# How to check if a number is a power of 2

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Today I needed a simple algorithm for checking if a number is a power of 2.

The algorithm needs to be:

1. Simple
2. Correct for any `ulong` value.

I came up with this simple algorithm:

``````private bool IsPowerOfTwo(ulong number)
{
if (number == 0)
return false;

for (ulong power = 1; power > 0; power = power << 1)
{
// this for loop used shifting for powers of 2, meaning
// that the value will become 0 after the last shift
// (from binary 1000...0000 to 0000...0000) then, the for
// loop will break out

if (power == number)
return true;
if (power > number)
return false;
}
return false;
}
``````

But then I thought, how about checking if `log``2``x` is an exactly round number? But when I checked for 2^63+1, `Math.Log` returned exactly 63 because of rounding. So I checked if 2 to the power 63 is equal to the original number - and it is, because the calculation is done in `double`s and not in exact numbers:

``````private bool IsPowerOfTwo_2(ulong number)
{
double log = Math.Log(number, 2);
double pow = Math.Pow(2, Math.Round(log));
return pow == number;
}
``````

This returned `true` for the given wrong value: `9223372036854775809`.

Does anyone have any suggestion for a better algorithm?

-
I think the solution `(x & (x - 1))` may return false positives when `X` is a sum of powers of two, e.g. `8 + 16`. – Joe Brown Nov 24 '11 at 2:52
All numbers can be written as a sum of powers of two, it's why we can represent any number in binary. Furthermore, your example does not return a false positive, because 11000 & 10111 = 10000 != 0. – vlsd Nov 24 '11 at 3:09
best explanation for how this works :) thanks! – Joe Brown Nov 29 '11 at 17:30

There's a simple trick for this problem:

``````bool IsPowerOfTwo(ulong x)
{
return (x & (x - 1)) == 0;
}
``````

For completeness, zero is not a power of two. If you want to take into account that edge case, here's how:

``````bool IsPowerOfTwo(ulong x)
{
return (x != 0) && ((x & (x - 1)) == 0);
}
``````

### Explanation

First and foremost the bitwise binary & operator from MSDN definition:

Binary & operators are predefined for the integral types and bool. For integral types, & computes the logical bitwise AND of its operands. For bool operands, & computes the logical AND of its operands; that is, the result is true if and only if both its operands are true.

Now let's take a look at how this all plays out:

The function returns boolean (true / false) and accepts one incoming parameter of type unsigned long (x, in this case). Let us for the sake of simplicity assume that someone has passed the value 4 and called the function like so:

``````bool b = IsPowerOfTwo(4)
``````

Now we replace each occurrence of x with 4:

``````return (4 != 0) && ((4 & (4-1)) == 0);
``````

Well we already know that 4 != 0 evals to true, so far so good. But what about:

``````((4 & (4-1)) == 0)
``````

This translates to this of course:

``````((4 & 3) == 0)
``````

But what exactly is `4&3`?

The binary representation of 4 is 100 and the binary representation of 3 is 011 (remember the & takes the binary representation of these numbers. So we have:

``````100 = 4
011 = 3
``````

Imagine these values being stacked up much like elementary addition. The `&` operator says that if both values are equal to 1 then the result is 1, otherwise it is 0. So `1 & 1 = 1`, `1 & 0 = 0`, `0 & 0 = 0`, and `0 & 1 = 0`. So we do the math:

``````100
011
----
000
``````

The result is simply 0. So we go back and look at what our return statement now translates to:

``````return (4 != 0) && ((4 & 3) == 0);
``````

Which translates now to:

``````return true && (0 == 0);
``````
``````return true && true;
``````

We all know that `true && true` is simply `true`, and this shows that for our example, 4 is a power of 2.

-
@Kripp: The number will be of the binary form 1000...000. When you -1 it, it will be of the form 0111...111. Thus, the two number's binary and would result is 000000. This wouldn't happen for non-power-of-twos, since 1010100 for example would become 1010011, resulting in an (continued...) – configurator Mar 1 '09 at 19:15
... Resulting in a 1010000 after the binary and. The only false positive would be 0, which is why I would use: return (x != 0) && ((x & (x - 1)) == 0); – configurator Mar 1 '09 at 19:16
Kripp, consider (2:1, 10:1) (4:3, 100:11) (8:7, 1000:111) (16:15, 10000:1111) See the pattern? – Thomas L Holaday Mar 1 '09 at 19:18
@ShuggyCoUk: two's complement is how negative numbers are represented. Since this is an unsigned integer, representation of negative numbers is not relevant. This technique only relies on binary representation of nonnegative integers. – Greg Hewgill Mar 1 '09 at 22:57
I am amazed that this is accepted and highly rated. This is wrong. It claims that zero is a power of two. – Matt Howells Nov 26 '09 at 16:33
show 21 more comments

Some sites that document and explain this and other bit twiddling hacks are:

And the grandaddy of them, the book "Hacker's Delight" by Henry Warren, Jr.:

As Sean Anderson's page explains, the expression `((x & (x - 1)) == 0)`incorrectly indicates that 0 is a power of 2. He suggests to use:

``````(!(x & (x - 1)) && x)
``````

to correct that problem.

