I have a small GUI test with a "Start" button and a Progress bar. The desired behavior is:

  • Click Start
  • Progressbar oscillates for 5 seconds
  • Progressbar stops

The observed behavior is the "Start" button freezes for 5 seconds, then a Progressbar is displayed (no oscillation).

Here is my code so far:

class GUI:
    def __init__(self, master):
        self.master = master
        self.test_button = Button(self.master, command=self.tb_click)
            text="Start", background="Grey",

    def progress(self):
        self.prog_bar = ttk.Progressbar(
            self.master, orient="horizontal",
            length=200, mode="indeterminate"

    def tb_click(self):
        # Simulate long running process
        t = threading.Thread(target=time.sleep, args=(5,))

root = Tk()
root.title("Test Button")
main_ui = GUI(root)

Based on the information from Bryan Oakley here, I understand that I need to use threads. I tried creating a thread, but I'm guessing that since the thread is started from within the main thread, it doesn't help.

I had the idea to place the logic portion in a different class, and instantiate the GUI from within that class, similar to the example code by A. Rodas here.

My question:

I can't figure out how to code it so that this command:

self.test_button = Button(self.master, command=self.tb_click)

calls a function that is located in the other class. Is this a Bad Thing to do or is it even possible? How would I create a 2nd class that can handle the self.tb_click? I tried following along to A. Rodas' example code which works beautifully. But I cannot figure out how to implement his solution in the case of a Button widget that triggers an action.

If I should instead handle the thread from within the single GUI class, how would one create a thread that doesn't interfere with the main thread?


When you join the new thread in the main thread, it will wait until the thread finishes, so the GUI will block even though you are using multithreading.

If you want to place the logic portion in a different class, you can subclass Thread directly, and then start a new object of this class when you press the button. The constructor of this subclass of Thread can receive a Queue object and then you will be able to communicate it with the GUI part. So my suggestion is:

  1. Create a Queue object in the main thread
  2. Create a new thread with access to that queue
  3. Check periodically the queue in the main thread

Then you have to solve the problem of what happens if the user clicks two times the same button (it will spawn a new thread with each click), but you can fix it by disabling the start button and enabling it again after you call self.prog_bar.stop().

import Queue

class GUI:
    # ...

    def tb_click(self):
        self.queue = Queue.Queue()
        self.master.after(100, self.process_queue)

    def process_queue(self):
            msg = self.queue.get(0)
            # Show result of the task if needed
        except Queue.Empty:
            self.master.after(100, self.process_queue)

class ThreadedTask(threading.Thread):
    def __init__(self, queue):
        self.queue = queue
    def run(self):
        time.sleep(5)  # Simulate long running process
        self.queue.put("Task finished")
| improve this answer | |
  • Another beautiful example. Thank you A. Rodas :) I have a follow up question: If I comment out self.master.after(100, self.process_queue) and replace it with simply self.process_queue() the behavior is the same. Is there a good reason to have the self.master.after... part? – Dirty Penguin May 25 '13 at 13:39
  • 2
    Yes, with self.master.after(100, self.process_queue) you schedule this method each 100 milliseconds, while self.process_queue() constatly executes it without any delay between each call. There is no need to do that, so after is a better solution to check the content peridically. – A. Rodas May 25 '13 at 14:28
  • Sorry, Rodas, I am in a similar situation as explained by the OP, but in my case I should call a function from another class when I press a button, but it continues to freeze. I am not so familiar with threading, so that's why I am asking how should I do it. Since I have to call a function (just when I click the button of the GUI) of an object created in the constructor of my GUI application, should I make my other class derive from Thread anyway? – nbro Nov 29 '14 at 18:00
  • 1
    @citizen2077 If you want to prevent users from doing that, you can handle the WM_DELETE_PROTOCOL and only destroying the GUI if the thread is not alive. – A. Rodas Feb 4 '18 at 17:34
  • 1
    @citizen2077 Adding a handler would be the first step to define what happens if the root is closed using the window manager, but you can also use a flag to communicate the thread that it should stop its execution. Feel free to ask your question separately, since it is not strictly related with OP's question. – A. Rodas Feb 4 '18 at 17:47

The problem is that t.join() blocks the click event, the main thread does not get back to the event loop to process repaints. See Why ttk Progressbar appears after process in Tkinter or TTK progress bar blocked when sending email

| improve this answer | |

I will submit the basis for an alternate solution. It is not specific to a Tk progress bar per se, but it can certainly be implemented very easily for that.

