24 June 2017
0 comments
Python
Suppose that you have a function and you wonder, "Can I make this faster?" Well, you might already have thought that and you might already have a theory. Or two. Or three. Your theory might be sound and likely to be right, but before you go anywhere with it you need to benchmark it first. Here are some tips and scaffolding for doing Python function benchmark comparisons.
Tenets
-
Internally, Python will warm up and it's likely that your function depends on other things such as databases or IO. So it's important that you don't test function1 first and then function2 immediately after because function2 might benefit from a warm up painfully paid for by function1. So mix up the order of them or cycle through them enough that they all pay for or gain from warm ups.
-
Look at the median first. The mean (aka. average) is often tainted by spikes and these spikes of slow-down can be caused by your local Spotify client deciding to reindex itself or something some such. Sometimes those spikes matter. For example, garbage collection is inevitable and will have an effect that matters.
-
Run your functions many times. So many times that the whole benchmark takes a while. Like tens of seconds or more. Also, if you run it significantly long it's likely that all candidates gets punished by the same environmental effects such as garbage collection or CPU being reassinged to something else intensive on your computer.
-
Try to take your benchmark into different, and possibly more realistic environments. For example, don't rely on reading a file like /Users/peterbe/only/on/my/macbook when, likely, the end destination for your code is an Ubuntu server in AWS. Write your code so that it's easy to copy and paste around, like into a vi/jed editor in an ssh session somewhere.
-
Sanity check each function before benchmarking them. No need for pytest or anything fancy but just make sure that you test them in some basic way. But the assertion testing is likely to add to the total execution time so don't do it when running the functions.
-
Avoid "prints" inside the time measured code. A print() is I/O and an "external resource" that can become very unfair to compare CPU bound performance.
-
Don't fear testing many different functions. If you have multiple ideas of doing a function differently, it's cheap to pile them on. But be careful how you "report" because if there are many different ways of doing something you might accidentally compare different fruit without noticing.
-
Make sure your functions take at least one parameter. I'm no Python core developer or C hacker but I know there are "murks" within a compiler and interpreter that might do what a regular memoizer might done. Also, the performance difference can be reversed on tiny inputs compared to really large ones.
-
Be humble with the fact that 0.01 milliseconds difference when doing 10,000 iterations is probably not worth writing a more complex and harder-to-debug function.
The Boilerplate
Let's demonstrate with an example:
# The functions to compare
import math
def f1(degrees):
return math.cos(degrees)
def f2(degrees):
e = 2.718281828459045
return (
(e**(degrees * 1j) + e**-(degrees * 1j)) / 2
).real
# Assertions
assert f1(100) == f2(100) == 0.862318872287684
assert f1(1) == f2(1) == 0.5403023058681398
# Reporting
import time
import random
import statistics
functions = f1, f2
times = {f.__name__: [] for f in functions}
for i in range(100000): # adjust accordingly so whole thing takes a few sec
func = random.choice(functions)
t0 = time.time()
func(i)
t1 = time.time()
times[func.__name__].append((t1 - t0) * 1000)
for name, numbers in times.items():
print('FUNCTION:', name, 'Used', len(numbers), 'times')
print('\tMEDIAN', statistics.median(numbers))
print('\tMEAN ', statistics.mean(numbers))
print('\tSTDEV ', statistics.stdev(numbers))
Let's break that down a bit.
-
The first area (# The functions to compare) is all up to you. This silly example tries to peg Python's builtin math.cos against your own arithmetic expression.
-
The second area (# Assertions) is where you do some basic sanity checks/tests. This comes in handy to make sure if you keep modifying the functions more and more to try to squeeze out some extra juice.
-
The last area (# Reporting) is the boilerplat'y area. You obviously have to change the line functions = f1, f2 to include all the named functions you have in the first area. And the number of iterations totally depends on how long the functions take to run. Here it's 100,000 times which is kinda ridiculous but I just needed a dead simple function to demonstrate.
-
Note that each measurement is in milliseconds.
You run that and get something like this:
FUNCTION: f1 Used 49990 times
MEDIAN 0.0
MEAN 0.00045161219591330375
STDEV 0.0011268475946446341
FUNCTION: f2 Used 50010 times
MEDIAN 0.00095367431640625
MEAN 0.0009188626294516487
STDEV 0.000642871632138125
More Examples
The example above already broke one of the tenets in that these functions were simply too fast. Doing rather basic mathematics is just too fast to compare with such a trivial benchmark. Here are some other examples:
Remove duplicates from list without losing order
# The functions to compare
def f1(seq):
checked = []
for e in seq:
if e not in checked:
checked.append(e)
return checked
def f2(seq):
checked = []
seen = set()
for e in seq:
if e not in seen:
checked.append(e)
seen.add(e)
return checked
def f3(seq):
checked = []
[checked.append(i) for i in seq if not checked.count(i)]
return checked
def f4(seq):
seen = set()
return [x for x in seq if x not in seen and not seen.add(x)]
def f5(seq):
def generator():
seen = set()
for x in seq:
if x not in seen:
seen.add(x)
yield x
return list(generator())
# Assertion
import random
def _random_seq(length):
seq = []
for _ in range(length):
seq.append(random.choice(
'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ'
))
return seq
L = list('abca')
assert f1(L) == f2(L) == f3(L) == f4(L) == f5(L) == list('abc')
L = _random_seq(10)
assert f1(L) == f2(L) == f3(L) == f4(L) == f5(L)
# Reporting
import time
import statistics
functions = f1, f2, f3, f4, f5
times = {f.__name__: [] for f in functions}
for i in range(3000):
seq = _random_seq(i)
for _ in range(len(functions)):
func = random.choice(functions)
t0 = time.time()
func(seq)
t1 = time.time()
times[func.__name__].append((t1 - t0) * 1000)
for name, numbers in times.items():
print('FUNCTION:', name, 'Used', len(numbers), 'times')
print('\tMEDIAN', statistics.median(numbers))
print('\tMEAN ', statistics.mean(numbers))
print('\tSTDEV ', statistics.stdev(numbers))
Results:
FUNCTION: f1 Used 3029 times
MEDIAN 0.6871223449707031
MEAN 0.6917867380307822
STDEV 0.42611748137761174
FUNCTION: f2 Used 2912 times
MEDIAN 0.054955482482910156
MEAN 0.05610262627130026
STDEV 0.03000829926668248
FUNCTION: f3 Used 2985 times
MEDIAN 1.4472007751464844
MEAN 1.4371055654145566
STDEV 0.888658217522005
FUNCTION: f4 Used 2965 times
MEDIAN 0.051975250244140625
MEAN 0.05343245816673035
STDEV 0.02957275548477728
FUNCTION: f5 Used 3109 times
MEDIAN 0.05507469177246094
MEAN 0.05678296204202234
STDEV 0.031521596461048934
Winner:
def f4(seq):
seen = set()
return [x for x in seq if x not in seen and not seen.add(x)]
Fastest way to count the number of lines in a file
# The functions to compare
import codecs
import subprocess
def f1(filename):
count = 0
with codecs.open(filename, encoding='utf-8', errors='ignore') as f:
for line in f:
count += 1
return count
def f2(filename):
with codecs.open(filename, encoding='utf-8', errors='ignore') as f:
return len(f.read().splitlines())
def f3(filename):
return int(subprocess.check_output(['wc', '-l', filename]).split()[0])
# Assertion
filename = 'big.csv'
assert f1(filename) == f2(filename) == f3(filename) == 9999
# Reporting
import time
import statistics
import random
functions = f1, f2, f3
times = {f.__name__: [] for f in functions}
filenames = 'dummy.py', 'hacker_news_data.txt', 'yarn.lock', 'big.csv'
for _ in range(200):
for fn in filenames:
for func in functions:
t0 = time.time()
func(fn)
t1 = time.time()
times[func.__name__].append((t1 - t0) * 1000)
for name, numbers in times.items():
print('FUNCTION:', name, 'Used', len(numbers), 'times')
print('\tMEDIAN', statistics.median(numbers))
print('\tMEAN ', statistics.mean(numbers))
print('\tSTDEV ', statistics.stdev(numbers))
Results:
FUNCTION: f1 Used 800 times
MEDIAN 5.852460861206055
MEAN 25.403797328472137
STDEV 37.09347378640582
FUNCTION: f2 Used 800 times
MEDIAN 0.45299530029296875
MEAN 2.4077045917510986
STDEV 3.717931526478758
FUNCTION: f3 Used 800 times
MEDIAN 2.8804540634155273
MEAN 3.4988239407539368
STDEV 1.3336427480808102
Winner:
def f2(filename):
with codecs.open(filename, encoding='utf-8', errors='ignore') as f:
return len(f.read().splitlines())
Conclusion
No conclusion really. Just wanted to point out that this is just a hint of a decent start when doing performance benchmarking of functions.
