I couldn't reproduce the problem.
My test was as follows (int version shown):
// deliberately made hard to optimise without whole program optimisation
public static int[] data = new int[1000000]; // long[] when testing long
// I happened to have a winforms app open, feel free to make this a console app..
private void button1_Click(object sender, EventArgs e)
{
long best = long.MaxValue;
for (int j = 0; j < 1000; j++)
{
Stopwatch timer = Stopwatch.StartNew();
int a1 = ~0, b1 = 0x55555555, c1 = 0x12345678; // varies: see below
int a2 = ~0, b2 = 0x55555555, c2 = 0x12345678;
int[] d = data; // long[] when testing long
for (int i = 0; i < d.Length; i++)
{
int v = d[i]; // long when testing long, see below
a1 &= v; a2 &= v;
b1 &= v; b2 &= v;
c1 &= v; c2 &= v;
}
// don't average times: we want the result with minimal context switching
best = Math.Min(best, timer.ElapsedTicks);
button1.Text = best.ToString() + ":" + (a1 + a2 + b1 + b2 + c1 + c2).ToString("X8");
}
}
For testing longs a1
and a2
etc are merged, giving:
long a = ~0, b = 0x5555555555555555, c = 0x1234567812345678;
Running the two programs on my laptop (i7 Q720) as a release build outside of VS (.NET 4.5) I got the following times:
int: 2238, long: 1924
Now considering there's a huge amount of loop overhead, and that the long
version is working with twice as much data (8mb vs 4mb), it still comes out clearly ahead. So I have no reason to believe that C# is not making full use of the processor's 64 bit bitops.
But we really shouldn't be benching it in the first place. If there's a concern, simply check the jited code (Debug -> Windows -> Disassembly). Ensure the compiler's using the instructions you expect it to use, and move on.
Attempting to measure the performance of those individual instructions on your processor (and this could well be specific to your processor model) in anything other than assembler is a very bad idea - and from within a jit compiled language like C#, beyond futile. But there's no need to anyway, as it's all in Intel's optimisation handbook should you need to know.
To this end, here's the disassembly of the a &=
for the long
version of the program on x64 (release, but inside of debugger - unsure if this affects the assembly, but it certainly affects the performance):
00000111 mov rcx,qword ptr [rsp+60h] ; a &= v
00000116 mov rax,qword ptr [rsp+38h]
0000011b and rax,rcx
0000011e mov qword ptr [rsp+38h],rax
As you can see there's a single 64 bit and operation as expected, along with three 64 bit moves. So far so good, and exactly half the number of ops of the int
version:
00000122 mov ecx,dword ptr [rsp+5Ch] ; a1 &= v
00000126 mov eax,dword ptr [rsp+38h]
0000012a and eax,ecx
0000012c mov dword ptr [rsp+38h],eax
00000130 mov ecx,dword ptr [rsp+5Ch] ; a2 &= v
00000134 mov eax,dword ptr [rsp+44h]
00000138 and eax,ecx
0000013a mov dword ptr [rsp+44h],eax
I can only conclude that the problem you're seeing is specific to something about your test suite, build options, processor... or quite possibly, that the &
isn't the point of contention you believe it to be. HTH.