multiprocessing.Pool and Rate limit - python

I'm making some API requests which are limited at 20 per second. As to get the answer the waiting time is about 0.5 secs I thought to use multiprocessing.Pool.map and using this decorator
rate-limiting
So my code looks like
def fun(vec):
#do stuff
def RateLimited(maxPerSecond):
minInterval = 1.0 / float(maxPerSecond)
def decorate(func):
lastTimeCalled = [0.0]
def rateLimitedFunction(*args,**kargs):
elapsed = time.clock() - lastTimeCalled[0]
leftToWait = minInterval - elapsed
if leftToWait>0:
time.sleep(leftToWait)
ret = func(*args,**kargs)
lastTimeCalled[0] = time.clock()
return ret
return rateLimitedFunction
return decorate
#RateLimited(20)
def multi(vec):
p = Pool(5)
return p.map(f, vec)
I have 4 cores and this program works fine and there is an improvement in time compared to the loop version. Furthermore, when the Pool argument is 4,5,6 it works and the time is smaller for Pool(6) but when I use 7+ I got errors (Too many connections per second I guess).
Then if my function is more complicated and can do 1-5 requests the decorator doesn't work as expected.
What else I can use in this case?
UPDATE
For anyone looking for use Pool remembers to close it otherwise you are going to use all the RAM
def multi(vec):
p = Pool(5)
res=p.map(f, vec)
p.close()
return res
UPDATE 2
I found that something like this WebRequestManager can do the trick. The problem is that doesn't work with multiprocessing. Pool with 19-20 processes because the time is stored in the class you need to call when you run the request.

Your indents are inconsistent up above which makes it harder to answer this, but I'll take a stab.
It looks like you're rate limiting the wrong thing; if f is supposed be limited, you need to limit the calls to f, not the calls to multi. Doing this in something that's getting dispatched to the Pool won't work, because the forked workers would each be limiting independently (forked processes will have independent tracking of the time since last call).
The easiest way to do this would be to limit how quickly the iterator that the Pool pulls from produces results. For example:
import collections
import time
def rate_limited_iterator(iterable, limit_per_second):
# Initially, we can run immediately limit times
runats = collections.deque([time.time()] * limit_per_second)
for x in iterable:
runat, now = runats.popleft(), time.time()
if now < runat:
time.sleep(runat - now)
runats.append(time.time() + 1)
yield x
def multi(vec):
p = Pool(5)
return p.map(f, rate_limited_iterator(vec, 20))

Related

Best way to use parallel computing within a for-loop in Python [duplicate]

This is probably a trivial question, but how do I parallelize the following loop in python?
# setup output lists
output1 = list()
output2 = list()
output3 = list()
for j in range(0, 10):
# calc individual parameter value
parameter = j * offset
# call the calculation
out1, out2, out3 = calc_stuff(parameter = parameter)
# put results into correct output list
output1.append(out1)
output2.append(out2)
output3.append(out3)
I know how to start single threads in Python but I don't know how to "collect" the results.
Multiple processes would be fine too - whatever is easiest for this case. I'm using currently Linux but the code should run on Windows and Mac as-well.
What's the easiest way to parallelize this code?
Using multiple threads on CPython won't give you better performance for pure-Python code due to the global interpreter lock (GIL). I suggest using the multiprocessing module instead:
pool = multiprocessing.Pool(4)
out1, out2, out3 = zip(*pool.map(calc_stuff, range(0, 10 * offset, offset)))
Note that this won't work in the interactive interpreter.
To avoid the usual FUD around the GIL: There wouldn't be any advantage to using threads for this example anyway. You want to use processes here, not threads, because they avoid a whole bunch of problems.
from joblib import Parallel, delayed
def process(i):
return i * i
results = Parallel(n_jobs=2)(delayed(process)(i) for i in range(10))
print(results) # prints [0, 1, 4, 9, 16, 25, 36, 49, 64, 81]
The above works beautifully on my machine (Ubuntu, package joblib was pre-installed, but can be installed via pip install joblib).
Taken from https://blog.dominodatalab.com/simple-parallelization/
Edit on Mar 31, 2021: On joblib, multiprocessing, threading and asyncio
joblib in the above code uses import multiprocessing under the hood (and thus multiple processes, which is typically the best way to run CPU work across cores - because of the GIL)
You can let joblib use multiple threads instead of multiple processes, but this (or using import threading directly) is only beneficial if the threads spend considerable time on I/O (e.g. read/write to disk, send an HTTP request). For I/O work, the GIL does not block the execution of another thread
Since Python 3.7, as an alternative to threading, you can parallelise work with asyncio, but the same advice applies like for import threading (though in contrast to latter, only 1 thread will be used; on the plus side, asyncio has a lot of nice features which are helpful for async programming)
Using multiple processes incurs overhead. Think about it: Typically, each process needs to initialise/load everything you need to run your calculation. You need to check yourself if the above code snippet improves your wall time. Here is another one, for which I confirmed that joblib produces better results:
import time
from joblib import Parallel, delayed
def countdown(n):
while n>0:
n -= 1
return n
t = time.time()
for _ in range(20):
print(countdown(10**7), end=" ")
print(time.time() - t)
# takes ~10.5 seconds on medium sized Macbook Pro
t = time.time()
results = Parallel(n_jobs=2)(delayed(countdown)(10**7) for _ in range(20))
print(results)
print(time.time() - t)
# takes ~6.3 seconds on medium sized Macbook Pro
To parallelize a simple for loop, joblib brings a lot of value to raw use of multiprocessing. Not only the short syntax, but also things like transparent bunching of iterations when they are very fast (to remove the overhead) or capturing of the traceback of the child process, to have better error reporting.
Disclaimer: I am the original author of joblib.
This IS the easiest way to do it!