-

`return (i & -i) == i`

-
any hint why this will or will not work? i checked its correctness in java only, where there are only signed ints/longs. if it is correct, this would be the superior answer. faster+smaller – Andreas Petersson Jul 21 '09 at 21:11
It takes advantage of one of the properties of two's-complement notation: to calculate the negative value of a number you perform a bitwise negation and add 1 to the result. The least significant bit of `i` which is set will also be set in `-i`. The bits below that will be 0 (in both values) while the bits above it will be inverted with respect to each other. The value of `i & -i` will therefore be the least significant set bit in `i` (which is a power of two). If `i` has the same value then that was the only bit set. It fails when `i` is 0 for the same reason that `i & (i - 1) == 0` does. – Michael Carman Aug 15 '09 at 14:04
If `i` is an unsigned type, twos complement has nothing to do with it. You're merely taking advantage of the properties of modular arithmetic and bitwise and. – R.. Sep 4 '10 at 0:57
This doesn't work if `i==0` (returns `(0&0==0)` which is `true`). It should be `return i && ( (i&-i)==i )` – bobobobo Nov 14 '11 at 16:59

I wrote an article about this recently at http://www.exploringbinary.com/ten-ways-to-check-if-an-integer-is-a-power-of-two-in-c/. It covers bit counting, how to use logarithms correctly, the classic "x && !(x & (x - 1))" check, and others.

-
``````bool IsPowerOfTwo(ulong x)
{
return x > 0 && (x & (x - 1)) == 0;
}
``````
-
@Carl: No. 2^0 = 1. – Matt Howells May 2 '12 at 15:09

After posting the question I thought of the following solution:

We need to check if exactly one of the binary digits is one. So we simply shift the number right one digit at a time, and return `true` if it equals 1. If at any point we come by an odd number (`(number & 1) == 1`), we know the result is `false`. This proved (using a benchmark) slightly faster than the original method for (large) true values and much faster for false or small values.

``````private static bool IsPowerOfTwo(ulong number)
{
while (number != 0)
{
if (number == 1)
return true;

if ((number & 1) == 1)
// number is an odd number and not 1 - so it's not a power of two.
return false;

number = number >> 1;
}
return false;
}
``````

Of course, Greg's solution is much better.

-
``````bool IsPowerOfTwo( ulong number )
{
if( i == 0 ) return false;
ulong minus1 = i -1;
return (i|minus1) == (i^minus1);
}
``````
-
 Yes, this is basically the same as (i != 0) && ((i & (i-1)) == 0) ? – configurator Aug 25 '10 at 21:41

Here's a simple c++ solution:

``````bool IsPowerOfTwo( unsigned int i )
{
return std::bitset<32>(i).count() == 1;
}
``````
-
I don't think C# defines std::bitset... – configurator Aug 25 '10 at 21:40
@configurator You're right! But this is C++... – Humphrey Bogart Aug 26 '10 at 14:45
It's also the slowest solution I've seen... – R.. Sep 4 '10 at 0:59
on gcc this compiles down to a single gcc builtin called `__builtin_popcount`. Unfortunately, one family of processors doesn't yet have a single assembly instruction to do this (x86), so instead it's the fastest method for bit counting. On any other architecture this is a single assembly instruction. – deft_code Sep 4 '10 at 18:11
``````bool isPow2 = ((x & ~(x-1))==x)? x : 0;
``````
-
Is this `c#`? I guess this is `c++` as `x` is returned as a bool. – Protron Sep 3 '10 at 18:58
I did write it as C++. To make it C# is trivial: bool isPow2 = ((x & ~(x-1))==x)? x!=0 : false; – abelenky Sep 3 '10 at 19:05
This should also work with C99 bool, but it's ugly. – R.. Sep 4 '10 at 0:58

