# How do I get indices of N maximum values in a NumPy array?

NumPy proposes a way to get the index of the maximum value of an array via `np.argmax`.

I would like a similar thing, but returning the indexes of the `N` maximum values.

For instance, if I have an array, `[1, 3, 2, 4, 5]`, then `nargmax(array, n=3)` would return the indices `[4, 3, 1]` which correspond to the elements `[5, 4, 3]`.

• Your question is not really well defined. For example, what would the indices (you expect) to be for `array([5, 1, 5, 5, 2, 3, 2, 4, 1, 5])`, whit `n= 3`? Which one of all the alternatives, like `[0, 2, 3]`, `[0, 2, 9]`, `...` would be the correct one? Please elaborate more on your specific requirements. Thanks
– eat
Aug 2, 2011 at 17:02
• @eat, I don't really care about which one is supposed to be returned in this specific case. Even if it seem logical to return the first one encountered, that's not a requirement for me. Aug 3, 2011 at 16:46
• `argsort` might be a viable alternative if you do not care about the order of the returned indeces. See my answer below.
– blue
May 13, 2016 at 14:24

## 20 Answers

Newer NumPy versions (1.8 and up) have a function called `argpartition` for this. To get the indices of the four largest elements, do

``````>>> a = np.array([9, 4, 4, 3, 3, 9, 0, 4, 6, 0])
>>> a
array([9, 4, 4, 3, 3, 9, 0, 4, 6, 0])

>>> ind = np.argpartition(a, -4)[-4:]
>>> ind
array([1, 5, 8, 0])

>>> top4 = a[ind]
>>> top4
array([4, 9, 6, 9])
``````

Unlike `argsort`, this function runs in linear time in the worst case, but the returned indices are not sorted, as can be seen from the result of evaluating `a[ind]`. If you need that too, sort them afterwards:

``````>>> ind[np.argsort(a[ind])]
array([1, 8, 5, 0])
``````

To get the top-k elements in sorted order in this way takes O(n + k log k) time.

• @varela `argpartition` runs in linear time, O(n), using the introselect algorithm. The subsequent sort only handles k elements, so that runs in O(k log k). Nov 26, 2014 at 15:52
• If anybody is wondering how exactly `np.argpartition` and its sister algorithm `np.partition` work there is a more detailed explanation in the linked question: stackoverflow.com/questions/10337533/… Mar 30, 2016 at 14:49
• @FredFoo: why did you use -4? did you do that to start backward?(since k being positive or negative works the same for me! it only prints the smallest numbers first! Nov 19, 2016 at 10:27
• @LKT use `a=np.array([9, 4, 4, 3, 3, 9, 0, 4, 6, 0])` because normal python lists do not support indexing by lists, unlike `np.array` Aug 8, 2017 at 19:34
• @Umangsinghal `np.argpartition` takes an optional `axis` argument. To find the indices of the top n values for each row: `np.argpartition(a, -n, axis=1)[-n:]` Jun 6, 2019 at 12:06

The simplest I've been able to come up with is:

``````In [1]: import numpy as np

In [2]: arr = np.array([1, 3, 2, 4, 5])

In [3]: arr.argsort()[-3:][::-1]
Out[3]: array([4, 3, 1])
``````

This involves a complete sort of the array. I wonder if `numpy` provides a built-in way to do a partial sort; so far I haven't been able to find one.

If this solution turns out to be too slow (especially for small `n`), it may be worth looking at coding something up in Cython.

• Could line 3 be written equivalently as `arr.argsort()[-1:-4:-1]`? I've tried it in interpreter and it comes up with the same result, but I'm wondering if it's not broken by some example. Sep 20, 2012 at 9:05
• @abroekhof Yes that should be equivalent for any list or array. Alternatively, this could be done without the reversal by using `np.argsort(-arr)[:3]`, which I find more readable and to the point. May 29, 2013 at 19:48
• what does [::-1] mean? @NPE Oct 17, 2016 at 5:29
• `arr.argsort()[::-1][:n]` is better because it returns empty for `n=0` instead of the full array Sep 8, 2017 at 1:34
• @NPE numpy has the function `argpartition` which will isolate the top K elements from the rest without doing a full sort, and then the sorting can be done only on those K.
– ely
Jul 12, 2019 at 12:44

Simpler yet:

``````idx = (-arr).argsort()[:n]
``````

where n is the number of maximum values.

