# Understanding weird boolean 2d-array indexing behavior in numpy

Why does this work:

``````a = np.random.rand(10, 20)
x_range = np.arange(10)
y_range = np.arange(20)

a_tmp = a[x_range<5,:]
b = a_tmp[:, np.in1d(y_range, [3,4,8])]
``````

and this does not:

``````a = np.random.rand(10,20)
x_range = np.arange(10)
y_range = np.arange(20)

b = a[x_range<5, np.in1d(y_range,[3,4,8])]
``````

The Numpy reference documentation's page on indexing contains the answers, but requires a bit of careful reading.

The answer here is that indexing with booleans is equivalent to indexing with integer arrays obtained by first transforming the boolean arrays with `np.nonzero`. Therefore, with boolean arrays `m1`, `m2`

``````a[m1, m2] == a[m1.nonzero(), m2.nonzero()]
``````

which (when it succeeds, i.e., `m1.nonzero().shape == m2.nonzero().shape`) is equivalent to:

``````[a[i, i] for i in range(a.shape[0]) if m1[i] and m2[i]]
``````

I'm not sure why it was designed to work like this --- usually, this is not what you'd want.

To get the more intuitive result, you can instead do

``````a[np.ix_(m1, m2)]
``````

which produces a result equivalent to

``````[[a[i,j] for j in range(a.shape[1]) if m2[j]] for i in range(a.shape[0]) if m1[i]]
``````
• It really does not make sense. I'll ask in the maillist why it is this way. Commented Oct 19, 2011 at 12:53
• scipy.org/Cookbook/Indexing p. 14 on Multidimenional Boolean Indexing says "look into numpy's masked array tools ... The obvious approach doesn't give the right answer." (That document is well-written, needs updating.) Commented Oct 19, 2011 at 14:35
• @denis, circa 2013 that document does explain it rather well. However, if you google numpy logical indexing, the document that comes up is docs.scipy.org/doc/numpy/reference/arrays.indexing.html and it isn't explained nearly as well.
– John
Commented Sep 8, 2013 at 0:56
• it succeeds if `m1.nonzero()[0].shape == m2.nonzero()[0].shape`, at least in current version. Commented Dec 9, 2015 at 16:50
• And it is not equivalent to `[a[i,i] ...]` but to `[a[i,j] for i,j in zip(m1.nonzero()[0], m2.nonzero()[0])]` Commented Dec 9, 2015 at 16:57

An alternative to `np.ix_` is to convert the boolean arrays to integer arrays (using `np.nonzero()`), and then use `np.newaxis` to create arrays of the right shape to take advantage of broadcasting.

``````import numpy as np

a=np.random.rand(10,20)
x_range=np.arange(10)
y_range=np.arange(20)

a_tmp=a[x_range<5,:]
b_correct=a_tmp[:,np.in1d(y_range,[3,4,8])]

m1=(x_range<5).nonzero()[0]
m2=np.in1d(y_range,[3,4,8]).nonzero()
b=a[m1[:,np.newaxis], m2]
assert np.allclose(b,b_correct)

b2=a[np.ix_(x_range<5,np.in1d(y_range,[3,4,8]))]
assert np.allclose(b2,b_correct)
``````

`np.ix_` tends to be slower than double indexing. The long-form solution appears to be a bit faster:

long-form:

``````In [83]: %timeit a[(x_range<5).nonzero()[0][:,np.newaxis], (np.in1d(y_range,[3,4,8])).nonzero()[0]]
10000 loops, best of 3: 131 us per loop
``````

double indexing:

``````In [85]: %timeit a[x_range<5,:][:,np.in1d(y_range,[3,4,8])]
10000 loops, best of 3: 144 us per loop
``````

using np.ix_:

``````In [84]: %timeit a[np.ix_(x_range<5,np.in1d(y_range,[3,4,8]))]
10000 loops, best of 3: 160 us per loop
``````

Note: It would be a good idea to test these timings on your machine since the rankings might change depending on your version of Python, numpy, or hardware.

For anyone that still struggles to understand what is going on

`Python for Data Analysis by Wes McKinney` has a good explanations: https://www.oreilly.com/library/view/python-for-data/9781449323592/ch04.html chapter: "Fancy Indexing"

In short.

1. A boolean indexes are converted to arrays of indexes using np.nonzero as @pv. explained.

2. Then we have two "fancy" indexes, which means selecting 1d array of elements for corresponding tuple of indexes.

``````>>> A=np.arange(0,9).reshape(3,-1)*10
>>> A
array([[ 0, 10, 20],
[30, 40, 50],
[60, 70, 80]])

>>> A[[1,2],[0,1]]
array([30, 70])
``````

As you can see it selected the values at indexes 1,0 and 2,1

``````>>> [A[1,0], A[2,1]]
[30, 70]
``````

Another way to achieve this is to select the per-axis indices you want separately, i.e.:

``````A[rows, :][:, cols]
``````

Concrete example:

``````>>> A = np.arange(9).reshape(3, 3)
>>> A
array([[0, 1, 2],
[3, 4, 5],
[6, 7, 8]])

# Slicing works as expected.
>>> A[1:, :2]
array([[3, 4],
[6, 7]])

# Indices that represent slice.
>>> cols = [0, 1]
>>> rows = [1, 2]
# Per OP, counterintuitively different.
>>> A[rows, cols]
array([3, 7])

# Workaround: Select axes separately.
>>> A[rows, :][:, cols]
array([[3, 4],
[6, 7]])
``````

(silly code to produce above text: link)