# Efficient way to normalize a Scipy Sparse Matrix

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.

• 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

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.

• 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

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()
``````

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()
for idx in np.unique(nonzero_rows):
data_idx = np.where(nonzero_rows==idx)
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.

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):
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.

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())

return scaling_matrix.dot(W)
``````