I am trying to do an animation program in VTK, in which I could make the VTK objects animate
but I failed to do pausing animation and restart animation, I came to know recently to stop the VTK timer but after if I click the animate button again to start then the program got crashed with following error, I have only one clue that the following line is crashing but this line will work at the first time of animation button click but fails on the second button click!!. The second function "animation_Stop" is my attempt of stopping the function by destroying the whole function, so I hoped I could avoid the program crash but it was also a failure!!
Error:
python.exe has stopped working
Error line:
self.renderWindowInteractor.SetRenderWindow(obj_renwin.renwin)
Please note my detailed code lines for animation and someone please help me to restart
and pause the animation in vtk python
def animation(self,obj_renwin,X):
if X==1:
print "start or restart animation"
self.renderWindowInteractor = vtk.vtkRenderWindowInteractor()
objRen=self.renderWindowInteractor.GetRenderWindow()
self.renderWindowInteractor.SetRenderWindow(obj_renwin.renwin)
obj_renwin.renwin.Render()
self.renderWindowInteractor.Initialize()
cb = vtkTimerCallback()
cb.actor = obj_renwin.actor
self.renderWindowInteractor.AddObserver('TimerEvent', cb.execute)
self.timerId = self.renderWindowInteractor.CreateRepeatingTimer(5);
if X==2:
print "stop animation"
self.renderWindowInteractor.DestroyTimer(self.timerId)
def animation_Stop(self,obj_renwin):
print "stop animation"
#self.animation(obj_renwin,1).destroy()
del (ConeRender.Cone.animation)
If you start the vtkTimer like that:
vtkSmartPointer<vtkTimerCallback> cb =
vtkSmartPointer<vtkTimerCallback>::New();
interactor->AddObserver(vtkCommand::TimerEvent, cb);
you may consider to stop/pause the timer with
vtkCommand::EndInteraction
i.e.
interactor->InvokeEvent(vtkCommand::TimerEvent, cb);
[It is just a moment thought, you can try it] ... :)
I'm very new to Python but have started writing a few small scripts this week. I'm currently trying to write a simple program to plot some data. I'd like to do the following:
ask the user to choose the data directory using a GUI
for each file in the directory, make a plot
close each plot with a mouse click and advance to the next plot
I've mostly gotten the program to work - I can choose the directory using tkFileDialog.askdirectory, then read in the data, make the plots and advance though them using a mouse click.
My problem is with the TK root window that opens with the tkFileDialog. If I use withdraw() the extra window doesn't open, but only the first plot will appear (a mouse click closes that plot but doesn't show the next one). If I don't use withdraw(), the extra window must be manually closed after the first plot to advance to the second.
I'm wondering if there is a way to choose the directory that will avoid displaying the extra window?
I'm attaching some sample code to show my thought process. This doesn't call the actual data but still reproduces the problem (you'll need to change the .D to some file type that you have in a directory):
import numpy as np
from pylab import *
import glob
import os
import Tkinter, tkFileDialog
##################################################
#define the mouse click event
##################################################
def moveon(event):
close()
##################################################
#ask for the directory
##################################################
root = Tkinter.Tk()
#root.withdraw()
direc = tkFileDialog.askdirectory(parent=root,initialdir="/",title='Please select a directory')
os.chdir(direc)
for files in glob.glob("*.D*"):
##################################################
#Read in the data
##################################################
#assume this reads x and y from each file
x = [1, 2]
y = [3, 4]
##################################################
#loop though the plots
##################################################
fig = figure(1)
plot(x,y)
cid = fig.canvas.mpl_connect('button_press_event',moveon)
show()
Since you don't seem to be using Tkinter after your file dialog, you could do root.destroy()
to close the Tk root window right after you have the user select a file.
After these instructions in the Python interpreter one gets a window with a plot:
from matplotlib.pyplot import *
plot([1,2,3])
show()
# other code
Unfortunately, I don't know how to continue to interactively explore the figure created by show() while the program does further calculations.
Is it possible at all? Sometimes calculations are long and it would help if they would proceed during examination of intermediate results.
Use matplotlib's calls that won't block:
Using draw():
from matplotlib.pyplot import plot, draw, show
plot([1,2,3])
draw()
print('continue computation')
# at the end call show to ensure window won't close.
show()
Using interactive mode:
from matplotlib.pyplot import plot, ion, show
ion() # enables interactive mode
plot([1,2,3]) # result shows immediatelly (implicit draw())
print('continue computation')
# at the end call show to ensure window won't close.
show()
Use the keyword 'block' to override the blocking behavior, e.g.
from matplotlib.pyplot import show, plot
plot(1)
show(block=False)
# your code
to continue your code.
