There is no quick way to do it, so I had to write a function. It returns a sparse matrix with the unique rows (axis=0) or columns (axis=1) of an input sparse matrix.
Note that the unique rows or columns of the returned matrix are not lexicographical sorted (as is the case with the `np.unique`

).

```
import numpy as np
import scipy.sparse as sp
def sp_unique(sp_matrix, axis=0):
''' Returns a sparse matrix with the unique rows (axis=0)
or columns (axis=1) of an input sparse matrix sp_matrix'''
if axis == 1:
sp_matrix = sp_matrix.T
old_format = sp_matrix.getformat()
dt = np.dtype(sp_matrix)
ncols = sp_matrix.shape[1]
if old_format != 'lil':
sp_matrix = sp_matrix.tolil()
_, ind = np.unique(sp_matrix.data + sp_matrix.rows, return_index=True)
rows = sp_matrix.rows[ind]
data = sp_matrix.data[ind]
nrows_uniq = data.shape[0]
sp_matrix = sp.lil_matrix((nrows_uniq, ncols), dtype=dt) # or sp_matrix.resize(nrows_uniq, ncols)
sp_matrix.data = data
sp_matrix.rows = rows
ret = sp_matrix.asformat(old_format)
if axis == 1:
ret = ret.T
return ret
def lexsort_row(A):
''' numpy lexsort of the rows, not used in sp_unique'''
return A[np.lexsort(A.T[::-1])]
if __name__ == '__main__':
# Test
# Create a large sparse matrix with elements in [0, 10]
A = 10*sp.random(10000, 3, 0.5, format='csr')
A = np.ceil(A).astype(int)
# unique rows
A_uniq = sp_unique(A, axis=0).toarray()
A_uniq = lexsort_row(A_uniq)
A_uniq_numpy = np.unique(A.toarray(), axis=0)
assert (A_uniq == A_uniq_numpy).all()
# unique columns
A_uniq = sp_unique(A, axis=1).toarray()
A_uniq = lexsort_row(A_uniq.T).T
A_uniq_numpy = np.unique(A.toarray(), axis=1)
assert (A_uniq == A_uniq_numpy).all()
```

`scipy`

for that.`np.unique`

with the new`axis`

parameter is probably the best route. If you have to stick with`sparse`

I'd suggest looking at the`lil`

format and its 'raw' rows and data attributes.