You can use asyncio. (Documentation can be found here). It is used as a foundation for multiple Python asynchronous frameworks that provide high-performance network and web-servers, database connection libraries, distributed task queues, etc. Plus it has both high-level and low-level APIs to accomodate any kind of problem.
import asyncio
def background(f):
def wrapped(*args, **kwargs):
return asyncio.get_event_loop().run_in_executor(None, f, *args, **kwargs)
return wrapped
#background
def your_function(argument):
#code
Now this function will be run in parallel whenever called without putting main program into wait state. You can use it to parallelize for loop as well. When called for a for loop, though loop is sequential but every iteration runs in parallel to the main program as soon as interpreter gets there.
1. Firing loop in parallel to main thread without any waiting
#background
def your_function(argument):
time.sleep(5)
print('function finished for '+str(argument))
for i in range(10):
your_function(i)
print('loop finished')
This produces following output:
loop finished
function finished for 4
function finished for 8
function finished for 0
function finished for 3
function finished for 6
function finished for 2
function finished for 5
function finished for 7
function finished for 9
function finished for 1
Update: May 2022
Although this answers the original question, there are ways where we can wait for loops to finish as requested by upvoted comments. So adding them here as well. Keys to implementations are: asyncio.gather() & run_until_complete(). Consider the following functions:
import asyncio
import time
def background(f):
def wrapped(*args, **kwargs):
return asyncio.get_event_loop().run_in_executor(None, f, *args, **kwargs)
return wrapped
#background
def your_function(argument, other_argument): # Added another argument
time.sleep(5)
print(f"function finished for {argument=} and {other_argument=}")
def code_to_run_before():
print('This runs Before Loop!')
def code_to_run_after():
print('This runs After Loop!')
2. Run in parallel but wait for finish
code_to_run_before() # Anything you want to run before, run here!
loop = asyncio.get_event_loop() # Have a new event loop
looper = asyncio.gather(*[your_function(i, 1) for i in range(1, 5)]) # Run the loop
results = loop.run_until_complete(looper) # Wait until finish
code_to_run_after() # Anything you want to run after, run here!
This produces following output:
This runs Before Loop!
function finished for argument=2 and other_argument=1
function finished for argument=3 and other_argument=1
function finished for argument=1 and other_argument=1
function finished for argument=4 and other_argument=1
This runs After Loop!
3. Run multiple loops in parallel and wait for finish
code_to_run_before() # Anything you want to run before, run here!
loop = asyncio.get_event_loop() # Have a new event loop
group1 = asyncio.gather(*[your_function(i, 1) for i in range(1, 2)]) # Run all the loops you want
group2 = asyncio.gather(*[your_function(i, 2) for i in range(3, 5)]) # Run all the loops you want
group3 = asyncio.gather(*[your_function(i, 3) for i in range(6, 9)]) # Run all the loops you want
all_groups = asyncio.gather(group1, group2, group3) # Gather them all
results = loop.run_until_complete(all_groups) # Wait until finish
code_to_run_after() # Anything you want to run after, run here!
This produces following output:
This runs Before Loop!
function finished for argument=3 and other_argument=2
function finished for argument=1 and other_argument=1
function finished for argument=6 and other_argument=3
function finished for argument=4 and other_argument=2
function finished for argument=7 and other_argument=3
function finished for argument=8 and other_argument=3
This runs After Loop!
4. Loops running sequentially but iterations of each loop running in parallel to one another
code_to_run_before() # Anything you want to run before, run here!
for loop_number in range(3):
loop = asyncio.get_event_loop() # Have a new event loop
looper = asyncio.gather(*[your_function(i, loop_number) for i in range(1, 5)]) # Run the loop
results = loop.run_until_complete(looper) # Wait until finish
print(f"finished for {loop_number=}")
code_to_run_after() # Anything you want to run after, run here!
This produces following output:
This runs Before Loop!
function finished for argument=3 and other_argument=0
function finished for argument=4 and other_argument=0
function finished for argument=1 and other_argument=0
function finished for argument=2 and other_argument=0
finished for loop_number=0
function finished for argument=4 and other_argument=1
function finished for argument=3 and other_argument=1
function finished for argument=2 and other_argument=1
function finished for argument=1 and other_argument=1
finished for loop_number=1
function finished for argument=1 and other_argument=2
function finished for argument=4 and other_argument=2
function finished for argument=3 and other_argument=2
function finished for argument=2 and other_argument=2
finished for loop_number=2
This runs After Loop!
Update: June 2022
This in its current form may not run on some versions of jupyter notebook. Reason being jupyter notebook utilizing event loop. To make it work on such jupyter versions, nest_asyncio (which would nest the event loop as evident from the name) is the way to go. Just import and apply it at the top of the cell as:
import nest_asyncio
nest_asyncio.apply()
And all the functionality discussed above should be accessible in a notebook environment as well.
What's the easiest way to parallelize this code?
Use a PoolExecutor from concurrent.futures. Compare the original code with this, side by side. First, the most concise way to approach this is with executor.map:
...
with ProcessPoolExecutor() as executor:
for out1, out2, out3 in executor.map(calc_stuff, parameters):
...
or broken down by submitting each call individually:
...
with ThreadPoolExecutor() as executor:
futures = []
for parameter in parameters:
futures.append(executor.submit(calc_stuff, parameter))
for future in futures:
out1, out2, out3 = future.result() # this will block
...
Leaving the context signals the executor to free up resources
You can use threads or processes and use the exact same interface.
