Unfortunately the simple solution `x/numpy.linalg.norm(x)`

doesn't work if `x`

is an array of vectors. But with a simple `reshape()`

you can force it into a flat list, use a list comprehension, and use `reshape()`

again to get back the original shape.

```
s=x.shape
np.array([ v/np.linalg.norm(v) for v in x.reshape(-1, s[-1])]).reshape(s)
```

First we store the shape of the array

```
s=x.shape
```

Then we reshape it into a simple (one-dimensional) array of vectors

```
x.reshape(-1, s[-1])
```

by making use of the '-1' argument of `reshape()`

which essentially means "take as many as it needs", e.g . if `x`

was a (4,5,3) array, `x.reshape(-1,3)`

would be of shape (20,3). The use of `s[-1]`

allows for an arbitrary dimension of the vectors.

Then we use a list comprehension to step through the array and calculate the unit vector one vector at a time

```
[ v/np.linalg.norm(v) for v in x.reshape(-1, s[-1])]
```

and finally we turn it back into an numpy array and give it back its original shape

```
np.array([ v/np.linalg.norm(v) for v in x.reshape(-1, s[-1])]).reshape(s)
```

`raise`

an exception!`x/np.linalg.norm(x)`

was not much slower (about 15-20%) than`x/np.sqrt((x**2).sum())`

in numpy 1.15.1 on a CPU.