# Numpy cross-product on rectangular grid

I have two numpy arrays holding 2d vectors:

``````import numpy as np
a = np.array([[ 0.999875,  0.015836],
[ 0.997443,  0.071463],
[ 0.686554,  0.727078],
[ 0.93322 ,  0.359305]])

b = np.array([[ 0.7219  ,  0.691997],
[ 0.313656,  0.949537],
[ 0.507926,  0.861401],
[ 0.818131,  0.575031],
[ 0.117956,  0.993019]])
``````

As you can see, `a.shape` is (4,2) and `b.shape` is (5,2).

Now, I can get the results I want thusly:

``````In [441]: np.array([np.cross(av, bv) for bv in b for av in a]).reshape(5, 4)
Out[441]:
array([[ 0.680478,  0.638638, -0.049784,  0.386403],
[ 0.944451,  0.924694,  0.423856,  0.773429],
[ 0.85325 ,  0.8229  ,  0.222097,  0.621377],
[ 0.562003,  0.515094, -0.200055,  0.242672],
[ 0.991027,  0.982051,  0.595998,  0.884323]])
``````

My question is: What's a more 'numpythonic' way of getting the above (i.e without the nested list comprehensions)? I've tried every combination of `np.cross()` I can think of, and I usually get results like this:

``````In [438]: np.cross(a, b.T, axisa=1, axisb=0)
---------------------------------------------------------------------------
ValueError                                Traceback (most recent call last)
<ipython-input-438-363c0765a7f9> in <module>()
----> 1 np.cross(a, b.T, axisa=1, axisb=0)

D:\users\ae4652t\Python27\lib\site-packages\numpy\core\numeric.p<snipped>
1242     if a.shape[0] == 2:
1243         if (b.shape[0] == 2):
-> 1244             cp = a[0]*b[1] - a[1]*b[0]
1245             if cp.ndim == 0:
1246                 return cp

ValueError: operands could not be broadcast together with shapes (4) (5)
``````
-
Are you trying to take an inner product? What you are doing is not a cross product. –  Ophion Jan 6 '13 at 0:40
I think I'm taking 20 cross-products on a 4 x 5 grid, no? That's the function I'm calling in the list comprehension –  subnivean Jan 6 '13 at 0:42
I see what your doing, it probably isnt worth it to optimize this unless these arrays are very large. –  Ophion Jan 6 '13 at 1:13
@EOL I agree, and I am now very curious to see if there is a way to take all combinations between two array's by row more efficiently then the way I proposed. –  Ophion Jan 6 '13 at 2:50
My arrays aren't very large yet; just wanted to be ready. That, and any time I see a `for` when I'm using numpy makes me feel a little queasy :-) Thanks for all the answers w/timings. –  subnivean Jan 6 '13 at 4:14

## 2 Answers

I haven't timed my code, but I am almost certain there is no more numpythonic way of doing this than the nice and simple:

``````>>> np.cross(a[None], b[:, None])
array([[ 0.68047849,  0.63863842, -0.0497843 ,  0.38640316],
[ 0.94445125,  0.92469424,  0.42385605,  0.77342875],
[ 0.85324981,  0.82290048,  0.22209648,  0.62137629],
[ 0.5620032 ,  0.51509455, -0.20005522,  0.24267187],
[ 0.99102692,  0.98205036,  0.59599795,  0.88432301]])
``````

Broadcasting is always the answer...

-
Nice; this should be the accepted answer. Although "always" is a bit of an exaggeration-- there are many cases where broadcasting results in impractically large intermediate arrays. –  DSM Jan 6 '13 at 3:49
Always as in except when not, of course... ;-) –  Jaime Jan 6 '13 at 3:51
Updated my post for timings! As I have never seen the use of [None] before is there any difference between that and reshape(1,-1)? –  Ophion Jan 6 '13 at 3:52
Thanks, that's exactly what I was looking for. I might suggest `np.newaxis` in place of `None`, but I'm not sure it reads any more clearly. And thanks for the link; I'll bone up again on broadcasting. –  subnivean Jan 6 '13 at 4:02
@Ophion I used to always do explicit reshapes, as you suggest, but lately I tend to lean more to slicing with `None`, since it usually allows for more compact code. Which is the same reason I go with `None` over `np.newaxis`. –  Jaime Jan 6 '13 at 4:21

I thought a bit more on this.

``````>>> a
array([[ 0.999875,  0.015836],
[ 0.997443,  0.071463],
[ 0.686554,  0.727078],
[ 0.93322 ,  0.359305]])
>>> b
array([[ 0.7219  ,  0.691997],
[ 0.313656,  0.949537],
[ 0.507926,  0.861401],
[ 0.818131,  0.575031],
[ 0.117956,  0.993019]])
>>> c = np.tile(a, (b.shape[0], 1))
>>> d = np.repeat(b, a.shape[0], axis=0)
>>> np.cross(c, d).reshape(5,4)
array([[ 0.68047849,  0.63863842, -0.0497843 ,  0.38640316],
[ 0.94445125,  0.92469424,  0.42385605,  0.77342875],
[ 0.85324981,  0.82290048,  0.22209648,  0.62137629],
[ 0.5620032 ,  0.51509455, -0.20005522,  0.24267187],
[ 0.99102692,  0.98205036,  0.59599795,  0.88432301]])
``````

Some timings:

``````import timeit

s="""
import numpy as np
a=np.random.random(100).reshape(-1, 2)
b=np.random.random(1000).reshape(-1, 2)
"""

ophion="""
np.cross(np.tile(a,(b.shape[0],1)),np.repeat(b,a.shape[0],axis=0))"""

subnivean="""
np.array([np.cross(av, bv) for bv in b for av in a]).reshape(b.shape[0], a.shape[0])"""

DSM="""
np.outer(b[:,1], a[:,0]) - np.outer(b[:,0], a[:,1])"""

Jamie="""
np.cross(a[None], b[:, None, :])"""

h=timeit.timeit(subnivean,setup=s,number=10)
m=timeit.timeit(ophion,setup=s,number=10)
d=timeit.timeit(DSM,setup=s,number=10)
j=timeit.timeit(Jamie,setup=s,number=10)

print "subnivean's method took",h,'seconds.'
print "Ophion's method took",m,'seconds.'
print "DSM's method took",d,'seconds.'

"
subnivean's method took 1.99507117271 seconds.
Ophion's method took 0.0149450302124 seconds.
DSM's method took 0.0040500164032 seconds.
Jamie's method took 0.00390195846558 seconds."
``````

For when the length of a=10 and b=100:

``````"
subnivean's method took 0.0217308998108 seconds.
Ophion's method took 0.00046181678772 seconds.
DSM's method took 0.000531911849976 seconds.
Jamie's method took 0.000334024429321 seconds."
``````

Hmm you switched the order of the cross product again, both answers are shown if you want (5,4) or (4,5).

-
No, I want the exact 5 x 4 array shown above –  subnivean Jan 6 '13 at 0:44
Updated for what you wanted. –  Ophion Jan 6 '13 at 1:55
Hey, that's not fair: when timing mine, you're not just testing my solution (using `np.outer`), you're including the `listcomp` line, which is the OP's solution I included only to check the answers.. –  DSM Jan 6 '13 at 1:57
Ah, I apologize- updating now. –  Ophion Jan 6 '13 at 1:58
+1 for putting the timings together –  subnivean Jan 6 '13 at 4:21