# How to assign to square submatrices in big matrix without loops in numpy

How can I vectorize this loop, which populates two square submatrices of a larger matrix (also keeps larger matrix symmetric) using numpy arrays:

``````for x in range(n):
assert m[x].shape == (n,)
M[i:i+n,j+x] = m[x]
M[j+x,i:i+n] = m[x]
``````

This is tempting but does not agree with loop above (see example disagreement below):

``````assert m.shape == (n,n)
M[i:i+n,j:j+n] = m
M[j:j+n,i:i+n] = m
``````

Here's a little example (crashes for n>1):

``````from numpy import arange,empty,NAN
from numpy.testing import assert_almost_equal

for n in (1,2,3,4):
# make the submatrix
m = (10 * arange(1, 1 + n * n)).reshape(n, n)

N = n # example below, submatrix is the whole thing

# M1 using loops, M2 "vectorized"
M1 = empty((N, N))
M2 = empty((N, N))
M1.fill(NAN)
M2.fill(NAN)

i,j = 0,0 # not really used when (n == N)

# this results in symmetric matrix
for x in range(n):
assert m[x].shape == (n,)
M1[i:i+n,j+x] = m[x]
M1[j+x,i:i+n] = m[x]

# this does not work as expected
M2[i:i+n,j:j+n] = m
M2[j:j+n,i:i+n] = m

assert_almost_equal(M1,M1.transpose(),err_msg="M not symmetric?")
print "M1\n",M1,"\nM2",M2
assert_almost_equal(M1,M2,err_msg="M1 (loop) disagrees with M2 (vectorized)")
``````

We end up with:

``````M1 = [10 30
30 40] # symmetric

M2 = [10 20
30 40] # i.e. m
``````
-

Your test is incorrect: for i,j=0,0 your M2[]= assignments just overwrite the same matrix block.

The reason you get the symmetric matrix when using M1 is because you assign the M1 values in a single loop.

if you would split the loop into two:

``````for x in range(n):
M1[i:i+n,j+x] = m[x]
for x in range(n):
M1[j+x,i:i+n] = m[x]
``````

The M1 will be obviously the same as M2.

So Summarizing, the following code works (equivalent to your M2 calculation) but ! it will only work if there is no overlap between blocks above and below the diagonal. if there is you have to decide what to do there

``````xs=np.arange(4).reshape(2,2)
ys=np.zeros((7,7))
ys[i:i+n,j:j+n]=xs
ys[j:j+n,i:i+n]=xs.T
print ys
>> array([[ 0.,  0.,  0.,  0.,  0.,  0.,  0.],
[ 0.,  0.,  0.,  0.,  1.,  0.,  0.],
[ 0.,  0.,  0.,  2.,  3.,  0.,  0.],
[ 0.,  0.,  2.,  0.,  0.,  0.,  0.],
[ 0.,  1.,  3.,  0.,  0.,  0.,  0.],
[ 0.,  0.,  0.,  0.,  0.,  0.,  0.],
[ 0.,  0.,  0.,  0.,  0.,  0.,  0.]])
``````
-
Ah good point, the code as written cannot easily be vectorized because the two assignments in the loop can interact. I thought I was hitting a subtle feature of indexing but it was a much simpler explanation. Thx! – Joseph Hastings Jun 12 '12 at 2:30