25

I'd like to write a function that normalizes the rows of a large sparse matrix (such that they sum to one).

from pylab import *
import scipy.sparse as sp

def normalize(W):
    z = W.sum(0)
    z[z < 1e-6] = 1e-6
    return W / z[None,:]

w = (rand(10,10)<0.1)*rand(10,10)
w = sp.csr_matrix(w)
w = normalize(w)

However this gives the following exception:

File "/usr/lib/python2.6/dist-packages/scipy/sparse/base.py", line 325, in __div__
     return self.__truediv__(other)
File "/usr/lib/python2.6/dist-packages/scipy/sparse/compressed.py", line 230, in  __truediv__
   raise NotImplementedError

Are there any reasonably simple solutions? I have looked at this, but am still unclear on how to actually do the division.

  • 3
    This is basically a duplicate of: stackoverflow.com/questions/12237954/… as it doesn't matter if its a row by row elementwise multiplication or division. Of course if someone has a better answer, great :) – seberg Sep 6 '12 at 20:39
  • I disagree, this is a different problem. The duplicate you pointed to does element-wise multiplication, whereas this question seems to want to divide each row by a different value (rather than all non-zero elements by the same value). Aaron McDaid's solution below should work efficiently (and does not require any copying of data). – conradlee Sep 12 '12 at 22:28
  • AFAICT it's a duplicate of stackoverflow.com/questions/8358962/… – Emmet Aug 21 '13 at 1:39
42

This has been implemented in scikit-learn sklearn.preprocessing.normalize.

from sklearn.preprocessing import normalize
w_normalized = normalize(w, norm='l1', axis=1)

axis=1 should normalize by rows, axis=0 to normalize by column. Use the optional argument copy=False to modify the matrix in place.

  • 3
    Note that if you normalize by features (axis=0) then the returned matrix is of type 'csc' even if w was a 'csr'. This may be unpleasant if you counted on it being a 'csr' – Leo Jul 10 '15 at 12:56
2

here is my solution.

  • transpose A
  • calculate sum of each col
  • format diagonal matrix B with reciprocal of sum
  • A*B equals normalization
  • transpose C

    import scipy.sparse as sp
    import numpy as np
    import math
    
    minf = 0.0001
    
    A = sp.lil_matrix((5,5))
    b = np.arange(0,5)
    A.setdiag(b[:-1], k=1)
    A.setdiag(b)
    print A.todense()
    A = A.T
    print A.todense()
    
    sum_of_col = A.sum(0).tolist()
    print sum_of_col
    c = []
    for i in sum_of_col:
        for j in i:
            if math.fabs(j)<minf:
                c.append(0)
            else:
                c.append(1/j)
    
    print c
    
    B = sp.lil_matrix((5,5))
    B.setdiag(c)
    print B.todense()
    
    C = A*B
    print C.todense()
    C = C.T
    print C.todense()
    
2

While Aarons answer is correct, I implemented a solution when I wanted to normalize with respect to the maximum of the absolute values, which sklearn is not offering. My method uses the nonzero entries and finds them in the csr_matrix.data array to replace values there quickly.

def normalize_sparse(csr_matrix):
    nonzero_rows = csr_matrix.nonzero()[0]
    for idx in np.unique(nonzero_rows):
        data_idx = np.where(nonzero_rows==idx)[0]
        abs_max = np.max(np.abs(csr_matrix.data[data_idx]))
        if abs_max != 0:
            csr_matrix.data[data_idx] = 1./abs_max * csr_matrix.data[data_idx]

In contrast to sunan's solution, this method does not require any casting of the matrix into dense format (which could raise memory problems) and no matrix multiplications either. I tested the method on a sparse matrix of shape (35'000, 486'000) and it took ~ 18 seconds.

0

Without importing sklearn, converting to dense or multiplying matrices and by exploiting the data representation of csr matrices:

from scipy.sparse import isspmatrix_csr

def normalize(W):
    """ row normalize scipy sparse csr matrices inplace.
    """
    if not isspmatrix_csr(W):
        raise ValueError('W must be in CSR format.')
    else:
        for i in range(W.shape[0]):
            row_sum = W.data[W.indptr[i]:W.indptr[i+1]].sum()
            if row_sum != 0:
                W.data[W.indptr[i]:W.indptr[i+1]] /= row_sum

Remember that W.indices is the array of column indices, W.data is the array of corresponding nonzero values and W.indptr points to row starts in indices and data.

You can add a numpy.abs() when taking the sum if you need the L1 norm or use numpy.max() to normalize by the maximum value per row.

0

I found this as an elegant way of doing it without using inbuilt functions.

import scipy.sparse as sp

def normalize(W):
    #Find the row scalars as a Matrix_(n,1)
    rowSumW = sp.csr_matrix(W.sum(axis=1))
    rowSumW.data = 1/rowSumW.data

    #Find the diagonal matrix to scale the rows
    rowSumW = rowSumW.transpose()
    scaling_matrix = sp.diags(rowSumW.toarray()[0])

    return scaling_matrix.dot(W)  

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