# Moving set bits to the end of 64bits integer

I am working on a function that takes a 64bits integer as parameter and returns a 64bits integer with all set bits at the end.

``````01011001 -> 00001111   // examples
00010100 -> 00000011
``````

I first thought about the following algorithm:

``````nb_ones = countSetBit(x)
int64 res = 1
for i from 1 to nb_ones+1:
res |= (1 << i)
``````

Here `countSetBit` is the one defined here

Is there something more straightforward ? I am working in C++

To set a given number of ones at the end, just go to the next power of two and subtract one.

``````nb_ones = countSetBit(x)
int64 res = nb_ones == 64 ? -1 : ((1 << nb_ones) - 1);
``````

Edit: Nice non-branching solution from MSalters' comment:

``````int64_t res = ((1^(nb_ones>>6))<<nb_ones)-1;
``````

(the 6th bit in nb_ones is one if-and-only-if nb_ones==64)

The background for the undefined behavior for << 64 is probably that the corresponding native operation might only use the bits of the argument needed for the maximum reasonable shift value, and handling this on the C++ side would add overhead.

• What about the case where `x == (int64)-1` ? Because `1 << 64` would trigger undefined behavior – Nayuki Nov 9 '17 at 15:01
• Yup, like that (have an upvote), but you do need to check for the edge case `-1`. – Bathsheba Nov 9 '17 at 15:01
• Thanks, fixed O:) – Stefan Haustein Nov 9 '17 at 15:02
• There's a non-branching solution : `int64_t res = ((1^(nb_ones>>6))<<nb_ones)-1;` - the 6th bit in `nb_ones` is one if-and-only-if `nb_ones==64`. – MSalters Nov 9 '17 at 15:51

You can avoid the loop:

``````const auto nb_ones = countSetBit(x)
if (nb_ones == 64) {
return -1; // 0xFFFFFFFFFFFFFFFF;
} else {
return (1u << nb_ones) - 1;
}
``````
• ͏+͏1͏. Out of interest, do you really find `0xFFFFFFFFFFFFFFFF` clearer than `-1`? Or am I an odd cat? – Bathsheba Nov 9 '17 at 15:02
• @Bathsheba: -1 is also clearer to me too. – Jarod42 Nov 9 '17 at 15:08

Counting all bits is a bit overkill as most CPU's have an efficient test against zero.

So, what we do is use that as the exit condition:

``````output = 0;
while (input != 0) {
if (input & 1) output = (output<<1)+1;
input >>= 1;
}
``````

The loop shifts the input to the right, adding one extra bit to `output` whenever a bit is shifted out of `input`. Clearly this adds as many bits to `output` as there are in `input` (possibly 0, possibly 64). But the bits in `output` are contiguous as `output` is only shifted when a bit is added.

If your CPU has a bitcount operation, that's going to be faster of course. And if you'd implement this in x86 or ARM assembly, you'd use the fact that `input&1` is the same bit that is shifted out by `>>=1`.

• You're late to the party but nonetheless this is the best answer. Have an upvote! – Bathsheba Nov 9 '17 at 16:37

Since you have several efficient answers, when you actually asked for a straightforward one, have a slow-but-conceptually-very-simple answer for variety:

``````uint64_t num(uint64_t x)
{
// construct a base-2 string
auto s = std::bitset<64>(x).to_string();
// sort the 1s to the end
std::sort(begin(s), end(s));
// and convert it back to an integer
return std::bitset<64>(s).to_ulong();
}
``````
• This is so nicely written it demonstrated to me that I implemented completely the wrong thing. Have an upvote too. – Bathsheba Nov 9 '17 at 16:54
• I still don't have any intuition about why OP wants these bits there, or what it could be useful for - which is probably why it took me a couple of reads to figure out as well. – Useless Nov 9 '17 at 17:00

I think you can do it with just a single loop:

``````std::uint64_t bits_to_end(std::uint64_t n)
{
std::uint64_t x = 0;

for(std::uint64_t bit = 0, pos = 0; bit < 64; ++bit)
if(n & (1ULL << bit))
x |= (1ULL << pos++);

return x;
}
``````