I was studying the python threading and came across join().

The author told that if thread is in daemon mode then i need to use join() so that thread can finish itself before main thread terminates.

but I have also seen him using t.join() even though t was not daemon

example code is this

import threading
import time
import logging

                    format='(%(threadName)-10s) %(message)s',

def daemon():

d = threading.Thread(name='daemon', target=daemon)

def non_daemon():

t = threading.Thread(name='non-daemon', target=non_daemon)



i don't know what is use of t.join() as it is not daemon and i can see no change even if i remove it

  • 9
    +1 for the title. 'Join' seems to be specially designed to encourage poor performance, (by continually creating/terminating/destroying threads), GUI lockups, (waiting in event-handlers) and app shutdown failures, (waiting for uninterruptible threads to terminate). Note - not just Python, this is a cross-language anti-pattern. – Martin James Feb 26 '13 at 11:00
up vote 190 down vote accepted

A somewhat clumsy ascii-art to demonstrate the mechanism: The join() is presumably called by the main-thread. It could also be called by another thread, but would needlessly complicate the diagram.

join-calling should be placed in the track of the main-thread, but to express thread-relation and keep it as simple as possible, I choose to place it in the child-thread instead.

without join:
+---+---+------------------                     main-thread
    |   |
    |   +...........                            child-thread(short)
    +..................................         child-thread(long)

with join
+---+---+------------------***********+###      main-thread
    |   |                             |
    |   +...........join()            |         child-thread(short)
    +......................join()......         child-thread(long)

with join and daemon thread
+-+--+---+------------------***********+###     parent-thread
  |  |   |                             |
  |  |   +...........join()            |        child-thread(short)
  |  +......................join()......        child-thread(long)
  +,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,     child-thread(long + daemonized)

'-' main-thread/parent-thread/main-program execution
'.' child-thread execution
'#' optional parent-thread execution after join()-blocked parent-thread could 
'*' main-thread 'sleeping' in join-method, waiting for child-thread to finish
',' daemonized thread - 'ignores' lifetime of other threads;
    terminates when main-programs exits; is normally meant for 
    join-independent tasks

So the reason you don't see any changes is because your main-thread does nothing after your join. You could say join is (only) relevant for the execution-flow of the main-thread.

If, for example, you want to concurrently download a bunch of pages to concatenate them into a single large page, you may start concurrent downloads using threads, but need to wait until the last page/thread is finished before you start assembling a single page out of many. That's when you use join().

  • Please confirm that a daemonized thread may be joined() without blocking program execution? – Aviator45003 Mar 3 '15 at 8:52
  • @Aviator45003: Yes, by using the timeout argument like: demon_thread.join(0.0), join() is by default blocking without regard to the daemonized attribute. But joining a demonized thread opens most likely a whole can of trouble! I'm now considering to remove the join() call in my little diagram for the daemon-thread... – Don Question Mar 3 '15 at 17:15

Straight from the docs

join([timeout]) Wait until the thread terminates. This blocks the calling thread until the thread whose join() method is called terminates – either normally or through an unhandled exception – or until the optional timeout occurs.

This means that the main thread which spawns t and d, waits for t to finish until it finishes.

Depending on the logic your program employs, you may want to wait until a thread finishes before your main thread continues.

Also from the docs:

A thread can be flagged as a “daemon thread”. The significance of this flag is that the entire Python program exits when only daemon threads are left.

A simple example, say we have this:

def non_daemon():
    print 'Test non-daemon'

t = threading.Thread(name='non-daemon', target=non_daemon)


Which finishes with:

print 'Test one'
print 'Test two'

This will output:

Test one
Test non-daemon
Test two

Here the master thread explicitly waits for the t thread to finish until it calls print the second time.

Alternatively if we had this:

print 'Test one'
print 'Test two'

We'll get this output:

Test one
Test two
Test non-daemon

Here we do our job in the main thread and then we wait for the t thread to finish. In this case we might even remove the explicit joining t.join() and the program will implicitly wait for t to finish.

  • Can you make some chnage to my code so that i can see the difference of t.join(). by adding soome sleep or something else. at moment i can see any chnage in program even if i use it or not. but for damemon i can see its exit if i use d.join() which i don't see when i don't use d.join() – user192362127 Feb 26 '13 at 9:46
  • @user192362127 Take a look at the updated answer. – dmg Feb 26 '13 at 10:01

Thanks for this thread -- it helped me a lot too.

I learned something about .join() today.

These threads run in parallel:


and these run sequentially (not what I wanted):


In particular, I was trying to clever and tidy:

class Kiki(threading.Thread):
    def __init__(self, time):
        super(Kiki, self).__init__()
        self.time = time

This works! But it runs sequentially. I can put the self.start() in __ init __, but not the self.join(). That has to be done after every thread has been started.

join() is what causes the main thread to wait for your thread to finish. Otherwise, your thread runs all by itself.

So one way to think of join() as a "hold" on the main thread -- it sort of de-threads your thread and executes sequentially in the main thread, before the main thread can continue. It assures that your thread is complete before the main thread moves forward. Note that this means it's ok if your thread is already finished before you call the join() -- the main thread is simply released immediately when join() is called.

