step by storing timestamps)

Reading the question again, if the rate limit is fully reset each 8 seconds, then here is a modification:

Start with a timestamp, `last_send`, at a time long ago (e.g., at the epoch). Also, start with the same 5-token bucket.

Strike the every 5/8 seconds rule.

Each time you send a message: First, check if `last_send` ≥ 8 seconds ago. If so, fill the bucket (set it to 5 tokens). Second, if there are tokens in the bucket, send the message (otherwise, drop/wait/etc.). Third, set `last_send` to now.

That should work for that scenario.

I've actually written an IRC bot using a strategy like this (the first approach). Its in Perl, not Python, but here is some code to illustrate:

The first part here handles adding tokens to the bucket. You can see the optimization of adding tokens based on time (2nd to last line) and then the last line clamps bucket contents to the maximum (MESSAGE_BURST)

``````    my \$start_time = time;
...
# Bucket handling
my \$bucket = \$conn->{fujiko_limit_bucket};
my \$lasttx = \$conn->{fujiko_limit_lasttx};
\$bucket += (\$start_time-\$lasttx)/MESSAGE_INTERVAL;
(\$bucket <= MESSAGE_BURST) or \$bucket = MESSAGE_BURST;
``````

\$conn is a data structure which is passed around. This is inside a method that runs routinely (it calculates when the next time it'll have something to do, and sleeps either that long or until it gets network traffic). The next part of the method handles sending. It is rather complicated, because messages have priorities associated with them.

``````    # Queue handling. Start with the ultimate queue.
my \$queues = \$conn->{fujiko_queues};
foreach my \$entry (@{\$queues->[PRIORITY_ULTIMATE]}) {
# Ultimate is special. We run ultimate no matter what. Even if
# it sends the bucket negative.
--\$bucket;
\$entry->{code}(@{\$entry->{args}});
}
\$queues->[PRIORITY_ULTIMATE] = [];
``````

That's the first queue, which is run no matter what. Even if it gets our connection killed for flooding. Used for extremely important things, like responding to the server's PING. Next, the rest of the queues:

``````    # Continue to the other queues, in order of priority.
QRUN: for (my \$pri = PRIORITY_HIGH; \$pri >= PRIORITY_JUNK; --\$pri) {
my \$queue = \$queues->[\$pri];
while (scalar(@\$queue)) {
if (\$bucket < 1) {
# continue later.
\$need_more_time = 1;
last QRUN;
} else {
--\$bucket;
my \$entry = shift @\$queue;
\$entry->{code}(@{\$entry->{args}});
}
}
}
``````

Finally, the bucket status is saved back to the \$conn data structure (actually a bit later in the method; it first calculates how soon it'll have more work)

``````    # Save status.
\$conn->{fujiko_limit_bucket} = \$bucket;
\$conn->{fujiko_limit_lasttx} = \$start_time;
``````

As you can see, the actual bucket handling code is very small — about four lines. The rest of the code is priority queue handling. The bot has priority queues so that e.g., someone chatting with it can't prevent it from doing its important kick/ban duties.

• Am I missing something... it looks like this would limit you to 1 message every 8 seconds after you get through the first 5 – chills42 Mar 20 '09 at 19:12
• @chills42: Yes, I read the question wrong... see the second half of the answer. – derobert Mar 20 '09 at 19:15
• @chills: If last_send is <8 seconds, you don't add any tokens to the bucket. If your bucket contains tokens, you can send the message; otherwise you can't (you've already sent 5 messages in the last 8 secs) – derobert Mar 20 '09 at 19:18
• I'd appreciate it if the folks downvoting this would please explain why... I'd like to fix any problems you see, but that's hard to do without feedback! – derobert Mar 20 '09 at 22:22

to block processing until the message can be sent, thus queuing up further messages, antti's beautiful solution may also be modified like this:

``````rate = 5.0; // unit: messages
per  = 8.0; // unit: seconds
allowance = rate; // unit: messages
last_check = now(); // floating-point, e.g. usec accuracy. Unit: seconds

when (message_received):
current = now();
time_passed = current - last_check;
last_check = current;
allowance += time_passed * (rate / per);
if (allowance > rate):
allowance = rate; // throttle
if (allowance < 1.0):
time.sleep( (1-allowance) * (per/rate))
forward_message();
allowance = 0.0;
else:
forward_message();
allowance -= 1.0;
``````

it just waits until enough allowance is there to send the message. to not start with two times the rate, allowance may also initialized with 0.

