Is there a trick for creating a faster integer modulus than the standard % operator for particular bases?
For my program, I'd be looking for around 1000-4000 (e.g. n%2048). Is there a quicker way to perform n modulus 2048 than simply:
If it's a power of 2, like your example of 2048, you could subtract 1 and do a bitwise-and.
Bear in mind that a good compiler will have its own optimizations for
For powers of two
For example (assuming 32 bit integers):
This is because
You could zero out the high order bits i.e.
x = 11 = 1011
so for x % 4 you could just take the last 2 bits - I'm not sure what would happen if negative numbers were used though
The fastest way to multiply/divide unsigned integers numbers is by bit shifting them left or right. Shift operations match directly to CPU commands. For example, 3 << 2 =6, while 4>>1 = 2.
You can use the same trick to calculate the module: Shift an integer far enough to the left so that only the remainder bits are left, then shift it back right so you can check the remainder value.
On the other hand, integer modulo also exists as a CPU command. If the integer modulo operator maps to this command in optimized builds, you will not see any improvement by using the bit shift trick.
The following code caclulates 7%4 by shifting far enough that only the 2 last bits are left (since 4=2^2). This means that we need to shift 30 bits:
The result is 3
I just read all the solutions proposing simply erasing the higher order bits. It has the same effect, but a lot simpler and direct.
Here's a few techniques that replicate the modulus operation.
Of those benchmarked, this was the fastest (modified to fit your 2048 scenario). As long as your "max" isn't millions and in the 1000-4000 range you mentioned, it may work faster for you too:
Give it a go. It performed faster on the author's machine at various settings, so should perform admirably well for you too.
If you are dividing by literals that are powers of two, then the answer is probably No: Any decent compiler will automatically turn such expressions into a variation of an AND operation, which is pretty close to optimal.