In fact, it just now occurs to me that the main thread waits at d.join() until thread d finishes before it moves on to t.join().

In fact, to be very clear, consider this code:

import threading
import time

class Kiki(threading.Thread):
    def __init__(self, time):
        super(Kiki, self).__init__()
        self.time = time

    def run(self):
        print self.time, " seconds start!"
        for i in range(0,self.time):
            print "1 sec of ", self.time
        print self.time, " seconds finished!"

t1 = Kiki(3)
t2 = Kiki(2)
t3 = Kiki(1)
print "t1.join() finished"
print "t2.join() finished"
print "t3.join() finished"

It produces this output (note how the print statements are threaded into each other.)

$ python test_thread.py
32   seconds start! seconds start!1

 seconds start!
1 sec of  1
 1 sec of 1  seconds finished!
 21 sec of
1 sec of  3
1 sec of  2
2  seconds finished!
1 sec of  3
3  seconds finished!
t1.join() finished
t2.join() finished
t3.join() finished

The t1.join() is holding up the main thread. All three threads complete before the t1.join() finishes and the main thread moves on to execute the print then t2.join() then print then t3.join() then print.

Corrections welcome. I'm also new to threading.

(Note: in case you're interested, I'm writing code for a DrinkBot, and I need threading to run the ingredient pumps concurrently rather than sequentially -- less time to wait for each drink.)

  • Hey, I'm also new to python threading and confused about the main thread, Is the first thread is main thread, If not, please guide me? – Rohit Khatri Aug 11 '16 at 6:14
  • The main thread is the program itself. Each of the threads are forked from there. They are then joined back -- because at the command join(), the program waits until the thread is finished before it continues to execute. – Kiki Jewell Jan 3 '17 at 5:16

The method join()

blocks the calling thread until the thread whose join() method is called is terminated.

Source : http://docs.python.org/2/library/threading.html

  • 10
    so what is the use of join? see OP question, don't just paraphrase the docs – Don Question Feb 26 '13 at 9:49
  • @DonQuestion i even tried adding sleep.timer(20) in non daemon thread without using t.join() and program still waits for it before termination. i don't see any use of t.join() here in my code – user192362127 Feb 26 '13 at 9:54
  • see my answer, for further explanation. regarding your sleep.timer in non-demon -> a demon-thread is decoupled of the life-time of it's parent thread and so the parent/sibling threads won't be affected by the life-time of the demonized thread and vice versa. – Don Question Feb 26 '13 at 10:10
  • 2
    The 'join' and 'block' terminology is puzzling. 'Blocked' suggests the calling process is 'blocked' from doing any number of things it still has to do, while in fact it's just blocked from terminating (returning to the OS), not more. By the same token, it's not so obvious that there's a main thread calling a child thread to 'join' it (ie terminate). So, Don Q, thanks for the explanation. – RolfBly Jan 14 '14 at 20:40

When making join(t) function for both non-daemon thread and daemon thread, the main thread (or main process) should wait t seconds, then can go further to work on its own process. During the t seconds waiting time, both of the children threads should do what they can do, such as printing out some text. After the t seconds, if non-daemon thread still didn't finish its job, and it still can finish it after main process finishes its job, but for daemon thread, it just missed its opportuninity window. However it will eventually die after the python program exits. Please correct me if there is something wrong.

"What's the use of using join()?" you say. Really, it's the same answer as "what's the use of closing files, since python and the OS will close my file for me when my program exits?".

It's simply a matter of good programming. You should join() your threads at the point in the code that the thread should not be running anymore, either because you positively have to ensure the thread is not running to interfere with your own code, or that you want to behave correctly in a larger system.

You might say "I don't want my code to delay giving an answer" just because of the additional time that the join() might require. This may be perfectly valid in some scenarios, but you now need to take into account that your code is "leaving cruft around for python and the OS to clean up". If you do this for performance reasons, I strongly encourage you to document that behavior. This is especially true if you're building a library/package that others are expected to utilize.

There's no reason to not join(), other than performance reasons, and I would argue that your code does not need to perform that well.

  • 4
    What you say about cleaning up threads is not true. Take a look at the source code of threading.Thread.join(). All that function does is wait on a lock, and then return. Nothing is actually cleaned up. – Collin Jul 16 '15 at 14:01
  • 1
    @Collin - The thread itself may be holding resources, in that case interpreter and OS will indeed need to clean up "cruft". – qneill Dec 1 '15 at 5:27
  • 1
    Again, look at the source code of threading.Thread.join(). There is nothing in there that triggers collection of resources. – Collin Dec 1 '15 at 16:01
  • Its not necessarily (and as you say, not at all) the threading module that is holding resources, but the thread itself. Using join() means you're waiting for the thread to finish doing what it wanted to do, which could include allocating and releasing resources. – Chris Cogdon Dec 2 '15 at 18:09
  • 1
    Whether you wait or not doesn't affect when the resources held by the thread are released. I'm not sure why you're tying this in with calling join(). – Collin Feb 5 '16 at 20:42

Your Answer


By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.