# Max in a sliding window in NumPy array

I want to create an array which holds all the `max()`es of a window moving through a given numpy array. I'm sorry if this sounds confusing. I'll give an example. Input:

``````[ 6,4,8,7,1,4,3,5,7,2,4,6,2,1,3,5,6,3,4,7,1,9,4,3,2 ]
``````

My output with a window width of 5 shall be this:

``````[     8,8,8,7,7,7,7,7,7,6,6,6,6,6,6,7,7,9,9,9,9     ]
``````

Each number shall be the max of a subarray of width 5 of the input array:

``````[ 6,4,8,7,1,4,3,5,7,2,4,6,2,1,3,5,6,3,4,7,1,9,4,3,2 ]
\       /                 \       /
\     /                   \     /
\   /                     \   /
\ /                       \ /
[     8,8,8,7,7,7,7,7,7,6,6,6,6,6,6,7,7,9,9,9,9     ]
``````

I did not find an out-of-the-box function within numpy which would do this (but I would not be surprised if there was one; I'm not always thinking in the terms the numpy developers thought). I considered creating a shifted 2D-version of my input:

``````[ [ 6,4,8,7,1,4,3,5,7,8,4,6,2,1,3,5,6,3,4,7,1 ]
[ 4,8,7,1,4,3,5,7,8,4,6,2,1,3,5,6,3,4,7,1,9 ]
[ 8,7,1,4,3,5,7,8,4,6,2,1,3,5,6,3,4,7,1,9,4 ]
[ 7,1,4,3,5,7,8,4,6,2,1,3,5,6,3,4,7,1,9,4,3 ]
[ 1,4,3,5,7,8,4,6,2,1,3,5,6,3,4,7,1,9,4,3,2 ] ]
``````

Then I could apply `np.max(input, 0)` on this and would get my results. But this does not seem efficient in my case because both my array and my window width can be large (>1000000 entries and >100000 window width). The data would be blown up more or less by a factor of the window width.

I also considered using `np.convolve()` in some fashion but couldn't figure out a way to achieve my goal with it.

Any ideas how to do this efficiently?

Pandas has a rolling method for both Series and DataFrames, and that could be of use here:

``````import pandas as pd

lst = [6,4,8,7,1,4,3,5,7,8,4,6,2,1,3,5,6,3,4,7,1,9,4,3,2]
lst1 = pd.Series(lst).rolling(5).max().dropna().tolist()

# [8.0, 8.0, 8.0, 7.0, 7.0, 8.0, 8.0, 8.0, 8.0, 8.0, 6.0, 6.0, 6.0, 6.0, 6.0, 7.0, 7.0, 9.0, 9.0, 9.0, 9.0]
``````

For consistency, you can coerce each element of `lst1` to `int`:

``````[int(x) for x in lst1]

# [8, 8, 8, 7, 7, 8, 8, 8, 8, 8, 6, 6, 6, 6, 6, 7, 7, 9, 9, 9, 9]
``````
• I found that you can rephrase your solution in a simpler manner: `a = np.array(…)`, `pd.rolling_max(a, window=5)`. And up to now this sounds like the best option for the sizes I'm dealing with. The `strides` solution of @Divakar would be faster if it worked for my sizes, though, so I'm still waiting before accepting this answer.
– Alfe
Apr 9, 2017 at 21:27
• The newer version of pandas tells me that my abbreviation will not be supported anymore in the future, so yours is the best solution.
– Alfe
Apr 11, 2017 at 0:57

Approach #1 : You could use `1D` max filter from Scipy -

``````from scipy.ndimage.filters import maximum_filter1d

def max_filter1d_valid(a, W):
hW = (W-1)//2 # Half window size
return maximum_filter1d(a,size=W)[hW:-hW]
``````

Approach #2 : Here's another approach with `strides` : `strided_app` to create a `2D` shifted version as view into the array pretty efficiently and that should let us use any custom reduction operation along the second axis afterwards -

``````def max_filter1d_valid_strided(a, W):
return strided_app(a, W, S=1).max(axis=1)
``````

Runtime test -

``````In [55]: a = np.random.randint(0,10,(10000))

# @Abdou's solution using pandas rolling
In [56]: %timeit pd.Series(a).rolling(5).max().dropna().tolist()
1000 loops, best of 3: 999 µs per loop

In [57]: %timeit max_filter1d_valid(a, W=5)
...: %timeit max_filter1d_valid_strided(a, W=5)
...:
10000 loops, best of 3: 90.5 µs per loop
10000 loops, best of 3: 87.9 µs per loop
``````
• This sounded extremely promising, comparing the performance to the `pandas` solution. Unfortunately, for the arrays I'm dealing with this raises a `ValueError: array is too big.`. Try for yourself: `a = np.arange(1000000)`, `np.lib.stride_tricks.as_strided(a, shape=(1000, len(a)-1000+1), strides=(a.strides[0], a.strides[0]))`. And in practice I'm going to need windows of size 100k in arrays of size 10m and larger. Do you have any workaround?
– Alfe
Apr 9, 2017 at 21:21
• @Alfe Just use the `scipy.ndimage.maximum_filter1d` approach he presented. It is almost as fast and should be really efficient even for huge arrays. Apr 9, 2017 at 21:49
• @MSeifert Unfortunately it's slower than the pandas `rolling_max()`, in my tests with sizes on the lower limit of my real sizes by a factor of ~ 2.
– Alfe
Apr 9, 2017 at 21:56
• That's interesting because on my computer `maximum_filter1d` is 3-4 times faster for a window size of 100k and an array size of 10m. Are you using the newest version of both packages? Apr 9, 2017 at 22:05
• @Alfe That `a = np.arange(1000000), np.lib.stride_tricks.as_strided(a, shape=(1000, len(a)-1000+1), strides=(a.strides[0], a.strides[0]))` worked fine for me. Could you report your NumPy, Pandas and Scipy versions? Apr 10, 2017 at 9:42