A working example
Here is working example code, that will demonstrate the value of :
Put this in a file - futuretest.py:
from concurrent.futures import ProcessPoolExecutor, ThreadPoolExecutor
from time import time
from http.client import HTTPSConnection
def processor_intensive(arg):
def fib(n): # recursive, processor intensive calculation (avoid n > 36)
return fib(n-1) + fib(n-2) if n > 1 else n
start = time()
result = fib(arg)
return time() - start, result
def io_bound(arg):
start = time()
con = HTTPSConnection(arg)
con.request('GET', '/')
result = con.getresponse().getcode()
return time() - start, result
def manager(PoolExecutor, calc_stuff):
if calc_stuff is io_bound:
inputs = ('python.org', 'stackoverflow.com', 'stackexchange.com',
'noaa.gov', 'parler.com', 'aaronhall.dev')
else:
inputs = range(25, 32)
timings, results = list(), list()
start = time()
with PoolExecutor() as executor:
for timing, result in executor.map(calc_stuff, inputs):
# put results into correct output list:
timings.append(timing), results.append(result)
finish = time()
print(f'{calc_stuff.__name__}, {PoolExecutor.__name__}')
print(f'wall time to execute: {finish-start}')
print(f'total of timings for each call: {sum(timings)}')
print(f'time saved by parallelizing: {sum(timings) - (finish-start)}')
print(dict(zip(inputs, results)), end = '\n\n')
def main():
for computation in (processor_intensive, io_bound):
for pool_executor in (ProcessPoolExecutor, ThreadPoolExecutor):
manager(pool_executor, calc_stuff=computation)
if __name__ == '__main__':
main()
And here's the output for one run of python -m futuretest:
processor_intensive, ProcessPoolExecutor
wall time to execute: 0.7326343059539795
total of timings for each call: 1.8033506870269775
time saved by parallelizing: 1.070716381072998
{25: 75025, 26: 121393, 27: 196418, 28: 317811, 29: 514229, 30: 832040, 31: 1346269}
processor_intensive, ThreadPoolExecutor
wall time to execute: 1.190223217010498
total of timings for each call: 3.3561410903930664
time saved by parallelizing: 2.1659178733825684
{25: 75025, 26: 121393, 27: 196418, 28: 317811, 29: 514229, 30: 832040, 31: 1346269}
io_bound, ProcessPoolExecutor
wall time to execute: 0.533886194229126
total of timings for each call: 1.2977914810180664
time saved by parallelizing: 0.7639052867889404
{'python.org': 301, 'stackoverflow.com': 200, 'stackexchange.com': 200, 'noaa.gov': 301, 'parler.com': 200, 'aaronhall.dev': 200}
io_bound, ThreadPoolExecutor
wall time to execute: 0.38941240310668945
total of timings for each call: 1.6049387454986572
time saved by parallelizing: 1.2155263423919678
{'python.org': 301, 'stackoverflow.com': 200, 'stackexchange.com': 200, 'noaa.gov': 301, 'parler.com': 200, 'aaronhall.dev': 200}
Processor-intensive analysis
When performing processor intensive calculations in Python, expect the ProcessPoolExecutor to be more performant than the ThreadPoolExecutor.
Due to the Global Interpreter Lock (a.k.a. the GIL), threads cannot use multiple processors, so expect the time for each calculation and the wall time (elapsed real time) to be greater.
IO-bound analysis
On the other hand, when performing IO bound operations, expect ThreadPoolExecutor to be more performant than ProcessPoolExecutor.
Python's threads are real, OS, threads. They can be put to sleep by the operating system and reawakened when their information arrives.
Final thoughts
I suspect that multiprocessing will be slower on Windows, since Windows doesn't support forking so each new process has to take time to launch.
You can nest multiple threads inside multiple processes, but it's recommended to not use multiple threads to spin off multiple processes.
If faced with a heavy processing problem in Python, you can trivially scale with additional processes - but not so much with threading.
There are a number of advantages to using Ray:
You can parallelize over multiple machines in addition to multiple cores (with the same code).
Efficient handling of numerical data through shared memory (and zero-copy serialization).
High task throughput with distributed scheduling.
Fault tolerance.
In your case, you could start Ray and define a remote function
import ray
ray.init()
#ray.remote(num_return_vals=3)
def calc_stuff(parameter=None):
# Do something.
return 1, 2, 3
and then invoke it in parallel
output1, output2, output3 = [], [], []
# Launch the tasks.
for j in range(10):
id1, id2, id3 = calc_stuff.remote(parameter=j)
output1.append(id1)
output2.append(id2)
output3.append(id3)
# Block until the results have finished and get the results.
output1 = ray.get(output1)
output2 = ray.get(output2)
output3 = ray.get(output3)
To run the same example on a cluster, the only line that would change would be the call to ray.init(). The relevant documentation can be found here.
Note that I'm helping to develop Ray.
I found joblib is very useful with me. Please see following example:
from joblib import Parallel, delayed
def yourfunction(k):
s=3.14*k*k
print "Area of a circle with a radius ", k, " is:", s
element_run = Parallel(n_jobs=-1)(delayed(yourfunction)(k) for k in range(1,10))
n_jobs=-1: use all available cores
Dask futures; I'm surprised no one has mentioned it yet . . .
from dask.distributed import Client
client = Client(n_workers=8) # In this example I have 8 cores and processes (can also use threads if desired)
def my_function(i):
output = <code to execute in the for loop here>
return output
futures = []
for i in <whatever you want to loop across here>:
future = client.submit(my_function, i)
futures.append(future)
results = client.gather(futures)
client.close()
why dont you use threads, and one mutex to protect one global list?
import os
import re
import time
import sys
import thread
from threading import Thread
class thread_it(Thread):
def __init__ (self,param):
Thread.__init__(self)
self.param = param
def run(self):
mutex.acquire()
output.append(calc_stuff(self.param))
mutex.release()
threads = []
output = []
mutex = thread.allocate_lock()
for j in range(0, 10):
current = thread_it(j * offset)
threads.append(current)
current.start()
for t in threads:
t.join()
#here you have output list filled with data
keep in mind, you will be as fast as your slowest thread
thanks #iuryxavier
from multiprocessing import Pool
from multiprocessing import cpu_count
def add_1(x):
return x + 1
if __name__ == "__main__":
pool = Pool(cpu_count())
results = pool.map(add_1, range(10**12))
pool.close() # 'TERM'
pool.join() # 'KILL'
The concurrent wrappers by the tqdm library are a nice way to parallelize longer-running code. tqdm provides feedback on the current progress and remaining time through a smart progress meter, which I find very useful for long computations.
