title: Making 1 million requests with python-aiohttp url: http://pawelmhm.github.io/asyncio/python/aiohttp/2016/04/22/asyncio-aiohttp.html hash_url: 44abc2fd416f673b9c6ae0f5147726a9
In this post I’d like to test limits of python aiohttp and check its performance in terms of requests per minute. Everyone knows that asynchronous code performs better when applied to network operations, but it’s still interesting to check this assumption and understand how exactly it is better and why it’s is better. I’m going to check it by trying to make 1 million requests with aiohttp client. How many requests per minute will aiohttp make? What kind of exceptions and crashes can you expect when you try to make such volume of requests with very primitive scripts? What are main gotchas that you need to think about when trying to make such volume of requests?
Async programming is not easy. It’s not easy because using callbacks and thinking in terms of events and event handlers requires more effort than usual synchronous programming. But it is also difficult because asyncio is still relatively new and there are few blog posts, tutorials about it. Official docs are very terse and contain only basic examples. There are some Stack Overflow questions but not that many only 410 as of time of writing (compare with 2 585 questions tagged “twisted”) There are couple of nice blog posts and articles about asyncio over there such as this, that, that or perhaps even this or this.
To make it easier let’s start with the basics - simple HTTP hello world - just making GET and fetching one single HTTP response.
In synchronous world you just do:
import requests
def hello()
return requests.get("http://httpbin.org/get")
print(hello())
How does that look in aiohttp?
#!/usr/local/bin/python3.5
import asyncio
from aiohttp import ClientSession
async def hello():
async with ClientSession() as session:
async with session.get("http://httpbin.org/headers") as response:
response = await response.read()
print(response)
loop = asyncio.get_event_loop()
loop.run_until_complete(hello())
hmm looks like I had to write lots of code for such a basic task… There is “async def” and “async with” and two “awaits” here. It seems really confusing at first sight, let’s try to explain it then.
You make your function asynchronous by using async keyword before function definition and using await keyword. There are actually two asynchronous operations that our hello() function performs. First it fetches response asynchronously, then it reads response body in asynchronous manner.
Aiohttp recommends to use ClientSession as primary interface to make requests. ClientSession
allows you to store cookies between requests and keeps objects that are common for
all requests (event loop, connection and other things). Session needs to be closed after using it,
and closing session is another asynchronous operation, this is why you need async with
every time you deal with sessions.
After you open client session you can use it to make requests. This is where another asynchronous
operation starts, downloading request. Just as in case of client sessions responses must be closed
explicitly, and context manager’s with
statement ensures it will be closed properly in all
circumstances.
To start your program you need to run it in event loop, so you need to create instance of asyncio loop and put task into this loop.
It all does sound bit difficult but it’s not that complex and looks logical if you spend some time trying to understand it.
Now let’s try to do something more interesting, fetching multiple urls one after another. With synchronous code you would do just:
for url in urls:
print(requests.get(url).text)
This is really quick and easy, async will not be that easy, so you should always consider if something more complex
is actually necessary for your needs. If your app works nice with synchronous code maybe there
is no need to bother with async code? If you do need to bother with async code here’s how you do
that. Our hello()
async function stays the same but we need to wrap it in asyncio Future
object
and pass whole lists of Future objects as tasks to be executed in the loop.
loop = asyncio.get_event_loop()
tasks = []
# I'm using test server localhost, but you can use any url
url = "http://localhost:8080/{}"
for i in range(5):
task = asyncio.ensure_future(hello(url.format(i)))
tasks.append(task)
loop.run_until_complete(asyncio.wait(tasks))
Now let’s say we want to collect all responses in one list and do some postprocessing on them. At the moment we’re not keeping response body anywhere, we just print it, let’s return this response, keep it in list, and print all responses at the end.