I have tried several variants now and would declare the Pandas version as the winner of this performance race. I tried several variants, even using a binary tree (implemented in pure Python) for quickly computing maxes of arbitrary subranges. (Source available on demand). The best algorithm I came up with myself was a plain rolling window using a ringbuffer; the max of that only needed to be recomputed completely if the current max value was dropped from it in this iteration; otherwise it would remain or increase to the next new value. Compared with the old libraries, this pure-Python implementation was faster than the rest.

In the end I found that the version of the libraries in question was highly relevant. The rather old versions I was mainly still using were way slower than the modern versions. Here are the numbers for 1M numbers, rollingMax'ed with a window of size 100k:

``````         old (slow HW)           new (better HW)
scipy:   0.9.0:  21.2987391949   0.13.3:  11.5804400444
pandas:  0.7.0:  13.5896410942   0.18.1:   0.0551438331604
numpy:   1.6.1:   1.17417216301  1.8.2:    0.537392139435
``````

Here is the implementation of the pure numpy version using a ringbuffer:

``````def rollingMax(a, window):
def eachValue():
w = a[:window].copy()
m = w.max()
yield m
i = 0
j = window
while j < len(a):
oldValue = w[i]
newValue = w[i] = a[j]
if newValue > m:
m = newValue
elif oldValue == m:
m = w.max()
yield m
i = (i + 1) % window
j += 1
return np.array(list(eachValue()))
``````

For my input this works great because I'm handling audio data with lots of peaks in all directions. If you put a constantly decreasing signal into it (e. g. `-np.arange(10000000)`), then you will experience the worst case (and maybe you should reverse the input and the output in such cases).

I just include this in case someone wants to do this task on a machine with old libraries.

Starting in `Numpy 1.20`, the `sliding_window_view` provides a way to slide/roll through windows of elements. Windows that you can then find the max for:

``````from numpy.lib.stride_tricks import sliding_window_view

# values = np.array([6,4,8,7,1,4,3,5,7,2,4,6,2,1,3,5,6,3,4,7,1,9,4,3,2])
np.max(sliding_window_view(values, window_shape = 5), axis = 1)
# array([8, 8, 8, 7, 7, 7, 7, 7, 7, 6, 6, 6, 6, 6, 6, 7, 7, 9, 9, 9, 9])
``````

where:

• `window_shape` is the size of the sliding window
• `np.max(array, axis = 1)` finds the max for each sub-array

and the intermediate result of the sliding is:

``````sliding_window_view(values, window_shape = 5)
# array([[6, 4, 8, 7, 1],
#        [4, 8, 7, 1, 4],
#        [8, 7, 1, 4, 3],
#        ...
#        [7, 1, 9, 4, 3],
#        [1, 9, 4, 3, 2]])
``````
• This was very helpful! For anyone wondering how to do a strided sliding window with a stride step larger than 1: `np.max(sliding_window_view(values, window_shape = 5)[::stride_step], axis = 1)` Dec 19, 2023 at 11:31

First of all, I think there is a mistake in your explanation because the 10th element of your initial imput array at the beginning of your explanation is equal to 8, and below, where you apply the window, it is 2.

After correcting that, I think that the code that does what you want is the following:

``````import numpy as np
a=np.array([ 6,4,8,7,1,4,3,5,7,8,4,6,2,1,3,5,6,3,4,7,1,9,4,3,2 ])
window=5
for i in range(0,len(a)-window,1):
b[i] = np.amax(a[i:i+window])
``````

I think, this way is better than creating a shifted 2D version of your imput because when you create such a version you need to use much more memory than using the original imput array, so you may run out of memory if the input is large.

• Gosh, you're right! I changed my input in the process of writing my question in order to show more cases. I wasn't consequent on that. I fixed that by now. To your proposal: I want to avoid any Python-written loop over my input because that always is slower than using any functionality of a package like `numpy`, `scipy`, `pandas` or the like. If you think your solution can compete, provide timeits. Otherwise: Sure, that's straight-forward and a good solution. It just doesn't meet my performance expectations.
– Alfe
Apr 9, 2017 at 20:23

If you have two dimension data, for example stock price and want to get rolling max or whatever, this will works. Caculating without using iteration.

``````n = 5  # size of rolling window

data_expanded = np.expand_dims(data, 1)
data_shift = [np.roll(data_expanded, shift=-i, axis=2) for i in range(n)]
data_shift = np.concatenate(data_shift, axis=1)

data_max = np.max(data_shift, axis=1)  # max, mean, std...
``````
• `for i in range(n)` looks very suspiciously like an iteration to me. In my case `n` will be very large, e. g. two seconds of an audio sample with 96kHz, so n > 150000. But thanks for your contribution anyway and welcome to StackOverflow :-)
– Alfe
Mar 7, 2019 at 10:53