I was implementing a weighting system called TF-IDF on a set of 42000 images, each consisting 784 pixels. This is basically a 42000 by 784 matrix.
The first method I attempted made use of explicit loops and took more than 2 hours.
def tfidf(color,img_pix,img_total): if img_pix==0: return 0 else: return color * np.log(img_total/img_pix) ... result = np.array() for img_vec in data_matrix: double_vec = zip(img_vec,img_pix_vec) result_row = np.array([tfidf(x,x,img_total) for x in double_vec]) try: result = np.vstack((result,result_row)) # first row will throw a ValueError since vstack accepts rows of same len except ValueError: result = result_row
The second method I attempted used numpy matrices and took less than 5 minutes. Note that data_matrix, img_pix_mat are both 42000 by 784 matrices while img_total is a scalar.
result = data_matrix * np.log(np.divide(img_total,img_pix_mat))
I was hoping someone could explain the immense difference in speed.
The authors of the following paper entitled "The NumPy array: a structure for eﬃcient numerical computation" (http://arxiv.org/pdf/1102.1523.pdf), state on the top of page 4 that they observe a 500 times speed increase due to vectorized computation. I'm presuming much of the speed increase I'm seeing is due to this. However, I would like to go a step further and ask why numpy vectorized computations are that much faster than standard python loops?
Also, perhaps you guys might know of other reasons why the first method is slow. Do try/except structures have high overhead? Or perhaps forming a new np.array for each loop is takes a long time?