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If I were to write assembly code for large integer calculations (e.g. prime factoring, modulo calculations, etc.) with a focus on speed, which architecture would be best suited for this: x86(-64), ARM, PowerPC, MIPS or others?

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What language do you plan to use for this ? –  Paul R Sep 9 '11 at 16:07
    
@Paul - assembly... –  Randy Sep 9 '11 at 16:08
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Sorry but this question unanswerable in its present form: you're mixing architectures that are at this moment not even targetting the same market segments (mobile vs desktop vs server - so, best suited in what type of computer?). You could restate the question as best integer performance per Hertz or per Watt, that might be answerable... –  fvu Sep 9 '11 at 16:11

2 Answers 2

There are multiple factors here. I'll try to list them:

  1. logically, an high clock would good thing, since most CPUs do integer calculations in 1 clock avg or less.
  2. However modern CPU's also have multiple execution units (that is per core), so the more integer ALU's the better.
  3. besides integer ALU's, SIMD ALU's (SSE,Altivec) can be employed to do integer calculations also.
  4. Not all CPU can actually emit the maximum instructions per clock that they could theoretically process. So decoding limits also apply.
  5. Since more ALU's help, more cores also help.
  6. Since more cores help, more sockets (CPUs) also helps.
  7. Any modern CPU calculating for more than a few ms will probably have to access memory. Due to the high CPU/memory speed ratio, more cache and faster mem will help.
  8. as fvu already indicates, very fast solutions that cost n*100kdollar (think IBM systems with Power7 here) or that require strange or costly ways of cooling are not very practical.
  9. and of course you need a compiler to actually generate optimal code for all this.
  10. and sb to operate the compiler :-)

In short, bang for the buck is probably x86. x86-64 can be better (if only for the higher count of SSE regs), if your tooling is up to it. If you algorithm is paralellizable, go for max(cores x clock) , otherwise go for max(clock).

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If you work with a small number of variable-size numbers, I think POWER 6 would suit your needs best (although I didn't work with this architecture) since it provides high IPC and very high frequency (up to 5GHz).

It you work with a large number of fixed-size numbers, x86-64 would be the best choice as it has SIMD operations which work on 64-bit numbers, and you can use those operations to speed up long arithmetic operations on multiple numbers. You will likely need an SSE 4.2-capable CPU (Intel Nehalem/Westmere/Sandy Bridge, or the upcoming AMD Bulldozer) since the 64-bit compare instruction PCMPGTQ was only added in SSE 4.2

Also, these GMP benchmark results might be interesting for you

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Power6, Power7 also have SIMD (AltiVec/VMX/VSX) –  Paul R Apr 23 '12 at 10:16
    
Yes, but they do not support 64-bit SIMD operations, and using 32-bit SIMD operations is not worth it - simple (non-SIMD) 64-bit ALU operations will deliver better performance –  Marat Dukhan Apr 23 '12 at 22:50

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