# Mapping element-wise a NumPy array into an array of more dimensions

I want map a `numpy.array` from NxM to NxMx3, where a vector of three elements is a function of the original entry:

``````lambda x: [f1(x), f2(x), f3(x)]
``````

However, things like `numpy.vectorize` do not allow to change dimensions. Sure, I can create an array of zeros and make a loop (and it is what I am doing by now), but it does not sound neither Pythonic nor efficient (as every looping in Python).

Is there a better way to perform an elementwise operation on numpy.array, producing a vector for each entry?

• If `N` and `M` are significantly larger than 3, the looping over the third dimension will have an insignificant effect on performance. And there's nothing un-pythonic in using for loops! What isn't very numpythonic or efficient is using `np.vectorize`. You could try to convert `f1`, `f2` and `f3` into a single function that took arrays and returned arrays. Without knowing what your functions are doing, it is not possible to know if this approach would suit your problem. – Jaime Jun 15 '13 at 14:07
• @Jaime I am looping over N and M, not 3. The problem is conversion of complex numbers in three floats [R, G, B], so I can plot a complex function (see the link in the question). – Piotr Migdal Jun 16 '13 at 13:05

Now that I see your code, for most simple mathematical operations you can let numpy do the looping, what is often referred to as vectorization:

``````def complex_array_to_rgb(X, theme='dark', rmax=None):
'''Takes an array of complex number and converts it to an array of [r, g, b],
where phase gives hue and saturaton/value are given by the absolute value.
Especially for use with imshow for complex plots.'''
absmax = rmax or np.abs(X).max()
Y = np.zeros(X.shape + (3,), dtype='float')
Y[..., 0] = np.angle(X) / (2 * pi) % 1
if theme == 'light':
Y[..., 1] = np.clip(np.abs(X) / absmax, 0, 1)
Y[..., 2] = 1
elif theme == 'dark':
Y[..., 1] = 1
Y[..., 2] = np.clip(np.abs(X) / absmax, 0, 1)
Y = matplotlib.colors.hsv_to_rgb(Y)
return Y
``````

This code should run much faster than yours.

• I didn't knew that it is possible to reference subarrays as `Y[..., i]` or `Y[i, ...]`. Thanks! Is there a particular name for this operation? (I was googling vectorization, but it returns things like `np.vectorize`.) – Piotr Migdal Jun 16 '13 at 17:06
• It´s the ellipsis notation. Corrected the typo. – Jaime Jun 17 '13 at 7:22
• I see. Now I see some notes on it: stackoverflow.com/a/773472/907575 and stackoverflow.com/questions/118370/…. – Piotr Migdal Jun 17 '13 at 10:41

If I understand your problem correctly, I suggest you use `np.dstack`:

``````Docstring:
Stack arrays in sequence depth wise (along third axis).

Takes a sequence of arrays and stack them along the third axis
to make a single array. Rebuilds arrays divided by `dsplit`.
This is a simple way to stack 2D arrays (images) into a single
3D array for processing.
``````

``````    In [1]: a = np.arange(9).reshape(3, 3)

In [2]: a
Out[2]:
array([[0, 1, 2],
[3, 4, 5],
[6, 7, 8]])

In [3]: x, y, z = a*1, a*2, a*3  # in your case f1(a), f2(a), f3(a)

In [4]: np.dstack((x, y, z))
Out[4]:
array([[[ 0,  0,  0],
[ 1,  2,  3],
[ 2,  4,  6]],

[[ 3,  6,  9],
[ 4,  8, 12],
[ 5, 10, 15]],

[[ 6, 12, 18],
[ 7, 14, 21],
[ 8, 16, 24]]])
``````
• I would avoid defining `x,y,z` before to save memory, calling the functions inside `np.dstack()` – Saullo G. P. Castro Jun 15 '13 at 18:45
• @sgpc -- You are right. I only did it for greater clarity. – root Jun 15 '13 at 18:52
• +1 Nice and works. I accepted Jaime's answer as it is more convenient for my purpose and for some generalizations. – Piotr Migdal Jun 16 '13 at 17:09