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When I have two non-sparse matrices A and B, is there a way to efficiently calculate C=A.T.dot(B) when I only want a subset of the elements of C? I have the desired indices of C stored in CSC format which is specified here.

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As much as this is the programming community, you might want to check this over at the Math SO. –  jdotjdot Dec 5 '12 at 20:09
    
@jdotjdot: To me this is purely a programming question, with next to no math contents. –  NPE Dec 5 '12 at 20:16
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I check mathexchange and while making the tags for the post, it didn't have any the ones that would seem relevant like scipy and numpy or even sparse. –  bluecat Dec 5 '12 at 21:44
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The answer to this question depends on: (i) how sparse is C, (ii) how large the dimensions of A and B are. Please specify. –  pv. Dec 6 '12 at 2:08

3 Answers 3

If you know in advance which parts of C you want and some of these parts are contiguous and rectangular regions*, then you can use the matrix algebra rules associated with the Multiplication of Partitioned Matrices (1) or Block matrix multiplication (2) to speed up some of these calculations. So for example, you can use the same basic logic of @GaryBishop, but instead of having a list of 'i' and 'j' elements you have a list (or array) of four-tuples of i_start, i_end and j_start, j_end that define sub-matrices of C then you can use those indices (though rules established in those links) to figure out the the sub-matrices of A and B you need to solve for the desired blocks of C.

For a simple example, Say you only wanted the middle block of C, so we partition C into C1, C2, and C3 by row and all we care about is C2. If A^{T} is likewise partitioned into three sets of rows A1, A2, A3 then C2 = A2 * B. The idea generalizes to rectangles of any shape, it just requires different partitions of A and B to calculate. The idea is the same.

  • -This is trivially true but you'd only get time savings if the regions are larger than single elements.
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That's the same that I thought. I suspect the rows that constitute C2 and A2 might even be non-contiguous (discontinuous slice) –  heltonbiker Dec 21 '12 at 13:22
    
I think you are correct, they don't have to be contiguous, though the algebra might be a bit trickier. A non-contiguous A2 might be best thought of as elements of a finer partition, e.g. A1 (out), A2a (in), A2b (out), A2C (in), A3(out) but with careful indexing and a good understanding of which elements you care about it may be faster to work with a non-contiguous subset directly then working with one piece of contiguous partition at a time. –  BKay Dec 21 '12 at 19:20

Ignoring the CSC business, and perhaps answering a simpler question than you are asking. Here is how I would compute a subset of the elements of C given a list of tuples of C index values.

Since you are evaluating C=A.T.dot(B) you are multiplying columns of A by columns of B. So,

for i, j in indexList:
    C[i, j] = np.dot(A[:,i], B[:,j])

I'm guessing that isn't what you're looking for but I find the simple answer sometimes helps clarify the question.

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Yes this is more or less the method I'm using right now, but unfortunately the looping calls to np.dot() are very slow. –  bluecat Dec 10 '12 at 16:05

You can have numpy do the looping, which should (very) considerably speed up GaryBishop's method, as follows:

def sparse_mult(a, b, coords) :
    rows, cols = zip(*coords)
    rows, r_idx = np.unique(rows, return_inverse=True)
    cols, c_idx = np.unique(cols, return_inverse=True)
    C = np.dot(a[rows, :], b[:, cols])
    return C[r_idx, c_idx]

>>> A = np.arange(12).reshape(3, 4)
>>> B = np.arange(6).reshape(3, 2)
>>> np.dot(A.T, B)
array([[100, 112, 124, 136, 148],
       [115, 130, 145, 160, 175],
       [130, 148, 166, 184, 202],
       [145, 166, 187, 208, 229]])
>>> sparse_mult(A.T, B, [(0, 0), (1, 2), (2, 4), (3, 3)])
array([100, 145, 202, 208])

sparse_mult returns a flattened array of the values at the coordinates you provide as a list of tuples. I am not very familiar with sparse matrix formats, so I don't know how to define CSC from the above data, but the following works

>>> coords = [(0, 0), (1, 2), (2, 4), (3, 3)]
>>> sparse.coo_matrix((sparse_mult(A.T, B, coords), zip(*coords))).tocsc()
<4x5 sparse matrix of type '<type 'numpy.int32'>'
    with 4 stored elements in Compressed Sparse Column format>

EDIT Just for the fun of it I did a timing test:

>>> import timeit
>>> a = np.random.rand(2000, 3000)
>>> b = np.random.rand(3000, 5000)
>>> timeit.timeit('np.dot(a,b)[[0, 0, 1999, 1999], [0, 4999, 0, 4999]]', 'from __main__ import np, a, b', number=1)
5.848562187263569
>>> timeit.timeit('sparse_mult(a, b, [(0, 0), (0, 4999), (1999, 0), (1999, 4999)])', 'from __main__ import np, a, b, sparse_mult', number=1)
0.0018596387374678613
>>> np.dot(a,b)[[0, 0, 1999, 1999], [0, 4999, 0, 4999]]
array([ 758.76351111,  750.32613815,  751.4614542 ,  758.8989648 ])
>>> sparse_mult(a, b, [(0, 0), (0, 4999), (1999, 0), (1999, 4999)])
array([ 758.76351111,  750.32613815,  751.4614542 ,  758.8989648 ])
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I'm trying to figure out how this works but I can't get it to work. Why is np.dot(A.T, B) a 5 by 4 matrix? Shouldn't it be 4x2? Using your example I get a failure in the function on line "C = np.dot(a[rows, :], b[:, cols])", "index error: index (2) out of range (0<=index<1) in dimension 1" –  BKay Apr 5 '13 at 13:21

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