int x = n / 3; // < make this faster
// for instance
int a = n * 3; // < normal integer multiplication
int b = (n << 1) + n; // < potentially faster multiplication



This is the fastest as the compiler will optimize it if it can depending on the output processor.



The guy who said "leave it to the compiler" was right, but I don't have the "reputation" to mod him up or comment. I asked gcc to compile int test(int a) { return a / 3; } for an ix86 and then disassembled the output. Just for academic interest, what it's doing is roughly multiplying by 0x55555556 and then taking the top 32 bits of the 64 bit result of that. You can demonstrate this to yourself with eg: $ ruby e 'puts(60000 * 0x55555556 >> 32)' 20000 $ ruby e 'puts(72 * 0x55555556 >> 32)' 24 $ The wikipedia page on Montgomery division is hard to read but fortunately the compiler guys have done it so you don't have to. 


There is a faster way to do it if you know the ranges of the values, for example, if you are dividing a signed integer by 3 and you know the range of the value to be divided is 0 to 768, then you can multiply it by a factor and shift it to the left by a power of 2 to that factor divided by 3. eg. Range 0 > 768 you could use shifting of 10 bits, which multiplying by 1024, you want to divide by 3 so your multiplier should be 1024 / 3 = 341, so you can now use (x * 341) >> 10 This will effectively divide the value 3, and will run at about 1.6 times the speed as a natural divide by 3 on a standard x86 / x64 CPU. Of course the only reason you can make this optimization when the compiler cant is because the compiler does not know the maximum range of X and therefore cannot make this determination, but you as the programmer can. Sometime it may even be more beneficial to move the value into a larger value and then do the same thing, ie. if you have an int of full range you could make it an 64bit value and then do the multiply and shift instead of dividing by 3. I had to do this recently to speed up image processing, i needed to find the average of 3 color channels, each color channel with a byte range (0  255). red green and blue. At first i just simply used: avg = (r + g + b) / 3; (So r + g + b has a maximum of 768 and a minimum of 0, because each channel is a byte 0  255) After millions of iterations the entire operation took 36 milliseconds. I changed the line to: avg = (r + g + b) * 341 >> 10; And that took it down to 22 milliseconds, its amazing what can be done with a little ingenuity. This speed up occurred in C# even though I had optimisations turned on and was running the program natively without debugging info and not through the IDE. 


See How To Divide By 3 for an extended discussion of more efficiently dividing by 3, focused on doing FPGA arithmetic operations. Also relevant: 


Depending on your platform and depending on your C compiler, a native solution like just using
Can be fast or it can be awfully slow (even if division is done entirely in hardware, if it is done using a DIV instruction, this instruction is about 3 to 4 times slower than a multiplication on modern CPUs). Very good C compilers with optimization flags turned on may optimize this operation, but if you want to be sure, you are better off optimizing it yourself. For optimization it is important to have integer numbers of a known size. In C int has no known size (it can vary by platform and compiler!), so you are better using C99 fixedsize integers. The code below assumes that you want to divide an unsigned 32bit integer by three and that you C compiler knows about 64 bit integer numbers (NOTE: Even on a 32 bit CPU architecture most C compilers can handle 64 bit integers just fine):
As crazy as this might sound, but the method above indeed does divide by 3. All it needs for doing so is a single 64 bit multiplication and a shift (like I said, multiplications might be 3 to 4 times faster than divisions on your CPU). In a 64 bit application this code will be a lot faster than in a 32 bit application (in a 32 bit application multiplying two 64 bit numbers take 3 multiplications and 3 additions on 32 bit values)  however, it might be still faster than a division on a 32 bit machine. On the other hand, if your compiler is a very good one and knows the trick how to optimize integer division by a constant (latest GCC does, I just checked), it will generate the code above anyway (GCC will create exactly this code for "/3" if you enable at least optimization level 1). For other compilers... you cannot rely or expect that it will use tricks like that, even though this method is very well documented and mentioned everywhere on the Internet. Problem is that it only works for constant numbers, not for variable ones. You always need to know the magic number (here 0xAAAAAAAB) and the correct operations after the multiplication (shifts and/or additions in most cases) and both is different depending on the number you want to divide by and both take too much CPU time to calculate them on the fly (that would be slower than hardware division). However, it's easy for a compiler to calculate these during compile time (where one second more or less compile time plays hardly a role). 


I don't know if it's faster but if you want to use a bitwise operator to perform binary division you can use the shift and subtract method described at this page:



What if you really don't want to multiply or divide? Here is is an approximation I just invented. It works because (x/3) = (x/4) + (x/12). But since (x/12) = (x/4) / 3 we just have to repeat the process until its good enough.
The result is 330. It could be made more accurate using b = ((b+2)>>2); to account for rounding. If you are allowed to multiply, just pick a suitable approximation for (1/3), with a powerof2 divisor. For example, n * (1/3) ~= n * 43 / 128 = (n * 43) >> 7. This technique is most useful in Indiana. 


If you really want to see this article on integer division, but it only has academic merit ... it would be an interesting application that actually needed to perform that benefited from that kind of trick. 


For really large integer division (e.g. numbers bigger than 64bit) you can represent your number as an int[] and perform division quite fast by taking two digits at a time and divide them by 3. The remainder will be part of the next two digits and so forth. eg. 11004 / 3 you say 11/3 = 3, remaineder = 2 (from 113*3) 20/3 = 6, remainder = 2 (from 206*3) 20/3 = 6, remainder = 2 (from 206*3) 24/3 = 8, remainder = 0 hence the result 3668



Easy computation ... at most n iterations where n is your number of bits:



A lookup table approach would also be faster in some architectures.


