I'm trying to compute a simple dot product but leave nonzero values from the original matrix unchanged. A toy example:

```
import numpy as np
A = np.array([[2, 1, 1, 2],
[0, 2, 1, 0],
[1, 0, 1, 1],
[2, 2, 1, 0]])
B = np.array([[ 0.54331039, 0.41018682, 0.1582158 , 0.3486124 ],
[ 0.68804647, 0.29520239, 0.40654206, 0.20473451],
[ 0.69857579, 0.38958572, 0.30361365, 0.32256483],
[ 0.46195299, 0.79863505, 0.22431876, 0.59054473]])
```

Desired outcome:

```
C = np.array([[ 2. , 1. , 1. , 2. ],
[ 2.07466874, 2. , 1. , 0.73203386],
[ 1. , 1.5984076 , 1. , 1. ],
[ 2. , 2. , 1. , 1.42925865]])
```

The actual matrices in question, however, are sparse and look more like this:

```
A = sparse.rand(250000, 1700, density=0.001, format='csr')
B = sparse.rand(1700, 1700, density=0.02, format='csr')
```

One simple way go would be just setting the values using mask index, like that:

```
mask = A != 0
C = A.dot(B)
C[mask] = A[mask]
```

However, my original arrays are sparse and quite large, so changing them via index assignment is painfully slow. Conversion to lil matrix helps a bit, but again, conversion itself takes a lot of time.

The other obvious approach, I guess, would be just resort to iteration and skip masked values, but I'd like not to throw away the benefits of numpy/scipy-optimized array multiplication.

**Some clarifications:** I'm actually interested in some kind of special case, where `B`

is always square, and therefore, `A`

and `C`

are of the same shape. So if there's a solution that doesn't work on arbitrary arrays but fits in my case, that's fine.

**UPDATE:** Some attempts:

```
from scipy import sparse
import numpy as np
def naive(A, B):
mask = A != 0
out = A.dot(B).tolil()
out[mask] = A[mask]
return out.tocsr()
def proposed(A, B):
Az = A == 0
R, C = np.where(Az)
out = A.copy()
out[Az] = np.einsum('ij,ji->i', A[R], B[:, C])
return out
%timeit naive(A, B)
1 loops, best of 3: 4.04 s per loop
%timeit proposed(A, B)
/usr/local/lib/python2.7/dist-packages/scipy/sparse/compressed.py:215: SparseEfficiencyWarning: Comparing a sparse matrix with 0 using == is inefficient, try using != instead.
/usr/local/lib/python2.7/dist-packages/scipy/sparse/coo.pyc in __init__(self, arg1, shape, dtype, copy)
173 self.shape = M.shape
174
--> 175 self.row, self.col = M.nonzero()
176 self.data = M[self.row, self.col]
177 self.has_canonical_format = True
MemoryError:
```

**ANOTHER UPDATE:**

Couldn't make anything more or less useful out of Cython, at least without going too far away from Python. The idea was to leave the dot product to scipy and just try to set those original values as fast as possible, something like this:

```
cimport cython
@cython.cdivision(True)
@cython.boundscheck(False)
@cython.wraparound(False)
cpdef coo_replace(int [:] row1, int [:] col1, float [:] data1, int[:] row2, int[:] col2, float[:] data2):
cdef int N = row1.shape[0]
cdef int M = row2.shape[0]
cdef int i, j
cdef dict d = {}
for i in range(M):
d[(row2[i], col2[i])] = data2[i]
for j in range(N):
if (row1[j], col1[j]) in d:
data1[j] = d[(row1[j], col1[j])]
```

This was a bit better then my pre-first "naive" implementation (using `.tolil()`

), but following hpaulj's approach, lil can be thrown out. Maybe replacing python dict with something like std::map would help.

`mask`

has the shape of`A`

, while`C`

might not necessarily be of the same shape as`A`

. So,`C[mask]`

doesn't make a whole lot of sense as such I guess we need more details on what you mean`zero values`

. – Divakar Jul 17 '16 at 8:32`B`

is square, co`A.dot(B).shape == A.shape`

.`A`

itself might not be square, however. But you're right, this won't work on arbitrary arrays. – rocknrollnerd Jul 17 '16 at 8:53`A`

's values that are equal to zero. By "original" matrix I mean`A`

, yes. – rocknrollnerd Jul 17 '16 at 8:54`B`

is sparse too? – Divakar Jul 17 '16 at 9:54