Here are some classes that allow you to run other tasks in the background of Tk, update the Tk controls when desired, and not lock up the gui!

Here's class TkRepeatingTask and BackgroundTask:

import threading

class TkRepeatingTask():

    def __init__( self, tkRoot, taskFuncPointer, freqencyMillis ):
        self.__tk_   = tkRoot
        self.__func_ = taskFuncPointer        
        self.__freq_ = freqencyMillis
        self.__isRunning_ = False

    def isRunning( self ) : return self.__isRunning_ 

    def start( self ) : 
        self.__isRunning_ = True

    def stop( self ) : self.__isRunning_ = False

    def __onTimer( self ): 
        if self.__isRunning_ :
            self.__tk_.after( self.__freq_, self.__onTimer )

class BackgroundTask():

    def __init__( self, taskFuncPointer ):
        self.__taskFuncPointer_ = taskFuncPointer
        self.__workerThread_ = None
        self.__isRunning_ = False

    def taskFuncPointer( self ) : return self.__taskFuncPointer_

    def isRunning( self ) : 
        return self.__isRunning_ and self.__workerThread_.isAlive()

    def start( self ): 
        if not self.__isRunning_ :
            self.__isRunning_ = True
            self.__workerThread_ = self.WorkerThread( self )

    def stop( self ) : self.__isRunning_ = False

    class WorkerThread( threading.Thread ):
        def __init__( self, bgTask ):      
            threading.Thread.__init__( self )
            self.__bgTask_ = bgTask

        def run( self ):
            try :
                self.__bgTask_.taskFuncPointer()( self.__bgTask_.isRunning )
            except Exception as e: print repr(e)

Here's a Tk test which demos the use of these. Just append this to the bottom of the module with those classes in it if you want to see the demo in action:

def tkThreadingTest():

    from tkinter import Tk, Label, Button, StringVar
    from time import sleep

    class UnitTestGUI:

        def __init__( self, master ):
            self.master = master
            master.title( "Threading Test" )

            self.testButton = Button( 
                self.master, text="Blocking", command=self.myLongProcess )

            self.threadedButton = Button( 
                self.master, text="Threaded", command=self.onThreadedClicked )

            self.cancelButton = Button( 
                self.master, text="Stop", command=self.onStopClicked )

            self.statusLabelVar = StringVar()
            self.statusLabel = Label( master, textvariable=self.statusLabelVar )

            self.clickMeButton = Button( 
                self.master, text="Click Me", command=self.onClickMeClicked )

            self.clickCountLabelVar = StringVar()            
            self.clickCountLabel = Label( master,  textvariable=self.clickCountLabelVar )

            self.threadedButton = Button( 
                self.master, text="Timer", command=self.onTimerClicked )

            self.timerCountLabelVar = StringVar()            
            self.timerCountLabel = Label( master,  textvariable=self.timerCountLabelVar )



            self.bgTask = BackgroundTask( self.myLongProcess )

            self.timer = TkRepeatingTask( self.master, self.onTimer, 1 )

        def close( self ) :
            print "close"
            try: self.bgTask.stop()
            except: pass
            try: self.timer.stop()
            except: pass            

        def onThreadedClicked( self ):
            print "onThreadedClicked"
            try: self.bgTask.start()
            except: pass

        def onTimerClicked( self ) :
            print "onTimerClicked"

        def onStopClicked( self ) :
            print "onStopClicked"
            try: self.bgTask.stop()
            except: pass
            try: self.timer.stop()
            except: pass                        