To collect bunch of responses you probably need to write something along the lines of:
#!/usr/local/bin/python3.5
import asyncio
from aiohttp import ClientSession
async def fetch(url):
async with ClientSession() as session:
async with session.get(url) as response:
return await response.read()
async def run(loop, r):
url = "http://localhost:8080/{}"
tasks = []
for i in range(r):
task = asyncio.ensure_future(fetch(url.format(i)))
tasks.append(task)
responses = await asyncio.gather(*tasks)
# you now have all response bodies in this variable
print(responses)
def print_responses(result):
print(result)
loop = asyncio.get_event_loop()
future = asyncio.ensure_future(run(loop, 4))
loop.run_until_complete(future)
Notice usage of asyncio.gather()
, this collects bunch of Future objects in one place
and waits for all of them to finish.
Now let’s simulate real process of learning and let’s make mistake in above script and try to debug it, this should be really helpful for demonstration purposes.
This is how sample broken async function looks like:
# WARNING! BROKEN CODE DO NOT COPY PASTE
async def fetch(url):
async with ClientSession() as session:
async with session.get(url) as response:
return response.read()
This code is broken, but it’s not that easy to figure out why if you dont know much about asyncio. Even if you know Python well but you dont know asyncio or aiohttp well you’ll be in trouble to figure out what happens.
What is output of above function?
It produces following output:
pawel@pawel-VPCEH390X ~/p/l/benchmarker> ./bench.py
[<generator object ClientResponse.read at 0x7fa68d465728>, <generator object ClientResponse.read at 0x7fa68cdd9468>, <generator object ClientResponse.read at 0x7fa68d4656d0>, <generator object ClientResponse.read at 0x7fa68cdd9af0>]
What happens here? You expected to get response objects after all processing is done, but here you actually get bunch of generators, why is that?
It happens because as I’ve mentioned earlier response.read()
is async
operation, this means that it does not return result immediately, it just returns generator.
This generator still needs to be called and
executed, and this does not happen by default, yield from
in Python 3.4 and await
in Python 3.5 were
added exactly for this purpose: to actually iterate over generator function. Fix to above error
is just adding await before response.read()
.
# async operation must be preceded by await
return await response.read() # NOT: return response.read()
Let’s break our code in some other way.
# WARNING! BROKEN CODE DO NOT COPY PASTE
async def run(loop, r):
url = "http://localhost:8080/{}"
tasks = []
for i in range(r):
task = asyncio.ensure_future(fetch(url.format(i)))
tasks.append(task)
responses = asyncio.gather(*tasks)
print(responses)
Again above code is broken but it’s not easy to figure out why if you’re just learning asyncio.
Above produces following output:
pawel@pawel-VPCEH390X ~/p/l/benchmarker> ./bench.py
<_GatheringFuture pending>
Task was destroyed but it is pending!
task: <Task pending coro=<fetch() running at ./bench.py:7> wait_for=<Future pending cb=[Task._wakeup()]> cb=[gather.<locals>._done_callback(0)() at /usr/local/lib/python3.5/asyncio/tasks.py:602]>
Task was destroyed but it is pending!
task: <Task pending coro=<fetch() running at ./bench.py:7> wait_for=<Future pending cb=[Task._wakeup()]> cb=[gather.<locals>._done_callback(1)() at /usr/local/lib/python3.5/asyncio/tasks.py:602]>
Task was destroyed but it is pending!
task: <Task pending coro=<fetch() running at ./bench.py:7> wait_for=<Future pending cb=[Task._wakeup()]> cb=[gather.<locals>._done_callback(2)() at /usr/local/lib/python3.5/asyncio/tasks.py:602]>
Task was destroyed but it is pending!
task: <Task pending coro=<fetch() running at ./bench.py:7> wait_for=<Future pending cb=[Task._wakeup()]> cb=[gather.<locals>._done_callback(3)() at /usr/local/lib/python3.5/asyncio/tasks.py:602]>
What happens here? If you examine your localhost logs you may see that requests are not reaching
your server at all. Clearly no requests are performed. Print statement prints that
responses variable contains <_GatheringFuture pending>
object, and later it alerts that
pending tasks were destroyed. Why is it happening? Again you forgot about await
faulty line is this
responses = asyncio.gather(*tasks)
it should be:
responses = await asyncio.gather(*tasks)
I guess main lesson from those mistakes is: always remember about using “await” if you’re actually awaiting something.
