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I've got a large matrix stored as a scipy.sparse.csc_matrix and want to subtract a column vector from each one of the columns in the large matrix. This is a pretty common task when you're doing things like normalization/standardization, but I can't seem to find the proper way to do this efficiently.

Here's an example to demonstrate:

# mat is a 3x3 matrix
mat = scipy.sparse.csc_matrix([[1, 2, 3],
                               [2, 3, 4],
                               [3, 4, 5]])

#vec is a 3x1 matrix (or a column vector)
vec = scipy.sparse.csc_matrix([1,2,3]).T

I want to subtract `vec` from each of the columns in `mat` yielding...
    [[0, 1, 2],
     [0, 1, 2],
     [0, 1, 2]]

One way to accomplish what I want is to hstack vec to itself 3 times, yielding a 3x3 matrix where each column is vec and then subtract that from mat. But again, I'm looking for a way to do this efficiently, and the hstacked matrix takes a long time to create. I'm sure there's some magical way to do this with slicing and broadcasting, but it eludes me.


EDIT: Removed the 'in-place' constraint, because sparsity structure would be constantly changing in an in-place assignment scenario.

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Your sample data doesn't show it, because both the matrix and the vector you have chosen are dense. But if you did that operation on a truly sparse matrix, you would likely change the sparsity structure of the matrix (i.e. there would be non-zero values in places where before there was a zero value), which means that the operation can't really be done in-place. –  Jaime Nov 19 '13 at 1:06
yeah I realized the in-place constraint didn't make sense, so I edited the question to reflect that. I'll annotate that edit now! –  follyroof Nov 19 '13 at 1:09

3 Answers 3

up vote 3 down vote accepted

For a start what would we do with dense arrays?

mat-vec.A # taking advantage of broadcasting
mat-vec.A[:,[0]*3] # explicit broadcasting
mat-vec[:,[0,0,0]] # that also works with csr matrix

In http://codereview.stackexchange.com/questions/32664/numpy-scipy-optimization/33566 we found that using as_strided on the mat.indptr vector is the most efficient way of stepping through the rows of a sparse matrix. (The x.rows, x.cols of an lil_matrix are nearly as good. getrow is slow). This function implements such as iteration.

def sum(X,v):
    rows, cols = X.shape
    row_start_stop = as_strided(X.indptr, shape=(rows, 2),
    for row, (start, stop) in enumerate(row_start_stop):
        data = X.data[start:stop]
        data -= v[row]

sum(mat, vec.A)
print mat.A

I'm using vec.A for simplicity. If we keep vec sparse we'd have to add a test for nonzero value at row. Also this type of iteration only modifies the nonzero elements of mat. 0's are unchanged.

I suspect the time advantages will depend a lot on the sparsity of matrix and vector. If vec has lots of zeros, then it makes sense to iterate, modifying only those rows of mat where vec is nonzero. But vec is nearly dense like this example, it may be hard to beet mat-vec.A.

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+1 Wah, this is even simpler than my answer! Can you refer to a documentation that refers to the usage of A? I can't seem to see that in the documentation –  justhalf Nov 19 '13 at 2:59
mat.A is just short hand for mat.toarray(). It's modeled on dense uses like .T. –  hpaulj Nov 19 '13 at 3:16
I see. I guess this should give the best performance? At least it's better than mine since mine is doing exactly the same thing, but it requires CSR, and I explicitly modify the mat.data –  justhalf Nov 19 '13 at 3:18

You can introduce fake dimensions by altering the strides of your vector. You can, with out additional allocation, "convert" your vector to a 3 x 3 matrix using np.lib.stride_tricks.as_strided. This page has an example and a bit of a discussion about it along with some discussion of related topics (like views). Search the page for "Example: fake dimensions with strides."

There are also quite a few example on SO about this... but my searching skills are failing me now.

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Sparse matrices (or vectors) don't have strides... –  Jaime Nov 19 '13 at 1:06
Ah... I did not know that. Though thinking about this that does make sense. –  Ben Whale Nov 19 '13 at 1:09
Couldn't Murad write an ndarray subclass that wraps the sparse matrix but by overriding __getitem__ would allow the inbuilt ndarray striding code to be used before accessing the sparse array? –  Ben Whale Nov 19 '13 at 1:12
there must be a simpler way... –  follyroof Nov 19 '13 at 1:15
@BenWhale The built-in ndarray routines don't use the __getitem__ method for anything relevant, but access the data directly with C code. So no, I don-t think that would work either... –  Jaime Nov 19 '13 at 4:41


So in short, if you use CSR instead of CSC, it's a one-liner:

mat.data -= numpy.repeat(vec.toarray()[0], numpy.diff(mat.indptr))


If you realized it, this is better done in row-wise fashion, since we will deduct the same number from each row. In your example then: deduct 1 from the first row, 2 from the second row, 3 from the third row.

I actually encountered this in a real life application where I want to classify documents, each represented as a row in the matrix, while the columns represent words. Each document has a score which should be multiplied to the score of each word in that document. Using row representation of the sparse matrix, I did something similar to this (I modified my code to answer your question):

mat = scipy.sparse.csc_matrix([[1, 2, 3],
                               [2, 3, 4],
                               [3, 4, 5]])

#vec is a 3x1 matrix (or a column vector)
vec = scipy.sparse.csc_matrix([1,2,3]).T

# Use the row version
mat_row = mat.tocsr()
vec_row = vec.T

# mat_row.data contains the values in a 1d array, one-by-one from top left to bottom right in row-wise traversal.
# mat_row.indptr (an n+1 element array) contains the pointer to each first row in the data, and also to the end of the mat_row.data array
# By taking the difference, we basically repeat each element in the row vector to match the number of non-zero elements in each row
mat_row.data -= numpy.repeat(vec_row.toarray()[0],numpy.diff(mat_row.indptr))
print mat_row.todense()

Which results in:

[[0 1 2]
 [0 1 2]
 [0 1 2]]

The visualization is something like this:

>>> mat_row.data
[1 2 3 2 3 4 3 4 5]
>>> mat_row.indptr
[0 3 6 9]
>>> numpy.diff(mat_row.indptr)
[3 3 3]
>>> numpy.repeat(vec_row.toarray()[0],numpy.diff(mat_row.indptr))
[1 1 1 2 2 2 3 3 3]
>>> mat_row.data -= numpy.repeat(vec_row.toarray()[0],numpy.diff(mat_row.indptr))
[0 1 2 0 1 2 0 1 2]
>>> mat_row.todense()
[[0 1 2]
 [0 1 2]
 [0 1 2]]
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