Thanks oetzi. This works better, but still drags the UI down somewhat. I did some research, and found the following, for those who are interested.
The difficulty with showing a responsive user-interface while running a computationally heavy process using threading, stems from the fact in this case one combines a so-called IO-bound thread (i.e. the GUI), with a CPU-bound thread (i.e. the computation). For a IO-bound process, the time it takes to complete is defined by the fact that the thread has to wait on input or output (e.g. a user clicking on things, or a timer). By contrast, the time required to finish a CPU-bound process is limited by the power of the processing unit performing the process.
In principle, mixing these types of threads in Python should not be a problem. Although the GIL enforces that only one thread is running at a single instance, the operating system in fact splits the processes up into smaller instructions, and switches between them. If a thread is running, it has the GIL and executes some of its instructions. After a fixed amount of time, it needs to release the GIL. Once released, the GIL can schedule activate any other 'runnable' thread - including the one that was just released.
The problem however, is with the scheduling of these threads. Here things become a bit fuzzy for me, but basically what happens is that the CPU-bound thread seems to dominate this selection, from what I could gather due to a process called the "convey effect". Hence, the erratic and unpredictable behavior of a Qt GUI when running a CPU-bound thread in the background.
I found some interesting reading material on this:
So... this is very nice and all, how do we fix this?
In the end, I managed to get what I want using multiprocessing. This allows you to actually run a process parallel to the GUI, instead in sequential fashion. This ensures the GUI stays as responsive as it would be without the CPU-bound process in the background.
Multiprocessing has a lot of difficulties of its own, for example the fact that sending information back and forth between processes is done by sending pickled objects across a pipeline. However, the end-result is really superior in my case.
Below I put a code snippet, showing my solution. It contains a class called
ProgressDialog, which provides an easy API for setting this up with your own CPU-bound process.
"""Contains class for executing a long running process (LRP) in a separate
process, while showing a progress bar"""
import multiprocessing as mp
from PySide2 import QtCore
from PySide2.QtCore import Qt
import PySide2.QtWidgets as QtWidgets
"""Dialog which performs a operation in a separate process, shows a
progress bar, and returns the result of the operation
Title of the dialog
Function of the form f(conn, *args) that will be run
Additional arguments for operation
The result is an integer. A 0 represents successful completion, or
cancellation by the user. Negative numbers represent errors. -999
is reserved for any unforeseen uncaught error in the operation.
The function passed as the operation parameter should be of the form
``f(conn, *args)``. The conn argument is a Connection object, used to
communicate the progress of the operation to the GUI process. The
operation can pass its progress with a number between 0 and 100, using
``conn.send(i)``. Once the process is finished, it should send 101.
Error handling is done by passing negative numbers.
>>> def some_function(conn, *args):
>>> a = 0
>>> for i in range(100):
>>> a += 1
>>> conn.send(i + 1) # Send progress
>>> except Exception:
>>> conn.send(-1) # Send error code
>>> conn.send(101) # Send successful completion code
Now we can use an instance of the ProgressDialog class within any
QtWidget to execute the operation in a separate process, show a progress
bar, and print the error code:
>>> progress_dialog = ProgressDialog("Running...", some_function, self)
>>> progress_dialog.finished.connect(lambda err_code: print(err_code))
def __init__(self, title, operation, args=(), parent=None):
self.progress_bar = QtWidgets.QProgressBar(self)
layout = QtWidgets.QHBoxLayout()
# Create connection pipeline
self.parent_conn, self.child_conn = mp.Pipe()
# Create process
args = (self.child_conn, *args)
self.process = mp.Process(target=operation, args=args)
# Create status emitter
self.progress_emitter = ProgressEmitter(self.parent_conn, self.process)
self.thread_pool = QtCore.QThreadPool()
def slot_update_progress(self, i):
if i < 0:
elif i == 101:
def closeEvent(self, *args):
self.progress_emitter.running = False
"""Listens to status of process"""
progress = QtCore.Signal(int)
def __init__(self, conn, process):
self.conn = conn
self.process = process
self.signals = ProgressEmitter.ProgressSignals()
self.running = True
progress = self.conn.recv()
if progress < 0 or progress == 101:
self.running = False
elif not self.process.is_alive():
self.running = False