Finally time for some fun. Let’s check if async is really worth the hassle. What’s the difference in efficiency between asynchronous client and blocking client? How many requests per minute can I send with my async client?
With this questions in mind I set up simple (async) aiohttp server. My server is going to read full html text of Frankenstein by Marry Shelley. It will add random delays between responses. Some responses will have zero delay, and some will have maximum of 3 seconds delay. This should resemble real applications, few apps respond to all requests with same latency, usually latency differs from response to response.
Server code looks like this:
#!/usr/local/bin/python3.5
import asyncio
from datetime import datetime
from aiohttp import web
import random
# set seed to ensure async and sync client get same distribution of delay values
# and tests are fair
random.seed(1)
async def hello(request):
name = request.match_info.get("name", "foo")
n = datetime.now().isoformat()
delay = random.randint(0, 3)
await asyncio.sleep(delay)
headers = {"content_type": "text/html", "delay": str(delay)}
# opening file is not async here, so it may block, to improve
# efficiency of this you can consider using asyncio Executors
# that will delegate file operation to separate thread or process
# and improve performance
# https://docs.python.org/3/library/asyncio-eventloop.html#executor
# https://pymotw.com/3/asyncio/executors.html
with open("frank.html", "rb") as html_body:
print("{}: {} delay: {}".format(n, request.path, delay))
response = web.Response(body=html_body.read(), headers=headers)
return response
app = web.Application()
app.router.add_route("GET", "/{name}", hello)
web.run_app(app)
Synchronous client looks like this:
import requests
r = 100
url = "http://localhost:8080/{}"
for i in range(r):
res = requests.get(url.format(i))
delay = res.headers.get("DELAY")
d = res.headers.get("DATE")
print("{}:{} delay {}".format(d, res.url, delay))
How long will it take to run this?
On my machine running above synchronous client took 2:45.54 minutes.
My async code looks just like above code samples above. How long will async client take?
On my machine it took 0:03.48 seconds.
It is interesting that it took exactly as long as longest delay from my server. If you look into messages printed by client script you can see how great async HTTP client is. Some responses had 0 delay but others got 3 seconds delay. In synchronous client they would be blocking and waiting, your machine would simply stay idle for this time. Async client does not waste time, when something is delayed it simply does something else, issues other requests or processes all other responses. You can see this clearly in logs, first there are responses with 0 delay, then after they arrrived you can see responses with 1 seconds delay, and so on until most delayed responses arrive.
Now that we know our async client is better let’s try to test its limits and try to crash our localhost. I’m going to start with sending 1k async requests. I’m curious how many requests my client can handle.
> time python3 bench.py
2.68user 0.24system 0:07.14elapsed 40%CPU (0avgtext+0avgdata 53704maxresident)k
0inputs+0outputs (0major+14156minor)pagefaults 0swaps
So 1k requests take 7 seconds, pretty nice! How about 10k? Trying to make 10k requests unfortunately fails…
responses are <_GatheringFuture finished exception=ClientOSError(24, 'Cannot connect to host localhost:8080 ssl:False [Can not connect to localhost:8080 [Too many open files]]')>
Traceback (most recent call last):
File "/home/pawel/.local/lib/python3.5/site-packages/aiohttp/connector.py", line 581, in _create_connection
File "/usr/local/lib/python3.5/asyncio/base_events.py", line 651, in create_connection
File "/usr/local/lib/python3.5/asyncio/base_events.py", line 618, in create_connection
File "/usr/local/lib/python3.5/socket.py", line 134, in __init__
OSError: [Errno 24] Too many open files
That’s bad, seems like I stumbled across 10k connections problem.
It says “too many open files”, and probably refers to number of open sockets.
Why does it call them files? Sockets are just file descriptors, operating systems limit number of open sockets
allowed. How many files are too many? I checked with python resource module and it seems like it’s around 1024.
How can we bypass this? Primitive way is just increasing limit of open files. But this
is probably not the good way to go. Much better way is just adding some synchronization
in your client limiting number of concurrent requests it can process. I’m going to do this
by adding asyncio.Semaphore()
with max tasks of 1000.