It is better to always check with the library you are using if it supports usage in a non-blocking way.
But if you want a more generic solution, or if there is no other way, you can run anything that blocks in a separated process by using the multprocessing module included in python. Computation will continue:
from multiprocessing import Process
from matplotlib.pyplot import plot, show
def plot_graph(*args):
for data in args:
plot(data)
show()
p = Process(target=plot_graph, args=([1, 2, 3],))
p.start()
print 'yay'
print 'computation continues...'
print 'that rocks.'
print 'Now lets wait for the graph be closed to continue...:'
p.join()
That has the overhead of launching a new process, and is sometimes harder to debug on complex scenarios, so I'd prefer the other solution (using matplotlib's nonblocking API calls)
Try
import matplotlib.pyplot as plt
plt.plot([1,2,3])
plt.show(block=False)
# other code
# [...]
# Put
plt.show()
# at the very end of your script to make sure Python doesn't bail out
# before you finished examining.
The show() documentation says:
In non-interactive mode, display all figures and block until the figures have been closed; in interactive mode it has no effect unless figures were created prior to a change from non-interactive to interactive mode (not recommended). In that case it displays the figures but does not block.
A single experimental keyword argument, block, may be set to True or False to override the blocking behavior described above.
IMPORTANT: Just to make something clear. I assume that the commands are inside a .py script and the script is called using e.g. python script.py from the console.
A simple way that works for me is:
Use the block = False inside show : plt.show(block = False)
Use another show() at the end of the .py script.
Example of script.py file:
plt.imshow(*something*)
plt.colorbar()
plt.xlabel("true ")
plt.ylabel("predicted ")
plt.title(" the matrix")
# Add block = False
plt.show(block = False)
################################
# OTHER CALCULATIONS AND CODE HERE ! ! !
################################
# the next command is the last line of my script
plt.show()
You may want to read this document in matplotlib's documentation, titled:
Using matplotlib in a python shell
In my case, I wanted to have several windows pop up as they are being computed. For reference, this is the way:
from matplotlib.pyplot import draw, figure, show
f1, f2 = figure(), figure()
af1 = f1.add_subplot(111)
af2 = f2.add_subplot(111)
af1.plot([1,2,3])
af2.plot([6,5,4])
draw()
print 'continuing computation'
show()
PS. A quite useful guide to matplotlib's OO interface.
Well, I had great trouble figuring out the non-blocking commands... But finally, I managed to rework the "Cookbook/Matplotlib/Animations - Animating selected plot elements" example, so it works with threads (and passes data between threads either via global variables, or through a multiprocess Pipe) on Python 2.6.5 on Ubuntu 10.04.
The script can be found here: Animating_selected_plot_elements-thread.py - otherwise pasted below (with fewer comments) for reference:
import sys
import gtk, gobject
import matplotlib
matplotlib.use('GTKAgg')
import pylab as p
import numpy as nx
import time
import threading
ax = p.subplot(111)
canvas = ax.figure.canvas
# for profiling
tstart = time.time()
# create the initial line
x = nx.arange(0,2*nx.pi,0.01)
line, = ax.plot(x, nx.sin(x), animated=True)
# save the clean slate background -- everything but the animated line
# is drawn and saved in the pixel buffer background
background = canvas.copy_from_bbox(ax.bbox)
# just a plain global var to pass data (from main, to plot update thread)
global mypass
# http://docs.python.org/library/multiprocessing.html#pipes-and-queues
from multiprocessing import Pipe
global pipe1main, pipe1upd
pipe1main, pipe1upd = Pipe()
# the kind of processing we might want to do in a main() function,
# will now be done in a "main thread" - so it can run in
# parallel with gobject.idle_add(update_line)
def threadMainTest():
global mypass
global runthread
global pipe1main
print "tt"
interncount = 1
while runthread:
mypass += 1
if mypass > 100: # start "speeding up" animation, only after 100 counts have passed
interncount *= 1.03
pipe1main.send(interncount)
time.sleep(0.01)
return
# main plot / GUI update
def update_line(*args):
global mypass
global t0
global runthread
global pipe1upd
if not runthread:
return False
if pipe1upd.poll(): # check first if there is anything to receive
myinterncount = pipe1upd.recv()
update_line.cnt = mypass
# restore the clean slate background
canvas.restore_region(background)
# update the data
line.set_ydata(nx.sin(x+(update_line.cnt+myinterncount)/10.0))
# just draw the animated artist
ax.draw_artist(line)
# just redraw the axes rectangle
canvas.blit(ax.bbox)
if update_line.cnt>=500:
# print the timing info and quit
print 'FPS:' , update_line.cnt/(time.time()-tstart)
runthread=0
t0.join(1)
print "exiting"
sys.exit(0)
return True
global runthread
update_line.cnt = 0
mypass = 0
runthread=1
gobject.idle_add(update_line)
global t0
t0 = threading.Thread(target=threadMainTest)
t0.start()
# start the graphics update thread
p.show()
print "out" # will never print - show() blocks indefinitely!