There is also the timeit built-in for "provides a simple way to time small bits of Python code" but it has the disadvantage that your functions are not allowed to be as complex. Also, it's harder to generate multiple different fixtures to feed your functions without that fixture generation effecting the times.
There's a lot of things that this boilerplate can improve such as sorting by winner, showing percentages comparisons against the fastests, ASCII graphs, memory allocation differences, etc. That's up to you.
16 June 2017
0 comments
Web development,
Python
tl;dr; It's faster to list objects with prefix being the full key path, than to use HEAD to find out of a object is in an S3 bucket.
Background
I have a piece of code that opens up a user uploaded .zip file and extracts its content. Then it uploads each file into an AWS S3 bucket if the file size is different or if the file didn't exist at all before.
It looks like this:
for filename, filesize, fileobj in extract(zip_file):
size = _size_in_s3(bucket, filename)
if size is None or size != filesize:
upload_to_s3(bucket, filename, fileobj)
print('Updated!' if size else 'New!')
else:
print('Ignored')
I'm using the boto3 S3 client so there are two ways to ask if the object exists and get its metadata.
Option 1: client.head_object
Option 2: client.list_objects_v2 with Prefix=${keyname}.
But why the two different approaches?
The problem with client.head_object is that it's odd in how it works. Sane but odd. If the object does not exist, boto3 raises a botocore.exceptions.ClientError which contains a response and in it you can look for exception.response['Error']['Code'] == '404'.
What I noticed was that if you use a try:except ClientError: approach to figure out if an object exists, you reset the client's connection pool in urllib3. So after an exception has happened, any other operations on the client causes it to have to, internally, create a new HTTPS connection. That can cost time.
I wrote and filed this issue on github.com/boto/boto3.
So I wrote two different functions to return an object's size if it exists:
def _key_existing_size__head(client, bucket, key):
"""return the key's size if it exist, else None"""
try:
obj = client.head_object(Bucket=bucket, Key=key)
return obj['ContentLength']
except ClientError as exc:
if exc.response['Error']['Code'] != '404':
raise
And the contender...:
def _key_existing_size__list(client, bucket, key):
"""return the key's size if it exist, else None"""
response = client.list_objects_v2(
Bucket=bucket,
Prefix=key,
)
for obj in response.get('Contents', []):
if obj['Key'] == key:
return obj['Size']
They both work. That was easy to test. But which is fastest?
Before we begin, which do you think is fastest? The head_object feels like it'll be able to send an operation to S3 internally to do a key lookup directly. But S3 isn't a normal database.
Here's the script partially cleaned up but should be easy to run.
The results
So I wrote a loop that ran 1,000 times and I made sure the bucket was empty so that 1,000 times the result of the iteration is that it sees that the file doesn't exist and it has to do a client.put_object.
Here are the results:
FUNCTION: _key_existing_size__list Used 511 times
SUM 148.2740752696991
MEAN 0.2901645308604679
MEDIAN 0.2569708824157715
STDEV 0.17742598775696436
FUNCTION: _key_existing_size__head Used 489 times
SUM 249.79622673988342
MEAN 0.510830729529414
MEDIAN 0.4780092239379883
STDEV 0.14352671121877011
Because it's network bound, it's really important to avoid the 'MEAN' and instead look at the 'MEDIAN'. My home broadband can cause temporary spikes.
Clearly, using client.list_objects_v2 is faster. It's 90% faster than client.head_object.
But note! this was 1,000 times of B) "does the file already exist?" and B) "No? Ok upload it". So the times there include all the client.put_object calls.
So why did I measure both? I.e. _key_existing_size__list+client.put_object versus. _key_existing_size__head+client.put_object? The reason is that the approach of using try:except ClientError: followed by a client.put_object causes boto3 to create a new HTTPS connection in its pool. Again, see the issue which demonstrates this in different words.
What if the object always exists?
So, I simply run the benchmark again. The first time, it uploaded all 1,000 uniquely named objects. So running it a second time, every time the answer is that the object exists, and its size hasn't changed, so it never triggers the client.put_object.
Here are the results this time:
FUNCTION: _key_existing_size__list Used 495 times
SUM 54.60546112060547
MEAN 0.11031406286991004
MEDIAN 0.08583354949951172
STDEV 0.06339202669609442
FUNCTION: _key_existing_size__head Used 505 times
SUM 44.59347581863403
MEAN 0.0883039125121466
MEDIAN 0.07310152053833008
STDEV 0.054452842190700346
In this case, using client.head_object is faster. By 20% but the median time is 0.08 seconds! Even on a home broadband connection. In other words, I don't think that difference is significant.
One more time, excluding the client.put_object
The point of using client.list_objects_v2 instead of client.head_object was to avoid breaking the connection pool in urllib3 that boto3 manages somehow. Having to create a new HTTPS connection (and adding it to the pool) costs time, but what if we disregard that and compare the two functions "purely" on how long they take when the file does NOT exist? Remember, the second measurement above was when every object exists.
