# Differences in division and multiplication vs bit shifting

## DISCLAIMER

I do not want to know when or if to use shift operators in my code, I am interested in why multiplication is faster than shifting bits to the left whereas division is not.

As I was just wandering around SO I came across this question regarding efficiency and speed of division and bit shifting. It basically states that although one might save a few seconds when performing bit shifts on powers of 2, it is not some difference one has to worry about.

Intrigued by this I decided to check how much faster bit shifting in C# actually is and realised something strange:

Bit shifting instead of dividing is faster, as I expected, but the "normal" multiplication method is faster than bit shifting.

My question is simple: Why is the multiplication of two numbers faster than bit shifting, although bit shifting is a primitive operation for the processor?

Here are the results for my test case:

``````           Division: | Multiplication:
Bit shift:   315ms   |   315ms
normal:   406ms   |   261ms
``````

The times are the averages of 100 cases with each case consisting of 10 operations per number on 10000000 random positive numbers ranging from 1 to `int.MaxValue`. The operations ranged from dividing/multiplying by 2 to 1024 (in powers of 2) and bit shifting from 1 to 10 digits.

## EDIT

@usr: I am using .NET version 4.5.1

I updated my results because I realised I only computed a tenth of the numbers I stated... facepalm

My Main:

``````static Main(string[] args)
{
Fill(); // fills the array with random numbers
Profile("division shift:", 100, BitShiftDiv);
Profile("division:", 100, Div);
Profile("multiplication shift:", 100, BitShiftMul);
Profile("multiplication:", 100, Mul);
}
``````

This is my profiling method:

``````static void Profile(string description, int iterations, Action func)
{
GC.Collect()
GC.WaitForPendingFinalizers();
GC.Collect();

func();

Stopwatch stopWatch = Stopwatch.StartNew();
for (int i = 0; i < iterations; i++)
{
func();
}
stopWatch.Stop();

Console.WriteLine(description);
Console.WriteLine("total: {0}ms", stopWatch.Elapsed.TotalMilliseconds);
Console.WriteLine("  avg: {0}ms", stopWatch.Elapsed.TotalMilliseconds / (double)iterations);
}
``````

The Actions containing the operations are structured like this:

``````static void <Name>()
{
for (int s = 1; s <= 10; s++)    /* for shifts */
for (int s = 2; s <= 1024; s++)  /* for others */
{
for (int i = 0; i < nums.Length; i++)
{
var useless = nums[i] <shift> s;    /* shifting  */
var useless = nums[i] <operator> s; /* otherwise */
}
}
}
``````

`nums` is a public array containing `10000000` `int`s, which is filled by the `Fill()` method.

-
Because the optimizer is not stupid. –  SLaks Jun 15 at 18:31
You're probably measuring wrongly; microbenchmarks are hard. –  SLaks Jun 15 at 18:32
You're probably still measuring wrongly. Beware the JITter. yoda.arachsys.com/csharp/benchmark.html –  SLaks Jun 15 at 18:41
The idea that shifting is faster than multiplying was true in some badly optimized C compilers on 1970s hardware. Let the optimizer do it's job. –  Eric Lippert Jun 15 at 18:54
Shifts have extra overhead in C#, explained in this answer. Not running with the optimizer enabled is a standard benchmark mistake. Use Agner Fog's instruction timing manual to get insight. Cycle times are an estimate: shifting a memory value by an arbitrary amount roughly takes 4 cycles, multiplication takes 1, dividing takes between 11 and 18 cycles. These big differences are blurred by the for(;;) loop overhead. –  Hans Passant Jun 15 at 22:33