• Can this be done for a 2d array? If not, do you perhaps know how? Sep 23, 2015 at 2:17
• @AndrewHundt : simply use (-arr).argsort(axis=-1)[:, :n] Dec 29, 2018 at 3:44
• similar would be `arr[arr.argsort()[-n:]]` instead of negating the array, just take a slice of the last n elements Mar 12, 2019 at 3:50
• `ind = np.argsort(-arr,axis=0)[:4]` worked for me to find out first 4 index coloum wise May 20, 2021 at 16:54

Use:

``````>>> import heapq
>>> import numpy
>>> a = numpy.array([1, 3, 2, 4, 5])
>>> heapq.nlargest(3, range(len(a)), a.take)
[4, 3, 1]
``````

For regular Python lists:

``````>>> a = [1, 3, 2, 4, 5]
>>> heapq.nlargest(3, range(len(a)), a.__getitem__)
[4, 3, 1]
``````

If you use Python 2, use `xrange` instead of `range`.

Source: heapq — Heap queue algorithm

• There's no need of a loop at all here: `heapq.nlargest(3, xrange(len(a)), a.take)`. For Python lists we can use `.__getitem__` instead of `.take`. Oct 28, 2014 at 9:09
• For n-dimensional arrays `A` in general: `heapq.nlargest(3, range(len(A.ravel())), A.ravel().take)`. (I hope this only operates on views, see also (`ravel vs flatten`](stackoverflow.com/a/28930580/603003)). Nov 10, 2017 at 17:57

If you happen to be working with a multidimensional array then you'll need to flatten and unravel the indices:

``````def largest_indices(ary, n):
"""Returns the n largest indices from a numpy array."""
flat = ary.flatten()
indices = np.argpartition(flat, -n)[-n:]
indices = indices[np.argsort(-flat[indices])]
return np.unravel_index(indices, ary.shape)
``````

For example:

``````>>> xs = np.sin(np.arange(9)).reshape((3, 3))
>>> xs
array([[ 0.        ,  0.84147098,  0.90929743],
[ 0.14112001, -0.7568025 , -0.95892427],
[-0.2794155 ,  0.6569866 ,  0.98935825]])
>>> largest_indices(xs, 3)
(array([2, 0, 0]), array([2, 2, 1]))
>>> xs[largest_indices(xs, 3)]
array([ 0.98935825,  0.90929743,  0.84147098])
``````

If you don't care about the order of the K-th largest elements you can use `argpartition`, which should perform better than a full sort through `argsort`.

``````K = 4 # We want the indices of the four largest values
a = np.array([0, 8, 0, 4, 5, 8, 8, 0, 4, 2])
np.argpartition(a,-K)[-K:]
array([4, 1, 5, 6])
``````

Credits go to this question.

I ran a few tests and it looks like `argpartition` outperforms `argsort` as the size of the array and the value of K increase.

## Three Answers Compared For Coding Ease And Speed

Speed was important for my needs, so I tested three answers to this question.

Code from those three answers was modified as needed for my specific case.

I then compared the speed of each method.

Coding wise:

1. NPE's answer was the next most elegant and adequately fast for my needs.
2. Fred Foos answer required the most refactoring for my needs but was the fastest. I went with this answer, because even though it took more work, it was not too bad and had significant speed advantages.
3. off99555's answer was the most elegant, but it is the slowest.

### Complete Code for Test and Comparisons

``````import numpy as np
import time
import random
import sys
from operator import itemgetter
from heapq import nlargest

''' Fake Data Setup '''
a1 = list(range(1000000))
random.shuffle(a1)
a1 = np.array(a1)

''' ################################################ '''
''' NPE's Answer Modified A Bit For My Case '''
t0 = time.time()
indices = np.flip(np.argsort(a1))[:5]
results = []
for index in indices:
results.append((index, a1[index]))
t1 = time.time()
print("NPE's Answer:")
print(results)
print(t1 - t0)
print()

''' Fred Foos Answer Modified A Bit For My Case'''
t0 = time.time()
indices = np.argpartition(a1, -6)[-5:]
results = []
for index in indices:
results.append((a1[index], index))
results.sort(reverse=True)
results = [(b, a) for a, b in results]
t1 = time.time()
print("Fred Foo's Answer:")
print(results)
print(t1 - t0)
print()

''' off99555's Answer - No Modification Needed For My Needs '''
t0 = time.time()
result = nlargest(5, enumerate(a1), itemgetter(1))
t1 = time.time()
print("off99555's Answer:")
print(result)
print(t1 - t0)
``````