        def onClickMeClicked( self ):
            print "onClickMeClicked"
            self.clickCountLabelVar.set( str(self.clickCounter_) )

        def onTimer( self ) :
            print "onTimer"
            self.timerCountLabelVar.set( str(self.timerCounter_) )

        def myLongProcess( self, isRunningFunc=None ) :
            print "starting myLongProcess"
            for i in range( 1, 10 ):
                    if not isRunningFunc() :
                        self.onMyLongProcessUpdate( "Stopped!" )
                except : pass   
                self.onMyLongProcessUpdate( i )
                sleep( 1.5 ) # simulate doing work
            self.onMyLongProcessUpdate( "Done!" )                

        def onMyLongProcessUpdate( self, status ) :
            print "Process Update: %s" % (status,)
            self.statusLabelVar.set( str(status) )

    root = Tk()    
    gui = UnitTestGUI( root )
    root.protocol( "WM_DELETE_WINDOW", gui.close )

if __name__ == "__main__": 

Two import points I'll stress about BackgroundTask:

1) The function you run in the background task needs to take a function pointer it will both invoke and respect, which allows the task to be cancelled mid way through - if possible.

2) You need to make sure the background task is stopped when you exit your application. That thread will still run even if your gui is closed if you don't address that!

| improve this answer | |
  • Wow, I don't think you understand how the after() method works. In the accepted answer, the self.master.after(100, self.process_queue) doesn't call self.process_queue recursively. It only schedules for it to be run again in 100 ms. The second argument is just the name of the function, not a call to it—and it only does this when exception Queue.Empty was raised, meaning that the ThreadedTask hasn't put anything in queue yet, so it need to keep checking. – martineau Jan 30 '17 at 20:14
  • @martineau I hope you are right! I ran that with some slight tweaks, and it crashed due to having too many recursive calls. In other languages and libraries I've used very similar repeating timers without a problem. I would love to see that work the way it seems like it should (i.e. non recursively). I will play with that and retract my answer when I have success. Although my BackgroundTask class still works well at least in my example - I haven't tested it enough to know what it will choke on with tk being non thread safe, however, an that concerned me about it! – BuvinJ Jan 30 '17 at 21:19
  • 1
    I'm really confident about what I said. Tkinter not being thread-safe doesn't mean you can't use it in a multi-threaded application. Only that you must limit the number of threads accessing Tkinter concurrently to one (and that is usually left up to the main thread). My answer to another Tkinter question has an example of that being done. – martineau Jan 30 '17 at 22:12
  • You are quite correct! I retract my harsh comments. I've radically altered my post. I absolutely did see that recursion crash, but there must have been something else going on. – BuvinJ Jan 30 '17 at 23:39
  • 1
    You could make it so it wasn't necessary to stop the background task(s) before exiting the application by setting their daemon attribute to True. See my answer to a different question for more details and links to the relevant documentation. – martineau Feb 4 '17 at 18:22

I have used RxPY which has some nice threading functions to solve this in a fairly clean manner. No queues, and I have provided a function that runs on the main thread after completion of the background thread. Here is a working example:

import rx
from rx.scheduler import ThreadPoolScheduler
import time
import tkinter as tk

class UI:
   def __init__(self):
      self.root = tk.Tk()
      self.pool_scheduler = ThreadPoolScheduler(1) # thread pool with 1 worker thread
      self.button = tk.Button(text="Do Task", command=self.do_task).pack()

   def do_task(self):

   def long_running_task(self):
      # your long running task here... eg:
      # if you want a callback on the main thread:
      self.root.after(5, self.on_task_complete)

   def on_task_complete(self):
       pass # runs on main thread

if __name__ == "__main__":
    ui = UI()

Another way to use this construct which might be cleaner (depending on preference):

tk.Button(text="Do Task", command=self.button_clicked).pack()


def button_clicked(self):

   def do_task(_):
      time.sleep(3) # runs on background thread
   def on_task_done():
      pass # runs on main thread

      on_completed=lambda: self.root.after(5, on_task_done), 
| improve this answer | |

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