Loops can be rewritten to run as concurrent threads through a simple call to thread_map, or as concurrent multi-processes through a simple call to process_map:
from tqdm.contrib.concurrent import thread_map, process_map
def calc_stuff(num, multiplier):
import time
time.sleep(1)
return num, num * multiplier
if __name__ == "__main__":
# let's parallelize this for loop:
# results = [calc_stuff(i, 2) for i in range(64)]
loop_idx = range(64)
multiplier = [2] * len(loop_idx)
# either with threading:
results_threading = thread_map(calc_stuff, loop_idx, multiplier)
# or with multi-processing:
results_processes = process_map(calc_stuff, loop_idx, multiplier)
Let's say we have an async function
async def work_async(self, student_name: str, code: str, loop):
"""
Some async function
"""
# Do some async procesing
That needs to be run on a large array. Some attributes are being passed to the program and some are used from property of dictionary element in the array.
async def process_students(self, student_name: str, loop):
market = sys.argv[2]
subjects = [...] #Some large array
batchsize = 5
for i in range(0, len(subjects), batchsize):
batch = subjects[i:i+batchsize]
await asyncio.gather(*(self.work_async(student_name,
sub['Code'],
loop)
for sub in batch))
This could be useful when implementing multiprocessing and parallel/ distributed computing in Python.
YouTube tutorial on using techila package
Techila is a distributed computing middleware, which integrates directly with Python using the techila package. The peach function in the package can be useful in parallelizing loop structures. (Following code snippet is from the Techila Community Forums)
techila.peach(funcname = 'theheavyalgorithm', # Function that will be called on the compute nodes/ Workers
files = 'theheavyalgorithm.py', # Python-file that will be sourced on Workers
jobs = jobcount # Number of Jobs in the Project
)
Have a look at this;
http://docs.python.org/library/queue.html
This might not be the right way to do it, but I'd do something like;
Actual code;
from multiprocessing import Process, JoinableQueue as Queue
class CustomWorker(Process):
def __init__(self,workQueue, out1,out2,out3):
Process.__init__(self)
self.input=workQueue
self.out1=out1
self.out2=out2
self.out3=out3
def run(self):
while True:
try:
value = self.input.get()
#value modifier
temp1,temp2,temp3 = self.calc_stuff(value)
self.out1.put(temp1)
self.out2.put(temp2)
self.out3.put(temp3)
self.input.task_done()
except Queue.Empty:
return
#Catch things better here
def calc_stuff(self,param):
out1 = param * 2
out2 = param * 4
out3 = param * 8
return out1,out2,out3
def Main():
inputQueue = Queue()
for i in range(10):
inputQueue.put(i)
out1 = Queue()
out2 = Queue()
out3 = Queue()
processes = []
for x in range(2):
p = CustomWorker(inputQueue,out1,out2,out3)
p.daemon = True
p.start()
processes.append(p)
inputQueue.join()
while(not out1.empty()):
print out1.get()
print out2.get()
print out3.get()
if __name__ == '__main__':
Main()
Hope that helps.
very simple example of parallel processing is
from multiprocessing import Process
output1 = list()
output2 = list()
output3 = list()
def yourfunction():
for j in range(0, 10):
# calc individual parameter value
parameter = j * offset
# call the calculation
out1, out2, out3 = calc_stuff(parameter=parameter)
# put results into correct output list
output1.append(out1)
output2.append(out2)
output3.append(out3)
if __name__ == '__main__':
p = Process(target=pa.yourfunction, args=('bob',))
p.start()
p.join()

How to get end of process time per processor using "pool" in Python?

I use Multiprocessing library in Python to distribute a function over multiple cores. To do that I use "Pool" function, but I want to know when each processor has completed its work.
Here is the code :
def parallel(m,G):
D=0
for i in xrange(G):
D+=random()
return 1*(D<1)
pool=Pool()
TOTAL=0
for i in xrange(10):
TOTAL += sum(pool.map(partial(parallel,G=2),xrange(100)))
print TOTAL
I know how to use time.time() in normal situation, but what I need is to know when each core has completed is part of the job. If I put a time stamp directly in the function I will get many time values without knowing on what core it is processed.
Any advice is welcome!
You may return the completion time along with the actual result from parallel and then pick the last timestamp for each worker.
import time
from random import random
from functools import partial
from multiprocessing import Pool, current_process
def parallel(m, G):
D = 0
for i in xrange(G):
D += random()
# uncomment to give the other workers more chances to run
# time.sleep(.001)
return (current_process().name, time.time()), 1 * (D < 1)
# don't deny the existence of Windows
if __name__ == '__main__':
pool = Pool()
TOTAL = 0
proc_times = {}
for i in xrange(5):
# times is a list of proc_name:timestamp pairs
times, results = zip(*pool.map(partial(parallel, G=2), xrange(100)))
TOTAL += sum(results)
# process_times_loc is guaranteed to hold the last timestamp
# for each proc_name, see the doc on dict
proc_times_loc = dict(times)
print 'local completion times:', proc_times_loc
proc_times.update(proc_times_loc)
print TOTAL
print 'total completion times:', proc_times
However when jobs are that simple you may find that calling time.time each time consumes too much of CPU time.)

Using threading/multiprocessing in python to do multiple calculations at the same time

I have a list of numbers. I want to perform some time-consuming operation on each number in the list and make a new list with all the results. Here's a simplified version of what I have:
def calcNum(n):#some arbitrary, time-consuming calculation on a number
m = n
for i in range(5000000):
m += i%25
if m > n*n:
m /= 2
return m
nums = [12,25,76,38,8,2,5]
finList = []
for i in nums:
return_val = calcNum(i)
finList.append(return_val)
print(finList)
Now, I wanted to take advantage of the multiple cores in my CPU, and give each of them a task of processing one of the numbers, and since the "number calculation" function is self-contained from start to finish I figured this would be fairly simple to do and a perfect situation for multiprocessing/threading.
My question is, which one should I use (multiprocessing or threading?), and what is the simplest way to do this?
