Is it possible to use argsort in descending order

Consider the following code:

``````avgDists = [1, 8, 6, 9, 4]
ids = np.array(avgDists).argsort()[:n]
``````

This gives me indices of the `n` smallest elements. Is it possible to use this same `argsort` in descending order to get the indices of `n` highest elements ?

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Isn't it simply `ids = np.array(avgDists).argsort()[-n:]`? –  Jaime May 10 '13 at 16:50
@Jaime: No, that doesn't work. 'right answer' is `[3, 1, 2]`. Your line produces `[2, 1, 3]` (if n==3 as an example) –  dawg May 11 '13 at 3:01
@drewk Well, then make it `ids = np.array(avgDists).argsort()[-n:][::-1]`. The thing is avoiding making a copy of the whole list, which is what you get when you add a `-` in front of it. Not relevant for the OP's small example, could be for larger cases. –  Jaime May 11 '13 at 14:46
@Jaime: You are right. See my updated answer. The syntax tho is just opposite from your comment on the ending slice: `np.array(avgDists).argsort()[::-1][:n]` will do it. Also, if you are going to use numpy, stay in numpy. First convert the list to an array: `avgDist=np.array(avgDists)` then it becomes `avgDist.argsort()[::-1][:n}` –  dawg May 11 '13 at 18:33

``````(-np.array(avgDists)).argsort()[:n]
``````

edit: The suggestion in dawg's answer is arguably better, because it avoids calculating the negation of the array (which creates a copy):

``````np.array(avgDists).argsort()[::-1][:n]
``````

These answers both give equivalent results.

However, it should be noted that this does not actually improve the time-complexity for large datasets. It replaces the O(n) negation with an O(1) slice, but the dominant term remains the argsort at O(n log n).

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It is even more efficient to slice before reversing, i.e., `np.array(avgDists).argsort()[:-n][::-1]` –  nedim Jul 16 at 9:06

Just like Python, in that `[::-1]` reverses the array returned by `argsort()` and `[:n]` gives that last n elements:

``````>>> avgDists=np.array([1, 8, 6, 9, 4])
>>> n=3
>>> ids = avgDists.argsort()[::-1][:n]
>>> ids
array([3, 1, 2])
``````

The advantage of this method is that `ids` is a view of avgDists:

``````>>> ids.flags
C_CONTIGUOUS : False
F_CONTIGUOUS : False
OWNDATA : False
WRITEABLE : True
ALIGNED : True
UPDATEIFCOPY : False
``````

(The 'OWNDATA' being False indicates this is a view, not a copy)

Another way to do this is something like:

``````(-avgDists).argsort()[:n]
``````

The problem is that the way this works is to create negative of each element in the array:

``````>>> (-avgDists)
array([-1, -8, -6, -9, -4])
``````

ANd creates a copy to do so:

``````>>> (-avgDists_n).flags['OWNDATA']
True
``````

So if you time each, even with this very small data set:

``````>>> import timeit
>>> timeit.timeit('(-avgDists).argsort()[:3]', setup="from __main__ import avgDists")
4.2879798610229045
>>> timeit.timeit('avgDists.argsort()[::-1][:3]', setup="from __main__ import avgDists")
2.8372560259886086
``````

The view method is substantially faster

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This answer is good, but I feel your wording misrepresents the real performance characteristics: "even with this very small data set, the view method is substantially faster". In reality, the negation is O(n) and the argsort is O(n log n). This means the timing discrepancy will diminish for larger data sets - the O(n log n) term dominates, however your suggestion is an optimisation of the O(n) part. So the complexity remains the same, and it's for this small data set in particular that we see any significant differences. –  wim Jul 15 at 21:51

You could create a copy of the array and then multiply each element with -1.
As an effect the before largest elements would become the smallest.
The indeces of the n smallest elements in the copy are the n greatest elements in the original.

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