I am using multiprocessing.Pool.imap to run many independent jobs in parallel using Python 2.7 on Windows 7. With the default settings, my total CPU usage is pegged at 100%, as measured by Windows Task Manager. This makes it impossible to do any other work while my code runs in the background.

I've tried limiting the number of processes to be the number of CPUs minus 1, as described in How to limit the number of processors that Python uses:

pool = Pool(processes=max(multiprocessing.cpu_count()-1, 1)
for p in pool.imap(func, iterable):

This does reduce the total number of running processes. However, each process just takes up more cycles to make up for it. So my total CPU usage is still pegged at 100%.

Is there a way to directly limit the total CPU usage - NOT just the number of processes - or failing that, is there any workaround?

  • 1
    Removing 1 core isn't enough. Because of the GIL, python only consumes 1 core's worth of processing time unless you are doing something threaded outside of the GIL in a module (e.g., numpy) or subprocesses. But the main process may not be completely idle and Windows itself is something of a hog. Depending on what what your code does and what else is running on the system, 2/3 of the CPUs is probably max. – tdelaney Feb 8 '17 at 5:30
  • 1
    You can lower process priority with win32 tools (example) or using the psutil Process.nice. You still get 100% usage but its less intrusive. You still want to run fewer than all of the cores. – tdelaney Feb 8 '17 at 5:30
  • @tdelaney thanks, those are helpful hints! If you feel like posting a code example that combines pool and psutil, that would certainly be a great answer to the question! – Dave Kielpinski Feb 8 '17 at 22:54

The solution depends on what you want to do. Here are a few options:

Lower priorities of processes

You can nice the subprocesses. This way, though they will still eat 100% of the CPU, when you start other applications, the OS gives preference to the other applications. If you want to leave a work intensive computation run on the background of your laptop and don't care about the CPU fan running all the time, then setting the nice value with psutils is your solution. This script is a test script which runs on all cores for enough time so you can see how it behaves.

from multiprocessing import Pool, cpu_count
import math
import psutil
import os

def f(i):
    return math.sqrt(i)

def limit_cpu():
    "is called at every process start"
    p = psutil.Process(os.getpid())
    # set to lowest priority, this is windows only, on Unix use ps.nice(19)

if __name__ == '__main__':
    # start "number of cores" processes
    pool = Pool(None, limit_cpu)
    for p in pool.imap(f, range(10**8)):

The trick is that limit_cpu is run at the beginning of every process (see initializer argment in the doc). Whereas Unix has levels -19 (highest prio) to 19 (lowest prio), Windows has a few distinct levels for giving priority. BELOW_NORMAL_PRIORITY_CLASS probably fits your requirements best, there is also IDLE_PRIORITY_CLASS which says Windows to run your process only when the system is idle.

You can view the priority if you switch to detail mode in Task Manager and right click on the process:

enter image description here

Lower number of processes

Although you have rejected this option it still might be a good option: Say you limit the number of subprocesses to half the cpu cores using pool = Pool(max(cpu_count()//2, 1)) then the OS initially runs those processes on half the cpu cores, while the others stay idle or just run the other applications currently running. After a short time, the OS reschedules the processes and might move them to other cpu cores etc. Both Windows as Unix based systems behave this way.

Windows: Running 2 processes on 4 cores:

OSX: Running 4 processes on 8 cores:

enter image description here

You see that both OS balance the process between the cores, although not evenly so you still see a few cores with higher percentages than others.


If you absolutely want to go sure, that your processes never eat 100% of a certain core (e.g. if you want to prevent that the cpu fan goes up), then you can run sleep in your processing function:

from time import sleep

def f(i):
    return math.sqrt(i)

This makes the OS "schedule out" your process for 0.01 seconds for each computation and makes room for other applications. If there are no other applications, then the cpu core is idle, thus it will never go to 100%. You'll need to play around with different sleep durations, it will also vary from computer to computer you run it on. If you want to make it very sophisticated you could adapt the sleep depending on what cpu_times() reports.

  • This is extremely helpful! The only reason I am not accepting it as the answer is because my question is Windows-specific, and you primarily address Linux and OSX. – Dave Kielpinski Feb 9 '17 at 17:54
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    @DaveKielpinski I haven't had time to dig into the windows implementation, but it looks like p.nice(psutil.BELOW_NORMAL_PRIORITY_CLASS) would be what you want. – tdelaney Feb 9 '17 at 19:45
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    @DaveKielpinski quick answer: psutil promises to work the same on Windows, if I find some minutes I'll check on Windows as well, but I expect it to be different in only minor details – hansaplast Feb 9 '17 at 20:24
  • @DaveKielpinski thanks for that input. In fact p.nice(19) does not work on Windows as Windows works with these distinct levels – hansaplast Feb 10 '17 at 7:17
  • @hansapalast thanks for this extremely informative answer! – Dave Kielpinski Feb 12 '17 at 5:44

