# 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])]
``````
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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]]
``````
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It really does not make sense. I'll ask in the maillist why it is this way. – tillsten Oct 19 '11 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.) – denis Oct 19 '11 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 Sep 8 '13 at 0:56
it succeeds if `m1.nonzero()[0].shape == m2.nonzero()[0].shape`, at least in current version. – kasal Dec 9 '15 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])]` – kasal Dec 9 '15 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.

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