So we know it took 0.09 seconds and 0.07 seconds respectively for the two functions to figure out that the object does exist. How long does it take to figure out that the object does not exist independent of any other op. I.e. just try each one without doing a client.put_object afterwards. That means we avoid the bug so the comparison is fair.
The results:
FUNCTION: _key_existing_size__list Used 499 times
SUM 123.57429671287537
MEAN 0.247643881188127
MEDIAN 0.2196049690246582
STDEV 0.18622877427652743
FUNCTION: _key_existing_size__head Used 501 times
SUM 112.99495434761047
MEAN 0.22553883103315464
MEDIAN 0.2828958034515381
STDEV 0.15342842113446084
The client.list_objects_v2 beats client.head_object by 30%. And it matters. Above I said that 20% difference didn't matter but now it does. That's because the time difference when it always finds the object was 0.013 seconds. When it comes to figuring out that the object did not exist the time difference is 0.063 seconds. That's still a pretty small number but, hey, you gotto draw the line somewhere.
In conclusion
Using client.list_objects_v2 is a better alternative to using client.head_object.
If you think you'll often find that the object doesn't exist and needs a client.put_object then using client.list_objects_v2 is 90% faster. If you think you'll rarely need client.put_object (i.e. that most objects don't change) then client.list_objects_v2 is almost the same performance.
07 June 2017
0 comments
Go,
MacOSX,
Linux
"machma - Easy parallel execution of commands with live feedback"
This is so cool! https://github.com/fd0/machma
It's a command line program that makes it really easy to run any command line program in parallel. I.e. in separate processes with separate CPUs.
Something network bound
Suppose I have a file like this:
▶ wc -l urls.txt
30 urls.txt
▶ cat urls.txt | head -n 3
https://s3-us-west-2.amazonaws.com/org.mozilla.crash-stats.symbols-public/v1/wntdll.pdb/D74F79EB1F8D4A45ABCD2F476CCABACC2/wntdll.sym
https://s3-us-west-2.amazonaws.com/org.mozilla.crash-stats.symbols-public/v1/firefox.pdb/448794C699914DB8A8F9B9F88B98D7412/firefox.sym
https://s3-us-west-2.amazonaws.com/org.mozilla.crash-stats.symbols-public/v1/d2d1.pdb/CB8FADE9C48E44DA9A10B438A33114781/d2d1.sym
If I wanted to download all of these files with wget the traditional way would be:
▶ time cat urls.txt | xargs wget -q -P ./downloaded/
cat urls.txt 0.00s user 0.00s system 53% cpu 0.005 total
xargs wget -q -P ./downloaded/ 0.07s user 0.24s system 2% cpu 14.913 total
▶ ls downloaded | wc -l
30
▶ du -sh downloaded
21M downloaded
So it took 15 seconds to download 30 files that totals 21MB.
Now, let's do it with machama instead:
▶ time cat urls.txt | machma -- wget -q -P ./downloaded/ {}
cat urls.txt 0.00s user 0.00s system 55% cpu 0.004 total
machma -- wget -q -P ./downloaded/ {} 0.53s user 0.45s system 12% cpu 7.955 total
That uses 8 separate processors (because my laptop has 8 CPUs).
Because 30 / 8 ~= 4, it roughly does 4 iterations.
But note, it took 15 seconds to download 30 files synchronously. That's an average of 0.5s per file. The reason it doesn't take 4x0.5 seconds (instead of 8 seconds) is because it's at the mercy of bad luck and some of those 30 spiking a bit.
Something CPU bound
Now let's do something really CPU intensive; Guetzli compression.
▶ ls images | wc -l
7
▶ time find images -iname '*.jpg' | xargs -I {} guetzli --quality 85 {} compressed/{}
find images -iname '*.jpg' 0.00s user 0.00s system 40% cpu 0.009 total
xargs -I {} guetzli --quality 85 {} compressed/{} 35.74s user 0.68s system 99% cpu 36.560 total
And now the same but with machma:
▶ time find images -iname '*.jpg' | machma -- guetzli --quality 85 {} compressed/{}
processed 7 items (0 failures) in 0:10
find images -iname '*.jpg' 0.00s user 0.00s system 51% cpu 0.005 total
machma -- guetzli --quality 85 {} compressed/{} 58.47s user 0.91s system 546% cpu 10.857 total
Basically, it took only 11 seconds. This time there were fewer images (7) than there was CPUs (8), so basically the poor computer is doing super intensive CPU (and memory) work across all CPUs at the same time. The average time for each of these files is ~5 seconds so it's really interesting that even if you try to do this in parallel execution instead of taking a total of ~5 seconds, it took almost double that.
In conclusion
Such a handy tool to have around for command line stuff. I haven't looked at its code much but it's almost a shame that the project only has 300+ GitHub stars. Perhaps because it's kinda complete and doesn't need much more work.
Also, if you attempt all the examples above you'll notice that when you use the ... | xargs ... approach the stdout and stderr is a mess. For wget, that's why I used -q to silence it a bit. With machma you get a really pleasant color coded live output that tells you the state of the queue, possible failures and an ETA.
24 May 2017
0 comments
MacOSX,
Web development,
Linux
tl;dr; Guetzli, the new JPEG compression program from Google can save a bytes with little loss of quality.
Inspired by this blog post about Guetzli I thought I'd try it out with something that's relevant to my project, 300x300 JPGs that can be heavily compressed.
So I installed it (with Homebrew) on my MacBook Pro (late 2013) and picked 7 JPGs I had, and use in SongSearch. Which is interesting because these JPEGs have already been compressed once. They are taken from converting from much larger PNGs with PIL (Pillow) at quality rating 80%. In other words, this is Guetzli on top of PIL.
I ran one iteration for every image for the following qualities: 85%, 90%, 95%, 99%, 100%.
The results on the size are as follows:
| Image |
Average Size (bytes) |
% Smaller |
| original |
23497.0 |
0 |
| 85% |
16025.4 |
32% |
| 90% |
18829.4 |
20% |
| 95% |
21338.1 |
9.2% |
| 99% |
22705.3 |
3.4% |
| 100% |
22919.7 |
2.5% |
So, for example, if you choose the 90% quality you save, on average, 4,667B (4.6KB).
As you might already know, Guetzli is incredibly memory hungry and very very slow. On average each image compression took on average 4-6 seconds (higher quality, shorter times). Meaning, if you like Guetzli you probably need to build around it so that the compression happens in a build step or async somewhere and ideally you don't want to run too many compressions in parallel as it might cause CPU and memory overloading.
Now, how does it look?
Go to https://codepen.io/peterbe/pen/rmPMpm and stare at the screen to see if you can A) see which one is more compressed and B) if the one that is more compressed is too low quality.
What do you think?
Is it worth it?
Is the quality drop too much to save 10% on image sizes?
Please share your thoughts. Perhaps we can re-do this experiment with some slightly larger JPGs.
