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

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 `log2 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`.

Is there 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
• My upvote brought the score to 256. Nice. – Rob Kielty Feb 14 '14 at 13:05
• @RobKielty `256 & (256 - 1) == 0`. Approved. – configurator Feb 15 '14 at 16:10
• @JoeBrown It doesn't have any false positives. In fact the expression returns the larger of any sum of two powers of two. – Samy Bencherif Dec 7 '18 at 23:48

There's a simple trick for this problem:

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

Note, this function will report `true` for `0`, which is not a power of `2`. If you want to exclude that, 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
• @SoapBox - what is more common? Zeroes or non-zero numbers which aren't powers of two? This is a question you can't answer without some more context. And it really, really doesn't matter anyway. – configurator Oct 22 '10 at 23:33

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.

• 0 is a power of 2... 2 ^ -inf = 0. ;) ;) ;) – Michael Bray Sep 28 '16 at 4:47
• Since this is a C# tagged thread, it is worth pointing out that the last expression (of Sean Anderson) is illegal in C# since `!` can only be applied to boolean types, and `&&` also requires both operands to be boolean- (Except that user defined operators make other things possible, but that is not relevant for `ulong`.) – Jeppe Stig Nielsen Mar 4 '18 at 11:13

`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
``````bool IsPowerOfTwo(ulong x)
{
return x > 0 && (x & (x - 1)) == 0;
}
``````
• This solution is better because it can also deal with negative number if negative were able to pass in. (if long instead of ulong) – Steven Jan 27 '15 at 0:54

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.

Here's a simple C++ solution:

``````bool IsPowerOfTwo( unsigned int i )
{
return std::bitset<32>(i).count() == 1;
}
``````
• 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
• @deft_code newer x86 microarchitectures support `popcnt` – phuclv Mar 16 '17 at 11:23

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.

• This was much easier for me to understand, thanks! – AdaRaider Dec 12 '18 at 13:45
``````    bool IsPowerOfTwo(int n)
{
if (n > 1)
{
while (n%2 == 0)
{
n >>= 1;
}
}
return n == 1;
}
``````

And here's a general algorithm for finding out if a number is a power of another number.

``````    bool IsPowerOf(int n,int b)
{
if (n > 1)
{
while (n % b == 0)
{
n /= b;
}
}
return n == 1;
}
``````

The following addendum to the accepted answer may be useful for some people:

A power of two, when expressed in binary, will always look like 1 followed by n zeroes where n is greater than or equal to 0. Ex:

``````Decimal  Binary
1        1     (1 followed by 0 zero)
2        10    (1 followed by 1 zero)
4        100   (1 followed by 2 zeroes)
8        1000  (1 followed by 3 zeroes)
.        .
.        .
.        .
``````

and so on.

When we subtract `1` from these kind of numbers, they become 0 followed by n ones and again n is same as above. Ex:

``````Decimal    Binary
1 - 1 = 0  0    (0 followed by 0 one)
2 - 1 = 1  01   (0 followed by 1 one)
4 - 1 = 3  011  (0 followed by 2 ones)
8 - 1 = 7  0111 (0 followed by 3 ones)
.          .
.          .
.          .
``````

and so on.

Coming to the crux

What happens when we do a bitwise AND of a number `x`, which is a power of 2, and `x - 1`?

The one of `x` gets aligned with the zero of `x - 1` and all the zeroes of `x` get aligned with ones of `x - 1`, causing the bitwise AND to result in 0. And that is how we have the single line answer mentioned above being right.

So, we have a property at our disposal now:

When we subtract 1 from any number, then in the binary representation the rightmost 1 will become 0 and all the zeroes before that rightmost 1 will now become 1

One awesome use of this property is in finding out - How many 1s are present in the binary representation of a given number? The short and sweet code to do that for a given integer `x` is:

``````byte count = 0;
for ( ; x != 0; x &= (x - 1)) count++;
Console.Write("Total ones in the binary representation of x = {0}", count);
``````

Another aspect of numbers that can be proved from the concept explained above is "Can every positive number be represented as the sum of powers of 2?".

