I'm currently experimenting with `numba`

and especially `vectorized`

functions, so I created a `sum`

vectorized function (because it is easy to compare this to `np.sum`

.

```
import numpy as np
import numba as nb
@nb.vectorize([nb.float64(nb.float64, nb.float64)])
def numba_sum(element1, element2):
return element1 + element2
@nb.vectorize([nb.float64(nb.float64, nb.float64)], target='parallel')
def numba_sum_parallel(element1, element2):
return element1 + element2
array = np.ones(elements)
np.testing.assert_almost_equal(numba_sum.reduce(array), np.sum(array))
np.testing.assert_almost_equal(numba_sum_parallel.reduce(array), np.sum(array))
```

Depending on the number of `elements`

the parallel code does not return the same number as the `cpu`

targeted code. I think that's because of something related to the usual threading-problems (but why? Is that a Bug in Numba or something that just happens when using parallel execution?). Funny is that sometimes it works, sometimes it does not. Sometimes it fails with `elements=1000`

sometimes it starts failing on `elements=100000`

.

For example:

```
AssertionError:
Arrays are not almost equal to 7 decimals
ACTUAL: 93238.0
DESIRED: 100000.0
```

and if I run it again

```
AssertionError:
Arrays are not almost equal to 7 decimals
ACTUAL: 83883.0
DESIRED: 100000.0
```

My question is now: Why would I ever want a *parallel* vectorized function? My understanding is that the purpose of a `vectorized`

function is to provide the numpy-ufunc possibilities but I tested `reduce`

and `accumulate`

and they stop working at some (variable) number of elements and who wants an unreliable function?

I'm using `numba 0.23.1`

, `numpy 1.10.1`

with `python 3.5.1`

.

`reduce`

as an example of a C/Fortran multithreading interface, which does this). If this is done, the answer should be reproducible (and right!). – DavidW Feb 17 '16 at 23:50