11 May 2017
0 comments
Django,
Web development,
Linux,
Python
I have an app that does a lot of Redis queries. It all runs in AWS with ElastiCache Redis. Due to the nature of the app, it stores really large hash tables in Redis. The application then depends on querying Redis for these. The question is; What is the best configuration possible for the fastest service possible?
Note! Last month I wrote Fastest cache backend possible for Django which looked at comparing Redis against Memcache. Might be an interesting read too if you're not sold on Redis.
Options
All options are variations on the compressor, serializer and parser which are things you can override in django-redis. All have an effect on the performance. Even compression, for if the number of bytes between Redis and the application is smaller, then it should have better network throughput.
Without further ado, here are the variations:
CACHES = {
"default": {
"BACKEND": "django_redis.cache.RedisCache",
"LOCATION": config('REDIS_LOCATION', 'redis://127.0.0.1:6379') + '/0',
"OPTIONS": {
"CLIENT_CLASS": "django_redis.client.DefaultClient",
}
},
"json": {
"BACKEND": "django_redis.cache.RedisCache",
"LOCATION": config('REDIS_LOCATION', 'redis://127.0.0.1:6379') + '/1',
"OPTIONS": {
"CLIENT_CLASS": "django_redis.client.DefaultClient",
"SERIALIZER": "django_redis.serializers.json.JSONSerializer",
}
},
"ujson": {
"BACKEND": "django_redis.cache.RedisCache",
"LOCATION": config('REDIS_LOCATION', 'redis://127.0.0.1:6379') + '/2',
"OPTIONS": {
"CLIENT_CLASS": "django_redis.client.DefaultClient",
"SERIALIZER": "fastestcache.ujson_serializer.UJSONSerializer",
}
},
"msgpack": {
"BACKEND": "django_redis.cache.RedisCache",
"LOCATION": config('REDIS_LOCATION', 'redis://127.0.0.1:6379') + '/3',
"OPTIONS": {
"CLIENT_CLASS": "django_redis.client.DefaultClient",
"SERIALIZER": "django_redis.serializers.msgpack.MSGPackSerializer",
}
},
"hires": {
"BACKEND": "django_redis.cache.RedisCache",
"LOCATION": config('REDIS_LOCATION', 'redis://127.0.0.1:6379') + '/4',
"OPTIONS": {
"CLIENT_CLASS": "django_redis.client.DefaultClient",
"PARSER_CLASS": "redis.connection.HiredisParser",
}
},
"zlib": {
"BACKEND": "django_redis.cache.RedisCache",
"LOCATION": config('REDIS_LOCATION', 'redis://127.0.0.1:6379') + '/5',
"OPTIONS": {
"CLIENT_CLASS": "django_redis.client.DefaultClient",
"COMPRESSOR": "django_redis.compressors.zlib.ZlibCompressor",
}
},
"lzma": {
"BACKEND": "django_redis.cache.RedisCache",
"LOCATION": config('REDIS_LOCATION', 'redis://127.0.0.1:6379') + '/6',
"OPTIONS": {
"CLIENT_CLASS": "django_redis.client.DefaultClient",
"COMPRESSOR": "django_redis.compressors.lzma.LzmaCompressor"
}
},
}
As you can see, they each have a variation on the OPTIONS.PARSER_CLASS, OPTIONS.SERIALIZER or OPTIONS.COMPRESSOR.
The default configuration is to use redis-py and to pickle the Python objects to a bytestring. Pickling in Python is pretty fast but it has the disadvantage that it's Python specific so you can't have a Ruby application reading the same Redis database.
The Experiment
Note how I have one LOCATION per configuration. That's crucial for the sake of testing. That way one database is all JSON and another is all gzip etc.
What the benchmark does is that it measures how long it takes to READ a specific key (called benchmarking). Then, once it's done that it appends that time to the previous value (or [] if it was the first time). And lastly it writes that list back into the database. That way, towards the end you have 1 key whose value looks something like this: [0.013103008270263672, 0.003879070281982422, 0.009411096572875977, 0.0009970664978027344, 0.0002830028533935547, ..... MANY MORE ....].
Towards the end, each of these lists are pretty big. About 500 to 1,000 depending on the benchmark run.
In the experiment I used wrk to basically bombard the Django server on the URL /random (which makes a measurement with a random configuration). On the EC2 experiment node, it finalizes around 1,300 requests per second which is a decent number for an application that does a fair amount of writes.
The way I run the Django server is with uwsgi like this:
uwsgi --http :8000 --wsgi-file fastestcache/wsgi.py --master --processes 4 --threads 2
And the wrk command like this:
wrk -d30s "http://127.0.0.1:8000/random"
(that, by default, runs 2 threads on 10 connections)
At the end of starting the benchmarking, I open http://localhost:8000/summary which spits out a table and some simple charts.
An Important Quirk
One thing I noticed when I started was that the final numbers' average was very different from the medians. That would indicate that there are spikes. The graph on the right shows the times put into that huge Python list for the default configuration for the first 200 measurements. Note that there are little spikes but generally quite flat over time once it gets past the beginning.
Sure enough, it turns out that in almost all configurations, the time it takes to make the query in the beginning is almost order of magnitude slower than the times once the benchmark has started running for a while.
So in the test code you'll see that it chops off the first 10 times. Perhaps it should be more than 10. After all, if you don't like the spikes you can simply look at the median as the best source of conclusive truth.
The Code
The benchmarking code is here. Please be aware that this is quite rough. I'm sure there are many things that can be improved, but I'm not sure I'm going to keep this around.
The Equipment
The ElastiCache Redis I used was a cache.m3.xlarge (13 GiB, High network performance) with 0 shards and 1 node and no multi-zone enabled.
The EC2 node was a m4.xlarge Ubuntu 16.04 64-bit (4 vCPUs and 16 GiB RAM with High network performance).
Both the Redis and the EC2 were run in us-west-1c (North Virginia).
The Results
Here are the results! Sorry if it looks terrible on mobile devices.
root@ip-172-31-2-61:~# wrk -d30s "http://127.0.0.1:8000/random" && curl "http://127.0.0.1:8000/summary"
Running 30s test @ http://127.0.0.1:8000/random
2 threads and 10 connections
Thread Stats Avg Stdev Max +/- Stdev
Latency 9.19ms 6.32ms 60.14ms 80.12%
Req/Sec 583.94 205.60 1.34k 76.50%
34902 requests in 30.03s, 2.59MB read
Requests/sec: 1162.12
Transfer/sec: 88.23KB
TIMES AVERAGE MEDIAN STDDEV
json 2629 2.596ms 2.159ms 1.969ms
msgpack 3889 1.531ms 0.830ms 1.855ms
lzma 1799 2.001ms 1.261ms 2.067ms
default 3849 1.529ms 0.894ms 1.716ms
zlib 3211 1.622ms 0.898ms 1.881ms
ujson 3715 1.668ms 0.979ms 1.894ms
hires 3791 1.531ms 0.879ms 1.800ms
Best Averages (shorter better)
###############################################################################
██████████████████████████████████████████████████████████████ 2.596 json
█████████████████████████████████████ 1.531 msgpack
████████████████████████████████████████████████ 2.001 lzma
█████████████████████████████████████ 1.529 default
███████████████████████████████████████ 1.622 zlib
████████████████████████████████████████ 1.668 ujson
█████████████████████████████████████ 1.531 hires
Best Medians (shorter better)
###############################################################################
███████████████████████████████████████████████████████████████ 2.159 json
████████████████████████ 0.830 msgpack
████████████████████████████████████ 1.261 lzma
██████████████████████████ 0.894 default
██████████████████████████ 0.898 zlib
████████████████████████████ 0.979 ujson
█████████████████████████ 0.879 hires
Size of Data Saved (shorter better)
###############################################################################
█████████████████████████████████████████████████████████████████ 60K json
██████████████████████████████████████ 35K msgpack
████ 4K lzma
█████████████████████████████████████ 35K default
█████████ 9K zlib
████████████████████████████████████████████████████ 48K ujson
█████████████████████████████████████ 34K hires
Discussion Points
- There is very little difference once you avoid the
json serialized one.
