# Compute fast log base 2 ceiling in python

for given `x < 10^15`, quickly and accurately determine the maximum integer `p` such that `2^p <= x`

Here are some things I've tried:

First I tried this but it's not accurate for large numbers:

``````>>> from math import log
>>> x = 2**3
>>> x
8
>>> p = int(log(x, 2))
>>> 2**p == x
True
>>> x = 2**50
>>> p = int(log(x, 2))
>>> 2**p == x #not accurate for large numbers?
False
``````

I could try something like:

``````p = 1
i = 1
while True:
if i * 2 > n:
break
i *= 2
p += 1
not_p = n - p
``````

Which would take up to 50 operations if p was 50

I could pre-compute all the powers of 2 up until 2^50, and use binary search to find p. This would take around log(50) operations but seems a bit excessive and ugly?

I found this thread for C based solutions: Compute fast log base 2 ceiling

However It seems a bit ugly and I wasn't exactly sure how to convert it to python.

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Is `x` always an integer? –  DSM Oct 28 '12 at 2:44
x is always an integer –  robert king Oct 28 '12 at 2:45
You may want to read docs for bitwise shift and and/or/xor. This can help you translate the C code to Python. –  mtrw Oct 28 '12 at 2:55
Similar to stackoverflow.com/a/19164783/125507 –  endolith Nov 7 at 23:51

In Python >= 2.7, you can use the `.bit_length()` method of integers:

``````def brute(x):
# determine max p such that 2^p <= x
p = 0
while 2**p <= x:
p += 1
return p-1

def easy(x):
return x.bit_length() - 1
``````

which gives

``````>>> brute(0), brute(2**3-1), brute(2**3)
(-1, 2, 3)
>>> easy(0), easy(2**3-1), easy(2**3)
(-1, 2, 3)
>>> brute(2**50-1), brute(2**50), brute(2**50+1)
(49, 50, 50)
>>> easy(2**50-1), easy(2**50), easy(2**50+1)
(49, 50, 50)
>>>
>>> all(brute(n) == easy(n) for n in range(10**6))
True
>>> nums = (max(2**x+d, 0) for x in range(200) for d in range(-50, 50))
>>> all(brute(n) == easy(n) for n in nums)
True
``````
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like a boss. I didn't know about the bit_length() function. Thanks and yeah I happen to be using python 3.3 for this project :P –  robert king Oct 28 '12 at 2:59

You could try the `log2` function from numpy, which appears to work for powers up to 2^62:

``````>>> 2**np.log2(2**50) == 2**50
True
>>> 2**np.log2(2**62) == 2**62
True
``````

Above that (at least for me) it fails due to the limtiations of numpy's internal number types, but that will handle data in the range you say you're dealing with.

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Works for me, Python 2.6.5 (CPython) on OSX 10.7:

``````>>> x = 2**50
>>> x
1125899906842624L
>>> p = int(log(x,2))
>>> p
50
>>> 2**p == x
True
``````

It continues to work at least for exponents up to 1e9, by which time it starts to take quite a while to do the math. What are you actually getting for `x` and `p` in your test? What version of Python, on what OS, are you running?

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Here's an example of the failure -- you have to click the "run session" button. –  Brian Cain Oct 28 '12 at 2:39
I get 49.999999 instead of 50.0 for p. Maybe it's because my PC is 32 bit –  robert king Oct 28 '12 at 2:40
I wouldn't expect 32 vs 64 bit to affect math.log. Strange. –  Russell Borogove Oct 28 '12 at 2:42

With respect to "not accurate for large numbers" your challenge here is that the floating point representation is indeed not as precise as you need it to be (`49.999999999993 != 50.0`). A great reference is "What Every Computer Scientist Should Know About Floating-Point Arithmetic."

The good news is that the transformation of the C routine is very straightforward:

``````def getpos(value):
if (value == 0):
return -1
pos = 0
if (value & (value - 1)):
pos = 1
if (value & 0xFFFFFFFF00000000):
pos += 32
value = value >> 32
if (value & 0x00000000FFFF0000):
pos += 16
value = value >> 16
if (value & 0x000000000000FF00):
pos += 8
value = value >> 8
if (value & 0x00000000000000F0):
pos += 4
value = value >> 4
if (value & 0x000000000000000C):
pos += 2
value = value >> 2
if (value & 0x0000000000000002):
pos += 1
value = value >> 1
return pos
``````

Another alternative is that you could round to the nearest integer, instead of truncating:

``````   log(x,2)
=> 49.999999999999993
round(log(x,2),1)
=> 50.0
``````
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