I think it's in the implementation of the np.sum(). For example:

```
import numpy as np
A = np.random.standard_normal((10000,10000))
C = np.array(A, order='C')
F = np.array(A, order='F')
```

Benchmarking with Ipython:

```
In [7]: %timeit C.sum(axis=0)
10 loops, best of 3: 101 ms per loop
In [8]: %timeit C.sum(axis=1)
10 loops, best of 3: 149 ms per loop
In [9]: %timeit F.sum(axis=0)
10 loops, best of 3: 149 ms per loop
In [10]: %timeit F.sum(axis=1)
10 loops, best of 3: 102 ms per loop
```

So it's behaving exactly the opposite as expected. But let's try out some other function:

```
In [17]: %timeit np.amax(C, axis=0)
1 loop, best of 3: 173 ms per loop
In [18]: %timeit np.amax(C, axis=1)
10 loops, best of 3: 70.4 ms per loop
In [13]: %timeit np.amax(F,axis=0)
10 loops, best of 3: 72 ms per loop
In [14]: %timeit np.amax(F,axis=1)
10 loops, best of 3: 168 ms per loop
```

Sure, it's apples to oranges. But np.amax() works along the axis as does sum and returns a vector with one element for each row/column. And behaves as one would expect.

```
In [25]: C.strides
Out[25]: (80000, 8)
In [26]: F.strides
Out[26]: (8, 80000)
```

Tells us that the arrays are in fact packed in row-order and column-order and looping in that direction should be a lot faster. Unless for example the sum sums each row by row as it travels along the columns for providing the column sum (axis=0). But without a mean of peeking inside the .pyd I'm just speculating.

EDIT:

From percusse 's link: http://docs.scipy.org/doc/numpy/reference/generated/numpy.ufunc.reduce.html

Reduces a‘s dimension by one, by applying ufunc along one axis.

Let a.shape = (N_0, ..., N_i, ..., N_{M-1}).
Then ufunc.reduce(a, axis=i)[k_0, ..,k_{i-1}, k_{i+1}, .., k_{M-1}] = the result of iterating j over range(N_i), cumulatively applying ufunc to each
a[k_0, ..,k_{i-1}, j, k_{i+1}, .., k_{M-1}]

So in pseudocode, when calling F.sum(axis=0):

```
for j=cols #axis=0
for i=rows #axis=1
sum(j,i)=F(j,i)+sum(j-1,i)
```

So it would actually iterate over the row when calculating the column sum, slowing down considerably when in column-major order. Behaviour such as this would explain the difference.

eric's link provides us with the implementation, for somebody curious enough to go through large amounts of code for the reason.

`b.sum(axis=0)`

is 2.51s and`c.sum(axis=0)`

is 0.14s`numpy`

are you using?`np.add.reduce(x, axis=0)`

shows the same behaviour, and is what`sum`

does under the hood