I did a test with various code I found in other questions to achieve this, and while it runs fine it doesn't seem to be doing any actual multithreading/processing and takes just as long as my first test:
from multiprocessing.pool import ThreadPool
def calcNum(n):#some arbitrary, time-consuming calculation on a number
m = n
for i in range(5000000):
m += i%25
if m > n*n:
m /= 2
return m
pool = ThreadPool(processes=3)
nums = [12,25,76,38,8,2,5]
finList = []
for i in nums:
async_result = pool.apply_async(calcNum, (i,))
return_val = async_result.get()
finList.append(return_val)
print(finList)
multiprocessing.pool and pool.map are your best friends here. It saves a lot of headache as it hides all the other complex queues and whatnot you need to make it work. All you need to do is set up the pool, assign it the max number of processes, point it to the function and iterable. See working code below.
Because of the join and the usage cases pool.map was intended to work, the program will wait until ALL processes have returned something before giving you the result.
from multiprocessing.pool import Pool
def calcNum(n):#some arbitrary, time-consuming calculation on a number
print "Calcs Started on ", n
m = n
for i in range(5000000):
m += i%25
if m > n*n:
m /= 2
return m
if __name__ == "__main__":
p = Pool(processes=3)
nums = [12,25,76,38,8,2,5]
finList = []
result = p.map(calcNum, nums)
p.close()
p.join()
print result
That will get you something like this:
Calcs Started on 12
Calcs Started on 25
Calcs Started on 76
Calcs Started on 38
Calcs Started on 8
Calcs Started on 2
Calcs Started on 5
[72, 562, 5123, 1270, 43, 23, 23]
Regardless of when each process is started or when it completes, map waits for each to finish and then puts them all back in the correct order (corresponding to the input iterable).
As #Guy mentioned, the GIL hurts us here. You can change the Pool to ThreadPool in the code above and see how it affects the timing of the calculations. Since the same function is used, the GIL only allows one thread to use the calcNum function at a time. So it near enough still runs serially.
Multirocessing with a process or pool essentially starts further instances of your script which gets around the issue of the GIL. If you watch your running processes during the above, you'll see extra instances of 'python.exe' start while the pool is running. In this case, you'll see a total of 4.
I guess you are affected by python Global Interpreter Lock
The GIL is controversial because it prevents multithreaded CPython programs from taking full advantage of multiprocessor systems in certain situations.
try to use multiprocessing instead
from multiprocessing import Pool

Proper way to use multiprocessor.Pool in a nested loop

I am using the multiprocessor.Pool() module to speed up an "embarrassingly parallel" loop. I actually have a nested loop, and am using multiprocessor.Pool to speed up the inner loop. For example, without parallelizing the loop, my code would be as follows:
outer_array=[random_array1]
inner_array=[random_array2]
output=[empty_array]
for i in outer_array:
for j in inner_array:
output[j][i]=full_func(j,i)
With parallelizing:
import multiprocessing
from functools import partial
outer_array=[random_array1]
inner_array=[random_array2]
output=[empty_array]
for i in outer_array:
partial_func=partial(full_func,arg=i)
pool=multiprocessing.Pool()
output[:][i]=pool.map(partial_func,inner_array)
pool.close()
My main question is if this is the correct, and I should be including the multiprocessing.Pool() inside the loop, or if instead I should create the pool outside loop, i.e.:
pool=multiprocessing.Pool()
for i in outer_array:
partial_func=partial(full_func,arg=i)
output[:][i]=pool.map(partial_func,inner_array)
Also, I am not sure if I should include the line "pool.close()" at the end of each loop in the second example above; what would be the benefits of doing so?
Thanks!
Ideally, you should call the Pool() constructor exactly once - not over & over again. There are substantial overheads when creating worker processes, and you pay those costs every time you invoke Pool(). The processes created by a single Pool() call stay around! When they finish the work you've given to them in one part of the program, they stick around, waiting for more work to do.
As to Pool.close(), you should call that when - and only when - you're never going to submit more work to the Pool instance. So Pool.close() is typically called when the parallelizable part of your main program is finished. Then the worker processes will terminate when all work already assigned has completed.
It's also excellent practice to call Pool.join() to wait for the worker processes to terminate. Among other reasons, there's often no good way to report exceptions in parallelized code (exceptions occur in a context only vaguely related to what your main program is doing), and Pool.join() provides a synchronization point that can report some exceptions that occurred in worker processes that you'd otherwise never see.
Have fun :-)
import itertools
import multiprocessing as mp
def job(params):
a = params[0]
b = params[1]
return a*b
def multicore():
a = range(1000)
b = range(2000)
paramlist = list(itertools.product(a,b))
print(paramlist[0])
pool = mp.Pool(processes = 4)
res=pool.map(job, paramlist)
for i in res:
print(i)
if __name__=='__main__':
multicore()
how about this?
import time
from pathos.parallel import stats
from pathos.parallel import ParallelPool as Pool
def work(x, y):
return x * y
pool = Pool(5)
pool.ncpus = 4
pool.servers = ('localhost:5654',)
t1 = time.time()
results = pool.imap(work, range(1, 2), range(1, 11))
print("INFO: List is: %s" % list(results))
print(stats())
t2 = time.time()
print("TIMER: Function completed time is: %.5f" % (t2 - t1))

How do I parallelize a simple Python loop?

This is probably a trivial question, but how do I parallelize the following loop in python?
# setup output lists
output1 = list()
output2 = list()
output3 = list()
for j in range(0, 10):
# calc individual parameter value
parameter = j * offset
# call the calculation
out1, out2, out3 = calc_stuff(parameter = parameter)
# put results into correct output list
output1.append(out1)
output2.append(out2)
output3.append(out3)
I know how to start single threads in Python but I don't know how to "collect" the results.
Multiple processes would be fine too - whatever is easiest for this case. I'm using currently Linux but the code should run on Windows and Mac as-well.
What's the easiest way to parallelize this code?
Using multiple threads on CPython won't give you better performance for pure-Python code due to the global interpreter lock (GIL). I suggest using the multiprocessing module instead:
pool = multiprocessing.Pool(4)
out1, out2, out3 = zip(*pool.map(calc_stuff, range(0, 10 * offset, offset)))
Note that this won't work in the interactive interpreter.
