The `csr`

and `csc`

formats were developed for linear algeba, especially the solution of large, but sparse, linear equations

```
A*x = b
x = b/A
```

`A`

must be invertible, and can't have all 0's rows or columns.

`A.sum(1)`

is done by matrix multiplication, with a (n,1) array of 1s.

With your `mat`

:

```
In [203]: np.allclose(mat*np.mat(np.ones((120,1))), mat.sum(1))
Out[203]: True
```

Doing that myself is actually a bit faster (overhead somewhere?)

```
In [204]: timeit mat.sum(1)
92.7 µs ± 111 ns per loop (mean ± std. dev. of 7 runs, 10000 loops each)
In [205]: timeit mat*np.mat(np.ones((120,1)))
59.2 µs ± 53.1 ns per loop (mean ± std. dev. of 7 runs, 10000 loops each)
```

I could also do this with a sparse matrix:

```
In [209]: mat*sparse.csc_matrix(np.ones((120,1)))
Out[209]:
<100x1 sparse matrix of type '<class 'numpy.float64'>'
with 100 stored elements in Compressed Sparse Column format>
In [211]: np.allclose(mat.sum(1),_.todense())
Out[211]: True
```

But the time is slower, even if I move the sparse creation outside the loop:

```
In [213]: %%timeit I=sparse.csc_matrix(np.ones((120,1)))
...: mat*I
...:
215 µs ± 401 ns per loop (mean ± std. dev. of 7 runs, 1000 loops each)
```

If `mat`

was `(115100,10)`

with lots of all 0 rows, this all sparse approach could give both time and space savings.

`mat[:,:10]`

is also performed with matrix multiplication, with a sparse extractor matrix.

It is actually slower than the row sum:

```
In [247]: timeit mat[:,:10]
305 µs ± 10.4 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
In [248]: timeit mat[:,:10].sum(1)
384 µs ± 9.05 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
```

I can combine the column selection with sum using:

```
In [252]: I = sparse.lil_matrix((120,1),dtype=int); I[:10,:]=1; I=I.tocsc()
In [253]: I
Out[253]:
<120x1 sparse matrix of type '<class 'numpy.int64'>'
with 10 stored elements in Compressed Sparse Column format>
In [254]: np.allclose((mat*I).todense(),mat[:,:10].sum(1))
Out[254]: True
```

Timing on this `mat*I`

is slower, though I could improve the `I`

construction step.

```
I = sparse.csc_matrix((np.ones(10,int), np.arange(10), np.array([0,10])), shape=(120,1))
```

`mat_head`

?`mat_head.shape = (115100,1)`

. In the question, they are none of zeros (upper) and all zeros (lower) examples.