# slicing sparse (scipy) matrix

I would appreciate any help, to understand following behavior when slicing a lil_matrix (A) from the scipy.sparse package.

Actually, I would like to extract a submatrix based on an arbitrary index list for both rows and columns.

When I used this two lines of code:

``````x1 = A[list 1,:]
x2 = x1[:,list 2]
``````

Everything was fine and I could extract the right submatrix.

When I tried to do this in one line, it failed (The returning matrix was empty)

``````x=A[list 1,list 2]
``````

Why is this so? Overall, I have used a similar command in matlab and there it works. So, why not use the first, since it works? It seems to be quite time consuming. Since I have to go through a large amount of entries, I would like to speed it up using a single command. Maybe I use the wrong sparse matrix type...Any idea?

-
what does list1 and list2 contents ? What gives A[list1:list2] ?? –  Louis Sep 30 '11 at 10:37
list1 and list 2 are are python list objects containing integers e.g. [1,4,6,8] A[list1:list2] is empty (<1x3 sparse matrix of type '<type 'numpy.int32'>' with 0 stored elements in LInked List format> –  user972858 Sep 30 '11 at 11:59

You could do:

``````A[np.array(list1)[:,np.newaxis],np.array(list2)]
``````

numpy indexing has many different behaviors depending on the type of its arguments.

You are picking arbitrary rows and columns, so you can't use basic slicing. That leaves so-called "advanced indexing".

The key thing to remember with advanced indexing with ndarrays is that if `arr1` and `arr2` are ndarrays, the `(i,j)` component of `A[arr1,arr2]` equals

``````A[arr1[i,j],arr2[i,j]]
``````

Thus you will want `arr1[i,j]` to equal `list1[i]` for all j, and you'll want `arr2[i,j]` to equal `list2[j]` for all i.

That can be arranged with the help of broadcasting (see below) by setting `arr1=np.array(list1)[:,np.newaxis]`, and `arr2=np.array(list2)`.

The shape of `arr1` is `(len(list1),1)` while the shape of `arr2` is `(len(list2),)` which can be broadcasted to `(1,len(list2))` since new axes are added on the left.

Each array can be further broadcasted to shape `(len(list1),len(list2))`. This is exactly what we want for `A[arr1[i,j],arr2[i,j]]` to make sense, since we want `(i,j)` to run over all possible indices for a result array of shape `(len(list1),len(list2))`.

``````import numpy as np
import scipy.sparse as sparse
import random
random.seed(1)

list1=[1,4,6,8]
list2=[2,4]

N=10
A = sparse.lil_matrix( (N,N) )
for _ in xrange(4*N):
A[random.randint(0,N-1),random.randint(0,N-1)]=random.randint(1,100)

x1 = A[list1,:]
x2 = x1[:,list2]
print(x2.toarray())
# [[  0.   0.]
#  [  0.  23.]
#  [  0.   0.]
#  [ 54.   3.]]

B=A.tocsc()  # or `.tocsr()`
print(B[np.array(list1)[:,np.newaxis],np.array(list2)].toarray())
# [[  0.   0.]
#  [  0.  23.]
#  [  0.   0.]
#  [ 54.   3.]]
``````
-
Thanks. This seems quite elegant, but keep in mind that I am using a sparse matrix from the scipy.sparse package. Unfortunatelly, this kind of indexing does not work. It gives an IndexError. –  user972858 Sep 30 '11 at 13:05
Hm. Indeed, it does not work with `lil_matrix`, but it does work with `csc_matrix` or `csr_matrix`. –  HappyLeapSecond Sep 30 '11 at 13:20
Thanks a lot. It was very helpful. –  user972858 Oct 5 '11 at 10:02
It seems to me that something like `A[list1,:][:,list2]` gives the same result but operates much faster on sparse matrices. –  passerby51 Jan 31 '14 at 4:03

for me the solution from unutbu works well, but is slow.

I found as a fast alternative,

``````A = B.tocsr()[np.array(list1),:].tocsc()[:,np.array(list2)]
``````

You can see that row'S and col's get cut separately, but each one converted to the fastest sparse format, to get index this time.

In my test environment this code is 1000 times faster than the other one.

I hope, I don't tell something wrong or make a mistake.

-

slicing happens with this syntax :

``````a[1:4]
``````

for a = array([1,2,3,4,5,6,7,8,9]), the result is

``````array([2, 3, 4])
``````

The first parameter of the tuple indicates the first value to be retained, and the second parameter indicates the first value not to be retained.

If you use lists on both sides, it means that your array has as many dimensions as the lists length.

So, with your syntax, you will probably need something like this :

``````x = A[list1,:,list2]
``````

depending on the shape of A.