On the OS level

you can use nice to set a priority to a single command. You could also start a python script with nice. (Below from: http://blog.scoutapp.com/articles/2014/11/04/restricting-process-cpu-usage-using-nice-cpulimit-and-cgroups)


The nice command tweaks the priority level of a process so that it runs less frequently. This is useful when you need to run a CPU intensive task as a background or batch job. The niceness level ranges from -20 (most favorable scheduling) to 19 (least favorable). Processes on Linux are started with a niceness of 0 by default. The nice command (without any additional parameters) will start a process with a niceness of 10. At that level the scheduler will see it as a lower priority task and give it less CPU resources.Start two matho-primes tasks, one with nice and one without:

nice matho-primes 0 9999999999 > /dev/null &matho-primes 0 9999999999 > /dev/null &
matho-primes 0 9999999999 > /dev/null &

Now run top.

enter image description here

As a function in Python

Another approach is to use psutils to check your CPU load average for the past minute and then have your threads check the CPU load average and spool up another thread if you are below the specified CPU load target, and sleep or kill the thread if you are above the CPU load target. This will get out of your way when you are using your computer, but will maintain a constant CPU load.

# Import Python modules
import time
import os
import multiprocessing
import psutil
import math
from random import randint

# Main task function
def main_process(item_queue, args_array):
    # Go through each link in the array passed in.
    while not item_queue.empty():
        # Get the next item in the queue
        item = item_queue.get()
        # Create a random number to simulate threads that
        # are not all going to be the same
        randomizer = randint(100, 100000)
        for i in range(randomizer):
            algo_seed = math.sqrt(math.sqrt(i * randomizer) % randomizer)
        # Check if the thread should continue based on current load balance
        if spool_down_load_balance():
            print "Process " + str(os.getpid()) + " saying goodnight..."

# This function will build a queue and
def start_thread_process(queue_pile, args_array):
    # Create a Queue to hold link pile and share between threads
    item_queue = multiprocessing.Queue()
    # Put all the initial items into the queue
    for item in queue_pile:
    # Append the load balancer thread to the loop
    load_balance_process = multiprocessing.Process(target=spool_up_load_balance, args=(item_queue, args_array))
    # Loop through and start all processes
    # This .join() function prevents the script from progressing further.

# Spool down the thread balance when load is too high
def spool_down_load_balance():
    # Get the count of CPU cores
    core_count = psutil.cpu_count()
    # Calulate the short term load average of past minute
    one_minute_load_average = os.getloadavg()[0] / core_count
    # If load balance above the max return True to kill the process
    if one_minute_load_average > args_array['cpu_target']:
        print "-Unacceptable load balance detected. Killing process " + str(os.getpid()) + "..."
        return True

# Load balancer thread function
def spool_up_load_balance(item_queue, args_array):

    print "[Starting load balancer...]"
    # Get the count of CPU cores
    core_count = psutil.cpu_count()
    # While there is still links in queue
    while not item_queue.empty():
        print "[Calculating load balance...]"
        # Check the 1 minute average CPU load balance
        # returns 1,5,15 minute load averages
        one_minute_load_average = os.getloadavg()[0] / core_count
        # If the load average much less than target, start a group of new threads
        if one_minute_load_average < args_array['cpu_target'] / 2:
            # Print message and log that load balancer is starting another thread
            print "Starting another thread group due to low CPU load balance of: " + str(one_minute_load_average * 100) + "%"
            # Start another group of threads
            for i in range(3):
                start_new_thread = multiprocessing.Process(target=main_process,args=(item_queue, args_array))
            # Allow the added threads to have an impact on the CPU balance
            # before checking the one minute average again

        # If load average less than target start single thread
        elif one_minute_load_average < args_array['cpu_target']:
            # Print message and log that load balancer is starting another thread
            print "Starting another single thread due to low CPU load balance of: " + str(one_minute_load_average * 100) + "%"
            # Start another thread
            start_new_thread = multiprocessing.Process(target=main_process,args=(item_queue, args_array))
            # Allow the added threads to have an impact on the CPU balance
            # before checking the one minute average again

            # Print CPU load balance
            print "Reporting stable CPU load balance: " + str(one_minute_load_average * 100) + "%"
            # Sleep for another minute while

if __name__=="__main__":

    # Set the queue size
    queue_size = 10000
    # Define an arguments array to pass around all the values
    args_array = {
        # Set some initial CPU load values as a CPU usage goal
        "cpu_target" : 0.60,
        # When CPU load is significantly low, start this number
        # of threads
        "thread_group_size" : 3

    # Create an array of fixed length to act as queue
    queue_pile = list(range(queue_size))
    # Set main process start time
    start_time = time.time()
    # Start the main process
    start_thread_process(queue_pile, args_array)
    print '[Finished processing the entire queue! Time consuming:{0} Time Finished: {1}]'.format(time.time() - start_time, time.strftime("%c"))

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