# Efficient way to plotting multiple images with many patches in matplotlib?

I'm writing code which displays features matches between images. The code runs fairly slow at the moment. I have some ideas on how to speed it up, but I'm not 100% comfortable with matplotlib yet or how its working behind the scenes.

The basic structure of the code is: (I'm leaving things out to make it more readable)

``````from matplotlib.patches import Rectangle, Circle, Ellipse
import matplotlib.gridspec as gridspec
from matplotlib.transforms import Affine2D
from scipy.linalg import inv, sqrtm
import matplotlib.pyplot as plt
import numpy as np
``````
• Add a list images. Each image gets its own axes: ax, and remembers ax.transData

``````gs = gridspec.GridSpec( nr, nc )
for i in range(num_images):
dm.ax_list[i] = plt.subplot(gs[i])
dm.ax_list[i].imshow( img_list[i])
transData_list[i] = dm.ax_list[i].transData
``````
• Visualize the feature representation as Ellipses

``````for i in range(num_chips):
axi =  chips[i].axi
ax  =  dm.ax_list[axi]
transData = dm.transData_list[axi]
chip_feats = chips[i].features
for feat in chip_feats:
(x,y,a,c,d) = feat
A = numpy.array( [ ( a, 0, 0 ) ,
( c, d, 0 ) ,
( 0, 0, 1 ) ] , dtype=np.float64)
EllShape = Affine2D( numpy.array(sqrtm( inv(A) ), dtype=np.float64) )
transEll  = EllShape.translate(x,y)
unitCirc = Circle((0,0),1,transform=transEll+transData)
``````

I've used RunSnakeRun to profile the code, and all I really gather from that is it is taking a long time to draw everything. The basic idea that I had when I learned about the transformation in matplotlib was to draw each image in its own coordinates, and then maintain several transformations so I could do cool things with them later, but I suspect that it's not going to scale well.

The actual output of the draw looks like this:

http://i.imgur.com/TeMrXv5.png

The figure takes about 4 seconds to redraw when I resize it, and I'm going to be wanting to pan/zoom.

I was adding two patches for each feature, and about (300 features per image) so I could see an outline and some transparency. So, there's obviously overhead for that. But its also relatively slow even without any ellipses.

I also need to write some code to put lines in between the matching features, but now I'm not so sure using multiple axes is a very good idea, especially when this is a relatively small dataset.

So, for more concrete questions:

• Would it be more efficient to plot Ellipses vs Transformed Circles? What is the overhead of using matplotlib transformations?
• Is there a way to combine a group of patches so they transform together or more efficiently?
• Would it be more efficient to pack everything into a single axes? Can the paradigm of transforms still be used if I do that? Or is the transform the main culprit here?
• Is there a quick way to do the sqrtm( inv( A ) ) on a list of matrices A? Or is it just as well that I have them in a for loop?
• Should I switch to something like pyqtgraph? I'm not planning on their being any animation beyond pan and zoom. ( maybe in the future I'll want to embed these into a interactive graph )

EDITS:

I've been able to increase drawing efficiency by computing the form of the square root inverted matrix by hand. Its a pretty big speed up too.

In the above code:

`````` A = numpy.array( [ ( a, 0, 0 ) ,
( c, d, 0 ) ,
( 0, 0, 1 ) ] , dtype=np.float64)
EllShape = Affine2D( numpy.array(sqrtm( inv(A) ), dtype=np.float64) )
``````

is replaced by

`````` EllShape = Affine2D([\
( 1/sqrt(a),         0, 0),\
((c/sqrt(a) - c/sqrt(d))/(a - d), 1/sqrt(d), 0),\
(         0,         0, 1)])
``````

I found some interesting timing results too:

``````  num_to_run = 100000
all_setup  = ''' import numpy as np ; from scipy.linalg import sqrtm ; from numpy.linalg import inv ; from numpy import sqrt
a=.1 ; c=43.2 ; d=32.343'''

timeit( \
'sqrtm(inv(np.array([ ( a, 0, 0 ) , ( c, d, 0 ) , ( 0, 0, 1 ) ])))',\
setup=all_setup, number=num_to_run)
>> 22.2588094075 #(Matlab reports 8 seconds for this run)

timeit(\
'[ (1/sqrt(a), 0, 0), ((c/sqrt(a) - c/sqrt(d))/(a - d), 1/sqrt(d), 0), (0, 0, 1) ]',\
setup=all_setup,  number=num_to_run)
>> 1.10265190941 #(Matlab reports .1 seconds for this run)
``````

