Is there a fast way of using 64bit ints on 32 x86 machines (in c
int isn't guaranteed to be 64 bits wide; It's guaranteed to be at least 16 bits wide. If you want a type that's guaranteed to be at least 64 bits wide, use
long long instead. Talking about optimisation at this level is quite fruitless. You're better off coming up with a complete solution, profiling it to determine what the slowest part of the solution is and targeting that part of your code for optimisation or choosing a different algorithm that performs that slow operation more quickly. Note: By solution, I mean "a program that solves an actual problem".
32 bit x86 support 64 bit operations in some extent (there is some movq instruction in old mmx and some other commands probably), but how to use it from c?
Whether or not your compiler performs the movq and/or mmx optimisations you mentioned automatically is questionable, as you haven't told us which compiler you're using. However, given the simplicity of this sort of optimisation compared to others (eg. dead code optimisation, tail call optimisation, even loop unrolling), I'd guess that your compiler does it automatically. This is another reason talking about optimisation at this level is fruitless; Those who write compilers are usually very good programmers, with a keen understanding of algorithms who can write automaton to perform simple optimisations easily.
What if someone want to use a 64bit ints arithmetic in c on 32 bit x86
machines - how to do it most easy and efficient?
Have you tried compiling a fully-optimised testcase and looking for
movq operations in it's machine code? If I haven't convinced you that you should profile your code to determine whether or not this is actually worth targetting, then do this: Compile your solution (something that solves a problem, remember... and compile as "fully optimised"), benchmark it so that you have something to measure your optimisations against, convert the machine code to assembly, perform any manual optimisations in assembly, recompile and benchmark again. You might:
- spend a week looking optimising and benchmarking to find that you've shaved a few microseconds and give up... This would be a good indication that your compiler spends a few seconds producing code that is as good as the code you'd take weeks to write. Keep the compiler, but give up on the micro-optimisation.
- find a significant optimisation that your compiler doesn't perform (fairly unlikely). Either choose a more optimal compiler, or get in contact with the people who wrote your compiler, and explain it to them...
Either way, progress!