## Output with Speed Reports

``````NPE's Answer:
[(631934, 999999), (788104, 999998), (413003, 999997), (536514, 999996), (81029, 999995)]
0.1349949836730957

Fred Foo's Answer:
[(631934, 999999), (788104, 999998), (413003, 999997), (536514, 999996), (81029, 999995)]
0.011161565780639648

off99555's Answer:
[(631934, 999999), (788104, 999998), (413003, 999997), (536514, 999996), (81029, 999995)]
0.439760684967041
``````

For multidimensional arrays you can use the `axis` keyword in order to apply the partitioning along the expected axis.

``````# For a 2D array
indices = np.argpartition(arr, -N, axis=1)[:, -N:]
``````

And for grabbing the items:

``````x = arr.shape[0]
arr[np.repeat(np.arange(x), N), indices.ravel()].reshape(x, N)
``````

But note that this won't return a sorted result. In that case you can use `np.argsort()` along the intended axis:

``````indices = np.argsort(arr, axis=1)[:, -N:]

# Result
x = arr.shape[0]
arr[np.repeat(np.arange(x), N), indices.ravel()].reshape(x, N)
``````

Here is an example:

``````In [42]: a = np.random.randint(0, 20, (10, 10))

In [44]: a
Out[44]:
array([[ 7, 11, 12,  0,  2,  3,  4, 10,  6, 10],
[16, 16,  4,  3, 18,  5, 10,  4, 14,  9],
[ 2,  9, 15, 12, 18,  3, 13, 11,  5, 10],
[14,  0,  9, 11,  1,  4,  9, 19, 18, 12],
[ 0, 10,  5, 15,  9, 18,  5,  2, 16, 19],
[14, 19,  3, 11, 13, 11, 13, 11,  1, 14],
[ 7, 15, 18,  6,  5, 13,  1,  7,  9, 19],
[11, 17, 11, 16, 14,  3, 16,  1, 12, 19],
[ 2,  4, 14,  8,  6,  9, 14,  9,  1,  5],
[ 1, 10, 15,  0,  1,  9, 18,  2,  2, 12]])

In [45]: np.argpartition(a, np.argmin(a, axis=0))[:, 1:] # 1 is because the first item is the minimum one.
Out[45]:
array([[4, 5, 6, 8, 0, 7, 9, 1, 2],
[2, 7, 5, 9, 6, 8, 1, 0, 4],
[5, 8, 1, 9, 7, 3, 6, 2, 4],
[4, 5, 2, 6, 3, 9, 0, 8, 7],
[7, 2, 6, 4, 1, 3, 8, 5, 9],
[2, 3, 5, 7, 6, 4, 0, 9, 1],
[4, 3, 0, 7, 8, 5, 1, 2, 9],
[5, 2, 0, 8, 4, 6, 3, 1, 9],
[0, 1, 9, 4, 3, 7, 5, 2, 6],
[0, 4, 7, 8, 5, 1, 9, 2, 6]])

In [46]: np.argpartition(a, np.argmin(a, axis=0))[:, -3:]
Out[46]:
array([[9, 1, 2],
[1, 0, 4],
[6, 2, 4],
[0, 8, 7],
[8, 5, 9],
[0, 9, 1],
[1, 2, 9],
[3, 1, 9],
[5, 2, 6],
[9, 2, 6]])

In [89]: a[np.repeat(np.arange(x), 3), ind.ravel()].reshape(x, 3)
Out[89]:
array([[10, 11, 12],
[16, 16, 18],
[13, 15, 18],
[14, 18, 19],
[16, 18, 19],
[14, 14, 19],
[15, 18, 19],
[16, 17, 19],
[ 9, 14, 14],
[12, 15, 18]])
``````
• I think you can simplify the indexing here by using `np.take_along_axis` (which likely did not exist when you answered this question)
– Eric
Dec 19, 2019 at 11:33
• The default axis parameter for np.argpartition is -1 so no need set it to 1 in your 2D array case. Jan 27 at 18:42

Method `np.argpartition` only returns the k largest indices, performs a local sort, and is faster than `np.argsort`(performing a full sort) when array is quite large. But the returned indices are NOT in ascending/descending order. Let's say with an example:

We can see that if you want a strict ascending order top k indices, `np.argpartition` won't return what you want.

Apart from doing a sort manually after np.argpartition, my solution is to use PyTorch, `torch.topk`, a tool for neural network construction, providing NumPy-like APIs with both CPU and GPU support. It's as fast as NumPy with MKL, and offers a GPU boost if you need large matrix/vector calculations.

