Sparse matrices (as suggested by @phg) are good, since most of the entries in your matrix are probably 0 (assuming most users follow only a few TV shows).
Probably more importantly, though, you're building the matrix in a very inefficient way (making lots of lists of python lists and copying them around), rather than just putting them in a nice compact numpy array in the first place. Also, you're spending a ton of time searching through lists (with the
in statement), when that's just not at all necessary for your loops.
This code loops over the follower list and looks up the user # for each id in a
user_ids dictionary. You can adapt it to a sparse matrix class pretty trivially (just switch
scipy.sparse.coo_matrix, I think).
user_ids = dict((user, i) for i, user in enumerate(unique_users))
follower_matrix = np.zeros(NoTvShows, len(unique_users), dtype=bool)
for show_idx, followers in enumerate(collected_users):
for user in followers:
follower_matrix[show_idx, user_ids[user]] = 1
Once you have the matrix, you really, really don't want to save it as JSON unless you have to: it's a really wasteful format for numeric matrices.
numpy.save is best if you're only using the data matrix again in numpy.
numpy.savetxt also works and at least eliminates the brackets and commas, and will probably have less memory overhead while writing. But when you have a 0-1 matrix and it's in the boolean datatype,
numpy.save only needs one bit per matrix element, while
numpy.savetxt needs two bytes = 16 bits (an ascii
'1' plus a space or newline), and json uses at least three bytes, I think (comma, space, plus some brackets on each line).
You may also be talking about dimensionality reduction techniques. That's also very possible; there are lots of techniques out there to reduce your vector of 140 dimensions (which TV shows are followed) to lower dimensionality, either by some kind of PCA-type technique, a topic model, maybe something based on clustering.... If your only concern is that it's taking a long time to build the matrix, though, that's not going to help at all (since those techniques generally require the full original matrix and then give you a lower-dimensional version). Try my suggestions here, if it's not good enough try a sparse matrix, and then worry about fancy ways to reduce the data (probably by learning a dimensionality reduction on a subset of the data and then constructing the rest).