# Indexing numpy array by a numpy array of coordinates

Suppose we have

• an n-dimensional numpy.array A
• a numpy.array B with dtype=int and shape of (n, m)

How do I index A by B so that the result is an array of shape (m,), with values taken from the positions indicated by the columns of B?

For example, consider this code that does what I want when B is a python list:

``````>>> a = np.arange(27).reshape(3,3,3)
>>> a[[0, 1, 2], [0, 0, 0], [1, 1, 2]]
array([ 1, 10, 20])    # the result we're after
>>> bl = [[0, 1, 2], [0, 0, 0], [1, 1, 2]]
>>> a[bl]
array([ 1, 10, 20])   # also works when indexing with a python list
>>> a[bl].shape
(3,)
``````

However, when B is a numpy array, the result is different:

``````>>> b = np.array(bl)
>>> a[b].shape
(3, 3, 3, 3)
``````

Now, I can get the desired result by casting B into a tuple, but surely that cannot be the proper/idiomatic way to do it?

``````>>> a[tuple(b)]
array([ 1, 10, 20])
``````

Is there a numpy function to achieve the same without casting B to a tuple?

One alternative would be converting to linear indices and then index with `np.take` or index into its flattened version -

``````np.take(a,np.ravel_multi_index(b, a.shape))
a.flat[np.ravel_multi_index(b, a.shape)]
``````

Custom `np.ravel_multi_index` for performance boost

We could implement a custom version to simulate the behaviour of `np.ravel_multi_index` to boost the performance, like so -

``````def ravel_index(b, shp):
return np.concatenate((np.asarray(shp[1:])[::-1].cumprod()[::-1],[1])).dot(b)
``````

Using it, the desired output would be found in two ways -

``````np.take(a,ravel_index(b, a.shape))
a.flat[ravel_index(b, a.shape)]
``````

### Benchmarking

Additionall incorporating `tuple` based method from the question and `map` based one from @Kanak's post.

Case #1 : dims = 3

``````In [23]: a = np.random.randint(0,9,([20]*3))

In [24]: b = np.random.randint(0,20,(a.ndim,1000000))

In [25]: %timeit a[tuple(b)]
...: %timeit a[map(np.ravel, b)]
...: %timeit np.take(a,np.ravel_multi_index(b, a.shape))
...: %timeit a.flat[np.ravel_multi_index(b, a.shape)]
...: %timeit np.take(a,ravel_index(b, a.shape))
...: %timeit a.flat[ravel_index(b, a.shape)]
100 loops, best of 3: 6.56 ms per loop
100 loops, best of 3: 6.58 ms per loop
100 loops, best of 3: 6.95 ms per loop
100 loops, best of 3: 9.17 ms per loop
100 loops, best of 3: 6.31 ms per loop
100 loops, best of 3: 8.52 ms per loop
``````

Case #2 : dims = 6

``````In [29]: a = np.random.randint(0,9,([10]*6))

In [30]: b = np.random.randint(0,10,(a.ndim,1000000))

In [31]: %timeit a[tuple(b)]
...: %timeit a[map(np.ravel, b)]
...: %timeit np.take(a,np.ravel_multi_index(b, a.shape))
...: %timeit a.flat[np.ravel_multi_index(b, a.shape)]
...: %timeit np.take(a,ravel_index(b, a.shape))
...: %timeit a.flat[ravel_index(b, a.shape)]
10 loops, best of 3: 40.9 ms per loop
10 loops, best of 3: 40 ms per loop
10 loops, best of 3: 20 ms per loop
10 loops, best of 3: 29.9 ms per loop
100 loops, best of 3: 15.7 ms per loop
10 loops, best of 3: 25.8 ms per loop
``````

Case #3 : dims = 10

``````In [32]: a = np.random.randint(0,9,([4]*10))

In [33]: b = np.random.randint(0,4,(a.ndim,1000000))

In [34]: %timeit a[tuple(b)]
...: %timeit a[map(np.ravel, b)]
...: %timeit np.take(a,np.ravel_multi_index(b, a.shape))
...: %timeit a.flat[np.ravel_multi_index(b, a.shape)]
...: %timeit np.take(a,ravel_index(b, a.shape))
...: %timeit a.flat[ravel_index(b, a.shape)]
10 loops, best of 3: 60.7 ms per loop
10 loops, best of 3: 60.1 ms per loop
10 loops, best of 3: 27.8 ms per loop
10 loops, best of 3: 38 ms per loop
100 loops, best of 3: 18.7 ms per loop
10 loops, best of 3: 29.3 ms per loop
``````

So, it makes sense to look for alternatives when working with higher-dimensional inputs and with large data.

Another alternative that fits your need involves the use of `np.ravel`

``````>>> a[map(np.ravel, b)]
array([ 1, 10, 20])
``````

However not fully `numpy`-based.

Performance-concerns. Updated following the comments below.

Be that as it may, your approach is better than mine, but not better than any of @Divakar's.

``````import numpy as np
import timeit

a = np.arange(27).reshape(3,3,3)
bl = [[0, 1, 2], [0, 0, 0], [1, 1, 2]]
b = np.array(bl)

imps = "from __main__ import np,a,b"
reps = 100000

tup_cas_t = timeit.Timer("a[tuple(b)]", imps).timeit(reps)
map_rav_t = timeit.Timer("a[map(np.ravel, b)]", imps).timeit(reps)
fla_rp1_t = timeit.Timer("np.take(a,np.ravel_multi_index(b, a.shape))", imps).timeit(reps)
fla_rp2_t = timeit.Timer("a.flat[np.ravel_multi_index(b, a.shape)]", imps).timeit(reps)

print tup_cas_t/map_rav_t  ## 0.505382211881
print tup_cas_t/fla_rp1_t  ## 1.18185817386
print tup_cas_t/fla_rp2_t  ## 1.71288705886
``````
• Well `flat` and `np.take` are two separate alternatives. Commented Nov 18, 2017 at 20:58
• @Divakar. Sorry. Blind copy-pasting, one of our worst enemy. Commented Nov 18, 2017 at 21:03
• Also, I would rather use `%timeit` when dealing with such tiny fractioned timings. You don't need to do those, I am just saying for a fair benchmarking that is. Again, OP seems to be going for a idiomatic way. Personal opinion - `tuple` isn't too bad either way. Commented Nov 18, 2017 at 21:04
• Good to know @Divakar. That being said, don't you think that 100000 repetitions ensures a minimum of benchmark-fairness? Also, `%timeit` is an IPython's feature/magic, isn't it ? If so, I do not use iPython. I have actually no reason for not doing so. Commented Nov 18, 2017 at 21:15
• Added some timings with large data and dims in my post. Commented Nov 18, 2017 at 22:07

Are you looking for `numpy.ndarray.tolist()` ?

``````>>> a = np.arange(27).reshape(3,3,3)
>>> bl = [[0, 1, 2], [0, 0, 0], [1, 1, 2]]
>>> b = np.array(bl)
>>> a[b.tolist()]
array([ 1, 10, 20])
``````

Or for arrays indexing arrays which is quite similar to list indexing :

``````>>> a[np.array([0, 1, 2]), np.array([0, 0, 0]), np.array([1, 1, 2])]
array([ 1, 10, 20])
``````

However as you can from the previous link, indexing an array a with an array b directly means you are indexing the first index of a only with your whole b array which can lead to confusing output.