In cases where y
is 2, there is a quick approach that avoids the need for a loop. This approach can be extended to cases where y
is some larger power of 2.
If x
is a power of 2, the binary representation of x
has a single set bit. There is a fairly simple bit-fiddling algorithm for counting the bits in an integer in O(log n) time where n is the bit-width of an integer. Many processors also have specialised instructions that can handle this as a single operation, about as fast as (for example) an integer negation.
To extend the approach, though, first take a slightly different approach to checking for a single bit. First determine the position of the least significant bit. Again, there is a simple bit-fiddling algorithm, and many processors have fast specialised instructions.
If this bit is the only bit, then (1 << pos) == x
. The advantage here is that if you're testing for a power of 4, you can test for pos % 2 == 0
(the single bit is at an even position). Testing for a power of any power of two, you can test for pos % (y >> 1) == 0
.
In principle, you could do something similar for testing for powers of 3 and powers of powers of 3. The problem is that you'd need a machine that works in base 3, which is a tad unlikely. You can certainly test any value x
to see if its representation in base y
has a single non-zero digit, but you'd be doing more work that you're already doing. The above exploits the fact that computers work in binary.
Probably not worth doing in the real world, though.