64 bit integer arithmetic instructions slower than their
32 bit counter parts (on
x86_64 machine with
64 bit OS)?
Edit: On current CPUs such Intel Core2 Duo, i5/i7 etc.
It depends on the exact CPU and operation. On 64-bit Pentium IVs, for example, multiplication of 64-bit registers was quite a bit slower. Core 2 and later CPUs have been designed for 64-bit operation from the ground up.
Generally, even code written for a 64-bit platform uses 32-bit variables where values will fit in them. This isn't primarily because arithmetic is faster (on modern CPUs, it generally isn't) but because it uses less memory and memory bandwidth.
A structure containing a dozen integers will be half the size if those integers are 32-bit than if they are 64-bit. This means it will take half as many bytes to store, half as much space in the cache, and so on.
64-bit native registers and arithmetic are used where values may not fit into 32-bits. But the main performance benefits come from the extra general purpose registers available in the x86_64 instruction set. And of course, there are all the benefits that come from 64-bit pointers.
So the real answer is that it doesn't matter. Even if you use x86_64 mode, you can (and generally do) still use 32-bit arithmetic where it will do, and you get the benefits of larger pointers and more general purpose registers. When you use 64-bit native operations, it's because you need 64-bit operations, and you know they'll be faster than faking it with multiple 32-bit operations -- your only other choice. So the relative performance of 32-bit versus 64-bit registers should never be a deciding factor in any implementation decision.
In a primarily 32-bit application (meaning only 32-bit arithmetic is used, and 32-bit pointers are sufficient), the real benefits of the x86-64 architecture are the other "updates" AMD made to the architecture:
This is evident by the new x32 ABI implemented in Linux.