To avoid the usual FUD around the GIL: There wouldn't be any advantage to using threads for this example anyway. You want to use processes here, not threads, because they avoid a whole bunch of problems.
from joblib import Parallel, delayed
def process(i):
return i * i
results = Parallel(n_jobs=2)(delayed(process)(i) for i in range(10))
print(results) # prints [0, 1, 4, 9, 16, 25, 36, 49, 64, 81]
The above works beautifully on my machine (Ubuntu, package joblib was pre-installed, but can be installed via pip install joblib).
Taken from https://blog.dominodatalab.com/simple-parallelization/
Edit on Mar 31, 2021: On joblib, multiprocessing, threading and asyncio
joblib in the above code uses import multiprocessing under the hood (and thus multiple processes, which is typically the best way to run CPU work across cores - because of the GIL)
You can let joblib use multiple threads instead of multiple processes, but this (or using import threading directly) is only beneficial if the threads spend considerable time on I/O (e.g. read/write to disk, send an HTTP request). For I/O work, the GIL does not block the execution of another thread
Since Python 3.7, as an alternative to threading, you can parallelise work with asyncio, but the same advice applies like for import threading (though in contrast to latter, only 1 thread will be used; on the plus side, asyncio has a lot of nice features which are helpful for async programming)
Using multiple processes incurs overhead. Think about it: Typically, each process needs to initialise/load everything you need to run your calculation. You need to check yourself if the above code snippet improves your wall time. Here is another one, for which I confirmed that joblib produces better results:
import time
from joblib import Parallel, delayed
def countdown(n):
while n>0:
n -= 1
return n
t = time.time()
for _ in range(20):
print(countdown(10**7), end=" ")
print(time.time() - t)
# takes ~10.5 seconds on medium sized Macbook Pro
t = time.time()
results = Parallel(n_jobs=2)(delayed(countdown)(10**7) for _ in range(20))
print(results)
print(time.time() - t)
# takes ~6.3 seconds on medium sized Macbook Pro
To parallelize a simple for loop, joblib brings a lot of value to raw use of multiprocessing. Not only the short syntax, but also things like transparent bunching of iterations when they are very fast (to remove the overhead) or capturing of the traceback of the child process, to have better error reporting.
Disclaimer: I am the original author of joblib.
This IS the easiest way to do it!
You can use asyncio. (Documentation can be found here). It is used as a foundation for multiple Python asynchronous frameworks that provide high-performance network and web-servers, database connection libraries, distributed task queues, etc. Plus it has both high-level and low-level APIs to accomodate any kind of problem.
import asyncio
def background(f):
def wrapped(*args, **kwargs):
return asyncio.get_event_loop().run_in_executor(None, f, *args, **kwargs)
return wrapped
#background
def your_function(argument):
#code
Now this function will be run in parallel whenever called without putting main program into wait state. You can use it to parallelize for loop as well. When called for a for loop, though loop is sequential but every iteration runs in parallel to the main program as soon as interpreter gets there.
1. Firing loop in parallel to main thread without any waiting
#background
def your_function(argument):
time.sleep(5)
print('function finished for '+str(argument))
for i in range(10):
your_function(i)
print('loop finished')
This produces following output:
loop finished
function finished for 4
function finished for 8
function finished for 0
function finished for 3
function finished for 6
function finished for 2
function finished for 5
function finished for 7
function finished for 9
function finished for 1
Update: May 2022
Although this answers the original question, there are ways where we can wait for loops to finish as requested by upvoted comments. So adding them here as well. Keys to implementations are: asyncio.gather() & run_until_complete(). Consider the following functions:
import asyncio
import time
def background(f):
def wrapped(*args, **kwargs):
return asyncio.get_event_loop().run_in_executor(None, f, *args, **kwargs)
return wrapped
#background
def your_function(argument, other_argument): # Added another argument
time.sleep(5)
print(f"function finished for {argument=} and {other_argument=}")
def code_to_run_before():
print('This runs Before Loop!')
def code_to_run_after():
print('This runs After Loop!')
2. Run in parallel but wait for finish
code_to_run_before() # Anything you want to run before, run here!
loop = asyncio.get_event_loop() # Have a new event loop
looper = asyncio.gather(*[your_function(i, 1) for i in range(1, 5)]) # Run the loop
results = loop.run_until_complete(looper) # Wait until finish
code_to_run_after() # Anything you want to run after, run here!
This produces following output:
This runs Before Loop!
function finished for argument=2 and other_argument=1
function finished for argument=3 and other_argument=1
function finished for argument=1 and other_argument=1
function finished for argument=4 and other_argument=1
This runs After Loop!
3. Run multiple loops in parallel and wait for finish
code_to_run_before() # Anything you want to run before, run here!
loop = asyncio.get_event_loop() # Have a new event loop
group1 = asyncio.gather(*[your_function(i, 1) for i in range(1, 2)]) # Run all the loops you want
group2 = asyncio.gather(*[your_function(i, 2) for i in range(3, 5)]) # Run all the loops you want
group3 = asyncio.gather(*[your_function(i, 3) for i in range(6, 9)]) # Run all the loops you want
all_groups = asyncio.gather(group1, group2, group3) # Gather them all
results = loop.run_until_complete(all_groups) # Wait until finish
code_to_run_after() # Anything you want to run after, run here!
This produces following output:
This runs Before Loop!
function finished for argument=3 and other_argument=2
function finished for argument=1 and other_argument=1
function finished for argument=6 and other_argument=3
function finished for argument=4 and other_argument=2
function finished for argument=7 and other_argument=3
function finished for argument=8 and other_argument=3
This runs After Loop!
4. Loops running sequentially but iterations of each loop running in parallel to one another
code_to_run_before() # Anything you want to run before, run here!
for loop_number in range(3):
loop = asyncio.get_event_loop() # Have a new event loop
looper = asyncio.gather(*[your_function(i, loop_number) for i in range(1, 5)]) # Run the loop
results = loop.run_until_complete(looper) # Wait until finish
print(f"finished for {loop_number=}")
code_to_run_after() # Anything you want to run after, run here!
