I have ran into a curious problem. An algorithm I am working on consists of lots of computations like this

q = x(0)*y(0)*z(0) + x(1)*y(1)*z(1) + ...

where the length of summation is between 4 and 7.

The original computations are all done using 64-bit precision. For experimentation, I tried using 32-bit precision for x,y,z input values (so that computations are performed using 32-bit), and storing final result as 64-bit value (straightforward cast).

I expected 32-bit performance to be better (cache size, SIMD size, etc.), but to my surprise there was no difference in performance, maybe even decrease.

The architecture in question is Intel 64, Linux, and GCC. Both codes do seem to use SSE and arrays in both cases are aligned to 16 byte boundary.

Why would it be so? My guess so far is that 32-bit precision can use SSE only on the first four elements, with the rest being done serially compounded by cast overhead.

  • You've added a bounty - what didn't you like about dsimcha's answer? It might also be worth trying the most recent GCC you can or Intel's compiler software.intel.com/en-us/articles/… to see if they do a better job compiling / vectorising.
    – Rup
    Jul 6 '10 at 16:56
  • @Rup I like his answer, nevertheless would like other opinions as well, so I put a bounty
    – Anycorn
    Jul 6 '10 at 19:12

On x87 at least, everything is really done in 80-bit precision internally. The precision really just determines how many of those bits are stored in memory. This is part of the reason why different optimization settings can change results slightly: They change the amount of rounding from 80-bit to 32- or 64-bit.

In practice, using 80-bit floating point (long double in C and C++, real in D) is usually slow because there's no efficient way to load and store 80 bits from memory. 32- and 64-bit are usually equally fast provided that memory bandwidth isn't the bottleneck, i.e. if everything is in cache anyhow. 64-bit can be slower if either of the following happens:

  1. Memory bandwidth is the bottleneck.
  2. The 64-bit numbers aren't properly aligned on 8-byte boundaries. 32-bit numbers only require 4-byte alignment for optimal efficiency, so they're less finicky. Some compilers (the Digital Mars D compiler comes to mind) don't always get this right for 64-bit doubles stored on the stack. This causes twice the amount of memory operations to be necessary to load one, in practice resulting in about a 2x performance hit compared to properly aligned 64-bit floats or 32-bit floats.

As far as SIMD optimizations go, it should be noted that most compilers are horrible at auto-vectorizing code. If you don't want to write directly in assembly language, the best way to take advantage of these instructions is to use things like array-wise operations, which are available, for example, in D, and implemented in terms of SSE instructions. Similarly, in C or C++, you would probably want to use a high level library of functions that are SSE-optimized, though I don't know of a good one off the top of my head because I mostly program in D.

  • 4
    "x87" - Slightly better than those old x86 processors. :-)
    – Thanatos
    Jul 10 '10 at 1:57

It's probably because your processor still makes the 64bit counting and then trimms the number. There was some CPU flag you could change, but I can't remember...


First check the ASM that gets produced. It may not be what you expect.

Also try writing it as a loop:

typedef float fp;
fp q = 0
for(int i = 0; i < N; i++)
  q += x[i]*y[i]*z[i]

Some compiler might notice the loop and not the unrolled form.

Lastly, your code used () rather than []. If your code is making lots of function calls (12 to 21), that will swamp the FP cost and even removing the fp computation all together won't make much difference. Inlineing OTOH might.

  • thanks, actually q() are macros converting directly to raw pointer access
    – Anycorn
    Jul 10 '10 at 2:21
  • @aaa: Well if there is any math at all, it might still be a large percentage. Also, I don't know how well compiler deal with mixing FP and other stuff. That might be enough to block it from using vector ops.
    – BCS
    Jul 10 '10 at 16:04

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