msgpack is the fastest by a tiny margin. I prefer median over average because it's more important how it over a long period of time. - The
default (which is pickle) is fast too.
lzma and zlib compress the strings very well. Worth thinking about the fact that zlib is a very universal tool and makes the app "Python agnostic". - You probably don't want to use the
json serializer. It's fat and slow.
- Using
hires makes very little difference. That's a bummer.
- Considering how useful
zlib is (since you can fit so much much more data in your Redis) it's impressive that it's so fast too!
- I quite like
zlib. If you use that on the pickle serializer you're able to save ~3.5 times as much data.
- Laugh all you want but until today I had never heard of
lzma. So based on that odd personal fact, I'm pessmistic towards that as a compression choice.
Conclusion
This experiment has lead me to the conclusion that the best serializer is msgpack and the best compression is zlib. That is the best configuration for django-redis.
msgpack has implementation libraries for many other programming languages. Right now that doesn't matter for my application but if msgpack is both faster and more versatile (because it supports multiple languages) I conclude that to be the best serializer instead.
27 April 2017
0 comments
Javascript,
Web development
This isn't rocket science in the world of Web Development but I think it's so darn useful that if you've been unlucky to miss this, it's worth mentioning one more time.
Suppose you're on a site with lots of links. Like https://www.peterbe.com/plog.
And you want to get a list of all URLs that contain word "react" in the URL pathname.
And you want to get this into your clipboard.
Here's what you do:
-
Open your browsers Web Console. In Firefox it's Alt+Cmd+K on OSX (or F12). In Chrome it's Alt+Cmd+J.
-
Type in the magic: copy([...document.querySelectorAll('a')].map(a => a.href).filter(u => u.match(/react/i)))
-
Hit Enter, go to a text editor and paste like regular.
It should look something like this:
[
"https://www.peterbe.com/plog/10-reasons-i-love-create-react-app",
"https://www.peterbe.com/plog/how-to-deploy-a-create-react-app",
"https://www.peterbe.com/plog/4-different-kinds-of-react-component-styles",
"https://www.peterbe.com/plog/onchange-in-reactjs",
"https://www.peterbe.com/plog/tips-on-learning-react",
"https://www.peterbe.com/plog/visual-speed-comparison-of-angularjs-and-reactjs",
"https://www.peterbe.com/plog/600-billion-challenge-reactions",
"https://www.peterbe.com/plog/active-reactor-watches"
]
The example is just that. An example. The cool thing about this is:
- The Web Console built-in command
copy().
- That
[...document.querySelectorAll('a')] turns the NodeList object into a regular array.
- That the
.map(a => a.href) is super simple and it turns each Node into its href attribute value.
- That you could have used a more advanced CSS selector like
document.querySelectorAll(a[target="_blank"]) for example.
The limit is your imagination. You can also do things like copy([...document.querySelectorAll('a')].filter(a => a.textContent.match(/react/i)).map(a => a.href)) and you filter by the links' text.
19 April 2017
1 comment
Python
tl;dr; I have a lot of code that does response = requests.get(...) in various Python projects. This is nice and simple but the problem is that networks are unreliable. So it's a good idea to wrap these network calls with retries. Here's one such implementation.
The First Hack
import time
import requests
# DON'T ACTUALLY DO THIS.
# THERE ARE BETTER WAYS. HANG ON!
def get(url):
try:
return requests.get(url)
except Exception:
# sleep for a bit in case that helps
time.sleep(1)
# try again
return get(url)
This, above, is a terrible solution. It might fail for sooo many reasons. For example SSL errors due to missing Python libraries. Or the URL might have a typo in it, like get('http:/www.example.com').
Also, perhaps it did work but the response is a 500 error from the server and you know that if you just tried again, the problem would go away.
# ALSO A TERRIBLE SOLUTION
while True:
response = get('http://www.example.com')
if response.status_code != 500:
break
else:
# Hope it won't 500 a little later
time.sleep(1)
What we need is a solution that does this right. Both for 500 errors and for various network errors.
The Solution
Here's what I propose:
import requests
from requests.adapters import HTTPAdapter
from requests.packages.urllib3.util.retry import Retry
def requests_retry_session(
retries=3,
backoff_factor=0.3,
status_forcelist=(500, 502, 504),
session=None,
):
session = session or requests.Session()
retry = Retry(
total=retries,
read=retries,
connect=retries,
backoff_factor=backoff_factor,
status_forcelist=status_forcelist,
)
adapter = HTTPAdapter(max_retries=retry)
session.mount('http://', adapter)
session.mount('https://', adapter)
return session
Usage example...
response = requests_retry_session().get('https://www.peterbe.com/')
print(response.status_code)
s = requests.Session()
s.auth = ('user', 'pass')
s.headers.update({'x-test': 'true'})
response = requests_retry_session(sesssion=s).get(
'https://www.peterbe.com'
)
It's an opinionated solution but by its existence it demonstrates how it works so you can copy and modify it.
Testing The Solution
Suppose you try to connect to a URL that will definitely never work, like this:
t0 = time.time()
try:
response = requests_retry_session().get(
'http://localhost:9999',
)
except Exception as x:
print('It failed :(', x.__class__.__name__)
else:
print('It eventually worked', response.status_code)
finally:
t1 = time.time()
print('Took', t1 - t0, 'seconds')
There is no server running in :9999 here on localhost. So the outcome of this is...
It failed :( ConnectionError
Took 1.8215010166168213 seconds
Where...
1.8 = 0 + 0.6 + 1.2
The algorithm for that backoff is documented here and it says:
A backoff factor to apply between attempts after the second try (most errors are resolved immediately by a second try without a delay). urllib3 will sleep for:
{backoff factor} * (2 ^ ({number of total retries} - 1))
seconds. If the backoff_factor is 0.1, then sleep() will sleep for [0.0s, 0.2s, 0.4s, ...] between retries. It will never be longer than Retry.BACKOFF_MAX.
