# fast way of counting non-zero bits in python

I need a fast way to count the number of bits in an integer in python. My current solutions is

``````bin(n).count("1")
``````

but I am wondering if there is any faster way of doing this?

PS: (i am representing a big 2D binary array as a singe list of numbers and doing bitwise operations, and that brings the time down from hours to minutes. and now i would like to get rid of those extra minutes.

Edit: 1. it has to be in python 2.7 or 2.6

and optimizing for small numbers does not matter that much since that would not be a clear bottle neck, but I do have numbers with 10 000 + bits at some places

for example this is a 2000 bit case:

``````12448057941136394342297748548545082997815840357634948550739612798732309975923280685245876950055614362283769710705811182976142803324242407017104841062064840113262840137625582646683068904149296501029754654149991842951570880471230098259905004533869130509989042199261339990315125973721454059973605358766253998615919997174542922163484086066438120268185904663422979603026066685824578356173882166747093246377302371176167843247359636030248569148734824287739046916641832890744168385253915508446422276378715722482359321205673933317512861336054835392844676749610712462818600179225635467147870208L
``````
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– dusan Mar 22 '12 at 20:15
What kind of representation are you using if your "integers" are longer than a standard python `int`? Does that not have its own method for calculating this? – Marcin Mar 22 '12 at 21:02
possible duplicate of Count bits of a integer in Python – endolith Apr 20 '14 at 17:51
To distinguish the question from that in stackoverflow.com/a/2654211/1959808 (if it is intended to be different --- at least so it looks like) please consider rephrasing the title to “...counting the number of non-zero bits...” or similar. Otherwise `int.bit_length` should be the answer, and not the one accepted below. – Ioannis Filippidis Nov 16 '14 at 11:38

For arbitrary-length integers, `bin(n).count("1")` is the fastest I could find in pure Python.

I tried adapting Óscar's and Adam's solutions to process the integer in 64-bit and 32-bit chunks, respectively. Both were at least ten times slower than `bin(n).count("1")` (the 32-bit version took about half again as much time).

On the other hand, gmpy `popcount()` took about 1/20th of the time of `bin(n).count("1")`. So if you can install gmpy, use that.

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Thank you very much, just the thing I was looking for. – zidarsk8 Mar 22 '12 at 23:15
+1! The converse of this is not accurate, however, it should be stated: `bin(n).count("0")` is not accurate because of the '0b' prefix. Would need to be `bin(n)[2:].count('0')` for those counting naughts.... – the wolf Mar 23 '12 at 2:03
You can't really count zero bits without knowing how many bytes you're filling, though, which is problematic with a Python long integer because it could be anything. – kindall Mar 23 '12 at 5:04
Although those are fast options for single integers, note that algorithms presented in other answers may be potentially vectorised, thus much faster if run across many elements of a large `numpy` array. – gerrit 20 hours ago

You can adapt the following algorithm:

``````def CountBits(n):
n = (n & 0x5555555555555555) + ((n & 0xAAAAAAAAAAAAAAAA) >> 1)
n = (n & 0x3333333333333333) + ((n & 0xCCCCCCCCCCCCCCCC) >> 2)
n = (n & 0x0F0F0F0F0F0F0F0F) + ((n & 0xF0F0F0F0F0F0F0F0) >> 4)
n = (n & 0x00FF00FF00FF00FF) + ((n & 0xFF00FF00FF00FF00) >> 8)
n = (n & 0x0000FFFF0000FFFF) + ((n & 0xFFFF0000FFFF0000) >> 16)
n = (n & 0x00000000FFFFFFFF) + ((n & 0xFFFFFFFF00000000) >> 32) # This last & isn't strictly necessary.
return n
``````

This works for 64-bit positive numbers, but it's easily extendable and the number of operations growth with the logarithm of the argument (i.e. linearly with the bit-size of the argument).

In order to understand how this works imagine that you divide the entire 64-bit string into 64 1-bit buckets. Each bucket's value is equal to the number of bits set in the bucket (0 if no bits are set and 1 if one bit is set). The first transformation results in an analogous state, but with 32 buckets each 2-bit long. This is achieved by appropriately shifting the buckets and adding their values (one addition takes care of all buckets since no carry can occur across buckets - n-bit number is always long enough to encode number n). Further transformations lead to states with exponentially decreasing number of buckets of exponentially growing size until we arrive at one 64-bit long bucket. This gives the number of bits set in the original argument.

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I seriously have no idea how this would work with 10 000 bit numbers though, but I do like the solution. can you give me a hint if and how i can applay that to bigger numbers? – zidarsk8 Mar 22 '12 at 20:52
I didn't see the number of bits you're dealing with here. Have you considered writing your data handling code in a low-level language like C? Perhaps as an extension to your python code? You can certainly improve performance by using large arrays in C compared to large numerals in python. That said, you can rewrite the `CountBits()` to handle 10k-bits numbers by adding just 8 lines of code. But it'll become unwieldy due to huge constants. – Adam Zalcman Mar 22 '12 at 21:05
You can write code to generate the sequence of constants, and set up a loop for the processing. – Karl Knechtel Mar 22 '12 at 21:40
This answer has the great advantage that it can be vectorised for cases dealing with large `numpy` arrays. – gerrit 20 hours ago

According to this post, this seems to be one the fastest implementation of the Hamming weight (if you don't mind using about 64KB of memory).

``````#http://graphics.stanford.edu/~seander/bithacks.html#CountBitsSetTable
POPCOUNT_TABLE16 = [0] * 2**16
for index in range(len(POPCOUNT_TABLE16)):
POPCOUNT_TABLE16[index] = (index & 1) + POPCOUNT_TABLE16[index >> 1]

def popcount32_table16(v):
return (POPCOUNT_TABLE16[ v        & 0xffff] +
POPCOUNT_TABLE16[(v >> 16) & 0xffff])
``````

On Python 2.x you should replace `range` with `xrange`.