Hope this helps someone,
Cheers!
In many cases it is more convenient til save the image as a .png file on the hard drive. Here is why:
Advantages:
You can open it, have a look at it and close it down any time in the process. This is particularly convenient when your application is running for a long
time.
Nothing pops up and you are not forced to have the windows open. This is particularly convenient when you are dealing with many figures.
Your image is accessible for later reference and is not lost when closing the figure window.
Drawback:
The only thing I can think of is that you will have to go and finder the folder and open the image yourself.
If you are working in console, i.e. IPython you could use plt.show(block=False) as pointed out in the other answers. But if you're lazy you could just type:
plt.show(0)
Which will be the same.
I had to also add plt.pause(0.001) to my code to really make it working inside a for loop (otherwise it would only show the first and last plot):
import matplotlib.pyplot as plt
plt.scatter([0], [1])
plt.draw()
plt.show(block=False)
for i in range(10):
plt.scatter([i], [i+1])
plt.draw()
plt.pause(0.001)
On my system show() does not block, although I wanted the script to wait for the user to interact with the graph (and collect data using 'pick_event' callbacks) before continuing.
In order to block execution until the plot window is closed, I used the following:
fig = plt.figure()
ax = fig.add_subplot(1,1,1)
ax.plot(x,y)
# set processing to continue when window closed
def onclose(event):
fig.canvas.stop_event_loop()
fig.canvas.mpl_connect('close_event', onclose)
fig.show() # this call does not block on my system
fig.canvas.start_event_loop_default() # block here until window closed
# continue with further processing, perhaps using result from callbacks
Note, however, that canvas.start_event_loop_default() produced the following warning:
C:\Python26\lib\site-packages\matplotlib\backend_bases.py:2051: DeprecationWarning: Using default event loop until function specific to this GUI is implemented
warnings.warn(str,DeprecationWarning)
although the script still ran.
I also wanted my plots to display run the rest of the code (and then keep on displaying) even if there is an error (I sometimes use plots for debugging). I coded up this little hack so that any plots inside this with statement behave as such.
This is probably a bit too non-standard and not advisable for production code. There is probably a lot of hidden "gotchas" in this code.
from contextlib import contextmanager
#contextmanager
def keep_plots_open(keep_show_open_on_exit=True, even_when_error=True):
'''
To continue excecuting code when plt.show() is called
and keep the plot on displaying before this contex manager exits
(even if an error caused the exit).
'''
import matplotlib.pyplot
show_original = matplotlib.pyplot.show
def show_replacement(*args, **kwargs):
kwargs['block'] = False
show_original(*args, **kwargs)
matplotlib.pyplot.show = show_replacement
pylab_exists = True
try:
import pylab
except ImportError:
pylab_exists = False
if pylab_exists:
pylab.show = show_replacement
try:
yield
except Exception, err:
if keep_show_open_on_exit and even_when_error:
print "*********************************************"
print "Error early edition while waiting for show():"
print "*********************************************"
import traceback
print traceback.format_exc()
show_original()
print "*********************************************"
raise
finally:
matplotlib.pyplot.show = show_original
if pylab_exists:
pylab.show = show_original
if keep_show_open_on_exit:
show_original()
# ***********************
# Running example
# ***********************
import pylab as pl
import time
if __name__ == '__main__':
with keep_plots_open():
pl.figure('a')
pl.plot([1,2,3], [4,5,6])
pl.plot([3,2,1], [4,5,6])
pl.show()
pl.figure('b')
pl.plot([1,2,3], [4,5,6])
pl.show()
time.sleep(1)
print '...'
time.sleep(1)
print '...'
time.sleep(1)
print '...'
this_will_surely_cause_an_error
If/when I implement a proper "keep the plots open (even if an error occurs) and allow new plots to be shown", I would want the script to properly exit if no user interference tells it otherwise (for batch execution purposes).
