memory exhaust on big matrix operation using dask

Currently I'm implementing this paper for my undergraduate theses with python, but I only use the mahalanobis metric learning (in case you're curious).

In a shortcut, I face a problem when I need to learn a matrix with the size of 67K*67K consisting of integer, by simply numpy.dot(A.T,A) where A is a random vector sized (1,67K). When I do that it's simply throw MemoryError since my PC only have 8gb ram, and the raw calculation of the memory needed is 16gb to init. Than I search for alternative and found dask.

so i moved on to dask with this dask.array.dot(A.T,A) and it's done. But than I need to do whitening transformation to that matrix, and in dask I can achieve it by get the SVD. But everytime I do that SVD, the ipython kernel dies (I assume it due to lack of memory).

this is what I do so far from init, until the kernel dies:

fv_length=512*2*66
W = da.random.randint(10,20,(fv_length),(1000,1000))
W = da.reshape(W,(1,fv_length))
W_T = W.T
Wt = da.dot(W_T,W); del W,W_T
Wt = da.reshape(Wt,(fv_length*fv_length/2,2))
U,S,Vt = da.linalg.svd(Wt); del Wt

I didn't get the U,S,and Vt yet.

Is my memory simply not enough to do these sort of things, even when I'm using dask? or actually this is not a spec problem, but my bad memory management? or something else?

At this point I'm desperately trying in other bigger spec PC, so I am planning to rent a bare metal server with a 32gb ram. Even if I do so, is it enough?

• Do you need the full SVD, or are you only interested in the N largest singular values/vectors? – ali_m Jun 19 '16 at 20:46
• I need the SVD, because furthermore I want to do whitening transformation, and PCA with that result. Btw @mrocklin has convinced me that doing things on a bigger spec much worth. Thanks anyway – yusufazishty Jun 19 '16 at 21:21
• You can generate a rank N whitened matrix from the N-largest singular values and vectors. Depending on the size of N, this can be many orders of magnitude more efficient than computing the full SVD. – ali_m Jun 19 '16 at 21:25
• any reference or tutorial how to get that? – yusufazishty Jun 19 '16 at 21:30
• If U, s, Vt = svd(X) then the columns of U[:, :n] and the rows of Vt[:n, :] will contain orthogonal vectors. Assuming that you subtracted the mean before computing the SVD, then U[:, :n].dot(Vt[:n]) will be a whitened version of X. At that point you've essentially already done PCA (see my previous answer here). da.linalg.svd_compressed uses Halko et al's clever randomized algorithm to efficiently compute the partial SVD. – ali_m Jun 19 '16 at 21:49