## Edit

If you need better performance (and your numbers are big integers), have a look at the `GMP` library. It contains hand-written assembly implementations for many different architectures.

`gmpy` is A C-coded Python extension module that wraps the GMP library.

``````>>> import gmpy
>>> gmpy.popcount(2**1024-1)
1024
``````
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I have edited my question to make it clear I need this for Large numbers (10k bits and more). optimizing something for 32 bit integers would probablt not make that much of a difference since the number of counts would have to be really big, in which case that would cause the slow execute time. – zidarsk8 Mar 22 '12 at 20:54
But GMP is exactly for very large numbers, including numbers at and far beyond the sizes you mention. – James Youngman Mar 23 '12 at 10:45
Memory usage will be better if you use `array.array` for `POPCOUNT_TABLE16`, as then it'll be stored as an array of integers, instead of as a dynamically sized list of Python `int` objects. – gsnedders Dec 25 '14 at 23:14

Here's a Python implementation of the population count algorithm, as explained in this post:

``````def numberOfSetBits(i):
i = i - ((i >> 1) & 0x55555555)
i = (i & 0x33333333) + ((i >> 2) & 0x33333333)
return (((i + (i >> 4) & 0xF0F0F0F) * 0x1010101) & 0xffffffff) >> 24
``````

It will work for `0 <= i < 0x100000000`.

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That's clever. Looking this up instead of shooting an answer from the hip is completely appropriate! – MrGomez Mar 22 '12 at 20:27
Did you benchmark this? On my machine using python 2.7, I found this to actually be a bit slower than `bin(n).count("1")`. – David Weldon Mar 22 '12 at 20:53
@DavidWeldon No I didn't, could you please post your benchmarks? – Óscar López Mar 22 '12 at 21:25
`%timeit numberOfSetBits(23544235423)`: `1000000 loops, best of 3: 818 ns per loop`; `%timeit bitCountStr(23544235423)`: `1000000 loops, best of 3: 577 ns per loop`. – gerrit 23 hours ago
However, `numberOfSetBits` processes my 864×64 `numpy.ndarray` in 841 µs. With `bitCountStr` I have to loop explicitly, and it takes 40.7 ms, or almost 50 times longer. – gerrit 20 hours ago

It turns out your starting representation is a list of lists of ints which are either 1 or 0. Simply count them in that representation.

The number of bits in an integer is constant in python.

However, if you want to count the number of set bits, the fastest way is to create a list conforming to the following pseudocode: `[numberofsetbits(n) for n in range(MAXINT)]`

This will provide you a constant time lookup after you have generated the list. See @PaoloMoretti's answer for a good implementation of this. Of course, you don't have to keep this all in memory - you could use some sort of persistent key-value store, or even MySql. (Another option would be to implement your own simple disk-based storage).

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-0. Clever, but unhelpful. – Steven Rumbalski Mar 22 '12 at 20:06
@StevenRumbalski How is it unhelpful? – Marcin Mar 22 '12 at 20:07
When I read your answer it contained only your first sentence: "The number of bits in an integer is constant in python." – Steven Rumbalski Mar 22 '12 at 20:34
I already have a bit count lookup table for all the the counts that it's possible to store, but having a large list of numbers and operating on them with a[i] & a[j] , makes your soltuion useless unless i have 10+GB of ram. array for & ^ | for tripples of 10000 numbers would be 3*10000^3 lookup table size. since i don't know what i will need, it makes more sense to just count the few thousand when i need them – zidarsk8 Mar 22 '12 at 20:49
@zidarsk8 Or, you could use some kind of database or persistent key-value store. – Marcin Mar 22 '12 at 20:53

You said Numpy was too slow. Were you using it to store individual bits? Why not extend the idea of using ints as bit arrays but use Numpy to store those?

Store n bits as an array of `ceil(n/32.)` 32-bit ints. You can then work with the numpy array the same (well, similar enough) way you use ints, including using them to index another array.

The algorithm is basically to compute, in parallel, the number of bits set in each cell, and them sum up the bitcount of each cell.

``````setup = """
import numpy as np
POPCOUNT_TABLE16 = np.zeros(2**16, dtype=int) #has to be an array

for index in range(len(POPCOUNT_TABLE16)):
POPCOUNT_TABLE16[index] = (index & 1) + POPCOUNT_TABLE16[index >> 1]

def popcount32_table16(v):
return (POPCOUNT_TABLE16[ v        & 0xffff] +
POPCOUNT_TABLE16[(v >> 16) & 0xffff])

def count1s(v):
return popcount32_table16(v).sum()

v1 = np.arange(1000)*1234567                       #numpy array
v2 = sum(int(x)<<(32*i) for i, x in enumerate(v1)) #single int
"""
from timeit import timeit

timeit("count1s(v1)", setup=setup)        #49.55184188873349
timeit("bin(v2).count('1')", setup=setup) #225.1857464598633
``````

Though I'm surprised no one suggested you write a C module.

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