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Does x86/x64 use SIMD register for high precision floating point operations or dedicated FP registers?

I mean the high precision version, not regular double precision.

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"High precision" is all done by software. The processor knows nothing beyond double precision and extended precision in the x87 FPU. – Mysticial Aug 9 '13 at 0:40
@Mysticial - every processor I know of has FP registers with resolution beyond 64 bit for internal operations to minimize approximation errors. – user2341104 Aug 9 '13 at 0:44
Those "internal" registers aren't accessible to the software. They are only slightly larger than 53/64 bits so that the final result is accurate to 53/64 bits. The multiplication ones might be as large as 106/128 bits before rounding. But you can't access them. – Mysticial Aug 9 '13 at 0:53
You can access the registers that the instruction set exposes. These include the x87 FPU/SSE/AVX. But there aren't higher precision versions of those that the software can use. Yes, internally, the processor may have higher precision registers, but they are only for internal operations which will all be rounded to 53/64 bits upon getting put back into an ISA accessible register. – Mysticial Aug 9 '13 at 0:58
@Mysticial Correctly-rounded multiplication is implemented with three additional bits to the width of the result, the last of which is specially wired (“sticky bit”). Scroll down to “sticky” on – Pascal Cuoq Aug 9 '13 at 7:26

The FPU stack is still available and exposes a 80-bits precision arithmetic as @EricPostpischil points out (not sure though if the processor still has the full logic or if this part got emulated at hardware level). It is made available to the developper in GCC with the long double type. For example, the generated assembly for method

long double f(long double a, long double b)
    return a*b ;

Will be

    fldt    16(%rbp)
    fldt    32(%rbp)
    fmulp   %st, %st(1)

This archive email provides useful elements for using such data e.g.:

long double my_logl(long double x)
  long double y;
  __asm__ volatile(
    "fldl   %1\n"
    : "=t" (y) : "m" (x));
  return y;

When compiling code without SSE, AVX or other vector extension, your code will likely generate such instructions using the 80bits FPU, and probably will output different values. Here is an example code to illustrate:

double epstest(long double a, long double b)
        long double y ;
        y = a + b ;
        y = y - a ;
        return y ;

#include <cstdio>

int main()
        double x = 1.0 ;
        double y = 1e-17 ;
        double z = x + y ;
        z = z - x ;
        printf ("double: %lf + %le - %lf = %le\n",  x, y, x, z);
        double res = epstest (x, y) ;
        printf ("long double: %lf + %le - %lf = %le\n",  x, y, x, res);
        return 0 ;

And the output:

double: 1.000000 + 1.000000e-17 - 1.000000 = 0.000000e+00
long double: 1.000000 + 1.000000e-17 - 1.000000 = 9.974660e-18

Higher precision (beyond long double) is implemented in software for x86_64.

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x87 still has high performance on current-generation x87 CPUs, as you can see from Agner Fog's insn tables. On Skylake, for example, fadd is 3c latency, one per 1c throughput (and runs on port5!). Only the complex x87 insns (like fsin) are microcoded. Even fsqrt is fast. Load/store of 80bit floats is very slow, though. – Peter Cordes 1 hour ago
By comparison, on Skylake, addps/addss are 4c latency, one per 0.5c throughput. (SSE/AVX add/sub/mul/fma on Skylake all have the same performance, since they dropped the lower-latency dedicated add unit that was present until Broadwell.) – Peter Cordes 1 hour ago
Also, you don't have to use -O0 or anything dumb like that. The x86-64 SysV ABI specifies that long double is the 80 bit x87 type, so code using that type is required to have that much precision. – Peter Cordes 1 hour ago

The FPU (Floating-Point Unit) has registers for 80-bit floating-point values (in an Intel format that is the IEEE 754 format with slight changes).

The various SIMD units (SSE, AVX et cetera) have larger registers that are usable for a number of things, but there are only instructions for using them as 32-bit and 64-bit floating-point.

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