Strict ascend/descend top k indices code will be:

Note that `torch.topk` accepts a torch tensor, and returns both top k values and top k indices in type `torch.Tensor`. Similar with np, torch.topk also accepts an axis argument so that you can handle multi-dimensional arrays/tensors.

• Code snippets are replicate when you share screenshots. Code blocks will be much appreciated. Jan 27 at 18:40

This will be faster than a full sort depending on the size of your original array and the size of your selection:

``````>>> A = np.random.randint(0,10,10)
>>> A
array([5, 1, 5, 5, 2, 3, 2, 4, 1, 0])
>>> B = np.zeros(3, int)
>>> for i in xrange(3):
...     idx = np.argmax(A)
...     B[i]=idx; A[idx]=0 #something smaller than A.min()
...
>>> B
array([0, 2, 3])
``````

It, of course, involves tampering with your original array. Which you could fix (if needed) by making a copy or replacing back the original values. ...whichever is cheaper for your use case.

• FWIW, your solution won't provide unambiguous solution in all situations. OP should describe how to handle these unambiguous cases. Thanks
– eat
Aug 2, 2011 at 17:09
• @eat The OP's question is a little ambiguous. An implementation, however, is not really open to interpretation. :) The OP should simply refer to the definition of np.argmax docs.scipy.org/doc/numpy/reference/generated/numpy.argmax.html to be sure this specific solution meets the requirements. It's possible that any solution meeting the OP's stated reqirement is acceptable..
– Paul
Aug 2, 2011 at 18:05
• Well, one might consider the implementation of `argmax(.)` to be unambiguous as well. (IMHO it tries to follow some kind of short circuiting logic, but unfortunately fails to provide universally acceptable behavior). Thanks
– eat
Aug 2, 2011 at 18:50

Use:

``````from operator import itemgetter
from heapq import nlargest
result = nlargest(N, enumerate(your_list), itemgetter(1))
``````

Now the `result` list would contain N tuples (`index`, `value`) where `value` is maximized.

Use:

``````def max_indices(arr, k):
'''
Returns the indices of the k first largest elements of arr
(in descending order in values)
'''
assert k <= arr.size, 'k should be smaller or equal to the array size'
arr_ = arr.astype(float)  # make a copy of arr
max_idxs = []
for _ in range(k):
max_element = np.max(arr_)
if np.isinf(max_element):
break
else:
idx = np.where(arr_ == max_element)
max_idxs.append(idx)
arr_[idx] = -np.inf
return max_idxs
``````

It also works with 2D arrays. For example,

``````In [0]: A = np.array([[ 0.51845014,  0.72528114],
[ 0.88421561,  0.18798661],
[ 0.89832036,  0.19448609],
[ 0.89832036,  0.19448609]])
In [1]: max_indices(A, 8)
Out[1]:
[(array([2, 3], dtype=int64), array([0, 0], dtype=int64)),
(array([1], dtype=int64), array([0], dtype=int64)),
(array([0], dtype=int64), array([1], dtype=int64)),
(array([0], dtype=int64), array([0], dtype=int64)),
(array([2, 3], dtype=int64), array([1, 1], dtype=int64)),
(array([1], dtype=int64), array([1], dtype=int64))]

In [2]: A[max_indices(A, 8)[0]][0]
Out[2]: array([ 0.89832036])
``````
• Works good, but gives more results if you have duplicate (maximum) values in your array A. I would expect exactly k results but in case of duplicate values, you get more than k results. Feb 21, 2018 at 12:53
• I slightly modified the code. The list of indices that is returned has length equal exactly to k. If you have duplicates, they are grouped into a single tuple. Feb 21, 2018 at 16:04

The following is a very easy way to see the maximum elements and its positions. Here `axis` is the domain; `axis` = 0 means column wise maximum number and `axis` = 1 means row wise max number for the 2D case. And for higher dimensions it depends upon you.

``````M = np.random.random((3, 4))
print(M)
print(M.max(axis=1), M.argmax(axis=1))
``````

Here's a more complicated way that increases n if the nth value has ties:

``````>>>> def get_top_n_plus_ties(arr,n):
>>>>     sorted_args = np.argsort(-arr)
>>>>     thresh = arr[sorted_args[n]]
>>>>     n_ = np.sum(arr >= thresh)
>>>>     return sorted_args[:n_]
>>>> get_top_n_plus_ties(np.array([2,9,8,3,0,2,8,3,1,9,5]),3)
array([1, 9, 2, 6])
``````

I found it most intuitive to use `np.unique`.

