# Efficiently Subtract Vector from Matrix (Scipy)

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.

Thanks!

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! –  Murad Salahi Nov 19 '13 at 1:09

For a start what would we do with dense arrays?

``````mat-vec.A # taking advantage of 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),
strides=2*X.indptr.strides)
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... –  Murad Salahi 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
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### Summary

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))
``````

### Explanation

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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