Yes, every positive number can be represented as the sum of powers of 2. For any number, take its binary representation. Ex: Take number `117`.

``````The binary representation of 117 is 1110101

Because  1110101 = 1000000 + 100000 + 10000 + 0000 + 100 + 00 + 1
we have  117     = 64      + 32     + 16    + 0    + 4   + 0  + 1
``````
• @Michi: Did I claim somewhere that 0 is a positive number? Or a power of 2? – displayName May 23 '17 at 4:08
• Yes, by putting 0 as an example and making that math on it inside that binary representation. It creates a Confusion. – Michi May 23 '17 at 16:45
• If adding two numbers confuses you into believing that they have to be positive, I cannot do anything about it. Further, 0's have been shown in the representation to imply that that power of 2 is skipped in this number. Anyone who knows basic maths is aware that adding 0 means not adding anything. – displayName Apr 9 at 21:25
``````bool isPow2 = ((x & ~(x-1))==x)? !!x : 0;
``````
• Is this `c#`? I guess this is `c++` as `x` is returned as a bool. – Mariano Desanze 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
• On my machine this is wrong 1,529,257,049 times! :) – Adam Burry Oct 24 '13 at 19:21
``````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.

``````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 a 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.

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

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 '13 at 17:31
• @configurator, yes, otherwise is_power_of_2(0) would return true – Chethan Apr 26 '13 at 9:17

Example

``````0000 0001    Yes
0001 0001    No
``````

Algorithm

1. Using a bit mask, divide `NUM` the variable in binary

2. `IF R > 0 AND L > 0: Return FALSE`

3. Otherwise, `NUM` becomes the one that is non-zero

4. `IF NUM = 1: Return TRUE`

5. Otherwise, go to Step 1

Complexity

Time ~ `O(log(d))` where `d` is number of binary digits

for any power of 2, the following also holds.

## n&(-n)==n

NOTE: fails for n=0 , so need to check for it
Reason why this works is:
-n is the 2s complement of n. -n will have every bit to the left of rightmost set bit of n flipped compared to n. For powers of 2 there is only one set bit.

Improving the answer of @user134548, without bits arithmetic:

``````public static bool IsPowerOfTwo(ulong n)
{
if (n % 2 != 0) return false;  // is odd (can't be power of 2)

double exp = Math.Log(n, 2);
if (exp != Math.Floor(exp)) return false;  // if exp is not integer, n can't be power
return Math.Pow(2, exp) == n;
}
``````

This works fine for:

``````IsPowerOfTwo(9223372036854775809)
``````

This program in java returns "true" if number is a power of 2 and returns "false" if its not a power of 2

``````// To check if the given number is power of 2

import java.util.Scanner;

public class PowerOfTwo {
int n;
void solve() {
while(true) {
//          To eleminate the odd numbers
if((n%2)!= 0){
System.out.println("false");
break;
}
//  Tracing the number back till 2
n = n/2;
//  2/2 gives one so condition should be 1
if(n == 1) {
System.out.println("true");
break;
}
}
}
public static void main(String[] args) {
// TODO Auto-generated method stub
Scanner in = new Scanner(System.in);
PowerOfTwo obj = new PowerOfTwo();
obj.n = in.nextInt();
obj.solve();
}

}

OUTPUT :
34
false

16
true
``````
``````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

return i > 0 && (i ^ -i) == (-i << 1);

Haven't found such an answer. Let it be mine

• `Let it be mine` not without an explanation why the `i > 0` part would be needed. – greybeard Mar 2 at 13:38
• this solution doesn't work for 0. As well it won't work if 'i' is negative. – Aliaksei Yatsau Mar 2 at 21:11
• You should probably expand on why `i ^ -i` would equal `-i << 1` if and only if i is a power of two. – configurator Mar 3 at 9:27
• I am not a math specialist so won't proof it with formulas. For power of 2 values `-i` operation would fill all zeros before `1` to `1`. Let say 0010 0000 -> 1110 0000. And XOR in such case removes the initial bit. That's why left shift needed. No proofs but clear to my vision how negative values behave in such cases and tested to Int.MAX it works as expected. So "Let it be mine" – Aliaksei Yatsau Mar 23 at 14:47