This produces following output:
This runs Before Loop!
function finished for argument=3 and other_argument=0
function finished for argument=4 and other_argument=0
function finished for argument=1 and other_argument=0
function finished for argument=2 and other_argument=0
finished for loop_number=0
function finished for argument=4 and other_argument=1
function finished for argument=3 and other_argument=1
function finished for argument=2 and other_argument=1
function finished for argument=1 and other_argument=1
finished for loop_number=1
function finished for argument=1 and other_argument=2
function finished for argument=4 and other_argument=2
function finished for argument=3 and other_argument=2
function finished for argument=2 and other_argument=2
finished for loop_number=2
This runs After Loop!
Update: June 2022
This in its current form may not run on some versions of jupyter notebook. Reason being jupyter notebook utilizing event loop. To make it work on such jupyter versions, nest_asyncio (which would nest the event loop as evident from the name) is the way to go. Just import and apply it at the top of the cell as:
import nest_asyncio
nest_asyncio.apply()
And all the functionality discussed above should be accessible in a notebook environment as well.
What's the easiest way to parallelize this code?
Use a PoolExecutor from concurrent.futures. Compare the original code with this, side by side. First, the most concise way to approach this is with executor.map:
...
with ProcessPoolExecutor() as executor:
for out1, out2, out3 in executor.map(calc_stuff, parameters):
...
or broken down by submitting each call individually:
...
with ThreadPoolExecutor() as executor:
futures = []
for parameter in parameters:
futures.append(executor.submit(calc_stuff, parameter))
for future in futures:
out1, out2, out3 = future.result() # this will block
...
Leaving the context signals the executor to free up resources
You can use threads or processes and use the exact same interface.
A working example
Here is working example code, that will demonstrate the value of :
Put this in a file - futuretest.py:
from concurrent.futures import ProcessPoolExecutor, ThreadPoolExecutor
from time import time
from http.client import HTTPSConnection
def processor_intensive(arg):
def fib(n): # recursive, processor intensive calculation (avoid n > 36)
return fib(n-1) + fib(n-2) if n > 1 else n
start = time()
result = fib(arg)
return time() - start, result
def io_bound(arg):
start = time()
con = HTTPSConnection(arg)
con.request('GET', '/')
result = con.getresponse().getcode()
return time() - start, result
def manager(PoolExecutor, calc_stuff):
if calc_stuff is io_bound:
inputs = ('python.org', 'stackoverflow.com', 'stackexchange.com',
'noaa.gov', 'parler.com', 'aaronhall.dev')
else:
inputs = range(25, 32)
timings, results = list(), list()
start = time()
with PoolExecutor() as executor:
for timing, result in executor.map(calc_stuff, inputs):
# put results into correct output list:
timings.append(timing), results.append(result)
finish = time()
print(f'{calc_stuff.__name__}, {PoolExecutor.__name__}')
print(f'wall time to execute: {finish-start}')
print(f'total of timings for each call: {sum(timings)}')
print(f'time saved by parallelizing: {sum(timings) - (finish-start)}')
print(dict(zip(inputs, results)), end = '\n\n')
def main():
for computation in (processor_intensive, io_bound):
for pool_executor in (ProcessPoolExecutor, ThreadPoolExecutor):
manager(pool_executor, calc_stuff=computation)
if __name__ == '__main__':
main()
And here's the output for one run of python -m futuretest:
processor_intensive, ProcessPoolExecutor
wall time to execute: 0.7326343059539795
total of timings for each call: 1.8033506870269775
time saved by parallelizing: 1.070716381072998
{25: 75025, 26: 121393, 27: 196418, 28: 317811, 29: 514229, 30: 832040, 31: 1346269}
processor_intensive, ThreadPoolExecutor
wall time to execute: 1.190223217010498
total of timings for each call: 3.3561410903930664
time saved by parallelizing: 2.1659178733825684
{25: 75025, 26: 121393, 27: 196418, 28: 317811, 29: 514229, 30: 832040, 31: 1346269}
io_bound, ProcessPoolExecutor
wall time to execute: 0.533886194229126
total of timings for each call: 1.2977914810180664
time saved by parallelizing: 0.7639052867889404
{'python.org': 301, 'stackoverflow.com': 200, 'stackexchange.com': 200, 'noaa.gov': 301, 'parler.com': 200, 'aaronhall.dev': 200}
io_bound, ThreadPoolExecutor
wall time to execute: 0.38941240310668945
total of timings for each call: 1.6049387454986572
time saved by parallelizing: 1.2155263423919678
{'python.org': 301, 'stackoverflow.com': 200, 'stackexchange.com': 200, 'noaa.gov': 301, 'parler.com': 200, 'aaronhall.dev': 200}
Processor-intensive analysis
When performing processor intensive calculations in Python, expect the ProcessPoolExecutor to be more performant than the ThreadPoolExecutor.
Due to the Global Interpreter Lock (a.k.a. the GIL), threads cannot use multiple processors, so expect the time for each calculation and the wall time (elapsed real time) to be greater.
IO-bound analysis
On the other hand, when performing IO bound operations, expect ThreadPoolExecutor to be more performant than ProcessPoolExecutor.
Python's threads are real, OS, threads. They can be put to sleep by the operating system and reawakened when their information arrives.
Final thoughts
I suspect that multiprocessing will be slower on Windows, since Windows doesn't support forking so each new process has to take time to launch.
You can nest multiple threads inside multiple processes, but it's recommended to not use multiple threads to spin off multiple processes.
If faced with a heavy processing problem in Python, you can trivially scale with additional processes - but not so much with threading.
There are a number of advantages to using Ray:
You can parallelize over multiple machines in addition to multiple cores (with the same code).
Efficient handling of numerical data through shared memory (and zero-copy serialization).
High task throughput with distributed scheduling.
Fault tolerance.