• When you sleep `(1-allowance) * (per/rate)`, you need to add that same amount to `last_check`. – Alp Apr 2 '15 at 22:21

Keep the time that the last five lines were sent. Hold the queued messages until the time the fifth-most-recent message (if it exists) is a least 8 seconds in the past (with last_five as an array of times):

``````now = time.time()
if len(last_five) == 0 or (now - last_five[-1]) >= 8.0:
last_five.insert(0, now)
send_message(msg)
if len(last_five) > 5:
last_five.pop()
``````
• You're doing much more work than the token bucket... – derobert Mar 20 '09 at 19:21
• Not since you revised it I'm not. – Pesto Mar 20 '09 at 19:25
• You're storing five time stamps and repeatedly shifting them through memory (or doing linked list operations). I'm storing one integer counter and one timestamp. And only doing arithmetic and assign. – derobert Mar 20 '09 at 19:28
• Except that mine will function better if trying to send 5 lines but only 3 more are allowed in the time period. Yours will allow sending the first three, and force a 8 second wait before sending 4 and 5. Mine will allow 4 and 5 to be sent 8 seconds after the fourth- and fifth-most-recent lines. – Pesto Mar 20 '09 at 19:31
• But on the subject, performance could be improved through using a circular linked list of length 5, pointing to the fifth-most-recent send, overwriting it on new send, and moving the pointer forward one. – Pesto Mar 20 '09 at 19:34

One solution is to attach a timestamp to each queue item and to discard the item after 8 seconds have passed. You can perform this check each time the queue is added to.

This only works if you limit the queue size to 5 and discard any additions whilst the queue is full.

If someone still interested, I use this simple callable class in conjunction with a timed LRU key value storage to limit request rate per IP. Uses a deque, but can rewritten to be used with a list instead.

``````from collections import deque
import time

class RateLimiter:
def __init__(self, maxRate=5, timeUnit=1):
self.timeUnit = timeUnit
self.deque = deque(maxlen=maxRate)

def __call__(self):
if self.deque.maxlen == len(self.deque):
cTime = time.time()
if cTime - self.deque > self.timeUnit:
self.deque.append(cTime)
return False
else:
return True
self.deque.append(time.time())
return False

r = RateLimiter()
for i in range(0,100):
time.sleep(0.1)
print(i, "block" if r() else "pass")
``````

Just a python implementation of a code from accepted answer.

``````import time

class Object(object):
pass

def get_throttler(rate, per):
scope = Object()
scope.allowance = rate
scope.last_check = time.time()
def throttler(fn):
current = time.time()
time_passed = current - scope.last_check;
scope.last_check = current;
scope.allowance = scope.allowance + time_passed * (rate / per)
if (scope.allowance > rate):
scope.allowance = rate
if (scope.allowance < 1):
pass
else:
fn()
scope.allowance = scope.allowance - 1
return throttler
``````

How about this:

``````long check_time = System.currentTimeMillis();
int msgs_sent_count = 0;

private boolean isRateLimited(int msgs_per_sec) {
if (System.currentTimeMillis() - check_time > 1000) {
check_time = System.currentTimeMillis();
msgs_sent_count = 0;
}

if (msgs_sent_count > (msgs_per_sec - 1)) {
return true;
} else {
msgs_sent_count++;
}

return false;
}
``````

I needed a variation in Scala. Here it is:

``````case class Limiter[-A, +B](callsPerSecond: (Double, Double), f: A ⇒ B) extends (A ⇒ B) {

import Thread.sleep
private def now = System.currentTimeMillis / 1000.0
private val (calls, sec) = callsPerSecond
private var allowance  = 1.0
private var last = now

def apply(a: A): B = {
synchronized {
val t = now
val delta_t = t - last
last = t
allowance += delta_t * (calls / sec)
if (allowance > calls)
allowance = calls
if (allowance < 1d) {
sleep(((1 - allowance) * (sec / calls) * 1000d).toLong)
}
allowance -= 1
}
f(a)
}

}
``````

Here is how it can be used:

``````val f = Limiter((5d, 8d), {
_: Unit ⇒
println(System.currentTimeMillis)
})
while(true){f(())}
``````

## protected by Alexander O'MaraFeb 9 '16 at 7:36

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