# NumPy: how to quickly normalize many vectors?

How can a list of vectors be elegantly normalized, in NumPy?

Here is an example that does not work:

``````from numpy import *

vectors = array([arange(10), arange(10)])  # All x's, then all y's
norms = apply_along_axis(linalg.norm, 0, vectors)

# Now, what I was expecting would work:
print vectors.T / norms  # vectors.T has 10 elements, as does norms, but this does not work
``````

The last operation yields "shape mismatch: objects cannot be broadcast to a single shape".

How can the normalization of the 2D vectors in `vectors` be elegantly done, with NumPy?

Edit: Why does the above not work while adding a dimension to `norms` does work (as per my answer below)?

-
FYI, a commenter may have a faster method, I edited my answer with more detail. –  Geoff Oct 26 '13 at 15:21

Well, unless I missed something, this does work:

``````vectors / norms
``````

The problem in your suggestion is the broadcasting rules.

``````vectors  # shape 2, 10
norms  # shape 10
``````

The shape do not have the same length! So the rule is to first extend the small shape by one on the left:

``````norms  # shape 1,10
``````

You can do that manually by calling:

``````vectors / norms.reshape(1,-1)  # same as vectors/norms
``````

If you wanted to compute `vectors.T/norms`, you would have to do the reshaping manually, as follows:

``````vectors.T / norms.reshape(-1,1)  # this works
``````
-
why not just do (vectors/norms).T if the OP wants this transposed. It seems both simple and elegant to me. –  Justin Peel May 17 '10 at 18:58
Ah, ah! so the dimension extension is done on the left: this indeed explains the observed behavior. Thanks! –  EOL May 17 '10 at 19:58

# Computing the magnitude

I came across this question and became curious about your method for normalizing. I use a different method to compute the magnitudes. Note: I also typically compute norms across the last index (rows in this case, not columns).

``````magnitudes = np.sqrt((vectors ** 2).sum(-1))[..., np.newaxis]
``````

Typically, however, I just normalize like so:

``````vectors /= np.sqrt((vectors ** 2).sum(-1))[..., np.newaxis]
``````

# A time comparison

I ran a test to compare the times, and found that my method is faster by quite a bit, but Freddie Witherdon's suggestion is even faster.

``````import numpy as np
vectors = np.random.rand(100, 25)

# OP's
%timeit np.apply_along_axis(np.linalg.norm, 1, vectors)
# Output: 100 loops, best of 3: 2.39 ms per loop

# Mine
%timeit np.sqrt((vectors ** 2).sum(-1))[..., np.newaxis]
# Output: 10000 loops, best of 3: 13.8 us per loop

# Freddie's (from comment below)
%timeit np.sqrt(np.einsum('...i,...i', vectors, vectors))
# Output: 10000 loops, best of 3: 6.45 us per loop
``````

Beware though, as this StackOverflow answer notes, there are some safety checks not happening with `einsum`, so you should be sure that the `dtype` of `vectors` is sufficient to store the square of the magnitudes accurately enough.

-
Interesting timing results (I obtain respectively 0.8 s and 1.4 s, with the more robust %timeit function of IPython), thanks! –  EOL Oct 8 '12 at 8:53
I have found `np.sqrt(np.einsum('...i,...i', vectors, vectors))` to be ~4 times faster than Method 1 as given above. –  Freddie Witherden Sep 27 '13 at 23:07
@FreddieWitherden - Thanks for the comment, I didn't know about `einsum`. There's in interesting related SO question here: stackoverflow.com/questions/18365073/… It will typically be faster, but may not be safe (depending on the `dtype` of the vector). –  Geoff Oct 26 '13 at 15:04
@FreddieWitherden, your method gives different (but `np.allclose`) values to mine. –  Geoff Oct 26 '13 at 15:19
@EOL - Thanks, I switched to ipython, and updated my answer. It turns out my HUGE array was giving some serious overhead. With a smaller one (in my new answer) the speed difference is much more noticeable. –  Geoff Oct 26 '13 at 15:21
show 2 more comments

Alright: NumPy's array shape broadcast adds dimensions to the left of the array shape, not to its right. NumPy can however be instructed to add a dimension to the right of the `norms` array:

``````print vectors.T / norms[:, newaxis]
``````

does work!

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Just a note, I use `norms[..., np.newaxis]` in case the matrix is not just 2D. It would work with a 3D (or more) tensor as well. –  Geoff Oct 26 '13 at 15:22

there is already a function in scikit learn:

``````import sklearn.preprocessing as preprocessing
norm =preprocessing.normalize(m, norm='l2')*
``````