By default, backoff is disabled (set to 0).
It does 3 retry attempts, after the first failure, with a backoff sleep escalation of: 0.6s, 1.2s.
So if the server never responds at all, after a total of ~1.8 seconds it will raise an error:
In this example, the simulation is matching the expectations (1.82 seconds) because my laptop's DNS lookup is near instant for localhost. If it had to do a DNS lookup, it'd potentially be slightly more on the first failure.
Works In Conjunction With timeout
Timeout configuration is not something you set up in the session. It's done on a per-request basis. httpbin makes this easy to test. With a sleep delay of 10 seconds it will never work (with a timeout of 5 seconds) but it does use the timeout this time. Same code as above but with a 5 second timeout:
t0 = time.time()
try:
response = requests_retry_session().get(
'http://httpbin.org/delay/10',
timeout=5
)
except Exception as x:
print('It failed :(', x.__class__.__name__)
else:
print('It eventually worked', response.status_code)
finally:
t1 = time.time()
print('Took', t1 - t0, 'seconds')
And the output of this is:
It failed :( ConnectionError
Took 21.829053163528442 seconds
That makes sense. Same backoff algorithm as before but now with 5 seconds for each attempt:
21.8 = 5 + 0 + 5 + 0.6 + 5 + 1.2 + 5
Works For 500ish Errors Too
This time, let's run into a 500 error:
t0 = time.time()
try:
response = requests_retry_session().get(
'http://httpbin.org/status/500',
)
except Exception as x:
print('It failed :(', x.__class__.__name__)
else:
print('It eventually worked', response.status_code)
finally:
t1 = time.time()
print('Took', t1 - t0, 'seconds')
The output becomes:
It failed :( RetryError
Took 2.353440046310425 seconds
Here, the reason the total time is 2.35 seconds and not the expected 1.8 is because there's a delay between my laptop and httpbin.org. I tested with a local Flask server to do the same thing and then it took a total of 1.8 seconds.
Discussion
Yes, this suggested implementation is very opinionated. But when you've understood how it works, understood your choices and have the documentation at hand you can easily implement your own solution.
Personally, I'm trying to replace all my requests.get(...) with requests_retry_session().get(...) and when I'm making this change I make sure I set a timeout on the .get() too.
The choice to consider a 500, 502 and 504 errors "retry'able" is actually very arbitrary. It totally depends on what kind of service you're reaching for. Some services only return 500'ish errors if something really is broken and is likely to stay like that for a long time. But this day and age, with load balancers protecting a cluster of web heads, a lot of 500 errors are just temporary. Obivously, if you're trying to do something very specific like requests_retry_session().post(...) with very specific parameters you probably don't want to retry on 5xx errors.
14 April 2017
0 comments
ReactJS,
Javascript
tl;dr; I'm not a TC39 member and I barely understand half of what those heros are working on but there is one feature they're working on that really stands out, in my view, for React coders; Public Class Fields.
The Problem?
Very common pattern in React code is that have a component that has methods that are tied to DOM events (e.g. onClick) and often these methods need acess to this. The component's this. So you can reach things like this.state or this.setState().
You might have this in your code:
class App extends Component {
state = {counter: 0}
constructor() {
super()
// Like homework or situps; something you have to do :(
this.incrementCounter = this.incrementCounter.bind(this)
}
incrementCounter() {
this.setState(ps => {
return {counter: ps.counter + 1}
})
}
render() {
return (
<div>
<p>
<button onClick={this.incrementCounter}>Increment</button>
</p>
<h1>{this.state.counter}</h1>
</div>
)
}
}
Demo
If you don't bind the class method to this in the constructor, this will be undefined inside the class instance field incrementCounter. Buu!
Suppose you don't like having the word incrementCounter written in 4 placecs, you might opt for this shorthand notation where you create a new unnamed function inside the render function:
class App extends Component {
state = {counter: 0}
render() {
return (
<div>
<p>
<button onClick={() => {
this.setState(ps => {
return {counter: ps.counter + 1}
})
}}>Increment</button>
</p>
<h1>{this.state.counter}</h1>
</div>
)
}
}
Demo
Sooo much shorter and kinda nice that the code can be so close in proximity to the actual onClick event definition.
But this notation has a horrible side-effect. It creates a new function on every render. If instead of a regular DOM jsx object <button> it might be a sub-component like <CoolButton/> then that sub-component would be forced to re-render every time (unless you write your own shouldComponentUpdate.
Also, this notation works when the code is small and light but it might get messy quickly if you need that functionality on other element's onClick. Or it might become mess with really deep indentation.
The Solution?
Public Class Fields.
That new feature is currently in the "Draft" stage at TC39. Aka. stage 1.
However, I discovered that you can use stage-2 in Babel to use this particular feature.
Note! I don't understand why you only have to put on your stage-2-brave socks for this feature when it's part of a definition that is stage 1.
Anyway, what it means is that you can define your field (aka method) like this instead:
class App extends Component {
state = {counter: 0}
incrementCounter = () => {
this.setState(ps => {
return {counter: ps.counter + 1}
})
}
render() {
return (
<div>
<p>
<button onClick={this.incrementCounter}>Increment</button>
</p>
<h1>{this.state.counter}</h1>
</div>
)
}
}
Demo
Now it's only mentioned by name incrementCounter twice. And no need for that manual binding in a constructor.
And since it's automatically bound, the function isn't recreated and those can easily make sub-components be pure.
So, let's always write our React methods this way from now on.
Oh, and in case you wonder. Inheritence works the same with these public class fields as the regular class instance fields.
09 April 2017
0 comments
Django,
Web development,
Python
The title is a bit of an understatement because I think it's pretty good. It's not perfect and it's not guaranteed to scale, but it works pretty well. Especially on search term typos.
This, my own blog, now has a search engine built with Elasticsearch using the Python library elasticsearch-dsl. The algorithm (if you can call it that) is my own afternoon hack invention. Before I explain how it works try out a couple of searches:
Try a couple of searches:
(each search appends &debug-search for extended output)
- corn - finds Cornwall, cron, Crontabber, crontab, corp etc.
- crown - finds crown, Crowne, crowded, crowds, crowd etc.
- react - finds create-react-app, React app, etc.
- jugg - finds Jung, juggling, judging, judged etc.
- pythn - finds Python, python2.4, python2.5 etc.
Also, by default it uses Elasticsearch's match_phrase so when you search for a multi-word thing, it requires a match on each term. E.g. date format which finds Date formatting, date formats etc.
But if you search for something where the whole phrase can't match, it splits up the search an uses a match operator instead (minus any stop words).
Typo-focussed
This solution is very much focussed on typos. One thing I really dislike in non-Google search engines is when you make a search and nothing is found and it says "Did you mean ...?". Quite likely I did, but why do I have to click it? Can't it just be clicked for me?