Find if the given number is a power of 2.

``````#include <math.h>

int main(void)
{
int n,logval,powval;
printf("Enter a number to find whether it is s power of 2\n");
scanf("%d",&n);
logval=log(n)/log(2);
powval=pow(2,logval);

if(powval==n)
printf("The number is a power of 2");
else
printf("The number is not a power of 2");

getch();
return 0;
}
``````
-
Or, in C#: return x == Math.Pow(2, Math.Log(x, 2)); – configurator Apr 1 '10 at 3:43
Broken. Suffers from major floating point rounding issues. Use `frexp` rather than nasty `log` stuff if you want to use floating point. – R.. Sep 4 '10 at 1:00
``````bool isPowerOfTwo(int x_)
{
register int bitpos, bitpos2;
asm ("bsrl %1,%0": "+r" (bitpos):"rm" (x_));
asm ("bsfl %1,%0": "+r" (bitpos2):"rm" (x_));
return bitpos > 0 && bitpos == bitpos2;
}
``````
-

int isPowerOfTwo(unsigned int x)

{

``````return ((x != 0) && ((x & (~x + 1)) == x));
``````

}

This is really fast. It takes about 6 minutes and 43 seconds to check all 2^32 integers.

-
 This answer is pretty much identical to stackoverflow.com/a/3638615/9536 – configurator Sep 20 '12 at 0:24

A number is a power of 2 if it contains only 1 set bit. We can use this property and the generic function `countSetBits` to find if a number is power of 2 or not.

This is a C++ program:

``````int countSetBits(int n)
{
int c = 0;
while(n)
{
c += 1;
n  = n & (n-1);
}
return c;
}

bool isPowerOfTwo(int n)
{
return (countSetBits(n)==1);
}
int main()
{
int i, val[] = {0,1,2,3,4,5,15,16,22,32,38,64,70};
for(i=0; i<sizeof(val)/sizeof(val[0]); i++)
printf("Num:%d\tSet Bits:%d\t is power of two: %d\n",val[i], countSetBits(val[i]), isPowerOfTwo(val[i]));
return 0;
}
``````

We dont need to check explicitly for 0 being a Power of 2, as it returns False for 0 as well.

OUTPUT

``````Num:0   Set Bits:0   is power of two: 0
Num:1   Set Bits:1   is power of two: 1
Num:2   Set Bits:1   is power of two: 1
Num:3   Set Bits:2   is power of two: 0
Num:4   Set Bits:1   is power of two: 1
Num:5   Set Bits:2   is power of two: 0
Num:15  Set Bits:4   is power of two: 0
Num:16  Set Bits:1   is power of two: 1
Num:22  Set Bits:3   is power of two: 0
Num:32  Set Bits:1   is power of two: 1
Num:38  Set Bits:3   is power of two: 0
Num:64  Set Bits:1   is power of two: 1
Num:70  Set Bits:3   is power of two: 0
``````
-
 returning c as an 'int' when the function has a return type of 'ulong'? Using a `while` instead of an `if`? I personally can't see a reason but it would seem to work. EDIT:- no ... it will return 1 for anything greater than `0`!? – James Khoury Jan 13 '12 at 2:08 @JamesKhoury I was writing a c++ program so I mistakingly returned an int. However that was a small typos and didn't deserved a downvote. But I fail to understand the reasoning for the rest of your comment "using while instead of if" and "it will return 1 for anything greater than 0". I added the main stub to check the output. AFAIK its the expected output. Correct me if I am wrong. – jerrymouse Jan 13 '12 at 6:56

return ((x != 0) && !(x & (x - 1)));

If x is a power of two, its lone 1 bit is in position n. This means x – 1 has a 0 in position n. To see why, recall how binary subtraction works. When subtracting 1 from x, the borrow propagates all the way to position n; bit n becomes 0 and all lower bits become 1. Now, since x has no 1 bits in common with x – 1, x & (x – 1) is 0, and !(x & (x – 1)) is true.

-

Here is another method I devised, in this case using `|` instead of `&` :

``````bool is_power_of_2(ulong x) {
if(x ==  (1 << (sizeof(ulong)*8 -1) ) return true;
return (x > 0) && (x<<1 == (x|(x-1)) +1));
}
``````
-
 Do you need the `(x > 0)` bit here? – configurator Apr 25 at 17:31 @configurator, yes, otherwise is_power_of_2(0) would return true – Chethan Apr 26 at 9:17
``````private static bool IsPowerOfTwo(ulong x)
{
var l = Math.Log(x, 2);
return (l == Math.Floor(l));
}
``````
-
Try that for the number 9223372036854775809. Does it work? I'd think not, because of rounding errors. – configurator Jul 22 '09 at 14:39
@configurator 922337203685477580_9_ doesn't look like a power of 2 to me ;) – Kirschstein Mar 31 '10 at 13:32
@Kirschstein: that number gave him a false positive. – Erich Mirabal Mar 31 '10 at 13:42
Kirschstein: It doesn't look like one to me either. It does look like one to the function though... – configurator Apr 1 '10 at 3:44

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