In your case, you could start Ray and define a remote function
import ray
ray.init()
#ray.remote(num_return_vals=3)
def calc_stuff(parameter=None):
# Do something.
return 1, 2, 3
and then invoke it in parallel
output1, output2, output3 = [], [], []
# Launch the tasks.
for j in range(10):
id1, id2, id3 = calc_stuff.remote(parameter=j)
output1.append(id1)
output2.append(id2)
output3.append(id3)
# Block until the results have finished and get the results.
output1 = ray.get(output1)
output2 = ray.get(output2)
output3 = ray.get(output3)
To run the same example on a cluster, the only line that would change would be the call to ray.init(). The relevant documentation can be found here.
Note that I'm helping to develop Ray.
I found joblib is very useful with me. Please see following example:
from joblib import Parallel, delayed
def yourfunction(k):
s=3.14*k*k
print "Area of a circle with a radius ", k, " is:", s
element_run = Parallel(n_jobs=-1)(delayed(yourfunction)(k) for k in range(1,10))
n_jobs=-1: use all available cores
Dask futures; I'm surprised no one has mentioned it yet . . .
from dask.distributed import Client
client = Client(n_workers=8) # In this example I have 8 cores and processes (can also use threads if desired)
def my_function(i):
output = <code to execute in the for loop here>
return output
futures = []
for i in <whatever you want to loop across here>:
future = client.submit(my_function, i)
futures.append(future)
results = client.gather(futures)
client.close()
why dont you use threads, and one mutex to protect one global list?
import os
import re
import time
import sys
import thread
from threading import Thread
class thread_it(Thread):
def __init__ (self,param):
Thread.__init__(self)
self.param = param
def run(self):
mutex.acquire()
output.append(calc_stuff(self.param))
mutex.release()
threads = []
output = []
mutex = thread.allocate_lock()
for j in range(0, 10):
current = thread_it(j * offset)
threads.append(current)
current.start()
for t in threads:
t.join()
#here you have output list filled with data
keep in mind, you will be as fast as your slowest thread
thanks #iuryxavier
from multiprocessing import Pool
from multiprocessing import cpu_count
def add_1(x):
return x + 1
if __name__ == "__main__":
pool = Pool(cpu_count())
results = pool.map(add_1, range(10**12))
pool.close() # 'TERM'
pool.join() # 'KILL'
The concurrent wrappers by the tqdm library are a nice way to parallelize longer-running code. tqdm provides feedback on the current progress and remaining time through a smart progress meter, which I find very useful for long computations.
Loops can be rewritten to run as concurrent threads through a simple call to thread_map, or as concurrent multi-processes through a simple call to process_map:
from tqdm.contrib.concurrent import thread_map, process_map
def calc_stuff(num, multiplier):
import time
time.sleep(1)
return num, num * multiplier
if __name__ == "__main__":
# let's parallelize this for loop:
# results = [calc_stuff(i, 2) for i in range(64)]
loop_idx = range(64)
multiplier = [2] * len(loop_idx)
# either with threading:
results_threading = thread_map(calc_stuff, loop_idx, multiplier)
# or with multi-processing:
results_processes = process_map(calc_stuff, loop_idx, multiplier)
Let's say we have an async function
async def work_async(self, student_name: str, code: str, loop):
"""
Some async function
"""
# Do some async procesing
That needs to be run on a large array. Some attributes are being passed to the program and some are used from property of dictionary element in the array.
async def process_students(self, student_name: str, loop):
market = sys.argv[2]
subjects = [...] #Some large array
batchsize = 5
for i in range(0, len(subjects), batchsize):
batch = subjects[i:i+batchsize]
await asyncio.gather(*(self.work_async(student_name,
sub['Code'],
loop)
for sub in batch))
This could be useful when implementing multiprocessing and parallel/ distributed computing in Python.
YouTube tutorial on using techila package
Techila is a distributed computing middleware, which integrates directly with Python using the techila package. The peach function in the package can be useful in parallelizing loop structures. (Following code snippet is from the Techila Community Forums)
techila.peach(funcname = 'theheavyalgorithm', # Function that will be called on the compute nodes/ Workers
files = 'theheavyalgorithm.py', # Python-file that will be sourced on Workers
jobs = jobcount # Number of Jobs in the Project
)
Have a look at this;
http://docs.python.org/library/queue.html
This might not be the right way to do it, but I'd do something like;
Actual code;
from multiprocessing import Process, JoinableQueue as Queue
class CustomWorker(Process):
def __init__(self,workQueue, out1,out2,out3):
Process.__init__(self)
self.input=workQueue
self.out1=out1
self.out2=out2
self.out3=out3
def run(self):
while True:
try:
value = self.input.get()
#value modifier
temp1,temp2,temp3 = self.calc_stuff(value)
self.out1.put(temp1)
self.out2.put(temp2)
self.out3.put(temp3)
self.input.task_done()
except Queue.Empty:
return
#Catch things better here
def calc_stuff(self,param):
out1 = param * 2
out2 = param * 4
out3 = param * 8
return out1,out2,out3
def Main():
inputQueue = Queue()
for i in range(10):
inputQueue.put(i)
out1 = Queue()
out2 = Queue()
out3 = Queue()
processes = []
for x in range(2):
p = CustomWorker(inputQueue,out1,out2,out3)
p.daemon = True
p.start()
processes.append(p)
inputQueue.join()
while(not out1.empty()):
print out1.get()
print out2.get()
print out3.get()
if __name__ == '__main__':
Main()
Hope that helps.
very simple example of parallel processing is
from multiprocessing import Process
output1 = list()
output2 = list()
output3 = list()
def yourfunction():
for j in range(0, 10):
# calc individual parameter value
parameter = j * offset
# call the calculation
out1, out2, out3 = calc_stuff(parameter=parameter)
# put results into correct output list
output1.append(out1)
output2.append(out2)
output3.append(out3)
if __name__ == '__main__':
p = Process(target=pa.yourfunction, args=('bob',))
p.start()
p.join()

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