# Given an integer, how do I find the next largest power of two using bit-twiddling?

If I have a integer number `n`, how can I find the next number `k > n` such that `k = 2^i`, with some `i` element of `n` by bitwise shifting or logic.

Example: if I have `n = 123`, how can I find `k = 128`, which is a power of two, and not `124` which is only divisible by two. This should be simple, but it eludes me.

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This would be a great interview question. –  Rick Minerich Aug 24 '09 at 14:11
@Rick: I hope you are not an interviewer and I now put a poor applicant in a tight spot ;-) –  AndreasT Aug 24 '09 at 14:23
Could be a duplicate of stackoverflow.com/questions/466204/…, anyway answers from this question could be of interest here too. –  ydroneaud Mar 11 '13 at 11:45

For 32-bit integers, this is a simple and straightforward route:

``````unsigned int n;

n--;
n |= n >> 1;   // Divide by 2^k for consecutive doublings of k up to 32,
n |= n >> 2;   // and then or the results.
n |= n >> 4;
n |= n >> 8;
n |= n >> 16;
n++;           // The result is a number of 1 bits equal to the number
// of bits in the original number, plus 1. That's the
// next highest power of 2.
``````

Here's a more concrete example. Let's take the number 221, which is 11011101 in binary:

``````n--;           // 1101 1101 --> 1101 1100
n |= n >> 1;   // 1101 1101 | 0110 1110 = 1111 1111
n |= n >> 2;   // ...
n |= n >> 4;
n |= n >> 8;
n |= n >> 16;  // 1111 1111 | 1111 1111 = 1111 1111
n++;           // 1111 1111 --> 1 0000 0000
``````

There's one bit in the ninth position, which represents 2^8, or 256, which is indeed the next largest power of 2. Each of the shifts overlaps all of the existing 1 bits in the number with some of the previously untouched zeroes, eventually producing a number of 1 bits equal to the number of bits in the original number. Adding one to that value produces a new power of 2.

Another example; we'll use 131, which is 10000011 in binary:

``````n--;           // 1000 0011 --> 1000 0010
n |= n >> 1;   // 1000 0010 | 0100 0001 = 1100 0011
n |= n >> 2;   // 1100 0011 | 0011 0000 = 1111 0011
n |= n >> 4;   // 1111 0011 | 0000 1111 = 1111 1111
n |= n >> 8;   // ... (At this point all bits are 1, so further bitwise-or
n |= n >> 16;  //      operations produce no effect.)
n++;           // 1111 1111 --> 1 0000 0000
``````

And indeed, 256 is the next highest power of 2 from 131.

If the number of bits used to represent the integer is itself a power of 2, you can continue to extend this technique efficiently and indefinitely (for example, add a `n >> 32` line for 64-bit integers).

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Beat me to it. +1 –  Pesto Aug 24 '09 at 13:53
Ah great thanks! I had a hard time to understand why you could double k every step, but since you "double" every '1' it became obvious. Thanks for the example. –  AndreasT Aug 24 '09 at 14:11
@AndreasT: No problem! (BTW, to see why you need to go all the way up to n >> 16, consider what happens if n is already a power of 2. You'll only have a single 1 bit that needs to cover all of the previous bits, which is why all the shifting is necessary.) –  John Feminella Aug 24 '09 at 14:16
+1 yes, good trick, I like it :) Some more bit-twiddling tricks can be found here: graphics.stanford.edu/~seander/bithacks.html –  zxcat Sep 9 '09 at 13:39
@endolith That takes log N shifts. This takes log(log N) shifts, so it uses fewer shifts. –  John Feminella Oct 9 '13 at 13:21

There is actually a assembly solution for this (since the 80386 instruction set).