Modified client code looks like this now:
# modified fetch function with semaphore
import random
import asyncio
from aiohttp import ClientSession
async def fetch(url):
async with ClientSession() as session:
async with session.get(url) as response:
delay = response.headers.get("DELAY")
date = response.headers.get("DATE")
print("{}:{} with delay {}".format(date, response.url, delay))
return await response.read()
async def bound_fetch(sem, url):
# getter function with semaphore
async with sem:
await fetch(url)
async def run(loop, r):
url = "http://localhost:8080/{}"
tasks = []
# create instance of Semaphore
sem = asyncio.Semaphore(1000)
for i in range(r):
# pass Semaphore to every GET request
task = asyncio.ensure_future(bound_fetch(sem, url.format(i)))
tasks.append(task)
responses = asyncio.gather(*tasks)
await responses
number = 10000
loop = asyncio.get_event_loop()
future = asyncio.ensure_future(run(loop, number))
loop.run_until_complete(future)
At this point I can process 10k urls. It takes 23 seconds and returns some exceptions but overall it’s pretty nice!
How about 100 000? This really makes my computer work hard but suprisingly
it works ok. Server turns out to be suprisingly stable although
you can see that ram usage gets pretty high at this point, cpu usage is around
100% all the time. What I find interesting is that my server takes significantly less cpu than client.
Here’s snapshot of linux ps
output.
pawel@pawel-VPCEH390X ~/p/l/benchmarker> ps ua | grep python
USER PID %CPU %MEM VSZ RSS TTY STAT START TIME COMMAND
pawel 2447 56.3 1.0 216124 64976 pts/9 Sl+ 21:26 1:27 /usr/local/bin/python3.5 ./test_server.py
pawel 2527 101 3.5 674732 212076 pts/0 Rl+ 21:26 2:30 /usr/local/bin/python3.5 ./bench.py
Overall it took around 5 minutes before it crashed for some reason. It generated around 100k lines of output so it’s not that easy to pinpoint traceback, seems like some responses are not closed, is it because of some error from my server or something in client?
After scrolling for couple of seconds I found this exception in client logs.
File "/usr/local/lib/python3.5/asyncio/futures.py", line 387, in __iter__
return self.result() # May raise too.
File "/usr/local/lib/python3.5/asyncio/futures.py", line 274, in result
raise self._exception
File "/usr/local/lib/python3.5/asyncio/selector_events.py", line 411, in _sock_connect
sock.connect(address)
OSError: [Errno 99] Cannot assign requested address
I dont really know what happens here. My initial hypothesis is that test server went down for some split second, and this caused some client error that was printed at the end. One of the readers suggests that this exception may be caused by OS running out of free ephemereal ports. I added semaphore earlier so number of concurrent connections should be maximum 1k, but some sockets may still be closing and not available for kernel to assign.
Overall it’s really not bad, 5 minutes for 100 000 requests? This makes around 20k requests per minute. Pretty powerful if you ask me.
Finally I’m going to try 1 million requests. I really hope my laptop is not going to explode when testing that. For this amount of requests I reduced delays from server to range between 0 and 1.
1 000 000 requests finished in 52 minutes
1913.06user 1196.09system 52:06.87elapsed 99%CPU (0avgtext+0avgdata 5194260maxresident)k
265144inputs+0outputs (18692major+2528207minor)pagefaults 0swaps
so it means my client made around 19230 requests per minute. Not bad isn’t it? Note that capabilities of my client are limited by server responding with delay of 0 and 1 in this scenario, seems like my test server also crashed silently couple of times.
You can see that asynchronous HTTP clients can be pretty powerful. Performing 1 million requests from async client is not difficult, and the client performs really well in comparison to synchronous code.
I wonder how it compares to other languages and async frameworks? Perhaps in some future post I could compare Twisted Treq with aiohttp. There is also question how many concurrent requests can be issued by async libraries in other languages. E.g. what would be results of benchmarks for some Java async frameworks? Or C++ frameworks? Or some Rust HTTP clients?