EDIT 2

Ive gotten the ellipses to be computed and drawn very quickly (in about a second, I didn't profile it) using a PatchCollection and some manual calculations. The only drawback is I can't seem to set the fill of the ellipses to be false

`````` from matplotlib.collections import PatchCollection
ell_list = []
for i in range(num_chips):
axi =  chips[i].axi
ax  =  dm.ax_list[axi]
transData = dm.transData_list[axi]
chip_feats = chips[i].features
for feat in chip_feats:
(x,y,a,c,d) = feat
EllShape = Affine2D([\
( 1/sqrt(a),         0, x),\
((c/sqrt(a) - c/sqrt(d))/(a - d), 1/sqrt(d), y),\
(         0,         0, 1)])
unitCirc = Circle((0,0),1,transform=EllShape)
ell_list = [unitCirc] + ell_list
ellipses = PatchCollection(ell_list)
ellipses.set_color([1,1,1])
ellipses.face_color('none') #'none' gives no fill, while None will default to [0,0,1]
ellipses.set_alpha(.05)
ellipses.set_transformation(transData)
``````
-
You might be able to put all the ellipses into a patch collection which may speed up the drawing as well. –  tcaswell Feb 25 '13 at 15:52
maybe try `PathCollection` instead ? It is the same idea but with paths instead of patches. Also try adding the kwarg `match_orginal=True` (stackoverflow.com/questions/14492241/…) –  tcaswell Mar 4 '13 at 1:33
I figured out an easier way. You can set the facecolor of the patch collection to the string: 'none'. (Note, it doesn't work if you use None, then it just defaults) –  Erotemic Mar 4 '13 at 2:08
yes, `'none'` is a string object and `None` is the `None` object. Sorry, I should have thought through my earlier comment a bit more carefully. –  tcaswell Mar 4 '13 at 3:18
Can you post your last comment as a solution, as you seemed to have solved your own problem? –  tcaswell Apr 7 '13 at 5:30

I've been able to increase drawing efficiency by computing the form of the square root inverted matrix by hand. Its a pretty big speed up too.

In the above code:

`````` A = numpy.array( [ ( a, 0, 0 ) ,
( c, d, 0 ) ,
( 0, 0, 1 ) ] , dtype=np.float64)
EllShape = Affine2D( numpy.array(sqrtm( inv(A) ), dtype=np.float64) )
``````

is replaced by

`````` EllShape = Affine2D([\
( 1/sqrt(a),         0, 0),\
((c/sqrt(a) - c/sqrt(d))/(a - d), 1/sqrt(d), 0),\
(         0,         0, 1)])
``````

I found some interesting timing results too:

``````  num_to_run = 100000
all_setup  = ''' import numpy as np ; from scipy.linalg import sqrtm ; from numpy.linalg import inv ; from numpy import sqrt
a=.1 ; c=43.2 ; d=32.343'''

timeit( \
'sqrtm(inv(np.array([ ( a, 0, 0 ) , ( c, d, 0 ) , ( 0, 0, 1 ) ])))',\
setup=all_setup, number=num_to_run)
>> 22.2588094075 #(Matlab reports 8 seconds for this run)

timeit(\
'[ (1/sqrt(a), 0, 0), ((c/sqrt(a) - c/sqrt(d))/(a - d), 1/sqrt(d), 0), (0, 0, 1) ]',\
setup=all_setup,  number=num_to_run)
>> 1.10265190941 #(Matlab reports .1 seconds for this run)
``````

EDIT 2

Ive gotten the ellipses to be computed and drawn very quickly (in about a second, I didn't profile it) using a PatchCollection and some manual calculations. The only drawback is I can't seem to set the fill of the ellipses to be false

`````` from matplotlib.collections import PatchCollection
ell_list = []
for i in range(num_chips):
axi =  chips[i].axi
ax  =  dm.ax_list[axi]
transData = dm.transData_list[axi]
chip_feats = chips[i].features
for feat in chip_feats:
(x,y,a,c,d) = feat
EllShape = Affine2D([\
( 1/sqrt(a),         0, x),\
((c/sqrt(a) - c/sqrt(d))/(a - d), 1/sqrt(d), y),\
(         0,         0, 1)])
unitCirc = Circle((0,0),1,transform=EllShape)
ell_list = [unitCirc] + ell_list
ellipses = PatchCollection(ell_list)
ellipses.set_color([1,1,1])
ellipses.face_color('none') #'none' gives no fill, while None will default to [0,0,1]
ellipses.set_alpha(.05)
ellipses.set_transformation(transData)