# How can I find the smallest power of 2 greater than n in Python

What is the simplest way to find the smallest power of 2 greater than a given n in python?

For example the smallest power of 2 greater than 6 is 8

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Since the OP apparently posted this just to give his own solution which he believes is faster than other ways to do it, let's test it:

``````import collections
import math
import timeit

def power_bit_length(x):
return 2**(x-1).bit_length()

def shift_bit_length(x):
return 1<<(x-1).bit_length()

def power_log(x):
return 2**(math.ceil(math.log(x, 2)))

def test(f):
collections.deque((f(i) for i in range(1, 1000001)), maxlen=0)

def timetest(f):
print('{}: {}'.format(timeit.timeit(lambda: test(f), number=10),
f.__name__))

timetest(power_bit_length)
timetest(shift_bit_length)
timetest(power_log)
``````

The reason I'm using `range(1, 1000001)` instead of just `range(1000000)` is that the `power_log` version will fail on `0`. The reason I'm using a small number of reps over a largeish range instead of lots of reps over a small range is because I expect that different versions will have different performance over different domains. (If you expect to be calling this with huge thousand-bit numbers, of course, you want a test that uses those.)

With Apple Python 2.7.2:

``````4.38817000389: power_bit_length
3.69475698471: shift_bit_length
7.91623902321: power_log
``````

With Python.org Python 3.3.0:

``````6.566169916652143: power_bit_length
3.098236607853323: shift_bit_length
9.982460380066186: power_log
``````

With pypy 1.9.0/2.7.2:

``````2.8580930233: power_bit_length
2.49524712563: shift_bit_length
3.4371240139: power_log
``````

I believe this demonstrates that the `2**` is the slow part here; using `bit_length` instead of `log` does speed things up, but using `1<<` instead of `2**` is more important.

Also, I think it's clearer. The OP's version requires you to make a mental context-switch from logarithms to bits, and then back to exponents. Either stay in bits the whole time (`shift_bit_length`), or stay in logs and exponents (`power_log`).

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Please note that the result is incorrect for `x == 0`, since `(-1).bit_length() == 1` in Python. –  Siu Ching Pong -Asuka Kenji- Mar 16 at 18:35
``````def next_greater_power_of_2(x):
return 2**(x-1).bit_length()
``````
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Isn't that awfully slow for large `x`? Apart from that, I can't say I understand it. –  delnan Jan 10 '13 at 21:28
@delnan -- Why would you expect this to be slow? (not that I understand the code either ...) –  mgilson Jan 10 '13 at 21:33
@delnan: First, `bit_length` is effectively log base 2 rounded up - 1, and very quickly. So, raise 2 to the power of that, and you're done. Maybe doing `1 <<` instead of `2 **` would be faster, but otherwise, what slowness are you expecting here? –  abarnert Jan 10 '13 at 21:34
I'm not sure how python implements bit_length, but it's pretty much instant even for huge values of `x`. –  jhoyla Jan 10 '13 at 21:35
bit_length returns "Number of bits necessary to represent self in binary." –  jhoyla Jan 10 '13 at 21:36

Would this work for you:

``````In [144]: math.log(6,2)
Out[144]: 2.584962500721156

In [145]: math.log(8,2)
Out[145]: 3.0

In [146]: math.ceil(math.log(6,2))
Out[146]: 3.0

In [147]: math.ceil(math.log(8,2))
Out[147]: 3.0

In [148]: math.ceil(math.log(16,2))
Out[148]: 4.0

In [149]: 2**math.ceil(math.log(6,2))
Out[149]: 8.0
``````
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Requires log, which I think is slower. –  jhoyla Jan 10 '13 at 21:35
@jhoyla Performance is very rarely relevant (and the slow part would be looking up two functions and calling them, not `log` specifically). This is definitely more readable and obvious (for me at least). –  delnan Jan 10 '13 at 21:40
The only way to find out if it's slower is to test… but it does have the disadvantage that it says `next_power_of_two(0)` is a `DomainError` instead of 1… –  abarnert Jan 10 '13 at 21:40
@abarnert: that's what I get for answering SO posts during class - lack of proper testing :P –  inspectorG4dget Jan 10 '13 at 21:41
The bit_length method gives 2 for 0, which is also wrong :P. –  jhoyla Jan 10 '13 at 21:48
``````v+=(v==0);
v--;
v|=v>>1;
v|=v>>2;
v|=v>>4;
v|=v>>8;
v|=v>>16;
v++;
``````

For a 16-bit integer.

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