Also, if there's ambiguity and possibly some results based on what you typed and multiple potential "Did you mean...?". Why not just blend them alltogether like Google does? Here is my attempt to solve that. Come with me...
Figuring Out ALL Search Terms
So if you type "Firefix" (not "Firefox", also scroll to the bottom to see the debug table) then maybe, that's an actual word that might be in the database. Then by using the Elasticsearch's Suggesters it figures out alternative spellings based on frequency distributions within the indexed content. This lookup is actually really fast. So now it figures out three alternative ways to spell this term:
firefox (score 0.9, 1 character different)firefli (score 0.7, 2 characters different)firfox (score 0.7, 2 characters different)
And, very arbitrarily I pick a score for the default term that the user typed in. Let's pick 1.1. Doesn't matter gravely and it's up for future tuning. The initial goal is to not bury this spelling alternative too far back.
Here's how to run the suggester for every defined doc type and generate a list of other search terms tuples (minimum score >=0.6).
search_terms = [(1.1, q)]
_search_terms = set([q])
doc_type_keys = (
(BlogItemDoc, ('title', 'text')),
(BlogCommentDoc, ('comment',)),
)
for doc_type, keys in doc_type_keys:
suggester = doc_type.search()
for key in keys:
suggester = suggester.suggest('sugg', q, term={'field': key})
suggestions = suggester.execute_suggest()
for each in suggestions.sugg:
if each.options:
for option in each.options:
if option.score >= 0.6:
better = q.replace(each['text'], option['text'])
if better not in _search_terms:
search_terms.append((
option['score'],
better,
))
_search_terms.add(better)
Eventually we get a list (once sorted) that looks like this:
search_terms = [(1.1 'firefix'), (0.9, 'firefox'), (0.7, 'firefli'), (0.7, 'firfox')]
The only reason the code sorts this by the score is in case there are crazy-many search terms. Then we might want to chop off some and only use the 5 highest scoring spelling alternatives.
Building The Boosted OR-query
In this scenario, we're searching amongst blog posts. The title is likely to be a better match than the body. If the title mentions it we probably want to favor that over those where it's only mentioned in the body.
So to build up the OR-query we'll boost the title more than the body ("text" in this example) and we'll build it up using all possible search terms and boost them based on their score. Here's the complete query.
strategy = 'match_phrase'
if original_q:
strategy = 'match'
search_term_boosts = {}
for i, (score, word) in enumerate(search_terms):
# meaning the first search_term should be boosted most
j = len(search_terms) - i
boost = 1 * j * score
boost_title = 2 * boost
search_term_boosts[word] = (boost_title, boost)
match = Q(strategy, title={
'query': word,
'boost': boost_title,
}) | Q(strategy, text={
'query': word,
'boost': boost,
})
if matcher is None:
matcher = match
else:
matcher |= match
search_query = search_query.query(matcher)
The core is that it does Q('match_phrase' title='firefix', boost=2X) | Q('match_phrase', text='firefix', boost=X).
Here's another arbitrary number. The number 2. It means that the "title" is 2 times more important than the "text".
And that's it! Now every match is scored based on how suggester's score and whether it be matched on the "title" or the "text" (or both). Elasticsearch takes care of everything else. The default is to sort by the _score as ultimately dictated by Lucene.
Match Phrase or Match
In this implementation it tries to match using a match phrase query which basically tries to find matches where every word in the query matches.
The cheap solution here is to basically keep whole search function as is, but if absolutely nothing is found with a match_phrase, and there were multiple words, then just recurse over one more time and do it with a match query instead.
This could probably be improved and do the match_phrase first with higher boost and do the match too but with a lower boost. All in one big query.
Want A Copy?
Note, this copy is quite a mess! It's a personal side-project which is an excuse for experimentation and goofing around.
The full search function is here.
Please don't judge me for the scrappiness of the code but please share your thoughts on this being a decent application of Elasticsearch for smallish datasets like a blog.
07 April 2017
5 comments
Web development,
Linux,
Python
tl;dr; Redis is twice as fast as memcached as a Django cache backend when installed using AWS ElastiCache. Only tested for reads.
Django has a wonderful caching framework. I think I say "wonderful" because it's so simple. Not because it has a hundred different bells or whistles. Each cache gets a name (e.g. "mymemcache" or "redis append only"). The only configuration you generally have to worry about is 1) what backed and 2) what location.
For example, to set up a memcached backend:
# this in settings.py
CACHES = {
'default': {
'BACKEND': 'django.core.cache.backends.memcached.MemcachedCache',
'KEY_PREFIX': 'myapp',
'LOCATION': config('MEMCACHED_LOCATION', '127.0.0.1:11211'),
},
}
With that in play you can now do:
>>> from django.core.cache import caches
>>> caches['default'].set('key', 'value', 60) # 60 seconds
>>> caches['default'].get('key')
'value'
Django comes without built-in backend called django.core.cache.backends.locmem.LocMemCache which is basically a simply Python object in memory with no persistency between Python processes. This one is of course super fast because it involves no further network (local or remote) beyond the process itself. But it's not really useful because if you care about performance (which you probably are if you're here because of the blog post title) because it can't be reused amongst processes.
Anyway, the most common backends to use are:
These are semi-persistent and built for extremely fast key lookups. They can both be reached over TCP or via a socket.
What I wanted to see, is which one is fastest.
The Experiment
First of all, in this blog post I'm only measuring the read times of the various cache backends.
Here's the Django view function that is the experiment:
from django.conf import settings
from django.core.cache import caches
def run(request, cache_name):
if cache_name == 'random':
cache_name = random.choice(settings.CACHE_NAMES)
cache = caches[cache_name]
t0 = time.time()
data = cache.get('benchmarking', [])
t1 = time.time()
if random.random() < settings.WRITE_CHANCE:
data.append(t1 - t0)
cache.set('benchmarking', data, 60)
if data:
avg = 1000 * sum(data) / len(data)
else:
avg = 'notyet'
# print(cache_name, '#', len(data), 'avg:', avg, ' size:', len(str(data)))
return http.HttpResponse('{}\n'.format(avg))
It records the time to make a cache.get read and depending settings.WRITE_CHANCE it also does a write (but doesn't record that).
What it records is a list of floats. The content of that piece of data stored in the cache looks something like this:
[0.0007331371307373047] [0.0007331371307373047, 0.0002570152282714844] [0.0007331371307373047, 0.0002570152282714844, 0.0002200603485107422]
So the data grows from being really small to something really large. If you run this 1,000 times with settings.WRITE_CACHE of 1.0 the last time it has to fetch a list of 999 floats out of the cache backend.