I may use something like a time-out-question "End of script! \nPress p if you want the plotting output to be paused (you have 5 seconds): " from https://stackoverflow.com/questions/26704840/corner-cases-for-my-wait-for-user-input-interruption-implementation.
plt.figure(1)
plt.imshow(your_first_image)
plt.figure(2)
plt.imshow(your_second_image)
plt.show(block=False) # That's important
raw_input("Press ENTER to exist") # Useful when you run your Python script from the terminal and you want to hold the running to see your figures until you press Enter
The OP asks about detatching matplotlib plots. Most answers assume command execution from within a python interpreter. The use-case presented here is my preference for testing code in a terminal (e.g. bash) where a file.py is run and you want the plot(s) to come up but the python script to complete and return to a command prompt.
This stand-alone file uses multiprocessing to launch a separate process for plotting data with matplotlib. The main thread exits using the os._exit(1) mentioned in this post. The os._exit() forces main to exit but leaves the matplotlib child process alive and responsive until the plot window is closed. It's a separate process entirely.
This approach is a bit like a Matlab development session with figure windows that come up with a responsive command prompt. With this approach, you have lost all contact with the figure window process, but, that's ok for development and debugging. Just close the window and keep testing.
multiprocessing is designed for python-only code execution which makes it perhaps better suited than subprocess. multiprocessing is cross-platform so this should work well in Windows or Mac with little or no adjustment. There is no need to check the underlying operating system. This was tested on linux, Ubuntu 18.04LTS.
#!/usr/bin/python3
import time
import multiprocessing
import os
def plot_graph(data):
from matplotlib.pyplot import plot, draw, show
print("entered plot_graph()")
plot(data)
show() # this will block and remain a viable process as long as the figure window is open
print("exiting plot_graph() process")
if __name__ == "__main__":
print("starting __main__")
multiprocessing.Process(target=plot_graph, args=([1, 2, 3],)).start()
time.sleep(5)
print("exiting main")
os._exit(0) # this exits immediately with no cleanup or buffer flushing
Running file.py brings up a figure window, then __main__ exits but the multiprocessing + matplotlib figure window remains responsive with zoom, pan, and other buttons because it is an independent process.
Check the processes at the bash command prompt with:
ps ax|grep -v grep |grep file.py
In my opinion, the answers in this thread provide methods which don't work for every systems and in more complex situations like animations. I suggest to have a look at the answer of MiKTeX in the following thread, where a robust method has been found:
How to wait until matplotlib animation ends?
Here is the simplest solution I found (thread blocking code)
plt.show(block=False) # this avoids blocking your thread
plt.pause(1) # comment this if you do not want a time delay
# do more stuff
plt.show(block=True) # this prevents the window from closing on you
If you want to open multiple figures, while keeping them all opened, this code worked for me:
show(block=False)
draw()
While not directly answering OPs request, Im posting this workaround since it may help somebody in this situation:
Im creating an .exe with pyinstaller since I cannot install python where I need to generate the plots, so I need the python script to generate the plot, save it as .png, close it and continue with the next, implemented as several plots in a loop or using a function.
for this Im using:
import matplotlib.pyplot as plt
#code generating the plot in a loop or function
#saving the plot
plt.savefig(var+'_plot.png',bbox_inches='tight', dpi=250)
#you can allways reopen the plot using
os.system(var+'_plot.png') # unfortunately .png allows no interaction.
#the following avoids plot blocking the execution while in non-interactive mode
plt.show(block=False)
#and the following closes the plot while next iteration will generate new instance.
plt.close()
Where "var" identifies the plot in the loop so it wont be overwritten.
What I have found as the best solution so the program does not wait for you to close the figure and have all your plots together so you can examine them side by side is to show all the plots at the end.
But this way you cannot examine the plots while program is running.
# stuff
numFig = 1
plt.figure(numFig)
numFig += 1
plt.plot(x1, y1)
# other stuff
plt.figure(numFig)
numFig += 1
plt.plot(x2, y2)
# more stuff
plt.show()
Use plt.show(block=False), and at the end of your script call plt.show().
This will ensure that the window won't be closed when the script is finished.