It isn't a big deal to keep all of the powers of 2 for a 32 bit integer (only 32 entries) do a quick binary search for the location it's supposed to be in. Then you can easily figure out which number it's closer to by subtracting from the higher and lower numbers and getting the abs. Then you can easily decide which one to add to.

You may be able to avoid the search by taking the log base 2 of your number and using that to index into the array

**UPDATE:** reminder this code is not thoroughly tested.

```
#include <array>
#include <cmath>
#include <iostream>
const std::array<unsigned int,32> powers =
{
1,1<<1,1<<2,1<<3,1<<4,1<<5,1<<6,1<<7,1<<8,1<<9,1<<10,1<<11,1<<12,1<<13,1<<14,
1<<15,1<<16,1<<17,1<18,1<<19,1<<20,1<<21,1<<22,1<<23,1<<24,1<<25,1<<26,1<<27,
1<<28,1<<29,1<<30,1<<31 -1
};
std::array<unsigned int,32> powers_of_two() {
std::array<unsigned int,32> powers_of_two{};
for (unsigned int i = 0; i < 31; ++i) {
powers_of_two[i] = 1 << i;
}
powers_of_two[31]=~0;
return powers_of_two;
}
unsigned int round_to_closest(unsigned int number) {
if (number % 2 == 0) return number;
unsigned int i = std::ceil(std::log2(number));
//higher index
return (powers[i]-number) < (number - powers[i-1]) ?
++number:--number;
}
int main() {
std::cout << round_to_closest(27) << std::endl;
std::cout << round_to_closest(23) << std::endl;
return 0;
}
```

Since I can't represent 2 ^ 31 I used the closest unsigned int to it ( all 1's) this means that 1 case out of all of them will produce the incorrect result, I figured that's not a big deal.

I was thinking that you could use a `std::vector<bool>`

as a very large lookup table on wether to add 1 or subtract 1, seems like overkill to me for an operation that seems to run quite fast.