The idea is, that the unique method returns the indices of the input values. Then from the max unique value and the indicies, the position of the original values can be recreated.

``````multi_max = [1,1,2,2,4,0,0,4]
uniques, idx = np.unique(multi_max, return_inverse=True)
print np.squeeze(np.argwhere(idx == np.argmax(uniques)))
>> [4 7]
``````

I think the most time efficiency way is manually iterate through the array and keep a k-size min-heap, as other people have mentioned.

And I also come up with a brute force approach:

``````top_k_index_list = [ ]
for i in range(k):
top_k_index_list.append(np.argmax(my_array))
my_array[top_k_index_list[-1]] = -float('inf')
``````

Set the largest element to a large negative value after you use argmax to get its index. And then the next call of argmax will return the second largest element. And you can log the original value of these elements and recover them if you want.

• TypeError: 'float' object cannot be interpreted as an integer Feb 25 at 21:54

This code works for a numpy 2D matrix array:

``````mat = np.array([[1, 3], [2, 5]]) # numpy matrix

n = 2  # n
n_largest_mat = np.sort(mat, axis=None)[-n:] # n_largest
tf_n_largest = np.zeros((2,2), dtype=bool) # all false matrix
for x in n_largest_mat:
tf_n_largest = (tf_n_largest) | (mat == x) # true-false

n_largest_elems = mat[tf_n_largest] # true-false indexing
``````

This produces a true-false n_largest matrix indexing that also works to extract n_largest elements from a matrix array

When top_k<<axis_length,it better than argsort.

``````import numpy as np

def get_sorted_top_k(array, top_k=1, axis=-1, reverse=False):
if reverse:
axis_length = array.shape[axis]
partition_index = np.take(np.argpartition(array, kth=-top_k, axis=axis),
range(axis_length - top_k, axis_length), axis)
else:
partition_index = np.take(np.argpartition(array, kth=top_k, axis=axis), range(0, top_k), axis)
top_scores = np.take_along_axis(array, partition_index, axis)
# resort partition
sorted_index = np.argsort(top_scores, axis=axis)
if reverse:
sorted_index = np.flip(sorted_index, axis=axis)
top_sorted_scores = np.take_along_axis(top_scores, sorted_index, axis)
top_sorted_indexes = np.take_along_axis(partition_index, sorted_index, axis)
return top_sorted_scores, top_sorted_indexes

if __name__ == "__main__":
import time
from sklearn.metrics.pairwise import cosine_similarity

x = np.random.rand(10, 128)
y = np.random.rand(1000000, 128)
z = cosine_similarity(x, y)
start_time = time.time()
sorted_index_1 = get_sorted_top_k(z, top_k=3, axis=1, reverse=True)[1]
print(time.time() - start_time)
``````

You can simply use a dictionary to find top k values & indices in a numpy array. For example, if you want to find top 2 maximum values & indices

``````import numpy as np
nums = np.array([0.2, 0.3, 0.25, 0.15, 0.1])

def TopK(x, k):
a = dict([(i, j) for i, j in enumerate(x)])
sorted_a = dict(sorted(a.items(), key = lambda kv:kv[1], reverse=True))
indices = list(sorted_a.keys())[:k]
values = list(sorted_a.values())[:k]
return (indices, values)

print(f"Indices: {TopK(nums, k = 2)[0]}")
print(f"Values: {TopK(nums, k = 2)[1]}")

Indices: [1, 2]
Values: [0.3, 0.25]
``````

A vectorized 2D implementation using argpartition:

``````k = 3
probas = np.array([
[.6, .1, .15, .15],
[.1, .6, .15, .15],
[.3, .1, .6, 0],
])

k_indices = np.argpartition(-probas, k-1, axis=-1)[:, :k]

# adjust indices to apply in flat array
adjuster = np.arange(probas.shape[0]) * probas.shape[1]
adjuster = np.broadcast_to(adjuster[:, None], k_indices.shape)
k_indices_flat = k_indices + adjuster

k_values = probas.flatten()[k_indices_flat]

# k_indices:
# array([[0, 2, 3],
#        [1, 2, 3],
#        [2, 0, 1]])
# k_values:
# array([[0.6 , 0.15, 0.15],
#        [0.6 , 0.15, 0.15],
#       [0.6 , 0.3 , 0.1 ]])
``````