You can use the BSR (Bit Scan Reverse) instruction to scan for the most significant bit in your integer.

bsr scans the bits, starting at the most significant bit, in the doubleword operand or the second word. If the bits are all zero, ZF is cleared. Otherwise, ZF is set and the bit index of the first set bit found, while scanning in the reverse direction, is loaded into the destination register

(Extracted from: http://dlc.sun.com/pdf/802-1948/802-1948.pdf)

And than inc the result with 1.

so:

``````bsr ecx, eax  //eax = number
jz  @zero
mov eax, 2    // result set the second bit (instead of a inc ecx)
shl eax, ecx  // and move it ecx times to the left
ret           // result is in eax

@zero:
xor eax, eax
ret
``````
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that is cool! thx! –  AndreasT Aug 26 '09 at 17:29
If your input is already a power of 2, this will not return it though –  endolith Oct 3 '13 at 2:15

A more mathematical way, without loops:

``````public static int ByLogs(int n)
{
double y = Math.Floor(Math.Log(n, 2));

return (int)Math.Pow(2, y + 1);
}
``````
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Thanks. But I was searching for a "bit-twiddle" way. ;-) –  AndreasT Aug 24 '09 at 14:06
+1, not what the OP wanted, but strangely enough I needed an answer that would fit in a single inline expression: `2 ^ (floor(log(x) / log(2)) + 1)` –  zildjohn01 Jul 12 '10 at 18:55
What if the input is `0`? Also, OP asked for the next largest power of 2, `floor` finds the next lower power of 2, no? –  endolith Dec 16 '12 at 17:47
It gets you the existing value. The next part, y+1 gets you the next largest power. –  DanDan Jan 8 '13 at 14:34
@DanDan: but if n is already a power of 2, it gives the next power of 2 rather than returning n –  endolith Dec 9 '13 at 2:48

``````function getK(int n)
{
int k = 1;
while (k < n)
k *= 2;
return k;
}
``````
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Here's a wild one that has no loops, but uses an intermediate float.

``````//  compute k = nextpowerof2(n)

if (n > 1)
{
float f = (float) n;
unsigned int const t = 1U << ((*(unsigned int *)&f >> 23) - 0x7f);
k = t << (t < n);
}
else k = 1;
``````

This, and many other bit-twiddling hacks, including the on submitted by John Feminella, can be found here.

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wtf! 8-) , will check it out. Thx –  AndreasT Aug 26 '09 at 17:28

Here's John Feminella's answer implemented as a loop so it can handle Python's long integers:

``````def next_power_of_2(n):
"""
Return next power of 2 greater than or equal to n
"""
n -= 1 # greater than OR EQUAL TO n
shift = 1
while (n+1) & n: # n+1 is not a power of 2 yet
n |= n >> shift
shift *= 2
return n + 1
``````

It also returns faster if n is already a power of 2.

For Python >2.7, this is simpler and faster for most N:

``````def next_power_of_2(n):
"""
Return next power of 2 greater than or equal to n
"""
return 2**(n-1).bit_length()
``````

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``````function Pow2Thing(int n)
{
x = 1;
while (n>0)
{
n/=2;
x*=2;
}
return x;
}
``````
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``````int pot = 1;
for (int i = 0; i < 31; i++, pot <<= 1)
if (pot >= x)
break;
``````
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You just need to find the most significant bit and shift it left once. Here's a Python implementation. I think x86 has an instruction to get the MSB, but here I'm implementing it all in straight Python. Once you have the MSB it's easy.

``````>>> def msb(n):
...     result = -1
...     index = 0
...     while n:
...         bit = 1 << index
...         if bit & n:
...             result = index
...             n &= ~bit
...         index += 1
...     return result
...
>>> def next_pow(n):
...     return 1 << (msb(n) + 1)
...
>>> next_pow(1)
2
>>> next_pow(2)
4
>>> next_pow(3)
4
>>> next_pow(4)
8
>>> next_pow(123)
128
>>> next_pow(222)
256
>>>
``````
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assume x is not negative.

``````int pot = Integer.highestOneBit(x);
if (pot != x) {
pot *= 2;
}
``````
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Forget this! It uses loop !

``````     unsigned int nextPowerOf2 ( unsigned int u)
{
unsigned int v = 0x80000000; // supposed 32-bit unsigned int

if (u < v) {
while (v > u) v = v >> 1;
}
return (v << 1);  // return 0 if number is too big
}
``````
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``````// n is the number
Is this idea: fill out the all the 1s up to the largest, currently 'on' bit? If so, would it be `n+min+1`? –  Garet Claborn Feb 13 '11 at 11:24