You can either test it with 1 specific backend in mind and see how fast Django can do, say, 10,000 of these. Here's one such example:
$ wrk -t10 -c400 -d10s http://127.0.0.1:8000/default
Running 10s test @ http://127.0.0.1:8000/default
10 threads and 400 connections
Thread Stats Avg Stdev Max +/- Stdev
Latency 76.28ms 155.26ms 1.41s 92.70%
Req/Sec 349.92 193.36 1.51k 79.30%
34107 requests in 10.10s, 2.56MB read
Socket errors: connect 0, read 0, write 0, timeout 59
Requests/sec: 3378.26
Transfer/sec: 259.78KB
$ wrk -t10 -c400 -d10s http://127.0.0.1:8000/memcached
Running 10s test @ http://127.0.0.1:8000/memcached
10 threads and 400 connections
Thread Stats Avg Stdev Max +/- Stdev
Latency 96.87ms 183.16ms 1.81s 95.10%
Req/Sec 213.42 82.47 0.91k 76.08%
21315 requests in 10.09s, 1.57MB read
Socket errors: connect 0, read 0, write 0, timeout 32
Requests/sec: 2111.68
Transfer/sec: 159.27KB
$ wrk -t10 -c400 -d10s http://127.0.0.1:8000/redis
Running 10s test @ http://127.0.0.1:8000/redis
10 threads and 400 connections
Thread Stats Avg Stdev Max +/- Stdev
Latency 84.93ms 148.62ms 1.66s 92.20%
Req/Sec 262.96 138.72 1.10k 81.20%
25271 requests in 10.09s, 1.87MB read
Socket errors: connect 0, read 0, write 0, timeout 15
Requests/sec: 2503.55
Transfer/sec: 189.96KB
But an immediate disadvantage with this is that the "total final rate" (i.e. requests/sec) is likely to include so many other factors. However, you can see that LocMemcache got 3378.26 req/s, MemcachedCache got 2111.68 req/s and RedisCache got 2503.55 req/s.
The code for the experiment is available here: https://github.com/peterbe/django-fastest-cache
The Infra Setup
I created an AWS m3.xlarge EC2 Ubuntu node and two nodes in AWS ElastiCache. One 2-node memcached cluster based on cache.m3.xlarge and one 2-node 1-replica Redis cluster also based on cache.m3.xlarge.
The Django server was run with uWSGI like this:
uwsgi --http :8000 --wsgi-file fastestcache/wsgi.py --master --processes 6 --threads 10
The Results
Instead of hitting one backend repeatedly and reporting the "requests per second" I hit the "random" endpoint for 30 seconds and let it randomly select a cache backend each time and once that's done, I'll read each cache and look at the final massive list of timings it took to make all the reads. I run it like this:
wrk -t10 -c400 -d30s http://127.0.0.1:8000/random && curl http://127.0.0.1:8000/summary
...wrk output redacted...
TIMES AVERAGE MEDIAN STDDEV
memcached 5738 7.523ms 4.828ms 8.195ms
default 3362 0.305ms 0.187ms 1.204ms
redis 4958 3.502ms 1.707ms 5.591ms
Best Averages (shorter better)
###############################################################################
█████████████████████████████████████████████████████████████ 7.523 memcached
██ 0.305 default
████████████████████████████ 3.502 redis
Things to note:
- Redis is twice as fast as memcached.
- Pure Python
LocMemcache is 10 times faster than Redis.
- The table reports average and median. The ASCII bar chart shows only the averages.
- All three backends report huge standard deviations. The median is very different from the average.
- The average is probably the more interesting number since it more reflects the ups and downs of reality.
- If you compare the medians, Redis is 3 times faster than memcached.
- It's luck that Redis got fewer datapoints than memcached (4958 vs 5738) but it's as expected that the
LocMemcache backend only gets 3362 because the uWSGI server that is used is spread across multiple processes.
Other Things To Test
Perhaps pylibmc is faster than python-memcached.
TIMES AVERAGE MEDIAN STDDEV
pylibmc 2893 8.803ms 6.080ms 7.844ms
default 3456 0.315ms 0.181ms 1.656ms
redis 4754 3.697ms 1.786ms 5.784ms
Best Averages (shorter better)
###############################################################################
██████████████████████████████████████████████████████████████ 8.803 pylibmc
██ 0.315 default
██████████████████████████ 3.697 redis
Using pylibmc didn't make things much faster. What if we we pit memcached against pylibmc?:
TIMES AVERAGE MEDIAN STDDEV
pylibmc 3005 8.653ms 5.734ms 8.339ms
memcached 2868 8.465ms 5.367ms 9.065ms
Best Averages (shorter better)
###############################################################################
█████████████████████████████████████████████████████████████ 8.653 pylibmc
███████████████████████████████████████████████████████████ 8.465 memcached
What about that fancy hiredis Redis Python driver that's supposedly faster?
TIMES AVERAGE MEDIAN STDDEV
redis 4074 5.628ms 2.262ms 8.300ms
hiredis 4057 5.566ms 2.296ms 8.471ms
Best Averages (shorter better)
###############################################################################
███████████████████████████████████████████████████████████████ 5.628 redis
██████████████████████████████████████████████████████████████ 5.566 hiredis
These last two results are both surprising and suspicious. Perhaps the whole setup is wrong. Why wouldn't the C-based libraries be faster? Is it so incredibly dwarfed by the network I/O in the time between my EC2 node and the ElastiCache nodes?
In Conclusion
I personally like Redis. It's not as stable as memcached. On a personal server I've run for years the Redis server sometimes just dies due to corrupt memory and I've come to accept that. I don't think I've ever seen memcache do that.
But there are other benefits with Redis as a cache backend. With the django-redis library you have really easy access to the raw Redis connection and you can do much more advanced data structures. You can also cache certain things indefinitely. Redis also supports storing much larger strings than memcached (1MB for memcached and 512MB for Redis).
The conclusion is that Redis is faster than memcached by a factor of 2. Considering the other feature benefits you can get out of having a Redis server available, it's probably a good choice for your next Django project.
Bonus Feature
In big setups you most likely have a whole slur of web heads that are servers that do nothing by handle web requests. And these are configured to talk to databases and caches over the near network. However, so many of us have cheap servers on DigitalOcean or Linode where we run web servers, relational databases and cache servers all on the same machine. (I do. This blog is one of those where there is Nginx, Redis, memcached and PostgreSQL on a 4GB DigitalOcean NYC SSD machine).
So here's one last test where I installed a local Redis and a local memcached on the EC2 node itself:
$ cat .env | grep 127.0.0.1
MEMCACHED_LOCATION="127.0.0.1:11211"
REDIS_LOCATION="redis://127.0.0.1:6379/0"
Here are the results:
TIMES AVERAGE MEDIAN STDDEV
memcached 7366 3.456ms 1.380ms 5.678ms
default 3716 0.263ms 0.189ms 1.002ms
redis 5582 2.334ms 0.639ms 4.965ms
Best Averages (shorter better)
###############################################################################
█████████████████████████████████████████████████████████████ 3.456 memcached
████ 0.263 default
█████████████████████████████████████████ 2.334 redis
The conclusion of that last benchmark is that Redis is still faster and it's roughly 1.8x faster to run these backends on the web head than to use ElastiCache. Perhaps that just goes to show how amazingly fast the AWS inter-datacenter fiber network is!
