*This question contains its own answer at the bottom. Use preallocated arrays.*

Following-up from this question years ago, is there a canonical "shift" function in numpy? I don't see anything from the documentation.

Here's a simple version of what I'm looking for:

```
def shift(xs, n):
if n >= 0:
return np.r_[np.full(n, np.nan), xs[:-n]]
else:
return np.r_[xs[-n:], np.full(-n, np.nan)]
```

Using this is like:

```
In [76]: xs
Out[76]: array([ 0., 1., 2., 3., 4., 5., 6., 7., 8., 9.])
In [77]: shift(xs, 3)
Out[77]: array([ nan, nan, nan, 0., 1., 2., 3., 4., 5., 6.])
In [78]: shift(xs, -3)
Out[78]: array([ 3., 4., 5., 6., 7., 8., 9., nan, nan, nan])
```

_{This question came from my attempt to write a fast rolling_product yesterday. I needed a way to "shift" a cumulative product and all I could think of was to replicate the logic in np.roll().}

So `np.concatenate()`

is much faster than `np.r_[]`

. This version of the function performs a lot better:

```
def shift(xs, n):
if n >= 0:
return np.concatenate((np.full(n, np.nan), xs[:-n]))
else:
return np.concatenate((xs[-n:], np.full(-n, np.nan)))
```

An even faster version simply pre-allocates the array:

```
def shift(xs, n):
e = np.empty_like(xs)
if n >= 0:
e[:n] = np.nan
e[n:] = xs[:-n]
else:
e[n:] = np.nan
e[:n] = xs[-n:]
return e
```

*The above proposal is the answer. Use preallocated arrays.*

`np.r_[np.full(n, np.nan), xs[:-n]]`

could be replaced with`np.r_[[np.nan]*n, xs[:-n]]`

likewise for other condition, without the need of`np.full`

`[np.nan]*n`

is plain python and will therefore be slower than`np.full(n, np.nan)`

. Not for small`n`

, but it will be transformed to numpy array by np.r_ which takes away the advantage.`[np.nan]*n`

is faster than`np.full(n, np.nan)`

for`n=[10,1000,10000]`

. Need to check if`np.r_`

takes a hit.